HP Hewlett Packard Power Supply 6621A User Manual

OPERATING MANUAL  
SYSTEM  
DC POWER SUPPLIES  
HP MODELS 6621A, 6622A,  
6623A, 6624A, and 6627A  
HP Part No 5957-6377  
HP Model 6621A, Serials 3213A-01681 and Above*  
HP Model 6622A, Serials 3210A-02091 and Above*  
HP Model 6623A, Serials 3209A-02231 and Above*  
HP Model 6624A, Serials 3210A-06721 and Above*  
HP Model 6627A, Serials 3209A-00841 and Above*  
* For instruments with higher Serial Numbers, a change page may be included.  
Microfiche Part No. 5957-6378  
Printed in USA: January, 1993  
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SAFETY SUMMARY  
The following general safety precautions must be observed during all phases of operation, service, and repair of this  
instrument. Failure to comply with these precautions or with specific warnings elsewhere in this manual violates safety  
standards of design, manufacture, and intended use of the instrument. Hewlett-Packard Company assumes no liability for  
the customer's failure to comply with these requirements.  
BEFORE APPLYING POWER.  
Verify that the product is set to match the available line voltage and the correct fuse is installed.  
GROUND THE INSTRUMENT.  
This product is a Safety Class 1 instrument (provided with a protective earth terminal). To minimize shock hazard, the instrument  
chassis and cabinet must be connected to an electrical ground. The instrument must be connected to the ac power supply mains through  
a three-conductor power cable, with the third wire firmly connected to an electrical ground (safety ground) at the power outlet. For  
instruments designed to be hard-wired to the ac power lines (supply mains), connect the protective earth terminal to a protective  
conductor before any other connection is made. Any interruption of the protective (grounding) conductor or disconnection of the  
protective earth terminal will cause a potential shock hazard that could result in personal injury. If the instrument is to be energized via  
an external autotransformer for voltage reduction, be certain that the autotransformer common terminal is connected to the neutral  
(earthed pole) of the ac power lines (supply mains).  
FUSES.  
Only fuses with the required rated current, voltage, and specified type (normal blow, time delay, etc.) should be used. Do not use  
repaired fuses or short circuited fuseholders. To do so could cause a shock or fire hazard.  
DO NOT OPERATE IN AN EXPLOSIVE ATMOSPHERE.  
Do not operate the instrument in the presence of flammable gases or fumes.  
KEEP AWAY FROM LIVE CIRCUITS.  
Operating personnel must not remove instrument covers. Component replacement and internal adjustments must be made by qualified  
service personnel. Do not replace components with power cable connected. Under certain conditions, dangerous voltages may exist  
even with the power cable removed. To avoid injuries, always disconnect power, discharge circuits and remove external voltage  
sources before touching components.  
DO NOT SERVICE OR ADJUST ALONE.  
Do not attempt internal service or adjustment unless another person, capable of rendering first aid and resuscitation, is present.  
DO NOT EXCEED INPUT RATINGS.  
This instrument may be equipped with a line filter to reduce electromagnetic interference and must be connected to a properly  
grounded receptacle to minimize electric shock hazard. Operation at line voltages or frequencies in excess of those stated on the data  
plate may cause leakage currents in excess of 5.0 mA peak.  
SAFETY SYMBOLS.  
Instruction manual symbol: the product will be marked with this symbol when it is necessary for the user to refer to  
the instruction manual (refer to Table of Contents) .  
Indicates hazardous voltages.  
Indicate earth (ground) terminal.  
The WARNING sign denotes a hazard. It calls attention to a procedure, practice, or the like, which, if not correctly  
performed or adhered to, could result in personal injury. Do not proceed beyond a WARNING sign until the  
indicated conditions are fully understood and met.  
The CAUTION sign denotes a hazard. It calls attention to an operating procedure, or the like, which, if not correctly  
performed or adhered to, could result in damage to or destruction of part or all of the product. Do not proceed  
beyond a CAUTION sign until the indicated conditions are fully understood and met.  
DO NOT SUBSTITUTE PARTS OR MODIFY INSTRUMENT.  
Because of the danger of introducing additional hazards, do not install substitute parts or perform any unauthorized modification to the  
instrument. Return the instrument to a Hewlett-Packard Sales and Service Office for service and repair to ensure that safety features  
are maintained.  
Instruments which appear damaged or defective should be made inoperative and secured against unintended operation until they can be  
repaired by qualified service personnel.  
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SAFETY SUMMARY (continued)  
GENERAL  
Any LEDs used in this product are Class 1 LEDs as per IEC 825-1.  
ENVIRONMENTAL CONDITIONS  
This instrument is intended for indoor use in an installation category II, pollution degree 2 environment. It is designed to  
operate at a maximum relative humidity of 95% and at altitudes of up to 2000 meters. Refer to the specifications tables for  
the ac mains voltage requirements and ambient operating temperature range.  
SAFETY SYMBOL DEFINITIONS  
Symbol  
Description  
Direct current  
Symbol  
Description  
Terminal for Line conductor on permanently  
installed equipment  
Alternating current  
Caution, risk of electric shock  
Caution, hot surface  
Both direct and alternating current  
Three-phase alternating current  
Earth (ground) terminal  
Caution (refer to accompanying documents)  
In position of a bi-stable push control  
Protective earth (ground) terminal  
Frame or chassis terminal  
Out position of a bi-stable push control  
On (supply)  
Terminal for Neutral conductor on  
permanently installed equipment  
Off (supply)  
Terminal is at earth potential  
Standby (supply)  
(Used for measurement and control  
circuits designed to be operated with  
one terminal at earth potential.)  
Units with this symbol are not completely  
disconnected from ac mains when this switch is  
off. To completely disconnect the unit from ac  
mains, either disconnect the power cord or have  
a qualified electrician install an external  
switch.  
Herstellerbescheinigung  
Diese Information steht im Zusammenhang mit den Anforderungen der  
Maschinenläminformationsverordnung vom 18 Januar 1991.  
* Schalldruckpegel Lp <70 dB(A) * Am Arbeitsplatz * Normaler Betrieb  
* Nach EN 27779 (Typprüfung).  
Manufacturer's Declaration  
This statement is provided to comply with the requirements of the German Sound Emission Directive,  
from 18 January 1991.  
* Sound Pressure Lp <70 dB(A) * At Operator Position * Normal Operation  
* According to EN 27779 (Type Test).  
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DECLARATION OF CONFORMITY  
according to ISO/IEC Guide 22 and EN 45014  
Manufacturer's Name:  
Manufacturer's Address:  
Hewlett-Packard Company  
150 Green Pond Road  
Rockaway, New Jersey 07866  
U.S.A.  
declares that the Product  
Product Name:  
a) Multiple-Output System Power Supply  
b) Precision Multiple-Output System Power Supply  
Model Number:  
a) HP 6621A, 6622A, 6623A, 6624A, 6627A  
b) HP 6625A, 6626A, 6628A, 6629A  
conforms to the following Product Specifications:  
Safety:  
EMC:  
IEC 348:1978 / HD 401S1: 19811  
CISPR 11:1990 / EN 55011:1991 - Group 1 Class B  
IEC 801-2:1991 / EN 50082-1:1992 - 4 kV CD, 8 kV AD  
IEC 801-3:1984 / EN 50082-1:1992 - 3 V / m  
IEC 801-4:1988 / EN 50082-1:1992 - 0.5 kV Signal Lines  
1 kV Power Lines  
Supplementary Information:  
The product herewith complies with the requirements of the Low Voltage Directive  
73/23/EEC and the EMC Directive 89/336/EEC and carries the CE-marking accordingly.  
Note 1: The product family was introduced prior to 12/93.  
New Jersey  
Location  
January 1997  
Date  
Bruce Krueger / Quality Manager  
European Contact: Your local Hewlett-Packard Sales and Service Office or Hewlett-Packard GmbH,  
Department TRE, Herrenberger Strasse 130, D-71034 Boeblingen (FAX:+49-7031-14-3143)  
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WHAT THIS MANUAL CONTAINS  
This is the Operating manual for the HP 6621A through 6624A and 6627A Series of Multiple Output Linear System  
Power Supplies. It contains information relating to the installation, operation, and programming of these supplies as  
outlined below. Maintenance and troubleshooting instructions are given in a separate Service Manual (HP Part No. 5957-  
6379).  
Chapter 1.--General Information  
Chapter 1 contains a general description of the power supplies as well as instrument specifications and information  
concerning options and accessories.  
Chapter 2.--Installation Procedures  
Chapter 2 contains information to prepare the supply for use. Included in this chapter are power requirements, line  
voltage conversion, and HP-IB interface connections.  
Chapter 3.--Getting Started  
Chapter 3 contains a brief description of the supply's front panel controls and indicators and describes how to turn on the  
supply and to check it's operation. An introduction to remote operation over the HP-IB is also given to help a first time  
user get started quickly.  
Chapter 4.--Output Connections and Operating Information  
Chapter 4 contains information about making connections to the supply's output terminals. General operating information  
is also provided.  
Chapter 5.--Remote Operation  
Chapter 5 contains all of the information required to operate the supply remotely via an HP-IB computer. All of the  
commands that can be used to program the supplies are described.  
Chapter 6.--Local Operation  
Chapter 6 contains instructions on using all of the front panel controls and indicators.  
Appendix A--Calibration Procedure  
Appendix A contains programming steps and procedures that are required to calibrate your power supply. It is  
recommended that the power supply be calibrated yearly.  
Appendix B--Programming with Series 200 Computer  
Appendix B contains Series 200/300 Computer programming examples (in HP extended BASIC language) for your Power  
Supply's most frequently used functions.  
Appendix C--Command Summary  
Appendix C contains an alphabetical listing of all commands that can be sent to a supply.  
Appendix D--Error Messages  
Appendix D contains a listing and brief explanation of all error codes and messages for all programming and hardware  
errors.  
Appendix E - Manual Backdating  
Appendix E contains backdating information for units with Serial numbers lower than those listed on the title page.  
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Table Of Contents  
1
General Information  
Introduction............................................................................................................................................11  
Safety Considerations................... ..........................................................................................................11  
Instrument and Manual Identification.....................................................................................................11  
Options...................................................................................................................................................11  
Accessories.............................................................................................................................................12  
Description ............................ ................................................................................................................12  
Basic Operation......................... .............................................................................................................13  
HP-IB Board.......................................................................................................................................13  
Output Boards.....................................................................................................................................14  
Specifications......................... ................................................................................................................15  
Qualifying Conditions.........................................................................................................................15  
Definitions..........................................................................................................................................15  
2
Installation  
Introduction............................................................................................................................................25  
Initial Inspection.....................................................................................................................................25  
Location and Cooling..............................................................................................................................25  
Input Power Requirements......................................................................................................................26  
Line Fuse................................................................................................................................................26  
Power Cord.............................................................................................................................................28  
Line Voltage Conversion................. .......................................................................................................28  
HP-IB Interface Connector......................................................................................................................29  
3
Getting Started  
Introduction ...........................................................................................................................................31  
Front Panel Controls and Indicators........................................................................................................31  
Turning On Your Supply................. .......................................................................................................31  
Normal Self Test Indications...............................................................................................................35  
Self Test Errors...................................................................................................................................36  
Checking Out Your Supply Using Local Control.....................................................................................36  
Voltage Test............................ ...........................................................................................................37  
Overvoltage Test.................................................................................................................................37  
Current Test............................ ...........................................................................................................37  
Introduction To Remote Operation..........................................................................................................38  
Enter/Output Statements.....................................................................................................................38  
Reading the HP-IB Address.............. ..................................................................................................39  
Changing the HP-IB Address..............................................................................................................39  
Sending a Remote Command..............................................................................................................39  
Getting Data from the Supply........... ..................................................................................................40  
Often Used Commands.................... ...................................................................................................40  
Returning the Supply to Local Mode...................................................................................................42  
4
Output Connections and Operating Information  
Introduction ...........................................................................................................................................43  
Output Ranges............................... .........................................................................................................43  
Operating Quadrants...........................................................................................................................44  
Range Selection............................. .....................................................................................................44  
Protection Features......................... ........................................................................................................44  
Connecting The Load......................... ....................................................................................................46  
Wire Size Selection.............................................................................................................................47  
Multiple Loads....................................................................................................................................49  
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Table Of Contents (continued)  
Positive and Negative Voltages.............. .............................................................................................49  
Remote Voltage Sensing..................... ....................................................................................................49  
Remote Sense Connections................... ..............................................................................................50  
Output Noise Considerations...............................................................................................................51  
Programming Response Time with an Output Capacitor............................. ........................................51  
Open Sense Leads...............................................................................................................................51  
Overvoltage Trigger Connections............................................................................................................52  
External Trigger Circuit................... ..................................................................................................52  
Power Supply Protection Considerations .......................... ......................................................................54  
Battery Charging........................... .....................................................................................................54  
Capacitive Load Limitation.................................................................................................................54  
Parallel Operation...................................................................................................................................54  
CV Operation............................... ......................................................................................................55  
CC Operation............................... ......................................................................................................56  
Remote Sensing........................... .......................................................................................................56  
Specifications for Parallel Operation...................................................................................................56  
Series Operation....................... ..............................................................................................................57  
CV Operation............................... ......................................................................................................57  
CC Operation............................... ......................................................................................................58  
Remote Sensing........................... .......................................................................................................58  
Specifications for Series Operation. ....................................................................................................58  
5
Remote Operation  
Introduction ...........................................................................................................................................61  
HP-IB Operation.....................................................................................................................................61  
Interface Function...............................................................................................................................61  
HP-IB Address Selection.....................................................................................................................62  
Power-On Service Request (PON).......................................................................................................63  
Programming Syntax......................... .....................................................................................................63  
Numeric Data............................... ......................................................................................................63  
Order of Execution......................... ....................................................................................................68  
Terminators........................................................................................................................................68  
Initial Conditions....................................................................................................................................68  
Power Supply Commands .......................................................................................................................68  
Voltage Programming.........................................................................................................................69  
Current Programming.........................................................................................................................69  
Range Switching.................................................................................................................................70  
Output On/Off.................................... ................................................................................................71  
Overvoltage Protection........................................................................................................................71  
Overcurrent Protection........................................................................................................................72  
Multiple Output Storage and Recall............... .....................................................................................72  
The Clear Command...........................................................................................................................73  
Status Reporting................................. ................................................................................................73  
Service Request Generation....................... .........................................................................................76  
Reprogramming Delay........................................................................................................................78  
Display On/Off................................... ................................................................................................78  
Other Queries.................................... .................................................................................................79  
6
Local Operation  
Introduction ...........................................................................................................................................83  
Local Mode.............................................................................................................................................83  
Local Control Of Output Functions.........................................................................................................83  
General...................................................................................................................................................83  
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Table Of Contents (continued)  
Setting Voltage...................................................................................................................................84  
Setting Current................................... ................................................................................................84  
Enabling/Disabling an Output.............................................................................................................85  
Setting Overvoltage Protection............................................................................................................85  
Resetting Overvoltage Protection................ ........................................................................................85  
Enabling/Disabling Overcurrent Protection.........................................................................................85  
Resetting Overcurrent Protection................. .......................................................................................85  
Displaying the Contents of the Fault Register......................................................................................85  
Setting the Reprogramming Delay................ ......................................................................................86  
Local Control Of System Functions.........................................................................................................86  
Setting the Supply's HP-IB Address............... .....................................................................................86  
Displaying Error Messages....................... ..........................................................................................87  
Storing and Recalling Voltage and Current Settings for all Outputs....................................................87  
A
B
Calibration  
Introduction............................................................................................................................................89  
Test Equipment and Setup Required................. ......................................................................................89  
General Calibration Procedure................................................................................................................91  
Calibration Program.............................. .................................................................................................93  
Programming With The Series 200/300 Computer  
Introduction ...........................................................................................................................................97  
I/O Path Names...................... ................................................................................................................97  
Voltage and Current Programming..... ....................................................................................................97  
Voltage and Current Programming With Variables.................................................................................98  
Voltage and Current Readback................................................................................................................98  
Programming Power Supply Registers.. ..................................................................................................99  
Present Status...................... ...............................................................................................................99  
Service Request and Serial Poll...........................................................................................................99  
Error Detection ................................................................................................................................ 101  
Stored Operating States........... ......................................................................................................... 102  
Programming Outputs Connected In Parallel..... ................................................................................... 102  
CC Operation....................... ............................................................................................................ 103  
CV Operation....................... ............................................................................................................ 103  
Programming Outputs Connected In Series........................................................................................... 104  
C
D
Command Summary  
Introduction.......................................................................................................................................... 105  
Error Messages  
Introduction.......................................................................................................................................... 109  
Power-On Self Test Messages......... ...................................................................................................... 109  
Error Responses.................................................................................................................................... 109  
Test Responses...................................................................................................................................... 109  
E
Manual Backdating  
Introduction ......................................................................................................................................... 113  
Make Changes ..................................................................................................................................... 113  
Addendum  
Generally Applicable Annotations/CE’92 Product Specific Annotations ........................ ...................... 114  
HP Sales and Support Office  
Contacts ............................................................................................................................................... 115  
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1
General Information  
Introduction  
This chapter contains a general description of your power supply, as well as its performance specifications. Information  
about options, accessories, and HP-IB cables is also provided. This manual describes all five models in the HP 6621A-  
6624A, and 6627A power supply family. Unless stated otherwise, the information in this manual applies to all of these  
models. Information that is specific to one model only is identified as such in this manual.  
Safety Considerations  
This product is a Safety Class 1 instrument, which means that it is provided with a protective earth terminal. This  
terminal must be connected to a power source that has a 3-wire ground receptacle. Review the instrument and this manual  
for safety markings and instructions before operation. Refer to the Safety Summary page at the beginning of this manual  
for a summary of general safety information. Safety information for specific procedures is located at appropriate places in  
this manual.  
Instrument and Manual Identification  
Hewlett-Packard power supplies are identified by a two-part serial number, i.e. 2601A-00101. The first part of the serial  
number (the prefix) is a number/letter combination that denotes either the date of manufacture or the date of a significant  
design change. It also indicates the country of origin. (Starting at 1960, 26 = 1986; 01 = the first week of the year; A =  
U.S.A.) The second part of the serial number is a different sequential number assigned to each instrument starting with  
00101.  
If the serial number prefix on your power supply differs from that shown on the title page of this manual, a yellow Manual  
Changes sheet that is supplied with this manual explains the difference between your instrument and the instrument  
described by this manual. The change sheet can also contain information for correcting errors in the manual.  
Options  
Options 100,120, 220, and 240 simply determine which line voltage is selected at the factory. For information about  
changing the line voltage setting, see Line Voltage Conversion, page 28.  
Option 750 consists of a fault indicator (FLT) and remote inhibit (INH) circuit and relay control, which provide additional  
shutdown protection should either the HP-IB and/or controller fail. This Option is described in a separate document  
entitled, "Appendix E Option 750 Operating Instructions for the Multiple Output Linear System DC Power Supply, HP  
Models 6621A, 6622A, 6623A, 6624A, and 6627A (HP P/N 5957-6372).  
#100 Input power, 100 Vac, 47--66 Hz  
#120 Input power, 120 Vac, 47--66 Hz  
#220 Input power, 220 Vac, 47--66 Hz  
#240 Input power, 240 Vac, 47--66 Hz  
#700 Computer Interface Intermediate Language (CIIL)  
#750 Fault (FLT) Remote Inhibit (INH) and Relay Control  
#908 One rack mount kit (5062-3977)  
#909 One rack mount kit with handles (5062-3983)  
#910 One service manual with extra operating manual  
General Information 11  
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Accessories  
10833A HP-IB cable, 1 m (3.3 ft)  
10833B HP-IB cable, 2 m (6.6 ft)  
10833C HP-IB cable, 4 m (13.2 ft)  
10833D HP-IB cable, 0.5 m (1.6 ft)  
10834A HP-IB connector extender  
Slide mount kit (1494-0059)  
Description  
The HP 6621A-6624A, and 6627A Multiple Output Linear Power Supplies feature a combination of programming  
capabilities and linear power supply performance that make systems applications. The five models in this family offer a  
total of up to 200 watts of output power, with voltages up to 50 volts and currents up to 10 amps. The output combinations  
that correspond to each model are shown in Table 1-1. Each isolated output can supply power in two ranges as shown in  
Figure 1-1. This flexibility allows you to use the same output to power loads with different voltage and current  
requirements. No separate command is required to program ranges; the power supply automatically selects one of the  
operating ranges based on the last parameter (voltage or current) that is set. Additionally, each output contains an active  
downprogrammer, which means that voltage downprogramming can be accomplished as quickly as upprogramming, even  
without a load.  
Table 1-1. Output Combinations Available  
Model  
HP 6621A  
HP 6622A  
HP 6623A  
HP 6624A  
HP 6627A  
Output 1  
Output 2  
Output 3  
Output 4  
80 W Low Voltage  
80 W High Voltage  
40 W Low Voltage  
40 W Low Voltage  
40 W High Voltage  
80 W Low Voltage  
80 W High Voltage  
80 W Low Voltage  
40 W Low Voltage  
40 W High Voltage  
-
-
-
-
-
40 W High Voltage  
40 W High Voltage  
40 W High Voltage  
40 W High Voltage  
40 W High Voltage  
The output voltage and current for any output can be monitored with the front panel display. Output specific error  
messages are also displayed. Front panel annunciators show the operating status of the instrument. The front panel keypad  
lets you set and readback the voltage limit, current limit, and overvoltage trip level of any output. With the keypad, you  
can also enable or disable outputs, mask and delay bits in the fault register, enable overcurrent protection, reset  
overvoltage and overcurrent protection, and return to local operating mode.  
Your multiple output power supply can be both a listener and a talker on the HP-IB. (HP-IB is Hewlett-Packard's  
implementation of IEEE-488). The built-in interface is tailored to the supply, resulting in simpler programming. Voltage  
and current settings can be sent directly to the specified dual range output in volts and amps.  
Service can be requested from your power supply for up to ten reasons. The supply responds to a serial poll by identifying  
the output on which the fault occurred. Self-contained measurement and readback capability eliminate the need for  
externally scanning the outputs using a separate DVM. Upon command the supply will measure its output voltage or  
current and return the value on the HP-IB. The following functions are implemented via the HP-IB:  
Voltage and current programming.  
Voltage and current measurement and readback.  
Present and accumulated status readback.  
Programmable service request mask.  
Programmable overvoltage and overcurrent protection.  
12 General Information  
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Storage and recall of programmed voltage and current values for all outputs.  
Queries of programmed functions or settings.  
Output enable or disable.  
Programming syntax error detection.  
Programmable delay time for service request and OCP mask.  
Voltage, current, and overvoltage calibration.  
HP-IB interface selftest.  
Message display capability on the front panel.  
Output connections are made to rear panel screw terminals. Either the positive or negative output terminal can be  
grounded, or the output can be floated up to ± 240 Vdc (including output voltage) from chassis ground. Output voltage  
can be locally or remotely sensed, and identical outputs can be operated in series or parallel combinations for increased  
output voltage or current capability. As shipped from the factory, the power supply is jumpered for local sensing.  
Your power supply can be calibrated without having to remove the cover or even having to remove it from your system  
cabinet. This feature allows you to calibrate the supply at its normal operating temperature. The recommended calibration  
interval is one year. Refer to Appendix A of this manual for complete calibration details. A calibration security jumper is  
available inside the unit. Access is described in the service manual.  
Basic Operation  
Figure 1-2 is a block diagram that illustrates the major assemblies contained within the power supply. As shown in the  
figure, each supply includes a power transformer, two or more output boards, an HP-IB board, and front panel (display  
and control keys).  
Output  
Low Range Values  
7 V @ 10 A  
High Range Values  
20 V @ 4 A  
80 W Low, Voltage  
80 W High Voltage  
40 W Low Voltage  
40 W High Voltage  
20 V @ 4 A  
7 V @ 5 A  
20 V @ 2 A  
50 V @ 2 A  
20 V @ 2 A  
50 V @ 0.8 A  
Figure 1-1. Output Operating Ranges for HP Models 6621A, 6624A and 6627A.  
The appropriate ac input voltage is applied to each output board where it is converted to a raw dc voltage which is  
subsequently linearly regulated to become the dc output voltage. The magnitude of the output and the mode of operation  
are determined by the load and the data received from the HP-IB computer or from the front panel.  
Each power supply model contains one output board for each output that it provides. Models 6624A and 6627A contain  
four 40 watt output boards; Model 6623A contains two 40 watt output boards and one 80 watt output board; Models  
6621A and 6622A each contain two 80 watt output boards.  
HP-IB Board  
The HP-IB board provides the interface between the user and the multiple outputs of the power supply. Each output board  
is actually an output channel that can be individually selected and controlled over the HP-IB or from the supply's front  
panel. Circuits on the HP-IB board interpret commands from the HP-IB or from the front panel to control the selected  
output.  
General Information 13  
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The HP-IB board also processes measurement and status data received from the output boards. This data may be read back  
over the HP-IB and/or displayed on the supply's front panel.  
The power supply has no potentiometers. Each output is individually calibrated over the HP-IB using calibration  
commands (see Appendix A). Correction factors are calculated by the power supply during calibration and are stored in a  
non-volatile memory which is located on the supply's HP-IB board. The supply contains no batteries.  
Output Boards  
The output boards are linear dc power supplies. Each isolated output has the L-shaped operating curve described in  
Description, page 12 and Figure 1-1.  
The ac input to each output board is rectified and applied to a regulator circuit. Each output board employs series  
regulation techniques. A regulator element is connected in series with the load and operates in the linear region (between  
saturation and cutoff) of the transistor characteristic curve. Regulation is achieved by varying the conduction of the series  
element in response to a change in line voltage or circuit load.  
The output board receives digital signals from the HP-IB board and converts them to analog signals which program the  
output voltage, current, and overvoltage values. The output may be programmed remotely over the HP-IB using  
commands (see Chapter 5) or locally from the supply's front panel using the control keys (see Chapter 6).  
The output board can be commanded to send measurement and status data back over the HP-IB and/or front panel. The  
data is sent back via the supply's HP-IB board. HP-IB readback capabilities include output voltage and current, present  
and accumulated status, and all programmed settings. The front panel LCD display can indicate the output voltage and  
current, the supply's HP-IB address, error messages, and programmed values. Annunciators on the front panel indicate the  
operating status of the selected channel (output board).  
Figure 1-2. HP 6621A, 6624A and 6627A Multiple Output System Power Supplies, Block Diagram  
14 General Information  
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Specifications  
Table 1-2 lists the performance specifications for the HP 662xA power supplies. Performance specifications describe the  
instrument's warranted performance. The service manual, Option 9l0, contains procedures for verifying the performance  
specifications.  
Table 1-3 lists the supplemental characteristics for the HP 662xA supplies. Supplemental characteristics are type-tested or  
typical values, which are based on a product sample and, while representative, are not guaranteed.  
Qualifying Conditions  
All performance specifications apply over the full operating temperature range of the power supply (0 to 55°C) unless  
otherwise specified. All regulation, accuracy, etc. specifications are plus or minus the values listed. All measurements are  
made at the rear terminals of the supply with a resistive load and local sensing unless otherwise specified. Voltage  
measurements are made from the + S to the - S terminals. Overvoltage measurements are made from the + V to the - V  
terminals. + Current refers to the output acting as a current source while - Current refers to the output acting as a current  
sink.  
Definitions  
Load effect: Maximum steady state change in the regulated output parameter due to a change in load resistance on the  
output in question.  
Source effect: Maximum steady state change in the regulated output parameter due to a change in the source voltage  
within rated values. (Expressed as a percentage of setting plus a constant).  
Cross regulation: Maximum steady state change in the regulated output parameter due to a change in load resistance on  
any other output(s).  
Programming accuracy: (Calibration temp ± 5°C) Maximum difference between the programmed value and the actual  
output. (Expressed as a constant plus a percentage of the setting.)  
Readback accuracy: (Calibration temp ± 5°C) Maximum error in reading back an output parameter. (Expressed as a  
constant plus a percentage of the reading).  
Output response time: Beginning at the time the power supply has finished processing a VSET command (change output  
voltage), the maximum time for the output voltage to settle to within a settling band about the final value from any  
specified operating point. This value must be added to the command processing time to obtain total programming time  
(see Figure 1-3). Time constant is the maximum time required for the voltage to reach 63% of its final value.  
Temperature coefficient: Maximum change in the regulated output parameter per °C change in ambient temperature  
after a 30 minute warmup. Expressed in parts-per-million plus a constant per °C (plus a constant for readback  
temperature coefficient).  
Long Term Drift: Maximum change of regulated output voltage or current during an 8-hour period following a 30  
minute warmup, with all influence and control quantities maintained constant. Expressed as a percentage of setting plus a  
constant.  
Short Term Drift: Maximum change of regulated output voltage or current within 30 minutes after a line and/or load  
change. Expressed as a percentage of setting plus a constant.  
Output Noise (PARD): PARD replaces the former term ripple and noise. PARD is the periodic and random deviation of  
dc output voltage or current from its average value, over a specified bandwidth and with all influence and control  
quantities maintained constant.  
General Information 15  
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Programming resolution: Average programming step size.  
Current Sinking ( - Current): Each output can sink as well as source current. The sinking capability is not  
programmable and depends upon the output voltage. The current sinking capability is described in greater detail in  
Chapter 4.  
Figure 1-3. Output Response Characteristics  
16 General Information  
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Table 1-2. Specifications  
PERFORMANCE SPECIFICATIONS (0 to 55°C unless otherwise specified)  
Outputs:  
40 W Low  
Voltage  
40 W High  
Voltage  
80 W Low  
Voltage  
80 W High  
Voltage  
DC Output Ranges: All outputs will accept voltage programming commands 1% higher than those listed and current programming  
commands 3% higher than those listed. Also, the minimum programmable current values are slightly above zero amps for each output.  
(See Table 5-4).  
Low Range  
High Range  
0-7 V; 0-5 A  
0-20 V; 0-2 A  
0-20 V; 0-2 A  
0-50 V: 0-0.8 A  
0-7 V; 0-10 A  
0-20 V; 0-4 A  
0-20 V: 0-4 A  
0-50 V; 0-2 A  
Load Effect (Regulation): When remote sensing, add 1 mV to the value listed for each 200 mV drop in the - V load lead.  
Voltage  
+ Current  
2 mV  
1 mA  
2 mV  
0.5 mA  
2 mV  
2 mA  
2 mV  
1 mA  
Source Effect:  
Voltage  
+ Current  
0.01% + 1 mV  
0.06% + 1 mA  
0.01% + 1 mV  
0.06% + 1 mA  
0.01% + 1 mV  
0.06% + 2 mA  
0.01% + 1 mV  
0.06% + 2 mA  
Programming Accuracy: (At calibration temperature ± 5°C)  
Note: The programming accuracy specifications may degrade slightly when the unit is subjected to an RF field equal to or greater than  
3 volts/meter.  
Voltage  
+ Current  
OVP  
19 mV + 0.06%  
100 mA + 0.16%  
200 mV + 0.13%  
50 mV + 0.06%  
20 mA + 0.16%  
475 mV + 0.13%  
19 mV + 0.06%  
100 mA + 0.16%  
200 mV + 0.13%  
50 mV + 0.06%  
40 mA + 0.16%  
475 mV + 0.13%  
Readback Accuracy: (At calibration temperature ±5°C)  
Voltage  
+ Current  
- Current  
20 mV + 0.05%  
10 mA +0.1%  
25 mA +0.2%  
50 mV +0.05%  
4 mA + 0.1%  
8 mA +0.2%  
20 mV + 0.05%  
20 mA +0.1%  
50 mA +0.2%  
50 mV +0.05%  
8 mA +0.1%  
20 mA +0.2%  
Load Transient Recovery Time:  
75 mS maximum to recover to within 75 mV of nominal value following a load change within the range 300 mA to full load for low  
voltage units, and 150 mA to full load for high voltage units.  
Maximum Output Noise (PARD):  
CV peak-to-peak  
(20 Hz--20 MHz)  
3 mV  
3 mV  
3 mV  
3 mV  
0.5 mV  
1 mA  
0.5 mV  
1 mA  
0.5 mV  
2 mA  
0.5 mV  
2 mA  
CV rms  
(20 Hz--10 MHz)  
+ CC rms  
(20Hz--10 MHz)  
AC Input Voltage and Frequency:  
Nominal Line = 100,120, 220, or 240 Vac  
Amplitude = + 6%, -13% of nominal line voltage  
Frequency Range = 47-66 Hz  
Note: At low line, the supply will operate with up to 3/4 W line resistance.  
General Information 17  
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Table 1-3. Supplemental Characteristics  
Outputs  
40 W Low  
Voltage  
40 W High  
Voltage  
80 W Low  
Voltage  
80 W High  
Voltage  
Temperature Coefficient:  
Voltage  
+Current  
OVP  
(60 ppm + 0.4 mV)/ °C  
(160 ppm +0.2mA)/°C  
(130 ppm + 1 mV)/ °C  
(60 ppm + 1 mV)/ °C  
(160 ppm +0.1 mA)/°C (160 ppm +0.4mA)/°C  
(130 ppm + 2 mV)/ °C  
(60 ppm + 0.4 mV)/ °C (60 ppm + 1 mV)/ °C  
(160 ppm +0.2 mA)/°C  
(130 ppm + 2 mV)/ °C  
(130 ppm + 1 mV)/ °C  
Readback Temperature Coefficient:  
Voltage  
+Current  
-Current  
(40 ppm +0.3 mV)/°C  
+ 10 mV  
(85 ppm +0.25 mA)/°C  
+3 mA  
(95 ppm + 0.3 mA)/°C  
+3 mA  
(40 ppm +0.7 mV)/°C  
+ 23 mV  
(85 ppm +0.1 mA)/°C  
+1 mA  
(95 ppm +0.1 mA)/°C  
+1.2 mA  
(40 ppm +0.3 mV)/°C  
+ 10 mV  
(85 ppm +0.5 mA)/°C  
+5 mA  
(95 ppm +0.6 mA)/°C  
+6 mA  
(40 ppm +0.7 mV)/°C  
+ 23 mV  
(85 ppm +0.2 mA)/°C  
+2 mA  
(95 ppm +0.2 mA)/°C  
+2.3 mA  
Long Term Drift: (In an 8 hour period following a 30 minute warmup):  
Voltage  
+ Current  
0.012% + 1 mV  
0.032% + 2 mA  
0.012% + 1 mV  
0.032% + 2 mA  
0.012% + 1 mV  
0.032% + 4 mA  
0.012% + 1 mV  
0.032% + 4 mA  
Short Term Drift: (Within 30 minutes after a line and/or load change):  
Voltage  
+Current  
0.042% + 2 mV  
0.11%+4 mA  
0.042% + 2 mV  
0.11%+4 mA  
0.042% + 2 mV  
0.11%+8 mA  
0.042% + 2 mV  
0.11%+8 mA  
Programmable OVP Ranges:  
0-23 V  
0-55 V  
0-23 V  
0-55 V  
Load Cross Regulation:  
Voltage  
+Current  
1 mV  
1 mA  
2.5 mV  
0.5 mA  
1 mV  
2 mA  
2.5 mV  
1 mA  
Output Response Characteristics: (See Figure 1-3)  
Max Output  
2 ms  
6 ms  
2 ms  
6 ms  
Programming  
Response Time  
Settling Band  
Max Time Constant  
20 mV  
250 mS  
50 mV  
750 mS  
20 mV  
250 mS  
50 mV  
750 mS  
DC Floating Voltage:  
No output terminal may be more than 240 Vdc from any other terminal or from chassis ground. Also, no overvoltage terminal may be  
more than 240 Vdc from any other terminal or chassis ground.  
Remote Sense Capability: (See wire size selection, page 47 and remote voltage sensing, page 48)  
Outputs can maintain specifications with up to 1 volt drop per load lead except that the maximum voltage at the output terminals must  
not exceed the rated output voltage + 1 volt (see Figure 4-6). If the steady state voltage drop exceeds approximately 1.5 V on either  
load lead when remote sensing, a circuit will trip the OVP.  
18 General Information  
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Table 1-3. Supplemental Characteristics (continued)  
Outputs  
40 W Low  
Voltage  
40 W High  
Voltage  
80 W Low  
Voltage  
80 W High  
Voltage  
Programming Resolution:  
Voltage  
+Current  
OVP  
6 mV  
25 mA  
100 mV  
15 mV  
10 mA  
250 mV  
6 mV  
50 mA  
100 mV  
15 mV  
20 mA  
250 mV  
Readback Resolution:  
Voltage  
+ or-Current  
6 mV  
2 mA  
15 mV  
0.8 mA  
6 mV  
4 mA  
15 mV  
1.6 mA  
Fixed Overvoltage Protection: (Measure at output terminals +V and -V):  
Minimum  
Nominal  
Maximum  
22.5 V  
24 V  
26 V  
56 V  
60 V  
64 V  
22.5 V  
24 V  
26 V  
56 V  
60 V  
64 V  
AC Input Power and Current:  
Maximum Power = 550 W  
100 V Option  
120 V Option  
85 A  
220 V Option  
50 A  
240 V Option  
50 A  
High Line Inrush Current 85 A  
(pk)  
High Line Input Current  
(rms)  
6.3 A  
5.7 A  
3.0 A  
3.0 A  
Fuse Rating  
8 A  
8 A  
4 A  
4 A  
HP-IB Interface Capabilities:  
SH1, AH1, T6, L4, SR1, RL1, PP1, DC1, DT0, C0, E1  
Current Sink Capability:  
Current sink limits are fixed approximately 10% higher than the maximum current source limits for a given operating  
voltage at any voltage above 2.5 V (see Chapter 4).  
Command Processing Time: (see Figure 1-3):  
7 milliseconds typical (with front panel display disabled). Using STO and RCL commands allows you to change all the  
voltage and current settings in about 10 mS (with front panel display disabled).  
Series and Parallel Operation:  
Two outputs can be operated directly in parallel or can be connected for straight series operation. Refer to Chapter 4 for  
more information.  
Reactive Load Capability:  
All outputs have been designed with the ability to operate with significant reactive loads without instability (refer to  
Figures 1-4 through 1-6).  
General Information 19  
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Table 1-3. Supplemental Characteristics (continued)  
Output Impedance:  
Approximated by a resistance in parallel with an inductance (see graphs in Figure 1-7). The values for each output are:  
40 W Low Voltage  
0.15W, 2.0mH  
40 W High Voltage 80 W Low Voltage  
0.3 W, 5 mH 0.15 W, 0.8 mH  
80 W High Voltage  
0.5 W, 3 mH  
Safety Agency Compliance:  
This series of power supplies is designed to comply with the following standards: IEC 348, UL 1244, and  
CSA 22.2 No. 231.  
Dimensions: (all models)  
Height = 132.6 mm (5.22in.)  
Width = 425.5 mm (16.75in.)  
Depth = 497.8 mm (19.6in.)  
Weight: (all models):  
Net Weight = 17.4 kg (38 lb.)  
Shipping Weight = 22.7 kg (50 lb.)  
20 General Information  
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Figure 1-4. CV Operation with Capacitive Load, Stability Graph for all Outputs  
General Information 21  
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Figure 1-5. CC Operation with Inductive Load, Small Signal Stability Graph for HV (0 to 50 V) Outputs  
22 General Information  
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Figure 1-6. CC Operation with Inductive Load, Small Signal Stability Graph for LV (0 to 20 V) Outputs  
General Information 23  
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Figure 1-7. Output Impedance (Typical) Graphs (See Supplemental Characteristics, Table 1-1)  
24 General Information  
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2
Installation  
Introduction  
This chapter contains instructions for checking and mounting your power supply, connecting your supply to ac power,  
converting it from one line voltage to another, and connecting the HP-IB cable.  
The power supply generates operating magnetic fields which may affect the operation of other instruments. If your  
instrument is susceptible to magnetic fields, do not locate it in the immediate vicinity of the power supply. Typically, at  
three inches from the power supply, the electromagnetic field is less than 5 gauss.  
NOTE  
The HP 662xA power supplies generate operating magnetic fields which may affect the operation of  
other instruments. If your instrument is susceptible to operating magnetic fields, position it more than 3  
inches from the HP 662xA supply.  
Initial Inspection  
Your instrument was thoroughly inspected and tested before it left the factory. As soon as you receive it, remove the power  
supply from its packing case and check to make sure it has not been damaged in shipment. Check that there are no broken  
connectors or keys, and that the cabinet and panel surfaces are free from dents and scratches. Check the rear panel  
terminal blocks and front panel display for any cracks. If damage is found, you should file a claim with the carrier  
immediately and notify the Hewlett-Packard Sales and Service office nearest you.  
Chapter 3 of this manual includes an electrical turn-on check-out procedure which, when carried out successfully, will  
give you a high level of confidence that the power supply is operating in accordance with its specifications. Detailed  
electrical checks complete with verification procedures are included in the Service Manual.  
Keep the original packing materials for the carrier' s inspection if there was damage, or in case any equipment has to be  
returned to Hewlett-Packard. Warranty information is printed on the inside cover of this manual. Remember to send a  
detailed description of the failure and symptoms when returning the power supply for service. Your Hewlett-Packard Sales  
and Service office will furnish the address of the nearest service office to which the instrument can be shipped .  
Location and Cooling  
Your power supply can operate without loss of performance within the temperature range of 0 to 55 ° C (measured at the  
fan intake). The fan, located at the rear of the unit, cools the supply by drawing air in through the openings on the rear  
panel and exhausting it through openings on the sides. Using Hewlett-Packard rack mount kits will not impede the flow of  
air.  
Because the power supply is fan cooled, it must be installed in a location that allows sufficient space at the rear and the  
sides for adequate circulation of air. Either side may be restricted to have as little as 1 inch (25 mm) space.  
Figure 2-1 gives the dimensions of the power supply cabinet. These dimensions apply to all five models. The cabinet has  
plastic feet that are shaped to ensure self-alignment when stacked with other Hewlett-Packard System II cabinets. The feet  
may be removed for rack mounting.  
The power supply can be mounted in a standard 19 inch rack panel or enclosure. Rack mounting accessories for this unit  
are listed on page 12, under Options of Chapter 1. Complete installation instructions are included with each rack  
mounting kit. Instrument support rails are required for non-stationary installations. These are normally supplied with the  
cabinet and are not included with the rack mounting kits.  
Installation 25  
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Figure 2-1. Outline Diagram  
Input Power Requirements  
You can operate this power supply from a nominal 100 V, 120 V, 220 V or 240 V single phase power source at 47 to 66  
Hz. The input voltage range, maximum input current, high line inrush current (PK), and the fuse required for each of the  
nominal inputs are listed in Table 2-1. You can check the line voltage setting of your supply by examining the door on the  
line module. This is located on the rear panel of your supply as shown in Figure 2-2.  
If necessary, you can convert the supply from one line voltage setting to another by following the instructions under Line  
Voltage Conversion (page 28).  
Table 2-1. Input Power  
Nominal Voltage  
Line Voltage  
Range  
Maximum Input  
Current (rms)  
6.3 A  
High Line Inrush Current  
Fuse  
(PK)  
85 A  
85 A  
50 A  
50 A  
100 V  
120 V  
220 V  
240 V  
8 A  
8 A  
4 A  
4 A  
Nominal  
-13%, +6%  
5.7 A  
3.0 A  
3.0 A  
Line Fuse  
The ac line fuse is located behind the door on the line module (see Figure 2-3). To access the fuse, remove the power cord  
and push against the tab on the line module in the direction of the ac input socket. The current rating of the fuse is based  
on the line voltage setting of your supply. Table 2-2 gives the HP part numbers for the fuses that should be used with  
specific line voltages.  
26 Installation  
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Figure 2-2. Rear Panel Detail (6624A Shown)  
Table 2-2 Line Fuses  
Line Voltage Fuse Needed  
HP Part Number(for 1/4 X 1-1/4 in.  
fuses only  
2110-0342  
2110-0055  
100/120 V  
220/240 V  
8A  
4A  
Note All fuses are rated for 250 V.  
Figure 2-3. Line Module Detail  
Installation 27  
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Power Cord  
The power supply is shipped from the factory with a power cord that has a plug appropriate for your location. Figure 2-4  
shows the standard configuration of plugs used by Hewlett-Packard. Below each drawing is the HP part number for the  
replacement power cord equipped with a plug of that configuration. If a different power cord is required, contact the  
nearest Hewlett-Packard Sales and Service office.  
For your protection, the National Electrical Manufacturer's Association (NEMA) recommends that the instrument panel  
and cabinet be grounded. This power supply is equipped with a three-conductor power cord; the third conductor being the  
ground. The power supply is grounded only when the power cord is plugged into an appropriate receptacle. Do not operate  
this power supply without adequate cabinet ground connection.  
Figure 2-4. Power Cord Plug Configurations  
SHOCK HAZARD Connect the power cord to a grounded receptacle before you connect any  
external floating voltages to the supply.  
The offset pin on the standard three-prong power cord connector is the ground connection. If a two contact receptacle is  
encountered, it must be replaced with a properly grounded three-contact receptacle in accordance with the National  
Electrical Code, local codes and ordinances. The work should be done by a qualified electrician.  
Line Voltage Conversion  
You can change the supply to accept 100 V, 120 V, 220 V and 240 V ac input by adjusting the voltage selector card  
located inside of the line module (see Figure 2-3). After you have changed the line voltage, refer to Table 2-2 and check  
that the fuse inside the line module is the correct fuse for that line voltage. The procedure is as follows:  
l. Turn off power and remove the power cord from the ac input socket on the back of the power supply.  
2. To open the line module, move the plastic door on the module aside. If your line voltage change requires a change in  
the rating of the fuse, rotate FUSE PULL to the left and remove the fuse.  
3. Grasp the voltage select pc board with a pair of needle-nose pliers and slide it out of its slot.  
4. To select a voltage, orient the pc board so that the desired voltage appears on the top left side of the board. Push the  
board all the way back into its slot. The desired line voltage must be visible when the board is installed.  
5. Install the correct fuse in the door of the line module if your line voltage change also requires a change in the rating of  
the fuse (see Table 2-2).  
28 Installation  
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FIRE HAZARD Make sure the replacement fuse is one of the same type (size) and rating (amps)  
that is consistent with the voltage level you are operating at. Do not use a substitute fuse; use a fuse  
with the same HP Part number listed in Table 2-2.  
6. Close the door of the line module and insert the power cord in the ac input socket. Your power supply is now  
configured to operate at the voltage you selected.  
HP-IB Interface Connector  
The HP-IB connector on the rear panel connects your power supply to your computer and other HP-IB devices (see Figure  
2-2). Chapter 1, page 12 lists the cables and cable accessories that are available from Hewlett-Packard. An HP-IB system  
can be connected together in any configuration (star, linear, or both) as long as the following rules are observed:  
1. The total number of devices, including the computer, is no more than 15.  
2. The total length of all the cables used is no more than two meters times the number of devices connected together, up to  
a maximum of 20 meters.  
NOTE  
IEEE Std. 488-1978 states that you should exercise caution if your individual cable lengths exceed 4m.  
Do not stack more than three connector blocks together on any HP-IB connector. The resultant leverage can exert  
excessive force on the mounting panels. Make sure that all connectors are fully seated and that the lock screws are firmly  
finger tightened. Do not use a screwdriver. Use a screwdriver only for the removal of the screws.  
Installation 29  
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3
Getting Started  
Introduction  
This chapter is intended for the first time user of the supply. It provides four main discussions:  
·
·
·
·
Front Panel Controls and Indicators  
Turning on Your Supply  
Checking Out Your Supply Using Local Control  
Introduction to Remote Operation  
First, the supply's front panel controls and indicators are briefly described. Some of the controls and indicators will be  
used in the Turn On and Checkout procedures that follow. Chapter 6 describes how to use all of the front panel controls.  
Successful completion of the turn on and checkout procedures ensures with a high level of confidence that your supply is  
operating properly. Complete performance testing and troubleshooting procedures are given in the Service Manual (HP  
Part No. 5957-6379).  
The checkout procedures are performed locally from the front panel. In addition to checking the operation of your supply,  
these simple step-by-step checkout procedures will help the first time user become familiar with operating the supply from  
the front panel.  
When you have completed the checkout procedures, you are then introduced to the fundamentals of operating the supply  
remotely from a computer. You will learn how to send a command to the supply from the computer and how to get data  
back to the computer from the power supply. A few of the most often used power supply commands will be described to  
help you get started and become familiar with the basics of programming your supply.  
After completing this chapter, you can proceed to Chapter 4 to find out how to make load connections to your supply's  
outputs and then to Chapter 5 (Remote Control) and/or Chapter 6 (Local Control) to learn all the details about operating  
your supply.  
Front Panel Controls and Indicators  
The power supply's controls and indicators are shown in Figure 3-1 and are described in Table 3-1. Note that the front  
panel controls are identical for HP Models 6621A-6624A, and 6627A, except for the number of OUTPUT annunciators  
(number 3 in Figure 3-1). The HP Model 6624A, shown in Figure 3-1, has four outputs (as does the HP 6627A), HP  
Models 6621A and 6622A each have two outputs, and HP Model 6623A has three outputs.  
Table 3-1, in addition to providing a brief description of each control and indicator, lists the paragraphs in which the use  
of each control and indicator is described. Because most of the functions performed by the front panel controls can also be  
performed remotely by power supply commands, the corresponding paragraphs in Chapter 5 (Remote Operation) are listed  
in Table 3-1 where applicable.  
Turning On Your Supply  
The following paragraphs describe the power-on sequence which includes a self test of most of the power supply's circuits.  
Before you turn on your supply, make sure that:  
·
The line module on the rear panel is set to match your input line voltage.  
Getting Started 31  
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·
The proper fuse is installed and the line cord is plugged in.  
If you have any questions concerning installation or power requirements, review Chapter 2.  
To turn on your supply, press the front panel LINE switch. When the power is initially applied, the supply performs a  
series of self tests which last about 3 seconds. Included in these tests are checks of circuits on the HP-IB board and on  
each of the output boards.  
Figure 3-1. HP 6624A Front Panel  
Table 3-1. Controls and Indicators  
Number  
Controls/lndicators  
Description  
Page  
1
Returns power supply to local mode (unless local lockout  
has been received via HP-IB). Also, turns the power  
supply's display on if it was turned off via the HP-IB.  
39, 61,  
83  
LCL key  
2
39, 61,  
83  
HP-IB Status Annunciators RMT - Indicates that the power supply is operating under  
(These three annunciators  
indicate the HP-IB status of  
the power supply) .  
remote control (HP-IB).  
37, 61  
ADDR - Indicates that the power supply is addressed to  
talk or to listen.  
61, 61,  
68  
SRQ - Indicates that the power supply is requesting  
service.  
32 Getting Started  
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Table 3-1. Controls and Indicators (continued)  
Number  
Controls/lndicators  
Description  
Page  
Indicate which output channel has been selected for front  
panel control and/or display. (Only one output  
annunciator can be on at a time.)  
36, 37,  
83, 83  
3
OUTPUT  
Annunciators  
37, 43,  
83  
4
Power Supply Status  
Annunciators  
CV - Indicates that the selected output channel is in the  
constant voltage mode.  
(These five annunciators  
indicate the status of the  
power supply).  
37, 43,  
83  
CC - Indicates that the selected output channel is in the  
positive constant current mode ( + CC) or the negative  
current limit ( - CC) mode.  
43  
UNR - Indicates that the selected output channel is  
unregulated; i.e., it is not regulated by CV or CC control  
loops.  
37, 63,  
83  
OCP ENBLD - Indicates that the overcurrent protection  
function for the selected channel is enabled.  
43, 68,  
84  
ERR - Indicates that a programming or hardware error  
has occurred and that the ERR bit in the serial poll  
register has not been cleared.  
Normally displays the measured output voltage and  
current for the selected channel. When programmed from 43, 69,  
the front panel, the function being programmed (e.g.  
VSET), the output channel (e.g. 2), and the present value  
(e.g. 2.250) will be displayed. Error conditions will be  
spelled out in alpha characters.  
36, 37,  
5
6
Alphanumeric LCD  
Display (When power is  
turned on, all segments will  
be displayed for  
83, 83  
approximately 2 seconds).  
37, 61,  
83  
System Control Keys  
(These four control keys  
affect the entire power supply  
and are independent of the  
output selected).  
ADDR - Displays the power supply's HP-IB address. You  
can change the address using the numeric entry keys. You  
cannot query or change the address remotely (over the  
HP-IB).  
69, 84  
63, 84  
ERR- Displays a programming or hardware error  
message and clears the ERR bit in the serial poll register.  
STO - Used in conjunction with the numeric entry keys to  
store the present output voltage and current settings for all  
outputs in the specified internal register (1 to 10). Each  
register contains voltage and current settings for all  
output channels.  
63, 84  
RCL - Used in conjunction with the numeric entry keys to  
recall the settings from the specified internal register (1 to  
10). All outputs are set to the recalled values.  
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Table 3-1. Controls and Indicators (continued)  
Number  
Controls/lndicators  
Description  
Page  
7
36, 37,  
83, 83  
Output Control Keys  
(These twelve keys are  
output dependent).  
OUTPUT SELECT - Selects one of the output channels  
for local control or display. This key allows the channels  
to be selected in forward (ç) or reverse ( ) sequence.  
37, 62,  
63, 83  
VSET - Displays the selected output's present voltage  
setting. The setting can be changed using the numeric  
entry keys.  
37, 62,  
63, 83  
ISET - Displays the selected output's present current  
setting. The setting can be changed using the numeric  
entry keys.  
63, 83  
OUTPUT ON/OFF - Toggles the selected output on and  
off. When off, "DISABLED" appears on the display.  
37, 63,  
83  
OVSET - Displays the selected output's overvoltage trip  
point. The setting can be changed using the numeric entry  
keys.  
37, 63,  
83  
OVRST - Resets the selected output's overvoltage  
crowbar (the cause of the overvoltage must be removed  
before reset is successful).  
37, 63,  
83  
OCP - Toggles the selected output's overcurrent  
protection circuit on and off.  
37, 63,  
83  
OCRST - Resets the selected output's overcurrent  
condition and returns the output to its previous settings  
(the cause of the overcurrent must be removed before reset  
is successful).  
83  
METER - Returns the display to the metering mode from  
any other mode (e.g. VSET). In the metering mode, the  
measured output voltage and current of the selected output  
are displayed.  
69, 83  
63, 83  
DLY - Displays the reprogramming delay for the  
specified channel. The setting can be changed using the  
numeric entry keys.  
UNMASK - Displays the present setting of the mask  
register for the specified channel. The setting can be  
changed using the numeric entry keys.  
68, 68,  
83  
FAULT - Displays the contents of the fault register for  
the specified channel. A bit gets set in the fault register  
when the corresponding bit is set in both the status and  
mask registers. Pressing the FAULT key also clears the  
fault register.  
34 Getting Started  
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Table 3-1. Controls and Indicators (continued)  
Number  
Controls/lndicators  
Description  
Page  
8
37, 83,  
84  
Numeric Entry Keys  
(These keys are used in  
conjunction with many of the  
System Control and Output  
Control keys to enter the  
desired values into the power  
supply.  
0 to 9 - Set the value of the specified function  
and  
(e.g. VSET 16.550)  
83  
¬ (backspace) - Erases the previous keystroke. Depressing  
this key without setting a value places the display in the  
metering mode.  
37, 83,  
84  
ENTER- Enters the values on the display for the  
specified function, initiates the function, and returns the  
display to the metering mode. Pressing this key without  
setting a value will result in retention of the previous  
values and returning the display to the metering mode.  
9
Turns ac power on and off.  
37  
LINE Switch  
Normal Self Test Indications  
If the supply passes the self test, the display will first show all segments of the LCD display with annunciators on as  
illustrated in Figure 3-2.  
Figure 3-2. Test Pattern of all Display Segments at Power-on  
After all segments are displayed, the supply's HP-IB address will appear for approximately 2 seconds as shown in Figure  
3-3. As shipped from the factory, the power supply's address is set to 5. You must know this address before you can  
remotely program your supply (see Reading the HP-IB Address, page 39).  
Figure 3-3. Typical Address Display During Power-On  
When self test is successfully completed, the output voltage and current readings (both approximately 0) for output 1 will  
appear in the display as shown in Figure 3-4. Note that the CV annunciator will also indicate that the output is in the  
constant voltage mode.  
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Figure 3-4. Typical Display at Power-On  
Self-Test Errors  
If the supply fails the power-on self-test, all power supply outputs will remain disabled (off) and the display will indicate  
the type of failure and the output channel on which it occurred. Figure 3-5 shows that self-test detected an error in output  
channel 3. Error messages that could appear on the display if self-test fails are listed below. Self-test error messages are  
explained in Appendix D and troubleshooting procedures are given in the Service Manual for the HP 6621A-6624A, and  
6627A Power Supplies. You may also call your HP Sales office for help.  
Power-On Self Test Error Messages  
HDW ERR CH "N"  
8291 FAILED  
TIMER FAILED  
CV DAC CH "N"  
CC DAC CH "N"  
OV DAC CH "N"  
FUSE CH “N”  
NOTE  
"N" specifies the failed output channel number 1,2,3, or 4 as applicable.  
Figure 3-5. Sample Self-Test Failure Display  
Checking Out Your Supply Using Local Control  
The following procedures use the display and keys on the front panel to check each of your power supply's outputs. No test  
equipment, other than a jumper wire (14 AWG), is required to perform these tests. The tests must be repeated for each  
output of your particular supply. The checkout consists of voltage, overvoltage, and current tests. It is assumed that power  
has already been turned on, the supply has passed the power-on self-test, loads are not connected to any of the supply's  
outputs, and sense clips are connected between the sense terminals and the output terminals.  
NOTE  
The following procedures are identical for all models and for all outputs. Use the OUTPUT SELECT  
key to select an output to be tested. If an output fails any of the tests, refer to the troubleshooting section  
in the Service Manual.  
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Voltage Test  
1. Set the voltage of the selected output to 10 V by pressing:  
VSET  
1
0
ENTER  
2. Check that the display reads approximately 10 V and 0 A and the CV annunciator is on indicating that the supply is in  
the constant voltage mode of operation.  
Overvoltage Test  
1. Program the overvoltage protection (OVP) to 19 V by pressing:  
OV  
1
9
ENTER  
SET  
2. Set the voltage to 16 V by pressing:  
VSET  
1
6
ENTER  
3. Check that the display reads approximately 16 V and 0 A.  
4. Set the voltage to 20 V by pressing:  
VSET  
2
0
ENTER  
ENTER  
5. Check that the display reads "OVERVOLTAGE".  
6. Reset the supply by pressing:  
VSET  
1
6
OV  
RST  
7. Check that the display reads approximately 16 V and 0 A.  
Current Test  
1. Turn off the supply.  
2. Remove the barrier block cover from the output to be tested and connect a short circuit (jumper wire) between the +V  
and -V terminals of the output being tested.  
3. Turn on the supply.  
4. Use the the  
to select output being tested.  
5. Set the voltage to 5 volts by pressing:  
VSET  
5
ENTER  
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6. Check that the display reads approximately 0 volts and the minimum current limit value (0.05 to 0.13A depending  
upon the model and output, see Table 5-4). Also, check that the front panel CC annunciator is on indicating that the  
output is in the constant current mode of operation.  
7. Set the current to 0.5 A by pressing:  
ISET  
5
ENTER  
.
8. Check that the display reads approximately 0 V and 0.5 A.  
9. Enable the overcurrent protection circuit by pressing:  
OCP  
10. Check that the OCP ENBLD annunciator is on indicating that overcurrent protection is enabled and the display reads  
"OVERCURRENT". When in overcurrent, the output is disabled.  
11. Disable the overcurrent protection circuit by pressing:  
OCP  
12. Reset the output by pressing:  
OC  
RST  
13. Check that the display reads approximately 0 V and 0.5 A.  
14. Turn off the supply and remove the jumper from the output terminals.  
Repeat the tests given on pages 37 & 38 for the other output channel (s) using the  
key.  
Introduction To Remote Operation  
The following paragraphs explain the fundamentals of operating the supply remotely from a computer. Only a few  
commonly used programming commands will be discussed. Refer to Chapter 5 for a detailed description of all the  
commands. The intent of this discussion is to help first time users to quickly become familiar with operating their supply  
from a computer.  
The programming examples that follow assume that a computer is connected to the HP-IB connector on the rear of your  
supply (see Chapter 2), power is applied, and loads are not connected to any of the supply's outputs. The examples used  
are primarily for HP Series 200 computers using HP BASIC language. Read the manuals for your particular computer to  
find out which statements you must use.  
Enter/Output Statements  
The programming statements you use to operate your supply from remote depend on your computer and its language. In  
particular, you need to know the statements your computer uses to output and enter information. For example, the HP  
BASIC language statement that addresses the power supply to listen and sends the command to the power supply is:  
38 Getting Started  
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OUTPUT  
The HP BASIC language statement that addresses the power supply to talk and reads back data from the power supply is:  
ENTER  
The supply's front panel ADDR annunciator is on when the supply is addressed to talk or to listen.  
Reading the HP-IB Address  
Before you can operate your power supply remotely, you need to know its HP-IB address. The address was displayed  
during the power on sequence described in Normal Self Test Indications, page 35. To see the address, press:  
ADDR  
A typical address display is shown in Figure 3-6:  
Figure 3-6. Typical Address Display  
The displayed response is the power supply's HP-IB address. When sending a remote command, you append this address  
to the computer's HP-IB interface select code (normally 7). For example, if the select code is 7 and the power supply's HP-  
IB address is 5, the combination is 705.  
Changing the HP-IB Address  
NOTE  
All examples in this discussion assume an HP-IB address of 5. It is recommended that you retain this  
address to simplify programming.  
Every device on the HP-IB must have an address. The supply's address is factory set to decimal 5. Any address from 0  
through 30 is a valid address. If you need to change the HP 662xA Supply's address press:  
ADDR  
You can now enter a new address. For example, press:  
1
4
ENTER  
You have now changed the address from 5 to 14. If you want to change the address back to 5, repeat the above procedure  
but use 5 instead of 14 in the last step. Note that the address is stored in the power supply's non-volatile memory and  
therefore will be retained through interruption of the ac line power.  
Sending a Remote Command  
To send the power supply a remote command, combine your computer's output statement with the HP-IB interface select  
code, the HP-IB device address, and finally, the power supply command. For example, to set the output voltage of output  
channel 1 to 2 volts, send:  
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Getting Data From The Supply  
The supply is capable of measuring the values of its output parameters in response to queries. In this example, the query  
asks the supply to measure the output voltage at output 1.  
When you send a query from remote, the supply does not display the response as it did when you executed the command  
from the front panel. Instead, it holds the response in an output buffer. The output buffer is a register that holds  
information until it is read by the computer or is replaced with new information.  
NOTE  
On an HP Series 200 Computer, the A variable must be declared before you do the following steps. Refer  
to your computer's operating manual for more information.  
Use your computer's enter statement to get the response from the output buffer. For example, execute:  
ENTER 705; A  
Followed by:  
DISP A  
The ENTER statement enters whatever is in the supply's output buffer into the computer's A variable. The DISP statement  
displays the A variable ' s contents on the computer's display.  
Often Used Commands  
The command set contains over forty commands that allow you to program the power supply in a variety of applications.  
Within this command set, however, is a small subset of commands that are all you need for most applications. These  
commands are: VSET, ISET, VOUT?, IOUT?, OUT, OVSET, and OCP.  
Each of these commands is briefly discussed in the following paragraphs to help you get started in programming your  
supply. To know more about these commands, refer to Chapter 5.  
Voltage and Current Programming. You can send voltage and current values to the power supply directly in volts or  
amps The following examples use voltage and current values that are within the range of any output that the power supply  
provides.  
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To set the voltage of output 1 to 5 volts, send:  
OUTPUT 705; "VSET 1,5"  
To set the current of output 2 to 450 milliamps, send:  
OUTPUT 705; "ISET 2,.450"  
Output Voltage and Current Measurement. You can instruct the supply to measure the actual output voltage and  
current at a specified output using the VOUT? and IOUT? queries, respectively.  
To measure the output voltage at output 1, send:  
OUTPUT 705; "VOUT? 1''  
To get the measurement from the output buffer, send:  
ENTER 705; A  
DISP A  
The computer should display a reading of approximately 5 volts.  
To measure the output current at output 2 send:  
OUTPUT 705, "IOUT? 2"  
To get the measurement from the output buffer, send:  
ENTER 705; A  
DISP A  
Output On/Off. You can turn a specified output on or off. Individual outputs can be controlled as shown below.  
To turn off output 1, send:  
OUTPUT 705; OUT 1,0  
When an output is turned off, it is set to 0 volts and to the minimum current limit value.  
To turn on output 1, send:  
OUTPUT 705; "OUT 1,1"  
When an output is turned on, it will return to the voltage and current settings determined by the present VSET and ISET  
values.  
Overvoltage Setting. You can send an overvoltage setting value to the power supply directly in volts. If the output  
voltage exceeds this setting, the output crowbar is fired, and the output voltage is quickly downprogrammed and disabled  
(0. volts output).  
To set the overvoltage value of output 2 to 3.5 volts, send:  
OUTPUT 705; "OVSET 2,3.5"  
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Overcurrent Protection. The output will go to the off state (0 volts and min. current) when the overcurrent protection  
(OCP) feature is enabled and the output is in the + CC mode. To enable the overcurrent protection mode for output 2,  
send:  
OUTPUT 705; "OCP 2,1"  
To disable the overcurrent protection mode for output 2, send:  
OUTPUT 705; "OCP 2,0"  
When overcurrent protection is disabled and the output is in + CC mode, the output current will be limited to and will stay  
at the ISET value.  
Returning the Supply to Local Mode  
In the remote mode (RMT annunciator on), the front panel keys have no effect on any of the supply's outputs and only the  
computer can control the supply. However, you can still use the front panel display to monitor the output voltage and  
current or check any of the present settings (VSET, ISET, OVSET, etc.) of the selected output channel.  
If you want to use the front panel keys to change the output settings, you must return the supply to the local mode. You  
can return the supply to the local mode (provided that the local lockout command has not been received from the  
computer) by pressing the LCL key. A change between the local and remote modes (or vice versa) will not result in a  
change in the power supply outputs. Refer to Chapter 6 for additional details on using the LCL key and operating the  
supply in the local mode.  
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4
Output Connections and Operating Information  
Introduction  
This chapter explains how to make connections to the output terminals located on-the rear of your power supply. Some  
general operating information is included in this chapter to help you understand how the power supply operates under  
various load conditions. This information applies whether you are operating the supply via the front panel or the HP-IB.  
Output Ranges  
Figure 4-1 identifies the output combinations that are available on the power supply. Each output can operate as a  
constant voltage (CV) or constant current (CC) source over a wide variety of output voltage and current combinations. In  
addition, each output has an active downprogrammer which operates at currents up to approximately 110% of the  
maximum positive current rating of the output. This means that each output can actively sink as well as source its  
maximum rated output current. At voltages below 2.5 V, a downprogramming resistor continues downprogramming until  
the voltage reaches approximately zero volts.  
Figure 4-1. Output Connections  
Output Connections and Operating Information 43  
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Operating Quadrants  
Figure 4-2 shows the operating locus of your power supply in three quadrants. The area in quadrant 1 shows the operating  
locus defined by the voltage and current settings of each output. The characteristics shown for quadrant 1 incorporate  
remote sensing and include the maximum available sense voltage plus load lead drop. The area in quadrant 2 indicates the  
locus where each output can operate as a current sink. You cannot program current limit values in quadrant 2. (Figure 4-3  
shows the current sink characteristics at voltages below 2.0 V in greater detail.) The area in quadrant 4 illustrates the  
reverse polarity diode characteristics of each output. Do not operate any output with reverse-voltage currents that are  
greater than the maximum rating of the output.  
Notice that the L shaped characteristics in quadrant 1 of Figure l-l consists of two overlapping ranges-a high voltage/low  
current range, and a low voltage/high current range. The power supply always limits its settings to within the boundaries  
of these ranges. Attempting to program voltage or current values that are greater than the maximum programmable values  
for a given output results in an error message and the values are ignored by the supply.  
Range Selection  
When a voltage and current are specified, each of which is within the maximum programmable value but whose  
combination lies outside the L shaped operating locus, the power supply will automatically select the operating range  
based on the value of the last VSET or ISET parameter that was programmed. The other parameter will automatically be  
reprogrammed to the maximum rating of the selected range. Chapter 5 includes an example of automatic range selection  
(also referred to as range switching).  
Once your power supply output is operating in a given range, it will not automatically switch to the other range because of  
a change in the load. The only time an output switches operating ranges is in response to a command from either the front  
panel or the HP-IB that changes the voltage or current settings. For the output to switch ranges, the voltage or current  
setting must specify a value that is inside the operating locus of the other range. If the value sent is common to both  
ranges, no range switching occurs.  
Protection Features  
Protective circuitry within the supply can limit or turn off an output in the event of an abnormal condition. The activated  
protection feature can be determined by observing the front panel display area. You can also read back the status of the  
supply over the HP-IB. The following protection features are implemented:  
OVERVOLTAGE -- shorts the output by firing an SCR crowbar and sets zero volts and minimum current on an output if  
any of the following conditions are present:  
1. The output voltage exceeds the programmed overvoltage trip point.  
or  
2. The voltage from the +V output terminal to the + S terminal or from the -S terminal to the -V output terminal exceeds  
1.5 V (applies to remote sensing only).  
or  
3. A trip signal is received on the output's OV terminals.  
or  
4. The output's fixed overvoltage circuit is activated.  
The OV trip point can be programmed up to 23 V on a low voltage output and up to 55 V on a high voltage output. When  
an overvoltage occurs, the word OVERVOLTAGE appears in the front panel display and the OV status bit is set for that  
output. Chapter 5 explains how to program the overvoltage trip level.  
44 Output Connections and Operating Information  
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Figure 4-2. Typical Output Range Characteristics  
Output Connections and Operating Information 45  
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A fixed overvoltage threshold of approximately 120% of the maximum rated output voltage is built into each output.  
Because the fixed overvoltage circuit is biased from the output terminals, it can be activated and provide protection even  
when the supply is not connected to the ac power line.  
The OVRST command restores the programmed voltage and current values and clears the OV once the cause of the  
overvoltage has been eliminated.  
OVERCURRENT--when the overcurrent protection feature is enabled, and the output is sourcing current and enters the  
+ CC operating mode, the output will be disabled (set to zero volts and minimum current) and the word OVERCURRENT  
will appear on the front panel display. In addition the OC status bit is set for that output. The OCRST command restores  
the programmed voltage and current values and clears the OC once the cause of the overcurrent condition has been  
eliminated. Refer to Chapter V for programming details.  
UNREGULATED OUTPUT--the supply informs the user when output regulation is not guaranteed. This can occur  
when attempting to sink excessive currents below 2.5 volts or when operating outputs in parallel. The UNR annunciator  
on the front panel and the UNR bit in the status register indicate that the specified output is unregulated. Line voltage  
dropout or an incorrectly set ac power module can also cause the output to become unregulated. If line voltage dropout  
continues, the supply shuts down and will return to the power-up condition when normal line voltage is restored.  
OVERTEMPERATURE--shuts down the linear pass and downprogrammer of the output that has reached an unsafe  
operating temperature. Operation of the other outputs is unaffected. An overtemperature can occur because of excessively  
high ambient temperature, a blocked fan, or insufficient space at the sides for adequate air circulation. When an  
overtemperature condition occurs, the word OVERTEMP appears in the front panel display and the OT status bit is set.  
This circuit resets automatically and restores the output approximately 30 seconds after the temperature drops sufficiently  
for safe operation.  
ERROR--if the power supply receives an invalid command either through the front panel or the HP-IB, the ERR  
annunciator on the front panel comes on and the ERR bit in the serial poll register is set. The power supply does not  
execute the command and remains at previously set values. Pushing the ERR button in local mode displays the error  
message and clears the error. The error indicator may also indicate that an instrument failure has occurred. Refer to  
Appendix D for further details.  
CONNECTING THE LOAD  
Each terminal block cover on the rear panel is secured by a locking tab which snaps into a slot at the left of the terminal  
block. To remove, insert a screwdriver into this rectangular slot and move the locking tab to the left. When the locking tab  
releases, gently pull the terminal block cover away from the terminal block. To reinstall the cover, align it over the  
terminal block and gently press it into position until the locking tab engages.  
SHOCK HAZARD Turn off ac power before making rear panel connections. All wires and straps  
must be properly connected with terminal block screws securely tightened. Replace terminal block  
covers before reapplying power.  
Each rear terminal block has six M3.5 x 0.6 x 6 mm screws for attaching wires (see Figure 2-2). Load connections to the  
supply are made at the + V and -V terminals on each terminal block Do. not connect unterminated wires to the load  
terminals. Wires used for load connections must be properly terminated with termination connectors securely attached.  
Remember to replace the impact resistant plastic covers (HP P/N 06624-20007) over the terminal blocks after making  
connections.  
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Figure 4-3 Typical Downprogramming Characteristic Below 2.0 V  
Wire Size Selection  
FIRE HAZARD Select a wire size large enough to carry short-circuit current without overheating.  
Two factors must be considered when selecting wire size for load connections: conductor temperature  
and voltage drop. To satisfy safety requirements, load wires must be heavy enough not to overheat  
while carrying the short-circuit output current of the unit. Table 4-1 lists the current-carrying  
capacity (ampacity) for various sizes of stranded wire.  
Note that the minimum wire size required to prevent overheating may not be large enough to prevent OV trip and to  
maintain good regulation. Under most conditions, the load wires should be heavy enough to limit the voltage drop to no  
more than l.0 V total (see Figure 4-6). With remote sensing, load regulation is degraded ImV per 200 mV in the -V output  
load lead (see page 50). On the 40 W low voltage outputs, when the output voltage is set to 7 V, there is no voltage drop  
Output Connections and Operating Information 47  
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available in the load leads for prolonged operation into a 5 A load during ac low line at high ambient temperature  
conditions.  
There is a similar stipulation for 80 W low voltage outputs at l0 A under the same conditions as above. See Figure 4-2A  
for worst case voltages available at the output terminals.  
Table 4-1. Stranded Copper Wire Ampacity and Maximum Wire Lengths to Limit Load Lead Voltage  
Drop  
Ampacity Per Wire (Amps)  
2 Wire Bundled 4 Wire Bundled  
7.8 6.9  
Resistivity  
Max Length to Limit  
Voltage to 1 V Per Lead  
Wire Size  
(AWG)  
20  
5 A  
10 A  
(feet)  
10  
15  
25  
20 A  
(W/ft)  
0.0102  
0.0064  
0.0040  
0.0025  
0.0016  
20  
30  
50  
--  
5
7.5  
12.5  
20  
18  
16  
14  
12  
14.5  
18.2  
29.3  
37.6  
12.8  
16.1  
25.9  
33.2  
40  
--  
--  
30  
(Cross Section  
Area in mm2)  
(meters)  
(W/m)  
0.5  
0.75  
1
1.5  
2.5  
7.8  
9.4  
12.7  
15.0  
23.5  
6.9  
8.3  
11.2  
13.3  
20.8  
0.0401  
0.0267  
0.0200  
0.0137  
0.0082  
5
7.4  
10  
14.6  
--  
2.4  
3.8  
5
7.2  
12.2  
1.2  
1.8  
2.6  
3.6  
6
Notes:  
1. Ampacities for AWG wires are derived from MIL-W-5088B. Maximum ambient temp: 55°C. Maximum wire temp:  
105°C.  
2. Ampacities for metric wires are derived from IE Publication 335-1.  
3. Ampacity of aluminum wire is approximately 84% of that listed for copper wire.  
4. Because of wire inductance considerations, it is recommended that you keep your load leads twisted, tie wrapped, or  
bundled together and less than 50 feet (14.7 meters) in length per lead.  
5. See pages 47 & 48 for information on wire gauge considerations with capacitive loads.  
NOTE  
To prevent tripping of the overvoltage circuit, pick a wire size sufficient to handle the FULL output  
current of the unit no matter what the intended load current or current limit setting.  
Table 4-1 lists the resistivity for various wire sizes and the maximum lengths to limit the voltage drop to 1.0 volts for  
various currents.  
NOTE  
The OVP circuit senses at the main output terminals and not on the sense leads. Thus, the voltage  
sensed by the OVP circuit could be as much as 2 V higher than the voltage being regulated at the load.  
Program the OVP trip voltage accordingly when using remote sensing. In addition, if the voltage drop  
exceeds 1.5 V on either load lead, a protective circuit will fire the OVP circuit regardless of the OVP  
setting.  
Load lead resistance is an important factor relating to the CV stability of the supply with remote sensing of capacitive  
loads. If high capacitance loads are expected, you should not use wire gauges heavier than 12 to 14 AWG for long runs of  
load lead. See Figure 1-4 for more information about stability with output capacitors.  
48 Output Connections and Operating Information  
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Multiple Loads  
If you are using the as-shipped terminal block strapping pattern (local sensing) and are connecting multiple loads to one  
output, connect each load to the output terminals using separate connecting wires (see Figure 4-4). This minimizes mutual  
coupling effects and takes full advantage of the power supply's low output impedance. Each pair of wires should be as  
short as possible and twisted or bundled to reduce lead inductance and noise pickup.  
If load considerations require the use of distribution terminals that are located remotely from the supply, connect the  
power supply output terminals to the remote distribution terminals by a pair of twisted or bundled wires. Connect each  
load to the distribution terminals separately. Remote voltage sensing is recommended under these circumstances. Sense  
either at the remote distribution terminals or, if one load is more sensitive than the others, directly at the critical load.  
Figure 4-4. Optimum Hookup for Multiple Loads, Local Sensing  
NOTE  
When a load is connected through relay or switch contacts, contact bounce may activate the overvoltage  
circuit and shut down the supply. Therefore, it is recommended that the output be downprogrammed to 0  
or turned-off (disabled) before the relay (or switch) contact is opened or closed .  
Positive and Negative Voltages  
Either positive or negative voltages can be obtained from the supply by grounding (or "commoning") one of the output  
terminals. Always use two wires to connect the load to the supply regardless of where or how the system is grounded.  
This supply can be operated with any output terminal ± 240 Vdc (including output voltage) from ground.  
Remote Voltage Sensing  
Because of the unavoidable voltage drop developed in the load leads, the as-shipped terminal block strapping pattern  
shown in Figure 4-4 does not provide the best possible voltage regulation at the load. The remote sensing connections  
shown in Figure 4-5 improve the voltage regulation at the load by monitoring the voltage there instead of at the supply's  
output terminals. This allows the power supply to automatically compensate for the voltage drop in the load leads. Remote  
Output Connections and Operating Information 49  
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sensing is especially useful for CV operation with load impedances that vary or have significant lead resistance. It has no  
effect during CC operation. Because sensing is independent of other power supply functions, remote sensing can be used  
regardless of how the power supply is programmed. Note that with remote sensing, voltage readback monitors the load  
voltage at the sense points.  
Figure 4-5. Remote Voltage Sensing  
Figure 4-6. Allowable Load Lead Voltage Drop with Remote Sensing  
The maximum voltage available at the power supply output terminals during remote sensing (see Figure 4-6) is the  
maximum voltage (20.2 V or 50.5 V) rating, plus one volt (i.e. 21.2 V or 51.5 V as shown in Figure 4-2).This allows a  
voltage drop of 0.5 V per load lead, or one volt total. For lower output voltages refer to Figure 4-2.  
Remote Sense Connections  
Remember to turn off the power supply before making or changing any connections on the rear panel terminal blocks.  
Connect the unit for remote sensing by first disconnecting the straps between sense and load terminals. Then make your  
connections as shown in Figure 4-5. Connect the sense leads as close to the load as possible. See pages 47 & 48 for  
information on selection of load lead wire gauge. Best results will be obtained by using the shortest load leads practical. It  
is recommended that you keep your load leads under 14.7 meters (50 feet) per lead because of inductance effects.  
The sense leads carry only a few milliamperes of current and therefore, can be lighter gauge than the load leads. However,  
note that any voltage drop in the sense leads can degrade the voltage regulation of the supply. Try to keep the sense lead  
resistance less than about 0.5W per lead (this requires 20 AWG or heavier for a 50 foot length). You can use the following  
formulas to calculate the CV load regulation error when using remote sensing:  
50 Output Connections and Operating Information  
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OUTPUT TYPE  
(40 W & 80 W)  
FORMULA  
Vset Vdrop  
LV Output CV Reg Error(mV) =  
HV Output CV Reg Error(mV) =  
Rs (  
-
)
45  
1.1  
Vset Vdrop  
Rs (  
-
)
105  
3.3  
CV Regulation Error = Remotely sensed voltage will change by this number of millivolts.  
Rs = Resistance of each sense lead in W.  
Vset = Programmed voltage value in volts.  
Vdrop = Total drop in the load leads in volts.  
In addition, include ±1 mV error per 200 mV drop in the -V load lead independent of Rs value.  
Output Noise Considerations  
Any noise picked up on the sense leads will appear at the supply's output and may adversely affect CV load regulation.  
Twist the sense leads or use a ribbon cable to minimize the pickup of external noise. In extremely noisy environments it  
may be necessary to shield the sense leads. Ground the shield at the power supply end only; do not use the shield as one of  
the sensing conductors.  
The noise specifications in Table 1-1 apply at the power supply output terminals when using local sensing. However,  
voltage transients may be produced at the load by noise induced in the leads or by load current transients acting on the  
inductance and resistance of the load lead. If it is desirable to keep voltage transient levels to a minimum, place an  
aluminum or a tantalum capacitor, with an approximate value of 10 mF per foot (30.5cm) of load lead, right across the  
load (see Figure 4-5). Refer to Figure 1-4 for capacitive load stability considerations.  
Programming Response Time with an Output Capacitor  
Because voltage programming into an external output capacitor may cause the supply to briefly enter CC operating mode,  
voltage programming response time may be longer than that specified in Table 1-1. Use the following formula to estimate  
the additional response time:  
Additional  
Response  
Time  
(Added Output Capacitor)(Change in Vout)  
Current Limit Setting  
=
Open Sense Leads  
The sense leads are part of the supply's feedback path. Connect them in such a way so that they do not inadvertently  
become open circuited. The power supply includes protection resistors that reduce the effect of open sense leads during  
remote-sensing operation. If the sense leads open during operation, the supply returns to the local sensing mode, with the  
voltage at the output terminals approximately 2.5% higher (low voltage outputs) or approximately 3% higher (high  
voltage outputs) than the programmed value.  
Output Connections and Operating Information 51  
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Overvoltage Trigger Connections  
Each output of your power supply has two OV terminals on its rear panel terminal block. These terminals are labeled  
+OV and -OV. By connecting the OV terminals all in parallel as shown in Figure 4-7, an overvoltage shutdown on any  
one output will also trigger the overvoltage on the remaining outputs. Any number of OV terminals up to eight sets can be  
strapped together. Observe polarity when connecting the OV terminals in parallel.  
Figure 4-7. Overvoltage Connections  
The overvoltage trip point for each output can be set either from the front panel or by remote programming. You can also  
externally fire the overvoltage circuit of one or more outputs by applying a 5 volt pulse of at least 50 mS to any pair of OV  
terminals (see Figure 4-8). As long as all OV terminals are wired together, the outputs will be crowbarred simultaneously.  
External Trigger Circuit  
Figure 4-8 illustrates a recommended external circuit that can be used to provide an OV trip signal to the OV terminals.  
This circuit configuration provides good noise immunity and protects against the voltage pulse that is returned from the  
OV terminals every time that the overvoltage circuit fires. It can be operated from a wide range of bias voltages provided  
the input limiting resistors are chosen as tabulated in the figure. If it is not required to trip the OV with a TTL signal, then  
a bias supply, switch, current limiting resistor (R2), and protection diode are all that are required. Note that with the unit  
off (ac power removed), the + OV and - OV terminals are inactive.  
52 Output Connections and Operating Information  
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Figure 4-8. External Trigger Circuit  
The internal equivalent OV circuit is shown in Figure 4-9. Note the internal DC blocking capacitor, bleed resistor and  
noise bypass capacitors.  
Do not exceed 50 volts maximum between the + OV and the - OV terminals. The OV terminals are  
rated at ±240 Vdc (including external OV voltage) from chassis ground or any other output terminals.  
Figure 4-9. Equivalent Internal OV Trigger Circuit  
Output Connections and Operating Information 53  
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Power Supply Protection Considerations  
Battery Charging  
If you are using your supply in a battery charging application, it is recommended that a series protection diode be added to  
prevent damage to the supply during an overvoltage shutdown. Remember that each output has an overvoltage protection  
circuit that fires a crowbar to disable the output for any of the OVERVOLTAGE conditions described in Protection  
Features, page 44.  
Figure 4-10 illustrates the recommended connections and protection circuit for a battery charging application. The diode  
will prevent damage to your supply that can result from excessive battery current flowing into the supply's output in the  
event of an overvoltage shutdown.  
Figure 4-10. Recommended Protection Circuit for Battery Charging  
Capacitive Load Limitation  
The programmable overvoltage protection circuit can be used to downprogram capacitive loads although it is primarily  
intended for use as a protection feature (page 44).  
Repetitive (over 100 cycles) tripping of the overvoltage circuit with output capacitors greater than  
5000mF on high voltage units and 20,000mF on low voltage units may result in eventual damage to  
the  
supply.  
Parallel Operation  
Connect in parallel only outputs that have equivalent voltage and current ratings.  
Connecting outputs in parallel provides a greater current capability than can be obtained from a single output. Because  
each output contains an active downprogrammer that is capable of sinking current from only ONE identical output, you  
can parallel no more than two outputs. These outputs must have equivalent voltage and current capability. For example,  
you can connect the 40 W low voltage outputs together because they have the same voltage and current ratings, but you  
cannot connect a 40 W high voltage and a 40 W low voltage output together because they have different voltage and  
current ratings.  
As an example, Figure 4-11 shows how to connect two outputs in parallel to a single load with local sensing. This  
configuration applies to both CV and CC operating modes. Connecting the load leads of output 2 directly to the + V and  
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- V terminals of output 1 keeps the total length of the load leads to a minimum and reduces the number of wire  
connections that must be made at the load itself. Connecting the + S and - S terminals of output 2 directly to the sense  
terminals of output 1 compensates for the IR drop in the interconnecting load leads.  
CV Operation  
For CV operation, one output must operate in CC mode and the other output must operate in CV mode. Although each  
output operates independently of the other, the output that is operating in CV mode will be ''controlling" the voltage  
regulation of both outputs. Setting the output voltages as outlined in the following paragraph and configuring the outputs  
as shown in Figure 4-11 will allow output 1 to operate in CV mode and output 2 to operate in CC mode.  
Figure 4-11. Parallel Connections with Local Sensing  
To assure that output 2 will be operating in CC mode, you must program output 2's voltage to a higher value than the  
voltage of output 1. One way to accomplish this is to first program output 2 to the maximum allowable voltage setting for  
the desired operating range (see Table 4-2 or Figure 4-2). These values are 1% higher than the rated voltage for the  
operating range. Then, program output 1's voltage to the desired operating voltage. The lower voltage setting of output 1  
will determine the voltage that appears across the load. The current limit point of the paralleled outputs is the sum of both  
individual current limit points. The output current of the parallel combination is the algebraic sum of the individual  
current readbacks.  
The + OV and - OV terminals of output 1 should be wired to the + OV and - OV terminals of output 2. When  
programming the overvoltage setpoint, set both outputs to the same overvoltage value. When resetting the overvoltage,  
first disable both outputs by using the OUTPUT ON/OFF key or OUT command. Next, reset both overvoltages. Finally,  
re-enable the outputs with the OUTPUT ON/OFF key or OUT command.  
Table 4-2. Maximum Allowable Voltage Setting  
Output Type(40 W & 80 W)  
Low Voltage Output  
High Voltage Output  
Maximum Low Range Voltage  
Maximum High Range Voltage  
7.07 V  
20.2 V  
20.2 V  
50.5 V  
NOTE  
Below 2.5 V the downprogrammer cannot sink the maximum rated current. (See Figures 4-2 and 4-3).  
To operate parallel outputs at voltages under 2.5 V, program both outputs to the same voltage setting.  
Depending on the load, one output may operate in the unregulated mode.  
Output Connections and Operating Information 55  
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CC Operation  
For CC operation, set the output voltages as outlined in CV operation (page 55), or alternatively, program the voltage  
settings of both outputs to the same voltage limit point. Then program the current of each output so that the sum of both  
currents equals the total desired operating current. The simplest way to accomplish this is to program each output to one  
half of the total desired operating current. Both outputs will operate in the CC mode.  
Remote Sensing  
If it is necessary to remote voltage sense at the load, parallel the sense leads of output 1 with the sense leads of output 2  
and connect to the load as shown in Figure 4-12. The outputs can be programmed as previously described. Additional  
information on programming outputs connected in parallel is given in Appendix B.  
Figure 4-12. Parallel Connections with Remote Sensing  
Specifications for Parallel Operation  
Specifications for outputs operating in parallel can be obtained from the specifications for single outputs. Most  
specifications are expressed as a constant or as a percentage (or ppm) plus a constant. For parallel operation, the  
percentage portion remains unchanged while constant portions or any constants are changed as indicated below. For  
current readback accuracy and temperature coefficient of current readback, use the minus current specifications:  
Current  
Voltage  
All parallel specifications referring to current are twice the single output specification except for  
programming resolution which is the same for both single output and parallel output operation.  
All parallel specifications referring to voltage are the same as for a single output except for CV load  
effect, CV load cross regulation, CV source effect, and CV short term drift. Below 2.5 V, these are  
all twice the voltage programming accuracy (including the percentage portion). CV load effect  
above 2.5 V could be twice the load effect specification for a single output. CV output noise for  
output voltages less than 2.5 V may be slightly higher than the output noise for a single output.  
Load Transient  
Recovery Time  
350ms maximum to recover within 100 mV of nominal value following a load change within the  
range of 0 to full load.  
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Series Operation  
SHOCK HAZARD Floating voltages must not exceed 240 Vdc. No output terminal may be more  
than 240 Vdc from chassis ground.  
Connect in series only outputs that have equivalent current ratings. Each output has a reverse voltage  
protection diode across its output terminals. The current conducted by this diode is not internally  
limited by the output. Therefore, never connect an output in such a way that this diode will conduct  
current in excess of the rated current of the output since damage could result.  
Connecting outputs in series provides a greater voltage capability than can be obtained from a single output. Because the  
current is the same through each element in a series circuit, outputs connected in series must have equivalent current  
ratings. Otherwise, the higher rated output could potentially damage the lower rated output by forcing excessive current  
through it under certain load conditions.  
Figure 4-13 shows an example of how to connect two outputs in series to a single load with local sensing. This  
configuration applies to both CV and CC operating modes. Connecting the + load lead of output 2 directly to the - V  
terminal of output 1 completes the series connection between the two outputs. Connecting the + S terminal of output 2  
directly to the - S terminal of output 1 and removing the sense jumper (between + S and + V) on output 2 compensates for  
the IR drop in the load lead from output 2 to output 1.  
Figure 4-13. Series Connections with Local Sensing  
CV Operation  
For CV operation, first program the current setting of each output to the desired current limit point. Then program the  
voltage of each output so that the sum of both voltages equals the total desired operating voltage. The simplest way to  
accomplish this is to program each output to one half of the total desired operating voltage. Both outputs will operate in  
CV mode.  
Output Connections and Operating Information 57  
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CC Operation  
For CC operation, the current setting of each output must be programmed to the desired operating current. The sum of the  
voltage settings determines the voltage limit point. As an example, one way to program the voltage of the output is to set  
the voltage of each output to one half of the total voltage limit point. Then, at load voltages less than one half of the total  
voltage limit point, one output will operate in CC mode while the other output will be conducting through its internal  
reverse voltage protection diode. At load voltages greater than one half the total voltage limit point, the output that was in  
CC mode will change to CV mode while the output that was conducting through its diode will regulate the current in CC  
mode and provide the balance of the voltage required by the load. Note that the total load voltage can be found by adding  
the results of reading back the individual series outputs only when neither reverse voltage protection diode is conducting.  
When this diode is conducting, the corresponding output has reverse voltage across it so that its voltage readback may not  
be accurate.  
When an output is conducting through its reverse voltage protection diode, the output will have a reverse voltage across its  
output terminals with the - V terminal more positive than the + V terminal. This voltage will be I maximum at the rated  
current of the output. (See Figure 4-2 for reverse diode characteristic). Note that when an output conducts through this  
diode, it will indicate CC mode even though it is not regulating the current or voltage. Also, note that the voltage  
readback is not specified to indicate negative voltages although it will operate down to a limit of about - .22 V on the low  
voltage outputs and -.52 V on the high voltage outputs. These values will still be indicated even if the actual voltage is  
more negative.  
Figure 4-14. Series Connections with Remote Sensing  
Remote Sensing  
If it is necessary to remote voltage sense at the load, connect the sense leads of output 1 and output 2 as shown in Figure  
4-14. Note that the + sense lead of output 2 must remain connected to the-sense terminal of output 1. The outputs may be  
set as previously described. Additional information on programming outputs connected in series is given in Appendix B.  
Specifications for Series Operation  
Specifications for outputs operating in sense can be obtained from the specifications for single outputs. Most specifications  
are expressed as a constant or a percentage (or ppm) plus a constant. For series operation, the percentage portion remains  
unchanged while constant portions or any constants are changed as indicated below.  
Voltage  
All series specifications referring to voltage are twice the single output specification except for  
programming resolution which is the same as for a single output.  
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Current  
All series specifications referring to current are the same as for a single output except for CC load  
effect, CC load cross regulation, CC source effect, and CC short term drift which are twice the  
current programming accuracy (including the percentage portion).  
Load Transient  
Recovery Time  
Load transient recovery time is the same to within approximately twice the voltage setting band since  
the output impedances of the series combination add together.  
Output Connections and Operating Information 59  
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5
Remote Operation  
Introduction  
Chapter 3 introduced you to the basics of remote operation and provided a few simple examples using a Series 200  
computer as the HP-IB controller. This chapter contains all the information required to control your power supply  
remotely and discusses in greater detail how each of the commands can be implemented. The material covered is intended  
for any controller capable of using the HP-IB interface functions mentioned in Interface Function, on this page.  
Four major sub-sections are discussed. These are:  
1. HP-IB Operation  
2. Programming Syntax  
3. Initial Conditions  
4. Power Supply Commands  
The HP-IB section briefly describes the HP-IB interface functions to get you acquainted with remote programming using  
the HP-IB. Under Programming Syntax, the syntax of all commands, the numeric data formats and the programmable  
ranges for all models are given. Initial Conditions highlights the initial values of all the parameters at power-on. Power  
Supply Commands will describe all the commands which can be used to program the supply's functions including status  
reporting, error handling, protection features, and voltage and current programming. The power supply commands are  
summarized in Appendix C.  
The examples are written in a generic form to make adaptation to your controller easy. You should be familiar with the  
use of your controller and its instruction set and how the power supply commands can be incorporated in your controller  
commands. If you are not familiar with the operation of the power supply, you are advised to read through Chapters 2  
through 4 first.  
HP-IB Operation  
Interface Function  
Remote control is implemented by the HP-IB. It enables instructions to be sent from an external computer equipped with  
an HP-IB interface. The power supply implements the following IEEE-488 Interface Functions:  
SH1- Source Handshake  
SR1 - Service Request  
AH1 - Acceptor Handshake  
RL1 - Remote/Local  
T6 - Talker  
PP1 - Parallel Poll  
L4- Listener  
DC1 - Device Clear  
The source handshake, acceptor handshake, talker and listener functions are implemented by the interface circuits of the  
power supply and the controller. The ADDR annunciator indicates when the power supply is addressed to listen or talk.  
(The talker function includes the Serial Poll, see page 62).  
Service Request. This is a message which can be initiated by the power supply to request service from the controller.  
When the supply is requesting service, it asserts the service request (SRQ) line on the HP-IB to interrupt the controller  
Remote Operation 61  
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providing the controller is configured to service interrupts. A service request can be generated whenever there is a fault on  
one of the outputs (up to 4 outputs), a programming error has occurred, or at power on providing certain commands are  
sent. Service request commands are discussed in detail on page 76.  
The SRQ annunciator on the front panel display is turned on when the power supply is requesting service from the  
computer and remains on until the controller conducts a serial poll. A serial poll removes the service request and turns off  
the SRQ annunciator regardless of whether the condition that caused the service request continues to exist. The service  
request is also removed when you send the "CLR" command (see page 73).  
Remote/Local. The power supply can receive programming information either from the HP-IB (remote) or from the  
front panel (local). When the power supply is in remote, the state of the supply cannot be changed by using the front panel  
keys, although the LCL key will remain enabled. Remote operation takes precedence over local operation, hence if the  
supply is accepting commands remotely and you attempt to change it to local operation, the supply will not allow any local  
settings and will remain in remote. You can prevent the front panel from sending programming information by sending  
the local lockout command. This command is sent only from the HP-IB. If you change from local to remote or vice-versa,  
there will be no change in the programmed settings.  
Parallel Poll. Parallel Poll allows the controller to receive at the same time one bit of data from each of up to eight  
instruments connected to the bus. HP power supplies designate bit #6, the RQS bit of the serial poll register for this  
operation. By checking the status of this bit, the computer can quickly determine which instruments on the bus requested  
service. Once an instrument is identified, the computer can perform a serial poll to find out the exact cause of the request.  
Parallel Poll does not reset this service request bit (RQS) in the power supply.  
NOTE  
IEEE-488 does not define what data an instrument should put on a bus in response to parallel poll.  
Many instruments such as Hewlett-Packard power supplies indicate the state of their RQS bit, but the  
operator should not assume that all instruments on the bus respond to parallel poll with their RQS bit.  
Unless remotely configured, the power supply will respond with a 1 on one of the HP-IB data lines if it is requesting  
service and its address is between 0 and 7. Addresses 0 through 7 define which data line (1 through 8) the supply will  
respond on. If the address is set to 8 or greater, the supply will not respond unless remotely configured.  
The power supply may be remotely configured to respond with a 0 or 1, on any of the data lines, to indicate that it is  
requesting service. This is done in accordance with IEEE-488 1978.  
Serial Poll. In a serial poll, the controller polls each instrument on the bus one at time. The power supply responds by  
placing the contents of the eight-bit serial poll register on the HP-IB data lines. Page 75 discusses the Serial Poll Register  
and defines the function of each of the bits. After the serial poll, the service request is cleared and the SRQ annunciator at  
the front panel is reset (off). However, the condition that generated the service request may still be present. See page 76.  
Device Clear. The Device Clear command is typically used in systems to send all devices in the system to a known state  
with a single command. It may be implemented as an addressed or an unaddressed command. The power supply CLR  
command performs the same function as Device Clear (see page 73).  
HP-IB Address Selection  
You can find out the present address or change the address of the supply by using the front panel ADDR key as described  
in Chapter 3. Any address 0 through 30 is a valid address. If you program an address outside this range you will get a  
number range error.  
NOTE  
Care should be taken to not select the controller address.  
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Power-On Service Request (PON)  
The power supply can request service from the controller when the power is turned on. This request can be enabled or  
disabled by sending a PON command (see page 77). When the request is enabled, the supply can generate an SRQ at  
power-on or when there is a momentary loss in power. You can execute a serial poll to clear the service request. Table 5-7  
details the conditions under which a PON command will generate an SRQ.  
NOTE  
The power supply has a non-volatile memory in which it stores certain system variables. Some of these  
variables are the calibration constants, the present supply address, and the present setting of the PON  
command.  
Programming Syntax  
The following paragraphs describe the syntax of the device command that is used to program your power supply. As  
shown in Figure 5-1, the device command is a specific part of the program statement that your computer will accept. The  
first part of the statement is computer as well as programming language specific. Figure 5-1 shows the structure of a  
typical programming statement for an HP Series 200 computer. If you are using a different computer or programming  
language, refer to your computer programming manual to determine the correct syntax for this portion of the program  
statement. This section of the manual is only concerned with the device command portion (the part inside the quotes for  
Series 200 computers with BASIC) of the program statement.  
Figure 5-1. Typical Program Statement for Series 200 Computers  
Figure 5-2 shows the possible syntax forms for the device commands that are used to program the power supply. Syntax  
forms for the calibration commands that are discussed in Appendix A are also included. The oblong shape at the left of  
the syntax forms contains the command header which must be entered as shown in Tables 5-1 and 5-2. Commands are  
accepted in either uppercase or lowercase letters (ASCII characters). Circles contain characters that must be entered  
exactly as shown. Characters such as a space <SP> or a comma are used to separate elements in the command string.  
Characters such as a line feed < LF > or a semicolon are used to terminate the command string. Rectangles contain  
parameters that follow the command header lines and arrows indicate the correct paths through the syntax diagrams.  
Numeric Data  
The power supply will accept numeric data in implicit point, explicit point, or scientific notation. A general syntax  
diagram for numeric data is included in Figure 5-2. Implicit point notation means that numbers do not contain a decimal  
point; integers for example. Numbers written in explicit notation contain a decimal point, such as 12.35. In scientific  
notation, the letter E stands for "10 raised to". For example, 1.2E3 is read as 1.2 times 10 raised to the 3rd power, which  
equals 1,200. Plus and minus signs are considered numeric characters and are optional. If you program a number with an  
accuracy that is greater than the resolution of the supply, the number will automatically be rounded to the nearest multiple  
of the power supply's resolution. Table 5-1 gives the ranges for numeric data that is sent to the supply.  
Remote Operation 63  
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The power supply will also return numeric data (ASCII characters) to your computer. The format of the numbers returned  
depends upon the type of data requested. Table 5-2 gives the format for data returned to the computer in response to any of  
the queries that are listed.  
Figure 5-2 (Sheet 1 of 2). Syntax Forms for Power Supply Commands  
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Figure 5-2 (Sheet 2 of 2). Syntax Forms for Power Supply Commands  
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Table 5-1. Power Supply Commands  
Command  
Set Voltage  
Set Current  
Set Overvoltage  
OC Protection On/Off OCP  
Output On/Off  
Set the State of all  
Outputs at Power-On  
Unmask  
Reprogram Delay  
(in seconds)  
Header  
*Output Channel  
1,2,3,4  
Data Range  
Syntax (Fig. 5-2)  
VSET  
ISET  
See Table 5-4  
See Table 5-4  
See Table 5-4  
0,1(off,on)  
C4  
C4  
C4  
C4  
C4  
C4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
OVSET  
OUT  
0,1(off,on)  
DCPON  
----  
0,1(off,on) CC+  
2,3 (off,on) CC-  
0-255  
UNMASK  
DLY  
1,2,3,4  
1,2,3,4  
C4  
C4  
0-32 (LSB=0.004)  
Reset Overvoltage  
Reset Overcurrent  
Service Request  
Power-On SRQ  
On/Off  
OVRST  
OCRST  
SRQ  
1,2,3,4  
1,2,3,4  
--  
--  
--  
C3  
C3  
C2  
C2  
0,1,2,3  
0,1(off, on)  
PON  
--  
Display On/Off  
Display Characters  
(up to 12 characters)  
Store Settings  
Recall Settings  
Clear Supply  
DSP  
DSP  
--  
--  
0,1(off, on)  
"string"  
C2  
C6  
STO  
RCL  
CLR  
--  
--  
--  
1-10  
1-10  
--  
C2  
C2  
C1  
*Output channels 3 and 4 are not used in all models (see Table 5-4).  
Table 5-2. Power Supply Queries  
Query  
Header  
(Note 7)  
VSET ?  
ISET ?  
Channel  
(Note 1)  
1,2,3,4  
Response  
(Notes 5 and 6)  
SZD.DDD  
Initial Value  
Syntax  
(Fig. 5-2)  
Q2  
Voltage Setting  
Current Setting  
0
1,2,3,4  
SZD.DDD  
Min. Value  
Q2  
SZZD.DD(Note 2)  
SZD.DDD  
SZD.DDD SD.DDDD  
(Note 3)  
(see Table 5-4)  
Voltage Output  
Current Output  
VOUT ?  
IOUT ?  
1,2,3,4  
1,2,3,4  
--  
--  
Q2  
Q2  
OVP Setting  
OVSET ?  
1,2,3,4  
SZZD.DD  
Full Scale  
Q2  
(See Table 5-4)  
OC Protection On/Off  
Output On/Off  
Unmask Setting  
Delay Setting  
Status  
Accumulated Status  
Fault  
Error  
Service Request Setting  
Power-On SRQ On/Off  
Display On/Off  
Model Number  
Selftest  
OCP ?  
OUT ?  
UNMASK ?  
DLY ?  
1,2,3,4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
--  
ZZD  
ZZD  
ZZD  
0(0ff)  
1(0n)  
0(cleared)  
0.02 sec  
Q2  
Q2  
Q2  
Q2  
Q2  
Q2  
Q2  
Q1  
Q1  
Q1  
Q1  
Q1  
Q1  
Q1  
<sp>ZD.DDD  
STS ?  
ZZD  
ZZD  
ZZD  
ZZD  
ZZD  
ZZD  
--  
--  
--  
--  
ASTS ?  
FAULT ?  
ERR ?  
SRQ ?  
PON ?  
DSP ?  
ID ?  
TEST ?  
CMODE ?  
--  
--  
--  
--  
--  
--  
0(0ff)  
Last stored value  
ZZD  
HP 662XA (Note 4)  
ZZD  
1(0n)  
--  
--  
Calibration Mode  
ZZD  
0(0ff)  
S = Sign  
Z = Digit with leading zeros put out as spaces.  
D= Digit  
<sp > = space  
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NOTES:  
1. Output channels 3 and 4 are not used in all models. (See Table 5-4).  
2. Applies to 80 W Low V output.  
3. Applies to 40 W High V and 80 W High V outputs.  
4. ''X'' depends upon model.  
5. A space is returned for a + sign.  
6. All responses are followed by a < CR > and < LF > (EOI asserted with < LF > ).  
7. Spaces are allowed between the header and the question mark.  
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Order of Execution  
When you send a set of instructions to the power supply, they are executed in the order in which they are received. The  
power supply completes the execution of the present command before executing another command. To send more than  
one command within the power supply command string, use a semicolon to separate the commands. This maximizes the  
rate at which the power supply accepts commands.  
Terminators  
Terminators mark the end of a command string. As shown in Figure 5-2, the semicolon, line feed < LF >, and carriage  
return line feed < CR > < LF > are the characters that indicate the end of a message to the power supply. When you are  
using the HP Series 200 computer with BASIC to send a command using the standard format (see Figure 5-1), the  
computer automatically sends < CR > < LF > on the data bus following the command.  
Initial Conditions  
Immediately after power on, the power supply automatically undergoes a self-test and sets all parameters to their initial  
values. Table 5-3 lists the parameters and their initial values.  
Table 5-3. Initial Conditions  
Parameter  
Initial Value  
Voltage  
0
Current  
Minimum current limit  
Reprogramming Delay  
Store/Recall Registers  
Overvoltage (OV)  
20 mS  
0 volts and min. current limit  
23 V on low voltage outputs and 55 V on  
high voltage outputs  
Output Channels  
OCP Enabled  
UNMASK Register  
SRQ  
On  
Off  
0 (cleared)  
0 (Off)  
Front Panel Metering  
Power Supply Address  
Local Control  
PON Bit  
Output #1  
Last stored value (Factory set to 5)  
On (enabled)  
On  
PON SRQ  
Cal Mode  
Last stored value (Factory set to 0)  
Off  
Power Supply Commands  
This section discusses the commands which you will use to program the supply's voltage and current, protection circuits,  
and enhanced features like storage and recall registers, and reprogramming delay. When programming, you should be  
aware that the current, voltage and overvoltage ranges for each output of your supply may differ. Table 5-4 shows these  
values for the power supply. If you send values out of these ranges, you will get a number range error. A summary of all  
commands appears in Appendix C.  
The output voltage of some output channels exceeds the safe operating limit of 42.2 V. To avoid any  
electrical shock, program the voltage to zero volts or turn off ac input power before changing any  
rear panel connections. Make certain all straps are properly connected, terminal block screws are  
securely tightened and terminal block covers are replaced before reapplying power.  
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Voltage Programming  
To program voltage, send the output channel and the programmed value. In the example below, output 1 is programmed  
to 5 V.  
VSET 1,5  
The values you send must always be volts. For example if you want to program 450 millivolts, convert to volts and then  
send the command:  
VSET 1,.45  
If the output channel is operating in constant voltage mode (CV annunciator on) then the actual voltage is the  
programmed voltage, but in CC mode of operation (CC annunciator on), the programmed voltage is the voltage limit for  
that output.  
To readback the programmed voltage setting for output 1, send the query:  
VSET? 1  
and address the supply to talk. If you want to know the value of the actual output voltage of output 1, send the query:  
VOUT? 1  
The results are placed on the HP-IB and read into the controller when the supply is addressed to talk.  
NOTE  
The power supply will round the VSET and ISFT settings to the nearest multiple of their resolution.  
Table 5-4 lists the average resolution of these settings.  
Current Programming  
To program the current, send the output channel and the programmed value in amps. In the example below, output is  
programmed to 1.15 amps.  
ISET 1,1.15  
The value you send must always be in amps. For example if you want to program 95 milliamps, convert to amps and then  
send the command  
ISET 1,.095  
If the output channel is in constant current (CC) mode of operation, then the actual current is the programmed current but  
if the output is in the CV mode, the programmed current is the current limit of that output.  
To readback the programmed current for output 1, send the query and addressing the supply to talk.  
ISET? 1  
You can also instruct the supply to measure the actual output current at output channel 1 by sending the following query  
and address the supply to talk.  
IOUT? 1  
The results are placed on the HP-IB and read into the controller .  
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Table 5-4. Programmable Output Ranges for the HP 662lA-6624A and 6627A Supplies  
Model  
6621A  
6622A  
6623A  
Output  
Channel  
Operating  
Range *  
Output Voltage  
(Avg.  
Resolution)  
0 to 7.07 V  
0 to 20.2 V  
(0.006 V)  
Output  
Current-(Avg.  
Resolution) **  
0.13 to 10.30 A  
0.13 to 4.12 A  
(0.050 A)  
0.07 to 4.12 A  
0.07 to 2.06 A  
(0.020 A)  
Overvoltage  
Range(Avg.  
Resolution  
0 to 23 V  
1 & 2  
(80 W Low V)  
Low  
High  
(0.10 V)  
1 & 2  
(80 W High V)  
Low  
High  
0 to 20.2 V  
0 to 50.5 V  
(0.015 V)  
0 to 7.07 V  
0 to 20.2 V  
(0.006 V)  
0 to 55 V  
(0.25 V)  
1
Low  
High  
0.08 to 5.15 A  
0.08 to 2.06 A  
(0.025 A)  
0 to 23 V  
(0.10 V)  
(40 W Low V)  
2
Low  
High  
0 to 7.07 V  
0 to 20.2 V  
(0.006 V)  
0.13 to 10.30  
0.13 to 4.12 A  
(0.050 A)  
0 to 23 V  
(0.10 V)  
(80 W Low V)  
3
Low  
High  
0 to 20.2 V  
0 to 50.5 V  
(0.015 V)  
0.05 to 2.06 A  
0.05 to 0.824 A  
(0.010 A)  
0 to 55 V  
(0.25 V)  
(40 W High V)  
6624A  
6627A  
1 & 2  
(40 W Low V)  
Low  
High  
0 to 7.07 V  
0 to 20.2 V  
(0.006 V)  
0 to 20.2 V  
0 to 50.5 V  
(0.015 V)  
0 to 20.2 V  
0 to 50.5 V  
(0.015 V)  
0.08 to 5.15 A  
0.08 to 2.06 A  
(0.025 A)  
0.05 to 2.06 A  
0.05 to 0.824 A  
(0.010 A)  
0.05 to 2.06 A  
0.05 to 0.824 A  
(0.010 A)  
0 to 23 V  
(0.10 V)  
3 & 4  
(40 W High V)  
Low  
High  
0 to 55 V  
(0.25 V)  
1-4  
Low  
High  
0 to 55 V  
(0.25 V)  
(40 W High V)  
*The maximum programmable voltage values for each range are 1% higher than the rated voltage and the maximum  
programmable current values for each range are 3% higher than the rated current.  
**Each output channel "wakes up" with current programmed to a small positive value. This permits the output channel's  
output voltage to be programmed up without specifically programming the current. An output channel, in fact, cannot be  
programmed to zero amps. If the output channel receives a command to go to zero amps, or any positive current below the  
minimum programmable current, it will set itself to the minimum. Note that you can use the DCPON command to cause  
the ouput channels to wake up with the current programmed to a small negative value. This prevents currrent overshoots  
at turn on if the unit is operating in constant current mode.  
Range Switching  
Each output operates in the boundaries of either the low range or the high range as specified in Table 5-4. Refer to page  
43 for a detailed description of the dual range operation. The range is selected based on the programmed parameters. If  
the last parameter (voltage or current) programmed is outside of the existing range, the supply will automatically switch  
ranges. A sequence of examples are given on the next page to illustrate this operation. Output 1, used in the examples, is a  
40 W Low V output.  
Example 1: VSET 1,5; ISET 1,2  
This example programs output 1 to 5 V and 2 A. These values are in the quadrant of the characteristic curve which has  
voltage and current boundaries common to both high and low operating ranges.  
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Example 2: VSET 1,20  
Now output 1 is in the high range programmed to 20 V and 2A.  
Example 3: VSET 1,5; ISET 1,3  
Output 1 is now in the low range programmed to 5 V and 3A.  
Example 4: VSET 1,10  
Now output 1 is in the high range and the current is automatically scaled back from 3 A to the lower current limit of  
2.06 A. The output is operating in the same range as that of Example 2.  
Example 5: VSET 1,20; ISET 1,3  
The ISET command will cause the voltage to be scaled back to the low range limit of 7.07 V and the output will operate  
within the boundaries of the low range as in Example 3.  
NOTE  
When the range is automatically switched, as in examples 4 and 5, the "coupled parameter'' bit (CP) in  
the status register (see Table 5-5) is set to indicate that range switching occurred.  
Output On/Off  
The OUT command disables/enables an output channel of the power supply. It will not disturb any other programmed  
function nor will it reset the protection circuits. You can control individual outputs with the OUT command as shown  
below. For example, to disable output channel 1 send the following:  
OUT 1,0  
To enable output channel 1 send the following command  
OUT 1,1  
You can find out the present state of output 1 by sending the query:  
OUT? 1  
and addressing the supply to talk. The response from the supply is either a "0" to indicate output 1 is off or a "1'' to  
indicate that the output is on. When disabled, the output behaves as if it were programmed to zero volts and minimum  
current.  
Overvoltage (OV) Protection  
The programmable OV is a protection feature which can be set by the operator to protect the load against excessive  
voltage. When the actual voltage exceeds the programmed overvoltage setting for a given output channel, the OV is  
tripped. The OV circuit will fire the SCR crowbar which shorts across the output and the output assumes a low  
impedance state.  
For example, to program the OV of output channel 1 to 9.5 V send the following command:  
OVSET 1,9.5  
To find out the OV setting for output channel 1 send the following query and address the supply to talk:  
OVSET? 1  
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To enable an output after it went into overvoltage, you must first remove the overvoltage condition and then send the OV  
reset command.  
To reset output 1 send:  
OVRST 1  
If you send the reset command without first removing the OV condition, the supply will fire the OV again.  
NOTE  
If the programmable OV fails, the supply has a fixed OV circuit which will fire the SCR crowbar if the  
voltage exceeds 120% of the maximum rated output. The fixed OV circuit will also fire the SCR  
crowbar if the supply is off (line cord disconnected) and an external source is supplying voltage which  
exceeds 120% of the maximum rated output.  
Overcurrent Protection (OCP)  
The OCP is a protection feature employed by the power supply to guard against excessive output currents. When the  
output enters the + CC mode and the OCP is enabled, the OCP circuit down programs the output voltage and disables the  
output.  
To enable the OCP, for output channel 1, send the command  
OCP 1,1  
To disable the OCP, send the command  
OCP 1,0  
You can find out the OCP setting by sending the following query and addressing the power supply to talk.  
OCP? 1  
The response from the power supply is either a "0" to indicate that OCP is off or a ''1" to indicate that it is on. To reset the  
output channel after an overcurrent trip, you can either disable the OCP and send the reset command, or you can reduce  
the output current below the programmed current and then send the reset command. To reset output 1, send the command:  
OCRST 1  
NOTE  
The supply can report a fault condition when an output is in overvoltage or overcurrent. Although the  
OVRST and OCRST commands reenable the output, they do not clear the fault register. As a  
housekeeping measure, it is advisable to always clear the fault register by querying its value after an OV  
or OC reset.  
Multiple Output Storage & Recall  
The power supply has 10 internal registers each of which can store the voltage and current settings of all the outputs. By  
storing voltage and current settings for all outputs and recalling them later, you can have significant savings in  
programming time. (See Supplemental Characteristics in Table 1-1).  
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At power-on, each of the registers contain 0 volts and the minimum current limit. To store voltage and current settings,  
you must specify the register (1 to 10). For example to store the present settings of current and voltage of all your supply's  
outputs in register 2, send the following command:  
STO 2  
This command will take the programmed voltage and current settings of all output channels and store them in register 2.  
You can set the power supply outputs to these stored voltage and current settings by sending the recall command.  
RCL 2  
When a register is recalled, the outputs will be set sequentially (output 1, output 2, etc.). If you attempt to recall registers  
which were not previously stored, then the supply will return the power-on values for that register (0 volts and minimum  
current limit). If you recalled registers outside the 1 to 10 range, you will get a number range error.  
The Clear Command  
This command will return the power supply to its power-on state and all parameters are returned to their initial power-on  
values except for the following:  
1. The store/recall registers are not cleared.  
2. The power supply remains addressed to listen.  
3. The PON bit in the serial poll register is cleared.  
To Clear the power supply, send the following command:  
CLR  
Status Reporting  
The power supply has the ability to report its internal status to the user whenever it is asked to do so. Depending on the  
type of status the user requested, the supply will interrogate the status, accumulated status, mask, or fault registers present  
in each output. The status register can report status independently or it can work together with the mask and fault  
registers to report a fault. The accumulated status register records every status condition the output experienced since the  
time it was last read. Figure 5-3 shows a conceptual model of the operation of these registers.  
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Figure 5-3. Functional Relationship of Status Registers  
The supply has one serial poll register which services all outputs and provides the user with other power supply status-  
related information as discussed on page 75.  
Status Register. Each output channel of the power supply maintains its present status in an 8-bit register. This status  
register reports the status of the output channel whenever it is queried. A "1" in any of the bit positions indicates that the  
condition is true. As long as the condition continues to be true, the bit will remain set. Assignments for the bits are shown  
in Table 5-5.  
Decoding of the reading is based on the weighted number placed on each bit of the 8-bit status registers. For example, bit  
position 5 in the register has a bit weight of 32 (see Table 5-5). Each bit is assigned to a particular condition and the  
corresponding bit weight is used to identify that condition. When set, bit 5 indicates that the associated output is in the  
unregulated state. If this is the only bit that is set, the number 32 will be returned when the output's status register is  
queried.  
Table 5-5. Bit Alignment for the Status, A Status, Fault, and Mask Register  
Bit Position  
Bit Weight  
Meaning  
Where  
7
128  
CP  
6
64  
OC  
5
32  
UNR  
4
16  
OT  
3
8
OV  
2
4
-CC  
1
2
+CC  
0
1
CV  
CV = Constant Voltage Mode  
+ CC = Positive Constant Current Mode  
- CC = Negative Current Limit Mode  
OV = Overvoltage Protection circuit tripped  
OT = Over Temperature Protection circuit tripped  
UNR = Unregulated Mode  
OC = Over Current Protection tripped  
CP = Coupled parameter (See Note)  
Note: When the range is automatically switched as discussed on page70, the CP bit is set. It is cleared when you send a  
voltage or current value that causes no range change.  
To query an output channel for its status, you must specify the output channel. For example, to find out the status at output  
2 send the following query and address the supply to talk:  
STS? 2  
Accumulated Status Register. Each output channel of the power supply also maintains a cumulative status in its  
accumulated status (astatus) register. This register records every status condition the power supply output entered since it  
was last queried. When queried, it returns a decimal number which is decoded as shown below. The astatus register is  
reset to the present value of the status register after it is queried. The bits are assigned as in Table 5-5. Here is an example  
to help you decode the decimal number (from 0 to 255) returned when the astatus register is queried. If the output channel  
was in overvoltage since the last reading of the astatus register and that channel is presently operating in constant voltage  
mode, the reading you will get when you query the register will be 9. To decode this we use table 5-5.  
9 =  
8
+
1
OV  
+
CV  
For example, to query the astatus register of output 2, send the following query and address the supply to talk.  
ASTS? 2  
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The Mask and Fault Register. The fault register works in conjunction with the mask register. These are two eight bit  
registers which report any fault condition on a particular output channel. The mask register is used to set up the  
conditions that generate a fault which is latched into the fault register. The user can then read the fault register to  
determine the fault. When a bit in the fault register is set, the power supply can generate a service request for that output  
providing the service request command on fault (SRQ 1 or SRQ 3) was previously sent. See page 76 for a discussion on  
service request.  
To understand how these two registers work, we must include the status register in this discussion. Recall that the status  
register takes its input from the power supply and the user cannot change its contents. The mask register takes its inputs  
from the user, and the power supply cannot change its contents. The fault register takes its inputs from both the mask and  
the status registers. You can find out the setting of the mask register of output 2 by sending the following query and  
addressing the supply to talk:  
UNMASK? 2  
The response will be a numeric code between 0 and 255 which can be decoded by consulting Table 5-5. You can set the  
conditions to generate a fault by setting (unmasking) one or more bits in the mask register. The conditions will remain  
unmasked until you change them. To unmask conditions in output 2 for example, send the following command:  
UNMASK 2,XXX  
where XXX specifies the numeric code (0 to 255) for the unmasked conditions (see Table 5-5). If during operation, the  
output experiences any of the previously unmasked conditions, it will set the corresponding bit(s) in its fault register.  
Remember that the bits in the fault register can be set when there is a change in either the status register or the mask  
register. Each output has its status, mask, and fault registers arranged as shown in Figure 5-3 and Table 5-5. The mask  
register, which is set by the user, is used to specify which bits in the status register are enabled (unmasked) to set bits in  
the fault register. A bit is set in the fault register when the corresponding bit in the status register changes from "0'' to "1"  
and the corresponding bit in the mask register is a "1". Also, if a bit in the status register is already set and then the  
corresponding bit in the mask register is set (unmasked), the corresponding bit in the fault register will be set.  
In addition, if both status and mask register bits remain set after the fault register was read (and cleared), the fault register  
will remain cleared as long as there are no changes in either the status or mask registers with the following exception.  
Executing a VSET, ISET, RCL, OVRST, OCRST, or OUT on/off command, will cause the CV, + CC, - CC, or UNR bit  
(as applicable) in the fault register to be set. Note that the fault register is cleared immediately after it is read.  
As shown in Figure 5-3, if one or more bits in the fault register of a given output channel are set, then the FAU bit for that  
output in the serial poll register will also be set and a service request may be generated (see page 76). To read the fault  
register of output 2 and find out which bits are set, send the following query and address the supply to talk:  
FAULT? 2  
The power supply responds with a number which can be decoded from Table 5-5. For example, the number 9 (8 + 1)  
indicates that the OV and the CV bits in the fault register are set.  
NOTE  
If the condition(s) generating the fault(s) is (are) removed but the fault register is not read, the bit(s) in  
the fault register will remain set.  
The Serial Poll Register. The serial poll register is an 8 bit register which the supply uses to keep track of its internal  
operating status and to determine the operating status of each of its outputs. Table 5-6 defines each bit.  
Table 5-6. Bit Assignment of the Serial Poll Register  
Bit Position  
Bit Weight  
Meaning  
7
128  
PON  
6
64  
RQS  
5
32  
ERR  
4
16  
RDY  
3
8
2
4
1
2
0
1
FAU 4  
FAU 3  
FAU 2  
FAU 1  
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The first four bits (0 to 3) in the register tell whether or not a particular output has a fault. If there is a fault in one of the  
outputs, then the corresponding FAU bit will be set. Thus if output 1 has a fault, then FAU 1 will be set. In models with  
only three outputs, FAU 4 will always be zero and in two output models, FAU 3 and FAU 4 will always be zero.  
The RDY bit is set when processing is complete and is cleared when the supply is processing commands.  
The ERR bit is set when a programming or hardware error occurs and is cleared when the error query (ERR?) is received.  
The error annunciator on the front panel informs the user when this bit is set or cleared.  
The RQS bit is set when the power supply generates a service request and cleared after a serial poll is done (see the  
following paragraph, Service Request Generation).  
The PON bit is set at power on and cleared when a CLR command is sent.  
Service Request Generation  
When operating your supply, you may want it to request service every time a fault or a programming error condition  
occurs. To do this you send a service request (SRQ) command. When the condition is true, the power supply responds by  
setting the RQS bit in the serial poll register, setting the SRQ annunciator on the front panel, and issuing an SRQ over the  
HP-IB.  
The 662xA supplies can generate a service request for any of the following reasons: (refer to Table 5-7).  
·
·
·
·
An Output Fault. If there is a fault on one or more of the output channels and you previously sent the SRQ 1 or  
SRQ 3 command (see Service Request Enable/Disable information below), then an SRQ will be generated.  
An Error. If there is an error (see Tables 5-8) and you previously sent the SRQ 2 or SRQ 3 command, (see Service  
Request Enable/Disable information below), then the supply will generate a service request.  
Power-on. At power-on, the PON bit of the serial poll register is set but the supply will only generate an SRQ if you  
previously sent a PON 1 command.  
Input Line Voltage Dropout. Same as power-on condition.  
To find out the nature of the service request, you must do a serial poll. This will isolate the output that generated the  
request by checking which of the FAU bits are set in the case of a fault, or checking to see if the error bit is set in the case  
of an error. If the SRQ on faults was set, then send the fault query.  
FAULT? 2 (using output 2 as an example)  
and address the supply to talk if you want to find out which of the conditions you unmasked in Figure 5-3 are true. For  
example if the supply was in overvoltage and that condition was unmasked then the response from the fault query will be  
''8" (see Table 5-5).  
NOTE  
When you query the fault, the fault register is cleared. Performing a serial poll will reset the PQS bit but  
will not clear the fault register.  
If the SRQ on error was set, then you can send the error query ERR? and address the supply to talk. The response will  
identify the error by its code (see Table 5-8).  
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Service Request Enable/Disable. You can query the status of the service request enable/disable function by sending  
the query:  
SRQ?  
and addressing the power supply to talk. The response from the supply is one of the following:  
0, 1, 2, or 3  
0--indicates that the service request capability (except for power-on; see The Power On-Service Request  
information below) is disabled.  
1--indicates that it is enabled for output fault conditions.  
2--indicates that it is enabled for error conditions.  
3--indicates that it is enabled for both fault and error conditions  
The ability to generate service requests can be enabled or disabled using the SRQ command as described below.  
To disable the service request capability, except for power-on, send:  
SRQ 0  
To enable the service request capability for all output faults,  
SRQ 1  
To enable the service request capability for errors, send:  
SRQ 2  
To enable the service request capability for both faults and errors, send:  
SRQ 3  
The Power-On Service Request. You can also cause the power supply to request service every time it is switched on  
or every time there is a temporary loss in power. To do this send the following command:  
PON 1  
If you want to disable this facility, send the command.  
PON 0  
If you want to find out if the power-on SRQ is enabled or disabled, send the following query:  
PON ?  
and address the supply to talk. The supply will respond with a 1 or 0 as discussed above.  
NOTE  
The power-on (PON) SRQ mode is stored in the non-volatile memory of the supply so that although the  
supply may be switched off, it will remember the status of the last PON command at power-on and  
respond accordingly.  
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Table 5-7 summarizes all the conditions under which a service request will be generated.  
Table 5-7 Condition for Generating a Service Request  
Condition  
Commands Sent  
State of  
RQS Bit  
PON  
SRQ  
0
1
-
0
0
1
1
1
·
Any  
-
·
Power-on  
Error  
2 or 3  
1 or 3  
·
-
·
Fault  
Reprogramming Delay  
The power supply may switch modes or become unregulated momentarily after a new output value is programmed.  
Because of their short duration, these cases may not ordinarily be considered a fault but the supply will recognize this  
deviation and generate a fault signal. To prevent this, the reprogramming delay feature is implemented.  
Reprogramming delay will delay the onset of certain fault conditions and prevent the power supply from registering a  
fault when these conditions are true. When the delay is in effect, the CV, + CC, - CC and UNR bits of the status register  
are masked and cannot communicate with the mask and fault registers and the OCP function. This will prevent the supply  
from registering a fault should any of these bits become set during the delay period. Reprogramming delay is initiated  
when any of the following functions are executed:  
VSET: ISET: RCL: OVRST: OCRST; OUT on/off  
At power-on reprogramming delay is set to 20 mS. You can specify new values between 0 and 32 S in steps of 4 mS. If  
you specify a value which is not a multiple of 4 mS, the supply will round off the set value to the nearest 4 mS multiple.  
To program a new value of 80 mS in output 2 for example, send the following:  
DLY 2,.08  
If you send a value outside the 0 to 32 S range you will get a programming error. You may use the programming response  
times in the specifications table to give you an idea of a typical delay setting. However, the appropriate delay setting will  
also depend on load capacitance, load resistance, and current limit setting. See page 51 for output capacitor  
considerations.  
To query the reprogramming delay setting of a particular output channel, send the following query:  
DLY? 2 (using output 2 as an example)  
and address the supply to talk. The response will be a numeric value between 0 and 32.  
Display On/Off  
When the display is on, the commands sent across the HP-IB may experience a slower processing time because the  
processor must also spend time to monitor the outputs and update the display. You can shorten your command processing  
time by turning off the display. To turn off the display, send the command:  
DSP 0  
To re-enable the display send the command:  
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DSP 1  
You can also find out the status of the display by sending the following query and addressing the supply to talk:  
DSP?  
The response will be either a "1'' or a "0''.  
Message Display Capability. The display command can also be used to display messages on the front panel. Messages  
may consist of a maximum of twelve alphanumeric characters. Only upper case alpha characters, numbers, and spaces  
will be displayed.  
For example, to display the message "OUTPUT 2 OK” send the following command:  
DSP "OUTPUT 2 OK"  
NOTE  
The BASIC programming statement for a series 200/300 computer would be as follows:  
OUTPUT 705; ''DSP'"'OUTPUT 2 OK""  
Other Queries  
In the examples discussed above, you saw how to use queries for each function discussed. The following paragraphs  
describe other queries which were not previously covered.  
ERROR Query. The power supply can detect both programming and hardware errors. You can use either the front panel  
(see page 87) or the HP-IB to find out the type of error. Upon detecting an error, the error annunciator on the front panel  
and the ERR bit in the serial poll register will be set. When in local mode the supply will display the error name in  
response to pressing the ERR key on the front panel. Over the HP-IB, only the error code will be returned. After a query,  
the error bit is cleared. A description of these codes is given in Table 5-8. To find out what the error is, send the following  
query and address the supply to talk:  
ERR?  
The supply will respond with an error code number (see Table 5-8).  
ID Query. If you want to know the model number of the power supply you are working with, you can send the ID? query  
over the HP-IB. To do this send the following over the HP-IB and address the supply to talk.  
ID?  
The supply will respond with its model number.  
Test Query. You can get the power supply to perform a limited self-test at any time during its operation by sending the  
TEST? query over the HP-IB. This test does not affect the analog control circuits of the supply and it can be performed  
while the outputs are connected to external circuits. For tests of the analog control circuits refer to Chapter 3. Responses to  
the test query are described in Table 5-9. This test cannot be done from the front panel. To instruct the power supply to  
carry out a self-test, send the following query and address the supply to talk:  
TEST?  
Calibration Mode Query. To be able to calibrate your power supply, the calibration mode (CMODE) must be turned on  
(See Appendix A for a detailed description of the calibration procedure). To find out if the CMODE is on or off, send the  
following query over the HP-IB and address the supply to talk:  
CMODE?  
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The supply will respond with a ''1" which indicates that CMODE is on or a "0" which indicates that CMODE is off.  
DCPON. The DCPON command sets the state of all outputs at power-on. You can specify if the outputs wake up enabled  
or disabled when the unit is turned on. To enable all outputs at turn-on send:  
DCPON 1  
To disable all outputs at turn-on send:  
DCPON 0  
Note that these commands set the output voltage to zero and the output current to a slightly positive value when the  
OUTPUT OFF command is issued. Therefore, the constant voltage feedback loop is active and the outputs are in constant  
voltage mode when programmed “OFF”.  
Starting with firmware revision A.00.04 and later, two additional commands let you set the output current to a slightly  
negative value when the OUPUT OFF command is issued, causing the outputs to be in constant current mode when  
programmed “OFF”. The benefit of being in constant current mode when the output is off is that if the load impedance  
and the voltage and current settings are such that the unit is forced into constant current mode at turn on, then the current  
feedback loop will be active during the transition to OUTPUT ON, and there will be no output current overshoot due to  
mode crossover.  
To enable all outputs in constant current mode at turn on send:  
DCPON 2  
To disable all outputs in constant current mode at turn-on send:  
DCPON 3  
Table 5-8. Error Messages  
Explanation  
Front Panel  
Response  
HP-IB  
Code  
.
NO ERROR  
0
This is the response to the ERR? query when there are no errors.  
You sent the supply a character it did not recognize.  
INVALID CHAR  
INVALID NUM  
INVALID STR  
SYNTAX ERROR  
1
2
3 or 28  
4
Format of your number is incorrect. Check number syntax.  
Occurs when you send a command the supply does not understand.  
Either too many parameters are sent without delimiters or the number  
representation is incorrect. Follow the Syntax Diagram in Figure 5-2. Check  
spaces and delimiters.  
NUMBER RANGE  
NO QUERY  
5
6
An out of range number was sent. Send a new number within the legal range.  
Computer addressed the supply to talk, but it did not first request data. Send  
query first then address supply to talk.  
DISP LENGTH  
BUFFER FULL  
EEPROM ERROR  
7
8
9
Quoted string exceeds the display length of 12 characters. Shorten string to a  
maximum of 12 characters.  
This error may occur if too many numbers are sent. Error #4 or #5 may occur  
first.  
EEPROM is not responding correctly to programming commands. An  
instrument failure has occurred and service is required.  
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HARDWARE ERR  
HDW ERR CH 1  
10  
11  
An output error has occurred in an unknown output. Service is required.  
Errors 11 through 14 refer to a specific output where there is an output error.  
Service is required.  
HDW ERR CH 2  
HDW ERR CH 3  
HDW ERR CH 4  
NO MODEL NUM  
12  
13  
14  
15  
Same as in Error #11  
Same as in Error #11  
Same as in Error #11  
The interface cannot find its model number. There may be a hardware failure  
or the instrument may require reprogramming. Service is required.  
CAL ERROR  
16  
17  
You tried to use either a calibration command with CMODE off or the  
calibration failed while in CMODE. Enable CMODE and check numbers sent  
during calibration. Also, there could be a hardware error.  
UNCALIBRATED  
There is an incorrect checksum in the EEPROM possibly as a result of  
incorrect calibration procedure. Recalibrate, and if the problem persists, your  
supply has a hardware failure.  
Table 5-8. Error Messages (continued)  
Explanation  
Front Panel  
Response  
CAL LOCKED  
HP-IB  
Code  
18  
Calibration was attempted with the Calibration Jumper on the HP-IB board in  
the lockout position. Reposition jumper if desired. See Service Manual.  
SKIP SLF TST  
22  
The self test jumper on the HP-IB board is in the Skip Self Test position. No  
self-test was done. This is for diagnostics only. See Service Manual.  
Table 5-9. TEST? Responses  
Explanation  
Code  
0
This is the response to the TEST? query when there are no errors.  
20  
21  
27  
The timer has failed self-test. Refer to the troubleshooting section in the Service Manual.  
The RAM has failed self-test. Refer to the troubleshooting section in the Service Manual.  
The ROM has failed the checksum test. Refer to the troubleshooting section in the Service Manual.  
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6
Local Operation  
Introduction  
Chapter 3 introduced you to the supply's front panel controls and indicators to help you turn on the supply and perform  
the checkout procedures that were given in that chapter. The following paragraphs describe how to use all of the front  
panel controls and indicators. Most of the remote operations described in Chapter 5 can also be performed locally from the  
supply's front panel.  
Local Mode  
In order to use the front panel keys to control the supply, the local mode must be in effect. The local mode is in effect  
immediately after power is applied. Table 5-3 lists the initial settings for all of the power supply's functions when power is  
initially applied. When the local mode is in effect (RMT annunciator off), the Output Function, System Function, and  
Numeric Entry keys on the front panel (see Figure 6-1) can be used to operate the power supply.  
In the remote mode (front panel RMT annunciator on), the front panel keys will have no effect on any of the supply's  
outputs and only the computer can control the supply. You can, however, still use the front panel display to view the  
output voltage and current readings or the present settings for the selected output channel while the supply is in the  
remote mode.  
You can return the supply to the local mode from the remote mode by pressing the LCL key provided that the local  
lockout command has not been received from the HP-IB controller. Pressing the LCL key will also turn the supply's  
display back on if it was turned off with a DSP command during remote operation (see page 78). A change between the  
local and remote modes will not result in a change in the power supply's outputs.  
Local Control Of Output Functions  
The Output Function keys (see Figure 6-1) allow you to control the selected output. Figure 6-1 shows the annunciator  
arrow over OUTPUT 2 indicating that output channel 2 is selected. Pressing the OUTPUT SELECT key selects the output  
channels in forward (ç) or reverse ( è ) sequence. Note that Figure 6-1 illustrates the front panel for the HP 6624A  
supply which has four output annunciators. The HP 6627A front panel also has four annunciators. The front panels for HP  
Models 6621A, 6622A, and 6623A are identical to Figure 6-1 except they have fewer output annunciators.  
General  
The power supply will accept programming values directly in volts and amps. The programmable voltage, current, and  
overvoltage ranges for the outputs of each model are given in Table 5-4. The power supply will round off the values  
received to the nearest multiple of the resolution for that particular output. If you send a value out of the valid range, it  
will not be executed and the ERR annunciator will come on. You can get a readout of the error on the display by pressing  
the ERR key. For an out-of-range error, the error message "NUMBER RANGE" will be displayed.  
When you press the VSET, ISET, OVSET, DLY, or UNMASK key, the output selected and the present setting for that  
function will be displayed. For example, the front panel display in Figure 6-1 shows the VSET function for output 2 set to  
1.250. You can change the setting using the numeric entry keys. Pressing the number keys will cause the present numeric  
setting to become blank and be replaced with the new numbers on the display. You can use the ¬ key to erase previous  
keystrokes if you make a mistake.  
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Figure 6-1. Front Panel (Model 6624A shown)  
Pressing the ENTER key will enter the values displayed for the function indicated, initiate that function, and return the  
display to the metering mode in which the measured output voltage and current for the selected output are displayed.  
Pressing the ENTER key without entering numbers will result in retention of the previous values and return to the  
metering mode. You can also return to the metering mode at anytime by pressing the METER key.  
Setting Voltage  
The selected output's voltage is programmed locally using the VSET key. For example, program the voltage to 5.25 volts  
by pressing:  
VSET  
5
.
2
5
ENTER  
The front panel display then indicates the actual output voltage and current for the selected output.  
Setting Current  
The selected output's current is programmed locally using the ISET key. For example, program the current to 1.5 amps by  
pressing:  
VSET  
1
.
5
ENTER  
The power supply will accept any programmed current between zero and the minimum programmable current and  
automatically set the output to the minimum programmable current without causing a programming error. See Table 5-4.  
NOTE  
As described on page 70, each output channel has a dual output range. The range is determined by the  
last value of voltage (VSET) or current (ISET) programmed.  
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Enabling/Disabling an Output  
The selected output channel can be turned on and off from the front panel. The OUTPUT ON/OFF key toggles the  
selected output on and off. When an output is turned off, the message ''DISABLED" will be displayed.  
The OUTPUT ON/OFF key will not affect any other programmed functions nor will it reset an overvoltage or overcurrent  
condition. An output disabled by the OUTPUT ON/OFF key will behave as if it were programmed to zero volts and  
minimum current.  
Setting Overvoltage Protection  
Programmable overvoltage protection (OVP) guards your load against overvoltage by crowbarring and downprogramming  
the power supply output if the programmed overvoltage setting is exceeded.  
A fixed OVP circuit with a trip level about 20 percent above the maximum programmable voltage acts as a backup to the  
programmable OVP. When overvoltage protection is activated, the output is shorted and the message ''OVERVOLTAGE"  
will appear on the front panel display.  
The selected output's overvoltage setting is programmed locally using the OVSET key. For example, program the  
overvoltage to 10.5 volts by pressing:  
OVSET  
1
0
.
5
ENTER  
Resetting Overvoltage Protection  
The condition that caused the OV must first be cleared and then the output can be returned to its previous state by  
pressing the OVRST key.  
Enabling/Disabling Overcurrent Protection  
The overcurrent protection feature guards against excessive output currents. When the output goes into the + CC mode  
and OCP is enabled, the OCP circuit is activated which downprograms the output voltage and disables the output. For this  
condition, the message ''OVERCURRENT'' appears on the front panel display.  
The selected output's overcurrent protection feature can be turned on and off from the front panel. The OCP key toggles  
the selected output's overcurrent protection circuit on and off. When it is on (enabled), the OCP ENBLD annunciator will  
be on.  
Resetting Overcurrent Protection  
The condition that activated the OCP circuit must first be cleared then the output can be returned to its previous state by  
pressing the OCRST key.  
Displaying the Contents of the Fault Register  
Each output channel has a fault register which can be used in conjunction with the status and mask registers to report a  
fault condition. A detailed description of these registers is given in Chapter 5. The main points of this description are  
repeated below for continuity in explaining how to use the front panel UNMASK and FAULT keys.  
The mask register, which is set by the user, is used to specify which bits in the status register are enabled (unmasked) to  
set bits in the fault register. A bit is set in the fault register when the corresponding bit in the status register changes from  
0 to 1 and the corresponding bit in the mask register is 1. Each output channel has its status, mask, and fault registers  
arranged as shown in Table 6-1.  
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Table 6-1. Bit Arrangement of the Status, Mask, and Fault Registers  
7
128  
CP  
6
64  
OC  
5
32  
UNR  
4
16  
OT  
3
8
OV  
2
4
-CC  
1
2
+CC  
0
1
CV  
Bit Position  
Bit Weight  
Condition  
Note that bits can be set in an output's fault register only when there is a change in either the status register or the mask  
register. Therefore, if a bit is set in the mask register (unmasked) while the corresponding condition is true in the status  
register, the associated bit will also be set in the fault register.  
The UNMASK key is used to send a decimal number that is the sum of the weights of the bits to be set. The decimal  
number 0 will clear all bits in the mask register so that status register bits cannot set any of the corresponding fault  
register bits.  
The following example uses the number 9 (8 + 1) to set the OV bit (8) and the CV bit (1) in the mask register of the  
selected output.  
UNMASK  
9
ENTER  
This example allows only an OV and/or CV condition to appear as faults; i.e., set the corresponding bits in the fault  
register. Note that the mask register does not affect the status register; it simply determines which bits in the status  
register can set bits in the fault register.  
When you press the FAULT key, the contents of the fault register are displayed. For example, the display 9 indicates that  
the OV and CV bits in the fault register are set. The fault register is cleared immediately after it is reset by pressing  
FAULT.  
Setting the Reprogramming Delay  
A power supply's output may switch modes momentarily after a new output value is programmed or the output is reset  
from zero. To prevent these momentary conditions from appearing as faults, each output has a reprogramming delay  
parameter. The delay parameter specifies a time period in which the CV, + CC, - CC, and UNR bits in the present status  
register are masked from the fault register and from the overcurrent protection (OCP) circuit after certain commands are  
sent. Refer to Reprogramming Delay, page 78, for additional details about the reprogramming delay parameter.  
The delay time is initiated following a VSET, ISET, OVRST, OCRST, OUT on/off, or RCL command that is sent from  
the front panel (or from a remote controller).  
The delay time is settable from 0 to 32 seconds in .004 s (4 ms) intervals. The default (or power on value) is 20 ms.  
For example, set the delay time of the selected output to 345 mS by pressing:  
DLY  
.
3
4
5
ENTER  
Local Control Of System Functions  
The System Function keys consist of the ADDR, ERR, STO, and RCL keys as shown in Figure 6-1. These keys are  
independent of the output selected and are used in setting the supply's HP-IB address, displaying error messages, and  
storing/recalling voltage and current settings for all of the supply's output channels.  
Setting the Supply's HP-IB Address  
As described on page 39 before you can operate the supply remotely, you must know its HP-IB address. You can find this  
out locally from the front panel by pressing:  
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ADDR  
The supply's present address will appear in the display. Address 5 is the factory set address.  
If you want to leave the address set at 5, you can return to the metering mode by pressing the METER key or you can  
press another function key.  
If you want to change the address, you can enter a new value.  
Any integer from 0 through 30 can be selected.  
For example, you can change the address of your supply to 10 by pressing:  
ADDR  
1
0
ENTER  
Displaying Error Messages  
The power supply can detect both programming and hardware errors. Upon detecting an error, the ERR annunciator on  
the front panel comes on and the ERR bit in the serial poll register will be set (see page 75).  
When an error is detected, you can display the error message by pressing the ERR key. The power supply will return the  
error message to the display and clear the error bit. For example, if you program a number that is not within the valid  
range, the ERR annunciator will come on. You can display the error message by pressing the ERR key. In this case, the  
error message "NUMBER RANGE" will be displayed. Errors generated either locally from the front panel or remotely  
from the HP-IB computer can be displayed by pressing the ERR key only when the supply is in the local mode. Pressing  
the ERR key also clears the error bit so if you press ERR again, the message "NO ERROR" will appear. All error codes  
and associated display messages are listed in Table 5-8.  
Storing and Recalling Voltage and Current Settings for All Outputs  
As described on page 72, the power supply has 10 internal registers for storing voltage and current settings of  
all outputs. At power on each location contains zero volts and the minimum current limit (see Initial Conditions, page 68).  
The STO and RCL keys allow you to store and recall voltage and current settings for all your output channels from any of  
the 10 internal registers (numbered 1 through 10). For example, you can store the present settings of voltage and current  
for all the output channels in internal register 2 by pressing:  
STO  
2
ENTER  
You can change the settings of any of your supply's outputs any number of times as required and then program them to the  
settings stored in internal register 2 by pressing;  
RCL  
2
ENTER  
The internal register will not retain the settings when power is turned off. When power is turned off and then on again,  
each internal register will be reset to the zero voltage and minimum current settings of each output channel.  
The advantages in using the internal registers are that command processing time is saved and repetitive programming of  
different settings is simplified. The STO key can be used in conjunction with the OUTPUT ON/OFF key to store settings  
while the outputs are disabled (OFF). These stored settings can be used later to program the outputs to the stored settings  
using the RCL and OUTPUT ON/OFF keys.  
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A
Calibration Procedures  
Introduction  
This appendix discusses the software calibration procedures for the power supply. These supplies should be calibrated  
annually or whenever certain repairs are made (see Service Manual).  
Because there are no internal or external hardware adjustments, your power supply can be calibrated without removing the  
covers or removing it from the cabinet if it is rack mounted. Calibration is performed by measuring actual output values  
and sending them to the supply over the HP-IB. The power supply uses these values to calculate output, readback, and  
overvoltage correction constants. These correction constants are stored in a non-volatile memory on the HP-IB interface  
board of the supply. Thereafter, when a command such as ''VSET1,5" is sent to set the voltage on output 1, the power  
supply uses the correction constants to accurately program the output.  
Correction constants for offset and full scale voltage and current values are stored for one output channel at a time. A  
separate calibration command calculates and stores correction constants for the internal overvoltage circuit. This appendix  
lists the equipment that you need, shows the test setup to perform the calibration, gives a general calibration procedure  
that explains all of the calibration commands, and gives a sample program you can use if you have a HP 3456A voltmeter  
and a HP Series 200/300 computer with BASIC.  
Security against accidental calibration is available. A jumper inside the unit may be moved to disable all calibration  
commands. Access to this jumper requires opening the unit (see the Service Manual).  
Tables A-1 and A-2 give the data ranges for all of the power supply calibration commands. Refer to Figure 5-2 for the  
syntax structure of the calibration commands. You can either execute the calibration commands directly from the  
keyboard, or you can use them in a program to reduce the time involved in calibrating each output.  
NOTE  
The memory used to store correction constants will accept and store data about 10,000 times, which is  
more than sufficient for normal calibrations over the life of the instrument. However, do not put the unit  
in a calibration loop that repeatedly turns the calibration mode on and off.  
Test Equipment and Setup Required  
The following test equipment is required for calibration:  
1. A computer connected to the HP-IB connector on the back of the power supply.  
2. A voltmeter accurate to 0.003% of reading.  
3. A precision 0.1 W, ± 0.05%, 10 amp shunt resistor (4 terminal).  
Figure A-1 shows the setup required for calibrating both voltage and current. Observe polarity when connecting the  
voltmeter. Note that for voltage calibration, the voltmeter leads are connected to the + S and - S terminals and NOT  
the + V and - V terminals. Note that for both + and - current calibration the voltmeter leads are connected to the shunt  
resistor's sense terminals.  
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Figure A-1. Calibration Setup  
90 Calibration Procedures  
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Table A-1. Calibration Commands  
Command  
Header  
Channel*  
Range  
Data  
Syntax  
(see Figure 5-2)  
Calibration Mode  
Set High Voltage  
Set Low Voltage  
Set High Current  
Set Low Current  
Calibrate Overvoltage  
Voltage Data  
CMODE  
VHI  
0,1 (off,on)  
C2  
C3  
C3  
C3  
C3  
C3  
C5  
C5  
1,2,3,4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
1,2,3,4  
-
VLO  
-
IHI  
-
ILO  
-
OVCAL  
VDATA  
IDATA  
-
see Table A-2  
see Table A-2  
Current Data  
*Channels 3 and 4 are not used in all models.  
Table A-2. Voltage and Current Data Ranges  
Voltage Range in Volts Current Range in Amps  
Vlo Vhi llo Ihi  
Output  
Min  
Max  
Min  
Max  
Min  
Max  
Min  
Max  
40 W Low Voltage  
0
0.1  
18.5  
20.5  
0
0.15  
4.5  
5.3  
40 W High Voltage  
80 W Low Voltage  
80 W High Voltage  
0.04  
0
0.20  
0.1  
44  
18.5  
44  
48  
20.5  
48  
0
0.05  
0
0.1  
0.25  
0.1  
1.5  
9
2.1  
10.5  
4.2  
0.04  
0.20  
3.5  
General Calibration Procedure  
This procedure causes the voltage of the specified output to go to full scale value. Take appropriate  
precautions.  
The following general procedure applies to any computer that you are using to control your power supply. This procedure  
must be repeated for each output on your power supply. The calibration commands shown are the actual string commands  
that must be sent to the power supply. Because the power supply will attempt to calibrate itself even when incorrect or  
invalid readings are sent to it, it is recommended that you perform some type of error checking after steps 4, 5, and 8 to  
ensure that the values sent to the supply are legitimate. Use the ranges in Table A-2 as a guide. If an error is detected  
while in calibration mode, send CLR or turn the supply off to maintain the previous calibration constants. This will  
prevent incorrect constants from being stored. See Table 5-8 for a list of errors.  
Before you continue with this procedure, disconnect all loads from the supply, strap the supply for local sensing, and  
connect the voltmeter to the + S and - S terminals as shown in the voltage calibration setup of Figure A-1.  
Start with output channel 1 and use the following commands to calibrate your power supply:  
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NOTE  
Do not turn the power supply off during the calibration procedures. Otherwise, the correction constants  
are not stored. Exercise care when moving the leads.  
1.  
CMODE < param > - This command turns the calibration mode either on or off. The parameter must be either a  
1 or a 0. CMODE1 is used in the beginning of the calibration procedure to turn calibration mode on. CMODE  
must be on to use any of the calibration statements. CMODE0 is used at the end of the procedure to store the  
correction constants and turn calibration mode off. The CMODE? query can also be used at any time to  
determine if the supply is in calibration mode. A 1 indicates calibration mode is on; a 0 indicates calibration  
mode is off. Continue to the next command.  
2.  
3.  
4.  
VHl<channel> - This command causes the voltage of the specified output channel to go to the high calibration  
point (full scale). After the command is sent, use the voltmeter to read the actual voltage <Vhi > put out by the  
power supply. Continue to the next command.  
VLO < channel > - This command causes the voltage of the specified output channel to go to the low calibration  
point (voltage offset). After the command is sent, use the voltmeter to read the actual voltage < Vlo > put out by  
the power supply. Continue to the next command.  
VDATA < channel >, < Vlo >, < Vhi > - This command is used to send the actual values measured by the  
voltmeter in the previous steps to the power supply. Refer to Table A-2 for the range of valid voltage readings  
that can be sent to the supply. <Vlo> is the voltage in volts that was measured after the VLO command was sent.  
< Vhi > is the voltage in volts that was measured after the VHI command was sent. The power supply uses these  
values to calculate the voltage and voltage readback correction constants of the specified output. Continue to the  
next command.  
5.  
OVCAL < channel > - This command automatically calibrates the programmable overvoltage. This can only be  
done after the voltage has been calibrated. It may take up to 10 seconds for this command to execute. During this  
time, the front panel display indicates "CALIBRATING" .  
When the front panel display of the power supply no longer indicates ''CALIBRATING", the overvoltage portion of the  
calibration procedure is complete. The voltages on the output are returned to zero volts after the overvoltage calibration.  
To continue with the current portion of the calibration procedure, connect a four terminal 0.1W current shunt resistor  
(0.05%, 10 A) between the +V and -V output terminals. Connect the voltmeter to the resistor's sense terminals. Refer to  
the current calibration setup in Figure A-1.  
Continue calibrating output 1 with the following commands:  
6.  
7.  
8.  
IHI < channel > - This command causes the current of the specified output channel to go to the high calibration  
point (full scale). After the command is sent, use the voltmeter to read the voltage drop across the current shunt  
resistor. Divide this reading by the shunt value to derive the actual current in amps < Ihi > put out by the supply.  
Continue to the next command.  
ILO <channel> - This command causes the current of the specified output channel to go to the low calibration  
point (current offset). After the command is sent, use the voltmeter to read the voltage drop across the current  
shunt resistor. Divide this reading by the shunt value to derive the actual current in amps <Ilo> put out by the  
supply. Continue to the next command.  
IDATA < channel >, < IIO >, < Ihi > - This command is used to send the actual current values derived in steps 6  
and 7 to the power supply. Refer to Table A-2 for the range of valid current readings that can be sent to the  
supply. < Ilo > is the current in amps that was put out by the supply after the ILO command was sent. < Ihi > is  
the current in amps that was put out by the supply after the IHI command was sent. The power supply uses these  
values to calculate the current and current readback correction constants of the specified output.  
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Repeat commands two through eight for any other outputs that must be calibrated on your power supply. After you have  
completed calibration of all outputs, turn the calibration mode off by sending the CMODE0 command (see step 1) to the  
power supply. The correction constants are stored in memory at this time.  
Calibration Program  
The following calibration program can be used as is, provided you have an HP Series 200 computer with the BASIC  
programming language and an HP 3456A voltmeter. The calibration program is written with the assumption that your  
power supply is at address 705 and the voltmeter is at address 722. The program will ask you which output is to be  
calibrated and will prompt you to make the voltage and current calibration connections shown in Figure A-1.  
10  
20  
! CALIBRATION EXAMPLE  
!
30  
40  
50  
60  
ASSIGN @Ps TO 705  
ASSIGN @Vm TO 722  
COM /lnstr/ @Ps,@Vm  
Shunt_resistor=.1  
!
70  
80  
90  
100  
110  
120  
130  
OUTPUT @Ps;"CLR"  
OUTPUT @Vm;"H T4"  
TRIGGER 722  
ENTER @Vm;Temp  
OUTPUT @Ps;"CMODE 1"  
!
! CLEAR VOLTMETER OUTPUT BUFFER  
140 Start_loop: ! LOOP TO HERE FOR ADDITIONAL OUTPUTS  
150  
160  
170  
180  
190  
200  
210  
220  
230  
240  
250  
260  
270  
280  
290  
300  
310  
320  
330  
340  
350  
360  
370  
380  
390  
400  
410  
420  
430  
440  
!
INPUT "ENTER OUTPUT CHANNEL TO BE CALIBRATED (1,2,3,or 4)'',Chan  
DISP ''SET UP OUTPUT ";Chan;" FOR VOLTAGE CALIBRATION & PRESS CONTINUE''  
PAUSE  
!
OUTPUT @Ps;''VHI'';Chan  
Vhi = FNDvm  
!
OUTPUT @Ps;"VLO";Chan  
Vlo = FNDvm  
!
OUTPUT @Ps;''VDATA";Chan,Vlo,Vhi  
!
IF FNPs _ err< >0 THEN Finish  
!
OUTPUT @Ps;"OVCAL";Chan  
REPEAT  
DISP "WAITING FOR OVERVOLTAGE CALIBRATION"  
UNTIL BlT(SPOLL(@Ps),4)  
!
IF FNPs _ err < > 0 THEN Finish  
!
DISP ''SET UP OUTPUT ";Chan;" FOR CURRENT CALIBRATION & PRESS CONTINUE"  
PAUSE  
!
OUTPUT @Ps;''IHI";Chan  
Ihi = FNDvm/Shunt _ resistor  
!
OUTPUT @Ps;"ILO";Chan  
Ilo = FNDvm/Shunt _ resistor  
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450  
460  
470  
480  
490  
500  
510  
520  
530  
540  
550  
560  
!
OUTPUT @Ps;''IDATA";Chan,Ilo,Ihi  
!
IF FNPs _ err < >0 THEN Finish  
!
OUTPUT @Ps;"VSET ";Chan,"0 ;ISET '';Chan,"0"  
!
INPUT "ANY MORE OUTPUTS TO CALIBRATE? (Y OR N)",X$  
IF (X$=''Y" OR X$=''y") THEN Start_loop  
!
OUTPUT @Ps;"CMODE 0"  
!
570 Finish: ! HERE WHEN DONE  
580  
590  
600  
610  
620  
630  
640  
650  
660  
670  
680  
690  
700  
710  
720  
730  
740  
750  
OUTPUT @Ps;''CLR"  
DISP "END OF CALIBRATION PROGRAM"  
END  
!
!
DEF FNDvm  
COM /Instr/ (@Ps,@Vm  
WAIT.02  
TRIGGER @Vm  
ENTER @Vm;Reading  
RETURN Reading  
FNEND  
!
DEF FNPs _ err  
COM /Instr/ @Ps,@Vrn  
OUTPUT @Ps;’’ERR?"  
ENTER @Ps;Err  
IF Err< >0 THEN PRINT "POWER SUPPLY ERROR # '';Err;" CORRECTION CONSTANTS NOT SAVED -  
RESTART. "  
760  
770  
RETURN Err  
FNEND  
LINE 10: This comment line identifies the program as a CALIBRATION EXAMPLE.  
LINE 30,40: Assigns I/O path names to the power supply and the voltmeter.  
LINE 50: Establishes a COM block for the instruments on the HP-IB.  
LINE 60: Initializes the variable Shunt _ resistor to .1 ohms.  
LINE 80: Clears the power supply.  
LINE 90: Initializes the voltmeter to take voltage readings.  
LINE 100,110: Tells the voltmeter to take a reading and clears the voltmeters output buffer. This reading is not used in  
the program.  
LINE 120: Turns on the power supply calibration mode.  
LINE 140: Labels the line ''Start_loop" to loop back to when calibrating more than one output.  
LINE 160: Enters the output channel number to be calibrated.  
LINE 170,180: Prompts the user to make voltage calibration connections and waits for CONTINUE key to be pressed.  
LINE 200: Sets the voltage of the specified output to the high calibration point.  
LINE 210: Sets the variable Vhi to the output voltage as measured by the user defined function FNDvm.  
LINE 230: Sets the voltage of the specified output to the low calibration point.  
LINE 240: Sets the variable Vlo to the output voltage as measured by the user defined function FNDvm.  
LINE 260: Sends the measured data in volts to the power supply for the specified channel.  
LINE 280: Checks the power supply for errors with the user defined function FNPs _ err. If there was an error, the  
program goes to the line labeled Finish and the supply is cleared. The new measured data is not used and the  
previous calibration constants are maintained.  
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LINE 300: Instructs the power supply to perform an overvoltage calibration on the specified channel.  
LINE 310--330: Displays a message on the computer until bit 4 (RDY) of the power supply's serial poll register indicates  
that the supply is finished processing the OVCAL command. This may take up to 10 seconds.  
LINE 350: Checks for errors. See line 280.  
LINE 370,380: Prompts the user to make current calibration connections and waits for CONTINUE key to be pressed.  
LINE 400: Sets the current of the specified output to the high calibration point.  
LINE 410: Sets the variable Ihi to the output current as measured by the voltmeter across the shunt resistor. Note that Ihi  
is in amps since the voltmeter returns volts and Shunt _ resistor is in ohms.  
LINE 430: Sets the current of the specified output to the low calibration point.  
LINE 440: Sets the variable Ilo to the output current as measured by the voltmeter across the shunt resistor.  
LINE 460: Sends the measured data in amps to the power supply for the specified channel.  
LINE 480: Checks for errors. See line 280.  
LINE 500: Set output voltage to 0 so that output connections may be safely moved.  
LINE 520,530: Loops to Start_loop if the user has more outputs to calibrate otherwise, continues.  
LINE 550: Stores the calibration constants by turning off the power supply calibration mode.  
LINE 570--600: Clears the supply and ends the main program.  
LINE 630: Defines the user defined function FNDvm.  
LINE 640: Brings in the COM block "Instr''.  
LINE 650: Waits .02 seconds for the supply to settle at the calibration points.  
LINE 660,670: Takes a reading from the voltmeter.  
LINE 680: Returns the voltmeter reading to the appropriate variable within the main program.  
LINE 690: Ends the user defined function FNDvm.  
LINE 710: Defines the user defined function FNPs _ err.  
LINE 720: Brings in the COM block "Instr".  
LINE 730,740: Queries the power supply for any errors.  
LINE 750: If an error occurred, the computer reports the error.  
LINE 760: Returns the error number to the appropriate place within the main program.  
LINE 770: Ends the user defined function FNPs _ err.  
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B
Programming With A Series 200/300 Computer  
Introduction  
The purpose of this appendix is to serve as an introduction to programming your power supply with an HP Series 200/300  
computer using the HP extended BASIC language. Examples are included that employ some of the most frequently used  
functions. These examples have been written so that they will run on any one of the five HP 6621A-6624A, and 6627A  
model power supplies. The values used in the examples (5 V and 1 A for instance), are within the operating locus of all  
outputs on all models. The examples program only channels one and two because all five models contain at least two  
channels (outputs).  
You must be familiar with the BASIC language to understand the examples. If you do not recognize a programming  
statement, look up the keyword in the BASIC Language Reference document that was supplied with your computer, and  
look up the device command in Chapter 5 of this manual. Questions about program structure and selection are discussed  
in the BASIC Programming Techniques manual.  
I/O Path Names  
Throughout this appendix, I/O path names are used in place of interface and device select codes. In a large program, I/O  
path names simplify changing the address of an instrument if necessary. Reading and writing the program is easier as  
well. The l/O path name can be carried in a common block and changed by a single assign statement.  
In the programming examples in this appendix, the I/O path name @Ps is used for the power supply. The ASSIGN  
statement that defines the I/O path must precede any statements that use the l/O path name. Therefore, instead of using  
the statement OUTPUT 705;"VSET1,5" in the following programs, the equivalent OUTPUT @Ps;"VSET1,5'' statement is  
used. The examples assume that the power supply is at address 5 and the HP-IB interface in the computer is select 7  
(factory default).  
Voltage and Current Programming  
The power supply normally functions in one of two modes, either constant voltage with current limit or constant current  
with voltage limit. The operating mode is determined by a combination of voltage and current settings and load resistance.  
For example, with a 10 W load connected to output 1, the following program will put output 1 in constant voltage mode at  
5 volts out with a 1 amp current limit. In this case the output current would be 0.5 A.  
10 ASSIGN @Ps TO 705  
20 OUTPUT @Ps;"VSET1,5;1SET1,1"  
30 END  
Line 10: Assigns the l/O pathname to the power supply.  
Line 20: Sets output voltage and current. Note the use of the semicolon to separate multiple device commands.  
If a 4 W load were used instead of a 10 W load, output 1 would have been operating in constant current mode at 1 amp out  
with a voltage limit of 5 volts. In this case the output voltage would be 4 V.  
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Voltage and Current Programming With Variables  
You can use variables in a program to represent data values in the device commands. This is useful in applications that  
require changing the voltage and current values to different predetermined settings. The following program uses a  
variable in a FOR NEXT loop to ramp up output voltage in 0.1 volt steps from 0 to 5 volts.  
10 ASSIGN @Ps TO 705  
20 OUTPUT @Ps;"CLR;ISET1,1"  
30 FOR Voltage=0 TO 5 STEP 0.1  
40 OUTPUT @Ps;"VSET1,'';Voltage  
50 WAIT 0.2  
60 NEXT Voltage  
70 END  
Line 10: Assigns the I/O pathname to the power supply.  
Line 20: Initializes the power supply to its power on state and sets the current limit.  
Line 30,60: Increments the voltage in 0.1 V steps to 5 volts.  
Line 40: Sets the voltage of output 1 to the value of the variable "Voltage''. The comma inside the quotes is required  
because it separates numbers in the device command (the output channel number from the voltage value in this  
case). A space < SP > may also be used instead of the comma. The semicolon outside the quotes is used because it  
suppresses the <CR > <LF> that the computer would normally send to the power supply if a comma were used as  
a separator after a string item. Using a comma in this case would produce a syntax error in the power supply.  
Line 50: Waits 0.2 seconds between steps.  
Another way to use variables to represent data values in device commands is when using input statements to program the  
power supply. The following program uses input statements to program the voltage and current settings of output 1 and  
output 2.  
10 ASSIGN @Ps TO 705  
20 INPUT "ENTER A VOLTAGE FOR OUTPUT #1",V1  
30 INPUT "ENTER A CURRENT LIMIT FOR OUTPUT #1",I1  
40 INPUT ''ENTER A VOLTAGE FOR OUTPUT #2",V2  
50 INPUT "ENTER A CURRENT LIMIT FOR OUTPUT #2",I2  
60 OUTPUT @Ps;''VSET1,";V1;";ISET1,'';I1;'';VSET2,";V2;";ISET2,";I2  
70 END  
Line 10: Assigns the I/O pathname to the power supply.  
Line 20,30: Enter voltage and current values for output 1.  
Line 40,50: Enter voltage and current values for output 2.  
Line 60: Sets the voltage and current of outputs 1 and 2 to the values entered into the variables. The previous example  
explained the use of the comma inside the quotes and the semicolon that precedes the variable. The semicolon  
that follows the variable suppresses the comma that the computer would normally send to the power supply if a  
comma were used as a separator after a numeric item. The leading semicolons inside the quotes separate multiple  
device commands (the VSET commands from the ISET commands in this case).  
Voltage and Current Readback  
Reading back data from the power supply requires two statements. First, an output statement is used to query the power  
supply. A list of queries appears in Table 5-2. The power supply responds to the query by entering the requested data into  
a buffer. Next, an enter statement is used to read the data from the buffer on the power supply into a variable in the  
computer. The following program queries the power supply for the voltage and current settings of output 1 and prints the  
results on the screen.  
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10 ASSIGN @Ps TO 705  
20 OUTPUT @Ps;"VSET?1''  
30 ENTER @Ps;Vsl  
40 OUTPUT @Ps;''ISET?1"  
50 ENTER @Ps;Isl  
60 PRINT ''VOLTAGE SETTING OF OUTPUT #1 = '';Vsl  
70 PRINT ''CURRENT LIMIT SETTING OF OUTPUT #1 = ";Is1  
80 END  
Line 10: Assigns the I/O pathname to the power supply.  
Line 20,30: Queries the supply for output 1's voltage setting. You cannot string multiple queries together in a single  
device command because the power supply can only return the most recently queried data.  
Line 40,50: Queries the supply for output 1's current limit.  
Line 60,70: Prints the results of the queries on the screen.  
Programming Power Supply Registers  
Present Status  
The power supply makes available several forms of status information. Chapter 5 discusses the different registers and their  
functions. The present status register contains continuously updated information. The following example shows how to  
query bit position 0 of output 1's status register to see if output 1 is in CV mode. In this example, the program references  
the function as a variable in a conditional execution statement. Note that instead of printing a message, line 30 could be  
used to branch to another part of the program in the event that the supply is in CV mode.  
10 ASSIGN @Ps TO 705  
20 COM /Ps/ @Ps  
30 IF FNCv_mode THEN  
40 PRINT "OUTPUT1 IS IN CV MODE"  
50 END IF  
60 END  
70 !  
80 !  
90 DEF FNCv_mode  
100 COM /Ps/ @Ps  
110 OUTPUT @Ps;"STS?1"  
120 ENTER @Ps;Sts  
130 RETURN BIT(Sts,0)  
140 FNEND  
Line 10: Assigns the I/O path name to the power supply.  
Line 20: Declare a common block for the I/O path name. The COM statement must be used for the @Ps variable to  
preserve its value in the function subprogram.  
Line 30,40,50: If FNCv_mode is true, print the message.  
Line 90: Defines the Cv_mode function.  
Line 100: Brings in the common block for the I/O pathname.  
Line 110,120: Reads the present status of output 1 into the variable Sts.  
Line 130: Returns the value of bit position 0 of Sts.  
Service Request and Serial Poll  
The fault and mask registers, when used in conjunction with the service request and serial poll functions, allow you to  
select which conditions can cause computer interrupts. The fault and mask registers can also be used independently of the  
serial poll or service request if so desired. The following example shows how to enable an interrupt to the computer in the  
case of an overvoltage condition. After the interrupt has occurred, this example includes an interrupt routine that conducts  
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a serial poll to determine on which output the overvoltage occurred. Note that this example assumes that terminal block  
external OV trip lines are not wired together.  
10 ASSIGN @Ps TO 705  
20 COM /Ps/ @Ps  
30 OUTPUT @Ps;''CLR;UNMASK1,8;UNMASK2,8;SRQ1''  
40 ON INTR 7,1 CALL Err _ trap  
50 ENABLE INTR 7;2  
60 OUTPUT @Ps;"OVSET1,4;0VSET2,4"  
70 OUTPUT @Ps;"VSET1,5;VSET2,5"  
80 Lbl: GOTO Lbl  
90 END  
100 !  
110 !  
120 SUB Err _ trap  
130 OFF INTR  
140 COM /Ps/ @Ps  
150 IF BlT(SPOLL(@Ps),0) THEN  
160 OUTPUT @Ps;''OUT1,0;OVRST1''  
170 PRINT ''OVERVOLTAGE ON OUTPUT #1"  
180 END IF  
190 IF BIT(SPOLL(@Ps),1) THEN  
200 OUTPUT @Ps;"OUT2,0;OVRST2"  
210 PRINT "OVERVOLTAGE ON OUTPUT #2"  
220 END IF  
230 OUTPUT @Ps;''FAULT?1;FAULT?2"  
240 SUBEND  
LINE 10: Assigns the I/O pathname to the power supply.  
LINE 20: Declare a common block for the I/O pathname. The COM statement must be used for the @Ps variable to  
preserve its value for use in the service routine.  
LINE 30: Returns the power supply to its power on state, unmasks output 1's and output 2's OV status bits to generate  
faults, and enables the service request capability on all outputs.  
LINE 40: Define interrupt at interface 7, with HP-IB priority 1.  
LINE 50: Enable interrupt at interface 7 for service request type interrupts only.  
LINE 60: Sets the overvoltage of outputs 1 and 2 to 4 volts.  
LINE 70: Sets the voltage of outputs 1 and 2 above the OV setting so that both outputs will overvoltage when the program  
is run.  
LINE 80: Waits for the computer to receive the interrupt. This simulates conditions that would normally exist when a  
program is running.  
LINE 120: Defines the error handling routine.  
LINE 130: Disables interrupt capability while processing.  
LINE 140: Brings in the common block for the I/O pathname.  
LINE 150-180: Conducts a serial poll. If bit 0 in serial poll register indicates a fault for output 1, output 1 is disabled and  
the overvoltage circuit is reset.  
LINE 190-220: Checks bit 1 in serial poll register for a fault on output 2. If true, output 2 is disabled and the overvoltage  
circuit is reset.  
LINE 230: Reads fault registers to clear FAU bits in serial poll register.  
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Error Detection  
The power supply can recognize programming errors and can inform you when a programming error occurs. When an  
error is detected, no attempt is made to execute the command. Instead, a bit in the serial poll register is set. If SRQ2 or  
SRQ3 is set, an interrupt will be generated. The following program checks for programming errors and can be entered and  
run as is. While it is running, commands can be sent to the power supply from the keyboard. If the ERROR annunciator  
on the power supply's front panel indicates that an error has been detected, depress the labeled softkey to display the error  
on your computer screen.  
10 ASSIGN @Ps TO 705  
20 COM /Ps/ @Ps  
30 ON KEY 0 LABEL "ERROR?" CALL Err_trap  
40 Lbl: GOTO Lbl  
50 END  
60 !  
70 !  
80 SUB Err _ trap  
90 OFF KEY  
100 COM /Ps/ @Ps  
110 OUTPUT @Ps;"ERR?''  
120 ENTER @Ps;Err  
130 OUTPUT 2 USING "#,K";CHR$(255)&CHR$(75)  
140 IF Err THEN  
150 PRINT "POWER SUPPLY PROGRAMMING ERROR:"  
160 END IF  
170 SELECT Err  
180 CASE 0  
190 PRINT "NO ERROR OCCURRED"  
200 SUBEXIT  
210 CASE 1  
220 PRINT "INVALID CHARACTER"  
230 CASE 2  
240 PRINT "INVALID NUMBER"  
250 CASE 3  
260 PRINT "INVALID STRING"  
270 CASE 4  
280 PRINT ''SYNTAX ERROR"  
290 CASE 5  
300 PRINT "NUMBER OUT OF RANGE"  
310 CASE 6  
320 PRINT "DATA REQUESTED WlTHOUT QUERY"  
330 CASE 7  
340 PRINT "STRING EXCEEDS DISPLAY LENGTH"  
350 CASE 8  
360 PRINT "NUMBER TOO LARGE FOR INPUT BUFFER"  
370 CASE 28  
380 PRINT ''INVALID CHARACTERS IN STRING"  
390 CASE ELSE  
400 PRINT ''UNRECOGNIZED ERROR NUMBER"; Err  
410 END SELECT  
420 PRINT "RE-ENTER STATEMENT AND TRY AGAIN"  
430 SUBEND  
Programming with a Series 200/300 Comput1e0r1  
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LINE 10: Assigns the I/O path name to the power supply.  
LINE 20: Declare a common block for the I/O path name.  
LINE 30: Define interrupt on softkey depression and branch to error routine.  
LINE 40: Idle on softkey definition.  
LINE 80: Define subprogram Err_trap  
LINE 90: Disable interrupt capability while processing.  
LINE 100: Bring in the common block for the I/O pathname.  
LINE 110,120: Enter error code from power supply.  
LINE 130: Clears computer screen.  
LINE 140,150: If an error occurred, print message.  
LINE 170-420: Print message based on error code. Prompt user to try again. If no error occurred, print message saying no  
error occurred.  
Stored Operating States  
Your power supply has registers that can store up to 10 operating states. These states can be recalled in arbitrary order.  
Storing a state involves taking a "snapshot" of the voltage and current settings that are in effect when the command is  
received. The following example uses stored operating states to set up an output. Using this method of setting up outputs  
saves processing time and facilitates repeating the same commands.  
10 ASSIGN @Ps TO 705  
20 OUTPUT @Ps;"OUT1,0;OUT2,0"  
30 !  
40 OUTPUT @Ps;"VSET1,1;ISET1,.1;VSET2,5;ISET2,.1;5TOl"  
50 OUTPUT @Ps;"VSET1,2;ISET1,.2;VSET2,4;ISET2,.2;STO2"  
60 OUTPUT @Ps;''VSET1,3;ISET1,.3;VSET2,3;ISET2,.3;STO3"  
70 OUTPUT @Ps;"VSET1,4;ISET1,.4;VSET2,2;ISET2,.4;STO4''  
80 OUTPUT @Ps;"VSET1,5;1SET1,.5;VSET2,1;1SET2,.5;STO5"  
90 !  
100 OUTPUT @Ps;"CLR"  
110 FOR State= 1 TO 5  
120 OUTPUT @Ps;"RCL";State  
130 WAIT 2  
140 NEXT State  
l50 END  
LINE 10: Assigns the I/O pathname to the power supply.  
LINE 20: Disables output 1 and output 2.  
LINE 40-80: Stores 5 operating states for output 1 and output 2 in storage registers 1 through 5. Outputs not explicitly  
programmed will store the settings that are in effect when the store command is received.  
LINE 100: Clears the supply. All outputs are enabled and set to the initial power on state (0 volts; minimum current  
setting).  
LINE 110-140: Loops through the sequence of five states with a two second wait between states.  
Programming Outputs Connected In Parallel  
Only outputs that have equivalent voltage and current ratings can be connected in parallel.  
When programming outputs that are connected in parallel, it is convenient if you first know if you will be operating in CC  
or CV mode. Refer to Chapter 4 for more information on parallel operation.  
102 Programming with a Series 200/300 Computer  
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CC Operation  
Programming for CC operation is straightforward. Program each output to the desired voltage limit point. Then program  
each output to supply half of the total desired operating current. Both outputs will operate in CC mode. Note that the total  
desired current cannot exceed the combined current capability of both outputs. Figures 4-11 and 4-12 are examples of  
parallel configurations. These configurations apply to both CV and CC operating modes. Note the sense lead connections.  
10 ASSIGN @Ps TO 705  
20 INPUT "ENTER VOLTAGE LIMIT'',V  
30 INPUT "ENTER OPERATING CURRENT",Oc  
40 C = Oc/2  
50 OUTPUT @Ps;"CLR;VSET1,'';V;";ISET1,";C;";VSET2,";V;";ISET2,";C  
60 END  
LINE 10: Assigns the I/O pathname to the power supply.  
LINE 20,30: Enter the voltage limit and operating current.  
LINE 40: Divides the total current requirement by 2.  
LINE 50: Clears the supply and sets each output to supply half of the desired operating current at any voltage up to the  
desired voltage limit.  
CV Operation  
For CV operation, one output must operate in CC mode and the other output must operate in CV mode. The output that is  
operating in CV mode will be controlling the voltage regulation of both outputs.  
In the example that follows, outputs 1 and 2 (both 40 W or 80 W Low V channels) will be operating in parallel with  
output 1 in CV mode and output 2 in CC mode at output voltages above 2.5 V. Each is programmed to one half of the  
desired current limit point. Above 2.5 V, the voltage for output 2 is always programmed higher than that of output 1 to  
ensure that output 2 operates in the CC mode. Note that any current from output 2 that is not required by the load flows  
into the downprogrammer of output 1 and is reflected in the current readback of output 1. The total current supplied to the  
load can be read back by adding the results of reading back the currents of outputs 1 and 2. At 2.5 V and below, the  
outputs are set to the same voltage and the operating modes depend upon the load.  
10 ASSIGN @Ps to 705  
20 INPUT "ENTER OPERATING VOLTAGE",V1  
30 INPUT "ENTER TOTAL CURRENT LIMIT",Ilim  
40 C = Ilim/2  
50 IF V1 > 7 THEN V2 = 20.2  
60 IF V1< =7 THEN V2=7.07  
70 IF Vl < = 2.5 THEN V2 = V1  
80 OUTPUT @Ps;"CLR;ISET1,";C;";VSET1,";V1  
90 OUTPUT @Ps;''ISET2,";C;"VSET2,";V2  
100 WAIT 1  
110 OUTPUT @Ps;"VOUT?1"  
120 ENTER @Ps;Vout  
130 OUTPUT @Ps;"IOUT?1''  
140 ENTER @Ps;Ioutl  
150 OUTPUT @Ps;"IOUT?2"  
160 ENTER @Ps;Iout2  
170 PRINT "OUTPUT VOLTAGE IS ";Vout  
180 PRINT "TOTAL OUTPUT CURRENT IS ";Ioutl + Iout2  
190 END  
Programming with a Series 200/300 Comput1e0r3  
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LINE 10: Assigns the I/O pathname to the power supply.  
LINE 20,30: Enter the operating voltage and current limit point.  
LINE 40: Sets C equal to one half of the current limit point.  
LINE 50-70: Determines the voltage setting for output 2. It is 20.2 V when the operating voltage is greater than 7 V, 7.07  
V when the operating voltage is between 7 V and 2.5 V, and the same as the operating voltage below 2.5 V.  
LINE 80: Clears the supply, sets the current of output 1 to one half of the current limit point, and sets the voltage of  
output 1 to the operating voltage.  
LINE 90: Sets the current of output 2 to one half of the current limit point and sets the voltage of output 2 to the value  
determined by the operating voltage.  
LINE 100: Waits 1 second before reading back output voltage and current.  
LINE 110-160: Reads the output voltage of output 1 and the output current of outputs 1 and 2.  
LINE 170: Prints the output voltage of the parallel outputs on the screen.  
LINE 180: Prints the total output current of the parallel outputs on the screen. Note that this is the sum of the output  
currents of outputs 1 and 2.  
Programming Outputs Connected In Series  
To program outputs connected in series, you must first determine the maximum voltage and current that you would like to  
have available to your load. These values are the desired voltage limit and current limit points. Next, program the current  
of both outputs to this desired current limit point. The voltage of each output can then be programmed so that the sum of  
the voltages equals the desired voltage limit point. An easy way to do this is to set each output to one half of the desired  
limit point. Refer to Chapter 4 for more information on series operation. Figures 4-13 and 4-14 are examples of series  
configurations which apply to both the CV and CC operating modes. Note the sense lead connections shown in Figure  
4-14.  
The following example programs outputs 1 and 2 which are connected in a series configuration.  
10 ASSIGN @Ps to 705  
20 INPUT "ENTER THE DESIRED CURRENT LIMIT POINT",I  
30 INPUT "ENTER TElE DESIRED VOLTAGE LIMIT POINT",V  
40 OUTPUT @s;"CLR;ISET1,";I;'';ISET2,";I  
50 OUTPUT @Ps;"VSET1,'';V/2;";VSET2,";V/2  
60 END  
LINE 10: Assigns the I/O pathname to the power supply.  
LINE 20: Enter the desired current limit point.  
LINE 30: Enter the desired voltage limit point.  
LINE 40: Clears the supply and sets the current of both outputs to the desired current limit point.  
LINE 50: Sets the voltage of each output to one half of the desired voltage limit point so that the sum is the desired  
voltage limit point.  
104 Programming with a Series 200/300 Computer  
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C
Command Summary  
Introduction  
Table C-1 provides an alphabetical listing and a brief description of each command that can be sent to the HP 6621A-  
24A, and 6627A power supplies. All of the commands can be executed remotely over the HP-IB. Many of the commands  
can also be executed locally from the supply's front panel as indicated in the table.  
Command headers are accepted in upper or in lower case letters although only upper case letters are used in this  
summary. The brackets < > indicate a number to be sent. Note that <ch> must specify an output channel number from 1  
through 4 as applicable. Commas or spaces are required between numbers. Spaces are optional between the command  
header and the first number. No commas are allowed between header and first number. Use semi-colons between multiple  
commands sent in one statement.  
Chapter 5 gives a complete description (including syntax) of most of the commands listed. Calibration commands are  
described in Appendix A. Two of the commands listed (ROM? and VMUX?) are described in the Service Manual.  
Table C-1. Command Summary  
Command  
ASTS? < ch >  
Description  
Queries the accumulated status (ASTS) of the specified output channel. The  
response (integer 0-255) represents the sum of the binary weights of the ASTS  
register bits (see page 74). The ASTS register is automatically set to the present  
status after being queried.  
CLR  
Returns the entire power supply (all outputs) to the power on state except that the  
supply is not unaddressed and its store/recall registers are not changed (see Clear  
Command page 73).  
CMODE <on/off>  
CMODE?  
Turns the calibration mode on or off. On/off is a 1 to turn the calibration mode  
on; a 0 turns it off (see Appendix A).  
Queries if the calibration mode is on or off. Response is either a 1 (on) or 0 (off),  
(see page 79).  
*DLY < ch >, < delay >  
Sets the reprogramming delay for the specified output channel. This delay is used  
to mask the CV, + CC, - CC, and UNR status bits from the fault register and the  
OCP function for the specified delay period (0 to 32 seconds). The delay time is  
initiated after a VSET, ISET, OUT, RCL, OVRST, or OCRST command is sent  
(see Reprogramming Delay, page 78).  
DLY? < ch >  
Queries the present reprogramming delay of the specified output channel (see  
page 78). The response can be a real number from 0.000 to 32 seconds (e.g., .450  
seconds).  
DSP < on/off >  
Turns the power supply's front panel display either on or off (see page 78). On/off  
equals 1 to turn the display on or a 0 to turn it off.  
* Indicates that the command can be executed from the front panel.  
Command Summa1ry05  
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Table C-l. Command Summary (continued)  
Description  
Command  
DSP?  
Queries the present status of the display (see page 78). Response is either a 1 (on)  
or a 0 (off).  
DSP " xxxxxxxxxxxx”  
*ERR?  
Puts the quoted string on the power supply's front panel display (see page 79).  
Only numerals, upper case letters, and spaces are allowed (12 characters max) in  
the quoted string  
Queries the present programming or hardware error (see page 79). An error code  
number is returned over the HP-IB to identify the error. In the local mode,  
pressing the ERR key will cause the appropriate error message (not the error  
code) to be displayed at the front panel. The error register is cleared after being  
read.  
*FAULT? < ch >  
Queries the fault register of the specified output channel (see Mask and Fault  
Register, page 74). A bit is set in the fault register when the corresponding bit in  
both the status and the mask registers. The response is an integer 0 to 255. The  
fault register is cleared after being read.  
ID?  
Queries the identification (model number) of the supply. Response can be HP  
6621A, HP 6622A, HP 6623A, HP 6624A, or HP 6627A, as applicable (see ID  
Query, page 79).  
IDATA < ch >, < Ilo >, < Ihi >  
Sends data to calibrate the current setting and readback circuits of the specified  
output channel. Ilo and Ihi are measured values which the supply uses to calculate  
correction constants (see Appendix A).  
IHI < ch >  
ILO <ch>  
Causes the current of the specified output channel to go to the high calibration  
point (see Appendix A).  
Causes the current of the specified output channel to go to the low calibration  
point (see Appendix A).  
IOUT? < ch >  
Queries the measured output current of the specified output channel (see page  
69). The response is a real number. The front panel display can be used to  
monitor the measured output current (and voltage) of the selected output channel.  
*ISET < ch >, < current >  
*ISET? <ch>  
Sets the current of the specified output channel (see page 69).  
Queries the present current setting of the specified output channel (see page 69).  
The response is a real number.  
*OCP < ch >, < on/off >  
Enables the overcurrent protection circuit for the specified output channel. This  
circuit, when enabled, causes the output to go to the off state when the output is in  
the + CC mode. On/off is a 1 to turn on (enable) or a 0 to turn off (disable) the  
circuit (see page 72).  
* Indicates that the command can be executed from the front panel.  
106 Command Summary  
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Table C-l. Command Summary (continued)  
Description  
Command  
OCP? < ch >  
Queries the overcurrent protection circuit on/off status for the specified output  
channel (see page 72). Response is either a 1 (on) or a 0 (off). The OCP ENBLD  
annunciator on the front panel displays the on/off status of the OCP circuit for the  
selected output.  
*OCRST < ch >  
Returns the specified output channel to the previous settings after it had been  
turned off by the overcurrent protection circuit (see page 72).  
* OUT < ch > , < on/off >  
DCPON < on/off >  
Turns the specified output channel on or off. On/off equals 1 to turn the output on  
and equals 0 to turn the output off (see page 71).  
Sets the state of the outputs at power-on. For on/off = 0, all outputs will be off  
when the power supply is turned on. For on/off = 1 all outputs will be on when the  
power supply is turned on.  
OUT? < ch >  
Queries whether the specified output channel is turned on or off (see page 71).  
The response is either 1 (on) or O (off). The front panel will display the message  
''DISABLED'' when the selected output channel is turned off.  
*OVSET < ch >, < overvoltage >  
OVCAL < ch >  
Sets the overvoltage trip point for the specified output channel (see page 71).  
Causes the specified output channel to go through the overvoltage calibration  
routine (see Appendix A).  
*OVRST < ch >  
*OVSET? < ch >  
PON < on/off >  
Attempts to reset the overvoltage crowbar circuit in the specified output channel  
(see page 71).  
Queries the present overvoltage setting of the specified output channel (see page  
71). The response is a real number.  
Enables power on service request (SRQ). On/off equals 1 causes the power supply  
to generate a service request when power is applied (see page 77). On/off equals 0  
disables the PON SRQ. The on/off setting is retained in the supply's memory  
through interruption of ac line power.  
PON?  
Queries the present state of the power on SRQ function (see page 77). The  
response is either 1 (on) or 0 (off).  
*RCL < reg >  
Recalls the voltage and current settings for all output channels from the specified  
internal register (1 to 10). These settings were previously stored using the STO  
command. RCL programs all output channels in sequential order (1, 2, 3, 4) to  
these stored settings (see page 72).  
ROM?  
Queries the revision date of the power supply's firmware. See Service Manual.  
SRQ < setting >  
Sets the causes for generating SRQ. Setting can be 0, 1, 2, or 3 as described on  
page 76.  
* Indicates that the command can be executed from the front panel.  
Command Summa1ry07  
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Table C-l. Command Summary (continued)  
Description  
Command  
SRQ?  
Queries the present setting of the reasons for issuing an SRQ (see page 76).  
Response is 0, 1, 2, or 3 that corresponds with the SRQ <setting> described  
previously.  
*STO < reg >  
STS? <ch>  
Stores the present voltage and current settings for all output channels in the  
specified register (1 to 10); see page 72. These settings can be recalled when  
desired (see RCL command).  
Queries the present status of the specified output channel. The response (integer  
0-255) represents the sum of the binary weights of the status register bits (see  
page 74).  
TEST?  
Causes the power supply to perform a self test of its HP-IB interface. The response  
Is 0 if the test passes or an integer failure code (see Test Query, page 79).  
VDATA <ch>, <Vlo>, <Vhi>  
Sends data to calibrate the voltage setting and readback circuits of the specified  
output channel. Vlo and Vhi are measured values which the supply uses to  
calculate correction constants (see Appendix A).  
VHI < ch >  
Causes the voltage of the specified output channel to go to the high calibration  
point (see Appendix A).  
VLO < ch >  
Causes the voltage of the specified output channel to go to the low calibration  
point (see Appendix A).  
VMUX? < ch >, < input >  
VOUT? < ch >  
Queries the measurement of the input (1 to 8) to the analog multiplexer on the  
specified output board. See Service Manual.  
Queries the measured output voltage of the specified output channel (see Voltage  
Programming, page 69). The response is a real number. The front panel display  
can be used to monitor the measured output voltage (and current) of the selected  
output channel.  
* VSET < ch >, < voltage >  
* VSET? < ch >  
Sets the voltage of the specified output channel (see page 69).  
Queries the present voltage setting of the specified output channel (see page 69)  
The response is a real number.  
*UNMASK < ch >, < setting >  
*UNMASK? < ch>  
Sets the bits in the mask register of the specified output channel to the setting  
(integer from 0 to 255). The mask register operates in conjunction with the status  
and fault registers (see page 74).  
Queries the present setting of the mask register of the specified output channel  
(see page 74). The response is an integer from 0 to 255.  
*Indicates that the command can be executed from the front panel.  
108 Command Summary  
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D
Error Codes and Messages  
Introduction  
This appendix describes the HP-IB error codes that can be readback to the controller and the error messages that can be  
displayed on the power supply's front panel. A brief explanation of each code and message is also given. The error codes  
and/or messages fall into three categories: Power-on Self Test Messages, responses to the ERR? query, and responses to  
the TEST? query.  
Power-On Self Test Messages  
The applicable message listed in Table D-1 is displayed on the supply's front panel if the corresponding function has  
failed the power-on self test. No error code numbers can be returned for these errors. If any of these error messages  
appear, refer to the Troubleshooting section in the Service Manual.  
Error Responses  
Table D-2 describes the error codes and messages that can be generated for various programming, calibration, and  
hardware errors. The error codes can be read back over the HP-IB in response to the ERR? query. The applicable error  
message is displayed on the supply's front panel when the ERR key is pressed. Sending the ERR? or pressing the ERR key  
clears the error.  
Test Responses  
Table D-3 describes the codes that can be read back over the HP-IB in response to the TEST? query. The TEST? query  
initiates a self test of the supply.  
Table D-l. Power-On Self Test Error Message  
Message  
TIMER FAILED  
Explanation  
The timer on the HP-IB board failed.  
8291 FAILED  
HP-IB control chip on the HP-IB board failed.  
CV DAC CH <ch>  
CC DAC CH <ch>  
OV DAC CH < ch >  
FUSE CH <ch>  
The voltage DAC on the specified output board failed.  
The current DAC on the specified output board failed.  
The overvoltage DAC on the specified output board failed.  
The return fuse on the specified output board is opened.  
The specified output board is down (no output).  
HDW ERR CH <ch>  
Error Codes and Messages  
109  
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Table D-2. ERROR Responses  
Explanation  
Error Code  
Message  
(ERR? query)  
(ERR key)  
0
NO ERROR  
INVALID CHAR  
INVALID NUM  
INVALID STR  
Indicates there are no errors.  
1
2
You sent the supply a character it did not recognize.  
The format of your number is incorrect. Check syntax (see Chapter 5).  
3 or 28  
You sent a command the supply does not understand. Resend a recognizable  
command.  
4
SYNTAX ERROR You sent a command with improper syntax. Check syntax of your command  
(see Chapter 5).  
5
6
NUMBER RANGE An out of range number was sent. Send a new number within the legal range.  
NO QUERY  
The computer addressed the supply to talk, but it did not first request data. Send  
query first and then address the supply to talk.  
7
8
DISP LENGTH  
BUFFER FULL  
Quoted string in the DSP command exceeds the display length of 12 characters.  
May occur if too many numbers are sent. Error code 4 or error code 5 are more  
likely to occur for this condition.  
9
EEPROM ERROR The EEPROM on the HP-IB board is not responding correctly to programming  
commands. An instrument failure has occurred and service is required. Refer to  
the Troubleshooting Section in the Service Manual.  
10  
11  
HARDWARE ERR An output error has occurred on an unknown output. Service is required. Refer  
to the Troubleshooting Section in the Service Manual.  
HDW ERR CH 1  
Error codes 11 through 14 refer to a specific output where an output error has  
occurred. Service is required. Refer to the Output Board Troubleshooting  
section in the Service Manual.  
12  
13  
14  
15  
HDW ERR CH 2  
HDW ERR CH 3  
HDW ERR CH 4  
Same as in error 11.  
Same as in error 11.  
Same as in error 11.  
NO MODEL NUM The supply's model number cannot be found. The HP-IB Interface board may be  
defective or the supply may require reprogramming. Refer to the  
Troubleshooting section of the Service Manual.  
16  
CAL ERROR  
An error has occurred during calibration. This may be the result of out of range  
numbers sent. If recalibration (See Appendix A) does not fix this there may be a  
hardware failure (Refer to the Troubleshooting Section in the Service Manual).  
110 Error Codes and Messages  
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Table D-2. ERROR Responses (continued)  
Explanation  
Error Code  
Message  
(ERR? query)  
(ERR key)  
17  
UNCALIBRATED Unexplained EEPROM error; possibly as the result of incorrect calibration  
procedure. Recalibrate as described in Appendix A. If the problem persists, a  
hardware failure exists (Refer to the Troubleshooting Section in the Service  
Manual).  
18  
22  
CAL LOCKED  
Calibration was attempted with the calibration jumper on the HP-IB board in  
the lockout position (See Chapter 4 in the Service Manual). Reposition the  
jumper and re-calibrate if this is desired.  
SKIP SLF TST  
The self test jumper on the HP-IB board is in the Skip Self Test Position (See  
Chapter 4 in the Service Manual). Reposition the jumper and carry out self-test  
if this is desired.  
Table D-3. TEST? Responses  
Explanation  
Response Code  
(TEST? query)  
0
No errors were detected.  
20  
The timer on the HP-IB board failed self test. Refer to the Troubleshooting Section in the Service  
Manual.  
21  
27  
The RAM on the HP-IB board failed self test. Refer to the Troubleshooting Section in the Service  
Manual. Note that if this failure occurred at power-on, it cannot be displayed on the front panel.  
The ROM on the HP-IB board failed self test. Refer to the Troubleshooting Section in the Service  
Manual. Note that if this failure occurred at power-on, it cannot be displayed on the front panel.  
Error Codes and Messages  
111  
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E
Manual Backdating  
Introduction  
The backdating information in this section applies to units that have the following serial numbers:  
HP Model 6621A serials 2611A-00101 to 01680  
HP Model 6622A serials 2611A-00101 to 02090  
HP Model 6623A serials 2611A-00101 to 02230  
HP Model 6624A serials 2550A-00101 to 06720  
HP Model 6627A serials 2751A-00101 to 00840  
Make Changes  
On page 28, replace the information in Line Voltage Conversion paragraph under steps number 2, 3, and 4 as follows:  
2. To open the line module push against the tab on the line module in the direction of the ac input socket.  
3. Remove the voltage selector card from its receptacle. This card is about one inch square and has a red notch in each of  
its four edges.  
4. To select a voltage, insert the card into its receptacle so that after the door is closed, the red notch shows through the  
window next to the voltage level you require.  
It is possible to insert the voltage selector card so that a red notch is not visible through any of the  
four windows. Do NOT operate the power supply while the selector card is in this position.  
Also on page 27, replace figure 2-3 with the following figure;  
Figure 2-3. Line Module Detail  
Manual Backdating  
113  
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ADDENDUM  
I. Generally Applicable Annotations  
Consistent with good engineering practice, leads attached to customer accessible signal/monitoring ports (such as  
the l0-pin Control Connector, the 7-pin Analog Connector, the 7-pin Digital Port/Trigger Connector, screw  
terminal Barrier Blocks, etc.) should be twisted and shielded to maintain the instrument's specified performance.  
II. CE'92 Product Specific Annotations  
When tested for radiated susceptibility as called for in EN 50082-1 per the EC EMC directive, the following  
changes in the Supplementary Characteristics of the 6621A and 6623A have been noted:  
6621A  
When subjected to radiated field strengths of 3 volts/meter in the vicinity of 90 MHz, the full scale  
programming accuracy of channel 2 increases from 31 millivolts at 20 volts output to 700 millivolts.  
The accuracy reverts to the published value of 31 millivolts when the field is reduced to 2 volts/ meter.  
When subjected to radiate field strengths of 3 volts/meter in the vicinity of 200 MHz, the full scale  
readback accuracy of channel 1 increases from 23 millivolts at 5 volts output to 100 millivolts.  
The accuracy reverts to the published value of 30 millivolts when the external field is reduced to  
2 volts/meter.  
6623A  
When subjected to radiated field strengths of 3 volts/meter in the vicinity of 160 MHz, the full scale  
programming accuracy of channel 1 increases from 31 millivolts at 20 volts output to 50 millivolts.  
The accuracy reverts to the published value of 31 millivolts when the field is reduced to 2.5 volts/ meter.  
When subjected to radiate field strengths of 3 volts/meter in the vicinity of 160 MHz. the full scale  
readback accuracy of channel 1 increases from 30 millivolts at 5 volts output to 50 millivolts.  
The accuracy reverts to the published value of 30 millivolts when the external field is reduced to 2.5  
volts/meter.  
114  
Addendum  
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HP Sales and Support Office  
For more information, call your local HP Sales Office listed in the telephone directory white pages. Ask for the Electronic  
Instruments Department.  
Or contact:  
United States:  
Europe:  
Hewlett-Packard Company  
4 Choke Cherry Road  
Rockville, MD 20850  
(301) 6704300  
European Headquarters  
Hewlett-Packard S.A.  
150, Route du Nant d'Avril  
1217 Meyrin 2  
Geneva -- Switzerland  
41/22 780-8111  
Hewlett-Packard Company  
5201 Tollview Drive  
Rolling Meadows, IL 60008  
(312) 255-9800  
Far East:  
Hewlett-Packard Asia Ltd.  
89 Queensway  
Hewlett-Packard Company  
5161 Lankershim Blvd.  
No. Hollywood, CA 91601  
(818) 505-5600  
Central, Hong Kong  
(5) 8487777  
Japan:  
Yokogawa-Hewlett-Packard Ltd.  
15-7, Nishi Shinjuku 4 Chome  
Shinjuku-ku, Tokyo 160, Japan  
(03) 5371-1351  
Hewlett-Packard Company  
2015 South Park Place  
Atlanta, GA 30339  
(404) 955-1500  
Latin America:  
Latin American Region Headquarters  
Monte Pelvoux Nbr. 111  
Lomas De Chapultepec  
11000 Mexico, D.F. Mexico  
(525) 202 0155  
Canada:  
Hewlett-Packard Ltd.  
6877 Goreway Drive  
Mississauga, Ontario L4VlM8  
(416) 678-9430  
Middle East and Africa:  
Geneva -- Switzerland  
41/22 780-7111  
Australia/New Zealand:  
Hewlett-Packard Australia Ltd.  
31-41 Joseph Street  
Blackburn, Victoria 3130  
Melbourne, Australia  
(03) 895-2895  
For all other areas:  
Hewlett-Packard Company  
Intercontinental Headquarters  
3495 Deer Creek Road  
Palo Alto, CA 94304  
U.S.A.  
HP Sales and Support Office  
115  
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