Campbell Manufacturing Modem R410 User Manual

RF400/RF410/RF415 Spread  
Spectrum Data Radio/Modem  
Revision: 3/05  
C o p y r i g h t ( c ) 2 0 0 1 - 2 0 0 5  
C a m p b e l l S c i e n t i f i c , I n c .  
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– CAUTION –  
Where an AC adapter is used, CSI recommends  
Item # 15966. This AC adapter is included as part of  
Item # 14220 RF400 Series Base Station Cable/Power Kit.  
Any other AC adapter used must have a DC output not  
exceeding 16.5 Volts measured without a load to avoid  
damage to the RF400 Series radio!  
Over-voltage damage is not  
covered by factory warranty!  
(See Power Supplies, Section 4.2 for AC adapter requirements)  
Power plug polarity  
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RF400 Series Table of Contents  
PDF viewers note: These page numbers refer to the printed version of this document. Use  
the Adobe Acrobat® bookmarks tab for links to specific sections.  
1. Introduction.................................................................1  
2. RF400 Series Specifications ......................................2  
3. Quick Start ..................................................................3  
4. System Components ..................................................7  
4.1 RF400 Series Data Radio..........................................................................7  
4.1.1 Indicator LEDs................................................................................7  
4.1.2 Setup Menu .....................................................................................8  
4.1.3 Networking......................................................................................9  
4.1.4 Error Handling and Retries ...........................................................10  
4.1.5 Received Signal Strength ..............................................................12  
4.2 Power Supplies .......................................................................................12  
4.3 Serial Cables ...........................................................................................14  
4.4 Antennas for the RF400 Series ...............................................................15  
4.5 Antenna Cables and Surge Protection.....................................................19  
4.5.1 Antenna Cables .............................................................................19  
4.5.2 Electro-static Issues.......................................................................19  
4.5.3 Antenna Surge Protector Kit .........................................................20  
5. Software Setup..........................................................21  
5.1 Point-to-Point..........................................................................................21  
5.2 Point-to-Multipoint .................................................................................21  
5.3 Example Setups.......................................................................................21  
5.3.1 Direct PC to RF400 Series Base Station Setup .............................21  
5.3.2 Remote Station Setup....................................................................23  
5.3.3 LoggerNet Configuration ..............................................................25  
5.3.4 PC208W Configuration.................................................................26  
6. Troubleshooting........................................................28  
Appendices  
A. Part 15 FCC Compliance Warning......................... A-1  
B. Setup Menu ............................................................ B-1  
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RF400 Table of Contents  
C. RF400 Series Address and Address Mask ...........C-1  
D. Advanced Setup Standby Modes .........................D-1  
E. RF400 Series Port Pin Descriptions ..................... E-1  
F. Datalogger RS-232 Port to RF400 Series Radio ... F-1  
G. Short-Haul Modems ...............................................G-1  
H. Distance vs. Antenna Gain, Terrain, and  
Other Factors.....................................................H-1  
I. Phone to RF400 Series............................................. I-1  
J. Monitor CSAT3 via RF400 Series............................J-1  
K. Pass/Fail Tests ....................................................... K-1  
L. RF400/RF415 Average Current Drain  
Calculations ....................................................... L-1  
Figures  
1. RF400......................................................................................................... 2  
2. RF400 Basic Point-to-Point Network......................................................... 5  
3. Point-to-Point LoggerNet Network Map.................................................... 6  
4. Some 900 MHz FCC Approved Antennas .......................................... 16-18  
5. Example COAX RPSMA-L Cable for Yagi or Omni Colinear................ 19  
6. Antenna Surge Protector .......................................................................... 19  
7. Enclosure with Antenna Surge Protector for RF400 ................................ 20  
8. Point-to-Multipoint System...................................................................... 26  
9. PC208W Datalogger Generic Dial String ................................................ 27  
G-1. Short-Haul Modem to RF400 Setup................................................... G-1  
I-1. LoggerNet Point-to-Multipoint Setup....................................................I-4  
K-1. Loop-back Test without Antennas...................................................... K-3  
K-2. Vertically Polarized 9 dBd 900 MHz Yagi........................................ K-5  
K-3. 3 dBd 900 MHz Collinear Omni Antenna.......................................... K-6  
Tables  
1. Lacking 12 V on CS I/O Pin 8 ................................................................... 5  
2. Standard Setup Menu................................................................................. 8  
3. 15966’s Voltage Regulation..................................................................... 14  
4. RF400 Series 12 V Power Supply Options .............................................. 14  
D-1. Advanced Setup Menu....................................................................... D-1  
H-1. 900 MHz Distance vs. Path Loss (Lp in dB) per Three Path Types .. H-6  
H-2. Path Type vs. Path Characteristics Selector....................................... H-6  
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RF400 Table of Contents  
K-1. 900 MHz Gain Antenna Test Distances..............................................K-6  
L-1. Advanced Setup Menu ........................................................................L-1  
iii  
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RF400 Table of Contents  
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iv  
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RF400 Series Spread Spectrum Data  
Radio/Modems  
1. Introduction  
This manual covers the RF400 series radios — the RF400, RF410, and RF415.  
These radios differ from one another primarily in the radio frequencies at  
which they communicate. In this manual the term “RF400” can refer to the  
“RF400 series” or to that specific model. For clarity we will sometimes add  
“900 MHz.”  
The RF400 is a 900 MHz, frequency hopping, spread spectrum, data  
radio/modem for point-to-point and point-to-multipoint communications. An  
excellent receiver combined with 100 mW transmitter power make possible,  
depending on path specifics, communication distances of 1/4 to 5 miles using  
omni-directional antennas and 10 to 20 miles using 9 dBd directional antennas  
(see Appendix H for a discussion of antenna gain and other factors affecting  
distance).  
The RF410 differs from the RF400 in that it operates at 922 MHz for regions  
such as Australia, New Zealand, and Israel. The RF410’s communication  
range is the same as that of the RF400.  
The RF415 is a 2.4 GHz version with 50 mW transmitter intended mainly for  
certain European and Asian markets. Communication distances vary from 300  
feet (indoors) to ¼ mile (100 to 400 meters) with omni-directional antennas to  
over 12 miles (19 kilometers) with gain antennas and optimal terrain.  
Users do not normally need a communications authority license for the RF400  
series configurations described in this manual including U.S. Government  
Agencies regulated by NTIA Annex K. The 900 MHz and 2.4 GHz bands are  
shared with other non-licensed services such as cordless telephones and with  
licensed services including emergency, broadcast, and air-traffic control, so  
band usage will vary from location to location as will man-made noise. Spread  
spectrum technology resists noise and interference; however, the user may  
wish to test communications on site using Quick Start (Section 3) before  
committing to its use.  
The RF400 operates from a 12 VDC power supply. The RF400’s low standby  
current modes allow it to operate at remote sites on small power budgets.  
The RF400 was designed for ease of installation. It works in many  
applications “out of the box” with default settings.  
1
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RF400 Series Spread Spectrum Data Radio/Modems  
FIGURE 1. RF400  
The RF400 has a 9-pin serial CS I/O port and a 9-pin serial DCE RS-232 port.  
The CS I/O port allows the RF400 to connect to a datalogger. The RS-232 port  
allows direct PC connection for Setup Menu access and to create a direct  
connect RF400 “base station” for point-to-point and point-to-multipoint  
communications. Where necessary, a more distant base station can be set up  
using short-haul modems or phone modems between PC and RF400.  
Base Station power is usually provided by a wall adapter. For a remote RF400,  
power is normally provided by the datalogger.  
A PC running LoggerNet, PC208W, or PC208 is used for data collection,  
program transfer, and other datalogger supported functions. The PakOS  
software or a terminal program is used to configure the RF400 radios.  
2. RF400 Series Specifications  
POWER  
Voltage  
Current  
9 – 18 VDC  
75 mA typical during transmit  
24 mA typical receiving a signal  
(36 mA for RF415)  
2
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RF400 Series Spread Spectrum Data Radio/Modems  
Quiescent Current in Standby Modes*  
Avg. Quiescent  
Current (mA)  
Advanced Setup  
Standby Mode  
Standard  
Setup  
RF400/  
RF410  
24.0  
3.9  
2.0  
1.1  
RF415  
33.0  
5.5  
2.8  
1.5  
0 (no duty cycling)  
1
2
3
3
4
5
6
7
0.64  
0.40  
0.84  
0.50  
4
* Not receiving a signal nor transmitting  
PHYSICAL  
Size  
Weight  
4.75 x 2.75 x 1.3 inches (12.1 x 7.0 x 3.3 cm)  
0.5 lbs (225 g)  
Operating temp. range –25°C to +50°C  
Humidity 0 to 95% RH, non-condensing  
RF/INTERFACE  
Transceiver modules  
MaxStream  
RF400 – 9XStream XO9-009  
RF410 – 9XStream XH9-009  
RF415 – 24XStream X24-009  
RF400 – 910.5 to 917.7 MHz  
RF410 – 920.0 to 927.2 MHz  
RF415 – 2.45015 to 2.45975 GHz  
1) CS I/O 9 pin  
Frequency bands  
Interface ports  
2) RS-232 9-pin (4 wire: Tx, Rx, CTS, GND)  
38.4 K, 19.2 K, 9600, 4800, 1200 bps  
Frequency hopping spread spectrum (FHSS), 25  
hop channels, 7 hopping sequences, direct FM  
frequency control  
I/O Data Rates  
Mode  
Channel capacity  
Transmitter output  
Receiver sensitivity  
65,535 addresses  
100 mW nominal (50 mW RF415)  
110 dBm at 10-4 bit error rate  
(104 dBm for RF415)  
50 , unbalanced (SMA male connector)  
70 dB at pager and cellular phone frequencies  
(RF400/RF410)  
Antenna impedance  
Interference reject  
RF packet size  
Error handling  
up to 64 bytes, half-duplex  
RF packet CRC failure detection/rejection or  
configurable retry levels  
3. Quick Start  
This section is intended to serve as a “primer” enabling you to quickly build a  
simple system and see how it operates. This section describes in four steps  
how to set up a pair of RF400s in a direct connect, point-to-point network. We  
recommend that you do this before undertaking field installation. For  
additional help on point-to-point networks and for help on creating point-to-  
multipoint networks, refer to Software Setup Section 5.  
3
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RF400 Series Spread Spectrum Data Radio/Modems  
For this system you will need the following hardware or the equivalent:  
1. Two RF400s  
2. Two RF400 antennas  
3. AC adapter (Item # 15966 or part of kit #14220)  
4. Serial cable (6 ft.) for PC COM port to RF400 RS-232 port (Item # 10873  
or part of Item # 14220)  
5. SC12 cable (included with RF400)  
6. Datalogger (CR10X, CR510, or CR23X)  
7. Field Power Cable (Item # 14291) if datalogger or wiring panel doesn’t  
have 12 V on pin 8 of CS I/O port  
You will also need:  
1. An IBMTM compatible PC with one available COM port  
2. LoggerNet or PC208W installed  
Step 1 – Set Up Base RF400  
a. Connect an antenna (or antenna cable with yagi or omni directional  
antenna attached) to the RF400 antenna jack. Any RF400 antenna will  
work at close range in any orientation. The main objective is to provide  
an antenna. If you should transmit without an antenna attached, there will  
be no equipment damage as the transmitter is protected against load  
mismatch. The separation between the base RF400 antenna and the  
remote RF400 antenna can be any convenient distance.  
b. Connect 6 ft. serial cable from PC COM port to base RF400 RS-232 port.  
c. Plug AC adapter into AC outlet and plug barrel connector into base  
RF400 “DC Pwr” jack. You will see the red “Pwr/TX” LED light  
immediately followed by the green RX LED in about 5 seconds. The  
green LED goes off after a second and the red after ten seconds indicating  
a successful power-up. The red LED then begins to flash on and off. The  
red LED flashes once every half second in the default “< 4 mA, ½ sec  
Cycle” standby mode as the RF400 wakes up briefly and listens for RF  
transmissions with an average current consumption less than 4 mA.  
d. Use default settings of RF400.  
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RF400 Series Spread Spectrum Data Radio/Modems  
AC Adapter  
TECHNOLOGIES INC.  
HICKSVILLE, NEW YORK  
apx  
CLASS  
MODEL NO:  
INPUT  
OUTPUT  
2
TRANSFORMER  
AP2105W  
:
120VAC 60Hz 20W  
:
12VDC  
LISTED  
1.0A  
2H56  
E144634  
U
U
L
L
R
R
MADE IN CHINA  
RS-232  
DC  
Pwr  
Logan, Utah  
RS232  
RF400  
Spread Spectrum Radio  
CS I/O  
This device contains transmitter module:  
FCC ID: OUR-9XTREAM  
The enclosed device complies with Part 15 of the  
FCC Rules.  
Program  
Antenna  
Operation is subject to the following two conditions:  
(1) This device may not cause harmful interference,  
and (2) this device must accept any intererence  
received, including interference that may cause  
undesired operation.  
Pwr/TX  
RX  
14320  
Serial  
#
MADE IN USA  
LoggerNet or PC208W  
Datalogger CS I/O  
Logan, Utah  
G
12V  
POWER  
IN  
SW 12V CTRL  
SW 12V  
G
CS I/O  
SE  
DIFF  
7
8
L
9
10  
L
11 12  
6
4
5
G
G
H
AG  
H
AG  
H
L
AG E3 AG  
G
G
5V 5V  
G
DC  
Logan, Utah  
Pwr  
CR10X WIRING PANEL  
MADE IN USA  
CS I/O  
RS232  
RF400  
Spread Spectrum Radio  
CS I/O  
SE  
DIFF  
1
2
L
3
4
L
5
6
This device contains transmitter module:  
FCC ID: OUR-9XTREAM  
SDM  
1
2
3
The enclosed device complies with Part 15 of the  
FCC Rules.  
G
G
H
AG  
H
AG  
H
L
AG E1 AG E2  
G
P1  
G
P2  
G
C8 C7 C6 C5 C4 C3 C2 C1  
G
12V 12V  
Program  
Antenna  
Operation is subject to the following two conditions:  
(1) This device may not cause harmful interference,  
and (2) this device must accept any intererence  
received, including interference that may cause  
undesired operation.  
EARTH  
GROUND  
Pwr/TX  
RX  
WIRING  
PANEL NO.  
14320  
Serial  
#
MADE IN USA  
FIGURE 2. RF400 Basic Point-to-Point Network  
Step 2 – Set Up Remote RF400  
a. Connect an antenna (or antenna cable with yagi or omni directional  
antenna attached) to the RF400 antenna jack. The separation between the  
base RF400 antenna and the remote RF400 antenna can be any convenient  
distance.  
b. Connect SC12 serial cable from datalogger CS I/O port to remote RF400  
CS I/O port. Current datalogger/wiring panel CS I/O ports apply power to  
the remote RF400.  
With older dataloggers lacking 12 V on pin 8 (see Table 1), you can  
power the RF400 using a Field Power Cable (see above hardware list)  
between the datalogger’s 12 V (output) terminals and the RF400’s “DC  
Pwr” jack.  
TABLE 1. Lacking 12 V on CS I/O Pin 8  
EQUIPMENT  
CR500  
SERIAL NUMBER  
< 1765  
CR7 700X Bd.  
21X  
< 2779  
< 13443  
CR10 Wiring Panels  
PS512M Power Supply  
All (black, gray, silver)  
< 1712  
When you connect power to the RF400 (through the SC12 cable or the  
optional Field Power Cable) you should see the power-up sequence of red  
and green LEDs described in Step 1 (assuming datalogger is powered).  
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RF400 Series Spread Spectrum Data Radio/Modems  
Current dataloggers and wiring panels (not mentioned in Table 1) provide  
12 V on pin 8. For older products not listed, check for 12 V between CS  
I/O connector pin 8 and pin 2 (GND) or contact Campbell Scientific.  
c. Use default settings of RF400.  
Step 3 – LoggerNet/PC208W Set-up  
a. The next step is to run LoggerNet/PC208W and configure it to connect to  
the datalogger via the RF400 point-to-point network you have set up. The  
RF400 in a point-to-point network can operate transparent to  
LoggerNet/PC208W. Simply add a datalogger to a COM port in the  
Device Map.  
FIGURE 3. Point-to-Point LoggerNet Network Map  
b. Set the Maximum Baud Rate for 9600 baud which is the rate at which the  
RF400 communicates by default. The datalogger “Extra Response Time”  
can be left at 0.  
For safety, maintain 20 cm (8 inches) distance between  
antenna and any nearby persons while RF400 is  
transmitting.  
CAUTION  
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RF400 Series Spread Spectrum Data Radio/Modems  
Auto Sense  
The RF400 has a default feature called “Auto Sense” that automatically  
configures certain RF400 settings. When you connect an RF400 to a  
datalogger (CS I/O port to CS I/O port) the RF400 detects the presence of the  
datalogger and makes its CS I/O port the active port. When you are not  
connected to a datalogger’s CS I/O port, Auto Sense detects that and  
configures its RS-232 port as the active port and configures certain other  
settings so it can serve as a base RF400.  
For point-to-point networks Auto Sense and default settings take care of  
everything. An exception to this is where you have a neighboring network that  
is also using the default RF400 settings. In this case, refer to Software Setup  
Section 5 and change your RF400s to a hopping sequence different than the  
default settings of “0” (zero). For this point-to-point network, configure both  
RF400s the same.  
Radio Address  
Each RF400 has a “Radio Address” that can be changed by the user. In order  
for two RF400s to communicate, their radio addresses must be set to the same  
number. The RF400’s factory default radio address is “0” (zero) so a pair of  
RF400s will be able to communicate out of the box (their network addresses  
and hopping sequences are also “0” (zero) by default). See Section 4.1.3.1 and  
Section 5 (Software Setup) for more details.  
Step 4 – Connect  
You are now ready to Connect to your datalogger using the  
LoggerNet/PC208W Connect screen. After you connect, notice the flashing of  
the green LEDs on both RF400s. This indicates that RF packets with the same  
hopping sequence are being received by the RF400s. The red LEDs light solid  
while the connection lasts. When you Disconnect, the red LEDs remain on for  
five seconds, which is the default setting of the “Time of Inactivity to Sleep.”  
Datalogger program transfer and data collection are now possible. Refer to  
Appendix H for a treatment of communication distance vs. factors in the RF  
path.  
4. System Components  
4.1 RF400 Series Data Radios  
4.1.1 Indicator LEDs  
The RF400 has a red LED labeled “Pwr/TX” and a green LED labeled “RX.”  
When 12V power is applied the red LED lights for ten seconds. About 5  
seconds after power-up the green LED lights for a second. Ten seconds after  
power-up the selected standby mode begins to control the red LED. The red  
LED lights to indicate when the receiver is actively listening. When the  
receiver detects RF traffic (header or data with the same hopping sequence),  
the red LED will light steadily. When the RF400 is transmitting, the red LED  
will pulse OFF as the RF packets are transmitted (it will not be on solid).  
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RF400 Series Spread Spectrum Data Radio/Modems  
Green LED activity indicates that there is an RF signal being received whose  
hopping sequence corresponds to the configured hopping sequence of the  
RF400. This does not necessarily mean that the network/radio address of the  
received packet corresponds with that of the RF400 (where a neighboring  
network exists it is a good idea to choose a unique hopping sequence).  
4.1.2 Setup Menu  
The RF400 has a built-in Setup Menu for configuring active interface, RS-232  
properties, network/radio addresses, hopping sequence, power saving (standby)  
modes, address masks, and other parameters. The Setup Menu is accessed by  
connecting the radio’s RS-232 port to a PC running a terminal program such as  
Hyper Terminal TM or ProcommTM (always 9600 baud, 8-N-1) and pressing the  
“Program” button on the RF400 for one second. Changed settings are saved in  
flash memory by selecting menu item “5” as you exit the Setup Menu. If left  
idle, the Setup Menu will time out 60 seconds after the last received character  
and exit without saving any parameter changes with the message “Config  
Timeout.” A datalogger can remain connected to the CS I/O port while setting  
RF400 parameters on the RS-232 port, although CS I/O communications  
would be inactive until exiting the Setup Menu.  
4.1.2.1 Auto Sense  
The factory default setting for Active Interface is “Auto Sense.” It is designed  
to automatically configure an RF400’s port and radio address mask for  
common user situations. When selected, Auto Sense determines whether or  
not a datalogger (or PS512M null modem) is connected to the RF400 by  
monitoring for 5 V on CS I/O pin 1. If 5 V is present, Auto Sense selects the  
RF400’s CS I/O port and a radio address mask appropriate for a remote station.  
Not finding 5 V on CS I/O pin 1, Auto Sense selects the RS-232 port and a  
radio address mask appropriate for a base station (see Section 4.1.3.1 and  
Appendix C for more information on radio address masks).  
4.1.2.2 Standby Modes  
The RF400’s average idle current can be set with the following Standby Modes  
(default setting shaded):  
TABLE 2. Standard Setup Menu  
Standby  
Mode  
Menu  
Wake-up  
Interval  
(red LED  
Advanced  
Standby  
Mode  
Avg.  
Receive  
Current  
Maximum  
Response  
Delay*  
Duty  
Cycle  
Selection  
flash interval)  
100%  
17%  
4%  
1
2
3
4
0
4
6
7
< 24 mA  
< 4 mA  
< 2 mA  
< .4 mA  
0 sec (constant)  
½ sec  
100 mS  
600 mS  
1 sec  
1100 mS  
8100 mS  
2%  
8 sec  
*Maximum time it takes to get an RF Packet sent and for the other RF400 to respond.  
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RF400 Series Spread Spectrum Data Radio/Modems  
The Standard Setup standby modes automatically configure:  
Time of Inactivity to Sleep  
Time of Inactivity to Long Header  
Long Header Time  
The default mode is the Standard Setup menu selection “2” for “< 4 mA and ½  
sec Cycle.” There are standby modes available in addition to those in the  
above table. They can be accessed in the Advanced Setup menu; however, if  
you configure one of those, it will be necessary to also configure each of the  
three bulleted parameters above. In any case, be sure to select the same  
Standby Mode for all of the RF400s in the network. For more details see  
Appendix D.  
4.1.3 Networking  
The RF400 acts as a transparent radio link. Each radio has a configurable  
network address, radio address, and hopping sequence, and only radios that  
have the same network address, radio address, and hopping sequence will  
receive each other’s transmissions. The exception to this is that an RF400 base  
station can receive packets from multiple remote station’s if the base station’s  
Radio Address Mask is other than the maximum allowed number of 3ffh  
(hexadecimal). When Auto Sense is selected, it sets the Radio Address Mask  
to 0h if no 5 V is detected on its CS I/O port pin 1 (see Auto Sense Section  
4.1.2.1).  
4.1.3.1 Address and Address Mask  
For simple point-to-point installations the RF400’s default settings (including  
address settings) should work unless there is a neighboring network which uses  
default settings. In that case the network address and, preferably, your hopping  
sequence should be set to different numbers than the neighboring network uses.  
A different network number is sufficient but a different hopping sequence  
(there are 7 available) will result in fewer retries.  
The RF400 has a two-part address. When the RF400’s Radio Address is  
appended to its Network Address you have the complete 16-bit address.  
Network Address  
(0 – 63)  
Radio Address  
(0 – 1023)  
decimal  
(0 - 11,1111)  
(3f)  
(0 - 11,1111,1111)  
(3ff)  
binary  
hexadecimal  
When an incoming packet arrives from another RF400 using the same hopping  
sequence, the receiving RF400 compares the packet header’s 16-bit address to  
its own 16-bit address. If they match, and there are no packet errors, the  
receiving RF400 sends the packet data to the configured active port (CS I/O or  
RS-232). This assumes a receiving RF400 address mask of ffffh. If other than  
ffffh (1111,1111,1111,1111 binary), only those address bits that correspond to  
address mask “1” bits will be used in the comparison. See Appendix C for  
details.  
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RF400 Series Spread Spectrum Data Radio/Modems  
4.1.3.2 ATDT Command Mode  
This mode is not required for basic point-to-point communication.  
For point-to-multipoint operation the RF400 can temporarily be put into AT  
Command Mode by sending a string of three ASCII characters. The default  
sequence to enter AT Command mode is:  
1. No characters sent for one second (before command character)  
2. “+++”characters sent (default command mode entry character)  
3. No characters sent for one second (after command mode character)  
4. RF400 responds by sending “OK” <CR>  
The AT Command mode characters are sent by PC208W along with other  
commands to change the base RF400’s Radio Address to talk to the desired  
remote RF400 (see point-to-multipoint example in Software Setup Section).  
4.1.3.3 Combination Mode Communications  
Besides the “direct” to PC communications described in the Quick Start and  
Installation sections, it is possible to combine methods in datalogger  
communications. Some examples:  
Phone to RF400: PC to external modem to COM210 w/PS512M to RF400  
to datalogger (see Appendix I)  
Short Haul modem to RF400: PC to short haul modems to RF400s to  
datalogger (see Appendix G)  
Network to RF400: PC to Internet to NL100 to RF400 to datalogger (use  
LoggerNet IPPort or PC208W socket, remote IP address, port number)  
4.1.4 Error Handling and Retries  
In the RF module received packets are analyzed for data corruption with an  
embedded CRC. The RF400 rejects a received packet (doesn’t send it out a  
port) if the packet’s header address fails to match the RF400 address, if an RF  
module receive error is detected, or if the RF packet’s CRC test fails.  
In early RF400s no notification was given when a packet was rejected, and  
there were no retries nor guaranteed delivery of packets. Retries were handled  
by protocols in LoggerNet and PC208W. Starting with SW Version 6.420 the  
RF400 series radios themselves are capable of doing retries in a network with  
an unlimited number of array-based stations or in a network consisting of two  
PakBus stations.  
4.1.4.1 Standard Retry Levels  
There are four pre-programmed Retry Levels available in the Standard Setup  
menu. All RF400s in the network should be configured for the same Retry  
Level. The default setting is “None.” The standard settings should satisfy  
most application requirements. Further choices are available in the Advanced  
Setup menu. All radios in a network should have the same “Maximum  
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Retries”, “Time-slots for Random Retry”, and “Bytes Transmitted before  
Delay” settings.  
STANDARD RETRY LEVELS  
Retry  
Level  
Maximum  
Retries  
Time-Slots for  
Random Retry  
Bytes Transmitted  
Before Delay  
Menu  
1
2
3
4
None  
Low  
0
3
0
2
3
5
65535  
1000  
1000  
1000  
Medium  
High  
6
10  
4.1.4.2 Number of Retries  
This setting specifies the maximum number of times an RF400 will re-send a  
packet failing to get an ACK response. The default setting is zero which  
inactivates retries. The allowable range is 0 to 255. Entering a number greater  
than zero activates retries. A receiving RF400 responds to the sending radio  
with an ACK packet for every RF packet that it receives, addressed to it, that  
has a valid CRC.  
4.1.4.3 Number of Time Slots for Random Retry  
This setting is active when the Number of Retries is greater than zero. It  
specifies the number of 38 ms time slots to create among which to randomly  
re-send a packet which has failed to get an ACK packet response. The  
allowable range is 0 to 255.  
If packets are failing because of periodic noise or signals, specifying more time  
slots for random retries will improve the chances for successful retry packet  
delivery. Increasing the number of time slots, however, results in longer  
average retry delays which could lower data throughput.  
4.1.4.4 Number of Bytes Transmitted before Delay  
This feature prevents an RF400 Series radio which has lots of data to transfer  
from tying up a network until it is finished. The range of settings is 1 to 65535.  
The default value is 65535 (bytes). This setting forces an RF400 to pause long  
enough, after sending the specified number of bytes, for another radio to send  
some data.  
4.1.4.5 Sync Timer Setting  
This setting determines how often sent packets will include hop  
synchronization information in the headers. The default setting is 0 which  
specifies that every packet will contain hop sync information. A value greater  
than zero specifies the interval at which a packet will contain hop sync  
information. The allowable range is 0 to 255 in units of 100 ms. All radios in  
the network should have the same Sync Timer Setting.  
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For example, if you input a value of 50, then packets with hop sync info will be  
sent out every 5 seconds improving (shortening) the response time of a  
transmit/response sequence. Even though this shortens the time required to  
send x amount of data, the throughput is still determined by the CS I/O or  
RS-232 port baud rate setting.  
4.1.4.6 Number of Retry Failures  
This reading is available in Setup Menu/Advanced Setup/Radio  
Parameters/Radio Diagnostics. It indicates the number of times that the RF400  
has re-transmitted the specified Number of Retries but failed to get an ACK  
packet from the receiving radio. For example, if the Number of Retries is set  
to 3, the transmitting radio will send the same packet up to 3 times; each time  
looking for an ACK packet back from the receiving radio. If it does not  
receive an ACK packet after sending the packet 3 times, the transmitting radio  
will increment its Number of Retry Failures count. If a radio is configured to  
do retries, it will produce an ACK packet for every RF packet that it receives,  
addressed to it, that has a valid CRC. If 0 retries are configured, the receiving  
RF400 will simply throw away any packet that fails the CRC. This reading is  
cleared upon exiting Setup Menu or cycling RF400 12 V power.  
4.1.5 Received Signal Strength  
Beginning with SW Version 6.420 the RF400 series radios provide a means of  
knowing the signal strength of the last packet received, addressed to it, that had  
a valid CRC. To see this reading enter the RF400’s Setup Menu /Advanced  
Setup/Radio Parameters/Radio Diagnostics menu. RSS readings are cleared  
upon exiting the Setup Menu or cycling the RF400’s 12 Volt power.  
The RSS reading is a relative signal level indication expressed in dB (decibels).  
Readings may vary up to 10 dB from radio to radio for a given received signal  
level. The weakest signal reading is around 25 dB and the strongest signal  
reading is near 86 dB. Although the RSS readings are not absolute, they will  
be of value in such activities as:  
determining the optimal direction to aim a yagi antenna  
seeing the effects of antenna height, location  
trying alternate (reflective) paths  
seeing the effect of seasonal tree leaves  
4.2 Power Supplies  
The typical base station RF400 connected directly to a PC uses a 120 VAC  
wall adapter to supply 12 VDC power. You can order the optional Base  
Cable/Power Kit (CSI Item # 14220) to obtain the wall adapter with 6 ft. serial  
cable. In a phone to RF400 base station configuration (without datalogger) the  
RF400 can obtain power from a PS512M null modem.  
The typical remote RF400 will be connected to a datalogger CS I/O port and  
get its 12 V power from that. If your datalogger is an earlier unit without 12 V  
on CS I/O pin 8 (see Table 1), there is an optional Field Power Cable available  
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RF400 Series Spread Spectrum Data Radio/Modems  
(CSI Item # 14291) with tinned leads to connect to power at the datalogger 12  
V output terminals and barrel connector to plug into the RF400’s “DC Pwr”  
jack. If 120 VAC is available at the site, the 120 VAC adapter alone (CSI Item  
# 15966) is an option.  
A 12 V supply may connect to either the RF400’s “DC Pwr” jack or CS I/O pin  
8 (or both, since there is diode isolation between supply inputs). The 12 V  
supply inputs are diode protected against the application of reverse polarity  
power.  
There are many AC adapters available with barrel  
connectors (plugs) that will fit the RF400. Some of these  
(including the CSI AC adapter Item # 272) will cause  
immediate damage if plugged into the RF400 even briefly.  
It is also possible to damage the RF400 with an AC  
adapter labeled as low as “12 VDC” because it may output  
an open-circuit (no current drain) voltage exceeding the  
maximum. The very low quiescent current (170 uA) of the  
RF400 in its default and other standby modes allows the  
supply voltage to rise at times virtually to its open-circuit  
level.  
CAUTION  
The RF400 series radio will sustain damage if  
the DC Pwr jack voltage ever exceeds 18  
Volts!  
120 VAC line voltages vary from location to location and  
from time to time so observing a 16.5 VDC maximum is  
wise. Unconsidered AC adapter selection raises the  
specter of over-voltage damage to the RF400 and non-  
warranty repairs!  
There are several things to consider. Beware of AC  
adapters outputting an AC voltage. An AC adapter can  
output the correct voltage but the wrong polarity. The  
center conductor of the barrel connector must be positive  
(+). The AC adapter must also be capable of supplying the  
instantaneous peak currents demanded by the RF400  
transmitter. The best approach is to obtain the AC adapter  
recommended by CSI (Item #15966 or the RF400 Base  
Station Cable/Power Kit Item # 14220 which contains it). If  
this is not possible, obtain an AC adapter that matches the  
voltage vs. current characteristics shown below.  
To be sure that the candidate AC adapter’s “no load” voltage is  
below the 16.5 VDC recommended maximum, measure the  
output with a DC voltmeter while the AC adapter is plugged into  
the outlet but not powering anything.  
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CSI AC adapter Item # 15966 voltage regulation (typical) while plugged into  
an AC outlet delivering 120.0 VAC:  
TABLE 3. 15966’s Voltage Regulation  
Current Drain  
(mA)  
0 (no load)  
Resistive Load  
(Ohms)  
(open circuit)  
100 Ω  
AC Adapter Output  
(Volts)  
12.22  
12.20  
12.11  
122  
807  
15 Ω  
The voltage regulation of the 15966 is exceptionally good.  
Power connector polarity: inner conductor positive (+)  
TABLE 4. RF400 Series 12 V Power Supply Options  
Network  
Role  
RF400  
Connection  
Direct to PC  
Options — CSI Item #  
AC Adapter 14220 (with serial cable)  
15966 (adapter only)  
If 12V on pin 8*  
Base  
CS I/O Port**  
Datalogger  
If no 12V on pin 8  
Field Power Cable 14291  
AC Adapter 14220 (in base cable/power kit)  
15966 (adapter only)  
PS512M  
PS512M null-modem connectors  
If 12V on pin 8*  
CS I/O Port  
Remote  
Datalogger  
If no 12V on pin 8  
Field Power Cable 14291  
AC Adapter 14220 (in base cable/power kit)  
15966 (adapter only)  
* See Quick Start Section 3, Step 2, Table 1  
** If powering RF400 from CS I/O port but communicating via RS-232 port,  
be sure to select “RS-232” as the Active Interface so CS I/O port is not auto  
selected by Auto Sense.  
4.3 Serial Cables  
In an RF400 base station, a straight-through DB9M/DB9F RS-232 cable will  
connect from the RF400’s RS-232 port to the PC COM port. This cable is part  
of the optional Base Cable/Power Kit (CSI Item # 14220).  
A remote RF400 normally uses the included SC12 cable to connect the  
RF400’s CS I/O port to the datalogger’s CS I/O port.  
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RF400 Series Spread Spectrum Data Radio/Modems  
A remote RF400 can be connected to a CR23X’s or CR5000’s RS-232 port  
with a null modem DB9M/DB9M cable (CSI Item # 14392). See Appendix F  
for details on power supply.  
4.4 Antennas for the RF400 Series  
Several antennas are offered to satisfy the needs for various base station and  
remote station requirements. These antennas have been tested at an authorized  
FCC open-field test site and are certified to be in compliance with FCC  
emissions limits. All antennas (or antenna cables) have an SMA female  
connector for connection to the RF400. The use of an unauthorized antenna  
could cause transmitted field strengths in excess of FCC rules, interfere with  
licensed services, and result in FCC sanctions against user.  
An FCC authorized antenna is a REQUIRED component. You  
must pick one of the antennas listed below.  
NOTE  
CSI Item Number  
14310  
Description  
0 dBd ANTENNA, 900 MHZ, OMNI ¼ WAVE WHIP,  
RPSMA STRAIGHT, LINX, 3.2 inches long.  
14204  
14221  
0 dBd ANTENNA, 900 MHZ, OMNI ½ WAVE WHIP,  
RPSMA RT ANGLE, ASTRON, 6.75 inches long.  
3 dBd ANTENNA, 900 MHZ, OMNI COLLINEAR,  
ANTENEX FG9023, 24 inches tall, W/FM2 MOUNTS,  
fits 1 in. to 2 in. O.D. mast (requires COAX RPSMA-L  
or COAX NTN-L)  
15970  
14205  
1 dBd ANTENNA, 900 MHZ, INDOOR OMNI ½  
WAVE DIPOLE, 10 ft. cable with SMA connector to fit  
RF400 Series, window or wall mounted by sticky back,  
4 inches wide.  
6 dBd ANTENNA, 900 MHZ, YAGI, LARSEN  
YA6900 TYPE N-F, boom length 17.25 inches, longest  
element 7.25 inches, W/MOUNTS, fits 1 in. to 2 in.  
O.D. mast (requires COAX RPSMA-L or COAX NTN-  
L)  
14201  
9 dBd ANTENNA, 900 MHZ, YAGI, MAXRAD  
BMOY8905 TYPE N-F, boom length 21.4 inches,  
longest element 6.4 inches, W/MOUNTS, fits 1 in. to 2  
in. O.D. mast (requires COAX RPSMA-L or COAX  
NTN-L)  
16005  
16755  
0 dBd ANTENNA, 2.4 GHz, OMNI ½ WAVE WHIP,  
RPSMA RT ANGLE, LINX ANT-2.4-CW-RCT-RP,  
4.5 inches long.  
13 dBd ANTENNA, 2.4 GHz, ENCLOSED YAGI,  
allows vertical or horizontal polarization, MAXRAD  
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WISP24015PTNF, boom length 17 inches, diameter 3  
inches, W/ END MOUNT to fit 1 to 2 in. O.D. mast  
(requires either (1) COAX RPSMA-L for short runs or  
(2) COAX NTN-L with Antenna Surge Protector Kit)  
COAX RPSMA-L  
COAX NTN-L  
14462  
LMR 195 ANTENNA CABLE, REVERSE POLARITY  
SMA TO TYPE N MALE  
RG8 ANTENNA CABLE, TYPE N MALE TO TYPE  
N MALE CONNECTORS, REQUIRES 14462  
ANTENNA SURGE PROTECTOR KIT  
FCC OET Bulletin No. 63 (October 1993)  
Changing the antenna on a transmitter can significantly increase, or decrease,  
the strength of the signal that is ultimately transmitted. Except for cable  
locating equipment, the standards in Part 15 are not based solely on output  
power but also take into account the antenna characteristics. Thus, a low  
power transmitter that complies with the technical standards in Part 15 with a  
particular antenna attached can exceed the Part 15 standards if a different  
antenna is attached. Should this happen it could pose a serious interference  
problem to authorized radio communications such as emergency, broadcast,  
and air-traffic control communications.  
In order to comply with the FCC RF exposure  
requirements, the RF400 series may be used only with  
approved antennas that have been tested with this radio  
and a minimum separation distance of 20 cm must be  
maintained from the antenna to any nearby persons.  
CAUTION  
Read Appendix A of this manual for important FCC information.  
ITEM # 14310 900 MHZ OMNI ¼ WAVE WHIP 0 dBd  
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RF400 Series Spread Spectrum Data Radio/Modems  
ITEM # 14204 900 MHZ OMNI ½ WAVE WHIP 0 dBd  
ITEM # 14201 900 MHZ YAGI 9 dBd w/MOUNTS  
ITEM #14205 900 MHz YAGI 6 dBd w/MOUNTS  
ITEM # 14221 900 MHZ OMNI COLLINEAR 3 dBd w/MOUNTS  
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RF400 Series Spread Spectrum Data Radio/Modems  
ITEM #15970 900 MHZ Indoor OMNI 1 dBd Window/Wall Mounted  
ITEM #16005 2.4 GHz OMNI HALF WAVE WHIP 0 dBd  
ITEM #16755 2.4 GHz ENCLOSED YAGI, 13 dBd w/MOUNTS  
FIGURE 4. Some FCC Approved Antennas  
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FIGURE 5. Example COAX RPSMA-L Cable for Yagi or Omni Colinear  
FIGURE 6. Antenna Surge Protector  
4.5 Antenna Cables and Surge Protection  
4.5.1 Antenna Cables  
The 14201, 14203, 14205, 14221, and 16755 antennas require an antenna  
cable; either (1) the COAX RPSMA or (2) the COAX NTN with surge  
protector. Indoor omni-directional antennas are either supplied with an  
appropriate cable or connect directly to the RF400 series radio.  
4.5.2 Electro-static Issues  
Many RF400 series installations are out of doors and therefore susceptible to  
lightning damage, especially via the antenna system. Also, depending on  
climate and location, electro-statically charged wind can damage sensitive  
electronics if sufficient electric charge is allowed to accumulate on the antenna  
and cable. To protect against this CSI offers the Item # 14462 Antenna Surge  
Protection Kit.  
The COAX NTN-L cable is a low-loss RG8 coaxial cable that requires the  
14462 surge protector in order to connect to an RF400 series radio. The RG8 /  
Antenna Surge Protector are recommended in preference to the COAX  
RPSMA in the following applications:  
When the antenna cable length exceeds 10 feet  
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RF400 Series Spread Spectrum Data Radio/Modems  
When use of COAX RPSMA would result in too much signal loss (see  
page H-3)  
When the RF400 series radio will be used in an environment susceptible to  
lightning or electro-static buildup  
4.5.3 Antenna Surge Protector Kit  
The Surge Protector Kit for the RF400 series radios includes the following:  
Polyphaser protector  
18 inches of COAX RPSMA to connect ‘tail end’ of surge protector to  
RF400  
Ground wire lead  
Screw and grommet to secure ground wire and polyphaser to backplate of  
enclosure  
The surge protector has female type N connectors on both ends; one for  
connection to the COAX NTN-L cable and the other for connection to the 18  
inch length of COAX RPSMA cable included in the kit. The COAX RPSMA  
cable is an LMR195 type that terminates in a type N Male connector on the  
‘antenna end’ and a Reverse Polarity SMA (RPSMA) connector on the RF400  
end.  
FIGURE 7. Enclosure with Antenna Surge Protector for RF400  
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5. Software Setup  
5.1 Point-to-point  
Set-up parameters are configured the same for the two RF400s. The RF400  
defaults to radio address “0” (zero) which works for many applications.  
See Section 4.2 for power supply options.  
5.2 Point-to-multipoint  
The radio addresses for a base RF400 and its remotes are typically configured  
to be different from one another. The base RF400 radio address might be 0,  
the first remote’s radio address might be 1, and the second remote’s radio  
address might be 2, etc.  
For the base RF400 to be able to transmit to a remote RF400, the base’s Radio  
Address must be temporarily changed to match that of the remote. The address  
change is done by putting the base RF400 into command mode, changing the  
address with an ATDT command, and then putting it back into data mode with  
the ATCN command. You can accomplish this by entering these commands in  
the Generic Dial String in PC208W’s datalogger Setup Connections screen (see  
example below).  
See Section 4.2 for power supply options.  
5.3 Example Setups  
The following procedures explain how to build a basic RF400 point-to-point  
network and a point-to-multipoint network with base station connected directly  
to the PC COM port. The PC should be running LoggerNet or PC208W. The  
remote station can consist of an RF400 connected to a datalogger.  
5.3.1 Direct PC to RF400 Series Base Station Setup  
1. Connect the RF400’s RS-232 port to a PC COM port using a straight  
through serial cable Item # 10873, or equivalent. Use a 25-pin to 9-pin  
adapter if necessary. This hardware configuration can serve (1) to do the  
set-up of the RF400, and (2) for base station communications with  
datalogger(s) in point-to-point or point-to-multipoint networks.  
2. Run Hyper TerminalTM, ProcommTM, or other terminal emulator program.  
a. Baud rate: 9600, 8-N-1  
c. Flow control: none  
d. Emulation: TTY  
e. ASCII (raw)  
f. COM1 (direct connect)  
3. Power up RF400 (wait two seconds) and press “Program” button for one  
second to see the following display.  
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Main Menu  
SW Version 6.425 (for example)  
(1) Standard Setup  
(2) Advanced Setup  
(3) Restore Defaults  
(4) Show All Current and Default Settings  
(5) Save All Parameters and Exit Setup  
(9) Exit Setup without Saving Parameters  
Enter Choice:  
4. Press “1” for Standard Setup  
Display:  
Standard Setup:  
Current Setting  
Auto Sense  
(1) Active Interface  
(2) Net Address  
(3) Radio Address  
0
1
(Net + Radio Address 0h)  
(4) Hopping Sequence  
(5) Standby Mode  
(6) Retry Level  
0
< 4 mA, ½ sec Cycle  
(9) Return to Main Menu  
Enter Choice:  
a. Leave Active Interface in “Auto Sense” (default setting) for most  
applications. In Auto Sense the RF400 will test for 5 V on CS I/O  
port (pin 1) to determine if a datalogger is present and if so select the  
CS I/O port.  
b. Select a Net Address from (0 – 63). Unless there is a neighboring  
network, leave network address “0.” The Network Address must be  
the same throughout the network of RF400s.  
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c. Select a Radio Address (0 – 1023). The radio addresses must be the  
same in point-to-point communications (for point-to-multipoint  
communications you could set the base RF400 to 0 and the remotes to  
1, 2, 3, etc.).  
It is a good idea to label each RF400 indicating the configured  
network address, radio address, hopping sequence, etc.  
d. Select a Hopping Sequence (0 – 6). The hopping sequence must be  
the same for all RF400s in the network.  
If there happens to be a neighboring RF400 network using the same  
hopping sequence, you should change to a different one in case their  
network and radio addresses happen to match yours and to reduce  
retries.  
- RX LED Test -  
To determine if there is a neighboring RF400 network in operation  
using the same hopping sequence as yours, stop communications on  
your network and observe an RF400 green LED for activity. A  
flashing green LED would indicate that there is a nearby network  
using the same hopping sequence.  
e. Select desired Standby mode (< 24 mA Always on, < 4 mA ½ sec  
Cycle, etc.) according to your power budget. All RF400s in the  
network must be in the same Standby Mode. The default setting is a  
good starting point (< 4 mA ½ sec Cycle).  
f. Select desired Retry Level (None, Low, Medium or High) according  
to the level of RF ‘collisions’ you expect. This depends on how  
many neighboring RF400s in and out of your network and the  
frequency of transmissions. Retries can, for example, reduce pauses  
in real-time monitoring of Input Locations.  
g. Press 9 to “Return to Main Menu”.  
h. There are other (“advanced”) parameters which typically remain  
“default” or as set by Auto Sense.  
i. Press “5” to “Save All Parameters and Exit Setup.”  
5.3.2 Remote Station Setup  
1. Point-to-point  
a. Complete steps 1 to 4 above making the remote station’s Network  
Address, Radio Address, and Hopping Sequence the same as the base  
station’s.  
b. While in Standard Setup verify that the Active Interface configuration  
is “Auto Sense” and set the Standby Mode the same as the base  
RF400 (default “2” ok).  
c. Exit and Save your configuration by pressing “5”.  
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2. Point-to-multipoint  
a. Complete steps 1 to 4 above making the remote stations’ Network  
Addresses and Hopping Sequences the same as the base station’s.  
b. While in Standard Setup verify that the active interface is “Auto  
Sense” and give each remote RF400 a unique Radio Address.  
You should label each RF400 (with masking tape) indicating the  
configured network address, radio address, hopping sequence, etc.  
c. Exit and Save your configuration by pressing “5”.  
3. Antenna considerations  
a. Line of sight – the single most important factor in radio performance  
is antenna placement. As Appendix H states, “height is everything.”  
The two RF400s must be able to ‘see’ each other if distances over a  
mile or two are required. This can be accomplished with a mast or  
tower.  
b. Mounting – the higher the gain of a yagi antenna, the more important  
it is to aim the yagi precisely and mount the yagi solidly to prevent  
movement due to strong winds, large birds, etc.  
c. Antenna cable routing – the antenna cable should be routed in a  
protected area and made secure against damage from wildlife, wind,  
and vandalism.  
d. Antenna cable weather sealing – the presence of water inside the  
antenna cable’s plastic sheath can attenuate your transmitted and  
received signals significantly. The RF energy, instead of traveling  
the length of the cable with little loss, is absorbed according to the  
amount of water present (like in a microwave oven). A small amount  
of water can ruin a once good communication link.  
When moisture gets inside the sheath it is very difficult to remove.  
Some careful cable handling (even pinholes can let in significant  
amounts of water), thoughtful cable routing, and good weather-  
proofing can prevent this.  
Apply a 1/8 inch thick coat of pure silicone rubber compound (RTV)  
1) where the cable connector screws onto the antenna connector  
(apply after the connector is in place allowing future removal) and  
2) at the junction between plastic cable sheath and cable connector. If  
carefully done this should last for years. An alternative approach is to  
wrap self-vulcanizing rubber tape around these same areas of the  
antenna connector, cable connector and cable sheath. This tape can  
be purchased at most electrical supply stores (see Troubleshooting  
Section 6, item 6).  
4. Site considerations  
Location of an RF400 near commercial transmitters, such as at certain  
mountaintop sites, is not recommended due to possible “de-sensing”  
problems for the RF400 receiver. A powerful signal of almost any  
frequency at close range can simply overwhelm a receiver. Lower  
24  
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RF400 Series Spread Spectrum Data Radio/Modems  
power and intermittent repeater sites may not be a problem. Test  
such a site with a representative setup before committing to it (see  
Troubleshooting Section 6). Keep in mind that commercial sites tend  
to evolve. Such a site may work now but could change in the future  
with the addition of new equipment.  
5.3.3 LoggerNet Configuration  
There are two ways of configuring the Setup map for a point-to-point  
‘network.’ You can represent the RF400s in the Setup map or simply leave  
them off. The simple map usually results in a quicker connection and requires  
less typing.  
(1) Point-to-point (not represented)  
(a) Setup map:  
ComPort_1  
CR10X  
(2) Point-to-point (represented)  
(a) Setup map:  
ComPort_1  
RF400  
RF400Remote  
CR10X  
(3) The station’s Maximum Baud Rate is typically 9600  
(4) Extra Response Times are typically 0 s  
In the case of point-to-multipoint, the RF400s are always represented in the  
LoggerNet Setup map so that LoggerNet can temporarily change the base  
RF400’s Radio Address to communicate with one out of a group of remote  
RF400s.  
(1) Point-to-multipoint  
(a) Setup map:  
ComPort_1  
RF400  
RF400Remote_1  
CR10X_1  
RF400Remote_2  
CR10X_2  
RF400Remote_3  
CR10X_3  
(2) All RF400Remotes have the same Network Address but each  
RF400Remote must have a unique Radio Address.  
(3) Extra Response Times are typically 0 s  
25  
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RF400 Series Spread Spectrum Data Radio/Modems  
3 dBd Omni Collinear  
9 dBd Yagi  
6 dBd Yagi  
0 dBd Half-wave  
CS I/O  
CS I/O  
CS I/O  
CS I/O  
CS I/O  
CS I/O  
RF400  
RF400  
RF400  
RS-232  
RF400  
DATALOGGER  
DATALOGGER  
DATALOGGER  
AC Adapter  
FIGURE 8. Point-to-Multipoint System  
5.3.4 PC208W Configuration  
a. Point-to-point  
(1) Device Map -  
COM1  
CR10X1  
(2) Set station CR10X1 baud rate to 9600 baud in network map  
(3) Datalogger extra response time – 0 mS  
b. Point-to-multipoint  
(1) Device Map -  
COM1  
Generic1  
10X3001  
10X3005  
(2) Set Generic Modem baud rate to 9600 in device map.  
(3) Generic Modem Settings  
(a) “Make DTR Active”  
(b) “Hardware Flow Control”  
(c) Extra Response Time (Standby Mode Max Response Delay +  
200 ms; see Table D-1)  
(i) 0 mS with 24 mA Standby Mode  
(ii) 1200 mS with 1/2 sec cycle default Standby Mode delay  
(iii) 4200 mS with 2 sec cycle Standby Mode delay  
26  
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RF400 Series Spread Spectrum Data Radio/Modems  
(4) Datalogger Station Settings  
(a) Example “Dialed Using Generic Dial String”:  
D1000 T"+++" R"OK"9200 T"ATDT3001^m"R"OK"1200  
T"ATCN^m"R"OK"1200  
(i) D1000 creates a 1 second delay  
(ii) T sends quoted string w/o waiting for a character echo  
(iii) +++ is string sent to put RF400 in AT Command mode  
(use other character if phone modems in path)  
(iv) R”OK”9200 waits up to 9.2 sec for RF400 “OK” response  
(v) ATDT3001 changes radio address to talk to remote RF400  
with network address of 12 and radio address of 1. This is a  
hexadecimal number (see Appendix C for example  
combined hexadecimal network/radio addresses) and is  
calculated by Setup Menu at Main Menu, Standard Setup,  
Radio Address.  
(vi) ATCN ends RF400 AT Command mode  
(b) Datalogger extra response time – 0 mS  
FIGURE 9. PC208W Datalogger Generic Dial String  
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RF400 Series Spread Spectrum Data Radio/Modems  
6. Troubleshooting  
If you can’t connect, check out these possible causes:  
1. Datalogger or Wiring Panel lacks 12 V power on pin 8 of CS I/O port  
The RF400 should go through its initialization with red and green LEDs  
lighting (see Section 4.1.1) when serial cable is connected if 12 V is  
present on CS I/O connector (see Quick Start Table 1). If needed obtain  
the optional Field Power Cable (CSI Item # 14291) to connect between  
datalogger 12 V output terminals and RF400 “DC Pwr” jack to supply  
power to the RF400.  
2. Active Interface set wrong  
This setting should normally be “Auto Sense” unless you have a phone to  
RF400 base station with PS512M and COM210 which requires the  
“COM2xx to RF400” setting or you have a PakBus datalogger requiring  
“Datalogger CSDC” due to another M.E. peripheral present. You could  
set the Active Interface to RS-232 or Datalogger Modem Enable if that is  
its permanent assignment, otherwise “Auto Sense” may be better.  
3. Low or weak battery voltage or 12 VDC supply voltage  
The power supply battery may not be charging properly due to solar panel  
orientation, poor connection, or due to a charging transformer problem.  
The battery itself may have discharged too low too many times, ruining  
the battery. Lead acid batteries like to be topped off.  
Power supply must be able to sustain at least 9.6 V (datalogger minimum)  
even during 75 mA transmitter bursts lasting only a few milliseconds.  
4. Lightning damage to RF400  
Swap in a known good RF400 with the same settings and see if this cures  
the problem. Lightning damage can occur leaving no visible indications.  
A “near miss” can cause damage as well as a more direct hit with  
evidence of smoke (see Appendix K for pass/fail tests).  
5. Lightning damage to antenna and/or cable  
Swap in a known good antenna and/or cable. Hidden damage may exist.  
6. Moisture in coaxial antenna cable  
It is possible that moisture has penetrated inside the plastic sheath of the  
coaxial cable. Water inside the cable can absorb RF energy and attenuate  
the transmitted signal; the received signal would also be attenuated. It is  
difficult to dry out the interior of a coaxial cable. Substitution of a dry  
cable is recommended.  
Placing a wet cable in a conventional oven at 160°F for a couple of hours  
should dry it out. Shield the antenna cable against damage from radiated  
heat from the oven element by placing the coiled cable on a large cookie  
sheet or a sheet of aluminum foil. See section 5.3.2 (3.d) for information  
on weatherproofing the antenna cable.  
28  
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RF400 Series Spread Spectrum Data Radio/Modems  
7. RF400 receiver “de-sensing” from nearby transmitter  
This problem can be observed from LED behavior when operating a hand-  
held radio near an RF400 that is receiving collected data from a remote  
station. If you key a hand-held 150 MHz or 450 MHz transmitter, even  
though its frequency of operation is far removed from the 900 MHz band,  
its close proximity to the base RF400 can overwhelm (de-sense) the  
RF400 receiver resulting in failed packets and LoggerNet/PC208W  
retries. This problem could also occur if you located an RF400 at a site  
containing commercial transmitters or repeaters. In general it is best to  
avoid such sites, especially the high-power FM or AM transmitter antenna  
sites which can change at any time with added equipment.  
It is possible to avoid de-sensing in some cases if RF400 link is solid  
enough due to: the proximity of your remote RF400(s); high antenna gains  
and directionality; high elevation; and sufficient distance separation  
between RF400 and commercial transmitter antenna. Try horizontal  
polarization of antennas. A field test in such situations is essential.  
8. Insufficient signal strength  
There are some things you can try to get that extra few dBs of signal  
strength sometimes necessary for a dependable RF link. The drop in  
signal going from Winter (no deciduous tree leaves) to Spring sometimes  
requires a little more signal.  
a. Raise the antenna height using a mast, tower or higher terrain. Often  
a little extra height makes the difference.  
b. Change to a higher gain antenna  
c. If in a multi-path situation such as inside a reflective building or  
canyon, try pointing the antenna in unlikely directions while looping  
back data (see Pass/Fail Appendix K) from the remote RF400 and  
typing characters in HyperTerminal. Sometimes a particular  
reflected signal will be stronger than the direct wave.  
d. Change polarization (element orientation) of all antennas in your  
network (yagi or collinear) from vertical to horizontal or vice versa.  
9. Interference from 900 MHz transmitter  
There are some measures you can take to reduce interference from  
neighboring 900 MHz transmitters:  
a. Move base station as far as possible from offending transmitter  
antenna.  
b. Install 9 dBd yagi and position station so that offending transmitter is  
located behind or to the side of the yagi to take advantage of yagi’s  
front-to-back or front-to-side ratio (back and side signal rejection).  
c. Change polarization (element orientation) of all yagi and collinear  
antennas in your network to see if that reduces effects of offending  
transmitter.  
29  
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RF400 Series Spread Spectrum Data Radio/Modems  
10. PC208W.dnd file corrupted  
The remote possibility exists that this file has become corrupted in your  
PC. After you create the Network Map in PC208W, you can back up  
PC208W.dnd in case this should happen. If this appears likely, exit  
PC208W and copy and paste your backup file over the suspect .dnd file  
to restore proper operation.  
11. RF400 has wrong Network Address, Radio Address, Hopping Sequence,  
or Standby Mode  
It is improbable that an RF400 that has been working would ever change  
address, hopping sequence or other settings. However, check the settings  
for the unlikely event this may have happened. Try “Restore Defaults”  
and set up RF400 again from that point.  
30  
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Appendix A. Part 15 FCC Compliance  
Warning  
Changes or modifications to the RF400 series radio systems not expressly  
approved by Campbell Scientific, Inc. could void the user’s authority to  
operate this product.  
Note: This equipment has been tested and found to comply with the limits for a  
Class B digital device, pursuant to part 15 of the FCC Rules. These limits are  
designed to provide reasonable protection against harmful interference in a  
residential installation. This equipment generates, uses, and can radiate radio  
frequency energy and, if not installed and used in accordance with the  
instructions, may cause harmful interference to radio communications.  
However, there is no guarantee that interference will not occur in a particular  
installation. If this equipment does cause harmful interference to radio or  
television reception, which can be determined by turning the equipment off and  
on, the user is encouraged to try to correct the interference by one or more of  
the following measures:  
Reorient or relocate the receiving antenna.  
Increase the separation between the equipment and receiver.  
Connect the equipment into an outlet on a circuit different from that  
to which the receiver is connected.  
Consult the dealer or an experienced radio/TV technician for help.  
This device complies with part 15 of the FCC Rules. Operation is subject to  
the following two conditions:  
1) This device may not cause harmful interference, and  
2) This device must accept any interference received, including interference  
that may cause undesired operation.  
A-1  
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Appendix B. Setup Menu  
Here is the structure of the RF400 series’ built-in Setup Menu system which can be  
accessed by configuring a terminal emulator program such as ProcommTM or  
HyperTerminalTM to 9600 baud (8-N-1) and pressing the “Program” button on the  
RF400 with RF400’s RS-232 port cabled to appropriate COM port of PC. Also  
displayed is a number representing the radio’s software and RF module versions.  
For example: 6.425.  
MAIN MENU  
SW Version 6.425  
1) Standard Setup  
a) Active Interface  
i) Auto Sense  
ii) RS-232  
iii) Datalogger Modem Enable  
iv) Datalogger SDC  
(not for Table Based Loggers)  
v) Datalogger CSDC  
(only for Table Based Loggers)  
vi) COM2xx to RF400  
b) Net Address (0 – 63)  
c) Radio Address (0 – 1023)  
d) Hopping Sequence ( 0 - 6)  
e) Standby Mode (select one of the following)  
i) <24 mA Always On  
ii) < 4 mA 1/2 sec Cycle  
iii) < 2 mA 1 sec Cycle  
iv) < .4 mA 8 sec Cycle  
2) Advanced Setup  
a) Radio Parameters  
i) Radio Address Parameters  
(1) Net Address  
(0 – 63)  
(2) Radio Address  
(0 – 1023)  
(3) Net Address Mask  
(0 – 3fh)  
(4) Radio Address Mask  
(0 – 3ffh)  
(5) Hop Table  
(0 – 6)  
B-1  
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Appendix B. Setup Menu  
ii) Radio Standby Modes  
(1) Standby Mode  
(0 => 24 mA Always ON 3 => 4 mA 1/2 sec Cycle)  
(4 => 2 mA 1 sec Cycle 5 => 1 mA 2 sec Cycle)  
(6 => .6 mA 4 sec Cycle 7 =>.4 mA 8 sec Cycle)  
(2) Time of Inactivity to Sleep  
(units of 100 msec; 1 – 32767)  
(3) Time of Inactivity to Long Header  
(units of 100 msec; 0 – 65535)  
Select 0 to always use long header  
Select 65535 to never use long header  
(4) Long Header Time  
(units of 100 msec; 0 – 255)  
iii) Radio AT Command Sequence Setup Menu  
(1) AT Command Sequence Character  
(any ASCII character)  
(2) Silence time before Command Sequence  
(units of 100 msec; 1 – 32767)  
(3) Silence time after Command Sequence  
(units of 100 msec; 1 – 32767)  
(4) AT Command Mode Timeout  
(units of 100 msec; 1 – 32767)  
iv) Radio Diagnostics  
Number of Retry Failures:  
Received Signal Strength:  
v) Radio Retry Settings  
(1) Number of Retries  
(0 – 255)  
(2) Number of time slots for random retry  
(units of 38 msec; 0 – 255)  
(3) Number of bytes transmitted before delay  
(1 – 65535)  
(4) Sync Timer Setting;  
(units of 100 msec; 0 – 255)  
b) Interface Parameters  
i) CSDC Address (Not Active):  
(7 or 8)  
ii) RS-232 Auto Power Down Enable  
0 => RS-232 always active to power RS-232 devices  
1 => RS-232 TX automatically powers down when no activity for 30 sec  
iii) RS-232 Parameters  
(1) RS-232 Baud Rate:  
0 => 1200  
1 => 4800  
2 => 9600  
3 => 19.2k  
B-2  
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Appendix B. Setup Menu  
4 => 38.3k  
(2) RS-232 Parity:  
0 => None  
1 => Odd  
2 => Even  
(3) RS-232 Character Length:  
0 => 8 bits  
1 => 7 bits  
(4) RS-232 Stop Bits:  
0 => 1  
1 => 2  
3) Restore Defaults  
4) Show All Current and Default Settings  
5) Save All Parameters and Exit Setup  
6) Exit Setup without Saving Parameters  
B-3  
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Appendix B. Setup Menu  
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B-4  
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Appendix C. RF400 Series Address and  
Address Mask  
Address  
An RF400’s address is 16 bits:  
(0 - 1111,1111,1111,1111)  
(0 - ffffh)  
binary  
hexadecimal  
decimal  
0 – 65535)  
The two parts of the address are the “Network Address” and the “Radio  
Address.” The six most significant bits of the address are the “Network  
Address”, and the ten least significant bits are the “Radio Address.”  
Network Address  
(0 - 11,1111)  
(0 - 3fh)  
Radio Address  
(0 - 11,1111,1111)  
(0 - 3ffh)  
binary  
hexadecimal  
decimal  
(0 – 63)  
(0 – 1023)  
Address mask  
The RF400 has a user programmable 16-bit address mask. Like the address,  
the address mask is divided into two parts. The six most significant bits are the  
Network Address Mask and the remaining ten bits are the Radio Address  
Mask.  
When an incoming packet header’s address is compared with the RF400’s  
address, only the address bits that correspond to address mask “1”s are used in  
the comparison.  
Example 1  
Incoming Packet’s Header Address xxxx xxxx xxxx xxxx  
RF400’s Network Address Mask  
RF400’s Network Address  
RF400’s Radio Address Mask  
RF400’s Radio Address  
1111 11  
yyyy yy  
11 1111 1111  
zz zzzz zzzz  
Since the address mask is all “1”s, all of the incoming Packet Header Address  
bits are compared against the corresponding RF400’s address bits.  
Example 2  
Incoming Packet’s Header Address xxxx xxxx xxxx xxxx  
RF400’s Network Address Mask  
RF400’s Network Address  
RF400’s Radio Address Mask  
RF400’s Radio Address  
1111 11  
yyyy yy  
11 1111 0000  
zz zzzz zzzz  
In this example, only the twelve most significant incoming Packet Header  
Address bits are used in the comparison with the RF400’s twelve most  
significant address bits because the entire address mask (Radio Address Mask  
appended to Network Address Mask) is 1111,1111,1111,0000. Since the last  
C-1  
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Appendix C. RF400 Series Address and Address Mask  
four bits are not compared, any remote RF400 with Radio Address of 0 to 1111  
(decimal 0 to 15) will be received by the base station.  
This allows multiple remotes in a network to be received by the base without  
changing the base Radio Address (the remotes cannot receive the base,  
however).  
Auto-Sense pre-configures as many settings as possible (including the address  
mask). If you have an RF400 connected to a PC’s RS-232 port and a remote  
RF400 connected to a datalogger’s CS I/O port, Auto-Sense will configure the  
remote’s address mask to (3fh, 3ffh) so that it will only receive a 16-bit address  
match (Network and Radio), but the base’s address mask to (3fh, 0h) so it will  
receive any packet that has the same Network Address (and hopping sequence)  
regardless of Radio Address.  
Combined Network/ Radio Addresses  
If programming PC208W for Point-to-Multipoint networks, the Generic Dial  
Strings require the combined 16-bit addresses of the RF400s to be called. The  
RF400 Setup Menu (in Standard Setup, Radio Address) calculates and displays  
the combined network and radio address when you enter the network and radio  
address values. Following are some examples.  
NET ADDRESS RADIO ADDRESS COMBINED 16-BIT ADDRESS  
(decimal)  
(decimal)  
(hexadecimal)  
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
2
3
4
5
6
7
0000  
0001  
0002  
0003  
0004  
0005  
0006  
0007  
0008  
0009  
000A  
000B  
000C  
000D  
000E  
000F  
0010  
0011  
0012  
0013  
0014  
0015  
0016  
0017  
0018  
0019  
000A  
000B  
000C  
8
9
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
20  
21  
22  
23  
24  
25  
26  
27  
28  
C-2  
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Appendix C. RF400 Series Address and Address Mask  
NET ADDRESS RADIO ADDRESS COMBINED 16-BIT ADDRESS  
(decimal)  
(decimal)  
(hexadecimal)  
0
0
0
0
29  
30  
31  
32  
001D  
001E  
001F  
0020  
0
0
1022  
1023  
03FE  
03FF  
1
1
0
1
0400  
0401  
2
2
0
1
0800  
0801  
3
3
0
1
0C00  
0C01  
4
4
0
1
1000  
1001  
5
5
0
1
1400  
1401  
6
6
0
1
1800  
1801  
7
7
0
1
1C00  
1C01  
8
8
0
1
2000  
2001  
9
9
0
1
2400  
2401  
10  
10  
0
1
2800  
2801  
11  
11  
0
1
2C00  
2C01  
12  
12  
0
1
3000  
3001  
13  
13  
0
1
3400  
3401  
14  
14  
0
1
3800  
3801  
C-3  
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Appendix C. RF400 Series Address and Address Mask  
NET ADDRESS RADIO ADDRESS COMBINED 16-BIT ADDRESS  
(decimal)  
(decimal)  
(hexadecimal)  
15  
15  
0
1
3C00  
3C01  
16  
16  
0
1
4000  
4001  
C-4  
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Appendix D. Advanced Setup Standby  
Modes  
The Standard Setup menu selections should fill the majority of user needs. The  
following information is given in case you need to program a non-standard  
standby mode.  
The Standard Setup menu selections do not correspond with Advanced Setup  
menu entries. For example: selecting a “3” in the Standard Setup menu selects  
(< 2 mA 1 sec Cycle) whereas entering a “3” in the Advanced Setup menu  
selects (< 4 mA 1/2 sec Cycle).  
Table D-1. Advanced Setup Menu  
STANDBY  
AVG RECEIVE  
CURRENT  
MAX.  
RESPONSE  
DELAY  
STANDBY  
MODE  
Wake-up Interval  
(red LED flash interval)  
01  
1
< 24 mA  
0 (constant)  
0 sec  
2
32  
43  
5
< 4 mA  
< 2 mA  
½ sec  
1 sec  
2 sec  
4 sec  
8 sec  
½ sec  
1 sec  
2 sec  
4 sec  
8 sec  
< 1 mA  
6
74  
< 0.6 mA  
< 0.4 mA  
Shaded modes 1, 2 not available  
1 Standard Setup menu selection 1  
2 Standard Setup menu selection 2  
3 Standard Setup menu selection 3  
4 Standard Setup menu selection 4  
Standard Setup automatically configures the following three parameters  
appropriately. If you configure a standby mode from the Advanced Setup  
menu you must also manually configure these parameters according to the  
following guidelines:  
(1) Time of Inactivity to Sleep  
(2) Time of Inactivity to Long Header  
(3) Long Header Time  
The first two parameters should be set to about the same value. What this  
value is will depend upon the nature of the anticipated activity. The defaults  
are 5 seconds and 4.8 seconds, so if you go more than 4.8 seconds without  
activity, a long header is sent, and a corresponding 5 second receive delay will  
be experienced.  
D-1  
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Appendix D. Advanced Setup Standby Modes  
In general, these inactivity timers should be set so that the RF400 stays on  
(receiving or transmitting, not in standby mode) longer than the quiet times  
during communication. You can experiment with this to see how it works.  
TIME OF INACTIVITY TO SLEEP  
The amount of receiver inactivity time desired before entering Standby Mode.  
This number is only valid in receive and duty cycling modes. Valid numbers  
range from 1 to 65535. The default number is 50 (for 5 seconds).  
TIME OF INACTIVITY TO LONG HEADER  
Set time before Long Header occurs. The time of inactivity on the wireless  
modem’s receive pin before a long header is issued. The valid number range is  
from 0 to 65535. 65535 selects no long header at all. The default is 48 (for 4.8  
seconds).  
LONG HEADER TIME  
Sets long header duration in tenths of a second. The default is 7 (for 0.7  
seconds). If changed from the default of 7, this number should be set to half of  
the “Delay” indicated in the Standby Mode you are using + 200 ms. For  
example, if your standby mode Delay is 4 seconds, set the Long Header Time  
to 22 (tenths of a second) for 2.2 seconds. The valid number range is from 0 to  
255. The longest long header time you should ever need is 8.2 seconds.  
D-2  
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Appendix E. RF400 Series Port Pin  
Descriptions  
RS-232 Port  
The “RS232” port is a partial implementation of RS-232C. It is configured as  
Data Communications Equipment (DCE) for direct cable connection to Data  
Terminal Equipment (DTE) such as an IBM-PC serial port.  
RS-232 CONNECTOR, 9-PIN D-SUB FEMALE  
PIN  
I/O  
DESCRIPTION  
1
2
3
4
5
6
7
8
9
O
I
TX  
RX  
GND  
CTS  
O
I = Signal Into the RF400, 0 = Signal Out of the RF400  
Only CTS is implemented for flow control. If data arrives (say from a PC)  
faster than the RF400 transmits it, the RF400 will de-assert CTS when the 640  
byte port buffer is full. If the PC continues to send data, the buffer will accept  
it and may wrap around over-writing oldest data. PC208W and LoggerNet  
monitor CTS to prevent buffer over-run.  
The RF400 can transmit RF packets slightly in excess of 9600 baud. When RF  
packets are received by the RF400, that data is immediately sent to the “active  
interface” port without flow control (no RTS).  
For many applications the RF400 works fine with no flow control. The need  
for flow control arises when longer standby modes are used, where more data  
could be sent than the 640 byte buffer can hold before transmittal. For  
example, if the RF400s are in Standby Mode 6 (see Appendix D), an RF400  
needs to buffer incoming RS-232 data for up to 8 seconds while waiting for  
the other RF400 to wake up before transmitting it. Also, if the RF400 is doing  
a lot of retries, that can take extra time and require flow control to avoid buffer  
over-run.  
CS I/O Port  
The CS I/O port is Campbell Scientific's input/output port. It is not a standard  
RS-232 pin-out. The following table provides pin-out information on the port  
when connected to a datalogger.  
E-1  
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Appendix E. RF400 Series Port Pin Descriptions  
CS I/O CONNECTOR, 9-PIN D-SUB MALE  
PIN  
FUNCTION  
I/O  
DESCRIPTION  
1
2
3
5V  
I
Sources 5 VDC to power peripherals  
GND for pin 1 and signals  
GND  
Ring  
O
Raised by modem to put datalogger  
into telecommunications mode  
4
5
RX  
O
I
Serial data receive line  
Modem Enable  
Raised when datalogger determines  
that associated modem raised the  
ring line  
6
7
Synchronous Device  
Enable  
I
Used by datalogger to address  
synchronous devices; can be used as  
a printer enable  
CLK/Handshake  
I/O  
Used by datalogger with SDE and  
TX lines to transfer data to  
synchronous devices  
8
9
12V supplied by  
datalogger  
PWR Sources 12 VDC to power  
peripherals  
TX  
I
Serial data transmit line  
I = Signal Into the RF400, 0 = Signal Out of the RF400  
E-2  
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Appendix F. Datalogger RS-232 Port to  
RF400 Series Radio  
A connection from RF400 RS-232 port to CR23X or CR5000 RS-232 port  
requires a 9-pin male to 9-pin male null-modem cable. This cable is available  
as CSI Item # 14392.  
A 12-Volt Field Power Cable (Item # 14291) or AC adapter (Item # 15966)  
must be installed to furnish 12 V to the “DC Pwr” connector on the RF400.  
The RF400 can operate with Active Interface in either the Auto Sense mode  
(default) or in the RS-232 mode with this configuration.  
With the CR23X, the *D 12 “--” setting (to turn datalogger RS-232 port on) is  
not required.  
F-1  
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This is a blank page.  
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Appendix G. Short-Haul Modems  
Set SRM-5A at PC end to “DCE” mode.  
Set SRM-5A at RF400 end to “DTE” mode.  
The PC to SRM-5A cable is typically a 9-pin female to 25-pin male (CSI Item  
# 7026). The SRM-5A to RF400 cable is 25-pin male to 9-pin male available  
as CSI Item # 14413.  
LoggerNet or PC208W Network Map:  
COM1  
CR10X1  
AC Adapter  
TECHNOLOGIES INC.  
HICKSVILLE, NEW YORK  
apx  
CLASS  
MODEL NO:  
INPUT  
OUTPUT  
2
TRANSFORMER  
AP2105W  
:
120VAC 60Hz 20W  
:
12VDC  
LISTED  
1.0A  
2H56  
E144634  
U
U
L
L
R
R
MADE IN CHINA  
SRM-5A Short-haul Modems  
RS-232  
DC  
Pwr  
Logan, Utah  
RS232  
RF400  
Spread Spectrum Radio  
CS I/O  
This device contains transmitter module:  
FCC ID: OUR-9XTREAM  
The enclosed device complies with Part 15 of the  
FCC Rules.  
Program  
Antenna  
Operation is subject to the following two conditions:  
(1) This device may not cause harmful interference,  
and (2) this device must accept any intererence  
received, including interference that may cause  
undesired operation.  
Pwr/TX  
RX  
14320  
Serial  
#
MADE IN USA  
DCE  
DTE  
Datalogger CS I/O  
G
G
12V  
12V  
Logan, Utah  
CS I/O  
SW 12V CTRL  
SW 12V  
G
CS I/O  
POWER  
IN  
SE  
DIFF  
7
8
L
9
10  
L
11 12  
6
4
5
G
G
H
AG  
H
AG  
H
L
AG E3 AG  
G
G
5V 5V  
G
DC  
Logan, Utah  
Pwr  
CR10X WIRING PANEL  
MADE IN USA  
RS232  
RF400  
Spread Spectrum Radio  
CS I/O  
SE  
DIFF  
1
2
L
3
4
L
5
6
This device contains transmitter module:  
FCC ID: OUR-9XTREAM  
SDM  
1
2
3
The enclosed device complies with Part 15 of the  
FCC Rules.  
G
G
H
AG  
H
AG  
H
L
AG E1 AG E2  
G
P1  
G
P2  
G
C8 C7 C6 C5 C4 C3 C2 C1  
G
12V 12V  
Program  
Antenna  
Operation is subject to the following two conditions:  
(1) This device may not cause harmful interference,  
and (2) this device must accept any intererence  
received, including interference that may cause  
undesired operation.  
EARTH  
GROUND  
Pwr/TX  
RX  
WIRING  
PANEL NO.  
14320  
Serial  
#
MADE IN USA  
FIGURE G-1. Short-Haul Modem to RF400 Setup  
Configure RF400s for point-to-point (see Software Setup Section 5.3). Default  
settings should work unless there is a neighboring network (see Section 5.3.1,  
4.d).  
12 V power for the base RF400 can be supplied by an AC adapter as shown or  
a Field Power Cable (see Power Supplies in Section 4.4). Current dataloggers  
will supply remote RF400 power via serial cable.  
G-1  
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Appendix G. Short-Haul Modems  
With short-haul modems it is necessary to configure the base  
NOTE  
station RF400’s “RS-232 Auto Power Down Enable” (in the  
Advanced Setup \ Interface Parameters menu) to mode "0" which  
will maintain the radio's RS-232 port always active. This results  
in an additional constant 2 mA current drain by the RF400. If  
you don’t do this, the base RF400’s RS-232 port will turn off 30  
seconds after activity and the attached SRM-5A which gets its  
power from the port will not receive any messages from the PC.  
This is a blank page.  
G-2  
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Appendix H. Distance vs. Antenna  
Gain, Terrain, and Other Factors  
RF Path Examples  
Distance  
Achieved  
Antennas  
Path Between Radios  
(miles)  
14204 OMNI ½ Wave 0 dBd* Whip Virtual line-of-sight on valley floor with  
2
to  
wetland foliage.  
14204 OMNI ½ Wave 0 dBd Whip  
14204 OMNI ½ Wave 0 dBd Whip  
to  
14204 OMNI ½ Wave 0 dBd Whip  
14204 OMNI ½ Wave 0 dBd Whip  
to  
Line-of-sight across a valley (on foothills  
approximately 300 feet above the valley  
floor on each end).  
Line-of-sight across a valley (on foothills  
approximately 300 feet above the valley  
floor on each end).  
10  
35  
14201 9 dBd YAGI  
* dBd = decibel level compared to a simple dipole antenna  
LINE-OF-SIGHT  
You should arrange for a line-of-sight signal path between RF400s. At 900  
MHz or 2.4 GHz there is little signal bending, however, there is reflection from  
hills, water, and conductive objects. Sometimes reflections provide a helpful  
path around an obstacle. There can be some trees and bushes in the signal path  
(with reduction in signal strength), but a hill will block the signal effectively.  
Thick trees can limit range to as little as 800 feet. Where possible avoid  
buildings and other man-made structures in the signal path as they absorb or  
reflect some of the direct wave, possibly below the level needed for  
communications.  
ANTENNA HEIGHT  
In situations where the RF400 antennas are situated virtually line-of-sight, the  
elevation of antennas (by choice of site or by installing a tower or mast) can  
substantially increase signal strengths. The amount of increase depends on  
factors in the propagation path between the radios including terrain, foliage,  
and man-made structures. Elevating one or both of the antennas essentially  
raises the signal path allowing the direct wave to better avoid absorption or  
reflection which can sometimes be more helpful than adding higher gain  
antennas.  
GAIN ANTENNAS  
Increasing antenna gains improves signal strength and distance. For example,  
the substitution of a 9 dBd yagi antenna where a 0 dBd OMNI existed  
theoretically extends the attainable distance by a factor of 2.8. Adding 9 dBd  
yagi antennas on both ends in place of 0 dBd OMNIs theoretically extends the  
distance by a factor of 7.9. The higher the yagi’s gain, the narrower the beam  
width and the more critical it is that it be aimed right on target.  
H-1  
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Appendix H. Distance vs. Antenna Gain, Terrain, and Other Factors  
How Far Can You Go?  
Distance Estimates for Spread Spectrum Radios  
Overview  
There is a great deal of interest in estimating the distance you can expect to  
achieve with the RF400 radios. Also of interest are the effects of cable length,  
antenna gain, and terrain. Some of these items are easy to quantify (cable loss,  
for instance); others are difficult to quantify (such as the effect of ground  
reflections). They are all important, though, and affect how well the RF system  
performs.  
Probably the best approach to take in making range estimates is to do a site  
survey that considers the topography, location of antennas and radios, and  
cable lengths, make some assumptions about the path losses, and see if there is  
still some net gain. If there is, or if it is close, the next course is to actually try  
it out.  
Link Analysis  
In an RF system, there are gains (transmitter power, antenna gains, and  
receiver sensitivity “gain”) and losses (cable loss and path loss). If the gains  
exceed the losses, you have a connection; any excess is the “link margin”.  
Parenthetical values pertain to 2.4 GHZ  
EXAMPLE GAINS  
EXAMPLE LOSSES  
Transmitter Power  
Transmitter Antenna  
Receiver Antenna  
20 (17)  
6
6
Transmitter Cable  
Free Space  
Receiver Cable  
3
120  
3
Receiver Sensitivity “gain” 110 (104)  
TOTAL GAINS 142 (133) dB TOTAL LOSSES  
=
=
126 dB  
Link Margin = (Total Gains) – (Total Losses) = 142 (133) – 126 = 16 (7) dB  
A minimum of 6 dB of link margin is recommended.  
Here is a block diagram of the various components of gain/loss:  
Radio  
Transmitter  
Cable  
Loss  
Antenna  
Gain  
Free Space  
Loss  
Antenna  
Gain  
Cable  
Loss  
Radio  
Receiver  
Pt  
-
Lt  
+
Gt  
-
Lp  
+
Gr  
-
Lr  
=
Pr  
Where:  
Pt =>  
transmitter output power, in dBm (20 dBm in the case of the RF400  
or RF410)  
Lt =>  
cable loss between transmitter and antenna in dB (see Cable Loss section)  
Gt => transmit antenna gain in dBi (dBi = dBd + 2.15)  
Lp => path loss between isotropic antennas in dB (see Tables H-1, H-2)  
Gr => receive antenna gain in dBi  
Lr =>  
cable loss between antenna and receiver in dB  
H-2  
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Appendix H. Distance vs. Antenna Gain, Terrain, and Other Factors  
Pr =>  
signal power at the radio receiver in dBm  
The signal power at the receiver (Pr) must exceed the receiver sensitivity  
(110 or –104 dBm) by a minimum of 6 dB for an effective link. The amount  
that Pr exceeds –110 dBm or –104 dBm (2.4 GHz) is the link margin.  
All of these elements are known, or are easily determined, with the exception  
of Lp. Unfortunately, signal path loss can make the difference between a  
marginal link ½ mile apart, and a reliable link 10 miles apart!  
Transmitter Power  
Transmitter output power is often expressed in dBm, which is a decibel power  
rating relative to 1 milliWatt. The formula is: dBm = 10 log (Pt) with Pt  
expressed in milliWatts.  
Transmitter Power (Pt)  
dBm  
(milliWatts)  
1
0
10  
50 (RF415)  
100 (RF400 or RF410)  
1000  
10  
17  
20  
30  
37  
5000  
Cable Loss  
Cable loss is a function of cable type, length, and frequency and is usually  
specified as attenuation (dB) per 100’ of cable. Using a low loss cable  
becomes very important as the cable run distances increase. Here are some  
typical cable types and their properties:  
Cable Type  
RG-58A/U  
COAX RPSMA-L  
RG-8  
Outside Diameter  
.195”  
Loss (dB/100’) @ 900 MHz  
Loss (dB/100’) @ 2.4 GHz  
21.1  
11.1  
6.9  
.195”  
.405”  
18.8  
COAX NTN-L  
LMR-400  
.405”  
.405”  
4.5  
3.9  
8.1  
6.7  
*CSI stocked antenna cables are shaded.  
CSI’s “COAX RPSMA-L” uses LMR-195 antenna cable. Cable loss is  
proportional to length as the following table illustrates.  
LMR-195 Cable Loss vs. Length @ 900 MHz  
LENGTH  
LOSS  
(dB)  
11.1  
5.6  
2.8  
1.1  
(ft.)  
100  
50  
25  
10  
6
0.7  
H-3  
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Appendix H. Distance vs. Antenna Gain, Terrain, and Other Factors  
Antenna Gain  
Antenna gain is specified either in dBi (decibels of gain relative to an isotropic  
radiator) or in dBd (decibels of gain relative to a dipole). The relationship is:  
dBi = dBd + 2.15  
Some antennas that are FCC approved for use with the RF400 series are:  
Mfg.  
Antenna Type  
Band  
Model  
CSI Item #  
dBd  
Gain  
0
3
9
dBi  
Size  
Gain  
2.15  
5.15  
11.15  
2.15  
15.1  
Astron  
Omni (1/2 wave) 900 MHz  
Collinear  
Yagi  
Omni (1/2 wave) 2.4 GHz  
Enclosed Yagi 2.4 GHz  
14204  
14221  
14201  
16005  
16755  
6.75”  
24”  
21.4”  
4.5”  
17”  
AXH900 RP SMA R  
FG9023  
BMOY8905  
ANT-2.4-CW-RCT-RP  
WISP24015PTNF  
Antenex  
MaxRad  
LINX  
900 MHz  
900 MHz  
0
13  
MaxRad  
Receiver Sensitivity  
Receiver sensitivity is usually specified in dBm for a specific bit error rate  
(BER). The transceiver module used in the RF400 (either 900 MHz radio) is  
specified at –110 dBm at ~10-4 raw BER.  
If the received signal strength is greater than the receiver sensitivity, a link can  
be established. Any excess signal strength above the receiver sensitivity is  
“link margin”, and is a very good thing; a minimum of 6 dB of link margin  
should be sought.  
Path Loss  
We have combined in this section the normal “free space” path loss (only seen  
in mountaintop to mountaintop scenarios) with loss due to ground reflections,  
diffraction, leaf/forest absorption, etc. It is all loss!  
A starting point is the “free space” path loss. Here are two equations for this:  
Lp (dB) = 32.4 + 20 x log( f ) + 20 x log ( d ) dB  
Lp (dB) = 36.6 + 20 x log( f ) + 20 x log ( d ) dB  
(f in MHz, d in km)  
(f in MHz, d in miles)  
Here is a table showing the free space path loss (in dB). Note the effect of  
frequency.  
Frequency  
Distance  
1 mi. 2 mi. 4 mi.  
8 mi.  
107  
114  
122  
10 mi.  
109  
116  
16 mi.  
113  
120  
22 mi.  
115  
123  
26 mi.  
117  
124  
30 mi.  
118  
125  
400 MHz  
915 MHz  
2.4 GHz  
89  
95  
101  
108  
116  
96  
104  
102  
110  
124  
128  
131  
133  
134  
Notice the relationship between path loss and distance: each time you double  
the distance, you lose 6 dB of signal under free space conditions. Or, put  
another way, if you add 6 dB of gain (for example with 6 dB of additional  
antenna gain, or 6 dB less cable loss), you can double the distance for free  
space conditions.  
H-4  
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Appendix H. Distance vs. Antenna Gain, Terrain, and Other Factors  
As mentioned before, free space conditions are the ideal, but seldom actually  
seen. The higher the antenna height relative to the terrain in the line of sight  
path, the closer to free space conditions. Antenna height is everything!  
Here are some additional propagation effects that increase the path losses:  
Diffraction  
This is caused by objects close to the line of sight path. Real world examples  
of this would be hills, buildings, or trees. The object may not be in the direct  
line-of-sight, but if it is close enough, it will cause the RF to diffract around the  
object, giving additional path loss. “Close enough” is a function of frequency,  
path length, and position of the obstacle along the path.  
An example at 900 MHz: a 10 mile path length with an obstacle halfway along  
the path will see diffraction “losses” from an obstacle within ~70 ft. of line-of  
sight. The amount of loss would be from 6 dB to 20 dB, depending on the  
obstacle surface. A sharp edge (like a rock cliff) would give the minimum loss  
(6 dB), while a rounded hill would give the maximum loss (20 dB).  
Ground Reflections  
These are caused by the RF signal being reflected from the ground (or water),  
and undergoing a phase shift so that it destructively interferes with the line of  
sight signal. The conditions that cause this the most are propagation over  
water, or over a low-lying fogbank. The reflected signal suffers little  
attenuation, gets out of phase, and interferes with the main signal. If antennas  
need to be sited near water, they should be positioned away from the water’s  
edge so that the ground vegetation attenuates the reflected RF.  
The result of the reflection and interference (worst case) is that the path loss  
increases as the 4th power of the distance, instead of the 2nd power. This  
changes the distance term in the path loss equation to: 40 x log ( d ) dB.  
Then, with each doubling of distance, the path loss increases by 12 dB, instead  
of 6 dB.  
Vegetation  
Losses due to vegetation (trees, bushes, etc) cause the path loss to increase by  
the 3rd to 4th power of the distance, instead of the 2nd power. This is just like in  
the severe ground reflection case above.  
Rain, Snow, and Fog  
Below 10 GHz, these don’t have much effect on path loss (see Ground  
Reflections).  
Real World Distance Estimates  
From the above discussion of departures from the ideal “free space” path loss,  
it is clear that we should usually use something other than the 2nd power  
distance table.  
H-5  
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Appendix H. Distance vs. Antenna Gain, Terrain, and Other Factors  
Here is a table which gives calculated path loss (Lp) values at 900 MHz for the  
2nd, 3rd, and 4th powers of distance; the equations (for 915 MHz) are:  
Lp (2nd power) = 95.8 + 20 × log ( d ) dB  
Lp (3rd power) = 95.8 + 30 × log ( d ) dB  
Lp (4th power) = 95.8 + 40 × log ( d ) dB  
(d in miles)  
(d in miles)  
(d in miles)  
Example calculated Lp values (in dB)  
TABLE H-1. 900 MHz Distance vs. Path Loss (Lp in dB) per Three Path Types  
Path Type  
2nd power  
3rd power  
4th power  
2 mi.  
102  
105  
108  
4 mi.  
108  
114  
120  
6 mi.  
111  
119  
127  
8 mi.  
114  
123  
132  
10 mi.  
116  
126  
14 mi.  
119  
130  
18 mi.  
121  
133  
22 mi.  
123  
136  
26 mi.  
124  
138  
30 mi.  
125  
140  
136  
142  
146  
149  
152  
155  
The following table helps select a Path Type in the above “Distance vs. Path  
Loss” table to best fit your situation.  
TABLE H-2. Path Type vs. Path  
Characteristics Selector  
Path Type  
Path Characteristics  
Mountaintop to mountaintop  
or Tall antenna towers  
Line-of-sight  
Dominantly line-of-sight  
Low antenna heights  
2nd power  
3rd power  
4th power  
Some trees  
At water’s edge (very reflective)  
Across field of grain (reflective)  
Lots of Trees (absorptive)  
Examples  
Some examples will help illustrate the tradeoffs in a link analysis. These  
examples will all use the RF400 900 MHz radio, and will use –107 dBm as the  
required power level at the radio receiver. This is 3 dB higher than the quoted  
sensitivity of –110 dBm, which will give us a 3 dB margin.  
Here’s the equation we will use, from the first page:  
Pt - Lt + Gt - Lp + Gr - Lr = Pr  
Example #1  
Antenex FG9023 antennas on each end, 20’ of LMR195 cable on one end, 10’  
of LMR195 on the other end, antennas at 10’ height, fairly open terrain with a  
few trees. How far can I go?  
Pt = 20 dBm  
Lt = 20’ x (11.1 dB/100 ft) = 2.22 dB  
Gt = Gr = 3 dBd = 5.15 dBi  
Lr = 10’ x (11.1 dB/100 ft) = 1.11 dB  
H-6  
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Appendix H. Distance vs. Antenna Gain, Terrain, and Other Factors  
Use –107 dBm for Pr, solve for Lp: Lp = 135 dB  
Use the 3rd to 4th power tables: Range from ~9 (4th power) to ~22 (3rd power)  
miles  
Example #2  
Base has MaxRad BMOY8905 Yagi, with 50’ of LMR195 cable on a 30’  
tower, also a lightening protection device with a VSWR of 1:1.75; remote also  
has a MaxRad BMOY8905 Yagi with 5’ of LMR195 cable on a 4’ pole.  
Terrain is mostly flat, with sagebrush. How far can I go?  
Pt = 20 dBm  
Lt = 50’ x (11.1 dB/100 ft) = 5.55 dB  
Gt = 9 dBd = 11.15 dBi  
Lr = 5’ x (11.1 dB/100 ft) = .55 dB  
Gr = 9 dBd = 11.15 dBi  
Need to include the loss from the surge arrestor: VSWR of 1:1.75 = .34 dB loss  
Use –107 dBm for Pr, solve for Lp: Lp = 143 dB  
Use the 3rd to 4th power tables: Range from ~14 (4th power) to 30+ (3rd power)  
miles  
Example #3  
You need to run 125’ of cable for the transmitter:  
How much loss if I use LMR195 cable?  
How much loss if I use LMR400 cable?  
125’ x (11.1 dB/100’) = 13.9 dB  
125’ x (3.9 dB/100’) = 4.9 dB  
If I am using path loss from the 2nd power table, and operating fine at 8 miles  
with LMR195 cable, how much more range could I expect if I use LMR400  
cable (assuming similar terrain)?  
13.9 dB – 4.9 dB => 9 dB more link margin  
Loss at 8 miles: 114 dB; could tolerate 114 + 9 dB = 123 dB loss =>>> 22  
miles (14 miles more)  
H-7  
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Appendix H. Distance vs. Antenna Gain, Terrain, and Other Factors  
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H-8  
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Appendix I. Phone to RF400 Series  
Where a phone to RF400 Base is desired, the following configurations will  
provide Point-to-Point or Point-to-Multipoint communications. To have a base  
datalogger in this configuration requires that another RF400 be added at the  
base.  
1. HARDWARE REQUIREMENTS  
a. RF400s  
b. COM210  
c. PS512M (or CH512R and battery)  
(have built-in null-modems and supply power for RF400 and  
COM210)  
d. AC charger (CSI Item # 9591) or solar panel  
e. Two SC12 cables (one included with RF400 and one with COM210)  
2. POINT-TO-POINT COMMUNICATIONS  
PC-Modem ------------ COM210-PS512M-RF400------------ RF400-DL  
(null-modem)  
LoggerNet SETUP  
a. Setup:  
ComPort_1  
PhoneBase  
PhoneRemote  
RF400  
RF400Remote  
CR10X  
b. ComPort_1 – default settings  
c. PhoneBase  
1) Maximum Baud Rate – 9600  
2). Modem Pick List – per PC’s phone modem  
3) Extra Response Time – 0 s  
d. PhoneRemote – input base site’s phone number  
e. RF400 – make Attention Character: “-“ ; leave the rest defaults  
f. RF400Remote – Radio Address: “0” ; leave the rest defaults  
g.  
CR10X – default settings, schedule collections as desired  
PC208W SETUP  
a. Device Map  
COM1  
Modem1  
CR10X1  
b. COM port - Default settings  
I-1  
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Appendix I. Phone to RF400 Series  
c. Phone Modem  
1) Baud Rate – 9600  
2) Modem Pick List – per PC’s phone modem  
3) Extra Response Time – 2000 ms  
d. Datalogger – Dialed Using Phone # at Base site  
RF400 CONFIGURATION  
a. Base RF400  
1) Active Interface: “COM2xx to RF400”  
2) AT Command (Attention) Character: “-“  
3) All other settings: defaults  
b. Remote RF400 – leave all settings: defaults  
Note: If there is a neighboring RF400 network, you should change  
the Hopping Sequence of base and remote RF400s to a new setting to  
avoid interference (see Section 5.3.1 for method to detect neighboring  
network).  
3. POINT-TO-MULTIPOINT COMMUNICATIONS  
PC-Modem ------------ COM210-PS512M-RF400------------RF400-DL1  
(null-modem)  
------------ RF400-DL2  
LoggerNet SETUP  
a. Setup:  
ComPort_1  
PhoneBase  
PhoneRemote  
RF400  
RF400Remote  
CR10X  
RF400Remote_2  
CR10X_2  
b. ComPort_1 – default settings  
c. PhoneBase  
1) Maximum Baud Rate – 9600  
2) Modem Pick List – per PC’s phone modem  
3) Extra Response Time – 0 s  
d. PhoneRemote – input base site’s phone number  
e. RF400 – make Attention Character: “-“ ; leave the rest defaults  
f. RF400Remote – make Radio Address: “1“ ; leave the rest defaults  
g. RF400Remote_2 – make Radio Address: “2“ ; leave the rest defaults  
h. Dataloggers – default settings, schedule collections as desired  
I-2  
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Appendix I. Phone to RF400 Series  
PC208W SETUP  
a. Network Map  
COM1  
Modem1  
Generic1  
CR10X_1  
CR10X_2  
b. COM port - default settings  
c. Phone Modem  
1) Baud Rate – 9600  
2) Modem Pick List – per PC’s phone modem  
3) Extra Response Time – 2000 ms  
d. Generic Modem  
1) Dialed Using phone # at base site  
2) Make DTR Active and Hardware Flow Control  
e.  
Datalogger 1  
1) Dialed Using Generic Modem Dial String:  
D1000T"---"R"OK"9200T"ATDT0001^m"R"OK"1200T"ATCN  
^m"R"OK"1200  
2) Set up scheduled collections as desired.  
f. Datalogger 2  
1) Dialed Using Generic Modem Dial String:  
D1000T"---"R"OK"9200T"ATDT0002^m"R"OK"1200T"ATCN  
^m"R"OK"1200  
2) Set up scheduled collections as desired.  
“0001” in the first ATDT command is the hexadecimal representation of  
the combined Network Address / Radio Address chosen for this example  
(i.e., Network Address = 0, Radio address = 1). The RF400 Setup Menu  
calculates and displays this number for you in Standard Setup as “0001h”.  
RF400 CONFIGURATION  
a. Base RF400  
1) Active Interface: “COM2xx to RF400”  
2) AT Command Character: “-”  
3) All other settings: defaults  
b. Remote RF400s  
1) Radio Addresses: 1, 2, etc. (unique for each remote RF400 and  
must agree with respective RF400Remote settings)  
2) All other settings: default  
Note 1: Using a non “+” Command Character for the base RF400 is  
necessary so the phone modem in the path passes the AT commands  
on to the base RF400 rather than responding to them.  
Note 2: If there is a neighboring RF400 network, you should change  
the Hopping Sequence of base and remote RF400s to a new setting to  
avoid interference (see Section 5.3.1 for method to detect neighboring  
network).  
I-3  
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Appendix I. Phone to RF400 Series  
FIGURE I-1. LoggerNet Point-to-Multipoint Setup  
4. HARDWARE  
After configuring LoggerNet or PC208W and the RF400s you are ready to  
set up hardware. The PS512M null-modem connectors (it’s not important  
which connector goes to which unit) connect via SC12 cables to the  
COM210 and the base RF400 CS I/O port. Connect the site phone line to  
COM210. Connect power to PS512M. Connect antenna to RF400.  
When you turn on the PS512M supply, the RF400 receives 12V power  
and you will see the LEDs light in their power-up sequence.  
Remote RF400s normally connect to datalogger CS I/O ports via SC12  
cables. Powering up the datalogger will start the RF400 operating. Install  
an antenna (or antenna cable and yagi or collinear) and you are ready to  
collect data.  
I-4  
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Appendix J. Monitor CSAT3 via RF400  
Series  
Procedure for installing a pair of RF400 series spread spectrum radios for  
monitoring a CSAT3 system at a distance. This function has traditionally been  
implemented by running a short haul modem cable between CSAT3 and PC.  
HARDWARE REQUIREMENTS  
Two RF400s (mounting bracket option available)  
Two RF400 antennas (and possibly cables, see Section 4.4 for  
options)  
Base Cable/Power Kit Item #14220 (contains 120V AC Adapter and  
6 ft. PC to RF400 serial cable).  
Remote station 12V Field Power Cable Item # 14291 or (if 120VAC  
is available), AC adapter Item # 15966  
9 pin male to 9 pin male null-modem serial cable (CSI Item # 14392)  
PC with HyperTerminalTM or ProcommTM for RF400 setup (if  
neighboring RF400s).  
Spare PC COM port (COMx)  
RF400 SETUP  
(1) Plug AC adapter into 120VAC outlet; plug barrel connector into  
“base” RF400 and wait 10 seconds for RF400 to initialize.  
(2) Connect 6 ft. cable (from base kit) between PC COM port and base  
RF400 RS-232 port.  
(3) Run HyperterminalTM or ProcommTM on PC and configure for  
(a) Baud rate: 9600, 8-N-1  
(b) Flow control: none  
(c) Emulation: TTY  
(d) ASCII  
(e) COMx (direct connect)  
Note: if using HyperterminalTM it will probably be necessary to do a  
Call Disconnect and then a Call Connect for new settings to take  
effect.  
(4) Press “Program” button on RF400  
The following text should be written to the terminal screen  
Main Menu  
SW Version XX.YYY  
(1) Standard Setup  
(2) Advanced Setup  
(3) Restore Defaults  
(4) Show All Current & Default Settings  
(5) Save All Parameters & Exit Setup  
(9) Exit Setup without Saving Parameters  
Enter Choice:  
J-1  
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Appendix J. Monitor CSAT3 via RF400 Series  
(5) Select “1” for “Standard Setup” and configure the following  
(a) Active Interface – leave at default “Auto Sense”  
(b) Network Address – can be default “0” if no neighboring RF400  
networks are operating; otherwise choose a different network  
address (see RX LED Test below).  
(c) Radio Address – can be default “0”  
(d) Hopping Sequence – can be default “0” if no neighboring RF400  
networks are operating; otherwise choose a different hopping  
sequence (1 – 6).  
- RX LED Test -  
To determine if there is a neighboring RF400 network in  
operation using the same hopping sequence as yours, stop  
communications on your network and observe RF400 green  
LEDs for activity. At this point, any green LED activity would  
indicate that there is a nearby network using the same hopping  
sequence.  
The other network’s network and/or radio addresses might be  
different than yours, so having the same hopping sequence isn’t  
necessarily a serious problem but having an exclusive hopping  
sequence results in fewer retries.  
(e) Standby Mode – leave at default “2”  
(f) Retry Level – if RF noise is a problem, try “Low” or a higher  
level to see if response improves.  
(6) Repeat steps 1 - 5 with “remote” RF400. Temporarily use 6 ft. cable  
and AC adapter during the remote RF400 setup. CSAT3 monitoring  
requires a Point-to-Point network so you should configure all remote  
RF400 settings the same as you did for the base RF400.  
CSAT3 SETUP  
(1) Power CSAT3 off and then back on  
(2) Connect CSAT3’s RS-232 cable to the desired PC COM port  
(3) Run CSAT32 software  
(4) Select correct COM port if necessary under Settings\Communication  
(5) Enter Terminal mode (bottom tab)  
(6) Open Port (if not already open)  
(7) Press [Enter] a couple of times to get “>“ prompt  
(8) Enter “br 0” and press [Enter] to send it to CSAT3 to configure RS-  
232 communications to 9600 baud (the RF400 always communicates  
at 9600 baud).  
(9) Enter “ri 1” and press [Enter] to send it to CSAT3 to turn on RS-232  
drivers (if you want to save this setting in non-volatile RAM, refer to  
CSAT3 Instruction Manual, Appendix B).  
(10)Return to Data mode (bottom tab)  
HARDWARE SETUP  
(1) Base station  
(a) Plug AC adapter into 120 VAC outlet and barrel connector into  
“DC Pwr” jack on base RF400.  
(b) Connect 6 ft. cable (from base kit) between PC COM port of  
choice and RF400 RS-232 port.  
J-2  
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Appendix J. Monitor CSAT3 via RF400 Series  
(2) Remote station  
(a) Connect 12 V power supply to RF400 (can be either 120V AC  
adapter or 12V Field Power Cable)  
(b) Connect 9 pin male to 9 pin male null-modem cable from  
CSAT3 RS-232 connector to RF400’s RS-232 connector.  
(c) You are ready to start taking measurements  
TROUBLESHOOTING  
(1) If your readings appear off-scale, try closing CSAT32 and running it  
again.  
(2) If not communicating with anemometer, make sure RS-232 driver is  
turned on (see CSAT3 SETUP).  
J-3  
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Appendix J. Monitor CSAT3 via RF400 Series  
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Appendix K. RF400/RF410 Pass/Fail  
Tests  
This appendix describes a method to functionally test RF400/RF410 system  
components including:  
PC COM port  
SC12 serial cable  
RF400/RF410  
RF400/RF410 Antenna  
Hardware/Software Required  
9
9
9
9
9
9
PC with one available COM port  
Terminal Program (HyperTerminalTM or ProcommTM  
Two RF400/RF410s  
)
Two SC12 serial cables  
¼ wave OMNI antenna (CSI Item # 14310)  
Two power supplies rated 12 Volts, 1 Amp  
(recommend AC adapter Item # 15966 and any 12 V battery pack with  
Field Power Cable Item # 14291)  
The following descriptions tell how to build an RF400/RF410 loop-back test  
system. Recommendations are given as to where to place the system to avoid  
rf-reflections (see TESTING ¼ Wave Antenna footnote 2 in this appendix).  
The basic parts of the system are:  
1) PC running a terminal program and a serial cable from PC COM port to  
base RF400/RF410  
2) Base RF400/RF410  
3) Remote RF400/RF410 with RS-232 port jumper wire between TX (pin 2)  
and RX (pin 3) for data loop-back.  
Build the RF400/RF410 test system in the order shown:  
1) TESTING SC12 CABLE and PC COM PORT  
2) TESTING RF400/RF410s  
3) TESTING ANTENNAS  
Label components of the system “known-good” as they pass the test.  
TESTING SC12 CABLE and PC COM PORT  
(1) Run a terminal program such as HyperTerminalTM or ProcommTM  
(a) Baud rate: 9600  
(b) Data, Parity, Stop Bits: 8-N-1  
(c) Flow control: none  
K-1  
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Appendix K. RF400/RF410 Pass/Fail Tests  
(d) Emulation: TTY  
(e) ASCII  
(f) COM1 (or any available COM port)  
NOTE  
With some versions of HyperTerminalTM after changing a setting  
it is necessary to do a “Call Disconnect” (or “Disconnect”)  
followed by a “Call Connect” (or “Call”) for the new setting to  
register.  
(2) Connect an SC12 to the selected PC COM port either directly or via  
known-good RS-232 cable.  
(3) Temporarily short together pins 2 and 3 (RX and TX) of the SC12 cable’s  
male connector using a small (22 - 24 gage) copper wire, PC card jumper,  
or flat-bladed screwdriver. Take care to connect only pins 2 and 3.  
End view of male SC12 Connector  
(4) Press any alpha-numeric keys on PC keyboard.  
Make sure that Properties/Settings/ASCII Setup “Echo characters  
locally” or the equivalent ProcommTM setting is NOT enabled.  
NOTE  
(5) If the SC12 cable is good you will see characters “echo” to the screen as  
you press the keys.  
(6) Remove the short circuit from the SC12 connector. Key presses should  
now cease to echo back.  
(7) Test the SC12 cable’s female drop by gently inserting a u-shaped portion  
of paper-clip into pins 2 and 3 and repeating steps 4 to 6 inclusive.  
End view of female SC12 Connector  
Be sure to remove shorts between pins 2 and 3 when  
done.  
CAUTION  
K-2  
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Appendix K. RF400/RF410 Pass/Fail Tests  
TESTING RF400/RF410s  
After verifying the functionality of the terminal program and the integrity of  
the serial cable and COM port, proceed as follows:  
(1) Connect 12V power to an RF400/RF410. This can be from an AC adapter  
(Item # 14220 or Field Power Cable (Item # 14291) with 12V battery pack  
attached (see step 12 below).  
(2) Connect first RF400/RF410’s RS-232 port to the PC COM port  
(3) Run a terminal program such as HyperTerminalTM or ProcommTM  
(a) Baud rate: 9600  
(b) Data, Parity, Stop Bits: 8-N-1  
(c) Flow control: none  
(d) Emulation: TTY  
(e) ASCII  
(f) Desired COM port  
Make sure that Properties/Settings/ASCII Setup “Echo characters  
locally” or the equivalent ProcommTM setting is NOT enabled.  
NOTE  
NOTE  
(4) Press “Program” button on RF400/RF410  
(5) Select “3” to restore defaults, then select “5” to save parameters and exit  
The presence of a neighboring RF400/RF410 network with  
default settings could interfere with your tests (see Section 5.3.1.  
(4.d) for detection method).  
(6) Repeat steps 1 to 5 inclusive with second RF400/RF410  
(7) Label the RF400/RF410 connected to the PC COM port as “Base”  
(8) Place the two RF400/RF410s side by side with antenna connectors 1 1/8  
inches apart on a non-metallic surface (see Figure K-1).  
FIGURE K-1. Loop-back Test without Antennas  
K-3  
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Appendix K. RF400/RF410 Pass/Fail Tests  
(9) Make sure that no antennas are attached to the RF400/RF410s  
(10) Label the other RF400/RF410, “Remote”  
(11) Insert jumper into the Remote RF400/RF410’s RS-232 connector pins 2  
and 3 (using a U-shaped portion of a paper clip) allowing data received  
from base RF400/RF410 to be transmitted back to terminal screen by  
remote RF400/RF410.  
RF400/RF410’s RS-232 Connector (female)  
(12) Connect 12V power to Remote RF400/RF410. This can be supplied by an  
AC adapter (Item # 14220) or Field Power Cable (Item # 14291)  
connected to a 12V battery (battery can be an 8 cell pack of alkaline A, C,  
or D cells, or a lead-acid battery).  
If your 12V power supply is a battery pack or rechargeable  
battery, make sure that the batteries are fresh or well-charged so  
they can supply the 75 mA peak current needed when the  
RF400/RF410 is transmitting in order to obtain valid test results.  
NOTE  
CAUTION  
For safety, people should maintain 20 cm (8 inches)  
distance from antenna while RF400/RF410 is transmitting.  
(13) Type 8 groups of 5 characters on the terminal (aaaaabbbbbccccc etc.)  
(14) You should see 100% of the characters typed echo back to the screen  
TESTING ANTENNAS  
After setting up the terminal program and verifying the integrity of the COM  
port, serial cable, and RF400/RF410s, you are ready to test an RF400/RF410  
antenna. Prepare to test an antenna by:  
Orienting RF400/RF410s so that the antenna connectors are on top  
Fastening RF400/RF410s to cardboard boxes or other non-metallic  
structures maintaining antenna connectors 20 inches above the floor.  
(1) TESTING ¼ Wave Antenna  
(a) Connect 12V power to base RF400/RF410 and remote RF400/RF410.  
We recommend AC adapter Item # 15966 or a Field Power Cable  
Item # 14291 connected to a 12V battery pack or 12V power supply.1  
K-4  
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Appendix K. RF400/RF410 Pass/Fail Tests  
(b) Choose an open area free of large2 metal objects within 10 feet of the  
RF400/RF410s (can be indoors or outdoors).  
(c) Attach a 1/4 wave omni antenna (Item # 14310) to base  
RF400/RF410  
(d) Set up remote RF400/RF410 with NO antenna  
(e) Separate RF400/RF410s by 5 feet  
(f) Type 8 groups of 5 characters on the terminal (aaaaabbbbbccccc etc.)  
(g) You should receive 100% of the characters  
(h) With bad or missing ¼ wave OMNI antenna you should get few to no  
characters echoed back.  
1
Be careful to not exceed maximum supply voltage of 18 VDC to RF400/RF410. Use  
“quiet” power supply without noise or hum (a 12V lead-acid battery is fine, if no trickle  
charger is attached during the tests).  
2
Examples of “large metal objects”: a steel filing cabinet; steel trim on cubicle  
dividers; or steel shelving. Especially avoid such metal objects facing the  
RF400/RF410s broadside. The idea is to avoid significant reflected signals because  
they can add to or subtract from the direct wave signal making test results vary a lot  
according to exact location. A fully absorbent rf environment with no reflections would  
be ideal.  
(2) TESTING YAGI or COLLINEAR ANTENNA  
(a) Connect 12V power to base RF400/RF410 and remote RF400/RF410.  
We recommend AC adapter Item # 15966 or a Field Power Cable  
Item # 14291 connected to a 12V battery pack or 12V power supply  
(see footnote 1 above).  
(b) Choose an open area to conduct the tests (see footnote 2 above).  
(c) Attach the yagi or collinear antenna being tested to base  
RF400/RF410  
(i) A yagi can be mounted on a microphone stand or similar (metal,  
wood or PVC ok). Orient antenna elements vertically as shown  
in figure below and adjust height so the bottoms of the elements  
are 20 inches above floor. Aim yagi at remote RF400/RF410.  
FIGURE K-2. Vertically Polarized 9 dBd 900 MHz Yagi  
(ii) A collinear antenna should be solidly mounted in a vertical  
position so that its omnidirectional “pancake” pattern is  
horizontal. A metal or wooden stand can be used.  
K-5  
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Appendix K. RF400/RF410 Pass/Fail Tests  
FIGURE K-3. 3 dBd 900 MHz Collinear Omni Antenna  
(d) Set up remote RF400/RF410 with NO antenna and with antenna  
connector 20 inches above floor.  
(e) Arrange antenna distance apart according to following table.  
TABLE K-1. 900 MHz Gain Antenna Test Distances  
Distance Apart*  
Antenna  
Gain  
Over ¼ Wave  
Power Ratio  
vs. ¼ Wave  
(
)
5 ft. × Power Ratio  
9 dBd  
6 dBd  
3 dBd  
11.2 dB  
8.2 dB  
5.2 dB  
0 dB  
13.18  
6.61  
3.31  
1.0  
18 ft.  
13 ft.  
9 ft.  
-2.2 dBd  
5 ft.  
* This assumes a signal strength vs. distance relationship of 1/d2  
(f) Type 8 groups of 5 characters on the terminal (aaaaabbbbbccccc etc.)  
(g) 100% of characters should appear on screen with good yagi/collinear  
antenna.  
(h) Removing yagi/collinear antenna, you should get no echoed  
characters.  
K-6  
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Appendix L. RF400/RF410 Average  
Current Drain Calculations  
For remote sites with tight power budgets due to solar or battery power  
supplies, the following will help determine average current consumption. The  
RF400/RF410’s average current drain is based on:  
Standby mode of RF400/RF410  
Data collection interval  
Number of data points collected  
“Time of inactivity to sleep” selection  
STANDBY MODES  
TABLE L-1. Advanced Setup Menu  
STANDBY  
AVG RECEIVE  
CURRENT  
(Is)  
DEFAULT  
TIME OF INACTIVITY  
TO SLEEP  
“LONG  
HEADER”  
LENGTH  
(L)  
STANDBY  
MODE  
(sec)  
01  
32  
43  
5
< 24 mA  
< 4 mA  
----  
5
0 ms  
700 ms  
< 2 mA  
5
1200 ms  
2200 ms  
4200 ms  
8200 ms  
< 1 mA  
5
6
< 0.6 mA  
< 0.4 mA  
5
74  
5
1
Standard Setup menu selection 1  
Standard Setup menu selection 2  
Standard Setup menu selection 3  
Standard Setup menu selection 4  
2
3
4
CALCULATIONS  
BASE  
The average current drain of a base RF400/RF410 configured for scheduled  
collections has 5 contributors:  
1) The STANDBY AVG RECEIVE CURRENT – Is  
2) The average transmit current of LONG HEADER – Ih  
3) The average transmit current of data request transmissions – Iq  
4) The average receive current of data receptions – Ir  
5) The average receive current of “time of inactivity to sleep” – Ii  
L-1  
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Appendix L. RF400/RF410 Average Current Drain Calculations  
The base RF400/RF410’s total average current (It) can be calculated over an  
interval (T) as follows:  
It = Is + Ih + Iq + Ir + Ii  
Is = {table value}  
L (ms)  
Ih =  
Iq =  
Ir =  
× 73 mA  
× 73 mA  
where L is the"long header"length  
T (ms)  
20 (ms)  
T (ms)  
[45 (ms) + 2 ms per data point]  
× 24 mA  
(4 ms per high - res data point)  
T (ms)  
5000 ms  
× 24 mA  
T (ms)  
Ii =  
(using default"time of inactivity to sleep"= 50)  
REMOTE  
The average current drain of a remote RF400/RF410 being collected on  
schedule has 4 contributors:  
1) The STANDBY AVG RECEIVE CURRENT – Is  
2) The average transmit current from data transmission – Id  
3) The average receive current of data request receptions – Ir  
4) The average receive current from “time of inactivity to sleep” – Ii  
The remote RF400/RF410’s total average current (It) can be calculated over an  
interval (T) as follows:  
It = Is + Id + Ir + Ii  
Is = {table mA value}  
[45 (ms) + 2 ms per data point]  
Id =  
Ir =  
× 73mA  
(4 ms per high - res data point)  
T (ms)  
20 (ms)  
T (ms)  
× 24 mA  
5000 ms  
T (ms)  
Ii =  
× 24 mA  
(using default"time of inactivity to sleep"= 50)  
L-2  
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Appendix L. RF400/RF410 Average Current Drain Calculations  
EXAMPLE #1 (Remote RF400/RF410 in default standby mode)  
There is a Point-to-Point system with base RF400/RF410 and remote  
RF400/RF410. The remote station senses weather conditions and sends low-  
resolution data to final storage. The base station collects 10 data points from  
the remote station once per minute. Both stations are configured for “<4 mA,  
½ sec Cycle” (the default standby mode). The remote station operates on solar  
power and we are interested in knowing the average current drain contribution  
of the RF400/RF410. From the above section:  
It = Is + Id + Ir + Ii  
Calculating each term:  
Is = table mA value = 4 mA  
[45 (ms) + 2 N (ms)]  
65 ms  
Id =  
Ir =  
× 73 mA =  
×73 mA = 0.08 mA  
T (ms)  
60,000 ms  
20 (ms)  
× 24 mA = 0.008 mA  
× 24 mA = 2 mA  
60,000 (ms)  
5000 ms  
Ii =  
60,000 (ms)  
It 6.1 mA  
The dominant average current drain contributors are the standby mode current  
and the “time of inactivity to sleep” currents. If large quantities of data per  
minute were being generated/collected, then Id would become a significant  
contributor. In this example the “time of inactivity to sleep” could be reduced  
because only 10 data points are sent per collection. Try a value of 10 instead  
of 50 reducing the Ii contribution from 2 mA to 0.4 mA.  
L-3  
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Appendix L. RF400/RF410 Average Current Drain Calculations  
EXAMPLE #2 (Base RF400/RF410 in default standby mode)  
The base RF400/RF410 in the above example does more receiving and less  
transmitting than the remote RF400/RF410 so you might expect less average  
current drain, however, the amount of data being transmitted per minute is  
small, and the long header required is significant. Here are the results:  
It = Is + Ih + Iq + Ir + Ii  
Calculating each term:  
Is = table mA value = 4 mA  
L (ms)  
T (ms)  
700 ms  
Ih =  
Iq =  
Ir =  
Ii =  
× 73 mA =  
×73 mA = 0.875 mA (default"long header"length = 700 ms)  
60,000 ms  
20 (ms)  
60,000 (ms)  
× 73mA = 0.025 mA  
[45 (ms) + 20 ms]  
× 24 mA = 0.026 mA  
60,000 (ms)  
5000 ms  
× 24 mA = 2 mA  
(using default"time of inactivity to sleep"= 50)  
It 6.9 mA  
60,000 (ms)  
As in Example #1, the standby mode current, long header, and the “time of  
inactivity to sleep” currents dominate the average RF400/RF410 current drains,  
so the calculated values for remote and base RF400/RF410s are nearly equal.  
Larger data collections would make the Ir contribution more significant.  
L-4  
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Appendix L. RF400/RF410 Average Current Drain Calculations  
EXAMPLE #3 (Base RF400/RF410 in “<0.4 mA, 8 sec Delay” standby mode)  
The RF400/RF410s in this example are configured for the lowest possible  
average standby mode current (Advanced Setup Menu selection 7). The same  
amount and frequency of data are collected as in Example 1.  
It = Is + Ih + Iq + Ir + Ii  
Calculating each term:  
Is = table mA value = 0.4 mA  
L (ms)  
T (ms)  
8200 ms  
Ih =  
Iq =  
Ir =  
× 73 mA =  
×73 mA = 10 mA ("long header"length = 8200 ms)  
60,000 ms  
20 (ms)  
60,000 (ms)  
× 73mA = 0.025 mA  
[45 (ms) + 20 ms]  
× 24 mA = 0.026 mA  
60,000 (ms)  
5000 ms  
Ii =  
× 24 mA = 2 mA  
(using default"time of inactivity to sleep"= 50)  
60,000 (ms)  
It 12.4 mA  
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Appendix L. RF400/RF410 Average Current Drain Calculations  
EXAMPLE #4 (Remote RF400/RF410 in “<0.4 mA, 8 sec Delay” standby mode)  
The RF400/RF410s in this example are configured for the lowest possible  
average standby mode current (Advanced Setup Menu selection 7). The same  
amount and frequency of data are collected as in Example 1.  
It = Is + Id + Ir + Ii  
Calculating each term:  
Is = table mA value = 0.4 mA  
[45 (ms) + 2 N (ms)]  
65 ms  
Id =  
Ir =  
× 73 mA =  
×73 mA = 0.08 mA  
T (ms)  
60,000 ms  
20 (ms)  
× 24 mA = 0.008 mA  
× 24 mA = 2 mA  
60,000 (ms)  
5000 ms  
Ii =  
60,000 (ms)  
It 2.4 mA  
In this example the dominant average current drain contributor becomes the  
“time of inactivity to sleep” current.  
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Appendix L. RF400/RF410 Average Current Drain Calculations  
EXAMPLE #5 (Base RF400/RF410 in default “<4 mA, 1 sec Delay” standby mode)  
The RF400/RF410s in this example are configured for the default average  
standby mode current. The same amount of data (10 data points) are collected  
as in Example 1, however the frequency of collection is changed from once a  
minute to once an hour.  
It = Is + Ih + Iq + Ir + Ii  
Calculating each term:  
Is = table mA value = 4 mA  
L (ms)  
T (ms)  
700 ms  
Ih =  
× 73 mA =  
× 73 mA = 0.014 mA ("long header" = 700 ms)  
3,600,000 ms  
20 (ms)  
Iq =  
Ir =  
Ii =  
×73 mA = 0.0004 mA  
× 24 mA = 0.0004 mA  
3,600,000 (ms)  
[45 (ms) + 20 ms]  
3,600,000 (ms)  
5000 ms  
× 24 mA = 0.033 mA  
(using default"time of inactivity to sleep"= 50)  
3,600,000 (ms)  
It 4.1 mA  
L-7  
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Appendix L. RF400/RF410 Average Current Drain Calculations  
EXAMPLE #6 (Base RF400/RF410 in “<0.4 mA, 8 sec Delay” standby mode)  
The RF400/RF410s in this example are configured for the lowest possible  
average standby mode current (Advanced Setup Menu selection 7). The same  
amount of data are collected as in Example 1, however the frequency of  
collection is changed from once a minute to once an hour.  
It = Is + Ih + Iq + Ir + Ii  
Calculating each term:  
Is = table mA value = 0.4 mA  
L (ms)  
T (ms)  
8200 ms  
Ih =  
× 73mA =  
× 73mA = .17 mA ("long header"length = 8200 ms)  
3,600,000 ms  
20 (ms)  
Iq =  
Ir =  
×73 mA = 0.0004 mA  
× 24 mA = 0.0004 mA  
3,600,000 (ms)  
[45 (ms) + 20 ms]  
3,600,000 (ms)  
5000 ms  
Ii =  
× 24 mA = 0.033 mA  
(using default"time of inactivity to sleep"= 50)  
3,600,000 (ms)  
It 0.6 mA  
L-8  
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Appendix L. RF400/RF410 Average Current Drain Calculations  
EXAMPLE #7 (Remote RF400/RF410 in “<0.4 mA, 4 sec Cycle” standby mode )  
The RF400/RF410s in this example are configured for the lowest possible  
average standby mode current (Advanced Setup Menu selection 7). The same  
amount of data are collected as in Example 1, however the frequency of  
collection is extended to once an hour.  
It = Is + Id + Ir + Ii  
Calculating each term:  
Is = table mA value = 0.4 mA  
[45 (ms) + 2 N (ms)]  
65 ms  
Id =  
Ir =  
× 73 mA =  
×73 mA = 0.001mA  
T (ms)  
3,600,000 ms  
20 (ms)  
× 24 mA = 0.0001mA  
× 24 mA = 0.033 mA  
3,600,000 (ms)  
5000 ms  
Ii =  
3,600,000 (ms)  
It 0.43 mA  
SUMMARY  
Choosing a lower current standby mode does not always result in an overall  
lower average current for the base RF400/RF410 because, by selecting a lower  
current standby mode, the base RF400/RF410 must generate a longer “long  
header” which involves more transmit time at 73 mA. However, the remote  
site will normally benefit from a lower standby mode current since it does not  
usually transmit a “long header.”  
If the remote station is doing call-backs, then the remote RF400/RF410 must  
initiate the connection by sending a “long header” so the remote  
RF400/RF410’s average current drain may be higher than that of the base  
RF400/RF410. Data collection may be a mixture of scheduled calls and call-  
backs (possibly event driven).  
As collection intervals become longer, the effects of “time of inactivity to  
sleep” and data amount lessen and the average current drain approaches the  
stated standby mode current.  
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Appendix L. RF400/RF410 Average Current Drain Calculations  
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