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iLD BigDisplay
Monitor/Controller
Embedded Ethernet
TABLE OF CONTENTS
Part 1: Introduction
1.1
Safety and EMC Considerations........................................................................2
1.2
Description ..........................................................................................................3
Part 2: Hardware
2.1
2.2
2.3
2.4
Physical Characteristics and Mounting ...........................................................4
Rear Panel of Meter with Embedded Ethernet Server .....................................4
DIP Switches on the iServer...............................................................................5
Serial Communication Interfaces (For Models with RS485 Port) ...................6
2.4.1
Wiring RS485 Interface ........................................................................7
2.5
Network Communication Interfaces .................................................................8
2.5.1
2.5.2
10Base-T RJ-45 Pinout.........................................................................8
10Base-T Crossover Wiring.................................................................8
Part 3: Network Configuration
3.1
3.2
3.3
3.4
3.5
Network Protocols .............................................................................................9
Ethernet (MAC) Address ....................................................................................9
DHCP
DNS
.............................................................................................................10
.............................................................................................................10
IP Address .........................................................................................................11
3.5.1
Default IP Address ..............................................................................11
3.6
Port Number.......................................................................................................11
Part 4: Operations
4.1
4.2
4.3
Serial Interface Configuration-Communication Protocol..............................12
Command Structure..........................................................................................12
Command Formats ...........................................................................................12
4.4
Operations .........................................................................................................14
4.5
Setup and Operation using a Web Browser ..................................................14
4.5.1
Read Devices .....................................................................................16
4.5.1.1 Device Setpoints ................................................................................16
4.5.2
4.5.3
Send Raw Command..........................................................................16
Device Setup .......................................................................................17
4.5.3.1 Modify Device Parameters (or Device List Entry)............................17
4.5.4
4.5.5
Configuration ......................................................................................18
Access Control ..................................................................................21
4.6
Setting a New IP Address over the Network ..................................................23
Terminal Server Function ................................................................................24
Terminal Emulation...........................................................................................25
Telnet Setup ......................................................................................................26
HTTPGET Program............................................................................................28
ARP Protocol .....................................................................................................29
Remote Access (Tunneling) .............................................................................30
4.12.1 Remote iServer ..................................................................................31
4.12.2 Local iServer ......................................................................................32
Mail Notifier Software .......................................................................................33
4.13.1 Installation...........................................................................................33
4.13.2 Program Options Setup and Configuration ....................................34
4.13.3 Device Setting Setup and Configuration..........................................35
4.7
4.8
4.9
4.10
4.11
4.12
4.13
Part 5: Specifications .................................................................................................................. 36
Part 6: Factory Preset Values ......................................................................................................37
Appendix A
Appendix B
Appendix C
Appendix D
Glossary.............................................................................................................38
IP Address ........................................................................................................39
IP Netmask.........................................................................................................40
ASCII Chart .......................................................................................................41
ASCII Chart Control Codes .............................................................................42
Part 7: Approvals Information
7.1
7.2
Electromagnetic Compatibility (EMC) ............................................................43
FCC
..............................................................................................................43
i
LIST OF FIGURES:
Figure 1.1
Figure 2.1
iServer on the Ethernet Network.................................................................3
Rear Panel View of i16 and i8 Series Meters with
Embedded Ethernet Server .........................................................................4
DIP Switches on the iServer........................................................................5
Multi-point, Half-Duplex RS485 Wiring.......................................................7
RJ45 Pinout ..................................................................................................8
10Base-T Crossover Cable Wiring .............................................................8
Labeling ........................................................................................................9
DIP Switch on the iServer .........................................................................10
Pinging eis03ec MS-DOS Prompt ............................................................14
Device Type ............................................................................................... 15
iServer Home Page Menu .........................................................................15
Login and Administrator Password .........................................................15
Read Devices ............................................................................................ 16
Device Setpoints ...................................................................................... 16
Serial Device Query .................................................................................. 16
Device Setup ............................................................................................. 17
Modify Device Parameters ....................................................................... 17
Configuration ............................................................................................ 18
Access Control ......................................................................................... 21
Access Control .........................................................................................23
Terminal Server Configuration .................................................................24
Terminal Emulation ....................................................................................25
Tera Term Telnet Connection Screen ......................................................26
Telnet Setup Menu - iServer Configuration Page ...................................26
Telnet Setup Menu - iServer Help Page ...................................................27
ARP Commands and Responses .............................................................29
PC-to-Device Communication...................................................................30
Device-to-Device Communication ............................................................30
Configuration Menu - Remote iServer......................................................31
Configuration Menu - Local iServer..........................................................32
iServer Mail Notifier Main Window............................................................33
iServer Mail Notifier Profile Setup ............................................................34
iServer Mail Notifier Device Setting .........................................................35
Figure 2.2
Figure 2.3
Figure 2.4
Figure 2.5
Figure 3.1
Figure 3.2
Figure 4.1
Figure 4.2
Figure 4.3
Figure 4.4
Figure 4.5
Figure 4.6
FIgure 4.7
Figure 4.8
Figure 4.9
Figure 4.10
Figure 4.11
Figure 4.12
Figure 4.13
Figure 4.14
Figure 4.15
Figure 4.16
Figure 4.17
Figure 4.18
Figure 4.19
Figure 4.20
Figure 4.21
Figure 4.22
Figure 4.23
Figure 4.24
Figure 4.25
LIST OF TABLES:
Table 2.1
Table 2.2
Table 2.3
Rear Panel Annunciators ............................................................................5
Data Transmission Characteristics RS485 ...............................................6
RS485 Half-Duplex Hookup.........................................................................7
Table 4.1
Table 4.2
Command Prefix Letters ...........................................................................12
Command Formats ....................................................................................12
ii
NOTES, WARNINGS and CAUTIONS
Information that is especially important to note is identified by following labels:
• NOTE
• WARNING or CAUTION
• IMPORTANT
• TIP
NOTE: Provides you with information that is important to successfully
setup and use the iServer.
CAUTION or WARNING: Tells you about the risk of electrical shock.
CAUTION, WARNING or IMPORTANT: Tells you of circumstances or
practices that can effect the instrument’s functionality and must refer
to accompanying documents.
TIP: Provides you helpful hints.
Before You Begin
Inspecting Your Shipment:
Remove the packing slip and verify that you have received everything listed. Inspect the
container and equipment for signs of damage as soon as you receive the shipment. Note
any evidence of rough handling in transit. Immediately report any damage to the shipping
agent. The carrier will not honor damage claims unless all shipping material is saved for
inspection. After examining and removing the contents, save the packing material and
carton in the event reshipment is necessary.
Customer Service:
If you need assistance, please contact the Customer Service Department nearest you.
Manuals, Software:
The latest Operation Manual as well as free configuration software and iServer Mail
Notifier are available at the website listed on the cover page of this manual or on the
CD-ROM enclosed with your shipment.
1
PART 1
INTRODUCTION
1.1 Safety and EMC Considerations
This device is marked with the international caution symbol. It is important to
read this manual before installing or commissioning this device as it contains
important information relating to Safety and EMC (Electromagnetic
Compatibility).
This instrument is a panel mount device protected in accordance with EN 61010-
1:2001, electrical safety requirements for electrical equipment for measurement,
control and laboratory. Installation of this instrument should be done by qualified
personnel. In order to ensure safe operation, the following instructions should be
followed.
This instrument has no power-on switch. An external switch or circuit-breaker
shall be included in the building installation as a disconnecting device. It shall be
marked to indicate this function, and it shall be in close proximity to the
equipment within easy reach of the operator. The switch or circuit-breaker shall
meet the relevant requirements of IEC 947–1 and IEC 947-3 (International
Electrotechnical Commission). The switch shall not be incorporated in the main
supply cord.
Furthermore, to provide protection against excessive energy being drawn from
the main supply in case of a fault in the equipment, an overcurrent protection
device shall be installed.
•
Do not exceed voltage rating on the label located on the top of the
instrument housing.
•
•
Always disconnect power before changing signal and power connections.
Do not use this instrument on a work bench without its case for safety
reasons.
•
•
•
Do not operate this instrument in flammable or explosive atmospheres.
Do not expose this instrument to rain or moisture.
Unit mounting should allow for adequate ventilation to ensure instrument
does not exceed operating temperature rating.
Use electrical wires with adequate size to handle mechanical strain and
power requirements. Install without exposing bare wire outside the connector
to minimize electrical shock hazards.
•
EMC Considerations
•
•
•
•
Whenever EMC is an issue, always use shielded cables.
Never run signal and power wires in the same conduit.
Use signal wire connections with twisted-pair cables.
Install Ferrite Bead(s) on signal wires close to the instrument if EMC
problems persist.
Failure to follow all instructions and warnings may result in injury!
2
1.2 Description
This iServer board can be purchased as a stand alone unit, or as an option
for an iLD monitor/controller (Embedded Ethernet iServer) with a RS485
communication port interface. Some iLD Big Display monitors/controllers
do not utilize RS485 communications. In such models, the RS485
instructions do not apply.
The Embedded Ethernet Server is designed to connect industrial devices with serial
interfaces to the Ethernet network using the TCP/IP protocol. It contains an Ethernet
Server and RS-485/422 interfaces.
The standard features include:
• Use standard Web Browser, TCP connection, HTTPGET DOS program or Telnet
Simulation for network connectivity.
• Install via RS-485/422 serial port connection.
• Transfer data from RS-485/422 serial interface to TCP/IP using built-in socket server.
• Use a standard home page or customize web page using special applets, which are
available on our Web site.
The following example illustrates how you can hookup the devices with serial interface
on the net using the Ethernet Server:
COMPUTER
COMPUTER
(COM Port
Redirector)
COMPUTER
(Standard
Web Browser)
(Telnet or
IP-enabled
Programs)
COMMUNICATIONS
ETHERNET
RESET
RX TX ON COL
DC POWER IN
+
-
N/C
Figure 1.1 iServer on the Ethernet Network
3
PART 2
HARDWARE
2.1 Physical Characteristics and Mounting
For physical dimensions and installation instructions see the Quickstart Manual.
2.2 Rear Panel of Meter with Embedded Ethernet Server
Communication Port
TB4
AC
DC REMOTE
PWR PWR PROGRAMMER
COMMUNICATION
OUTPUTS
TB5
T/C INPUT
TB7 TB8
INPUTS
TB9
1
2
3
4
5
6
TB1 TB2
TB3
TB4
PJ3
1 2 3
L N
1 2 1 2 3 4 5
+ -
1 2 3
1 2 3 4 5 6
OUTPUT2 OUTPUT1
1 2 3 4 5 6 7 8
+ -
RTN Rx Tx
1 2 3 4 5 6
TB5A TB5B TB5C
1 2
3 4 5 6
OUTPUT2
OUTPUT1
iLD24 OUTPUTS
Figure 2.1 Rear Panel View of Meter
with Embedded Ethernet Server
4
2.3 DIP Switches on the iServer
For Dipswitch access you must remove the main board from the case. Refer to the
Disassembly Instructions in your iLD Big Display Monitor/Controller Quickstart Manual.
1 To change the IP address
from the serial port
2 To change to default factory
settings
ON
ON
3 To enable/disable DHCP
1
2
4 To enable/disable Terminal
OFF
3
4
1
Server function
2
OFF
3
4
The iServer is shipped with all DIP
switches in "OFF" position
Figure 2.2 DIP Switches on the iServer
Table 2.1 Rear Panel Annunciators
Serial Communication Interface Section (For Models with RS485):
TB4 Pin 3
TB4 Pin 2
TB4 Pin 1
-Rx/Tx
+Rx/Tx
Return, Common Ground Shield connection
Network Communication Interface Section:
ETHERNET
RESET
RJ45 interface for 10BASE-T connection.
Button: Used for power reseting the iServer.
COL / ACTIVITY LED (Red) Blinking: Indicates network activities (receiving or sending packets).
ON / NET LINK LED (Green) Solid: Indicates good network link.
TX
RX
LED (Yellow) Blinking: Indicates transmitting data to the serial port.
LED (Green) Blinking: Indicates receiving data on the serial port.
5
2.4 Serial Communication Interfaces (For Models with RS485 Port)
The iLD Big Display controller/monitor with the Embedded Ethernet Server option board
support only RS485/422 interfaces. These standards define the electrical characteristics
of a communication network. The RS485 port of the Ethernet Server is fully compatible
for use with RS422 instruments. The RS485 is an extended version of the RS422
communication standard which increases the allowable number of devices from 10 to
32 by improving the electrical characteristics.
• The RS485 standard (multi-point) allows one or more devices (multi-dropped) to be
connected to the Ethernet Server using a two-wire connection (half-duplex) +Rx/+Tx
and –Rx/-Tx. Use of RS485 communications allows up to 32 devices to connect to the
Web Server with cable length up to 4000 feet long.
Although the RS485 is commonly referred to as a "two wire" connection, the
Web Server also provides a ground/return shield connection to use as a
common connection for EMI noise protection.
Table 2.2 shows some characteristics of the RS485 communication interface.
Table 2.2 Data Transmission Characteristics RS485
Data Transmission Characteristics
Transmission Mode
RS485
Differential
2 wire
Electrical connections
Drivers per line
32 drivers
Receivers per line
32 receiver
10M bits/s
4000 ft (1200 meters)
Maximum data rate
Maximum cable length
6
2.4.1 Wiring RS485 Interface
RS485 interface uses a two-wire communication system (one for transmitting and one for
receiving) plus a common wire to connect to the shield of the cable. It is recommended
to use a shielded cable with one twisted pair.
Use of twisted pair and shield will significantly improve noise immunity.
Figure 2.3 shows multi-point, half-duplex RS485 interface connections for the iServer.
DEVICE #1
DEVICE #29
.........................
.........................
iLD Big Display TB4
1 2 3
DEVICE #31
-Tx/-Rx
-Tx/-Rx
+Tx/+Rx
+Tx/+Rx
GND
Twisted shielded pair
120 Ohm
...............................
Termination resistor
...............................
DEVICE #2 DEVICE #30
Figure 2.3 Multi-point, Half-Duplex RS485 Wiring
Value of the termination resistor is not critical and depends on the cable
impedance.
Table 2.3 shows RS485 half-duplex hookup between the iServer serial port and device
with RS485 communication interface.
Table 2.3 Half Duplex Hookup
TB4 Pin#
Pin 2
Pin 3
iLD Big Display
DEVICE # WITH RS485
+Tx/+Rx (+Transmit/+Receive)
-Tx/-Rx (-Transmit/-Receive)
GND (Common GND)
+Tx/+Rx (+Transmit/+Receive)
-Tx/-Rx (-Transmit/-Receive)
RTN (Common GND)
Pin 1
7
2.5 Network Communication Interfaces
2.5.1 10Base-T RJ-45 Pinout
The 10BASE-T Ethernet network (RJ-45) system is used in the iServer for network
connectivity. The 10 Mbps twisted-pair Ethernet system operates over two pairs of wires.
One pair is used for receiving data signals and the other pair is used for transmitting data
signals. This means that four pins of the eight-pin connector are used.
Pin
1
2
3
4
5
6
7
8
Name
+Tx
-Tx
+RX
N/C
N/C
-Rx
Description
+ Transmit Data
- Transmit Data
+ Receive Data
Not Connected
Not Connected
- Receive Data
Not Connected
Not Connected
N/C
N/C
Figure 2.4 RJ45 Pinout
2.5.2 10Base-T Crossover Wiring
When connecting the iServer directly to the computer, the transmit data pins of the
computer should be wired to the receive data pins of the iServer, and vice versa. The
10Base-T crossover cable with pin connection assignments are shown on Figure 2.5.
Figure 2.5 10Base-T Crossover Cable Wiring
Use straight through cable for connecting the iServer to an Ethernet hub.
The ports on the hub are already crossed.
8
PART 3
NETWORK CONFIGURATION
3.1 Network Protocols
The iServer can be connected to the network using standard TCP/IP protocols. It also
supports ARP, HTTP (WEB server), DHCP, DNS and Telnet protocols.
3.2 Ethernet (MAC) Address
MAC (Media Access Control) address is your computer's unique hardware number.
When you're connected to the LAN from your computer, a correspondence table relates
your IP address to your computer's physical (MAC) address. The MAC address can be
found on the label of your device and contains 6 bytes (12 characters) of hexadecimal
numbers XX:XX:XX:XX:XX:XX hex
For example: 0A:0C:3D:0B:0A:0B
Remove the small label with the default IP address and there will be room to put
your IP address. See Figure 3.1.
MODEL/SERIAL LABEL
MODEL NO:
SERIAL NO:
INPUT POWER:
IP:
REMOVE DEFAULT IP
ADDRESS LABELAND PUT
NEW CUSTOMER'S
IP ADDRESS
#.#
#.#
MAC ADDRESS
LABEL IN
HEX CODE
MICRO-PROC
VERSION #
iSERVER'S
VERSION #
Figure 3.1 Labeling
9
3.3 DHCP
DHCP, Dynamic Host Configuration Protocol enables individual computers or devices to
extract their IP configurations from a server (DHCP server). If the DHCP is enabled on
your iServer, as soon as the iServer is connected to the network, there is an exchange of
information between DHCP server and the iServer. During this process the IP address,
the Gateway address, and the Subnet Mask will be assigned to the iServer by the DHCP
server. Note that the DHCP server must be configured correctly to do such assignment.
If fixed or static IP address is desired, the DHCP must be disabled. The iServer is
shipped with DHCP disabled (factory default). The DHCP can be enabled by setting the
DIP switch # 3 to the “ON” position.
ON
ON
1
2
OFF
3
4
1
2
OFF
3
4
Figure 3.2 DIP Switch on the iServer
3.4 DNS
DNS, Domain Name System enables individual computers and devices to be recognized
over a network based on a specific name instead of an IP address. For example, instead
any eight character name stored as Host Name under Access Control menu in the
iServer Home Page. The default DNS name for an iServer is "eis" followed by the last
four digits of the MAC address of that particular iServer.
1. It is very important to communicate with the network administrator in order to
understand the DHCP and its existing configurations on the host server,
before enabling the DHCP on the iServer.
2. The iServers are shipped with a default static IP address of
192.168.1.200 and Subnet Mask of 255.255.255.0.
3. On Novell networks or Windows 2000 where the DCHP is an updated
function of DNS this feature may be beneficial since a particular name can be
assigned eliminating the need for the IP address, as described in Section 3.4.
10
3.5 IP Address
Every active device connected to the TCP/IP network must have a unique IP address.
This IP address is used to build a connection to the iServer’s serial port. Every computer
using TCP/IP should have a unique 32-bit address. It is divided into two portions, the
network ID and the host ID. For instance, every computer on the same network uses the
same network ID. At the same time, all of them have a different host ID. For more details
about the IP address see Appendix B.
3.5.1 Default IP Address
The iServer is shipped with a default IP address set to 192.168.1.200 and Subnet Mask
of 255.255.255.0. If you are going to use a Web browser or Telnet program to access
the iServer using its default IP address, make sure that the PC from which you’re
establishing the connection has an IP address that is in the same range as the iServer’s
IP address (192.168.1.x, where x can be any number from 1 to 254.
Your PC’s IP address cannot be the same as the iServer’s IP address).
You also need to make sure that your PC’s Subnet Mask is 255.255.255.0. This is a
good way to access the iServer over the network and make any configuration changes
needed. If the factory default address is already in use on your network, use an Ethernet
crossover cable between your computer and the iServer and modify the IP address or
any other settings within the iServer.
3.6 Port Number
All TCP connections are defined by the IP address and a port number. A port number is
an internal address that provides an interface between an application running on your
computer and the network through the TCP/IP protocol.
There are three default TCP socket port numbers assigned to the iServer:
1. Port (socket) number 1000 when using HTTPGET program.
2. Port (socket) number 2000 when trying to access your serial device connected to
the serial port of the iServer.
3. Port (socket) number 2002 when trying to access the iServer itself for reading or
changing the settings. This can be done using Telnet application.
Example: C:\>Telnet 192.168.1.200 2002
11
PART 4
OPERATIONS
An industrial device with serial interfaces (PLC, CNC controllers, PC, Data Display
Devices, etc.) can be connected to the serial port of the Web Server.
4.1 SERIAL INTERFACE CONFIGURATION - Communication Protocol
A data communication protocol defines the rules and structure of messages used by all
devices on a network for data exchange. A typical transaction will consist of a request to
send from the MASTER followed by the response from one or more SLAVE devices.
Either a single (point-to-point) or multi-drop network (multi-point) is possible.
4.2 Command Structure
There are different command types associated with communication between the
Ethernet Server and your device shown in Table 4.1, which shows the Command Prefix
Letters (Command Classes)
Table 4.1 Command Prefix Letters
COMMAND PREFIX
(COMMAND CLASS) MEANING
^AE
Special read, Communication parameters
Write HEX data into RAM
Write HEX data into EEPROM.
Read HEX data from RAM
Read HEX data from EEPROM
Read status byte
Read measurement data string in decimal format
Read measurement data values in decimal format
Disable
P (Put)
W (Write)
G (Get)
R (Read)
U
V
X
D
E
Z
Enable
Reset
4.3 Command Formats
Table 4.2 shows the command formats for the Ethernet Server.
Table 4.2 Command Formats
For "P" and "W" Command For "G" and "R" Command For "X", "V", "U", "D", "E",
classes:
classes:
Point-to-point mode
* ccc <cr>
Multi-point mode
* nnccc <cr>
& "Z" Command classes:
Point-to-point mode
* ccc <cr>
Multi-point mode
* nnccc <cr>
Point-to-point mode
* ccc<data><cr>
Multi-point mode
* nnccc [<data>]<cr>
12
Where:
"*" is the selected Recognition Character. You may select any ASCII table symbol from
"!" (HEX address "21") to the right-hand brace (HEX "7D") except for the caret "^", "A",
"E", which are reserved for bus format request.
"ccc" stands for the hex-ASCII Command Class letter (one of eleven given in Table 4.1),
followed by the two hex-ASCII Command Suffix characters identifying the meter data,
features, or menu items to which the command is directed.
"<data>" is the string of characters containing the variable information the computer is
sending to the meter. These data (whether BCD or binary) are encoded into hex-ASCII
character (see Appendix D for binary-hex-ASCII chart), two characters to the byte.
Square brackets [indicating optional status] enclose this string, since some commands
contain no data.
"<nn>" are the two ASCII characters for the device Bus Address of RS485 communication.
Use values from "00" to hex "C7" (199 decimal).
The following format is used for each byte sent and received through serial port of
Ethernet Server:
1. Seven or Eight-bit binary, Hexadecimal (0 ... 9, A ... F)
2. Two hexadecimal characters contained in each eight-bit field of the message
3. 1 start bit; 7 or 8 data bit; 1 Stop Bit; Odd, Even (No Parity) Bit
The figure below shows the bit sequences when a byte is transmitted or received
through the Ethernet Server.
LSB
1
MSB
8
START
2
3
4
5
6
7
STOP PARITY
LSB – Least Significant bit
MSB – Most Significant bit
Least Significant beat sent first
13
4.4 OPERATIONS
This iServer can be used and configured in several ways, depending on user’s
preference and network setup. It can be used in Telnet simulation mode where it
emmulates serial communication operation over a network cable or directly from a Web
browser, like Netscape or Internet Explorer.
If DHCP and DNS servers are used, the connection is very simple, you do not need to
worry about IP address, MAC address, or network conflicts, all of these issues are solved
for you by your network DHCP and DNS server. All that is left for you to do, is to use a
straight/normal network cable to connect the device to a hub and power it up. Then you
can go to your computer that is connected over the same network and from the MS-DOS
Prompt window type "ping eisxxxx" followed by the last four digits from the MAC address
located on the side or back of the device.
C:\>ping eis03ec
Pinging eis03ec with 32 bytes of data:
Reply from eis03ec: bytes=32 time=15ms TTL=60
Reply from eis03ec: bytes=32 time=8ms TTL=60
Reply from eis03ec: bytes=32 time=8ms TTL=60
Reply from eis03ec: bytes=32 time=8ms TTL=60
Pinging statistics for eis03ec:
Packets: Sent=4, Received=4, Lost=0 (0% loss)
Approximate round trip times in milli-seconds:
Minimum=8ms, Maximum=15ms, Average=9ms
Figure 4.1 Pinging eis03ec MS-DOS Prompt
This proves that the connection is proper and you can get into configuration or run mode
using the Telnet or Web browser.
4.5 Setup and Operation Using a Web Browser
a) Start your web browser.
address label located on the device if DHCP and DNS are used. If a static IP address
c) The Home Page, shown below, will be displayed.
d) From the drop-down window you can select the type of device connected (iSeries,
iDRN, iDRX, iR2, INFB, or iLD) then press Update to get to the Home Page.
14
4.5 Setup and Operation Using a Web Browser (continued)
iSERVER
iSERVER
Device Type Selection:
iSeries
iDRN
iDRX
iR2
INF-B
iLD
Update
Reset
Firmware Version x.x
Figure 4.2 Device Type
SERVER HOME PAGE
Address
SERVER HOME PAGE
Read Devices
Terminal Emulation
Device Setup
Configuration
Serial Device Query
Access Control
Figure 4.3 iServer Home Page Menu
In order to access certain menu items of the iServer Home Page, users may be
prompted for a Login Password.
LOGIN
ADMINISTRATOR
LOGIN
ADMINISTRATOR
Figure 4.4 Login and Administrator Passwords
Login Password: This allows users to access and modify all of the iServer Home Page
menu items, except “Access Control”, which requires an Administrator password (refer to
Section 4.5.5). The “Read Devices” does not require a password.
The default Login password is 12345678. This password can be up to 16 alpha-numeric
case-sensitive characters.
15
4.5.1 Read Devices
• Read variables from up to eight different devices.
• Read up to eight variables from the same device.
• Read and write the setpoint values to the device.
READ DEVICES
Address
READ DEVICES
092.4 Deg. C
1. iSeries1
092.4 Deg.C
If you have 000, click the Auto Update
button to manually refresh the page.
If you want to change the time
interval of the page refresh, enter the
amount of seconds in the box.
Auto Update
000
Click on Device No. on the left to query/change Device Setpoints
Main Menu
Figure 4.5 Read Devices
4.5.1.1 Device Setpoints
• When you click on Device No in the Read Device Page, you can edit the Setpoints.
DEVICE SETPOINTS
Address
DEVICE SETPOINTS
Device No. (R01)
Setpoint #1: 0.
Setpoint #2: 0.
Setpoint #3: 0.
Setpoint #4: 0.
Update Reset
Main Menu
Figure 4.6 Device Setpoints
4.5.2 Send Raw Command
• Send single command and receive response.
SERIAL DEVICE QUERY
Address
SERIAL DEVICE QUERY
Send
Command
Response
*01 X01
01X01092.4
Figure 4.7 Serial Device Query
16
4.5.3 Device Setup
• Device Setup helps you to see eight different variables or devices by “Check” box.
• Up to four different devices or parameters can be modified.
• Device Address or ID is in Hex format. See Appendix D for conversion.
DEVICE SETUP
Address
DEVICE SETUP
Display
Format
decimal
raw
No. Check Device Name Address Reading SP1 SP2 SP3 SP4 Display Units
Click on numbers for
Device Parameters
1
2
3
4
5
6
7
8
iSeries 1
*01
*01
*01
*01
*01
*01
*01
*01
X01
X01
X01
X01
X01
X01
X01
X01
R01 R02
Deg. C
ABCDEFGH
ABCDEFGH
ABCDEFGH
ABCDEFGH
ABCDEFGH
ABCDEFGH
ABCDEFGH
R01 R02 R03 R04 ABCDEFGH
R01 R02 R03 R04 ABCDEFGH
R01 R02 R03 R04 ABCDEFGH
R01 R02 R03 R04 ABCDEFGH
R01 R02 R03 R04 ABCDEFGH
R01 R02 R03 R04 ABCDEFGH
R01 R02 R03 R04 ABCDEFGH
raw
raw
raw
raw
raw
raw
Click on Device No. on the left to modify Device Parameters.
Update Checked Box
Take Readings
Main Menu
Figure 4.8 Device Setup
4.5.3.1 Modify Device Parameters (or Device List Entry)
DEVICE PARAMETERS
Address
MODIFY DEVICE PARAMETERS
Device No. 1
Device Address
*01
Device Name iSeries 1
Reading Command X01
SP1 Command R01
SP2 Command R02
SP3 Command
SP4 Command
Display Units Deg. C
raw
Display Format
Update Reset
Cancel
Main Menu
Figure 4.9 Modify Device Parameters
17
4.5.4 Configuration
• This section explains the Configuration page of the iServers’s Web interface.
• When connecting your device to the iServer, the Serial Communications parameters
must match, between the iServer and your serial device.
CONFIGURATION
Address
CONFIGURATION
Serial Communication
Baud Rate 9600
Flow Control none
Data Bit 7 Bits Parity odd
Stop Bits 1 bit
Transciever RS-485
Modbus/TCP disable
A
B
C
Timeout
End Character (Hex) 0D Forward End Char enable
0500 msecs
Serial Port Password disable 1234abcd
Terminal Server
Server Type slave
TCP/UDP TCP
Number of Connections
Local Port 02000
0
Connection Ctrl not used
Connection Timeout 00100 msecs
Device No.
1
Remote Access (Tunneling)
Remote Access
Remote IP Address 0.0.0.0
Remote Port 02000
disable
Save Reset
Main Menu
Figure 4.10 Configuration
4.5.4.A Serial Communication
Baud Rate: The speed on the serial port and can be set from 300 to 115,200 bits/s
(default is 9600 bits/s.)
Data Bit: Options are 7 or 8 (default is 7 bits.)
Parity: Options are Odd, Even, and None (default is Odd.)
Stop Bits: Options are 1 and 2 bits (default is 1 bit.)
Flow Control: Options are Software Flow Control (Xon/Xoff), Hardware Flow Control
(CTS/RTS), and None (default is None.)
18
4.5.4.A Serial Communication (continued)
Transceiver: Can either be set to RS-232 or two-wire RS-485 (default is RS-485.)
Modbus/TCP: A widely used protocol mainly in industrial automation applications with default
TCP port number of 502 (see Local Port field). The options are Enable and Disable. If enabled,
the Modbus/TCP is the only protocol driven by the iServer on its LAN port. If disabled, the
TCP/IP is the only protocol driven by the iServer on its LAN port (default is disable).
End Character: When the defined Hex character is received by the iServer on its serial
port, the iServer will forward the buffered serial data to the Ethernet. The default value is
00, which forces the iServer to forward the data to the Ethernet as it receives the data on
its serial port (this means that the iServer requires NO “end character” to forward the data).
Forward End Char: If enabled, the iServer will send the End Character out to the
Ethernet as part of the data. If disabled, the iServer will not count the End Character as
part of the data and will drop it (default is enabled.)
Timeout: In RS232 connection, if the iServer does not receive any more serial data within
the given time value, the iServer will forward the buffered serial data to the Ethernet. For
example, if the Timeout is set to 200 ms, the iServer will send out the buffered serial data to
the LAN, if it does not receive any more data on its serial port for a period of 200 ms.
In RS485 connection, the Timeout value is used to switch between serial transmit and
receive mode. Since the iServer supports 2-wire RS485, it needs to either transmit or
receive serial data and the Timeout value determines the time interval for each. The
range can be from 0 to 9999 ms (default is 500 ms).
4.5.4.B Terminal Server
TCP/UDP: The iServer supports TCP and UDP protocol (default is TCP). If UDP is
selected, it can be configured either for Broadcast UDP or Directed UDP. In case of
Broadcast UDP, the iServer will transmit the serial data to every node on the network.
This can be accomplished if the Remote IP Address is set to 255.255.255.255.
The Broadcast UDP is a practical solution when one device needs to communicate with
multiple PC’s or devices over the network (one-to-many connection). In the case of
directed UDP, the iServer will transmit the serial data to a specific node on the network
(one-to-one connection). This can be accomplished if the Remote IP Address is set to
the IP address of that specific node.
Server Type: In most cases the iServer will be acting as a Slave device. Slave option is
chosen when a network host needs to connect to the serial port of the iServer (default is Slave)
Number of Connections: The range is from 0 to 5. If 0 is selected, the Terminal Server
feature is disabled. That means that no network connection can be made to the serial
port of the iServer. If 1 is selected, only one network connection can be made to the
iServer’s serial port. Any number more than 1 would allow the network hosts to monitor
(read only) the traffic on the iServer’s serial port simultaneously, but only one network
host would be allowed to read and write (default is 0).
Local Port: This is the port or socket number for the iServer’s serial port. Any number
between 500 and 9999 can be defined with the exceptions of 1000 and 2002 which are
already used by the iServer for other purposes.
If the “Number of Connections” is set to 0, the iServer’s “Local Port” will be 1000,
regardless of the displayed value inside the “Local Port” box. Once the “Number
of Connections” is changed to a non-zero number (1 - 5) the “Local Port” value will
be what is inside the box, this value by default indicates 2000 and is changable.
19
4.5.4.B Terminal Server (continued)
Connection Control: Some serial devices accept connections or disconnect
connections based on certain signal conditions. For example, a serial device may accept
a connection only if the incoming DTR signal (connected to device’s DSR or DCD) is
high or low. In this case, when the iServer receives the TCP connection, before it
forwards it to its serial port, it must raise its DTR (DTR+) or to lower its DTR (DTR-). The
iServer is capable of doing this with any of the hardware or modem control signals (DTR,
DSR, DCD, RTS, and CTS).
"Reconnect" is one of the options in the Connection Control menu. This option
can be used in the Serial Tunneling described in Section 4.11. If the connection
in Serial Tunneling is broken due to network problems, power failure, etc., the
Reconnect option will try to get the connection back on line every whatever the
"Connection Timeout" is set to. For Example, if the Connection Timeout is set to
1000 x10 ms or 10 seconds, then every 10 seconds the iServer attempts to
reconnect and reestablish the serial tunnel to the other network node.
Device No.: Refer to Section 4.5.1
4.5.4C Remote Access: This option needs to be enabled when Serial Tunneling is
configured. The Serial Tunneling is explained in detail in Section 4.11.
Changes made in the iServer’s Configuration page can be saved permanently
by pressing the Save button. Pressing the Reset button will set all the fields
back to their default values.
20
4.5.5 Access Control
This section describes the "Access Control" page of the iServers’s Web interface. This
page allows the users to set up the network and security parameters of the iServer.
To get into the Access Control page, the user will be prompted with an Administrator
Password. The default Admin password is 00000000 and is changeable, if desired.
At the initial entrance to the “Access Control” page you will be prompted for the Login
Password (see Figure 4.4) prior to an Administrator Password.
ACCESS CONTROL
Address
ACCESS CONTROL
Login Password 12345678
Admin Password
00000000
Web Server enable
Host Name eis21d9
MAC Address 00:03:03:00:21:D9
IP Address 192.168.1.200
Gateway Address
0.0.0.0
Subnet Mask
255.255.255.0
Save Reset
Power Recycle
Main Menu
Figure 4.11 Access Control
Login Password: This allows users to access and modify all of the iServer Home Page
menu items, except “Access Control”, which requires an Administrator password. The
default Login password is 12345678. This password can be up to 16 alpha-numeric
case-sensitive characters.
If there is no Login Password assigned (blank box) the iServer will not require a
password to access and modify iServer Home page menu items.
Admin (administrator) Password: This allows users to access and modify the "Access
Control" page. The default password is 00000000. This password can be up to 16 alpha-
numeric case-sensitive characters.
If there is no Administrator Password assigned (blank box) the iServer will not require
password to access and modify "Access Control" page.
Web Server: This will allow or disallow accessing the iServer’s Web server using an
Internet browser (default is enabled.)
21
4.5.5 Access Control (continued)
Host Name: Refer to Section 3.4, DNS.
MAC Address: This is also called Hardware address or Ethernet address, which is
assigned to the iServer at production. The MAC (Media Access Control) address is the
iServer’s unique hardware number and is not changeable.
IP Address: The IP (Internet Protocol) address is a 32-bit number that identifies each
sender or receiver of information that is sent in packets across the Ethernet or the
Internet. The iServer’s default IP address is 192.168.1.200. The iServer’s IP address
should be changed to fit user’s networking environment. Consult with your IT department
for obtaining an IP address.
The DHCP will be enabled in the
iServer if its IP address is set to
ON
0.0.0.0. The DHCP can also be
enabled by setting the dip switch
number 3 to ON position.
1
2
OFF
3
4
Gateway Address: A gateway is a network point that acts as an entrance to another
network. A gateway is often associated with a router, which knows where to direct a
given packet of data that arrives at the gateway. If the iServer is sending packets to
another network node that is not on the same network on which the iServer is connected,
a gateway address needs to be given to the iServer. The gateway address should be the
IP address of the router connected to the same LAN to which the iServer is connected.
The iServer’s default gateway address is 0.0.0.0. Consult with your IT department for
obtaining a gateway address.
Subnet Mask: It’s a 32-bit number that is used to determine which part of the IP address
Changes made in the iServer’s Access Control page can be saved permanently
by pressing the Save button and power recycling the iServer (press Power
Recycle button). Pressing the Reset button will set all the fields back to their
default values.
22
4.6 Setting a New IP Address over the Network
The iServer is shipped with a default IP address of 192.168.1.200 and Subnet Mask of
255.255.255.0. You can configure your PC’s Network connection with an IP address that
is in the same range as the iServer’s IP address (192.168.1.x) and connect to the iServer
using a crossover network cable between your PC and the iServer.
With this completed, you can go to the DOS-Prompt and ping 192.168.1.200. If you
receive responses back (similiar to Figure 4.1), you can go to the Web browser and type
Page.
Select Access Control button, you’ll be asked for the password. First default Login
password is "12345678" and the Admin password is "00000000", then you should be on
the administrator setup page were you can simply type in the desired Static IP address,
and click Save.
ACCESS CONTROL
Address
ACCESS CONTROL
Login Password 12345678
Admin Password
00000000
Web Server enable
Host Name eis21d9
MAC Address 00:03:03:00:21:D9
IP Address 192.168.1.200
Gateway Address
0.0.0.0
Subnet Mask
255.255.255.0
Save Reset
Power Recycle
Main Menu
Figure 4.12 Access Control
For the IP address to take effect the iServer needs to be turned OFF/ON or
press the Reset button.
Once all of this is done, you can connect the iServer to an Ethernet hub using a straight
through cable, power it up, and follow the ping routine mentioned in the previous section.
23
4.7 Terminal Server Function
It is used to provide dedicated connectivity between computers and serial devices
through the iServer over the Ethernet, without dedicated wiring. The typical Internet
protocol consists of a request and a replay to that request. In this situation the server is
the Host that generates the request and receives the replay from the device, that gets
forwarded to the appropriate party on the network. But there are specific applications
where a message is generated by the device, and the server is simply passing the data
to the appropriate party on the network, in this situation the server acts as Slave.
Examples are the Attendance Time Clocks, Bar Code Readers, remote Displays or
Electronic signboards, etc.
For the iServer to pass the data back and forth between its Serial and Ethernet
interfaces, the Terminal Server option needs to be configured as follows (Figure 4.13):
1. Set the Server Type to Slave
2. Set the Number of Connections to 0.
3. Set the Local Port or Socket number to any number from 599 - 65535, except
numbers 1000 and 2002.
4. Press the Save button to store the new settings.
From your application software on the host machine, you can now point to the IP address
of the iServer and the assigned port number to establish a TCP connection to your serial
device connected to the serial port of the iServer.
CONFIGURATION
Address
CONFIGURATION
If DIP
switch #4 is
“ON”,
Serial Communication
Terminal Server
Baud Rate 9600
Flow Control none
Data Bit 7 Bits Parity odd
Stop Bits1 bit
function is always
enabled, regardless
of the firmware
Transciever RS-485
Modbus/TCP disable
Timeout
End Character (Hex) 0D Forward End Char enable
0500 msecs
configuration.
By default, this DIP
switch is set to
Serial Port Password disable 1234abcd
“OFF” position.
Terminal Server
You have the option
to enable the
Server Type slave
TCP/UDP TCP
Number of Connections
Local Port 02000
0
Terminal Server
feature either
through the
Connection Ctrl not used
Connection Timeout 00100 msecs
Device No.
1
firmware or the DIP
switch #4.
Remote Access (Tunneling)
Remote Access
Remote IP Address 0.0.0.0
Remote Port 02000
disable
Save Reset
Main Menu
Figure 4.13 Terminal Server Configuration
24
4.8 Terminal Emulation
On this page you can send and receive data to and from the instrument. Simply, type the
command in the open window and as you type the characters, the characters will be
transmitted out from the serial port of the iServer.
If the command is more than one character, you must type the command in a different
window and then use “copy” and “paste” options to drop the command in the Terminal
Emulation window (the right mouse button will give you “copy” and “paste” options).
TERMINAL SERVER
Address
TERMINAL EMULATION
reading
Main Menu
Figure 4.14 Terminal Emulation
25
4.9 Telnet Setup
Telnet stands for Telecommunications Network, is a protocol that provides a way for users (or
clients) to connect to computers (or servers) on a network, whether in the next building or
across the other side of the world.
You can open a Telnet session using other terminal emulation programs like Tera Term Pro
(downloadable from the internet), which is a free software for MS-Windows. It supports
VT100 emulation, Telnet connection and serial port connection.
Once the Telnet mechanism is decided we can open a session by simply typing the IP
address of the iServer, and setting the Port on 2002 for logging into the iServer Configuration
page or 2000 for accessing the serial device connected to the iServer’s serial port.
Firmware Version 4.1
Admin Password:00000000
Admin. Login Successful
p
Configuration
Firmware Version 4.1
BD =
PT =
ST =
DT =
MD =
TO =
TT =
TN =
HN =
IP =
LP =
SP =
TP =
RE =
RI =
RP =
GW =
SM =
EC =
PP =
FC =
MB =
TU =
CC =
CT =
FE =
EP =
CP =
WB =
MAC=
q
9600 (5)
odd (1)
1 bit (0)
7 bits (0)
RS-485 (1)
500
SLAVE (1)
0
Figure 4.15
Tera Term Telnet Connection Screen
eis1376
192.168.1.200
12345678
00000000
iLD (5)
enable (1)
0.0.0.0
02000
0.0.0.0
255.255.255.0
0D
02000
None (0)
disable(0)
TCP (0)
not used(0)
01000
enable (1)
disable(0)
1234abcd
enable (1)
00:03:34:00:13:76
Quit
Figure 4.16 Telnet Setup
iServer Configuration Page
The default password for Telnet Login is 00000000 and can be changed if
desired. Telnet works only in RS-232 mode
26
4.9 Telnet Setup (continued)
In the Configuration mode you can make any changes just like you would do using the Web
Browser. After connected to the iServer, the user can use the following commands to read, modify,
and get help from the iServer console.
? Following with a return character, the console will show all the commands and options (Figure 4.17).
p Following with a return character, the console will show the iServer configurations (Figure 4.16).
s Is the configuration command, used to set a new setting (see the example in Figure 4.17)
r
This command is used to read the status of the digital I/O signals (0 is low and 1 is high)
Example:
r DCD
r DTR
response will be
response will be
DCD (DSR)=0
DTR=0
w This command is used to change the status of the digital I/O signals (applies only to the
outgoing signals, DTR and RTS)
Example :
w RTS=1 means raise the RTS
w DTR=0 means lower the DTR
RESET following with a return character, it will recycle the Power on the iServer.
FACTORY following with a return character, it will set the iServer to it’s factory default settings.
Admin. Password:00000000
Admin. Login Successful
iServer Configuration Command:
?
cc description
BD BaudRate
pppppp
0-300,1-600,2-1200,3-2400,4-4800,5-9600,6-19200,
7-38400, 8-57600, 9-115200
0-none,1-Odd,2-even
0-1bits,1-2bits
PT Parity
ST StopBits
DT DataBits
0-7bits,1-8bits
FC FlowControl
MD Mode
0-none,1-XON/XOFF,2-Hardware
0-RS232, 1-RS485
MB Modbus/TCP
TO TimeOut
0-disable, 1-enable
xxxx ms Rang range 100-9999
0-TCP, 1-UDP
TU TCP/UDP
TT TerminalType
TN TerminalNumber
PP TerminalPort
HN HostName
0-Host, 1-Slave
0-5
XXXXX 500-65535 but 1000 and 2002
XXXXXXXX
maxim 18 characters
IP Static IP
LP Login Password
SP Admin Password
TP Device Type
RE Remote Enable
RI Remote IP
RP Remote Port
GW Gateway
XXX.XXX.XXX.XXX
XXXXXX maxim 16 characters
XXXXXX maxim 16 characters
0-iServer,1-iDRN,2-iDRX,3-iSeries,4-iNFB,5-iLD
0-Disable, 1-Enable
XXX.XXX.XXX.XXX
XXXXX 500-65535 but 1000 and 2002
XXX.XXX.XXX.XXX
EC End Char
XX represents the Hex Num. of ASCII. i.e 0D means CR
(Carrige Return)
FE Forward End Char 0-disabled, 1-enabled
EP Enable Serial Port Password
CP Serial Port Password
0-disabled, 1-enabled
XXXXXX maxim 16 characters
CC Connect CTRL
0-not used,1-RTS+,2-RTS-,3-CTS+,4-CTS_,5-RTS-CTS+,
6-RTS-CTS-, 7-DTS+,8-DTR-, 9-DCD/DSR+,
A-DCD/DSR-, B-DTR-DCD+, C-DTR-DCD-, D-RECONNECT
CT Connect Timeout XXXXX 1-65535
WB Web Server
Example:
0-disable, 1-enable
To configure Baudrate 9600, 1 stop bit, Odd Parity, and RS232 mode.
s -BD5 -PT1 -ST1 -MD0
Figure 4.17 Telnet Setup - iServer Help Page
27
4.10 HTTPGET Program
You can setup and read the information from the iServer by using the HTTPGET
program. The following program can be used to read data from the embedded server
firmware by using TCP port 1000. The command string sends to this TCP port, then it
reads back the response from the same port. Whatever you write to the port goes to the
serial port unmodified. Any response from the serial port can be read back from the
same socket.
The Httpget.exe file is used to setup and read information from the iServer. This file will
be automatically installed when you run any iServer related software available on our
website and CD.
Example to use the "Httpget" program:
1. Create a directory C:\iServer\Httpget.
2. Copy httpget.exe and readme_features.doc files to this directory.
3. Make sure that you are in this directory and then enter the following test program:
C:\iServer\Httpget\httpget –r –S "*01X01\r" 192.168.1.200:1000
where:
"-r –S" are switches before the command string
"01" is device address (in hex format) for RS485 communication interface (skip for
RS232)
"X01" read measurement data value (iLD protocol)
"\r" calls out a CR
"192.168.1.200" is an IP address
"1000" is a local port number
Respond:
01X01074.3
where:
"01X01" is Echo command
"074.3" is a display reading of the 4-digit device
In the example above the 4-digit iLD Big Display controller has been connected
to the serial communication port of iServer.
28
4.11 ARP Protocol
ARP is the Internet layer protocol responsible for determining the MAC (hardware)
address that corresponds to a particular IP address. The ARP command allows the user
to view the current contents of the ARP cache of the local computer (residing on the
same network) or remote computer (residing on the different network) through a router.
Microsoft includes the ARP.EXE utility for viewing and modifying the ARP cache with its
Windows products. The following ARP commands can be used to view cache entries:
• arp –a © Use this command to view all ARP cache entries.
• arp –a plus IP address © Use this command to view ARP cache entries associated
with one particular interface on a network with multiple adapters.
• arp –g © Same as arp –a.
• arp –N © Use this command to display ARP entries for specific network interface.
• arp – s plus IP address plus Physical address © Use this command to manually add
a permanent static entry to the ARP cache.
• arp –d © Use this command to manually delete a static entry.
Ping the destination computer using IP address first before using the arp -a
command.
The following window shows examples of arp commands and responses.
• Your computer has an IP address of 192.168.1.118
• The destination computer has an IP address of 192.168.1.96
C:\>arp - 192.168.1.96
No ARP Entries Found
C:\>ping 192.168.1.96
Pinging 192.168.1.96 with 32 bytes of data:
Reply from 192.168.1.96=bytes=32 time=5ms TTL=32
Reply from 192.168.1.96=bytes=32 time=3ms TTL=32
Reply from 192.168.1.96=bytes=32 time=3ms TTL=32
Reply from 192.168.1.96=bytes=32 time=4ms TTL=32
C:\>arp -a 192.168.1.96
Interface: 192.168.1.118
Internet Address Physical Addresss
192.168.1.96 00-03-34-00-00-23
Type
dynamic
C:\>arp -s 192.168.1.96 00-03-34-00-00-23
C:\>arp -a 192.168.1.96
Interface: 192.168.1.118
Internet Address Physical Addresss
192.168.1.96 00-03-34-00-00-23
Type
static
C:\>arp -d 192.168.1.96
C:\>arp -a 192.168.1.96
No ARP Entries Found
C:\>
Figure 4.18 ARP Commands and Responses
29
4.12 Remote Access (Tunneling)
To "tunnel", in this context, is to transmit data between two points through a private
conduit on a shared or public network. The network could be an Ethernet LAN, a WAN,
or the Internet. The iServer allows for a connection between a serial device and a PC, or
between two serial devices, using an existing network rather than dedicated wiring.
Today, there are number of serial devices like sensors, gauges, PLCs, card readers,
security alarms, barcode scanners, data loggers, video cameras, ATM machines, time &
attendance terminals, medical lab equipments, electronic signboards, and many others
that are directly connected to PCs via their serial ports. These devices can be attached
to shared Ethernet networks (TCP/IP protocol) and get accessed, controlled, and
managed remotely using the iServer products. Any two iServer’s can talk to each other
over the Ethernet LAN, WAN, and Internet using TCP/IP protocol. Therefore, the
connected serial devices to iServer’s can also communicate with each other back and
forth over these networks. This characteristic is called Tunneling and it’s illustrated
below.
Figure 4.19 PC-to-Device Communication
Figure 4.20 Device-to-Device Communication
In order to use this Tunneling feature, some settings are required within the local and
remote iServer’s.
30
4.12.1 Remote iServer
It’s recommended to configure the Remote iServer and have it up and running before the
Local iServer is configured.
1. A static IP address must be assigned to the Remote iServer. This means that the DHCP
must remain disabled. Refer to the DHCP section of the user’s manual for details.
2. Use a browser to access the Remote iServer’s WEB page. Simply type the iServer’s
IP address at the browser’s URL location (i.e. 192.168.1.50) followed by an Enter key.
You should then see the iServer’s main WEB page.
3. Click on the Update button.
4. Click on Configuration, you will be prompted with a Password (default is 12345678).
5. On the Configuration page, under Serial Communication section, make sure the
parameters such as Baud Rate, Data Bits, Parity, Stop Bits, Flow Control, etc. match
with your attached serial device.
6. Make sure to set the End Character (Hex) to 0D and the Timeout to 500.
7. Under Terminal Server section, set Number of Connections to 1 or higher.
8. Click on Save button for the changes to take place.
Make sure that the serial cable and communication settings between the iServer and the
serial device are valid.
CONFIGURATION
Address
CONFIGURATION
Serial Communication
Baud Rate 9600
Flow Control none
Data Bit 7 Bits Parity odd
Stop Bits1 bit
Figure 4.21
shows the valid
Transciever RS-485
Modbus/TCP disable
values that
need to be set
Timeout
End Character (Hex) 0D Forward End Char enable
0500 msecs
in the Remote iServer.
The Baud Rate, Data
Bits, Parity, Stop Bits,
Flow Control, and
Transceiver values
depend on what the
serial device supports.
Serial Port Password disable 1234abcd
Terminal Server
Server Type slave
TCP/UDP TCP
Number of Connections
Local Port 02000
1
Connection Ctrl not used
Connection Timeout 00100 msecs
Device No.
1
Remote Access (Tunneling)
Remote Access
Remote IP Address 0.0.0.0
Remote Port 02000
disable
Save Reset
Main Menu
Figure 4.21 Configuration Menu - Remote iServer
31
4.12.2 Local iServer
1. An IP address should be assigned to the iServer dynamically or statically (recommended).
2. Use a browser to access the Local iServer’s WEB page. Simply type the iServer’s IP
address at the browser’s URL location (i.e. 192.168.1.49) followed by an Enter key.
You should then see the iServer’s main WEB page.
3. Click on the Update button.
4. Click on Configuration, you will be prompted with a Password (default is 12345678).
5. On the Configuration page, under Serial Communication section, make sure the
parameters such as Baud Rate, Data Bits, Parity, Stop Bits, Flow Control, etc. match
with your attached serial device and its application software.
6. Make sure to set the End Character (Hex) to 0D and the Timeout to 500.
7. Under Terminal Server section, set Number of Connections to 0.
8. Under Remote Access section, set the Remote Access to enable, Enter the Remote
IP address (would be the IP address of the remote iServer, 192.168.1.50), and use the
default Remote Port number 2000.
9. Set Connection Control to Reconnect and set the Connection Timeout to a desired value.
The Reconnect option is used in Serial Tunneling and it applies only to the Local
iServer. If the tunneling connection between the two iServers goes down due to
network problems, power failure, etc., the Reconnect option will enable the Local
iServer to reconnect with the Remote iServer based on the specified time interval in
the Connection Timeout. For example, based on a timeout of 1000 x 10 ms (10
seconds), the Local iServer will continually attempt to reconnect and re-establish the
tunnel with the Remote iServer every 10 seconds.
10. Click on Save button for the changes to take place.
11. Initialize the serial device application software to establish the connection.
CONFIGURATION
Address
CONFIGURATION
Serial Communication
Baud Rate 9600
Flow Control none
Data Bit 7 Bits Parity odd
Stop Bits1 bit
Figure 4.22 shows
the valid values
Transciever RS-485
Modbus/TCP disable
that need to be set
Timeout
End Character (Hex) 0D Forward End Char enable
0500 msecs
in the Local
Serial Port Password disable 1234abcd
iServer. The Baud Rate,
Data Bits, Parity, Stop Bits,
Flow Control, and
Terminal Server
Transceiver values depend
on what the attached device
to the iServer supports.
Server Type slave
TCP/UDP TCP
Number of Connections
Local Port 02000
0
Connection Ctrl reconnect
Connection Timeout 00100 msecs
Device No.
1
Remote Access (Tunneling)
Remote Access
Remote IP Address 192.168.1.50
Remote Port 02000
enable
Save Reset
Main Menu
Figure 4.22 Configuration Menu - Local iServer
32
4.13 Mail Notifier Software
The Mail Notifier Software can be used only with NEWPORT Electronics instruments.
For complete information of how to use the Mail Notifier software, click on the Help menu
of the main window.
The Mail Notifier software generates email notifications for alarm conditions. Users can
be notified automatically of alarm conditions monitored via internet connections
throughout the world. By use of the email forwarding of alarm conditions, alarm
conditions can be monitored on a network isolated from the internet and forwarded to
connections on the Internet.
The Mail Notifier utility operates under Windows 98, NT 4.0, 2000, and XP in conjunction
with existing email that supports the MAPI messaging interface. If MS Outlook has been
loaded, the MAPI support should be available.
4.13.1 Installation
The Mail Notifier must be loaded on a computer running Microsoft Windows (versions
specified earlier) using an email program that provides MAPI access. Network access
must be available between this computer and the iServer. Network access must also be
available from this computer to the appropriate email server and from the email server to
the recipient’s email server.
Figure 4.23 iServer Mail Notifier Main Window
33
4.13.2 Program Options Setup and Configuration
Complete program setup requires:
•
•
•
Entering a recipient for the email
Specifying connection details to MAPI services.
Defining alarms for devices, and selecting how and when the email will be active.
Figure 4.24 iServer Mail Notifier Profile Setup
The “Send To” tab contains a field to specify an email address to which alarm
notifications will be sent (i.e. the recipient). Only one entry is permitted, in the address
field. Additional addresses can be placed into “More Addresses” list.
Email Connection (MAPI Access)
The following instructions work with some versions of Microsoft Outlook. Note though
that some email systems may prevent the use of Mail Notifier due to security constraints.
The simplest way to obtain a connection the the Email services is as follows:
1. Configure the Mail Notifier to connect to the email by displaying a Login Box. This
option is found by selecting View, Options from the Mail Notifier's menubar. Select
the "Email Setup" tab, mark the checkbox for "Use Login Box"
2. After Mail Notifier is configured to use the login box, the Mail Notifier can be started
without user intervention if your MS Outlook program is running beforehand.
Otherwise, the Mail Notifier will display a Login Box that should display the
necessary User Profile.
34
4.12.3 Device Setting and Configuration
Device setup requires:
• Entering the IP address for iServer device (for example 192.168.1.200).
• Specifying Socket number (1000 or 2000 depending on iServer settings).
• Defining RS485 Unit # interface address (1 to 199). Enter "0" for RS232 interface
or for iServer.
• Entering Reading command. Normally set to X01 to obtain reading from the devices.
If you want to change this setting, refer to HTTPget Section 4.10.
• Defining the Alarm setup (High/Low, High value, or Low value).
• Specifying Pause Interval. It determines how many seconds each subsequential alarm
notification will be sent.
• Determining Monitor interval. It establishes the interval or time resolution in seconds
for which readings will be obtained from the device.
Figure 4.25 iServer Mail Notifier Device Setting
35
PART 5
SPECIFICATIONS
SERIAL INTERFACE
INTERNAL WEB SERVER
Interface:
RS-422 or RS-485 (2 wire)
Uses: Dynamic web pages and Java
applets (256 Kbyte capacity)
Data Rates:
300 to 115200 bps
ENVIRONMENTAL
Characters:
Operating Temperature:
7 or 8 data bits
0 to 50°C (32 to 122°F) 90%RH
Parity:
odd, even, or none
Stop bits:
1 or 2
Flow Control:
Software (Xon/Xoff)
Hardware (CTS/RTS)
Power Input
100-240Vac 10%, 50/60 Hz
Consumption:
22.5 W max
GENERAL
NETWORK INTERFACE
Agency Approvals
FCC-B, CE
Interface:
Ethernet 10 Base-T
Software
Connector:
Firmware upgradeable. Compatible with
Windows 9x / ME / NT / 2000 / XP software
and related utilities
RJ45
Protocols:
ARP, TCP/IP, ICMP, DNS, DHCP,
Telnet simulation and HTTP
Indicators (LED):
Refer to the iLD Big Display Manual
and Quickstart for physical
characteristics of iLD Big Display
devices with the Embedded
Ethernet Server.
Col / Network Activity (red),
On / Network Link (green),
TX-Transmit (yellow),
RX-Receive (green)
PROCESSOR
CPU:
Enhanced 8051, 22 MHz
Memory:
16 Kbyte SRAM, 512 Kbyte Flash
Management:
Serial Login, Telnet Login,
Internal Web Server
36
PART 6
FACTORY PRESET VALUES
PRESET PARAMETERS
FACTORY DEFAULTS
Network Interface:
IP Address
192.168.1.200
Gateway Address
Subnet Mask
0.0.0.0
255.255.255.0
Device Host Name
Login Password
Admin Password
DHCP
eis and Last 4 digits from the MAC address
12345678
00000000
Disabled
Serial Interface:
Communication Protocol
Flow Control
RS-485
None
Baud Rate
9600
Parity
Odd
Stop Bit
1 bit
Data Bit
7 bits
Timeout
500 msec
End Character
Terminal Server:
Server Type
0D (Hex) (Carridge Return)
Slave
0
Number of Connections
Port #
1000
Disable
Server Mode
Remote Access (Tunneling):
Remote Access
Remote Port
Disable
2000
Remote IP Address
0.0.0.0
37
APPENDIX A
GLOSSARY
User of this manual should be familiar with following definitions:
ARP (Address Resolution Protocol) is a protocol for mapping an Internet Protocol
address (IP address) to a physical machine address that is recognized in the local
network. For example, the IP address in use today is an address that is 32-bits long.
In an Ethernet local area network, however, addresses for attached devices are 48-bits
long. (The physical machine address is also known as a Media Access Control or
MAC address.) A table, usually called the ARP cache, is used to maintain a correlation
between each MAC address and its corresponding IP address. ARP provides the
protocol rules for making this correlation and providing address conversion in both
directions.
Ethernet is a network protocol defined by the IEEE 802.3 standard. Ethernet-based
networks use MAC Address rather then IP Address to exchange data between
computers. By using ARP and adding TCP/IP support, Ethernet devices may be
connected as part of the Internet. An Ethernet LAN typically uses coaxial cable or special
grades of twisted pair wires. The most commonly installed Ethernet systems are called
10BASE-T and provide transmission speeds up to 10 Mbps. Devices are connected to
the cable and compete for access using a Carrier Sense Multiple Access with Collision
Detection (CSMA/CD) protocol.
IP (Internet Protocol) is the method or protocol by which data is sent from one computer
to another on the Internet.
IP address (Internet Protocol address) is a 32-bit number that identifies each sender
or receiver of information that is sent in packets across the Internet.
IP Netmask is a 32-bit pattern of bits used to determine which part of the IP address is
the network portion and which part is the host portion.
MAC (Media Access Control) Address is your computer's unique hardware number.
When you're connected to the Internet from your computer, a correspondence table
relates your IP address to your computer's physical (MAC) address on the LAN.
Ping is a utility that tests the network connectivity. It is used to determine if the host is
capable of exchanging information with another host.
Port number/Socket number is a way to identify a specific process to which an Internet
or other network message is to be forwarded when it arrives at a server. It is a
predefined address that serves as a route from the application to the Transport layer or
from the Transport layer to the application of the TCP/IP system.
Sockets are a method for communication between a client program and a server
program in a network and defined as "the endpoint in a connection." Information
transferred across the Internet primarily occurs between sockets.
TCP/IP (Transmission Control Protocol/Internet Protocol) is the basic communication
language or protocol of the Internet. When you are set up with direct access to the
Internet, your computer is provided with a copy of the TCP/IP program just as every
other computer that you may send messages to or get information from also has a copy
of TCP/IP. TCP/IP often is used as a general term to indicate generic access to the
Internet.
38
Appendix B
IP Address
An IP address is a unique 32-bit address assigned to a computer and includes:
• A network ID number identifying a network.
• A host ID number identifying a computer on the network.
All IP addresses have been divided into three smaller groups (classes) A, B and C
• Class A addresses have 8-bits of network ID and 24-bits of host ID. They can support
a large number of hosts, approximately 2 = 16,777,216 computers per network.
The IP addresses range in binary from 00000001.xxxxxxxx.xxxxxxxx.xxxxxxxx
to 01111111.xxxxxxxx.xxxxxxxx.xxxxxxxx
The IP addresses range in decimal from 1.x.x.x to 127.x.x.x
Class A network ID’s support a very large number of hosts.
• Class B addresses have 16-bits of network ID and 16-bits of host ID. They can
support approximately 216 = 65,536 computers per network.
The IP addresses range in binary from 10000000 00000000.xxxxxxxx.xxxxxxxx
to 10111111 11111111.xxxxxxxx.xxxxxxxx
The IP addresses range in decimal from 128.0.x.x to 191.255.xxx.xxx
Class B network ID’s support a medium number of hosts.
• Class C addresses have 24-bits of network ID and 8-bits of host ID. They can support
approximately 28 = 256 computers per network.
The IP addresses range in binary from 11000000.00000000.00000000.xxxxxxxx
to 11011111.11111111.11111111.xxxxxxxx
The IP addresses range in decimal from 192.0.0.xxx to 223.255.255.xxx
Class C network ID’s support a small number of hosts.
The rest of the addresses are divided into two classes, D and E.
Class D networks are not assigned to the host. They are used for multicasting.
The address range from 224.x.x.x to 239.x.x.x
Class E networks are experimental or reserved addresses.
The address range from 240.x.x.x to 247.x.x.x
39
Appendix C
IP Netmask
IP Netmask or Subnet Mask is a 32-bit pattern of ones and zeros used to determine
network portion of an IP address from the host portion of the IP address. Subnet mask is
a network ID that is created by borrowing bits from host portion of IP address and using
them as part of a network ID. The table below shows a default subnet mask for address
Classes A, B, and C. Each bit that is set to "1" in the subnet mask corresponds to the bit
in the IP address that is to be used as the network ID. Each bit that is set to "0" in the
subnet mask corresponds to a bit in the IP address that is to be used as the host ID.
Address Class
Mask Binary Value
Mask Decimal Value
or Dotted Notation
255.0.0.0
11111111 00000000 00000000 00000000
11111111 11111111 00000000 00000000
11111111 11111111 11111111 00000000
Class A
Class B
Class C
255.255.0.0
255.255.255.0
If your network requires more network ID’s, you can extend the default subnet mask to
include additional bits from the host ID. This allows for additional network ID’s within the
network. The table below shows some examples of subnet masks and bits moved from
the hosts ID to create a new subnet.
Mask Dotted Notation
Mask Binary
Mask Bits
Class A
11111111 00000000 00000000 00000000
11111111 11000000 00000000 00000000
11111111 11100000 00000000 00000000
11111111 11110000 00000000 00000000
11111111 11111000 00000000 00000000
11111111 11111100 00000000 00000000
11111111 11111110 00000000 00000000
11111111 11111111 00000000 00000000
11111111 11111111 10000000 00000000
11111111 11111111 11000000 00000000
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11111111 11111111 11111111 11111100
Class B
255.0.0.0 (Default)
255.192.0.0
0
2
255.224.0.0
3
255.240.0.0
4
255.248.0.0
5
255.252.0.0
6
255.254.0.0
7
255.255.0.0
8
255.255.128.0
255.255.192.0.0
…………….........
255.255.255.252
9
10
.
22
255.255.0.0 (Default)
255.255.192.0
…………….........
255.255.255.252
0
2
11111111 11111111 00000000 00000000
11111111 11111111 11000000 00000000
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
.
14
11111111 11111111 11111111 11111100
Class C
255.255.255.0 (Default)
255.255.255.192
………………….
0
2
.
11111111 11111111 11111111 00000000
11111111 11111111 11111111 11000000
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
11111111 11111111 11111111 11111100
255.255.255.254
6
To determine the number of valid hosts ID’s remaining after subnetting, use the following
equation: 2n – 2, where n is the number of octet digits left after the subnet mask.
40
Appendix D
ASCII Chart
ASCII
ASCII
Char
NUL
SOH
STX
ETX
EOT
ENQ
ACK
BEL
BS
HT
LF
Dec
Hex
Binary
Dec
Hex
Binary
No Parity
00000000
00000001
00000010
00000011
00000100
00000101
00000110
00000111
00001000
00001001
00001010
00001011
00001100
00001101
00001110
00001111
00010000
00010001
00010010
00010011
00010100
00010101
00010110
00010111
00011000
00011001
00011010
00011011
00011100
00011101
00011110
00011111
00100000
00100001
00100010
00100011
00100100
00100101
00100110
00100111
00101000
00101001
00101010
00101011
00101100
00101101
00101110
Char
@
A
B
C
D
E
F
G
H
I
J
K
L
M
N
O
P
Q
R
S
T
No parity
01000000
01000000
01000010
01000011
01000100
01000101
01000110
01000111
01001000
01001001
01001010
01001011
01001100
01001101
01001110
01001111
01010000
01010001
01010010
01010011
01010100
01010101
01010110
01010111
01011000
01011001
01011010
01011011
01011100
01011101
01011110
01011111
01100000
01100001
01100010
01100011
01100100
01100101
01100110
01100111
01101000
01101001
01101010
01101011
01101100
01101101
01101110
00
01
02
03
04
05
06
07
08
09
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
00
01
02
03
04
05
06
07
08
09
0A
0B
0C
0D
0E
0F
10
11
12
13
14
15
16
17
18
19
1A
1B
1C
1D
1E
1F
20
21
22
23
24
25
26
27
28
29
2A
2B
2C
2D
2E
64
65
40
41
42
43
44
45
46
47
48
49
4A
4B
4C
4D
4E
4F
50
51
52
53
54
55
56
57
58
59
5A
5B
5C
5D
5E
5F
60
61
62
63
64
65
66
67
68
69
6A
6B
6C
6D
6E
66
67
68
69
70
71
72
73
74
VT
FF
CR
SO
SI
75
76
77
78
79
DLE
DC1
DC2
DC3
DC4
NAK
SYN
ETB
CAN
EM
SUB
ESC
FS
GS
RS
US
SP
!
80
81
82
83
84
U
V
W
X
Y
Z
85
86
87
88
89
90
[
91
\
92
]
93
^
94
_
95
96
`
a
b
c
d
e
f
g
h
I
j
k
l
m
n
97
"
98
#
99
$
100
101
102
103
104
105
106
107
108
109
110
%
&
‘
(
)
*
+
,
-
.
41
Appendix D
ASCII Chart Continuation
/
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
2F
30
31
32
33
34
35
36
37
38
39
3A
3B
3C
3D
3E
3F
00101111
00110000
00110001
00110010
00110011
00110100
00110101
00110110
00110111
00111000
00111001
00111010
00111011
00111100
00111101
00111110
00111111
o
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
6F
70
71
72
73
74
75
76
77
78
79
7A
7B
7C
7D
7E
7F
01101111
01110000
01110001
01110010
01110011
01110100
01110101
01110110
01110111
01111000
01111001
01111010
01111011
01111100
01111101
01111110
01111111
p
0
1
2
3
4
5
6
7
8
9
:
q
r
s
t
u
v
w
x
y
z
{
|
}
~
;
<
=
>
?
DEL
ASCII Control Codes
ASCII Dec Hex Ctrl Key Definition
Char Equiv.
NUL 00 00 Crtl @ Null Character DC1
ASCII Dec Hex Ctrl Key Definition
Char
Equiv.
17
18
19
11
12
13
Crtl Q Data Control 1
- XON
Crtl R Data Control 2
SOH 01 01 Crtl A
STX 02 02 Crtl B
Start of
Header
Start of Text
DC2
DC3
Crtl S Data Control 3
- XOFF
ETX 03 03 Crtl C
EOT 04 04 Crtl D
End of Text
End of
Transmission
Inquiry
DC4
NAK
20
21
14
15
Crtl T Data Control 4
Crtl U
Negative
Acknowledge
ENQ 05 05 Crtl E
SYN
22
23
16
17
Crtl V Synchronous
Idle
Crtl W End of Trans
Block
ACK 06 06 Crtl F Acknowledge ETB
BEL 07 07 Crtl G
Bell
CAN
EM
SUB
24
25
26 1A
18
19
Crtl X
Cancel
BS
HT
08 08 Crtl H
09 09 Crtl I
Back Space
Horizontal
Tabulation
Line Feed
Vertical
Crtl Y End of Medium
Crtl Z
Crtl [
Substitute
LF
VT
10 0A Crtl J
11 0B Crtl K
ESC
FS
27 1B
28 1C
Escape
Crtl \ File Separator
Tabulation
Form Feed
FF
12 0C Crtl L
13 0D Crtl M
GS
RS
29 1D
30 1E
31 1F
Crtl ]
Crtl |
Group
Separator
Record
CR
Carriage
Return
Shift Out
Shift In
Separator
Unit Separator
Space
_
SO
SI
14 0E Crtl N
15 0F Crtl O
US
SP
Crtl
32
20
DLE 16 10 Crtl P
Data Link
Escape
42
PART 7
APPROVALS INFORMATION
7.1 CE APPROVALS INFORMATION
This product conforms to the EMC directive 89/336/EEC amended by
93/68/EEC, and with the European Low Voltage Directive 72/23/EEC.
Electrical Safety EN61010-1:2001
Safety requirements for electrical equipment for measurement, control and
laboratory.
Double Insulation
Pollution Degree 2
Dielectric withstand Test per 1 min
• Power to Input/Output:
2300Vac (3250Vdc)
• Power to Input/Output:
1500Vac (2120Vdc)
(Low Voltage dc Power Option*)
• Power to Relays/SSR Output:
• Ethernet to Inputs:
• Isolated RS232 to Inputs:
• Isolated Analog to Inputs:
• Analog/Pulse to Inputs:
Measurement Category I
2300Vac (3250Vdc)
1500Vac (2120Vdc)
500Vac (720Vdc)
500Vac (720Vdc)
No Isolation
Category I are measurements performed on circuits not directly connected to the
Mains Supply (power). Maximum Line-to-Neutral working voltage is 50Vac/dc.
This unit should not be used in Measurement Categories II, III, IV.
Transients Overvoltage Surge (1.2 / 50uS pulse)
• Input Power:
2500V
• Input Power:
1500V
(Low Voltage dc Power Option*)
• Ethernet:
• Input/Output Signals:
1500V
500V
Note: *Units configured for external low power dc voltage, 12-36Vdc
EMC EN61326:1997 + and A1:1998 + A2:2001
Immunity and Emissions requirements for electrical equipment for measurement,
control and laboratory.
• EMC Emissions Table 4, Class B of EN61326
• EMC Immunity** Table 1 of EN61326
Note: **I/O signal and control lines require shielded cables and these cables must
be located on conductive cable trays or in conduits. Furthermore, the length
of these cables should not exceed 30 meters
Refer to the EMC and Safety installation considerations (Guidelines) of this
manual for additional information.
7.2
FCC
This device complies with Part 15, Subpart B, Class B of the FCC rules.
43
WARRANTY/DISCLAIMER
OMEGA ENGINEERING, INC. warrants this unit to be free of defects in materials and workmanship for a period of one (1) year
from the date of purchase. In addition to OMEGA’s standard warranty period, OMEGA Engineering will extend the warranty
period for one (1) additional year if the warranty card enclosed with each instrument is returned to OMEGA.
If the unit malfunctions, it must be returned to the factory for evaluation. OMEGA’s Customer Service Department will issue an
Authorized Return (AR) number immediately upon phone or written request. Upon examination by OMEGA, if the unit is found
to be defective, it will be repaired or replaced at no charge. OMEGA’s WARRANTY does not apply to defects resulting from any
action of the purchaser, including but not limited to mishandling, improper interfacing, operation outside of design limits,
improper repair, or unauthorized modification. This WARRANTY is VOID if the unit shows evidence of having been tampered
with or shows evidence of having been damaged as a result of excessive corrosion; or current, heat, moisture or vibration;
improper specification; misapplication; misuse or other operating conditions outside of OMEGA’s control. Components which
wear are not warranted, including but not limited to contact points, fuses, and triacs.
OMEGA is pleased to offer suggestions on the use of its various products. However, OMEGA neither assumes
responsibility for any omissions or errors nor assumes liability for any damages that result from the use of its
products in accordance with information provided by OMEGA, either verbal or written. OMEGA warrants only that the
parts manufactured by it will be as specified and free of defects. OMEGA MAKES NO OTHER WARRANTIES OR
REPRESENTATIONS OF ANY KIND WHATSOEVER, EXPRESS OR IMPLIED, EXCEPT THAT OF TITLE, AND ALL
IMPLIED WARRANTIES INCLUDING ANY WARRANTY OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR
PURPOSE ARE HEREBY DISCLAIMED. LIMITATION OF LIABILITY: The remedies of purchaser set forth herein are
exclusive, and the total liability of OMEGA with respect to this order, whether based on contract, warranty, negligence,
indemnification, strict liability or otherwise, shall not exceed the purchase price of the component upon which liability
is based. In no event shall OMEGA be liable for consequential, incidental or special damages.
CONDITIONS: Equipment sold by OMEGA is not intended to be used, nor shall it be used: (1) as a “Basic Component”
under 10 CFR 21 (NRC), used in or with any nuclear installation or activity; or (2) in medical applications or used on
humans. Should any Product(s) be used in or with any nuclear installation or activity, medical application, used on
humans, or misused in any way, OMEGA assumes no responsibility as set forth in our basic WARRANTY/DISCLAIMER
language, and, additionally, purchaser will indemnify OMEGA and hold OMEGA harmless from any liability or damage
whatsoever arising out of the use of the Product(s) in such a manner.
RETURN REQUESTS/INQUIRIES
Direct all warranty and repair requests/inquiries to the OMEGA Customer Service Department. BEFORE RETURNING
ANY PRODUCT(S) TO OMEGA, PURCHASER MUST OBTAIN AN AUTHORIZED RETURN (AR) NUMBER FROM
OMEGA’S CUSTOMER SERVICE DEPARTMENT (IN ORDER TO AVOID PROCESSING DELAYS). The assigned AR
number should then be marked on the outside of the return package and on any correspondence.
The purchaser is responsible for shipping charges, freight, insurance and proper packaging to prevent breakage in
transit.
FOR WARRANTY RETURNS, please have the following
information available BEFORE contacting OMEGA:
FOR NON-WARRANTY REPAIRS, consult OMEGA for current
repair charges. Have the following information available
BEFORE contacting OMEGA:
1. Purchase Order number under which the product was
PURCHASED,
1. Purchase Order number to cover the COST of the repair,
2. Model and serial number of product, and
2. Model and serial number of the product under warranty,
and
3. Repair instructions and/or specific problems relative to the
product.
3. Repair instructions and/or specific problems relative to
the product.
OMEGA’s policy is to make running changes, not model changes, whenever an improvement is possible. This affords our
customers the latest in technology and engineering.
© Copyright 2006 OMEGA ENGINEERING, INC. All rights reserved. This document may not be copied, photocopied,
reproduced, translated, or reduced to any electronic medium or machine-readable form, in whole or in part, without the prior
written consent of OMEGA ENGINEERING, INC.
® , and
are Trademarks of OMEGA ENGINEERING, INC.
®
®
TRADEMARK NOTICE:
, omega.com ,
™
PATENT NOTICE: This product is covered by one or more of the following patents: U.S. Pat. No. Des. 336,895; 5,274,577/
CANADA 2052599; 2052600 / ITALY 1249456; 1250938 / FRANCE BREVET No. 91 12756 / SPAIN 2039150; 2048066 / UK
PATENT No. GB2 249 837; GB2 248 954 / GERMANY DE 41 34398 C2. Other US and International Patents pending or
applied for.
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