Communications Gateway (For Gateway firmware 2.14 and higher)
Version 5.3 14 Dec 2015
Gateway Manual Sept 2015 Page 1 of 113
Copyright
LineIQ Gateway User Manual
© CHK GridSense Pty Ltd 2011, 2012 The material presented in this manual is copyright protected by CHK GridSense Pty Ltd
2012. Any reproduction in whole or part for any purpose without the prior written consent
of CHK GridSense Pty Ltd is strictly prohibited. Information in this document is subject to
change without notice.
All trademarks are property of their respective owners.
LIMITED WARRANTY The Gateway is guaranteed to be free of mechanical and electrical defects w h e n
dispatched from our store. Provided that the Gateway has been operated within its normal
ratings as specified, it will be repaired or replaced free of charge if, within a period of
t w e l v e
(12) Months from date of our invoice to the original purchase, it is proven, upon
examination by our engineers, to be defective in material or workmanship. This warranty is
void if the unit has been tampered with, abused or if the defect is related to service not
performed by CHK GridSense Pty Ltd.
Responsibility of CHK GridSense Pty Ltd: Under this guarantee, the responsibility of CHK
GridSense Pty Ltd is limited to the repairing or replacing of any defective part provided the
instrument is returned freight paid to and from our Testing and Service office in Sydney,
NSW Amendments
AUSTRALIA / NEW ZEALAND EMC NOTES
N3207
This is a CISPR 22 Class A product. In a domestic
environment this product may cause radio interference,
which the user may need to take steps to prevent.
Gateway Manual Sept 2015 Page 2 of 113
Contents
1 International Safety Symbols .......................................................................................... 9
2 The LineIQ and Gateway Remote Monitoring Solution ................................................. 10
3 The LIQ Gateway ......................................................................................................... 13
3.1 What’s in the box? ............................................................................................. 14
3.2 Optional Accessories ......................................................................................... 15
4 Quick Start Guide ......................................................................................................... 16
5 Gateway Overview ....................................................................................................... 18
5.1 The Gateway .....................................................................................................18
5.2 Indicators and Controls. ....................................................................................19
5.3 External Connectors ..........................................................................................20
5.4 Local RF Link .....................................................................................................20
5.5 AC Power Cable (Optional) ............................................................................... 20
5.6 AC Power Cable with large clamps leads (Optional) ........................................ 21
5.7 External Solar Panel (Optional) ..........................................................................22
5.8 AC Power Cable with tinned leads (Optional) ...................................................23
5.9 DC Power Cable (Optional) ................................................................................24
5.10 PC Data Cable (Optional) ...................................................................................25
5.11 Modem Data Cable (Optional) .......................................................................... 26
5.12 Ethernet Data Cable (Optional) ..........................................................................26
5.13 Internal Ethernet Module (Optional) ...................................................................27
5.14 Cellular Modem (Optional) .................................................................................27
5.15 Utility Radio (Optional) .......................................................................................28
5.16 Omni Directional Antenna Kit (Optional) ............................................................. 28
5.17 External High Gain Yagi Antenna Kit (Optional) .................................................28
Gateway Manual Sept 2015 Page 3 of 113
6 Safe Use of the Gateway.............................................................................................. 29
6.1 Hazard Assessment ...........................................................................................29
6.2 Live low voltage work ........................................................................................ 30
6.3 Live high voltage work ...................................................................................... 30
6.4 Equipment safety ............................................................................................... 30
7 Configuring The Gateway Before Use .......................................................................... 31
7.1 Introduction ........................................................................................................31
7.2 Communicating with the Gateway .....................................................................31
7.3 Gateway Status .................................................................................................31
7.4 Starting LineMan ...............................................................................................34
7.5 How will the Gateway communicate? ............................................................... 35
7.6 Working with LineMan Remote ..........................................................................35
7.7 Working with a DNP3 SCADA master ................................................................35
8 Installing Your Gateway ............................................................................................... 37
8.1 Pre-installation checks ......................................................................................37
8.2 Mounting ............................................................................................................37
8.3 Post-installation checks..................................................................................... 37
9 Commissioning the Gateway ....................................................................................... 39
9.1 Step 1: Configuring the CMS devices ................................................................39
9.2 Step 2: Configuring the Gateway ...................................................................... 39
9.3 Step 3: Commissioning the Gateway .................................................................41
10 Troubleshooting .......................................................................................................... 42
10.1 Internal battery is discharged: ...........................................................................42
10.2 LineMan cannot communicate with Gateway: ...................................................42
10.3 Gateway does not communicate with external peripherals: .............................. 42
Gateway Manual Sept 2015 Page 4 of 113
10.4 Unable to connect via LineMan-Remote: ...........................................................42
10.5 Unable to communicate with SCADA system: ................................................... 43
10.6 Gateway displays alternating red and amber LEDs after commissioning: ..........43
10.7 Gateway displays fast flashing red LED: ........................................................... 43
11 Operating Principles .................................................................................................... 44
11.1 Gateway Memory Usage .................................................................................. 44
11.2 Event Memory ...................................................................................................44
11.3 Unsolicited event data transfers ........................................................................44
11.4 Solicited event data transfers ............................................................................45
11.5 Load Log Memory .............................................................................................45
11.6 Estimated Download Times ...............................................................................47
11.7 Gateway lack of response during Health Checks ..............................................49
11.8 Real Time Clock (RTC) ....................................................................................... 51
11.9 Solar Panel Mounting Considerations ................................................................52
12 Maintenance ............................................................................................................... 56
12.1 Standby battery ................................................................................................ 56
12.2 Calibration .........................................................................................................56
12.3 Cleaning ...................................................................................................................... 56
12.4 Periodic Maintenance and Testing ....................................................................56
12.5 Operational Problems ........................................................................................56
12.6 Firmware and Software Upgrades .....................................................................57
12.7 Repairs ........................................................................................................................ 57
12.8 Customer Registration .......................................................................................57
12.9 Technical Sales and Assistance ....................................................................... 58
13 Gateway Specifications ............................................................................................... 59
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14 Accessory Specifications ........................................................................................................... 61
14.1 10 W External Solar Panel .............................................................................................. 61
APPENDIX A – LINEMAN .................................................................................................................. 62
A1 Installing LineMan ................................................................................................................ 62
A2 Starting LineMan................................................................................................................. 62
APPENDIX B – LINEMAN REMOTE ................................................................................................... 65
APPENDIX C – INTERNAL ETHERNET MODULE .............................................................................. 67
C1 Introduction ......................................................................................................................... 67
C2 Installation ........................................................................................................................... 68
APPENDIX D - DNP3 COMMUNICATIONS ....................................................................................... 73
D1 Introduction ......................................................................................................................... 73
D2 Locating the DNP3 Interface Settings .................................................................................. 73
D3 Selecting the Health Check Interval ..................................................................................... 74
D4 Changing the DNP3 Interface Settings ................................................................................ 75
D5 Selecting and configuring the DNP3 RS232 Port ................................................................. 76
D6 Permanently powering the radio modem ............................................................................. 76
D7 Setting DNP3 Protocol Parameters ..................................................................................... 76
D8 Other Pertinent Parameters ................................................................................................. 81
D9 Checklist for Configuring the Interface ................................................................................ 81
APPENDIX E – RECOMMENDED DNP3 POINTS USAGE ................................................................. 82
APPENDIX F – DNP3 DEVICE PROFILE ............................................................................................ 83
F1 Device Identification .............................................................................................................. 83
F2 Link Layer ............................................................................................................................. 87
F3 Application Layer .................................................................................................................. 88
F4 Fill Out the Following Items for Outstations Only .................................................................. 90
Gateway Manual Sept 2015 Page 6 of 113
F5 Outstation Unsolicited Response Support ............................................................................. 92
F6 Outstation Unsolicited Response Trigger Conditions ............................................................ 93
F7 Outstation Performance ........................................................................................................ 95
F8 Individual Field Outstation Parameters. ................................................................................. 95
F9 Implementation Table ........................................................................................................... 96
F10 Capabilities and Current Settings for Device Database (Outstation Only) –Point List… … . 97
F10.1 Single-Bit Binary Inputs ............................................................................................. 97
F10.2 Analog Input Points ................................................................................................... 98
APPENDIX G – Detailed DNP3 Point List ....................................................................................... 100
G1 Octet String Events ............................................................................................................ 100
G2 Single Binary Inputs ........................................................................................................... 101
G3 16 Bit Analog Inputs ........................................................................................................... 102
Appendix H – Gateway Firmware Upgrades .................................................................................... 103
Appendix I – Remote Access via TCP/IP…………….…………………………………………………… 110
Gateway Manual Sept 2015 Page 7 of 113
Table of Figures
Figure 1: LineIQ System Overview .................................................................................................. 12
Figure 2: Gateway Isometric View .................................................................................................. 18
Figure 3: Gateway Front Panel ........................................................................................................ 19
Figure 4: Gateway Connectors ........................................................................................................ 20
Figure 5: AC Power Supply Cable .................................................................................................. 21
Figure 6: AC Power Cable with large clamps ............................................................................... 21
Figure 7: External Solar Panel ......................................................................................................... 22
Figure 8: AC power cable with tinned ends .................................................................................. 23
Figure 9: DC power cable with tinned ends .................................................................................. 24
Figure 10: PC Data Cable and Pin Out .......................................................................................... 25
Figure 11: Modem data cable and pinout...................................................................................... 26
Figure 12: Ethernet data cable ........................................................................................................ 26
Figure 13: Cellular Modem power supply connector pinout ...................................................... 28
Figure 14: Status indicators ............................................................................................................. 31
Figure 15: Status Indicator Summary ............................................................................................. 34
Figure 16: Estimated LineIQ Log Average memory usage .......................................................... 46
Figure 17: Estimated Gateway communication speeds .............................................................. 47
Figure 18: LineIQ-60 Health Check downloads times using a cellular modem ....................... 48
Figure 19: LineIQ Health Check download times using cellular model .................................... 49
Figure 20: Lack of response time during Health Check for LineIQs ......................................... 50
Figure 21: Lack of response time during Health Check for LINEIQs ........................................ 51
Figure 22: Solar panel facing the equator (Northern hemisphere mounting) ........................... 53
Figure 23: Solar panel angle measured from vertical .................................................................. 54
Figure 24: Solar panel angle measured from vertical .................................................................. 55
Gateway Manual Sept 2015 Page 8 of 113
Figure 25: LineMan Opening Screen .............................................................................................. 62
Figure 26: LineMan Connection Screen......................................................................................... 63
Figure 27: Selecting the Communications Port from the pull down menu ............................... 63
Figure 28: LineMan Remote Connection Screen ......................................................................... 66
Figure 29: Internal Ethernet module kit .......................................................................................... 67
Figure 30: Internal Ethernet module ............................................................................................... 67
Figure 31: Gateway with cover opened .......................................................................................... 68
Figure 32: Gateway with main shield cover removed .................................................................. 69
Figure 33: Centre pair of SIL 8 pin female connectors (at bottom) ............................................ 69
Figure 34: S3 connector (bottom pair of SIL female connectors) .............................................. 70
Figure 35: Internal RJ45 connector inserted into internal Ethernet module ............................. 71
Figure 36: Internal RJ45 connector inserted into internal module (shield cover replaced) ... 71
Figure 37: External RJ45 cable connected to Data Connector ................................................ 72
Figure 38: LineMan main screen ..................................................................................................... 74
Figure 39: IFC setting window ......................................................................................................... 75
Figure 40: Verifying the COM port number .................................................................................. 103
Figure 41: Gateway Firmware Upgrader opening screen ......................................................... 104
Figure 42: Selecting the .LHX file .................................................................................................. 104
Figure 43: Gateway firmware upgrader with .LHX file selected ............................................... 105
Figure 44: Figure 44: Gateway Firmware Upgrader with COM port selected ........................ 105
Figure 45: Gateway Firmware Upgrade commencing ............................................................... 106
Figure 46: Gateway Firmware Upgrade in progress .................................................................. 107
Figure 47: Gateway Firmware Upgrade completed ................................................................... 107
Figure 48: Using LineMan to verify the firmware version number............................................ 108
Figure 49-55: Gateway Remote Access via TCP/IP...……………………………….......109-113
Gateway Manual Sept 2015 Page 9 of 113
1 International Safety Symbols
CAUTION Symbol: See explanation in manual
This manual covers the Gateway. Other products in the LineIQ suite are described in other manuals.
GridSense places the highest emphasis on safety. Please see section “Error! Reference source not
found.” on page Error! Bookmark not defined.. Ensure that only qualified personnel use the Gateway.
Gateway Manual Sept 2015 Page 10 of 113
2 The LineIQ and Gateway Remote Monitoring Solution The LineIQ system allows electric utilities and other owner/operators of high voltage
overhead conductor electric power transmission systems to remotely monitor and respond
to faults and load changes on the HV network, using LineIQ Conductor Mounted Sensors
(CMS) to detect and store network events (faults, momentary interruptions, outages &
restorations) as well as monitor load currents, conductor temperatures and ambient
temperatures.
LineIQ-60 devices are installed on energized lines. They are battery and solar powered for
long term and continuous monitoring. They can be configured wirelessly using a license
free low power radio (LocalLink) which can is also used to download event and load log
data and to upgrade firmware.
Local wireless configuration and data downloads are performed via the LocalLink unit and
a personal computer (PC) running the GridSense Lineman application software.
For remote connection to LIQ-60 and access to stored data records, a Gateway Pole
Attached Collator (PAC) is mounted within radio range of the LineIQ CMS. The Gateway
functions as a Remote Terminal Unit (RTU) and collates event and load log data from up to
9 LIQ-60 using the low power radio link.
The Gateway can be mains powered DC or battery/solar powered.
LIQ-60 devices transfer event data detecting an event, while load log (line current, line
temperature & ambient temperature) is collected by the Gateway from the LIQ-60 at
regular, user selected intervals, typically once a day.
Transmission of load log data from LIQ-60 to the Gateway occurs during a “health check”.
This data is then transmitted by the Gateway to the remote monitoring system (SCADA) or
is accessed on demand using LineMan Remote software as shown in Figure 1.
A system “Health Check” is initiated by the Gateway independently of events. The Gateway
initiates communications with each LIQ-60 to download all log data and health records
(battery voltage, solar charge current etc.) to the Gateway memory. This information can be
remotely accessed on demand via LineMan Remote or accessed by SCADA via DNP3.
Event records are transferred to the Gateway via unsolicited report and are automatically
transferred to SCADA. If the Gateway is not connected to SCADA, the event records can
be accessed through LineMan Remote or onsite by downloading the data loca l l y .
The Gateway communicates to external systems using either a cellular modem or a utility
radio, and includes space for these to be mounted inside the Gateway.
Gateway Manual Sept 2015 Page 11 of 113
The LineIQ system is powered by solar trickle charged sealed lead acid batteries designed
to provide continuous and long term unsolicited remote reporting of events and historic
load data. This is achieved by minimizing local RF and remote communications through
scheduled and unsolicited reporting, as this means that the communication systems (RF
link and cellular modem or utility radio) can be powered up only when required.
Figure 1 shows how the Gateway interfaces wirelessly to Conductor Mounted Sensors
(CMS) and remotely to external systems via the Gateway RTU and various remote software
applications.
Gateway Manual Sept 2015 Page 12 of 113
Fig
ure
1:
Lin
eIQ
Sys
tem
Ov
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iew
Gateway Manual Sept 2015 Page 13 of 113
3 The LIQ Gateway Congratulations! On your purchase of a LIQ Gateway– a state of the art Remote Terminal
Unit (RTU) for use with LineIQ Conductor Mounted Sensors (CMS).
The Gateway provides an interface to LIQ-60 line mounted high voltage load and event
loggers which are used for load logging and fault detection on overhead high voltage
transmission lines.
Features of the Gateway include:
Low power license free RF communication to up to 9 LIQ-60 CMS devices within RF
range
Supports industry standard DNP3 interface for SCADA applications
Provides remote access to log and event data via:
o LineMan Remote
o Industry standard DNP3 interface
Provides gateway to data from remote locations via:
o Solicited load, line and device status queries (polls) to DNP3 SCADA master
o Unsolicited fault event, momentary outages and load log data to DNP3
SCADA master
o On demand remote download of fault events, load log data and
instantaneous line status queries via LineMan Remote software
Includes multiple communication options:
o UtilinetTM or other utility radio
o GSM Cellular (circuit or packet switched)
o CDMA Cellular (circuit or packet switched)
o 3G Cellular (circuit or packet switched)
o PSTN
o RS232 direct connect
o TCP or UDP over Ethernet
16 bit processor with 4\512 kB non-volatile memory
Real time clock with battery backup
Remote diagnostic and troubleshooting tools
Gateway Manual Sept 2015 Page 14 of 113
Robust IP65 rated weather-proof housing with hinged lid
3.1 What’s in the box?
The Gateway is normally supplied in a ready to use kit which does not include a modem:
Part No. Description
1ALT-PACv2-1 Remote Data Concentrator excluding modem, ready for use
with LIQ-60
1ALT-PACv2-2 Remote Data Concentrator excluding modem, ready for use
with LIQ-60/45/50 (916-US)
1ALT-PACv2-3 Remote Data Concentrator excluding modem, ready for use
with LIQ-60
1ALT-PACv2-4 Remote Data Concentrator excluding modem, ready for use
with LIQ-60 (916-US)
1ALT-PACv2-5 Remote Data Concentrator excluding modem, ready for use
with LIQ-60
1ALT-PACv2-6 Remote Data Concentrator excluding modem, ready for use
with LIQ-60 (916-US)
For safety reasons, use only GridSense accessories specifically designed for use with this product. The
use of any other manufacturer's equipment is NOT recommended, will void the warranty and may cause
safety hazards.
Gateway Manual Sept 2015 Page 15 of 113
3.2 Optional Accessories
The following optional accessories are also available:
Part No. Description
AC-PAC-PC5 AC Power Supply Cable with Australian GPO plug
AC-PAC-PC5-2 AC Power Supply Cable with North American GPO plug
AC-PAC-ACVC AC Power Supply Cable with Clamps
AC-PAC-ACVT AC Power Supply Cable with tinned leads
AC-PAC-DCVT DC Power Supply Cable with tinned leads
1AAC-PAC-Solar External Solar Panel (5 W)
1AAC-PAC-Solar-10W External Solar panel (10 W)
1AAC-PAC-RC2-PC Gateway external RS232 Data Cable for direct PC connection, 3m length
1AAC-PAC-RC2-RTU Gateway external RS232 Data Cable for direct Modem/RTU connection, 3m length
1AAC-PAC-ETHMODULE Ethernet upgrade module (including Ethernet Data Cable)
AC-PAC-ETHERNET-CABLE Gateway external PAC to Ethernet connection cable, 3m length
1AAC-3GK 3G ModMax cellular modem kit for use with Gateway
1AAC-GSMK GSM/GPRS cellular modem kit for use with Gateway
1AAC-PSTNK Landline modem kit for use with Gateway
1AAC-CDMAK CDMA modem for use with Gateway
1AAC-SATK Satellite modem for use with Gateway
Utility radio - no part number as not supplied by GridSense
1AAntenna-800/900 Gateway external 3G Cellular Antenna accessory kit
1AAC-PAC-Yagi High Gain Yagi Antenna
1AAC-PAC-OMNI Omni Directional Antenna
For safety reasons, use only GridSense accessories specifically designed for use with this product. The
use of any other manufacturer's equipment is NOT recommended, will void the warranty and may cause
safety hazards.
Gateway Manual Sept 2015 Page 16 of 113
4 Quick Start Guide The information presented in this section is a duplicate of the information presented on a
sticker inside the front lid of the Gateway.
1. If a cellular modem is to be installed, mount it to the modem mounting plate using
the two screws provided. Connect the DB15 data connector the antenna connector
and the power supply connector to the modem. The modem will need to be
preconfigured before installation.
2. If a radio modem is to be installed, mount it above the battery pack using the
mounting hardware provided. Do not remove the protective cove on the battery
pack. Connect the DB9 data connector, the antenna connector and the power
supply cable.
3. Install the RF antenna located on the inside of the lid. Screw it to the small socket
mounted on the right hand side of the enclosure. Don’t over tighten the antenna.
4. Check that all unused connectors are fitted with blanking plugs. Close the lid and
secure the latches.
5. Switch on the Gateway. The Status and Fault indicators will flash as follows:
The Fault indictor will flash red rapidly for 3 seconds
The Status indicator will flash amber rapidly for 3 seconds
The Status indicator will flash amber once every second for an
uncommissioned Gateway.
6. Mount the Gateway within 30 meters of the associated LIQ-60s with a direct line of
sight between the Gateway and the LIQ-60s. The Gateway should be oriented so
that the connectors are facing down so that it is possible to view the LED indicators
from the ground.
7. To optimize the performance of the LineIQ RF communications with the Gateway ,
the orientation of the Radio antenna’s between the Gateway and LineIQ must be
kept as parallel as possible as illustrated below:
8. Connect the cellular or radio antennas as required.
9. Connect the power supply. Your supply will be either (a) solar panel, (b) AC mains or
a (c) DC source:
a) Solar Panel - Install the solar panel so that it face towards the sun
at noon - south in the northern hemisphere and north in the
Gateway Manual Sept 2015 Page 17 of 113
Southern hemisphere. Adjust the angle of the solar panel,
measured from the vertical, to be approximately latitude + 15o.
Connect the solar panel to the Gateway.
b) AC mains - Connect the AC supply using appropriate safety
equipment if working on live connections. The supply must be
between 55 V and 600 V AC at either 50 Hz or 60 Hz.
c) DC Source - Connect the external power cable to a 12 V 1 Amp DC
supply, and then connect this cable, observing polarity, to the
Gateway.
10. Using a LocalLink and LineMan software installed on your PC, configure the LIQ-
60and Gateway.
11. Send a commission command to activate the site.
12. Finally, verify that data is being correctly received via the remote communication
system.
Gateway Manual Sept 2015 Page 18 of 113
5 Gateway Overview
5.1 The Gateway
An isometric view of the Gateway is shown in Figure 2 below:
Figure 2: Gateway Isometric View
The Gateway is an intelligent Remote Terminal Unit (RTU) for GridSense LIQ-60 line
mounted sensors to be efficiently and easily integrated into remote SCADA systems using
DNP3 protocol. In parallel the Gateway provides communication and data transfer to the
GridSense LineMan Remote application software.
The Gateway enables remote unsolicited fault and outage events for network reliability
applications. Detailed fault profiles for fault location analysis, modelling and scenarios, as
Gateway Manual Sept 2015 Page 19 of 113
well as system loading information for planning, line balancing and asset utilization
applications.
5.2 Indicators and Controls
Figure 3: Gateway Front Panel
The Gateway base has four connectors AC Mains / Solar power input, Data, Radio Antenna
& Cellular Antenna, an ON/OFF switch and it also has two visual indicators.
The “Status” Indicator is an amber high intensity LED, while the “Fault” Indicator is a red
high intensity LED. The status indicators are used for fault/event annunciation and to
indicate remote connection, activities, to confirm that the Gateway is on and what mode it
is in.
The unlabeled hexagonal item in the center of the front panel is a pressure relief valve. This
valve allows the internal air pressure to equalize with the external air pressure while
maintaining the IP65 integrity of the Gateway.
Gateway Manual Sept 2015 Page 20 of 113
5.3 External Connectors
Connector Specification
AC MAINS /
SOLAR
8 pin voltage connector – used to connect external power sources – AC mains
(55 – 600 Volts AC 50 Hz or 60 Hz), solar panel or DC source (13.8 Volts DC 1
Amp)
DATA 12 pin data connector – allows external wired connections (RS232, or Ethernet)
RADIO
ANTENNA
N type female – allows connection of an external radio antenna
CELLULAR
ANTENNA
N type female – allows connection of an external cellular antenna
Local RF
Antenna
SMA female (mounted on side of Gateway)
Figure 4: Gateway Connectors
5.4 Local RF Link
The local license free RF communication system uses low power half duplex radio links.
The minimum operating range is 30 m (100 ft.) using the small antenna mounted on the side
of the Gateway enclosure.
The operating RF frequency is at 2.4GHz with maximum power output of 4mW.
5.5 AC Power Cable (Optional)
The fused PC5 (PC5-2 in North America) Power Cable provides a means of connecting
electrical power to the Gateway. A GPO plug is available to suit local requirements.
The internal switch mode power supply operates from 60 to 600 V AC at standard supply
frequencies (50 Hz or 60 Hz). Maximum power consumption is 15 VA.
Gateway Manual Sept 2015 Page 21 of 113
Figure 5: AC Power Supply Cable
5.6 AC Power Cable with large clamps leads (Optional)
The AC-PAC-ACVC power cable is fitted with large clamps. The clamps include integral
High Rupture Capacity (HRC) fuses which are not user replaceable.
Figure 6: AC Power Cable with large clamps
As shown in Figure 6, labels “Phase A” and “Neutral” are fitted adjacent to the two clamps.
The leads are 3 m (10 ft.) long.
Gateway Manual Sept 2015 Page 22 of 113
5.7 External Solar Panel (Optional)
The AC-PAC-SOLAR External Solar Panel allows the Gateway to operate without access to
mains power.
Figure 7: External Solar Panel
A connection cable and mounting bracket is included with the Solar Panel.
Depending on the application, customers may wish to use their own higher capacity solar
panel. A DC power cable is available for this purpose. Contact GridSense if you are unsure
if the standard solar panel is suitable for your application.
Gateway Manual Sept 2015 Page 23 of 113
5.8 AC Power Cable with tinned leads (Optional)
The AC-PAC-ACVT power cable has tinned ends and allows direct connection of an
external AC supply. This cable includes non-replaceable in line High Rupture Capacity
(HRC) fuses.
Figure 8: AC power cable with tinned ends
Gateway Manual Sept 2015 Page 24 of 113
5.9 DC Power Cable (Optional)
The AC-PAC-DCVT power cable allows operation from an external regulated 13.8 Volt DC
supply, or from a large external solar panel. It is provided with tinned ends.
Figure 9: DC power cable with tinned ends
Gateway Manual Sept 2015 Page 25 of 113
5.10 PC Data Cable (Optional)
The AC-PAC-RC2 Data cable allows connection of the Gateway to a standard 9 pin male
PC or RTU serial port.
Figure 10: PC Data Cable and Pin Out
The PC Data cable is fitted with a 9 pin female connector. 5 pins are connected – TX, RX,
CTS, RTS and GND.
For troubleshooting purposes, this cable is used to connect the Gateway to a PC running
LineMan software.
Gateway Manual Sept 2015 Page 26 of 113
5.11 Modem Data Cable (Optional)
The AC-PAC-MODEM-CABLE allows connection of the Gateway to a standard 9 pin female
modem serial port.
Figure 11: Modem data cable and pinout
The Modem Data cable is fitted with a 9 pin male connector. 5 pins are connected - TX, RX,
CTS, RTS and GND.
This cable is used to connect the Gateway to an external modem.
5.12 Ethernet Data Cable (Optional)
Figure 12: Ethernet data cable
Gateway Manual Sept 2015 Page 27 of 113
This Ethernet Data Cable is used to connect the Gateway directly to the internet using an
industry standard RJ45 10 base T connector, typically in a substation.
5.13 Internal Ethernet Module (Optional)
The Ethernet module provides TCP and UDP internet access, and is supplied complete
with an external Ethernet Data Cable.
If the Gateway is ordered with this accessory, it is pre-installed.
If the Internal Ethernet Module is ordered at a later date as an accessory to be installed into
an existing Gateway, refer to “APPENDIX C – INTERNAL ETHERNET MODULE” for
installation details.
Refer to section 18.2 for details on how to configure the Internal Ethernet Module.
5.14 Cellular Modem (Optional)
An internally mounted modem can be used to interface the Gateway to external systems
using commercial cellular phone systems.
If the cellular modem is ordered with the Gateway, the modem power supply loom is
supplied and connected to the modem, which is installed in the G a t e w a y .
If no cellular modem is ordered with the Gateway, the modem power supply loom is not
supplied. The required 3 pin connector is provided and is installed onto the main printed
circuit board.
Both 12V DC and 5V DC supplies are available. The pinouts for the connector areas shown
in Figure 10.
Gateway Manual Sept 2015 Page 28 of 113
Figure 13: Cellular Modem power supply connector pinout
5.15 Utility Radio (Optional)
An internal mounting location is provided for a user supplied utility radio for interfacing the
Gateway to an external radio network.
5.16 Omni Directional Antenna Kit (Optional)
The AC-PAC-OMNI external Omni-directional antenna kit provides standard coverage for
the internally mounted cellular modem.
Note that the antenna must match the cellular frequency as dictated by the cellular modem
and cellular service provider.
5.17 External High Gain Yagi Antenna Kit (Optional)
The AC-PAC-YAGI external Yagi Antenna kit allows for reliable cellular communications in
areas of marginal coverage.
Note that the antenna must match the cellular frequency as dictated by the cellular modem
and cellular service provider.
Gateway Manual Sept 2015 Page 29 of 113
6 Safe Use of the Gateway
The LineIQ Conductor Mounted Sensors associated with the Gateway are intended to be
used on high voltage energized lines or equipment. Personnel using equipment on
energized lines must be authorized by the relevant regulatory bodies to carry out such work
and must have appropriate training.
The information given in this document is given as a guide only. It is the user's
responsibility to ensure that correct and safe procedures are followed at the actual
worksite. GridSense offers no warranty or indemnity for accidents that may occur when
following these instructions.
6.1 Hazard Assessment
Prior to installing the Gateway, the operator must carry out a worksite, pre-job hazard
assessment to identify the safety and environmental needs. This must be done prior to
commencing work and prior to recommencing work after leaving and returning to the
worksite. As a minimum, this hazard assessment should:
Identify possible hazards and risks
Identify the safety needs of the job
Identify the correct procedures, practices and equipment for the job
Eliminate unsafe conditions and actions from the worksite
Identify the need for personal protective equipment
There should also be an on-going risk assessment during the job
Inspection before use
Prior to using a Gateway, you should check the following:
The sheaths of all cables are secured and undamaged at both ends
If you do not understand any instructions in this manual, please ask someone
to assist you.
If the Gateway and accessories are used in a manner not specified in this
manual, the protection provided by the equipment may be impaired.
Gateway Manual Sept 2015 Page 30 of 113
Plugs and connectors are properly connected and serviceable
6.2 Live low voltage work
For the correct and safe use of this equipment, it is essential that all operating personnel
follow appropriate safety procedures.
6.3 Live high voltage work
For the correct and safe use of this equipment, it is essential that all operating personnel
follow appropriate safety procedures.
6.4 Equipment safety
The Gateway equipment should be regularly tested and maintained to make sure the
equipment and cables are in good order.
Check your relevant employer or regulatory body's rules for working with live
low voltage equipment.
Check your relevant employer or regulatory body's rules for working with live
high voltage equipment.
Gateway Manual Sept 2015 Page 31 of 113
7 Configuring the Gateway before Use
7.1 Introduction
The Gateway is configured using LineMan software. Refer to the LineMan User Manual for
detailed instructions on how to install and use Lineman. Brief details are also provided in
APPENDIX A.
7.2 Communicating with the Gateway
Plug in the LocalLink1 to an open USB on the PC. Make sure the proper COMS port is
selected in LineMan. You are now ready to communicate with the LIQ-60 and Gateway
units.
7.3 Gateway Status
Gateway status is provided by the two LED indicators in the bottom right hand corner of
the front panel.
Figure 14: Status indicators
The main modes of operation are shown as follows:
Power On / Reboot
8 short red flashes followed by 8 short amber flashes
1 To determine the COM Port connection, access the Device Manager (Control Panel → System
→ Device Manager) and expend the selection “Ports”, the selection USB Serial Port will identify
the correct COM Port number
Gateway Manual Sept 2015 Page 32 of 113
This sequence indicates successful initialization and start-up of the Gateway. Refer to
Section 10, “Troubleshooting,” if you do not see this sequence after the Gateway is
switched on.
For the first 5 minutes after power is applied, the red LED will flash whenever RF activity is
detected. This provides an indication of RF interference which may cause communication
errors.
Gateway requires Commissioning
Amber LED flashes once per second
This sequence indicates that the Gateway has not been commissioned.
Commissioning involves initialization of several aspects of the LineIQ site being monitored.
Many aspects of Gateway operation, including DNP3 communications, are disabled until
the Gateway is commissioned.
GridSense recommend that after physical installation has been completed, the Gateway
and associated LIQ-60units are commissioned manually on site using the LocalLink and
LineMan software.
This allows the user to verify that the commissioning process has been successfully
completed prior to leaving the site by monitoring the Status LEDs.
If a Gateway is not manually commissioned, an auto-commission will occur immediately
prior to the first scheduled health check or after one hour, whichever occurs first.
Failed Commission
Alternating Red and Amber LEDs
This sequence indicates that commissioning has failed.
Refer to Section 10 for further information.
Normal operation
Three Amber flashes repeated each minute
This indicates normal idle operation.
RF Communications in progress
Fast Flashing Amber LED
Gateway Manual Sept 2015 Page 33 of 113
This indicates that the Gateway is communicating over the local RF link to one of the
associated LineIQ Conductor Mounted Sensors (CMS).
Local RF communication occurs:
During the commissioning process
When a periodic health check is in progress
When an event has been detected by a LineIQ CMS
When instantaneous line data has been requested by a SCADA master
When instantaneous line data has been requested by LineMan Remote software
You will not be able to communicate with the Gateway using LineMan software and the
local RF link during this time.
Please wait until the Gateway returns to normal idle operation before attempting to
communicate with it.
Outbound call in progress
Slow flashing Red LED (once per second)
This indicates that the Gateway is making an outbound call to report data or
commissioning results to SCADA
You will not be able to communicate with the Gateway using LineMan software and the
local RF link during this time.
Ethernet communications in progress
Continuous fast flickering Amber LED
This indicates that Ethernet communications are in progress.
Firmware upgrade in progress
Red and Amber LEDs permanently on
This indicates that a firmware upgrade is in progress.
Configuration Error
Fast Flashing Red LED
This indicates that there has been a configuration error.
The status indication modes are summarized in Figure 15 below:
Gateway Manual Sept 2015 Page 34 of 113
LED Indicator Description
Amber LED
Red LED
Figure 15: Status Indicator Summary
7.4 Starting LineMan
1. Start LineMan by double clicking on the desktop icon, or selecting it from the Start
Menu.
2. If you are not familiar with LineMan or you need to install it, refer to the LineMan
User Manual or to Section 7.4.
3. From the LineMan device selection window, select the Gateway.
Gateway Manual Sept 2015 Page 35 of 113
4. The following commands can then be used:
Status - provides details of the battery voltage, battery drain current, charging
voltage, charging current and internal temperature
Summary – provides details of serial number, firmware version, hardware
revision and other parameters
Configure – allows the Gateway to be configured
Data Download – allows data to be downloaded. This command is normally
used only with conductor mounted sensors (CMS)
Commission – allows the Gateway to be commissioned. This should only be
done after the entire site (Gateway and LineIQs) have been correctly configured
Restart – performs a warm restart (reboot) of the Gateway microprocessor, and
is equivalent to switching the power off and then on again
7.5 How will the Gateway communicate?
From the viewpoint of the Gateway, the outside world can manifest itself in three ways:
As a PC running LineMan Remote software. In this mode, the Gateway only
responds to external requests for event and load log data. In this mode, the
Gateway never initiates external event and load log data transfers
As a SCADA control system, to which the Gateway can send unsolicited event
and load log data, and which can request the Gateway to provide event and
load log data
The configuration of the Gateway depends on which of these viewpoints is to be
implemented. Please refer to the relevant section below for information on how to configure
the Gateway.
7.6 Working with LineMan Remote
LineMan Remote allows remote connection to a Gateway.
Refer to the LineMan Remote User Manual for details on how to communicate with a
Gateway using LineMan Remote.
A brief introduction to LineMan Remote is provided in APPENDIX B.
7.7 Working with a DNP3 SCADA master
The Gateway implements a versatile, industry standard DNP3 interface for seamless
integration into SCADA systems. The interface can operate:
Gateway Manual Sept 2015 Page 36 of 113
in a fully polled mode
a report by exception (unsolicited) mode
a combination of the two above modes
Refer to APPENDIX D for a detailed description on how to configure and use the DNP3
interface.
APPENDIX E provides a quick reference to the DNP3 points implemented by GridSense in
the Gateway.
Refer to APPENDIX F for the complete DNP3 Implementation Table.
Refer to APPENDIX G for the complete DNP3 Point List.
Gateway Manual Sept 2015 Page 37 of 113
8 Installing Your Gateway
8.1 Pre-installation checks
If AC line power is provided, verify that the supply voltage is between 60 and 600 V
AC, and capable of supplying 15 VA. Supply frequency can be either 50 Hz or 60 Hz
If using cellular communications, confirm that there is adequate coverage at the
site. If possible, ascertain the direction of the closest cellular tower
If using internet communications, verify that a working internet connection is
available
If using an external solar panel, verify that adequate sunlight is available, and
determine the direction to the sun at noon – south in the northern hemisphere and
north in the southern hemisphere
8.2 Mounting
The Gateway should be mounted within 30 m (100 ft.) of associated LIQ-60 units.
Orient the Gateway so that the connectors are towards the ground.
Mount the Gateway using 2 suitable sized screws above and below the main body, using
the attached metal mounting bracket.
The solar panel should be mounted in a sunny location so that it faces the equator (south in
the northern hemisphere and north in the southern hemisphere).
The solar panel should be mounted so that the angle between the face of the solar panel
and a horizontal plane is approximately 15 degrees more than the latitude of the location.
8.3 Post-installation checks
Once installation is complete, check that:
The Gateway is securely mounted
The solar panel is securely mounted, faces the equator and is at the correct angle
The small RF antenna is screwed securely to the socket on the side of the Gateway
All connectors are securely tightened
The waterproof cap is installed on the data port connector
All cables are secure and unlikely to move or dislodge
Gateway Manual Sept 2015 Page 38 of 113
If used, AC power is available and is connected
If used, DC power is available and is connected with the correct polarity
Gateway Manual Sept 2015 Page 39 of 113
9 Commissioning the Gateway After installation is complete, and before you leave the site, the Gateway and associated
LIQ-60 devices must be configured, and then the Gateway must be commissioned.
To do this, you will need a LocalLink and LineMan software.
Before commencing, make sure that the real time clock in the PC or laptop is set correctly.
GridSense recommends that 24 hour mode is used for the clock, rather than AM/PM mode.
For further information on LineMan, refer to the LineMan User Manual. APPENDIX A
provides brief details on LineMan software.
9.1 Step 1: Configuring the CMS devices
Using LineMan and the LocalLink, connect to each CMS device.
Confirm that:
The internal battery voltage exceeds 2 V
There is some solar charge current if the solar panel is illuminated
Event recording is enabled if required
Load logging is enabled if required
Line currents are as expected
Voltage sensor values are as expected
The appropriate Gateway has been assigned as a parent to the CMS
9.2 Step 2: Configuring the Gateway
Turn on the Gateway using the front panel switch.
Observe the red and amber indicators:
The red indicator should flash 8 times
The amber indicator should flash 8 times
The amber indicator should flash slowly at 1 second intervals
Using the LocalLink and LineMan, connect to the Gateway.
Gateway Manual Sept 2015 Page 40 of 113
Confirm that:
The internal battery voltage exceeds 12 V
There is some solar charge current if the solar panel is illuminated
The appropriate LIQ-60 devices have been assigned as children to the Gateway
The health check interval has been assigned
The interface control (IFC) settings have been properly configured for the
desired Gateway application and modem or other communications interface
Gateway Manual Sept 2015 Page 41 of 113
9.3 Step 3: Commissioning the Gateway
The final step before leaving the site is to commission the Gateway.
The Gateway will then automatically commission any associated LIQ-60 devices, and
initiate the first health check.
Subsequent health checks will occur at the specified interval, typically every 24 hours.
The GridSense recommended procedure is to:
Commission the Gateway using LineMan and a LocalLink
Observe the Gateway status indicators and confirm that the Idle state has been
reached (three amber flashes every minute)
This may take several minutes. Status indications during commissioning will include a fast
amber flash while the Gateway is communicating with LineIQs via the RF link.
If the Gateway begins to flash alternating red and amber LEDs, the commissioning process
has failed. Refer to Section 9 or further details.
GridSense recommends that correct operation of the remote communications
system is verified as part of the installation process before leaving the site
Gateway Manual Sept 2015 Page 42 of 113
10 Troubleshooting
10.1 Internal battery is discharged:
The Gateway will not start up until the internal 12 V battery is charged. If the internal 12 V
battery is completely discharged, connect the AC or DC power and wait for at least 16
hours before turning the Gateway on.
10.2 LineMan cannot communicate with Gateway:
Ensure that the LocalLink is connected to the PC, and that the correct
communication port (RS232) is selected
Some notebook hardware RS232 ports are also incompatible with the LocalLink
Ensure that the Gateway is switched on and the internal battery is charged
10.3 Gateway does not communicate with external peripherals:
Check that the port selections and baud rates are correctly configured
Ensure that the site has been commissioned
10.4 Unable to connect via LineMan-Remote:
Check that the modem is powered on and correctly configured
Ensure that you have the correct modem phone number, including international
and area codes. If you are dialing through a PABX, make sure that you have
included the appropriate access code for an external line
Confirm that you have an analog phone line. Many PABX systems provide digital
phone lines which are incompatible with analog modems
Confirm that the internet connection is working
Verify that you have the correct IPV4 style TCP or UDP internet address and port
number
Gateway Manual Sept 2015 Page 43 of 113
10.5 Unable to communicate with SCADA system:
Check that the Gateway SCADA port is correctly configured
Confirm that DNP3 is enabled
Ensure that the DNP3 link address is correct
10.6 Gateway displays alternating red and amber LEDs after
commissioning:
This indicates that commissioning of at least one LIQ-60 has failed.
Check that:
The list of child LIQ-60s assigned to the Gateway is correct
Each LIQ-60 is powered on and can be successfully communicated with using
Lineman
Each LIQ-60 is no further than 30 m (100 ft.) from the Gateway
10.7 Gateway displays fast flashing red LED:
This indicates that the Gateway configuration is invalid.
Re-configure the Gateway using the latest version of LineMan software
If this problem persists, please contact GridSense for assistance
system is verified as part of the installation process before leaving the site
Gateway Manual Sept 2015 Page 44 of 113
11 Operating Principles
11.1 Gateway Memory Usage
The internal 512 kB memory of the Gateway is partitioned into 3 sections
256 kB is used for internal variables and a data scratchpad
128 kB is used for storage of event information
128 kB is used for storage of load log information
11.2 Event Memory
As events are detected by associated LineIQ CMS, the event information is transferred to
the Gateway and stored in the Gateway event memory.
A typical event, including current and voltage waveforms, requires approximately 1 kB of
memory for storage.
Event information is transferred from the Gateway event memory to an external system by
either an unsolicited (initiated by the Gateway) or a solicited (initiated remotely) request.
11.3 Unsolicited event data transfers
Unsolicited event data is sent to a SCADA control system.
There is a small delay (approximately 1 minute) between when the first event data is
detected by a LIQ-60 and when the unsolicited data transfer commences. This delay is
required to allow event data from all associated LIQ-60 to be transferred to and collated by
the Gateway.
Once an acknowledgment of successful data transfer has been received, the Gateway
event memory is cleared.
In this mode, because the event data is transferred shortly after the events occur, there is
generally no problem with the event memory filling up and event data being lost.
Gateway Manual Sept 2015 Page 45 of 113
11.4 Solicited event data transfers
Solicited event data can be requested by LineMan Remote or a SCADA system.
As each event recorded by a LIQ-60requires approximately 1 kB of memory for storage,
about 120 individual events can be stored in the Gateway event memory.
So for a Gateway with three child LineIQ CMS, all of which are presumed to see the same
event, only 40 events can be stored.
For a system with 9 child LineIQs, approximately 12 events can be stored.
It is up to the user to ensure that event data is transferred from the Gateway before the
event memory fills up.
For a DNP3 solicited event data transfer, once an acknowledgment of successful
data transfer has been received, the Gateway event memory is cleared
For a LineMan Remote solicited event data transfer, the user has the option as to
whether to clear the event memory or not.
If the event memory is not cleared, when the event memory fills up, older events will be
overwritten by newer events
11.5 Load Log Memory
Load log (line current) data (including conductor temperature for LineIQ CMS) is
downloaded from associated LineIQs on a regular basis during a Health Check, and is
stored in the Gateway Load Log memory.
The amount of data which is downloaded depends on the number of associated LineIQ
CMS, the type of LIQ-60and on the Log Average period.
For an LIQ-60 logging line current, power factor, conductor temperature and ambient
temperature, each Log Average sample requires 48 bytes of storage in the Gateway.
With the recommended Log Average interval of 15 minutes, this is equivalent to 1.5 kB of
storage per day for each 4.5 kB per day for each LineIQ-60 CMS.
Figure 18 below shows estimated percentage memory usage for 3, 6 and 9 LIQ-60 with
Log Average rates between 2 and 60 minutes
Gateway Manual Sept 2015 Page 46 of 113
Days to Fill Gateway Log Average Memory with
Line Tracker LIQ-60 Load Log Data
Log Average
(min)
3x LIQ-60
(days)
6x LIQ-60
(days)
3x LIQ-60
(days)
2 1.3 0.6 0.4
5 3.2 1.6 1.1
10 6.3 3.2 2.1
15 9.5 4.0 3.2
30 19.0 9.5 6.3
60 37.9 19.0 12.6
Figure 16: Estimated LineIQ Log Average memory usage
Note that with a 2 minute Log Average period, the Gateway memory capacity is exceeded
in less than 1 day with 6 or 9 associated LineIQ CMS.
If the load log data is transferred out of the Gateway at the recommended rate (once per
day as set by the Health check period), then the tables above show that except in extreme
cases of rapid sampling, the Gateway load log memory capacity is never exceeded, so that
no load log data is lost.
For solicited systems, these tables can also be used to estimate the frequency at which the
data must be downloaded from the Gateway.
For example, for a system with 6 LineIQ CMS installed and in which the Log Average
period is set to 30 minutes, it is necessary to download the load log data once a week,
since otherwise the Gateway Log Average memory will overflow after 9.5 days. The
additional 2.5 days of memory capacity would act as a reserve to allow for a download
after say 8 days, as might happen because of unforeseen circumstances such as public
holiday.
Gateway Manual Sept 2015 Page 47 of 113
11.6 Estimated Download Times
Estimated communication speeds for the five communication systems which can be used
to transfer event and load log data from the Gateway are shown Figure 19 below:
Comms
System
Effective
Throughput Units Comments
Estimated Download Time
(mins)
Internet 115 kB/min direct wired
connection 1.1
mins to transfer event
or load log memory
Direct
RS232
85
kB/min
direct wired
connection, 19 200
Baud
1.5
mins to transfer event
or load log memory
Cellular
Modem 55 kB/min
based on 9600 baud
overall throughput 2.3
mins to transfer event
or load log memory
Utility Radio 25 kB/min based on 4800 baud
overall throughput 5.1
mins to transfer event
or load log memory
RF Link 84 kB/min based on 57600
baud connection 1.5
mins to transfer event
or load log memory
Figure 17: Estimated Gateway communication speeds
These speeds are limited either by the communication system (cellular modem or utility
radio) or by the Gateway itself (Internet or RS232). The RF link speeds are limited by the
packet system (180 byte packet length) and the half duplex communication system.
The times are shown in seconds, and do not include call set up times.
This table includes down load times for 2, 5, 10, 15, 30 & 60 minute log average periods,
Health Check periods of 1, 2, 4, and 13 & 24 hours and for 3, 6 & 9 associated LineIQ CMS.
The download time is proportional to the amount of load log data collated by and stored in
the Gateway, and this is related to the three input variables modelled in this table:
Log Average period - as this decreases, more load log data is collected by
the LineIQ CMS, and therefore the amount of load log data collated by the
Gateway between each Health Check increases.
Gateway Manual Sept 2015 Page 48 of 113
Health Check interval – as this increases, the amount of load log data
collated by the Gateway during each Health Check interval increases.
No of associated CMS – as this increases, the amount of load log data
collated by the Gateway during each Health Check interval increases.
The shortest download times occur with the largest Log Average period, the smallest
Health Check interval and the least number of associated LineIQ CMS.
The longest download times occur with the smallest Log Average period, the longest
Health Check interval and the largest number of associated LineIQ CMS.
The user must be aware that with a small Log Average period, long Health Check interval
and large number of associated LineIQ CMS, the capacity of the Gateway load log memory
(128 kB) may be exceeded, and load log data will be lost.
Gateway Health Check download time (sec.) for LIQ-60 via Cellular Modem at 55Kb/min
Health Check
Every Hour
Health Check
Every 2 Hour
Health Check
Every 4 Hour
Health Check
Every 12 Hour
Health Check
Every 24 Hour
Log Average
(mins)
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
2 2 4 5 4 7 10 7 13 19 19 37 56 37 74 111
5 1 2 2 2 3 4 3 5 8 8 15 23 15 30 45
10 1 1 1 1 2 2 2 3 4 4 8 12 8 15 23
15 1 1 1 1 1 2 1 2 3 3 5 8 5 10 15
30 1 1 1 1 1 1 1 1 2 2 3 4 3 5 8
60 1 1 1 1 1 1 1 1 1 1 2 2 2 3 4
Figure 18: LIQ-60 Health Check downloads times using a cellular modem
In Figure 17 above, the Gateway memory capacity is almost exceeded with a 2 minute Log
Average period, a Health Check interval of 24 hours, and 9 associated LineIQ CMS.
With a different communication system, and hence a different data transfer rate, the times
shown in Figure 21 will change proportionately.
For example, if the Health Check data is transmitted using a direct wired internet
connection, the effective data transfer rate increases from 55 kB/min to 115 kB/min, so the
download times shown in Figure 21 will reduce by a factor of 2.1, giving a download time of
45 / 2.1 = 22 seconds for a Gateway monitoring 9 LineIQ CMS with Log Average period of
5 minutes and a Health Check interval of 24 hours.
Figure 19 is similar to Figure 18, but shows download times for LineIQ CMS.
Gateway Manual Sept 2015 Page 49 of 113
Health Check download time (sec.) for LIQ-60 via Cellular Modem at 55kB/min
Health Check
Every Hour
Health Check
Every 2 Hour
Health Check
Every 4 Hour
Health Check
Every 12 Hour
Health Check
Every 24 Hour
Log Average
(mins)
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
2 7 14 20 10 20 30 20 40 59 56 112 O'flow 112 O'flow O'flow
5 4 7 10 7 14 20 10 20 30 23 46 69 46 98 138
10 4 7 10 4 7 10 7 14 20 14 27 40 23 46 69
15 4 7 10 4 7 10 4 7 10 10 20 30 17 33 50
30 4 7 10 4 7 10 4 7 10 7 14 20 10 20 30
60 4 7 10 4 7 10 4 7 10 4 7 10 7 14 20
Notes 1 Cells shaded red represent senarios where the Gateway load log memory overflows during the health check
Figure 19: LineIQ Health Check download times using cellular model
Note that because of the increased (three times) memory requirements of a LineIQ CMS
compared to a LineIQ CMS, the download times for a given configuration are three times
longer.
Note also that with a 2 minute Log Average period and a long Health Check interval, the
Gateway load log memory will overflow between Health Checks. These cases are shown in
red in Error! Reference source not found.
11.7 Gateway lack of response during Health Checks
While the Gateway is performing a health check, it is unresponsive to events generated by
associated LineIQ CMS, and to external requests (from LineMan Remote or a SCADA
system) for data. This is because the Gateway needs to talk to each associated LIQ-60 to
download the load log data from the CMS over the local radio link.
External requests will be ignored while the Health Check is in progress.
Unsolicited event data from associated LIQ-60 will be ignored. The event data will not be
lost, however, as the automatic retry system means that the CMS will repeatedly try to re-
send the event data. Once the Health Check is completed, the Gateway will respond to
these requests, and the event data will be downloaded into the Gateway.
The amount of time that the Gateway is unresponsive depends on a number of factors:
The Log Average period used in the LineIQ-60 to store load log data – the shorter
the load log interval, the more data has to be downloaded during each Health
Check.
Gateway Manual Sept 2015 Page 50 of 113
The Health Check interval – a longer Health Check interval increases the amount of
load log data to be downloaded, leading to a commensurate increase in the
download time.
Refer to Figure 20 for a table of times during which a Gateway monitoring LineIQ LIQ-60
CMS is unresponsive to external requests.
Time in minutes during which the Gateway is unresponsive due to LIQ-60 Health Check
Activity
Health Check
Every Hour
Health Check
Every 2 Hour
Health Check
Every 4 Hour
Health Check
Every 12 Hour
Health Check
Every 24 Hour
Log Average
(mins)
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
2 1.0 1.9 2.8 1.3 2.6 3.9 2.2 4.4 6.6 5.5 10.9 16.3 10.5 21.0 31.5
5 0.6 1.2 1.8 0.8 1.5 2.3 1.1 2.3 3.4 2.6 5.1 7.7 4.6 9.1 13.6
10 0.6 1.2 1.8 0.6 1.2 1.8 0.8 1.5 2.3 1.5 3.0 4.5 2.6 5.1 7.7
15 0.6 1.2 1.8 0.6 1.2 1.8 0.8 1.5 2.3 1.1 2.3 3.4 0.9 3.7 5.5
30 0.6 1.2 1.8 0.6 1.2 1.8 0.8 1.2 1.5 0.8 1.5 2.3 1.1 2.3 3.4
60 0.6 1.2 1.8 0.6 1.2 1.8 0.8 1.2 1.2 0.6 1.2 1.8 0.8 1.5 2.3
Notes 1 Cells shaded yellow represent scenarios where the Gateway is unresponsive for more than 15 mins during each health check
Cells shaded red represent scenarios where the Gateway is unresponsive for more than 30 mins during each health check 2
Figure 20: Lack of response time during Health Check for LineIQs
GridSense recommends that Health Checks be performed only once per day (i.e. the
Health Check interval is 24 hours), and that the Log Average period be set to 15 minutes.
With these settings, a Gateway monitoring 6 LineIQ-60 CMS is unresponsive for only 3.7
minutes each day. This represents 99.7% availability.
If this site were configured for a Log Average period of 2 minutes with a Health Check every
hour, the Gateway will be unresponsive for 1.9 minutes each hour, or 45.6 minutes each
day, which represents 96.8% availability.
Refer to Figure 21 for a table of times during which a Gateway monitoring LineIQ-60 is
unresponsive to external requests.
Gateway Manual Sept 2015 Page 51 of 113
Health Check
Every Hour
Health Check
Every 2 Hour
Health Check
Every 4 Hour
Health Check
Every 12 Hour
Health Check
Every 24 Hour
Log Average
(mins)
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
3 x
LIQ‐60
6 x
LIQ‐60
9 x
LIQ‐60
2 1.3 2.6 3.9 2.2 4.4 6.6 3.8 7.7 11.5 10.5 21.0 O'flow 20.4 O'flow O'flow
5 0.8 1.5 2.3 1.1 2.3 3.4 1.9 3.7 5.5 4.6 9.1 13.6 8.5 17.0 25.5
10 0.6 1.2 1.8 0.8 1.5 2.3 1.1 2.3 3.4 2.6 5.1 7.7 4.6 9.1 13.6
15 0.6 1.2 1.8 0.8 1.5 2.3 1.0 1.9 2.8 1.9 3.7 5.5 3.1 6.2 9.3
30 0.6 1.2 1.8 0.6 1.2 1.8 0.8 1.5 2.3 1.1 2.3 3.4 1.9 3.7 5.5
60 0.6 1.2 1.8 0.6 1.2 1.8 0.8 1.2 1.8 0.8 1.5 2.3 1.1 2.3 3.4
Notes 1 Cells shaded yellow represent senarios where the Gateway is unresponsive for more than 15 mins during each health check
Cells shaded red represent senarios where the Gateway load log memory overflows during the health check 2
Figure 21: Lack of response time during Health Check for LINEIQs
With the GridSense recommended Health Check interval of 24 hours, and the GridSense
recommended Log Average period of 15 minutes, a Gateway monitoring 6 LineIQ LIQ-60is
unresponsive for only 6.2 minutes each day. This represents 99.6% availability.
11.8 Real Time Clock (RTC)
The Gateway includes a battery backed real time clock (RTC).
During normal Gateway operation (when the Gateway is turned on), the RTC is powered
directly from the Gateway, and the RTC backup battery is not used.
The RTC backup battery is only used when the Gateway is switched off.
The estimated RTC backup battery life is 10 years.
The Real Time Clock is set during the manufacturing process.
The RTC backup battery is a lithium button cell, type CR2032, and is located on the
Gateway printed circuit board (PCB). Access to the PCB is obtained by removing the
access plate under the cellular modem.
Please contact GridSense if you need to reset the Real Time Clock or replace the RTC
backup battery.
In order to conserve internal memory and maximize transmission efficiency, and to maintain
compatibility with earlier Series 1 LIQ-60 and PACs, the RTC is not used directly. Instead, it
is used to set an internal counter which is then used to provide a date and time reference
for event and load log data.
Gateway Manual Sept 2015 Page 52 of 113
When event and load log data is processed by LineMan or LineMan Remote software, the
counter date/time stamp values are converted to conventional date/time stamps, using the
clock of the PC on which the software is running as a reference.
For this reason, it is important that the PC date and time be set correctly on the PC before
event and load log data is downloaded from LIQ-60 and Gateways.
11.9 Solar Panel Mounting Considerations
The solar panel supplies all the energy required to operate the Gateway, and must provide
enough energy to ensure that the internal Gateway battery pack remains charged.
The solar panel converts the energy contained in sunlight directly into electrical energy.
Correct orientation of the solar panel is important, especially at high latitudes.
The amount of energy generated depends on the following factors:
The amount of incident solar energy. This energy is provided by the sun, and varies with
the time of day, the time of year, the latitude and with the amount of cloud cover.
The angle at which the incident solar energy strikes the solar panel.
The amount of shading (by nearby structures) or obstruction (e.g. by snow or dust) of the
solar panel.
The Gateway solar panel has an adjustable mount, which allows the solar panel to be
oriented for maximum energy generation.
Since the amount of incident solar energy varies with seasons (more in summer, less in
winter) it is better to orient the solar panel to maximize the solar energy in winter rather than
in summer.
The following step by step process details how to mount the solar panel correctly:
1. Determine the direction to the equator. In the northern hemisphere this is due
south, while in the southern hemisphere it is due north. Note that you must
determine the true rather than the magnetic direction, as these vary considerably.
This direction can be determined in a number of ways:
Use an atlas, a physical map or a street directory
Use an internet based geographic information system such as Google Earth
Determine the direction to the sun at 12 noon in winter (or 1pm during
daylight saving times)
Gateway Manual Sept 2015 Page 53 of 113
Use an electronic compass such as a Global Positioning System (GPS)
receiver
Use a magnetic compass, corrected for magnetic deviation.
It is sufficient to determine the direction to the equator to within 5 degrees.
Mount the solar panel so that in plan view it points directly towards the equator
– true south in the northern hemisphere
– true north in the southern hemisphere
Figure 22 shows how the solar panel is positioned in the Northern hemisphere.
Figure 22: Solar panel facing the equator (Northern hemisphere mounting)
2. Determine the latitude. This is your position on the earth, measured in degrees.
If you are at the equator, your latitude will be 0 degrees.
If you are at the North Pole, your latitude will be 90 degrees north.
If you are at the South Pole, your latitude will be 90 degrees south.
The latitude of Sydney, NSW in Australia is approximately 35 degrees South
The latitude of Sacramento CA in the United States of America is 40 degrees
North
Gateway Manual Sept 2015 Page 54 of 113
You can determine your latitude in a number of ways:
Use an atlas, a physical map or a street directory
Use an internet based geographic information system such as Google Earth
Use an electronic positioning system such as a Global Positioning System
(GPS) receiver
It is sufficient to determine your latitude within 5 degrees.
Use the following table to determine the angle at which to mount the solar panel. The angle
specified in Figure 23 is measured from the face of the solar panel to the vertical.
Latitude
Example Location
Winter Elevation
Angle from vertical
(degrees)
Autumn/Spring
Elevation Angle
from vertical
(degrees)
Summer Elevation
Angle from vertical
(degrees)
Average Elevation
Angle from Vertical
(degrees) 90 N North Pole no sun 10 20 15
80 N no sun 15 30 23
70 N North West Passage no sun 20 40 30
60 N Kodiak, Alaska USA 10 30 50 30
50 N Vancouver, BC Canada 20 40 60 40
40 N Sacramento, CA USA 30 50 70 50
30 N Houston, Texas USA 40 60 80 60
20 N Mexico City, Mexico 50 70 90 70
10 N Nairobi, Kenya 60 80 90 77
0 Singapore 70 80 90 80
10 S Darwin NT Australia 60 80 90 77
20 S Alice Springs NT Australia 50 70 90 70
30 S Sydney, NSW Australia 40 60 80 60
40 S Hobart, TAS Australia 30 50 70 50
50 S Invercargill New Zealand 20 40 60 40
60 S Southern Ocean 10 30 50 30
70 S Mawson Base, Antarctica no sun 20 40 30
80 S no sun 15 30 23
90 S South Pole no sun 10 20 15
Figure 23: Solar panel angle measured from vertical
The rightmost column is the average of the winter. Autumn/spring and summer columns.
Use this angle if you are not going to change the angle as the seasons change.
Figure 24 shows how the solar panel angle is measured.
Gateway Manual Sept 2015 Page 55 of 113
Figure 24: Solar panel angle measured from vertical
Gateway Manual Sept 2015 Page 56 of 113
12 Maintenance
12.1 Standby battery
The Gateway includes a sealed lead acid standby battery.
The performance of the standby battery will degrade if it is exposed to long periods of high
temperature and/or it is allowed to discharge excessively.
The battery life of the Gateway can be extended by following a few simple precautions as
outlined below:
Store the Gateway at ambient temperatures below 30o C
Store the Gateway with a fully charged battery. This can be achieved by energizing
the Gateway for 24 hours before storage
Recharge the battery after every three months of storage
12.2 Calibration
The Gateway does not require calibration.
12.3 Cleaning
All equipment should be cleaned with a soft, moist cloth using only a mild detergent.
12.4 Periodic Maintenance and Testing
The Gateway and accessories should be inspected on a regular basis.
12.5 Operational Problems
If you have any questions about the operation of the Gateway or associated software
(LineMan, Lineman Remote, and LineView), first look in the relevant User Manual or consult
the on-line help files included with the software.
Gateway Manual Sept 2015 Page 57 of 113
12.6 Firmware and Software Upgrades
The Gateway is a complex instrument which utilizes embedded firmware and PC based
software (LineMan, Lineman Remote, and LineView).
GridSense occasionally releases firmware upgrades for the Gateway and new versions of
LineMan, Lineman Remote, and LineView software.
Users who have electronically registered with GridSense will be notified of firmware
upgrades and new versions of LineMan, LineMan Remote, and LineView
Updated firmware and software can be downloaded from the GridSense web site after
registering at:
http://www.gridsense.com/customer-downloads/
The customer download webpage is only accessible after customer login.
Firmware upgrades are accomplished using the Gateway Firmware Upgrade Tool.
This is a small program (Gateway_FW_Upgrade.exe) which connects to the Gateway via
either a serial port or a direct Ethernet connection.
Refer to “Appendix H – Gateway Firmware Upgrades” for detailed instructions on how to
upgrade the Gateway firmware
12.7 Repairs
The Gateway and accessories do not contain any user serviceable parts.
If the equipment is found to be faulty in any way, including blown fuses, it should be
returned to your supplier for inspection and repair.
If service is required, return the Gateway and all accessories to GridSense at the addresses
shown below.
NORTH AMERICA
GridSense Inc.
2568 Industrial Blvd, Ste. 110
West Sacramento CA 95691
USA
12.8 Customer Registration
GridSense suggest that you register as a customer on the GridSense web site:
Gateway Manual Sept 2015 Page 58 of 113
http://www.gridsense.com/gridsense-login/
Registered customers are able to download firmware and software upgrades from the
GridSense web site.
12.9 Technical Sales and Assistance
If you are experiencing any technical problems, or require any assistance with the proper
use or application of this instrument, please contact us:
NORTH AMERICA
Phone: +1 916 372 4945
Fax: +1 916 372 4948
Support: http://www.gridsense.com/product-support/
Web: http://www.gridsense.com/
Gateway Manual Sept 2015 Page 59 of 113
13 Gateway Specifications
INTERFACES
Internal Memory 512 kB non volatile
Internal Radio serial
port
RS232 via male DB9 connector
1 start bit, 8 data bits, no parity & 1 stop bit with RTS/CTS flow control
Baud rates 1200, 2400, 4800, 9600, 19200, 28800, 57600 & 115200
baud
Internal Modem serial
port
RS232 connector or PCB socket
1 start bit, 8 data bits, no parity & 1 stop bit with RTS/CTS flow control
RS232: male DB15 connector. Baud rates 1200, 2400, 4800, 9600,
14400, 19200, 28800, 33600 & 57600 baud
PCB socket: TTL logic. Baud rates 1200, 2400, 4800, 9600, 14400,
19200, 28800, 33600 & 57600 baud
External serial port
RS232 via DB9 serial data cable.
1 start bit, 8 data bits, no parity & 1 stop bit with RTS/CTS flow control
Baud rates 1200, 2400, 4800, 9600, 14400, 19200, 28800, 33600,
57600 & 115200 baud
RF Interface port Proprietary TTL level interface to RF module.
Ethernet interface
port
10/100 MHz 10-base-T
Global Positioning
System (GPS)(2)
50-channel GPS receiver with -160dBm SuperSense ® sensitivity,
active Antenna and accurate time keeping options. ® SuperSense is a
registered trademark of u-blox AG
Internal WiFi
Module(3)
IEEE 802.11 b/g (11/54MBps), Wi-Fi compliant, with support for WEP
(64 and 128 bit), and WPA (TKIP). 4MBps effective data throughput. -
71dBm to -87dBm sensitivity.
Communication
protocols DNP3 & GridSense proprietary
Gateway Manual Sept 2015 Page 60 of 113
MECHANICAL & POWER
Display Amber and Red high intensity LEDs
Power Consumption 8 mA at 12 V DC with no active communications
AC Power 55 – 600 Volts AC 50 Hz or 60 Hz
Solar Power External 12 V 10 W solar panel
DC Power 13.8 V DC rated at 1 Amp
Backup Battery 12 V 5 Ah rechargeable sealed lead acid
Real Time Clock
Battery CR2032 3V lithium
Dimensions (l x w x d) 510 mm (20 in) x 295 mm (11 5/8 in) x 160 mm (6 5/16 in) 20 in (l) x
(w) x (d)
Weight 7.6 kg (17 lbs) Gateway only, 15kg (33 lbs) typical with accessories in
shipping case
ENVIRONMENTAL & SAFETY
Temperature -20°C to +60°C (-4°F to +130°F)
Humidity 20% to 99% RH
Protection Class AS 60529-2004 - IP65
ABSOLUTE MAXIMUM RATINGS
Supply Voltage 600 Volts
DC Power 14 Volts
Solar Panel Voltage 30 Volts
Gateway Manual Sept 2015 Page 61 of 113
14 Accessory Specifications
14.1 10 W External Solar Panel
SPECIFICATIONS
Nominal Rating 10 W at 12 VDC
Open Circuit Voltage 21 V
Short Circuit Current 700 mA
Nominal output 16.8 V
Nominal output 600 mA
Rated output 10 W at 800 W/m2 and 47 oC
Dimensions (l x w x 421 mm (16 9/16 ins) x 269 mm (10 9/16 in) x 23 mm (7/8 in)
Weight 2 kg
Gateway Manual Sept 2015 Page 62 of 113
APPENDIX A – LINEMAN
A1 Installing LineMan To install LineMan software, insert the CD supplied with the Gateway into a CD drive.
If the installer does not start automatically, browse to the LineIQ directory on the CD and
run the LineMan setup program.
Follow the on screen instructions to install LineMan software.
A2 Starting LineMan Start LineMan by double clicking on the desktop icon, or selecting it from the Start Menu.
Start/Programs/GridSense/LineIQ/LineMan/LineMan.exe
The splash screen shown will appear for 1 second.
The LineMan opening screen will then appear as shown below:
Figure 25: LineMan Opening Screen
In the pull down box in the Lineman connection screen, select the appropriate
Communications Port and then click on the “Connect to LineIQ” button.
Gateway Manual Sept 2015 Page 63 of 113
Figure 26: LineMan Connection Screen
If this screen is not shown, the communications port can be selected using the pull down
menu on the right hand end of the menu bar, as shown below:
Figure 27: Selecting the Communications Port from the pull down menu
Once the correct communications port is selected use the File/Start command to initiate
communications.
LineMan will then scan for all available devices. The Gateway will appear, along with any
other nearby devices, in the device list.
Select the Gateway in the device list.
The following commands can then be used:
Status - provides details of the battery voltage, battery drain current,
charging voltage, charging current and internal temperature.
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Summary – provides details of serial number, firmware version, hardware
revision and other parameters.
Configure – allows the Gateway to be configured.
Data Download – allows data to be downloaded. This command is normally
used only with conductor mounted sensors (CMS).
Commission – allows the Gateway to be commissioned. This should only be
done after the entire site (Gateway and LineIQs) have been correctly
configured.
Restart – performs a warm restart (reboot) of the Gateway microprocessor,
and is equivalent to switching the power off then on again.
Gateway Manual Sept 2015 Page 65 of 113
APPENDIX B – LINEMAN REMOTE LineMan Remote allows remote connection to a Gateway.
In order for LineMan Remote to initiate communications with a Gateway, the Gateway must
be powered externally. This can be achieved by one of the following methods:
An external solar panel with sufficient capacity to power the Gateway and
associated modem at all times.
An external AC power supply.
In order to allow LineMan Remote to connect to a Gateway, the Gateway must be fitted
with a suitable remote communication interface.
This interface can be one of the following:
A modem connected to a standard PSTN telephone line.
A cellular modem.
A working internet connection.
Using LineMan Remote, two main functions can be performed:
Log and event data can be downloaded.
Gateway status and line current (along with line temperature if LIQ-
60devices are installed) can be monitored.
Gateway Manual Sept 2015 Page 66 of 113
Figure 28: LineMan Remote Connection Screen
For further information on using LineMan Remote, refer to the LineMan Remote User
Manual.
Gateway Manual Sept 2015 Page 67 of 113
APPENDIX C – INTERNAL ETHERNET MODULE
C1 Introduction The Internal Ethernet Module consists of a small printed circuit board (PCB) which is
mounted into J3 on the main Gateway PCB.
The RJ45 internal loom which is required to connect the Ethernet Module to the Data
connector on the front panel is already installed in all Gateways.
An external cable with an RJ45 connector is provided with the Internal Ethernet Module to
allow connection to a standard 10BaseT Ethernet system.
Figure 29: Internal Ethernet module kit
Figure 30: Internal Ethernet module
Gateway Manual Sept 2015 Page 68 of 113
C2 Installation To install the internal Ethernet Module, you will need a large flat bladed screwdriver and a
small pair of side cutters.
a) Open the front cover of the Gateway.
Figure 31: Gateway with cover opened
Note that the Gateway may not look exactly the same as shown in Figure 31, as it may
have cellular and radio modems installed.
b) Remove the Main Shield Cover by undoing the two captive screws at the
bottom of the cover.
The Internal Ethernet Module is supplied in an antistatic bag. Do not remove the module from the
antistatic bag until you are ready to install it. Appropriate antistatic measures should be used during
installation.
Gateway Manual Sept 2015 Page 69 of 113
Figure 32: Gateway with main shield cover removed
The RJ45 internal wires can be seen at the bottom left hand corner of Figure 32.
c) Locate S3, which is the center pair of white single in line (SIL) 8 pin female
connectors.
Figure 33: Centre pair of SIL 8 pin female connectors (at bottom)
d) Insert the Internal Ethernet Module into S3. Ensure that the correct
orientation is used. The RJ45 connector must be on the right.
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Figure 34: S3 connector (bottom pair of SIL female connectors)
e) Remove the cable tie holding the RJ45 wiring loom on the left of the
Gateway. This is shown in Figure 32.
f) Route the RJ45 wiring loom underneath the two antenna cables, and
connect it to the Internal Ethernet Module.
g) Make sure that the Internal Ethernet Module is securely and fully located
onto J3.
h) Replace the Main Shield Cover, making sure that all cables are routed
through the appropriate glands and are not pinched by the cover in any way.
i) If necessary, secure any loose cables to the wiring loom on the left hand
side of the Gateway with cable ties.
Gateway Manual Sept 2015 Page 71 of 113
Figure 35: Internal RJ45 connector inserted into internal Ethernet module
Figure 36: Internal RJ45 connector inserted into internal module (main shield cover replaced)
j) If necessary, secure any loose cables to the wiring loom on the left
hand side of the Gateway with cable ties.
k) Close the front cover of the Gateway.
l) Unscrew the sealing cap and connect the external Ethernet cable
to the data connector on the front panel of the Gateway.
Gateway Manual Sept 2015 Page 72 of 113
Figure 37: External RJ45 cable connected to Data Connector
If the external Ethernet cable is ever removed, the sealing cap must be replaced to prevent
corrosion of the Data connector.
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APPENDIX D - DNP3 COMMUNICATIONS
D1 Introduction Critical fault data as well as load logging data and device status information is available
through the versatile industry standard DNP3 interface.
The interface is highly configurable and should be set up to best fit your application. The
purpose of this appendix is to explain how to achieve this using LineMan software. If you
are not familiar with LineMan, consult the LineMan User Manual.
The DNP3 interface can be configured to provide both solicited and unsolicited
communications. Event and load log data, as well as status information can be accessed
via the DNP3 interface.
D2 Locating the DNP3 Interface Settings Referring to “Error! Reference source not found.” below, select the Gateway in the
LineIQ ID List window (1), then access the device configuration settings by pressing the
Device Config button (2).
Gateway Manual Sept 2015 Page 74 of 113
Figure 38: LineMan main screen
This will open the Sensor Configuration pane, shown on the right in Figure 38.
D3 Selecting the Health Check Interval Historical data, such as load logging information, is accumulated first in the conductor
mounted sensors and only transferred to the Gateway during the periodic ‘Health Check
(3)’. Therefore such data only becomes available to the external DNP3 master device after
each health check.
The health check interval should therefore be chosen with consideration to how time-
critical the historical information is to the external system.
Gateway Manual Sept 2015 Page 75 of 113
When choosing the health check interval the longest acceptable interval should be chosen
to limit battery drain on the LineIQs due to the power required for the short range RF
communications between the Gateway and the LineIQs during health checks.
Typically 2 hours is considered the absolute shortest acceptable health check interva l .
D4 Changing the DNP3 Interface Settings
The DNP3 interface settings are located under the Interface Control settings, which are
accessed by pressing the Communication Settings w indo w.
This will open Figure 39 as shown below.
Figure 39: IFC setting window
10
Gateway Manual Sept 2015 Page 76 of 113
D5 Selecting and configuring the DNP3 RS232 Port This will be either the internal RS232 port intended for connection to utility radios, or the
external RS232 data port.
In area 7 above, select the desired baud rate on the appropriate port using the drop-down
menu, and select whether to implement RTS/CTS hardware flow control on the selected
port.
D6 Permanently powering the radio modem In area 8 above, if you are using the internal RS232 port and utility radio, ensure that the
radio is permanently powered on (box ticked).
D7 Setting DNP3 Protocol Parameters In the lower right of Figure 39, the following options are available:
DNP3 Unsolicited Reporting
Otherwise known as ‘Report by Exception’, this setting determines whether the Gateway
can be configured to send unsolicited reports. Note that in accordance with the DNP3
standard, all classes of unsolicited data are disabled by default and must be enabled as
required by the master device via the Enable/Disable unsolicited reporting commands. The
Gateway will send an unsolicited Null Response on start up to indicate device restart .
Things to Note:
Unsolicited data can only be enabled or disabled by class. See the GatewayDNP3
points-list in Appendix E to determine the class of each data point.
The Gateway is a DNP3 Level 1 device and does not support dynamic class
assignments.
When unsolicited reporting is enabled another selection becomes available in the
IFC Settings to configure the hardware port to which unsolicited reports are sent.
When using unsolicited reporting it is critical to configure the Link Destination
Address to that of the attached DNP3 master device.
Modem and Ethernet support are under development. Contact GridSense for further
details.
GridSense Recommended Setting: Where the master station supports unsolicited
messages from outstations, it is recommended that this feature is enabled, to
p r o v i d e
Gateway Manual Sept 2015 Page 77 of 113
Immediate notification of new data. This will eliminate communications channel congestion
due to polling. DNP3 Static Polling (see next bullet-point) can allow for infrequent polling of
instantaneous line parameters.
DNP3 Static Polling (Do RF Status Command)
This checkbox determines the Gateway behavior when it receives a request for the value of
static data points from the DNP3 master. Since the Gateway is physically isolated from the
LineIQ devices it is monitoring, to determine the instantaneous status of a device (such as
the instantaneous line current) it must send out a request over the local RF communications.
The low-power nature of the LineIQ devices requires that this RF command be used
sparingly. It may be difficult or undesirable to re-configure the DNP3 master to only poll
these points rarely, so this checkbox is provided to enable or suppress the RF command
when a poll request is received from the DNP3 master.
To leave this box Unchecked is to configure the Gateway to return the last known value
when these static points are requested. This value will have been retrieved during the last
‘Health Check’, which occurs at a configurable interval (see more details of health check
intervals below).
Things to Note:
DNP3 requests which trigger RF commands will not receive a response from the
Gateway until after the RF communications are complete. This may take several
minutes depending on the number of LineIQs assigned to the Gateway.
GridSense Recommended Setting: When using a polling method to retrieve data from the
outstation, this checkbox should be left unchecked. Where unsolicited reporting (report by
exception) is used to retrieve outstation data, this box should be checked to allow
instantaneous line parameters to be read when desired.
DNP3 Waveform Support
Fault current and voltage waveforms are available to be retrieved through the DNP3
interface as data object 111 (Octet String Event).
Since each waveform consists of 249 Bytes and this data object 111 is not supported by
some DNP3 masters, the option is provided here to choose whether or not waveform data
is generated.
Gateway Manual Sept 2015 Page 78 of 113
Things to Note:
Waveform data is a separate DNP3 class to the fault summary data. This allows
the DNP3 master to enable unsolicited reporting of summary data but not
waveform data, and the waveform can be retrieved if desired.
One voltage and one current waveform is stored for each LineIQ event. When
the Gateway internal memory fills up, the oldest (earliest) waveforms will be
overwritten.
When the waveform data is extracted, the extracted waveforms are cleared from
the Gateway memory.
GridSense Recommended Setting: This box should only be checked if the user expects
to use waveform data to analyze fault information. If such data is not desired the box
should be left unchecked to limit the amount of data transferred over the communications
channel.
Clock Validation Period
This is the time period in minutes between which the Gateway will set the Time
Synchronization Required IIN bit in the DNP3 application layer frame. The master should
send a time synchronization message.
Things to Note:
Setting this parameter to 0 disables periodic time synchronization requests. The
IIN bit will only be set on restart.
GridSense Recommended Setting: This parameter should be set for daily time
synchronization (every 86400 seconds) if the master station has access to an accurate time
source and the latency of the communications channel is small. In other cases the value
should be set to 0 to prevent periodic time synchronization r e q u e s t s .
Unsolicited Max Short Retries
Determines the number of times the Gateway will attempt to send unsolicited messages at
the configurable short retry interval if the master does not acknowledge the message.
Once this number of retries has expired, the Gateway will send retries indefinitely at the
configurable long retry interval.
Gateway Manual Sept 2015 Page 79 of 113
GridSense Recommended Setting: This parameter, combined with the unsolicited short
retry delay, should be set such that the Gateway will always attempt to resend unsolicited
messages for longer than the time a master station might be expected to be unresponsive
doing other tasks. Should a master station never be expected to be unresponsive, then a
default of 3 short retries should be applied.
Link Source Address
The address of the Gateway at the DNP3 Link Layer. The Gateway will only respond to
requests sent to this address.
GridSense Recommended Setting: This parameter is entirely dependent on the
requirements that the master station places on the addresses of outstations.
Link Destination Address
The DNP3 Link Layer address to which the Gateway will send all unsolicited messages.
Things to Note:
This address is for unsolicited messages only, the Gateway will respond to any
requests with the GatewayDNP3 address in the destination field.
Responses will be addressed to the sender of the request, even if that differs
from the address configured here.
GridSense Recommended Setting: Good design practice is to set, this parameter to the
address of the master station even if unsolicited reporting is not being us ed .
App. Confirmation Timeout
The time in seconds to wait for the master to confirm a DNP3 application layer message.
Once this time elapses, the Gateway considers the message lost and aborts sending any
remaining fragments and starts the retry timer (if the message is unsolicited).
GridSense Recommended Setting: This parameter should be set to at least quadruple the
maximum expected one-way latency of the communications channel or double the
maximum expected time the master station will be unresponsive handling other tasks
(whichever is longer). If neither of these parameters is known, a default value of 30 seconds
should be adequate for the majority of installations.
Gateway Manual Sept 2015 Page 80 of 113
Unsolicited Short Retry Delay
The time in seconds to wait before resending an unsolicited message that was not
confirmed by the master.
The number of retries sent at this interval is configurable.
Things to Note:
This delay begins at the end of the configurable application layer confirmation
timeout.
GridSense Recommended Setting: This parameter, combined with the max. number of
unsolicited short retries, should be set such that the Gateway will always attempt to resend
unsolicited messages for longer than the time a master station might be expected to be
unresponsive doing other tasks. Should a master station never be expected to be
unresponsive, then a default of 30 seconds should be applied.
Unsolicited Long Retry Delay
The time in seconds to wait before resending an unsolicited message after the configurable
number of short retry attempts has been exhausted.
The Gateway will continue to send the message at this interval indefinitely until
acknowledged by the master.
GridSense Recommended Setting: Unsolicited long retries are a fallback if the master
station has failed to respond to short retries for longer than should ever be expected under
normal circumstances. This would usually be as a result of a failure of the communications
channel or a serious problem with the DNP3 master station. In this case a recommended
retry of every hour (3600 seconds) should allow for prompt recovery once the
communications channel or master station is restored.
Gateway Manual Sept 2015 Page 81 of 113
D8 Other Pertinent Parameters
Maximum Supported Fragment Sizes
DNP3 Link Layer Tx Frame 146 Bytes
DNP3 Application Layer Tx Fragment 300 Bytes
DNP3 Application Layer Rx Fragment 512 Bytes
DNP3 Commands During Health Check or Event Data Download
When the Gateway is occupied conducting a health check on the LineIQs or retrieving
event data, it will not respond to DNP3 requests.
If the time from receiving the request until the Gateway becomes idle exceeds 32 seconds,
the Gateway will consider the request expired and discard it without r e s p o n s e .
D9 Checklist for Configuring the Interface
1. Enable the DNP3 protocol handler by ensuring the Enable DNP3 checkbox is
checked.
2. Configure the hardware interface (7).
3. If an internal radio is being powered from the Gateway internal dedicated radio
power, ensure the checkbox Permanently Power Radio (8) is selected.
4. Configure the protocol parameters (9). These are each described earlier in this
document.
5. Close the IFC Settings dialog (10) and apply the configuration.
6. Configuration changes are not saved until the Apply Configuration button (4) is
pressed.
7. Commission the Gateway, by pressing the Commission (Remote) button (5). The
Gateway needs information it retrieves during the commissioning process to
properly respond to DNP3 requests. As a result, the protocol handler is not started
until after commissioning, even if the Enable DNP3 setting has been applied.
Gateway Manual Sept 2015 Page 82 of 113
APPENDIX E – RECOMMENDED DNP3 POINTS USAGE
Obj Var Description Obj Var Class Description
0 000 30 2Analog Input -- 16-bit
with flagBattery Voltage -- PAC
Static Variation Recommended for
DataPAC battery health check. divided by 100
Obj Var Description Obj Var Class Description
1 001 30 2Analog Input -- 16-bit
with flag
Instantaneous* Battery Voltage --
CMS G1P1
Recommended for battery health
check.divided by 100
2 002 30 2Analog Input -- 16-bit
with flag
Instantaneous* Line Voltage Indication -
- CMS G1P1
Static Variation Optional - Can be
polled infrequently for real time
indication of line voltage
times 100
3 003 30 2Analog Input -- 16-bit
with flag32 4 1
Analog Input Event -- 16-
bit with time
Most Recent Trigger Current / Event
Trigger Current -- CMS G1P1
Event Variation Recommended for
fault current magnitude.divided by 10
4 004 30 2Analog Input -- 16-bit
with flag32 4 1
Analog Input Event -- 16-
bit with time
Most Recent Pre-Trigger Current / Pre-
Trigger Current --CMS G1P1
Event Variation Recommended for
pre-event line current informationdivided by 10
5 005 30 2Analog Input -- 16-bit
with flag32 4 1
Analog Input Event -- 16-
bit with time
Most Recent Pre-Trigger Current / Pre-
Trigger Current --CMS G1P1
Event Variation Recommended for
post-event line current informationdivided by 10
6 006 30 2Analog Input -- 16-bit
with flag32 4 2
Analog Input Event -- 16-
bit with time
Instantaneous* Current / Load Log
Current -- CMS G1P1
Static Variation Optional Can be
polled infrequently for instantaneous
load readings / Event Variation
Recommended for long term load
trend study.
divided by 10
7 007 30 2Analog Input -- 16-bit
with flagLineFrequency -- CMS G1P1
Static Variation Optional - Can be
polled infrequently for line frequency
readings. LineTracker support
dependent
divided by 10
8 008 30 2Analog Input -- 16-bit
with flag
32 4 3
Analog Input Event -- 16-
bit with time
Displacement Power Factor
(Instantaneous* / Historical) -- CMS
G1P1
Static Variation Optional - Can be
polled infrequently for taking
instantaneous power factor
readings.
Event Variation Recommended for
long term historical power factor
study. LineTracker support
dependent
divided by 1000
9 009 30 2Analog Input -- 16-bit
with flag
32 4 3
Analog Input Event -- 16-
bit with time
Phase Angle (Instantaneous* /
Historical) -- CMS G1P1
Static Variation Optional - Can be
polled infrequently for taking
instantaneous phase angle
readings.
Event Variation Recommended for
long term historical phase angle
study.LineTracker support
dependent
divided by 10
10 00A 30 2Analog Input -- 16-bit
with flag
32 4 2
Analog Input Event -- 16-
bit with time
Ambient Temperature (Instantaneous*
/ Historical) -- CMS G1P1
Static Variation Optional - Can be
polled infrequently for taking
instantaneous ambient temperature
readings.
Event Variation Recommended for
long term historical ambient
temperature study.LineTracker
support dependent
divided by 100
11 00B 30 2Analog Input -- 16-bit
with flag
32 4 2
Analog Input Event -- 16-
bit with time
Conductor Temperature
(Instantaneous* / Historical) -- CMS
G1P1
Static Variation Optional - Can be
polled infrequently for taking
instantaneous conductor
temperature readings.
Event Variation Recommended for
long term historical conductor
temperature study. LineTracker
support dependent
divided by 100
Obj Var Description Obj Var Class Description
0 001 1 2Binary Input -- With
Flags2 2 1
Binary Input Event -- With
absolute time
Most recent event type SI (Short
Interruption) / Event Type - SI -- CMS
G1P1
Event Variation Recommended for
line event classification.not applicable
1 001 1 2Binary Input -- With
Flags2 2 1
Binary Input Event -- With
absolute time
Most recent event type LI (Long
Interruption) / Event Type - LI -- CMS
G1P1
Event Variation Recommended for
line event classification.not applicable
2 002 1 2Binary Input -- With
Flags2 2 1
Binary Input Event -- With
absolute time
Most recent event type FP (on the
Fault Path) / Event Type - FP -- CMS
G1P1
Event Variation Recommended for
line event classification.not applicable
3 003 1 2Binary Input -- With
Flags2 2 1
Binary Input Event -- With
absolute time
Most recent event type PR (Power
Return) / Event Type - PR -- CMS
G1P1
Event Variation Recommended for
line event classification.not applicable
4 004 1 2Binary Input -- With
Flags2 2 1
Binary Input Event -- With
absolute time
Most recent event type Pre-Trigger
Power Status / Event Type - Pre-
Trigger Power Status -- CMS G1P1
Event Variation Recommended for
line event classification.not applicable
5 005 1 2Binary Input -- With
Flags2 2 1
Binary Input Event -- With
absolute time
Most recent event type Post-Trigger
Power Status / Event Type - Post-
Trigger Power Status -- CMS G1P1
Event Variation Recommended for
line event classification.not applicable
* Note: If RF Comms are disabled (default setting) during DNP3 polling, then the returned analog reading was taken at the time of the preceeding DataPAC health check.
If RF Comms are enabled during DNP3 polling, then the returned analog reading is a "real time" value read from the CMS at the time of DNP3 polling.
Point Name
Event Variation
Point
Index
(Dec)
Note
Static Variation Event Variation
Point
Index
(Dec)
Analog points usage recommendations - LineTracker points (block is repeated for each assigned LineTracker)
Static Variation
Point
Index
(Hex)
Point Name
Static Variation / Event Variation
Point Name
Static Variation / Event VariationNote
Point
Index
(Hex)
Analog points usage recommendations - DataPAC points
Scaling
Scaling
Binary Points Usage Recommendations (block is repeated for each assigned LineTracker)
Point
Index
(Dec)
Point
Index
(Hex)
Static Variation Event Variation
Note
Scaling
Gateway Manual Sept 2015 Page 83 of 113
APPENDIX F – DNP3 DEVICE PROFILE
F1 Device Identification
DEVICE
IDENTIFICATION Capabilities Current Value
If configurable,
list methods
Device Function: Master
Outstation
Master
Outstation
Vendor Name CHK GridSense
Device Name Gateway Device manufacturer’s
hardware version
string:
Device manufacturer’s
software version
string:
Device Profile Document
Version
Number:
0.1.3
DNP Levels Supported for: Outstations Only:
None
Level 1
Level 2
Level 3
Level 4
None
Level 1
Level 2
Level 3
Level 4
Supported Function Blocks: Self-Address Reservation
Object 0 – attribute objects
Data Sets
File Transfer
Virtual Terminal
Mapping to IEC 61850 Object
Models defined in a DNP3 XML
file
Function code 31, activate
configuration
Self-Address Reservation
Object 0 – attribute objects
Data Sets
File Transfer
Virtual Terminal
Gateway Manual Sept 2015 Page 84 of 113
DEVICE IDENTIFICATION
Capabilities
Current Value
If configurable,
list methods
Notable Additions:
A brief description intended to
quickly identify for the reader the
most obvious features the
device supports in addition to
the Highest DNP Level
Supported. The complete list of
features is described in the
Implementation Table.
· Binary input - All Variations :
Read all points
· Analog input - All Variations :
Read all points
Methods to set Configurable
Parameters:
XML – Loaded via DNP3 File
Transfer
XML – Loaded via other
transport mechanism
Terminal – ASCII Terminal
Command Line
Software – Vendor software
named
Proprietary file loaded via
DNP3 file transfer
Proprietary file loaded via other
transport mechanism
Direct – Keypad on device front
panel
Factory – Specified when
device is ordered
Protocol – Set via DNP3 (e.g.
assign class)
Other – explain
Software – Vendor software
named: Line Man
Connections Supported: Serial (complete section
1.2)
IP Networking (complete
section 1.3)
Other, explain
Serial (complete section
1.2)
IP Networking (complete
section 1.3)
Other, explain
SERIAL CONNECTIONS Capabilities Current Value If configurable,
list methods
Gateway Manual Sept 2015 Page 85 of 113
Port Name
Name used to reference the
communication port defined
in this section.
Electrical Interface: RS232, GSM
or GPRS, CDMA or CDMA1x.
Type of connector: 9 pin SUB-D,
male
Serial Connection
Parameters:
Asynchronous - 8 Data Bits, 1
Start Bit, 1 Stop Bit, No Parity
Other, explain
Asynchronous - 8 Data Bits, 1
Start Bit, 1 Stop Bit, No Parity
Other, explain
Baud Rate: Fixed at
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Fixed at
Configurable, range to
Configurable, selectable from
1200, 2400, 4800 , 9600, 14400,
19200, 28800,33600, 57600 ,
115200,
Configurable, other,
describe
Configuration is
done by vendor
provided LineMan
software.
Hardware Flow Control
(Handshaking):
Describe hardware
signaling requirements of
the interface.
Where a transmitter or
receiver is inhibited until a
given control signal is
asserted, it is considered
to require that signal prior
to sending or receiving
characters.
Where a signal is asserted
prior to transmitting, that
signal will be maintained
active until after the end of
transmission.
Where a signal is asserted
to enable reception, any
data sent to the device
when the signal is not
active could be discarded.
None
RS-232 / V.24 / V.28 Options:
Before Tx, Asserts:
RTS
DTR
Before Rx, Asserts:
RTS
DTR
Always Asserts:
RTS
DTR
Before Tx, Requires: Asserted
De-asserted
CTS
DCD
DSR
RI
Rx Inactive
Before Rx, Requires: Asserted
Disserted
CTS
DCD
DSR
RS-232 / V.24 / V.28 Options:
Before Tx, Asserts:
RTS
DTR
Before Rx, Asserts:
RTS
DTR
Always Asserts:
RTS
DTR
Before Tx, Requires: Asserted
De-asserted
CTS
DCD
DSR
RI
Rx Inactive
Before Rx, Requires: Asserted
Disserted
CTS
DCD
DSR
Configurable by
vendor provided
software –
LineMan.
Gateway Manual Sept 2015 Page 86 of 113
RI
Always Ignores:
CTS
DCD
DSR
RI
Other, explain
RS-422 / V.11 Options:
Requires Indication before
Rx
Asserts Control before Tx
Other, explain
RS-485 Options:
Requires Rx inactive
before Tx
Other, explain
RI
Always Ignores:
CTS
DCD
DSR
RI
Other, explain enable or
disable Hardware Flow Control
is configurable.
Gateway Manual Sept 2015 Page 87 of 113
F2 Link Layer
LINK LAYER Capabilities Current Value If configurable,
list methods
Maximum number of octets
Transmitted in a Data Link Frame:
This number includes the CRCs. With
a length field of 255, the maximum
size would be 292.
Fixed at
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Fixed at
146_
Maximum number of octets that
can be Received in a Data Link
Frame:
This number includes the CRCs. With
a length field of 255, the maximum
size would be 292. The device must
be able to receive 292 octets to be
compliant.
Fixed at
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Fixed at
146_
Maximum Data Link Retries:
The number of times the device will
retransmit a frame that requests Link
Layer confirmation.
Never Retries
Fixed at
Configurable, range to
Configurable, selectable from
, ,_ Configurable,
other, describe
Fixed at 3.
Sends Confirmed User Data
Frames:
A list of conditions under which the
device transmits confirmed link layer
services (TEST_LINK_STATES,
RESET_LINK_STATES,
CONFIRMED_USER_DATA).
Always
Sometimes, explain
Never
Never
Data Link Layer Confirmation
Timeout:
This timeout applies to any
secondary data link message that
requires a confirm or response (link
reset, link status, user data, etc.)
None
Fixed at_ ms
Configurable, range to
ms
Configurable, selectable from
, , ms
Configurable, other,
describe
Variable, explain
None
Gateway Manual Sept 2015 Page 88 of 113
F3 Application Layer
APPLICATION
LAYER Capabilities Current Value
If configurable,
list methods
Maximum number of
octets Transmitted in an
Application Layer
Fragment other than File
Transfer:
This size does not include
any transport or frame
octets.
• Masters must provide a
setting less than or equal
to 249.
• Outstations must provide
a setting less than or equal
to 2048. .
Fixed at
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Fixed at _512
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Maximum number of
octets Transmitted in an
Application Layer
Fragment containing File
Transfer:
Fixed at
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Maximum number of
octets that can be
Received in an
Application Layer
Fragment:
This size does not include
any transport or frame
octets.
• Masters must provide a
setting greater than or
equal to 2048.
• Outstations must provide
a setting greater than or
equal to 249.
Fixed at
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Fixed at 512
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Gateway Manual Sept 2015 Page 89 of 113
APPLICATION
LAYER
Capabilities
Current Value
If configurable,
list methods
Maximum Application
Layer Retries for
Request Messages:
The number of times a
Master will retransmit an
application layer request
message if a response is
not received. This
parameter must never
cause a Master to
retransmit control or time
sync messages.
Outstations should never
transmit retries.
None (required)
Fixed at_
Configurable, range to
Configurable, selectable from , ,
Configurable, other,
describe
Variable, explain
None (required)
Fixed at_
Configurable, range to
Configurable, selectable from
, ,
Configurable, other,
describe
Variable, explain
Timeout waiting for
Complete Application
Layer Fragment:
Timeout if all frames of a
message fragment are not
received in the specified
time. Measured from time
first frame of a fragment is
received until the last
frame is received.
None
Fixed at_ ms
Configurable, range to
ms
Configurable, selectable from , , ms
Configurable, other,
describe
Variable, explain
Configurable, range 0 to
65535 seconds
LineMan
Maximum number of
objects allowed in a
single control request
for Analog Outputs
(group 41):
Fixed at (enter 0 if
controls are not supported)
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Variable, explain
Gateway Manual Sept 2015 Page 90 of 113
F4 Fill Out the Following Items for Outstations Only
FILL OUT THE
FOLLOWING ITEMS
FOR OUTSTATIONS
ONLY
Capabilities
Current Value
If configurable,
list methods
Timeout waiting for
Application Confirm of
solicited response
message:
None
Fixed at_ ms
Configurable, range to ms
Configurable, selectable from , , ms
Configurable, other,
describe
Variable, explain
Configurable,
range 0_ to
_65535_ s
LineMan
How often is time
synchronization
required from the
master?
Never needs time
Within seconds after IIN1.4 is set
Periodically every seconds
Periodically every
86400 seconds
Device Trouble Bit
IIN1.6:
If IIN1.6 device trouble bit
is set under certain
conditions, explain the
possible causes.
Never used
Reason for
setting
Reason for setting:
Device not configured
properly.
Event Buffer Overflow
Behaviour:
Discard the oldest event
Discard the newest event
Other, explain
Discard the oldest
event
Event Buffer
Organization:
Explain how event buffers
are arranged (per Object
Group, per Class, single
buffer, etc,) and provide
their sizes
Gateway Manual Sept 2015 Page 91 of 113
Sends Multi-Fragment
Responses:
Indicates whether an
Outstation sends multi-
fragment responses
(Masters do not send
multi-fragment requests).
Ye
s
No
Yes
No
FILL OUT THE
FOLLOWING ITEMS
FOR OUTSTATIONS
Capabilities
Current Value
If configurable,
list methods
ONLY
DNP Command Settings Assign Class preserved through a
device reset: Analog Deadbands
If data associated with Data Set Prototypes
any of these requests are Data Set Descriptors
written through the DNP
protocol but not Function Code 31 Activate Configuration
preserved through a restart of the Outstation, the Master will have to write them again anytime the Restart IIN bit is set
Gateway Manual Sept 2015 Page 92 of 113
F5 Outstation Unsolicited Response Support
OUTSTATION UNSOLICITED
RESPONSE SUPPORT
Capabilities
Current Value
If configurable, list
methods
Supports Unsolicited Reporting:
When the unsolicited response mode
is configured “off”, the device is to
behave exactly like an equivalent
device that has no support for
unsolicited responses. If set to On, the
Outstation will send a null Unsolicited
Response after it restarts, then wait
for an Enable Unsolicited Response
command from the master before
sending additional Unsolicited
Responses containing event data.
Not Supported
Configurable, selectable from
On and Off
Not Supported
Configurable, selectable
from On and Off
Configurable via
SCADA master
Master Data Link Address:
The destination address of the master
device where the unsolicited
responses will be sent.
Fixed at_
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Configurable, range
0 to 65535_
LineMan
Unsolicited Response Confirmation
Timeout:
This is the amount of time that the
outstation will wait for an Application
Layer confirmation back from the
master indicating that the master
received the unsolicited response
message. As a minimum, the range of
configurable values must include
times from one second to one minute.
This parameter may be the same one
that is used for normal, solicited,
application confirmation timeouts, or it
may be a separate parameter.
Fixed at_ ms
Configurable, range to
ms
Configurable, selectable from
, , ms
Configurable, other,
describe
Variable, explain
Configurable, range
0 to 65535_s
LineMan
OUTSTATION UNSOLICITED
RESPONSE SUPPORT
Capabilities
Current Value
If configurable, list
methods
Number of Unsolicited Retries:
This is the number of retries that an
outstation transmits in each
unsolicited response series if it does
not receive confirmation back from the
master. The configured value includes
identical and regenerated retry
messages. One of the choices must
provide for an indefinite (and
potentially infinite) number of
transmissions.
None
Fixed at
Configurable, range
to
Configurable, selectable from
, ,_
Configurable, other,
describe
Always infinite, never gives up
Always infinite, never
gives up
Gateway Manual Sept 2015 Page 93 of 113
F6 Outstation Unsolicited Response Trigger Conditions
OUTSTATION
UNSOLICITED RESPONSE
TRIGGER CONDITIONS
Capabilities
Current Value
If configurable,
list methods
Number of class 1 events: Class 1 not used to trigger Unsolicited
Responses
Fixed at
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Fixed at 1
Number of class 2 events: Class 2 not used to trigger Unsolicited
Responses
Fixed at
Configurable, range to
Configurable, selectable from
, ,_
Configurable, other,
describe
Fixed at 1
Hold time after class 1
event:
A configured value of 0
indicates that responses are
not delayed due to this
parameter.
Class 1 not used to trigger Unsolicited
Responses
Fixed at ms
Configurable, range to
ms
Configurable, selectable from
, ,_ ms
Configurable, other,
describe
Fixed at 0
ms
Hold time after class 2
event:
A configured value of 0
indicates that responses are
not delayed due to this
parameter.
Class 2 not used to trigger Unsolicited
Responses
Fixed at ms
Configurable, range to
ms
Configurable, selectable from
, ,_ ms
Configurable, other,
describe
Fixed at 0
ms
Gateway Manual Sept 2015 Page 94 of 113
OUTSTATION
UNSOLICITED RESPONSE
TRIGGER CONDITIONS
Capabilities
Current Value
If configurable,
list methods
Hold time after event
assigned to any class:
A configured value of 0
indicates that responses are
not delayed due to this
parameter.
Class events not used to trigger
Unsolicited Responses
Fixed at ms
Configurable, range to
ms
Configurable, selectable from
, ,_ ms
Configurable, other,
describe
Fixed at 0
ms
Retrigger Hold Timer:
The hold-time timer may be
retriggered for each new
event detected (increased
possibly of capturing all the
changes in a single response)
or not retriggered (giving the
master a guaranteed update
time).
Hold-time timer will be retriggered for
each new event detected (may get more
changes in next response)
Hold-time timer will not be retriggered
for each new event detected (guaranteed
update time)
Hold-time timer will be
retriggered for each new
event detected (may get
more changes in next
response)
Other Unsolicited Response
Trigger Conditions:
There are two conditions that will trigger
unsolicited response.
1. Periodic Load Log
measurement timer.
(configurable through vendor
software—LineMan.)
2. Events occurred on high
voltage power line. (such as
high current, power OFF, power
return etc.)
Gateway Manual Sept 2015 Page 95 of 113
F7 Outstation Performance
OUTSTATION
PERFORMANCE
Capabilities
Current Value
If configurable,
list methods
When does outstation set
IIN1.4?
Never
Asserted at startup until first Time
Synchronization request received
Periodically, range to
seconds
Periodically, selectable from
, ,_ seconds
Range _to seconds after
last time sync
Selectable
from , _, seconds after last
time sync
When time error may have drifted
by range _to ms
When time error may have drifted
by selectable from , ,
Asserted at startup until
first Time Synchronization
request received
Range _0_ to__65535
minutes after last time sync
Maximum Response time
(ms):
The amount of time an
Outstation will take to respond
upon receipt of a valid
request. This does not include
the message transmission
time.
Maximum time from start-up
to IIN 1.4 assertion (ms):
F8 Individual Field Outstation Parameters
INDIVIDUAL FIELD OUTSTATION
PARAMETERS
Value of Current Setting
If configurable, list methods
User-assigned location name or code string
(same as g0v245):
Configurable Through CHK GSN
LineMan.
Device Serial Number string (same as
g0v248):
Configured At Manufacture
Device Firmware Version (same as g0v242): Configured At Manufacture
Device Hardware Version (same as g0v243): Configured At Manufacture
Gateway Manual Sept 2015 Page 96 of 113
F9 Implementation Table
The following implementation table identifies which object groups and variations, function
codes and qualifiers the device supports in both requests and responses. The Request
columns identify all requests that may be sent by a Master, or all requests that must be
parsed by an Outstation. The Response columns identify all responses that must be parsed
by a Master, or all responses that may be sent by an Outstation.
DNP OBJECT GROUP & VARIATION REQUEST
outstation must parse
RESPONSE
Outstation may issue
Notes
Group
Num
Var
Num
Description
Function
Codes
(dec)
Qualifier
Codes
(hex)
Function
Codes
(dec)
Qualifier
Codes
(hex)
1 0 Binary Input – All Variations 1 (read) 06 (no range, or
all)
07,08 (limited qty)
1 2 Binary Input – with flags 1 (read) 06 (no range, or 129 (response) 00,17,28
(index)
all) 07,08 (limited qty)
2 0 Binary Input Event – With Absolute
Time
1 (read) 06 (no range, or
all)
07,08 (limited qty)
2 2 Binary Input Event – With Absolute
Time
1 (read) 06 (no range, or
all)
07,08 (limited qty)
129 (response)
130 (unsold.resp)
00,17,28
(index)
30 0 Analog Input – Any Variation 1 (read) 06 (no range, or
all)
07,08 (limited qty
30 2 Analog Input – 16-bit with flag 1 (read) 06 (no range, or 129 (response) 00,17,28(index
)
all) 07,08 (limited qty)
32 0 Analog Input Event – Any Variation 1 (read) 06 (no range, or
all)
07,08 (limited qty)
32 4 Analog Input Event—16-bit with time 1 (read) 06 (no range, or 129 (response) 00,17,28 all)
130 (unsold.resp) (index) 07,08 (limited qty)
50 1 Time and Date 2 (write) 07
=1)
(limited qty
The implementation table must list all functionality required by the device
whether Master or Outstation as defined within the DNP3 IED Conformance
Test Procedures. Any functionality beyond the subset level 1 supported is
indicated by highlighted rows. Text shaded as 07,08 (limited qty) indicates
subset level4 and above functionality. Any Object Groups not provided by an
outstation or not processed by a Master are indicated by strikethrough (note
these Object Groups will still be parsed).
Gateway Manual Sept 2015 Page 97 of 113
1 (read) 07 (limited, 129 (response) 07 (limited
qty=1) qty) (qty = 1)
60 1 Class Objects – Class 0 data 1 (read) 06 (no range, or
all)
60 2 Class Objects – Class 1 data 1 (read)
20 (enbl.unsol.)
06 (no range, or
all)
21 (dab. Unsold.) 07,08 (limited qty) 60 3 Class Objects – Class 2 data 1 (read)
20 (enbl.unsol.)
06 (no range, or
all)
21 (dab. Unsold.) 07,08 (limited qty) 60 4 Class Objects – Class 3 data 1 (read)
20 (enbl.unsol.)
06 (no range, or
all)
21 (dab. Unsold.) 07,08 (limited qty) 80 1 Internal Indications – Packed format 2 (write) 00 (start-stop)
Index = 7
111 249 Octet String Event Object 1 (read) 06 (no range, or 129 (response) 00,17,28 all)
130 (unsold.resp) (index) 07,08 (limited qty)
No object 13 (cold restart)
No object 23 (delay meas.)
F10 Capabilities and Current Settings for Device Database (Outstation Only) –
Point List
F10.1 Single-Bit Binary Inputs
SINGLE-BIT BINARY INPUTS
Static (Steady-State) Group
Number: 1
Event Group Number: 2
Capabilities
Current Value
If configurable,
list methods
Static Variation reported when
variation 0 requested:
Variation 1 – Single-bit Packed
format
Variation 2 – Single-bit with flag
Based on point Index (add
column to table below)
Variation 2 – Single-bit
with flag
Event Variation reported when
variation 0 requested:
Variation 1 – without time
Variation 2 – with absolute time
Variation 3 – with relative time
Based on point Index (add
column to table below)
Variation 2 – with
absolute time
Gateway Manual Sept 2015 Page 98 of 113
Point List of Single-Bit Binary Input is in APPENDIX G – Detailed DNP3 Point List
Binary input is used to report Event Type and Power ON status before and after event
triggered. The static value of Binary Input Point is the most recent recorded value. (i.e.,
most recent event type.)
F10.2 Analog Input Points
ANALOG INPUT POINTS
Static (Steady-State) Group
Number: 30
Event Group Number: 32
Capabilities
Current Value
If configurable
list methods
Static Variation reported when
variation 0 requested:
Variation 1 – 32-bit with flag
Variation 2 – 16-bit with flag
Variation 3 – 32-bit without flag
Variation 4 – 16-bit without flag
Variation 5 – single-precision floating point
with flag
Variation 6 – double-precision floating point
with flag
Based on point Index (add column to table
below)
Variation 2 –
16-bit with flag
Event variation reported when
variation 0 requested:
Variation 1 – 32-bit without time
Variation 2 – 16-bit without time
Variation 3 – 32-bit with time
Variation 4 – 16-bit with time
Variation 5 – single-precision floating point
w/o time
Variation 6 – double-precision floating point
w/o time
Variation 7 – single-precision floating point
with time
Variation 8 – double-precision floating point
with time
Based on point Index (add column to table
below)
Variation 4 –
16-bit with time
Event reporting mode:
When responding with event data
and more than one event has
occurred for a data point, an
Outstation may include all events or
only the most recent event. Only the
most recent event is typically
reported for Analog Inputs.
Only most recent
All events
All events
Gateway Manual Sept 2015 Page 99 of 113
Analog Inputs Included in Class 0
response:
If Analog Inputs are not included in
the Class 0 response, Analog Input
Events (group 32) may not be
reported.
Alway
s
Never
Only if point is assigned to Class 1, 2, or 3
Based on point Index (add column to table
below)
Always
ANALOG INPUT POINTS Static (Steady-State) Group
Number: 30 Capabilities Current Value
If configurable
list methods
Event Group Number: 32
Definition of Analog Input Point
List:
List all addressable points. Points
that do not exist (for example,
because an option is not installed)
shall be omitted from the table.
Fixed, list shown in table below
Configurable(current list may be shown in
table below)
Other, explain
Fixed, list
shown in table
below
Point List of Analog Input is in APPENDIX G – Detailed DNP3 Point List.
Static Analog Input Points are mainly used to read instantaneous (or most recent
measured) status of Data-PAC and CMS installed, e.g., Static analog input on points 3, 4, 5
represent most recent recorded event trigger current.
Event Analog Input Points are mainly used to record all events data recorded since last
Event Analog Input reading, in which each point could have more than one event values
with different time stamp. (e.g., Event Analog Input on points 3, 4, 5, 6)
Gateway Manual July 2012 page 100 of 109
APPENDIX G – Detailed DNP3 Point List
G1 Octet String Events
Point Index
(Dec)
Point Index
(Hex)
Event Variation Point Name Scaling
Obj Var Class Description
0 000 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Current -- CMS G1P1
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) No Scaling
1 001 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Voltage -- CMS G1P1
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) divided by 10
2 002 111 x 1 Octet String Input -- x Bytes Reserved -- CMS G1P1
3 003 111 249 1 Octet String Input -- 247 Bytes
Waveform Data - Current -- CMS G1P2
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) No Scaling
4 004 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Voltage -- CMS G1P2
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) divided by 10
5 005 111 x 1 Octet String Input -- x Bytes Reserved -- CMS G1P2
6 006 111 249 1 Octet String Input -- 247 Bytes
Waveform Data - Current -- CMS G1P3
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) No Scaling
7 007 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Voltage -- CMS G1P3
(120x16bitsSamples+48bitsTimeStamp+8bitCheckSum) divided by 10
8 008 111 x 1 Octet String Input -- x Bytes Reserved -- CMS G1P3
9 009 111 249 1 Octet String Input -- 247 Bytes
Waveform Data - Current -- CMS G2P1
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) No Scaling
10 00A 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Voltage -- CMS G2P1
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) divided by 10
11 00B 111 x 1 Octet String Input -- x Bytes Reserved -- CMS G2P1
12 00C 111 249 1 Octet String Input -- 247 Bytes
Waveform Data - Current -- CMS G2P2
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) No Scaling
13 00D 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Voltage -- CMS G2P2
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) divided by 10
14 00E 111 x 1 Octet String Input -- x Bytes Reserved -- CMS G2P2
15 00F 111 249 1 Octet String Input -- 247 Bytes
Waveform Data - Current -- CMS G2P3
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) No Scaling
16 010 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Voltage -- CMS G2P3
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) divided by 10
17 011 111 x 1 Octet String Input -- x Bytes Reserved -- CMS G2P3
18 012 111 249 1 Octet String Input -- 247 Bytes
Waveform Data - Current -- CMS G3P1
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) No Scaling
19 013 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Voltage -- CMS G3P1
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) divided by 10
20 014 111 x 1 Octet String Input -- x Bytes Reserved -- CMS G3P1
21 015 111 249 1 Octet String Input -- 247 Bytes
Waveform Data - Current -- CMS G3P2
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) No Scaling
22 016 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Voltage -- CMS G3P2
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) divided by 10
23 017 111 x 1 Octet String Input -- x Bytes Reserved -- CMS G3P2
24 018 111 249 1 Octet String Input -- 247 Bytes
Waveform Data - Current -- CMS G3P3
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) No Scaling
25 019 111 249 1 Octet String Input -- 247 Bytes Waveform Data - Voltage -- CMS G3P3
(120x16bitsSamples+48bitsTimeStamp+16bits(Counter of micro seconds)+8bitsCheckSum) divided by 10
26 01A 111 x 1 Octet String Input -- x Bytes Reserved -- CMS G3P3
Note: Current waveform has 120 sample points, and every sample point is 16 bit signed integer value. No scaling needed. (Unit: Ampere)
Voltage waveform has 120 sample points, and every sample point is 16 bit signed integer value. To be divided by 10 to get real value. (Unit: Percentage.)
Range of real value.(-100.0%~+100.0%)
Timestamp is 48bit DNP3 time stamp which represents the time stamp of the first sample point.
249Bytes=Waveform(240Bytes)+TimeStamp(6Bytes)+Reserved(2Bytes)+CheckSum(1Byte)
(Waveform is sampled at 600HZ. 120samples will cover 200ms time duration, which corresponds to 10 cycles for 50Hz Line, and 12 cycles for 60Hz Line.)
G1 Octet Troubleshooting Points
Point Index
(Dec)
Point Index
(Hex)
Event Variation Point Name Scaling
Obj Var Class Description
166 0A6 111 4 3 Octet String Input -- 2 Bytes RF Health Check Error
16bits(lowest bit is G1P1) No Scaling
167 0A7 111 4 3 Octet String Input -- 2 Bytes Commission Error
16bits(lowest bit is G1P1) No Scaling
Gateway Manual Sept 2015 Page 101 of 113
G2 Single Binary Inputs
Point Index
(Dec)
Point Index
(Hex) Obj Var Description Obj Var Class Description Point Name
0 000 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - Gateway Battery Alarm
1 001 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LineIQ Battery Alarm -G1P1 2 002 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - SI (short interruption) - G1P1
3 003 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LI (long interruption) - G1P1
4 004 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - FP (on the fault path) - G1P1
5 005 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - PR (power return) - G1P1
6 006 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PreTrigger Power Status -- CMS - G1P1
7 007 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PostTrigger Power Status -- CMS - G1P1
8 008 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LineIQ Battery Alarm -G1P2
9 009 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - SI (short interruption) - G1P2
10 00A 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LI (long interruption) - G1P2
11 00B 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - FP (on the fault path) - G1P2
12 00C 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - PR (power return) - G1P2
13 00D 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PreTrigger Power Status -- CMS - G1P2
14 00E 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PostTrigger Power Status -- CMS - G1P2
15 00F 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LineIQ Battery Alarm -G1P3
16 010 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - SI (short interruption) - G1P3
17 011 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LI (long interruption) - G1P3
18 012 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - FP (on the fault path) - G1P3
19 013 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - PR (power return) - G1P3
20 014 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PreTrigger Power Status -- CMS - G1P3
21 015 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PostTrigger Power Status -- CMS - G1P3
22 016 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LineIQ Battery Alarm -G2P1
23 017 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - SI (short interruption) - G2P1
24 018 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LI (long interruption) - G2P1
25 019 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - FP (on the fault path) - G2P1
26 01A 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - PR (power return) - G2P1
27 01B 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PreTrigger Power Status -- CMS - G2P1
28 01C 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PostTrigger Power Status -- CMS - G2P1
29 01D 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LineIQ Battery Alarm -G2P2
30 01E 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - SI (short interruption) - G2P2
31 01F 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LI (long interruption) - G2P2
32 020 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - FP (on the fault path) - G2P2
33 021 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - PR (power return) - G2P2
34 022 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PreTrigger Power Status -- CMS - G2P2
35 023 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PostTrigger Power Status -- CMS - G2P2
36 024 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LineIQ Battery Alarm -G2P3
37 025 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - SI (short interruption) - G2P3
38 026 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LI (long interruption) - G2P3
39 027 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - FP (on the fault path) - G2P3
40 028 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - PR (power return) - G2P3
41 029 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PreTrigger Power Status -- CMS - G2P3
42 02A 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PostTrigger Power Status -- CMS - G2P3
43 02B 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LineIQ Battery Alarm -G3P1
44 02C 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - SI (short interruption) - G3P1
45 02D 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LI (long interruption) - G3P1
46 02E 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - FP (on the fault path) - G3P1
47 02F 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - PR (power return) - G3P1
48 030 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PreTrigger Power Status -- CMS - G3P1
49 031 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PostTrigger Power Status -- CMS - G3P1
50 032 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LineIQ Battery Alarm -G3P2
51 033 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - SI (short interruption) - G3P2
52 034 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LI (long interruption) - G3P2
53 035 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - FP (on the fault path) - G3P2
54 036 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - PR (power return) - G3P2
55 037 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PreTrigger Power Status -- CMS - G3P2
56 038 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PostTrigger Power Status -- CMS - G3P2
57 039 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LineIQ Battery Alarm -G3P3
58 040 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - SI (short interruption) - G3P3
59 041 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - LI (long interruption) - G3P3
60 042 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - FP (on the fault path) - G3P3
61 043 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time Event Type - PR (power return) - G3P3
62 044 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PreTrigger Power Status -- CMS - G3P3
63 045 1 2 Binary Input -- With Flags 2 2 1 Binary Input Event -- With absolute time PostTrigger Power Status -- CMS - G3P3
Gateway Manual Sept 2015 Page 102 of 113
G3 16 Bit Analog Inputs
Point Index
(Dec)
Point Index
(Hex)
Static Variation Event Variation Point Name
Static Variation / Event Variation SCALING
Obj Var Description Obj Var Class Description
0 000 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- PAC divided by 100
1 001 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- CMS G1P1 divided by 100
2 002 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time VSensor Static / VSensor Event Profile --CMS G1P1 times 100
3 003 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / Event Trigger Current --CMS G1P1 divided by 10
4 004 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / PreTrigger Current --CMS G1P1 divided by 10
5 005 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / PostTrigger Current --CMS G1P1 divided by 10
6 006 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Load Log Current -- CMS G1P1 divided by 10
7 007 30 2 Analog Input -- 16-bit with flag
LineFrequency -- CMS G1P1 divided by 10
8 008 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Power Factor (Instantaneous / Historical) -- CMS G1P1 divided by 1000
9 009 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Phase Angle (Instantaneous / Historical) -- CMS G1P1 divided by 10
10 00A 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Ambient Temperature (Instantaneous / Historical ) -- CMS G1P1 divided by 100
11 00B 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Conductor Temperature (Instantaneous / Historical ) -- CMS G1P1 divided by 100
12 00C 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- CMS G1P2 divided by 100
13 00D 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time VSensor Static / VSensor Event Profile --CMS G1P2 times 100
14 00E 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / Event Trigger Current --CMS G1P2 divided by 10
15 00F 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PreTrigger Current --CMS G1P2 divided by 10
16 010 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PostTrigger Current --CMS G1P2 divided by 10
17 011 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Load Log Current -- CMS G1P2 divided by 10
18 012 30 2 Analog Input -- 16-bit with flag
LineFrequency -- CMS G1P2 divided by 10
19 013 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Power Factor (Instantaneous / Historical) -- CMS G1P2 divided by 1000
20 014 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Phase Angle (Instantaneous / Historical) -- CMS G1P2 divided by 10
21 015 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Ambient Temperature (Instantaneous / Historical ) -- CMS G1P2 divided by 100
22 016 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Conductor Temperature (Instantaneous / Historical ) -- CMS G1P2 divided by 100
23 017 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- CMS G1P3 divided by 100
24 018 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time VSensor Static / VSensor Event Profile --CMS G1P3 times 100
25 019 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / Event Trigger Current --CMS G1P3 divided by 10
26 01A 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PreTrigger Current --CMS G1P3 divided by 10
27 01B 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PostTrigger Current --CMS G1P3 divided by 10
28 01C 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Load Log Current -- CMS G1P3 divided by 10
29 01D 30 2 Analog Input -- 16-bit with flag
LineFrequency -- CMS G1P3 divided by 10
30 01E 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Power Factor (Instantaneous / Historical) -- CMS G1P3 divided by 1000
31 01F 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Phase Angle (Instantaneous / Historical) -- CMS G1P3 divided by 10
32 020 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Ambient Temperature (Instantaneous / Historical ) -- CMS G1P3 divided by 100
33 021 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Conductor Temperature (Instantaneous / Historical ) -- CMS G1P3 divided by 100
34 022 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- CMS G2P1 divided by 100
35 023 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time VSensor Static / VSensor Event Profile --CMS G2P1 times 100
36 024 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / Event Trigger Current --CMS G2P1 divided by 10
37 025 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PreTrigger Current --CMS G2P1 divided by 10
38 026 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PostTrigger Current --CMS G2P1 divided by 10
39 027 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Load Log Current -- CMS G2P1 divided by 10
40 028 30 2 Analog Input -- 16-bit with flag
LineFrequency -- CMS G2P1 divided by 10
41 029 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Power Factor (Instantaneous / Historical) -- CMS G2P1 divided by 1000
42 02A 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Phase Angle (Instantaneous / Historical) -- CMS G2P1 divided by 10
43 02B 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Ambient Temperature (Instantaneous / Historical ) -- CMS G2P1 divided by 100
44 02C 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Conductor Temperature (Instantaneous / Historical ) -- CMS G2P1 divided by 100
45 02D 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- CMS G2P2 divided by 100
46 02E 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time VSensor Static / VSensor Event Profile --CMS G2P2 times 100
47 02F 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / Event Trigger Current --CMS G2P2 divided by 10
48 030 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PreTrigger Current --CMS G2P2 divided by 10
49 031 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PostTrigger Current --CMS G2P2 divided by 10
50 032 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Load Log Current -- CMS G2P2 divided by 10
51 033 30 2 Analog Input -- 16-bit with flag
LineFrequency -- CMS G2P2 divided by 10
52 034 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Power Factor (Instantaneous / Historical) -- CMS G2P2 divided by 1000
53 035 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Phase Angle (Instantaneous / Historical) -- CMS G2P2 divided by 10
54 036 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Ambient Temperature (Instantaneous / Historical ) -- CMS G2P2 divided by 100
55 037 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Conductor Temperature (Instantaneous / Historical ) -- CMS G2P2 divided by 100
56 038 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- CMS G2P3 divided by 100
57 039 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time VSensor Static / VSensor Event Profile --CMS G2P3 times 100
58 03A 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / Event Trigger Current --CMS G2P3 divided by 10
59 03B 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PreTrigger Current --CMS G2P3 divided by 10
60 03C 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PostTrigger Current --CMS G2P3 divided by 10
61 03D 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Load Log Current -- CMS G2P3 divided by 10
62 03E 30 2 Analog Input -- 16-bit with flag
LineFrequency -- CMS G2P3 divided by 10
63 03F 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Power Factor (Instantaneous / Historical) -- CMS G2P3 divided by 1000
64 040 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Phase Angle (Instantaneous / Historical) -- CMS G2P3 divided by 10
65 041 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Ambient Temperature (Instantaneous / Historical ) -- CMS G2P3 divided by 100
66 042 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Conductor Temperature (Instantaneous / Historical ) -- CMS G2P3 divided by 100
67 043 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- CMS G3P1 divided by 100
68 044 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time VSensor Static / VSensor Event Profile --CMS G3P1 times 100
69 045 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / Event Trigger Current --CMS G3P1 divided by 10
70 046 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PreTrigger Current --CMS G3P1 divided by 10
71 047 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PostTrigger Current --CMS G3P1 divided by 10
72 048 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Load Log Current -- CMS G3P1 divided by 10
73 049 30 2 Analog Input -- 16-bit with flag
LineFrequency -- CMS G3P1 divided by 10
74 04A 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Power Factor (Instantaneous / Historical) -- CMS G3P1 divided by 1000
75 04B 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Phase Angle (Instantaneous / Historical) -- CMS G3P1 divided by 10
76 04C 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Ambient Temperature (Instantaneous / Historical ) -- CMS G3P1 divided by 100
77 04D 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Conductor Temperature (Instantaneous / Historical ) -- CMS G3P1 divided by 100
78 04E 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- CMS G3P2 divided by 100
79 04F 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time VSensor Static / VSensor Event Profile --CMS G3P2 times 100
80 050 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / Event Trigger Current --CMS G3P2 divided by 10
81 051 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PreTrigger Current --CMS G3P2 divided by 10
82 052 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PostTrigger Current --CMS G3P2 divided by 10
83 053 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Load Log Current -- CMS G3P2 divided by 10
84 054 30 2 Analog Input -- 16-bit with flag
LineFrequency -- CMS G3P2 divided by 10
85 055 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Power Factor (Instantaneous / Historical) -- CMS G3P2 divided by 1000
86 056 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Phase Angle (Instantaneous / Historical) -- CMS G3P2 divided by 10
87 057 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Ambient Temperature (Instantaneous / Historical ) -- CMS G3P2 divided by 100
88 058 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Conductor Temperature (Instantaneous / Historical ) -- CMS G3P2 divided by 100
89 059 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Battery Voltage Raw value -- CMS G3P3 divided by 100
90 05A 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time VSensor Static / VSensor Event Profile --CMS G3P3 times 100
91 05B 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current / Event Trigger Current --CMS G3P3 divided by 10
92 05C 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PreTrigger Current --CMS G3P3 divided by 10
93 05D 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Instantaneous Current /PostTrigger Current --CMS G3P3 divided by 10
94 05E 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Load Log Current -- CMS G3P3 divided by 10
95 05F 30 2 Analog Input -- 16-bit with flag
LineFrequency -- CMS G3P3 divided by 10
96 060 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Power Factor (Instantaneous / Historical) -- CMS G3P3 divided by 1000
97 061 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Phase Angle (Instantaneous / Historical) -- CMS G3P3 divided by 10
98 062 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Ambient Temperature (Instantaneous / Historical ) -- CMS G3P3 divided by 100
99 063 30 2 Analog Input -- 16-bit with flag 32 4 2 Analog Input Event -- 16-bit with time Conductor Temperature (Instantaneous / Historical ) -- CMS G3P3 divided by 100
100 064 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Reserved, diagnosis only. (RF health check Error)
101 065 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Reserved, diagnosis only. (Communication Error)
102 066 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Reserved, diagnosis only. (Modem Script Error.) Lower Word of 32bits
103 067 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Reserved, diagnosis only. (Modem Script Error.) Higher Word of 32bits
104 068 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Reserved (Debug One) Lower Word of 32bits
105 069 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Reserved (Debug One) Higher Word of 32bits
106 06A 30 2 Analog Input -- 16-bit with flag 32 4 3 Analog Input Event -- 16-bit with time Reserved (Debug Two)
Gateway Manual Sept 2015 Page 103 of 113
Point Index
(Dec)
Point Index
(Hex)
Static Variation Event Variation Point Name
Static Variation / Event Variation SCALING
Obj Var Description Obj Var Class Description
172
AC 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G1P1
173 AD 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G1P1
174 AE 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G1P1
182 B6 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G1P2
183 B7 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G1P2
184 B8 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G1P2
192 C0 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G1P3
193 C1 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G1P3
194 C2 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G1P3
202 CA 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G2P1
203 CB 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G2P1
204 CC 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G2P1
212 D4 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G2P2
213 D5 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G2P2
214 D6 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G2P2
222 DE 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G2P3
223 DF 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G2P3
224 E0 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G2P3
232 E8 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G3P1
233 E9
30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G3P1
234 EA 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G3P1
242 F2 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G3P2
243 F3 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G3P2
244 F4 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G3P2
252 FC 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G3P3
253 FD 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G3P3
254 FE 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G3P3
262 106 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G4P1
263 107 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G4P1
264 108 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G4P1
272 110 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G4P2
273 111
11
30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G4P2
274 112 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G4P2
282 11A 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G4P3
283 11B 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G4P3
284 11C
30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G4P3
292 124 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G5P1
293 125 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G5P1
294 126 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G5P1
302
12E 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G5P2
303 12F 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G5P2
304 130 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G5P2
312 138 30
2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Load Direction – CMS G5P3
313 139 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Direction – CMS G5P3
314 13A 30 2 Analog Input -- 16-bit with flag 32 4 1 Analog Input Event -- 16-bit with time Fault Boolean – CMS G5P3
Fault Direction Returned Values (0=n/a, 1=N, 2=NE, 3=E, 4=SE, 5=S, 6=SW, 7=W, 8=NW)
Appendix H – Gateway Firmware Upgrades The Gateway Firmware Upgrade tool (Gateway _FW_Upgrade.exe) is distributed as a zip
file along with the .LHX file which contains the actual firmware upgrade.
To upgrade the Gateway firmware, you must be able to make a direct serial port
connection, or a direct Ethernet connection to the Gateway
Follow the steps below to perform the upgrade.
1. Unzip the Firmware Upgrade file and copy the Gateway _FW_Upgrade.exe
executable and the .LHX file (e.g. V043-Gateway C30TcpIpDnp3-O1.lhx ) to your
desktop.
2. Turn on the Gateway and wait for the initialization process to complete.
3. Make a direct connection to the Gateway.
If using a serial (COM) port, you will need to know the COM port number of the serial port
you are using.
If you are unsure of the COM port number, right click on the My Computer icon, and select
Manage. Then select “Device Manager” and scroll to the “Ports (COM & LPT)” entry, and
expand it.
Gateway Manual Sept 2015 Page 104 of 113
Figure 40: Verifying the COM port number
Gateway Manual Sept 2015 Page 105 of 113
The available COM ports and their numbers (e.g. COM5) will be shown.
If you are using an Internet connection you will need to know the IP address of the
Gateway.
4. Start the Gateway Firmware Upgrade Program by clicking on the desktop icon.
Figure 41: Gateway Firmware Upgrader opening screen
5. Using the Browse button, select and open the .LHX file.
Figure 42: Selecting the .LHX file
Gateway Manual Sept 2015 Page 106 of 113
Figure 43: Gateway firmware upgrader with .LHX file selected
6. Enter the COM port (e.g. COM5) or the IP address, using the style shown below the
Comms input box.
Figure 44: Figure 44: Gateway Firmware Upgrader with COM port selected
Gateway Manual Sept 2015 Page 107 of 113
7. Verify that the entries you have made are correct, and then click on Upgrade.
8. The information box will now show you the status of the upgrade. The initial screen
will say that communications have been established with the Gateway, and that the
upgrade process has commenced.
Figure 45: Gateway Firmware Upgrade commencing
9. As the upgrade proceeds, the Percentage Complete number will be updated at
10% intervals.
Gateway Manual Sept 2015 Page 108 of 113
Figure 46: Gateway Firmware Upgrade in progress
10. When the upgrade is complete, the following screen will be displayed.
Figure 47: Gateway Firmware Upgrade completed
Gateway Manual Sept 2015 Page 109 of 113
11. To check the Gateway status, use LineMan to connect to the Gateway via a
LocalLink, and check the Gateway summary. You will need to wait for the firmware
upgrade process to complete and for the Gateway to reboot and the Gateway
initialization process to complete before you can check the status.
Figure 48: Using LineMan to verify the firmware version number
12. Confirm that the COM Firmware Version is correct.
Gateway Manual Sept 2015 Page 110 of 113
Appendix I – Remote Access via TCP/IP The Gateway remote access tool (RF-DataLink-Emulator.exe) is distributed as a zip file,
which contains the command line utility as well as a GUI interface.
*A null modem cable or virtual null program is need for both GridInSite as well as
DNP3/LineMan Remote applications.
**Gateway firmware version 2.15 and LineMan version 1.9.8.6 or higher is required to
connect for customers using GridInsite.
***Connecting to units setup to call into GridInSite/GServer will only be allowed to connect
within 5 minutes of the last Health Check. If the windows is missed you will have to wait till
the next health check
To access the Gateway, you must use either a virtual or hardware based null modem serial
port, and a direct TCP/IP connection to the Gateway.
Follow the steps below to perform the connection
1. Open the program by clicking on the “RF-DataLink-Emulator-UI.exe” f ilename as shown below.
Figure 49.
2. The following window will open up.
Gateway Manual Sept 2015 Page 111 of 113
Figure 50.
3. Enter one of the null serial port addresses in to the LineMan COM Port text box.
Figure 51.
4. Next, Select LineMan LIQ60 for LineIQ products.
Gateway Manual Sept 2015 Page 112 of 113
Figure 52.
5. In the PAC Comms textbox, enter the IP Address of the unit you wish to talk to, with the port equal to
9000
Figure 53.
Gateway Manual Sept 2015 Page 113 of 113
6. Click Start to Begin the session.
Figure 54.
7. Open LineMan and select the other serial port that is connected to your null connection.
Figure 55.
8. If successful, the program will behave as normal.