Point list manual - ABB Group › public › 1892491075d749e7a... · The point list manual describes the outlook and properties of the data points specific to the IED. The manual

— RELION® 670 SERIES

DNP, 670 series Version 2.1 Point list manual

Document ID: 1MRK511354-UUS Issued: March 2019

Revision: AProduct version: 2.1

© Copyright 2016 ABB. All rights reserved

Copyright

This document and parts thereof must not be reproduced or copied without written permissionfrom ABB, and the contents thereof must not be imparted to a third party, nor used for anyunauthorized purpose.

The software and hardware described in this document is furnished under a license and may beused or disclosed only in accordance with the terms of such license.

This product includes software developed by the OpenSSL Project for use in the OpenSSL Toolkit.(http://www.openssl.org/) This product includes cryptographic software written/developed by:Eric Young ([email protected]) and Tim Hudson ([email protected]).

Trademarks

ABB and Relion are registered trademarks of the ABB Group. All other brand or product namesmentioned in this document may be trademarks or registered trademarks of their respectiveholders.

Warranty

Please inquire about the terms of warranty from your nearest ABB representative.

Disclaimer

The data, examples and diagrams in this manual are included solely for the concept or productdescription and are not to be deemed as a statement of guaranteed properties. All personsresponsible for applying the equipment addressed in this manual must satisfy themselves thateach intended application is suitable and acceptable, including that any applicable safety or otheroperational requirements are complied with. In particular, any risks in applications where a systemfailure and/or product failure would create a risk for harm to property or persons (including butnot limited to personal injuries or death) shall be the sole responsibility of the person or entityapplying the equipment, and those so responsible are hereby requested to ensure that allmeasures are taken to exclude or mitigate such risks.

This document has been carefully checked by ABB but deviations cannot be completely ruled out.In case any errors are detected, the reader is kindly requested to notify the manufacturer. Otherthan under explicit contractual commitments, in no event shall ABB be responsible or liable for anyloss or damage resulting from the use of this manual or the application of the equipment.

Conformity

This product complies with the directive of the Council of the European Communities on theapproximation of the laws of the Member States relating to electromagnetic compatibility (EMCDirective 2004/108/EC) and concerning electrical equipment for use within specified voltagelimits (Low-voltage directive 2006/95/EC). This conformity is the result of tests conducted by ABBin accordance with the product standard EN 60255-26 for the EMC directive, and with the productstandards EN 60255-1 and EN 60255-27 for the low voltage directive. The product is designed inaccordance with the international standards of the IEC 60255 series and ANSI C37.90. The DNPprotocol implementation in the IED conforms to "DNP3 Intelligent Electronic Device (IED)Certification Procedure Subset Level 2", available at www.dnp.org.

Table of contents

Section 1 Introduction..............................................................................................................31.1 This manual................................................................................................................................................ 31.2 Intended audience.................................................................................................................................... 31.3 Product documentation.......................................................................................................................... 41.3.1 Product documentation set...............................................................................................................41.3.2 Document revision history................................................................................................................. 51.3.3 Related documents.............................................................................................................................. 51.4 Document symbols and conventions....................................................................................................71.4.1 Symbols.................................................................................................................................................. 71.4.2 Document conventions....................................................................................................................... 8

Section 2 DNP3 data mappings...............................................................................................92.1 Overview..................................................................................................................................................... 92.2 Point list for the IEDs............................................................................................................................... 9

Section 3 DNP3 protocol implementation........................................................................... 373.1 DNP3 device profile................................................................................................................................ 373.2 DNP3 implementation table................................................................................................................. 79

Section 4 Glossary.................................................................................................................. 854.1 Glossary....................................................................................................................................................85

Table of contents

DNP, 670 series 1Point list manual

2

Section 1 Introduction

1.1 This manualGUID-AB423A30-13C2-46AF-B7FE-A73BB425EB5F v19

The point list manual describes the outlook and properties of the data points specific to the IED.The manual should be used in conjunction with the corresponding communication protocolmanual.

1.2 Intended audienceGUID-C9B8127F-5748-4BEA-9E4F-CC762FE28A3A v10

This manual addresses the communication system engineer or system integrator responsible forpre-engineering and engineering for communication setup in a substation from an IEDperspective.

The system engineer or system integrator must have a basic knowledge of communication inprotection and control systems and thorough knowledge of the specific communication protocol.

1MRK511354-UUS A Section 1Introduction


1.3 Product documentation

1.3.1 Product documentation setGUID-3AA69EA6-F1D8-47C6-A8E6-562F29C67172 v15

IEC07000220-4-en.vsd

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Application manual

Operation manual

Installation manual

Engineering manual

Communication protocol manual

Cyber security deployment guideline

Technical manual

Commissioning manual

IEC07000220 V4 EN-US

Figure 1: The intended use of manuals throughout the product lifecycle

The engineering manual contains instructions on how to engineer the IEDs using the various toolsavailable within the PCM600 software. The manual provides instructions on how to set up aPCM600 project and insert IEDs to the project structure. The manual also recommends a sequencefor the engineering of protection and control functions, LHMI functions as well as communicationengineering for IEC 60870-5-103, IEC 61850, DNP3, LON and SPA.

The installation manual contains instructions on how to install the IED. The manual providesprocedures for mechanical and electrical installation. The chapters are organized in thechronological order in which the IED should be installed.

The commissioning manual contains instructions on how to commission the IED. The manual canalso be used by system engineers and maintenance personnel for assistance during the testingphase. The manual provides procedures for the checking of external circuitry and energizing theIED, parameter setting and configuration as well as verifying settings by secondary injection. Themanual describes the process of testing an IED in a substation which is not in service. Thechapters are organized in the chronological order in which the IED should be commissioned. Therelevant procedures may be followed also during the service and maintenance activities.

Section 1 1MRK511354-UUS AIntroduction

4 DNP, 670 seriesPoint list manual

The operation manual contains instructions on how to operate the IED once it has beencommissioned. The manual provides instructions for the monitoring, controlling and setting of theIED. The manual also describes how to identify disturbances and how to view calculated andmeasured power grid data to determine the cause of a fault.

The application manual contains application descriptions and setting guidelines sorted perfunction. The manual can be used to find out when and for what purpose a typical protectionfunction can be used. The manual can also provide assistance for calculating settings.

The technical manual contains operation principle descriptions, and lists function blocks, logicdiagrams, input and output signals, setting parameters and technical data, sorted per function.The manual can be used as a technical reference during the engineering phase, installation andcommissioning phase, and during normal service.

The communication protocol manual describes the communication protocols supported by theIED. The manual concentrates on the vendor-specific implementations.

The point list manual describes the outlook and properties of the data points specific to the IED.The manual should be used in conjunction with the corresponding communication protocolmanual.

The cyber security deployment guideline describes the process for handling cyber security whencommunicating with the IED. Certification, Authorization with role based access control, andproduct engineering for cyber security related events are described and sorted by function. Theguideline can be used as a technical reference during the engineering phase, installation andcommissioning phase, and during normal service.

1.3.2 Document revision historyGUID-C8027F8A-D3CB-41C1-B078-F9E59BB73A6C v2

Document revision/date History

January 2016 First release

1.3.3 Related documentsGUID-94E8A5CA-BE1B-45AF-81E7-5A41D34EE112 v4

Documents related to REB670 Document numbers

Application manual 1MRK 505 337-UUS

Commissioning manual

Product guide 1MRK 505 340-BEN

Technical manual 1MRK 505 338-UUS

Type test certificate 1MRK 505 340-TUS

Documents related to REC670 Document numbers


Commissioning manual 1MRK 511 360-UUS






Documents related to RED670 Document numbers






Documents related to REG670 Document numbers






Documents related to REL670 Document numbers






Documents related to RET670 Document numbers






Documents related to RES670 Document numbers








Documents related to RER670 Document numbers

Commissioning manual 1MRK 506 361-UEN


Technical manual 1MRK 506 360-UEN

Type test certificate 1MRK 506 362-TEN

1.4 Document symbols and conventions

1.4.1 SymbolsGUID-2945B229-DAB0-4F15-8A0E-B9CF0C2C7B15 v12

The electrical warning icon indicates the presence of a hazard which could result inelectrical shock.

The warning icon indicates the presence of a hazard which could result in personalinjury.

The caution hot surface icon indicates important information or warning about thetemperature of product surfaces.

The caution icon indicates important information or warning related to theconcept discussed in the text. It might indicate the presence of a hazard whichcould result in corruption of software or damage to equipment or property.

The information icon alerts the reader of important facts and conditions.

The tip icon indicates advice on, for example, how to design your project or how touse a certain function.

Although warning hazards are related to personal injury, it is necessary to understand that undercertain operational conditions, operation of damaged equipment may result in degraded processperformance leading to personal injury or death. It is important that the user fully complies with allwarning and cautionary notices.



1.4.2 Document conventionsGUID-96DFAB1A-98FE-4B26-8E90-F7CEB14B1AB6 v8

• Abbreviations and acronyms in this manual are spelled out in the glossary. The glossary alsocontains definitions of important terms.

• Parameter names are shown in italics.For example, the function can be enabled and disabled with the Operation setting.

• Each function block symbol shows the available input/output signal.

• the character ^ in front of an input/output signal name indicates that the signal namemay be customized using the PCM600 software.

• the character * after an input signal name indicates that the signal must be connectedto another function block in the application configuration to achieve a valid applicationconfiguration.

• Dimensions are provided both in inches and millimeters. If it is not specifically mentionedthen the dimension is in millimeters.



Section 2 DNP3 data mappings

2.1 OverviewGUID-EC7D1F5E-FFE0-4837-B02A-45E1CD531A94 v3

This document describes the available DNP3 data points and structures in the IEDs. The datapoints are unmapped as a default. The point list tables represents the superset of available DNP3data points in these IEDs. The actual set of available points depends on the product, optionalfunctionalities and configuration.

The DNP3 points can be freely added, removed, reorganized and reconfigured using PCM600.

As a default, the class assignments are Class 0 and Class 3 for binary inputs and outputs and fordouble bit indications. The class assignment for analog inputs and for counters are Class 0 andClass 2. Analog values are provided with default scalings. The scalings can be freely modified.

The point list table only shows the signals of the first instance of each function if more than oneinstance of a function can be configured.

Signals with user-defined names are listed with their default name in the point list table.

See the engineering manual and DNP3 communication protocol manual for moreinformation.

2.2 Point list for the IEDsGUID-88A55057-7A4C-4EB3-8E7A-19AD2821D5CA v5

Table 1: Signal point list

Function name Signal type Signal name Description

Hardware input and output monitoring

BIM Binary inputs STATUS Binary input module status

BI1 Binary input 1

BI2 Binary input 2

BI3 Binary input 3

BI4 Binary input 4

BI5 Binary input 5

BI6 Binary input 6

BI7 Binary input 7

BI8 Binary input 8

BI9 Binary input 9

BI10 Binary input 10





Table continues on next page

1MRK511354-UUS A Section 2DNP3 data mappings





OSCWRN Oscillation warning

BOM Binary inputs STATUS Binary output part of BOM module status

BLOCK Block binary outputs

BO1 Binary output 1

BO2 Binary output 2

BO3 Binary output 3

BO4 Binary output 4

BO5 Binary output 5

BO6 Binary output 6

BO7 Binary output 7

BO8 Binary output 8

BO9 Binary output 9

BO10 Binary output 10















IOM Binary inputs STATUS Binary input part of IOM module status

BI1 Binary input 1

BI2 Binary input 2

BI3 Binary input 3

BI4 Binary input 4

BI5 Binary input 5

BI6 Binary input 6

BI7 Binary input 7

BI8 Binary input 8

BLKOUT Block binary outputs

BO1 Binary output 1

BO2 Binary output 2

BO3 Binary output 3

BO4 Binary output 4

BO5 Binary output 5

BO6 Binary output 6

BO7 Binary output 7

BO8 Binary output 8

BO9 Binary output 9




Section 2 1MRK511354-UUS ADNP3 data mappings




OSCWRN Oscillation warning

SOM Binary inputs STATUS Static binary output module status

BLOCK Block binary outputs

BO1 Binary output 1

BO2 Binary output 2

BO3 Binary output 3

BO4 Binary output 4

BO5 Binary output 5

BO6 Binary output 6

BO7 Static binary output 7






General command handling from DNP master

AUTOBITS Binary outputs CMDBIT1 Command out bit 1

CMDBIT2 Command out bit 2



































General functions for showing signals for DNP master

MVGAPC Analog inputs IN Magnitude of deadband value

SP16GAPC Binary inputs IN1 Input 1 status

IN2 Input 2 status

IN3 Input 3 status

IN4 Input 4 status

IN5 Input 5 status

IN6 Input 6 status

IN7 Input 7 status

IN8 Input 8 status

IN9 Input 9 status

IN10 Input 10 status







OUTOR Output status logic OR gate for input 1 to 16

SPGAPC Binary inputs IN Input status

Directly linked signals

ACTVGRP Binary inputs GRP1 Setting group 1 is active

GRP2 Setting group 2 is active





AEGPVOC Binary inputs TRIP Trip signal from accidental energizing of generator protection

B16I Analog inputs OUT Output value

BCZSPDIF Binary input TRIP Check zone general trip

BCZPDIF Binary input TRIP Check zone general trip

BFPTRC_F01 -BFPTRC_F24 Binary input TRIP Common trip signal to the feeder CB

Analog input ZONCONI Status of feeder connections to all zones

BICPTRC_01 -BICPTRC_05 Binary input TRIP Common trip signal to the bus-interconnector CB

Analog inputs ZONCONI1 Status of bus-interc. CT1 connections to all zones

ZONCONI2 Status of bus-interc. CT2 connections to all zones

BZNPDIF_Z1 -BZNPDIF_Z6 Binary inputs ALDIFF Differential current alarm





OCT General open CT alarm

TRCBF Zone trip due to external trip from any bay (CBF trip)

TRDIFF Zone trip due to biased differential algorithm

TREXTZ Zone trip caused by input TRZONE (external trip)

TRIP General zone trip

TRSENS Zone trip due to sensitive differential algorithm

BCZTPDIF Binary inputs TRIP Check zone general trip

TR_A Check zone trip phase A

TR_B Check zone trip phase B

TR_C Check zone trip phase C

BDCGAPC Binary inputs ALARM Delayed alarm for abnormal aux. contact status, 00 or 11

CLOSED Indicates that primary object is closed

FORCED Primary object status forced to open or closed by setting

OPEN Indicates that primary object is open

BRCPTOC Binary inputs TRIP Operate signal of the protection logic

BRPTOC Binary input TRIP Trip signal

BTIGAPC Analog input OUT Output value

BUSPTRC_B1 Binary inputs CONNZA Bay is connected to zone A

CONNZB Bay is connected to zone B

TRIP Common trip signal for the bay














































































BUTPTRC_B1 Binary inputs CONNZA Bay is connected to zone A
























BZISGGIO Binary inputs ACTIVE Load Transfer/Zone Interconnection active

ALARM Too long load transfer alarm

BZITGGIO Binary inputs ACTIVE Load Transfer/Zone Interconnection active

ALARM Too long load transfer alarm





BZNSPDIF_A Binary inputs ALDIFF Differential current alarm Zone A

OCT General open CT alarm Zone A

TRCBF Zone A trip due to external trip from one of connected bays

TRDIFF Biased differential trip output Zone A

TREXTZ Zone A trip due to external input signal

TRIP Zone A general trip

TRSENS Sensitive differential function trip Zone A

BZNSPDIF_B Binary inputs ALDIFF Differential current alarm Zone B

OCT General open CT alarm Zone B

TRCBF Zone B trip due to external trip from one of connected bays

TRDIFF Biased differential trip output Zone B

TREXTZ Zone B trip due to external input signal

TRIP Zone B general trip

TRSENS Sensitive differential function trip Zone B

BZNTPDIF_A Binary inputs ALDIFF_A Differential current alarm in phase A Zone A

ALDIFF_B Differential current alarm in phase B Zone A

ALDIFF_C Differential current alarm in phase C Zone A

OCT General open CT alarm Zone A

TRCBF Zone A trip due to external trip from one of connected bays

TRDIFF_A Biased differential trip phase A Zone A

TRDIFF_B Biased differential trip phase B Zone A

TRDIFF_C Biased differential trip phase C Zone A

TREXTZ Zone A trip due to external input signal

TRIP Zone A general trip

TRSENS_A Sensitive differential function trip phase A Zone A

TRSENS_B Sensitive differential function trip phase B Zone A

TRSENS_C Sensitive differential function trip phase C Zone A

BZNTPDIF_B Binary inputs ALDIFF_A Differential current alarm in phase A Zone B

ALDIFF_B Differential current alarm in phase B Zone B

ALDIFF_C Differential current alarm in phase C Zone B

OCT General open CT alarm Zone B

TRCBF Zone B trip due to external trip from one of connected bays

TRDIFF_A Biased differential trip phase A Zone B

TRDIFF_B Biased differential trip phase B Zone B

TRDIFF_C Biased differential trip phase C Zone B

TREXTZ Zone B trip due to external input signal

TRIP Zone B general trip

TRSENS_A Sensitive differential function trip phase A Zone B

TRSENS_B Sensitive differential function trip phase B Zone B

TRSENS_C Sensitive differential function trip phase C Zone B

CBPGAPC Binary inputs TRHOL Trip signal for harmonic over load

TRIP Common trip signal

TROC Trip signal for over current

TROCL1 Trip signal for over current of phase L1



TRQOL Trip signal for reactive power over load





TRUC Trip signal for undercurrent

TRUCL1 Trip signal for under current of phase L1



CCPDSC Binary inputs TRIP Trip signal to CB

CCRBRF Binary inputs CBALARM Alarm for faulty circuit breaker

TRBU Back-up trip by breaker failure protection function

TRBU2 Second back-up trip by breaker failure protection function

TRRET Retrip by breaker failure protection function

TRRET_A Retrip by breaker failure protection function phase A

TRRET_B Retrip by breaker failure protection function phase B

TRRET_C Retrip by breaker failure protection function phase C

CCRWRBRF Binary inputs CBALARM Alarm for faulty circuit breaker

TRBU Back-up trip by breaker failure protection function

TRRET Retrip by breaker failure protection function

CCSRBRF Binary inputs CBALARM Alarm for faulty circuit breaker

TRBU Back-up trip by breaker failure protection

TRBU2 Second back-up trip by breaker failure protection

TRRET Retrip by breaker failure protection

CCSSPVC Binary inputs FAIL Detection of current circuit failure

CMMXU Analog inputs IA Phase A current magnitude of reported value

IA_ANGL Phase A current magnitude angle

IB Phase B current magnitude of reported value

IB_ANGL Phase B current magnitude angle

IC* Phase C current magnitude of reported value

IC_ANGL* Phase C current magnitude angle

*Not valid for RER

CMSQI Analog inputs3I0 (not for RER)2I0 (only for RER)

3I0 magnitude of reported value2I0 Amplitude, magnitude of reported value

3I0ANGL (not for RER)2I0ANGL (only for RER)

3I0 Angle, magnitude of reported value2I0 Angle, magnitude of reported value

I1 I1 magnitude of reported value

I1ANGL I1 Angle, magnitude of reported value

I2* I2 Magnitude of reported value

I2ANGL* I2 Angle, magnitude of reported value

*Not valid for RER

COUVGAPC Binary inputs 59 Trip Common trip signal for compensated over voltage

59_Trip_A Trip signal for compensated over voltage of phase A

59_Trip_B Trip signal for compensated over voltage of phase B

59_Trip_C Trip signal for compensated over voltage of phase C

27 Trip Common trip signal for compensated under voltage

27_Trip_A Trip signal for compensated under voltage of phase A

27_Trip_B Trip signal for compensated under voltage of phase B

27_Trip_C Trip signal for compensated under voltage of phase C

CVGAPC Analog inputs CURRENT Measured current value

VOLTAGE Measured voltage value





Binary inputs TRIP Common trip signal

TROC1 Trip signal from overcurrent function OC1

TROC2 Trip signal from overcurrent function OC2

TROV1 Trip signal from overvoltage function OV1

TROV2 Trip signal from overvoltage function OV2

TRUC1 Trip signal from undercurrent function UC1

TRUC2 Trip signal from undercurrent function UC2

TRUV1 Trip signal from undervoltage function UV1

TRUV2 Trip signal from undervoltage function UV2

CVMMXN Analog inputs F System frequency magnitude of deadband value

I Calculated current magnitude of deadband value

P Active Power magnitude of deadband value

PF Power Factor magnitude of deadband value

Q Reactive Power magnitude of deadband value

S Apparent Power magnitude of deadband value

V Calculated voltage magnitude of deadband value

Binary inputs ILAG Current is lagging voltage

ILEAD Current is leading voltage

DNPFREC Analog inputs ActSetGrp Active setting group

Ch1Ang Prefault Angle

Ch1FltAng Fault Angle

Ch1FltMag Fault Magnitude

Ch1Mag Prefault Magnitude





























































































































Ch31TrigMag Magnitude at trig










FaultFreq Fault Freq

FaultLoc Fault Location

FaultNumber Fault Number

FaultType Fault Type

GetPrevRec Get previous disturbance





NoOfFaultIED No of faults in IED

TrigDay Trigger Day

TrigHour Trigger Hour

TrigMillisec Trigger Millisecond

TrigMin Trigger Minute

TrigMonth Trigger Month

TrigSec Trigger Second

TrigSigId Channel number for trig signal

TrigYear Trigger Year

Binary inputs GetFirstRec Get first disturbance

GetNextRec Get next disturbance

D2PTOC Binary inputs TRIP Common trip signal

TRSTP1 Trip signal from overcurrent function step1

TRSTP2 Trip signal from overcurrent function step 2

DPGAPC Double bit indications POSITION Double point indication

DRPRDRE Analog inputs FaultNumber Disturbance fault number

Binary inputs RECMADE Disturbance recording made

ECPSCH Binary inputs CS Pilot channel start signal

LCG Loss of channel guard signal output from communication scheme logic

PRORX Teleprotection permissive signal received from remote end

TRIP Trip signal by communication scheme logic

ECRWPSCH Binary inputs ECHO Permissive signal transmitted as echo signal or in case of weak end infeed

TRWEI Trip signal from weak end infeed logic

EF4PTOC Binary inputs PUFW Pick up foward direction

PUREV Pick up reverse direction

TRST1 Trip signal from step 1




TRIP General trip signal

TRSOTF Trip signal from switch onto fault function

EF2PTOC Binary inputs PUFW Pick up forward direction

PUREV Pick up reverse direction

TRIP Non-directional general trip

TRSOTF Trip signal from switch onto fault function

TRSTP1 Trip signal from step 1

TRSTP2 Trip signal from step 2

EFPIOC Binary input TRIP Trip signal

EFRWPIOC Binary input TRIP Trip signal

ETPMMTR Binary inputs EAFALM Alarm for active forward energy exceed limit in set interval

EARALM Alarm for active reverse energy exceed limit in set interval

ERFALM Alarm for reactive forward energy exceed limit in set interval





ERRALM Alarm for reactive reverse energy exceed limit in set interval

FDPSPDIS Binary inputs FWD_A Fault detected in phaseA - forward direction

FWD_B Fault detected in phase B - forward direction

FWD_C Fault detected in phase C - forward direction

FWD_G Ground fault detected in forward direction

NDIR_A Non directional fault detected in Phase A

NDIR_B Non directional fault detected in Phase B

NDIR_C Non directional fault detected in Phase C

NDIR_G Non directional phase-to-ground fault detected

REV_A Fault detected in phase A- reverse direction

REV_B Fault detected in phase B - reverse direction

REV_C Fault detected in phase C - reverse direction

REV_G Ground fault detected in reverse direction

TRIP Trip by pilot communication scheme logic

FMPSPDIS Binary inputs PICKUP Indicates that something has picked up

PU_A Fault detected in phase A

PU_B Fault detected in phase B

PU_C Fault detected in phase C

PHG_FLT Ground fault detected

FRPSPDIS Binary inputs FWD_A Fault detected in phaseA - forward direction

FWD_B Fault detected in phase B - forward direction

FWD_C Fault detected in phase C - forward direction

FWD_G Ground fault detected in forward direction

NDIR_A Non directional fault detected in Phase A

NDIR_B Non directional fault detected in Phase B

NDIR_C Non directional fault detected in Phase C

NDIR_G Non directional phase-to-ground fault detected

REV_A Fault detected in phase A- reverse direction

REV_B Fault detected in phase B - reverse direction

REV_C Fault detected in phase C - reverse direction

REV_G Ground fault detected in reverse direction


FTAQFVR Analog inputs ACCTIME Accumulated time for frequency band limits

Binary inputs ACCALARM Alarm signal for reaching the frequency time accumulation value

TRIP Trip signal of the function

FUFSPVC Binary inputs BLKV General pickup

STDUDIL1 Start of change based function in phase L1



FRWSPVC Binary inputs BLKV General pickup

PU_DV_A Pick up on sudden change in phase voltage A

PU_DV_AB Pick up on sudden change in phase to phase voltage

PU_DV_B Pick up on sudden change in phase voltage B

GENPDIF Binary inputs BLKH Common harmonic block signal

OPENCTAL Open CT Alarm output signal. Issued after a delay ...





TRIP General, common trip signal

TRIPRES Trip signal from restrained differential protection

TRIPUNRE Trip signal from unrestrained differential protection

TRNSSENS Trip signal from sensitive negative sequence differential protection

TRNSUNR Trip signal from unrestrained negative sequence differential protection

GENPDIF Binary inputs INTDIST Indication that internal fault has been detected

GOPPDOP Binary inputs TRIP Common trip signal

TRIP1 Trip of stage 1


GRPTTR Binary inputs LOCKOUT Trip lockout output (latched)

TRIP General trip signal from the function

GSPTTR Binary inputs LOCKOUT Trip lockout output (latched)

TRIP General trip signal from the function

GUPPDUP Binary inputs TRIP Common trip signal



HZPDIF Binary inputs TRIP Trip signal

INTERRSIG Analog inputs FAIL Internal fail

Binary inputs TSYNCERR Time synchronization error

WARNING Internal warning

L3CPDIF Binary inputs BLK2H Block signal due to second harmonic

BLK5H Block signal due to fifth harmonic

INTFAULT Internal fault has been detected


PickupENH pickup of enhanced differential protection

PickupRES Pick up of restrained differential protection

PickupUNR Pick up of Unrestrained differential protection

TRIP Main Trip Signal

TR_A Trip signal from phase A

TR_B Trip signal from phase B

TR_C Trip signal from phase C

L4CPDIF Binary inputs OPENCT An open CT was detected

PU_UNR Pick up of Unrestrained differential protection

TRIP Common, main, trip output signal




L4UFCNT Binary inputs LIMIT1 Counted value is larger than or equal to CounterLimit1

LIMIT2 Counted value is larger than or equal to CounterLimit2







Counters VALUE Counted value

L6CPDIF Binary inputs BLK2H Block signal due to second harmonic











LAPPGAPC Binary inputs TRLAP Trip low active power

TRLPF Trip low power factor

TRTPFA Trip low power factor phase A

TRLPFB Trip low power factor Phase B

TRLPFC Trip low power factor Phase C

LCCRPTRC Binary inputs TRIP Common trip

TR_A Trip Phase A

TR_B Trip phase B

TR_C Trip Phase C

LCNSPTOC Binary input TRIP Trip signal negative sequence over current protection

LCNSPTOV Binary input TRIP Trip signal for negative sequence over voltage

LCP3PTOC Binary inputs TRIP Common trip signal




LCP3PTUC Binary inputs TRIP Common trip signal




LCPTTR Binary inputs ALARM Alarm signal

LOCKOUT Lockout signal

TRIP Trip

LCZSPTOC Binary inputs TRIP Trip signal for zero sequence over current protection

LCZSPTOV Binary inputs TRIP TRIP signal for zero sequence over voltage protection

LDLPSCH Binary inputs DIFLBLKD Local line differential function blocked

TRIP General trip from differential protection system








LDRGFC Binary inputs BFI_3P Pick Up

LEXPDIS Binary inputs TRIP Common trip signal

TRZ1 Trip signal from impedance zone Z1

TRZ2 Trip signal from impedance zone Z2

LFPTTR Binary inputs ALARM Alarm signal


TRIP Trip

LMBRFLO Analog input FLT_DIST Distance to fault in line length unit

LOLSPTR Analog input AGERATE Insulation ageing rate

Binary inputs ALARM1 Hot spot temperature level 1 alarm signal

ALARM2 Hot spot temperature level 2 alarm signal

Analog inputs HPTEMPMAX Maximum hot spot temperature

PLOLTOT Total percent loss of life

REMLIFE Transformer remaining life in hours

TOTCALC Calculated transformer top oil temperature

Binary input WARNING2 Hot spot temperature level 2 warning signal

LOVPTUV Binary input TRIP Trip signal

LT3CPDIF Binary inputs BLK2H Block signal due to second harmonic











LT6CPDIF Binary inputs BLK2H Block signal due to second harmonic











NS2PTOC Binary inputs ALARM Alarm signal








NS4PTOC Binary inputs PUFW Forward directional pickup signal

PUREV Reverse directional pickup signal





TRIP General trip signal

OC4PTOC Binary inputs TRST1 Common trip signal from step1

TRST1_A Trip signal from step1 phase A

TRST1_B Trip signal from step1 phase B

TRST1_C Trip signal from step1 phase C

TRST2 Common trip signal from step2












TRIP Trip




OEXPVPH Analog inputs VPERHZ Voltage to frequency ratio in per-unit

Binary inputs ALARM Overexcitation above set alarm pickup (delayed)

TRIP Trip from overexcitation function

OOSPPAM Binary inputs TRIP Common trip, issued when either zone 1 or zone 2 trip

OV2PTOV Binary inputs TRST1 Common trip signal from step1








TRIP Trip

O2RWPTOV Binary input TRIP Common trip signal

PAPGAPC Binary inputs ARST Start signal to the autorecloser function

TRINP_3P Trip caused by residual current detection

TRIP General trip

TR_A Trip phase A





TR_B Trip phase B

TR_C Trip phase C

PCFCNT Analog inputs SCAL_VAL Scaled value with time and status information

Counters CNT_VAL Actual pulse counter value

PH4SPTOC Binary inputs TRST1 Common trip signal from step1




TRIP Trip

PHPIOC Binary inputs TRIP Trip signal from any phase



TR_C* Trip signal from phase C

*Not valid for RER

PMUSTATUS Analog inputs PMUInst1 PMU instance 1 status

PMUInst2 PMU instance 2 status

Binary inputs TCPConnStatus1 TCP connection 1 status

TCPConnStatus2 TCP connection 2 status







Analog inputs UDPStreamStat1 UDP data stream status

UDPStreamStat2

UDPStreamStat3

UDPStreamStat4

UDPStreamStat5

UDPStreamStat6

PSLPSCH Binary inputs CS Carrier send signal controlled by the power swing

TRIP Trip through Power Swing Logic

PSPPPAM Analog inputs SFREQ Slip frequency

Binary inputs GEN Generator is faster than the system

MOTOR Generator is slower than the system


TRIP1 Trip1 after the N1Limit slip in zone1

TRIP2 Trip2 after the N2Limit slip in zone2

QCBAY Binary inputs CMD_BLKD Function is blocked for commands

LOC Local operation allowed

REM Remote operation allowed

UPD_BLKD Update of position is blocked

REFPDIF Binary inputs BLK2H Block due to 2-nd harmonic

DIR_INT Directional Criteria satisfied for internal fault

TRIP Trip by restricted earth fault protection function





ROTIPHIZ Binary inputs ALARM Alarm

ERROR Error

ERRSTAT Error indication

TRIP Trip (common AC and DC side of exciter)

TRIPAC Trip for AC side of exciter

TRIPDC Trip for DC side of exciter

ROV2PTOV Binary inputs TRST1 Common trip signal from step1


TRIP Trip

RWRFLO Analog input FLT_DIST Distance to fault in line length unit

SAPFRC Binary inputs BLKDMAGN Blocking indication due to low magnitude

TRIP Operate/trip signal for frequency gradient

SAPTOF Binary inputs BLKDMAGN Measurement blocked due to low amplitude


SAPTUF Binary inputs BLKDMAGN Measurement blocked due to low voltage amplitude


SCCVPTOC Binary inputs TRIP Common trip signal

SCILO Binary inputs EN_CLOSE Close operation at open or intermediate or bad position is enabled

EN_OPEN Open operation at closed or intermediate or bad position is enabled

SCSWI Double bit indications POSITION Position indication

Analog inputs L_CAUSE Latest value of the error indication during command

Binary inputs CMD_BLK Commands are blocked

Binary outputs CLOSE_CMD Close command parameter for DNP protocol

OPEN_CMD Open command parameter for DNP protocol

SDEPSDE Binary inputs TRDIRIN Trip of the directional residual over current function

TRIP General trip of the function

TRNDIN Trip of non directional residual over current

TRVN Trip of non directional residual over voltage

SECALARM Analog inputs EVENTID EventId of the generated security event

SEQNUMBER Sequence number of the generated security event

SESRSYN Analog inputs FRDIFFME Calculated difference of frequency

PHDIFFME Calculated difference of phase angle

VDIFFME Calculated difference of voltage in p.u of set voltage base value

Binary inputs AUTOENOK Automatic energizing check OK

B1SEL Bus1 selected

B2SEL Bus2 selected

L1SEL Line1 selected

L2SEL Line2 selected

MANENOK Manual energizing check OK

SYNFAIL Synchronizing failed





SYNOK Synchronizing OK output

SYNPROGR Synchronizing in progress

AUTOREL Automatic release

MANREL Manual release

SLGAPC Analog inputs SWPOSN Switch position (integer)


Binary outputs OPEN_CMD Open command parameter for DNP protocol

SMBI Binary inputs BI1 Binary input 1

BI2 Binary input 2

BI3 Binary input 3

BI4 Binary input 4

BI5 Binary input 5

BI6 Binary input 6

BI7 Binary input 7

BI8 Binary input 8

BI9 Binary input 9


SMBO Binary inputs BO1 SMT Connect output

BO2 SMT Connect output









SMBRREC Binary inputs 1PT1 Single-phase reclosing is in progress, shot 1

2PT1 Two-phase reclosing is in progress, shot 1

3PT1 Three-phase reclosing in progress, shot 1





ACTIVE Reclosing sequence in progress

BLOCKED The AR is in blocked state

CLOSECMD Closing command for CB

READY Indicates that the AR function is ready for a new sequence

SETON The AR operation is switched on, operative

UNSUCCL Reclosing unsuccessful, signal resets after the reclaim time

Counters COUNT1P Counting the number of single-phase reclosing shots

COUNT2P Counting the number of two-phase reclosing shots

COUNT3P1 Counting the number of three-phase reclosing shot 1









COUNTAR Counting total number of reclosing shots

RER signals:

Binary inputs ACTIVE Reclosing sequence in progress

BLOCKED AR is blocked

CLOSECB Close command for circuit breaker

IPT1 Reclosing in progress for shot 1





READY AR is ready for a new sequence

SETON AR is operative

UNSUCCL Reclosing is unsuccessful

Counters COUNTAR Number of total reclosing shots

COUNTT1 Number of shot 1 reclosings





SMPPTRC Binary inputs CLLKOUT Circuit breaker lockout output (set until reset)

TR1P* Tripping single-pole

TR2P* Tripping two-pole

TR3P* Tripping three-pole

TRIP General trip output signal

TR_A* Trip signal from phase A

TR_B* Trip signal from phase B

TR_C* Trip signal from phase C

*Not valid for RER

SSCBR Binary inputs CBLIFEAL Remaining life of CB reduced to Life alarm level

GPRESALM Pressure below alarm level

GPRESLO Pressure below lockout level

SPCHALM Spring charging time has crossed the set value

Counter NOOPER Number of CB operation cycle

SSIMG Binary inputs PRES_ALM Pressure below alarm level

PRES_LO Pressure below lockout level

TEMP_ALM Temperature above alarm level

TEMP_LO Temperature above lockout level

SSIML Binary inputs LVL_ALM Level below alarm level

LVL_LO Level below lockout level

TEMP_ALM Temperature above alarm level

TEMP_LO Temperature above lockout level

STBPTOC Binary inputs TRIP Trip

TRL1 Trip signal from phase L1



STEFPHIZ Binary inputs TRIP Main, common trip command

TRIP3H Trip by one of two 3rd harmonic voltage-based prot.





TRIP_VN Trip by fund. freq. neutral over-voltage protection

STTIPHIZ Binary inputs ALARM Alarm

ERROR Error

OPCIRC Injection circuit open

TRIP Trip

Analog input ERRSTAT Error indication

SXCBR Analog input EEHEALTH External equipment health. 1=No warning or alarm, 2=Warning, 3=Alarm

Binary inputs CLOSEPOS Apparatus closed position

OPENPOS Apparatus open position

UPD_BLKD Update of position indication is blocked

Counter CNT_VAL Operation counter value

Double bit indications POSITION Apparatus position indication

TR_POS Truck position indication

SXSWI Analog input EEHEALTH External equipment health. 1=No warning or alarm, 2=Warning, 3=Alarm

Binary inputs CLOSEPOS Apparatus closed position

OPENPOS Apparatus open position

UPD_BLKD Update of position indication is blocked

Counter CNT_VAL Operation counter value

Double bit indications POSITION Apparatus position indication

T1PPDIF Binary inputs IDALARM Alarm for sustained diff current

PU2NDHARM Second harmonic detected

ST5THHRM Fifth harmonic detected

TRDRSEN Trip signal from sensitive directional diff. protection

TRDRUNR Trip signal from unrestrained directional diff. protection


TRRES Trip signal from restrained differential protection

TRUNRES Trip signal from unrestrained differential protection

T2WPDIF Binary inputs BLK2H Common second harmonic block signal from any phase

BLK5H Common fifth harmonic block signal from any phase


INTFAULT Indication that internal fault has been detected






T3WPDIF Binary inputs BLK2H Common second harmonic block signal from any phase

BLK5H Common fifth harmonic block signal from any phase

INTFAULT Indication that internal fault has been detected











TCLYLTC Analog input TCPOS Integer value corresponding to actual tap position

Binary inputs HIPOSAL Alarm for tap in highest volt position

LOPOSAL Alarm for tap in lowest volt position

POSERRAL Alarm that indicates a problem with the position indication

Counter CNT_VAL Number of operations on tap changer

TCMYLTC Analog input TCPOS Integer value corresponding to actual tap position

Binary inputs HIPOSAL Alarm for tap in highest volt position

LOPOSAL Alarm for tap in lowest volt position

POSERRAL Alarm that indicates a problem with the position indication

Counter CNT_VAL Number of operations on tap changer

TEIGAPC Binary inputs ALARM Indicator of the integrated time has reached the alarm limit

WARNING Indicator of the integrated time has reached the warning limit

TEILGAPC Binary inputs ALARM Indicator that accumulated time has reached alarm limit

Analog inputs ACC_DAY Accumulated time in days

ACC_HOUR Accumulated time in hours

Binary inputs OVERFLOW Indicator that accumulated time has reached overflow limit

WARNING Indicator that accumulated time has reached warning limit

TESTMODE Binary inputs BLOCK Active when LD0 is blocked or test blocked

IED_TEST IED test mode is active

TEST In test via IED TEST or via LD0 Mode

TFMGAPC Binary inputs ALARM General fault detection alarm

REPMADE Report is ready for file transfer

TFCNT

I2TALM General fault (I^2)t alarm for an event

CMLI2TALM

TMAGAPC Binary inputs OUTPUT1 OR function betweeen inputs 1 to 16

OUTPUT2 OR function between inputs 17 to 32

OUTPUT3 OR function between inputs 1 to 32

TPPIOC Binary input TRIP Trip signal

TR1ATCC Analog inputs BUSVOLT The average of the measured busbar voltage (service value)

ILOAD Magnitude of measured load current (service value)

TCPOS Tap position

VLOAD Calculated compensated voltage (service value)

Binary inputs AUTO Automatic control mode is active

AUTOBLK Block of auto commands

MAN The control is in manual mode

TOTBLK Block of auto and manual commands

TR8ATCC Analog inputs BUSVOLT The average of the measured busbar voltage (service value)

ICIRCUL Circulating current

ILOAD Magnitude of measured load current (service value)

TCPOS Tap position

VLOAD Calculated compensated voltage (service value)

Binary inputs AUTO Automatic control mode is active





AUTOBLK Block of auto commands

COMMERR Communication error

DISCONN The transformer is disconnected

FOLLOWER This transformer is a follower

MAN The control is in manual mode

MASTER The transformer is master

OUTOFPOS To high difference in tap positions

PARALLEL The transformer operates in parallel mode

SINGLE The transformer operates in single mode

TOTBLK Block of auto and manual commands

MSTRSLV Master slave is active

TRPTTR Binary inputs ALARM1 First level alarm signal

ALARM2 Second level alarm signal


TRIP Trip Signal

UV2PTUV Binary inputs TRST1 Common trip signal from step1








TRIP Trip

U2RWPTUV Binary input TRIP Common trip signal

VDCPTOV Binary inputs TRIP Voltage differential protection operated

VDSPVC Binary inputs MAINFUF Block of main fuse failure

V1AFAIL Fuse failure of Main fuse group phase A

V1BFAIL Fuse failure of Main fuse group phase B

V1CFAIL Fuse failure of Main fuse group phase C

VMMXU Analog inputs VAB VAB Reported magnitude value

VAB_ANGL VAB Angle, magnitude of reported value

VBC* VBC Reported magnitude value

VBC_ANGL* VBC Angle, magnitude of reported value

VCA* VCA Reported magnitude value

VCA_ANGL* VCA Angle, magnitude of reported value

*Not valid for RER

VMSQI Analog inputs3V0 (not for RER)2V0 (only for RER)

3V0 Reported magnitude value2V0 Amplitude, magnitude of reported value

3V0ANGL (not for RER)2V0ANGL (only for RER)

3V0 Magnitude angle2V0 Angle, magnitude of reported value

V1 V1 Reported magnitude value

V1ANGL V1 Magnitude angle

V2* V2 Reported magnitude value

V2ANGL* V2 Magnitude angle

*Not valid for RER

VNMMXU Analog inputs VA VA Amplitude, magnitude of reported value





VA_ANGL VA Angle, magnitude of reported value

VB VB Amplitude, magnitude of reported value

VB_ANGL VB Angle, magnitude of reported value

VC* VC Amplitude, magnitude of reported value

VC_ANGL* V_C Angle, magnitude of reported value

*Not valid for RER

VRPVOC Binary inputs TRIP Common trip signal

TROC Trip signal from voltage restrained overcurrent stage

27 Trip Trip signal from undervoltage function

VSGAPC Binary inputs POS1 Position 1 indication, logical signal

POS2 Position 2 indication, logical signal

Double bit indications POSITION Position indication, integer


OPEN_CMD Open command parameter for DNP protocol

ZC1PPSCH Binary inputs GENERAL Logical OR of carrier Send signal from all the three phases

PRORX Carrier signal received or missing carrier guard signal

TRIP Common trip output in any of the phase

TR_A Trip output in Phase A

TR_B Trip output in Phase B

TR_C Trip output in Phase C

ZC1WPSCH Binary inputs ECHO Carrier Send by WEI logic

PRORX Teleprotection signal received for a fault detected in forward direction

TRPWEI Trip of WEI logic

TRPWEI_A Trip of WEI logic in Phase A

TRPWEI_B Trip of WEI logic in Phase B

TRPWEI_C Trip of WEI logic in Phase C

ZCLCPSCH Binary inputs TRLL Trip by loss of load

TRZE Trip by zone extension

ZCPSCH Binary inputs CS Pilot channel start signal

LCG Loss of channel guard signal output from communication scheme logic

PRORX Teleprotection permissive signal received from remote end


ZCRWPSCH Binary inputs ECHO A signal that indicates channel start (CS) by WEI logic

TRWEI Trip signal from weak end infeed logic

TRWEI_A Trip signal from weak end infeed logic in phase A

TRWEI_B Trip signal from weak end infeed logic in phase B

TRWEI_C* Trip signal from weak end infeed logic in phase C

*Not valid for RER

ZCVPSOF Binary inputs TRIP Trip by pilot communication scheme logic

ZDARDIR Binary inputs FWD_G Forward start signal from phase-to-ground directional element

REV_G Reverse start signal from phase-to-ground directional element

ZGTPDIS Binary inputs TRIP Common trip signal

TRZ1 Trip signal zone 1







ZGVPDIS Binary inputs TRIP General Trip

27 Trip Trip from Under voltage seal in

TRZ1 Trip signal Zone 1



ZMCAPDIS Binary inputs TRIP General Trip, issued from any phase or loop




ZMCPDIS Binary inputs TRIP General Trip, issued from any phase or loop




ZMFCPDIS Binary inputs TRIP Trip in any phase or phases from any zone or zones

TRZ1 Trip in any phase or phases from zone 1 - forward direction


TRZ3 Trip in any phase or phases from zone 3 - zone direction



TRZRV Trip in any phase or phases from zone RV - reverse dir.

ZMFPDIS Binary inputs TRIP Trip in any phase or phases from any zone or zones






TRZRV Trip in any phase or phases from zone RV - reverse dir.

ZMHPDIS Binary inputs TRIP Trip General

TR_A Trip phase A

TR_B Trip phase B

TR_C Trip phase C

TRPG Trip phase-to-ground

TRPP Trip phase-to-phase

ZMMAPDIS Binary inputs TRIP General Trip, issued from any phase or loop




ZMMPDIS Binary inputs TRIP General Trip, issued from any phase or loop




ZMQAPDIS Binary inputs TRIP General Trip, issued from any phase or loop








ZMQPDIS Binary inputs TRIP General Trip, issued from any phase or loop




ZMRAPDIS Binary inputs TRIP General Trip, issued from any phase or loop




ZMRPDIS Binary inputs TRIP General Trip, issued from any phase or loop




ZMRPSB Binary inputs PICKUP Power swing detected

ZSMGAPC Binary inputs BLKCHST Blocking signal to remote end to block overreaching zone

BLKZMTD Block signal for blocking of time domain high speed mho

CHSTOP Stops the blocking signal to remote end

HSIR Indication of source impedance ratio above set limit



Section 3 DNP3 protocol implementation

3.1 DNP3 device profileGUID-842FB3DD-B5E2-4E8A-B617-C9D6A8BDD6D1 v3

The following table provides a device profile document in the standard format defined in the DNP3Subset Definitions Document. While it is referred to in the DNP3 Subset Definitions as a document,it is in fact a table, and only a component of a total interoperability guide. The table, incombination with the Implementation table and the point list tables, provides a completeconfiguration/interoperability guide for communicating with a device.

When going down in baudrate, the size of the configuration on DNP must beconsidered.

DNP3 device profile document:

Table 2: Device identification

1.1 Device identification Capabilities Current value If configurable, listmethods

1.1.1 Device function Outstation Outstation

1.1.2 Vendor name ABB AB

1.1.3 Device name 670 series

1.1.4 Devicemanufacturer'shardware version

2.1

1.1.5 Devicemanufacturer'ssoftware version

2.1

1.1.6 Device profiledocument version(revision)

Refer to theDocument revisionhistory table

1.1.7 DNP levelssupported for

Outstations only requests and responses:

○ None

● Level 1

● Level 2

○ Level 3

○ Level 4


1MRK511354-UUS A Section 3DNP3 protocol implementation



1.1.8 Supportedfunction blocks

PST or LHMI

● Self Address Reservation

○ Data Sets

○ File Transfer

○ Virtual Terminal

○ Mapping to IEC 61850 Object Models defined in a DNP3XML file

○ Function code 31, activate configuration (if checked, see1.12)

○ Authentication (if checked, see 1.12)

1.1.9 Notable additions

1.1.10 Methods to setconfigurableparameters

Software or direct PST, CMT, or LHMI

○ XML - Loaded through DNP3 File Transfer

○ XML - Loaded through other transport mechanism

○ Terminal - ASCII terminal command line

○ Software - Vendor software named

○ Proprietary file loaded through DNP3 file transfer

● Proprietary file loaded through other transportmechanism

○ Direct - Keypad on device front pane

○ Factory - Specified when device is ordered

○ Protocol - Set via DNP3 (for example assign class)

○ Other - explain

1.1.11 DNP3 XML filesavailable on-line

Rd Wr Filename Description of contents Not supported

○ dnpDp.xml Complete device profile

○ dnpDPCap.xml Device profile capabilities

○ dnpDPCfg.xml Device profile configvalues

○ ○ _____*.xml

* The Complete Device Profile Document contains thecapabilities, Current Value, and configurablemethods columns.

* The Device Profile Capabilities contains only thecapabilities and configurable methods columns.

* The Device Profile Config. Values contains only theCurrent Value column.


Section 3 1MRK511354-UUS ADNP3 protocol implementation



1.1.12 DNP3 XML filesavailable off-line

Rd Wr Filename Description of contents Not supported

○ ● dnpDp.xml Complete device profile

○ ○ dnpDPCap.xml Device profile capabilities

○ ○ dnpDPCfg.xml Device profile configvalues

* The Complete Device Profile Document contains thecapabilities, Current Value, and configurablemethods columns.

* The Device Profile Capabilities contains only thecapabilities and configurable methods columns.

* The Device Profile Config. Values contains only theCurrent Value column.

1.1.13 Connectionssupported

● Serial (complete section 1.2) Serial IP networking PST of LHMI

● IP networking (complete section 1.3)

○ Other, explain:

1.1.14 ConformanceTesting

○ Self-tested, version ________

● Independently tested, version

Version 2.6 rev1 28th October 2010

Test organisation name

DNV GL

Table 3: Serial connections

1.2a Serial connections Capabilities Current value If configurable, listmethods

1.2.1 Port name: Nameused to reference thecommunication portdefined in this section

RS485 PST of LHMI

1.2.2 Serial connectionparameters

Asynchronous PST of LHMI

● Asynchronous - Data Bits, Start Bit, Stop Bit, Parity

○ Other, explain:

1.2.3 Baud rate ○ Fixed at 9600 PST of LHMI(BaudRate)

● Configurable, range 300 to 115200

○ Configurable, selectable from _____,_____,_____

○ Configurable, other, describe:

1.2.4 Hardware flow control (Handshaking): Describe hardware signaling requirements of the interface. Where a transmitter orreceiver is inhibited until a given control signal is asserted, it is considered to require that signal before sending or receivingcharacters. Where a signal is asserted before 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 None PST of LHMI(tRxToTxMinDel)

○RS-485 options:

● Requires Rx inactive before Tx

○ Other, explain:

1.2.5 Interval to request link status. Indicates how often to send Data Link Layer status requests on a serial connection. Thisparameter is separate from the TCP Keep-alive timer.

● Not Supported Not supported

○ Fixed at _____ seconds

○ Configurable, range ___ to ___ seconds

○ Configurable, selectable from ___,___,___ seconds


1.2.6 Supports DNP3 collision avoidance: Indicates whether an Outstation uses a collision avoidance algorithm. Collision avoidancemay be implemented by a back-off timer with two parameters that define the back-off time range or by some other vendor-specificmechanism. The recommended back-off time is specified as being a fixed minimum delay plus a random delay, where the randomdelay has a maximum value specified. This defines a range of delay times that are randomly distributed between the minimum valueand the minimum plus the maximum of the random value. If a back-off timer is implemented with only a fixed or only a random value,select the Back-off time method and set the parameter that is not supported to “Fixed at 0 ms”.

○ No Yes PST or LHMI(tBackOffDelay andtMaxRndDelBkOf)● Yes, using Back-off time = (Min + Random) method

Minimum Back-off time:

○ Fixed at_________ms

● Configurable, range 0 to 60000 ms

○ Configurable, selectable from __,__,__ ms


Maximum Random Back-off time component:

○ Fixed at_________ms




○ Other, explain ________________________

1.2.7 Receiver Inter-character time-out: When serial interfaces with asynchronous character framing are used, this parameterindicates if the receiver makes a check for gaps between characters, that is, extensions of the stop bit time of one character prior tothe start bit of the following character within a message). If the receiver performs this check and the time-out is exceeded, then thereceiver discards the current data link frame. A receiver that does not discard data link frames on the basis of inter-character gaps isconsidered not to perform this check. Where no asynchronous serial interface is fitted this parameter is not applicable. In this case,none of the options shall be selected.





● Not Checked Not checked

○ No gap permitted

○ Fixed at _____ bit times

○ Fixed at _____ ms

○ Configurable, range ____ to ____ bit times

○ Configurable, range ____ to ____ ms

○ Configurable, Selectable from ___,___,___bit times

○ Configurable, Selectable from ____, ____, ____ ms


○ Variable, explain ____

1.2.8 Inter-character gaps in transmission: When serial interfaces with asynchronous character framing are used, this parameterindicates whether extra delay is ever introduced between characters in the message, and if so, the maximum width of the gap. Whereno asynchronous serial interface is fitted this parameter is not applicable. In this case none of the options shall be selected.

● None (always transmits with no inter-character gap) None

○ Maximum _____ bit times

○ Maximum _____ ms

Table 4: Serial connections

1.2b Serialconnections

Capabilities Currentvalue

Ifconfigurable,list methods

1.2.1 Portname: Nameused toreferencethecommunication portdefined inthis section

Optical PST of LIMO

1.2.2 Serialconnectionparameters

● Asynchronous - 8 Data Bits, 1 Start Bit, 1 Stop Bit, No Parity Asynchronous

PST of LHMI

○ Other, explain:

1.2.3 Baudrate

○ Fixed at 9600 PST of LHMI(BaudRate)


○ Configurable, selectable from ____,____,____


1.2.4 Hardware flow control (Handshaking): Describe hardware signaling requirements of the interface. Where a transmitter orreceiver is inhibited until a given control signal is asserted, it is considered to require that signal before sending or receivingcharacters. Where a signal is asserted before 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 None PST or LHMI(tRxToTxMinDel)RS–485 Options:

● Requires Rx inactive before Tx

○ Other, explain:

1.2.5 Interval to request link status: Indicates how often to send Data Link Layer status requests on a serial connection. Thisparameter is separate from the TCP Keep-alive timer.

● Not Supported Notsupported

○ Fixed at_________ seconds

○ Configurable, range _____ to ______ seconds

○ Configurable, selectable from __,__,__ seconds


1.2.6 Supports DNP3 collision avoidance: Indicates whether an Outstation uses a collision avoidance algorithm. Collision avoidancemay be implemented by a back-off timer with two parameters that define the back-off time range or by some other vendor-specificmechanism. The recommended back-off time is specified as being a fixed minimum delay plus a random delay, where the randomdelay has a maximum value specified. This defines a range of delay times that are randomly distributed between the minimum valueand the minimum plus the maximum of the random value. If a back-off timer is implemented with only a fixed or only a random value,select the Back-off time method and set the parameter that is not supported to “Fixed at 0 ms”.

● No No

○ Yes, using Back-off time = (Min + Random) method

Minimum Back-off time:

○ Fixed at_________ ms

○ Configurable, range 0 to 60000 ms



Maximum Random Back-off time component:

○ Fixed at_________ ms

○ Configurable, range 0 to 60000 ms



○ Other, explain:

1.2.7 Receiver Inter-character time-out: When serial interfaces with asynchronous character framing are used, this parameterindicates if the receiver makes a check for gaps between characters, that is, extensions of the stop bit time of one character prior tothe start bit of the following character within a message). If the receiver performs this check and the time-out is exceeded then thereceiver discards the current data link frame. A receiver that does not discard data link frames on the basis of inter-character gaps isconsidered not to perform this check. Where no asynchronous serial interface is fitted this parameter is not applicable. In this case,none of the options shall be selected.







● Not checked Notchecked

○ No gap permitted

○ Fixed at bit times

○ Fixed at ms

○ Configurable, range ___ to ___ bit times

○ Configurable, range ____ to ____ ms

○ Configurable, Selectable from ___,___,___bit times

○ Configurable, Selectable from _ _ _ ms


○ Variable, explain:

1.2.8 Inter-character gaps in transmission: When serial interfaces with asynchronous character framing are used, this parameterindicates whether extra delay is ever introduced between characters in the message, and if so, the maximum width of the gap. Whereno asynchronous serial interface is fitted, this parameter is not applicable. In this case, none of the options shall be selected

● None (always transmits with no inter-character gap) None

○ Maximum _____ bit times

○ Maximum _____ ms

Table 5: IP networking

1.3 IP networking Capabilities Current value If configurable, listmethods

1.3.1 Port Name: nameused to reference thecommunications portdefined in this section

Both back-ports

1.3.2 Type of end point:

○ TCP Initiating (Master Only) TCP listening

● TCP Listening (Outstation Only)

○ TCP Dual (required for Masters)

● UDP Datagram (required)

1.3.3 IP address of thisdevice:

*.*.*.* PST or LHMI

1.3.4 Subnet mask: *.*.*.* PST or LHMI

1.3.5 Gateway IPaddress:

*.*.*.* PST or LHMI

1.3.6 Accepts TCP connections or UDP datagrams from:





● Allows all (show as *.*.*.* in 1.3.7) Specified IP-Address

● Limits based on IP address

○ Limits based on list of IP addresses

● Limits based on a wildcard IP address

○ Limits based on list of wildcard IP addresses

○ Other validation, explain:

1.3.7 IP address(es)from which TCPconnections or UDPdatagrams areaccepted:

*.*.*.* PST or LHMI(MasterIP-Addr)

1.3.8 TCP listen port number: If Outstation or dual end point Master, port number on which to listen for incoming TCP connectrequests. Required to be configurable for Masters and recommended to be configurable for Outstations.

○ Not Applicable (Master w/o dual end point) 20000 PST or LHMI(TCPIPLisPort)

○ Fixed at 20,000




1.3.9 TCP listen port number of remote device: If Master or dual end point Outstation, port number on remote device with which toinitiate connection. Required to be configurable for Masters and recommended to be configurable for Outstations.

● Not Applicable (Outstation w/o dual end point)

○ Fixed at 20,000

○ Configurable, range _______ to _______



1.3.10 TCP keep-alive timer: The time period for the keep-alive timer on active TCP connections.

○ Fixed at ___________ms 10 seconds PST or LHMI(tKeepAliveT)

● Configurable, range 1 to 3600 s

○ Configurable, selectable from ___,___,___ms


1.3.11 Local UDP port: Local UDP port for sending and/or receiving UDP datagrams. Masters may let system choose an available port.Outstations must use one that is known by the Master.

● Fixed at 20,000 20000 PST or LHMI(UDPPortAccData)




○ Let system choose (Master only)

1.3.12 Destination UDP port for DNP3 requests (Master Only):





○ Fixed at 20,000

○ Configurable, range _______ to _______



1.3.13 Destination UDP port for initial unsolicited null responses (UDP only Outstations): For a UDP only Outstation, the destinationUDP port for sending initial unsolicited Null response.

○ None 20000 PST or LHMI(UDPPortAccData)

○ Fixed at 20,000




1.3.14 Destination UDP port for responses (UDP only Outstations): For a UDP only Outstation, the destination UDP port for sendingall responses other than the initial unsolicited Null response.

○ None 0 PST or LHMI(UDPPortCliMast)

○ Fixed at 20,000



● Configurable, other, describe: If set to 0 the receivingUDP port number will be used.

○ Use source port number

1.3.15 Multiple outstation connections (Masters only): Indicates whether multiple outstation connections are supported.

○ Supports multiple outstations (Masters only)

1.3.16 Multiple master connections (Outstations only): Outstations only. Indicates whether multiple master connections aresupported and the method that can be used to establish connections.

● Supports multiple masters (Outstations only) Ifsupported, the following methods may be used:

Combination ofMethod 1 andMethod 2

PST or LHMI(MasterIP-Addr andTCPIPLisPort)

● Method 1 (based on IP address) - required

● Method 2 (based on IP port number) - recommended

○ Method 3 (browsing for static data) - optional

1.3.17 Time synchronization support:

● DNP3 LAN procedure (function code 24) LAN procedure

● DNP3 Write Time (not recommended over LAN)

○ Other, explain:

○ Not Supported



Table 6: Link layer

1.4 Link layer Capabilities Current value If configurable, listmethods

1.4.1 Data Link Address: Indicates if the link address is configurable over the entire valid range of 0 to 65,519. Data link addresses0xFFF0 through 0xFFFF are reserved for broadcast or other special purposes.

○ Fixed at______ 1 PST or LHMI(SlaveAddress)


○ Configurable, selectable from____,____,____


1.4.2 DNP3 Source address validation: Indicates whether the Outstation will filter out requests not from a specific source address.

● Never Always PST or LHMI(ValMasterAddress)

● Always, one address allowed (shown in1.4.3)

○ Always, any one of multiple addressesallowed (each selectable as shown in 1.4.3)

○ Sometimes, explain:

1.4.3 DNP3 source address(es) expected when validation is enabled: Selects the allowed source address(es).

○ Configurable to any 16 bit DNP Data LinkAddress value

1 PST or LHMI(MasterAddress)




1.4.4 Self Address Support using address 0xFFFC: If an Outstation receives a message with a destination address of 0xFFFC it shallrespond normally with its own source address. It must be possible to disable this feature if supported.

● Yes (only allowed if configurable) Yes PST or LHMI(AddrQueryEnbl)

● No

1.4.5 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).

● Never Never PST or LHMI(DLinkConfirm)

● Always

● Sometimes, explain:

1.4.6 Data link layer confirmation time-out: This time-out applies to any secondary data link message that requires a confirm orresponse (link reset, link status, user data, etc).

○ None 2 seconds PST or LHMI(tDLinkTimeout)

○ Fixed at ms

● Configurable, range 0 to 60 s

○ Configurable, selectable from___,___,___ms



1.4.7 Maximum data link retries: The number of times the device will retransmit a frame that requests link layer confirmation.




1.4 Link layer Capabilities Current value If configurable, listmethods

○ None 3 PST or LHMI(DLinkRetries)

○ Fixed at




1.4.8 Maximum number of octets transmitted in a data link frame: This number includes the CRCs. With a length field of 255, themaximum size would be 292.

● Fixed at 292 292

○ Configurable, range ________ to _______



1.4.9 Maximum number of octets that can be received in a data link frame: This number includes the CRCs. With a field length of 255,the maximum size would be 292. The device must be able to receive 292 octets to be compliant.

● Fixed at 292 292




Table 7: Application layer

1.5 Application layer Capabilities Current value If configurable, listmethods

1.5.1 Maximum number of octets transmitted in an application layer fragment other than file transfer: This size does not include anytransport 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.Note: The current value of this outstation parameter is available remotely using protocol object Group 0 Variation 240.

○ Fixed at 2048 PST or LHMI(ApLayMaxTxSize)




1.5.2 Maximum number of octets transmitted in an application layer fragment containing file transfer:

○ Fixed at




1.5.3 Maximum number of octets that can be received in an application layer fragment:– Masters must provide a setting greater than or equal to 2048.– Outstations must provide a setting greater than or equal to 249.Note: The current value of this outstation parameter is available remotely using protocol object Group 0 Variation 241.





○ Fixed at 2048 PST or LHMI(ApLayMaxRxSize)




1.5.4 Time-out waiting for complete application layer fragment: Time-out if all frames of a message fragment are not received in thespecified time. Measured from time first frame of a fragment is received until the last frame is received.

● None None

○ Fixed at ms

○ Configurable, range _______ to _______ms




1.5.5 Maximum number of objects allowed in a single control request for CROB (Group 12): Note: The current value of this outstationparameter is available remotely using protocol object Group 0 Variation 216.

● Fixed at 10 (enter 0 if controls are notsupported for CROB)

10





1.5.6 Maximum number of objects allowed in a single control request for Analog Outputs (Group 41):

● Fixed at 0 (enter 0 if controls are notsupported for analog outputs)

0





1.5.7 Maximum number of objects allowed in a single control request for data sets (Groups 85, 86, 87):

● Fixed at 0 (enter 0 if controls are notsupported for Data Sets)

0





1.5.8 Supports mixed object groups (AOBs, CROBs and Data sets) in the same control request:

○ Not applicable - controls are not supported Yes

● Yes

○ No





1.5.9 Control Status Codes Supported: Indicates which control status codes are supported by the device:

• Masters must indicate which control status codes they accept in outstation responses• Outstations must indicate which control status codes they generate in responses

Control status code 0 (success) must be supported by Masters and Outstations.

●1 – TIMEOUT

● 2 – NO_SELECT

● 3 – FORMAT_ERROR

● 4 – NOT_SUPPORTED

● 5 – ALREADY_ACTIVE

○ 6 – HARDWARE_ERROR

● 7 – LOCAL

● 8 – TOO_MANY_OBJS

● 9 – NOT_AUTHORIZED

● 10 – AUTOMATION_INHIBIT

○ 11 – PROCESSING_LIMITED

○ 12 – OUT_OF_RANGE

○ 13 – DOWNSTREAM_LOCAL

○ 14 – ALREADY_COMPLET

○ 15 – BLOCKED

○ 16 – CANCELLED

○ 17 – BLOCKED_OTHER_MASTER

○ 18 – DOWNSTREAM_FAIL

○ 126 – RESERVED

● 127 – UNDEFINED

Table 8: Fill out for outstations only

1.7 Fill out thefollowing items foroutstations only

Capabilities Current value If configurable, listmethods

1.7.1 Time-out waiting for application confirm of solicited response message:

○ None 10 seconds PST or LHMI(tApplConfTout)

○ Fixed at ms


○ Configurable, selectable from ms



1.7.2 How often is time synchronization required from the master: Details of when the master needs to perform a timesynchronization to ensure that the outstation clock does not drift outside of an acceptable tolerance. If the option to relate this toIIN1.4 is used, then details of when IIN1.4 is asserted are in section 1.10.2.






● Never needs time 1800 seconds. PST or LHMI(tSynchTimeout)

○ Within seconds after IIN1.4 is set

○ Periodically, fixed at ____ seconds

● Periodically, between 30 and 3600 seconds

1.7.3 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: Set if the IED has detected problems (Internalfail).

1.7.4 File handle time-out: If there is no activity referencing a file handle for a configurable length of time, the outstation must do anautomatic close on the file. The time-out value must be configurable up to 1 hour. When this condition occurs the outstation will senda File Transport Status Object (group 70 var 6) using a status code value of file handle expired (0x02).

● Not applicable, files not supported

○ Fixed at ____ ms

○ Configurable, range _______ to _______ms




1.7.5 Event buffer overflow behavior:

● Discard the oldest event Delete the newestevent

PST or LHMI(DelOldBufFull)

● Discard the newest event

○ Other, explain:

1.7.6 Event buffer organization: Explain how event buffers are arranged (per Object Group, per Class, single buffer etc) and specifythe number of events that can be buffered.






● Per Object Group (see part 3) per Object Group

○ Per Object Group (see part 3)

Class 1:

Fixed at______

Configurable, range _______ to_______

Configurable, selectable from___,___,___

Configurable, other,describe_____________

Class 2:

Fixed at______




Class 3:

Fixed at______




○ Single Buffer

Fixed at______




○ Other, describe:

1.7.7 Sends multi-fragment responses: Indicates whether an outstation sends multi-fragment responses (Masters do not send multi-fragment requests).

● Yes Yes PST or LHMI(ApplMultFrgRes)

● No

1.7.8 Last fragment confirmation: Indicates whether the outstation requests confirmation of the last fragment of a multi-fragmentresponse.




○ Always Sometimes

● Sometimes, explain: Only when it contains events

○ Never

1.7.9 DNP command settings preserved through a device reset: If any of these settings are written through the DNP protocol and theyare not preserved through a restart of the outstation, the Master will have to write them again anytime the Restart IIN bit is set.

○ Assign Class

○ Analog Deadbands

○ Data Set Prototypes

○ Data Set Descriptors

○ Function Code 31 Activate Configuration

1.7.10 Supports configuration signature: Indicates whether an Outstation supports the Group 0 device attribute “Configurationsignature” (variation 200). If yes, list the vendor-defined name(s) of the algorithm(s) available to calculate the signature.Note: The algorithm used for calculating the signature is identified by name in a string that can be determined remotely usingprotocol object Group 0 Variation 201. If only a single algorithm is available, identifying that algorithm in this object is optional.

○ Configuration signature supported

If configuration signature is supported, then the followingalgorithm(s) are available for calculating the signature:Algorithm Name: ____________________

1.7.11 Requests Application Confirmation:Indicate if application confirmation is requested: when responding with events when sending non-final fragments of multifragment responsesNote: to be compliant both must be selected as “yes”.

For event responses:

● Yes

○ No

○ Configurable

For non-final fragments:

● Yes

○ No

○ Configurable

Table 9: Outstation unsolicited response support

1.8 Outstation unsolicitedresponse support


1.8.1 Supports unsolicited reporting: When the unsolicited response mode is configured "off", the device is to behave exactly like anequivalent device that has no support for unsolicited responses. If set to "on", the Outstation will send a null Unsolicited Responseafter it restarts, then wait for an Enable Unsolicited Response command from the master before sending additional UnsolicitedResponses containing event data.

○ Not Supported On PST or LHMI (UREnable)

● Configurable, selectable from On and Off

1.8.2 Master data link address: The destination address of the master device where the unsolicited responses will be sent.




1.8 Outstation unsolicitedresponse support


○ Fixed at 1 PST or LHMI(MasterAddres)




1.8.3 Unsolicited response confirmation time-out: This is the amount of time that the outstation will wait for an application layerconfirmation back from the master indicating that the master received the unsolicited response message. As a minimum, the rangeof configurable values must include times from one second to one minute. This parameter may be the same one that is used fornormal, solicited, application confirmation time-outs, or it may be a separate parameter.

○ Fixed at______ ms 5 seconds PST or LHMI(tURRetryDelay)

● Configurable, range 0 to 60 seconds




1.8.4 Number of Unsolicited Retries: This is the number of retries that an outstation transmits in each unsolicited response series if itdoes not receive confirmation back from the master. The configured value includes identical and regenerated retry messages. One ofthe choices must provide for an indefinite (and potentially infinite) number of transmissions.

● None 5 PST or LHMI(UROfflineRetry)

○ Fixed at




○ Always infinite, never gives up

Table 10: Outstation unsolicited response trigger conditions

1.9 Outstation unsolicitedresponse trigger conditions


1.9.1 Number of class 1 events:

○ Class 1 not used to trigger UnsolicitedResponses

5 PST or LHMI(UREvCntThold1)

○ Fixed at







○ Fixed at












○ Fixed at




1.9.4 Total number of events from any class:

● Total Number of Events not used to triggerUnsolicited Responses

○ Fixed at




1.9.5 Hold time after class 1 event: A configurable value of 0 indicates that responses are not delayed due to this parameter.


5 seconds PST or LHMI(tUREvBufTout1)

○ Fixed at ___________ ms


○ Configurable, selectable from ____,____,____ms





○ Fixed at ___________ ms







○ Fixed at ___________ ms




1.9.8 Hold time after event assigned to any class: A configurable value of 0 indicates that responses are not delayed due to thisparameter.






● Class events not used to trigger UnsolicitedResponses

○ Fixed at ___________ ms

○ Configurable, range ________ to _______ ms



1.9.9 Retrigger hold time: The hold-time timer may be retriggered for each new event detected (increased possibility of capturing allthe changes in a single response) or not retriggered (giving the master a guaranteed update time).

○ Hold-time timer will be retriggered for eachnew event detected (may get more changesin next response)

● Hold-time timer will not be retriggered foreach new event detected (guaranteed updatetime)

1.9.10. Other unsolicitedresponse triggerconditions:

__________________________________________

Table 11: Outstation performance

1.10 Outstation performance Capabilities Current value If configurable, listmethods

1.10.1 Maximum time base drift (milliseconds per minute): If the device is synchronized by DNP, what is the clock drift rate over thefull operating temperature range.

○ Fixed at ___________ ms 3 ms (worst case)

○ Range ________ to _______ ms

○ Selectable from ____,____,____ ms

● Other, describe:

1.10.2 When does outstation set IIN1.4? When does the outstation set the internal indication NEED_TIME?





● Never At startup and 1800seconds after last sync

PST or LHMI(tSynchTimeout)

● Asserted at startup until first TimeSynchronization request received

○ Periodically every____ seconds

○ Periodically, range ____to____ seconds

○ Periodically, selectable from ____,____,___seconds

○ ____seconds after last time sync

● Range 30 to 3600 seconds after last timesync

○ Selectable from___,___,___ seconds afterlast time sync

○ When time error may have drifted by ____ms

○ When time error may have drifted by range____to____ ms

○ When time error may have drifted byselectable from ____,____,___

1.10.3 Maximum internal time reference error when set via DNP (ms): The difference between the time set in DNP write time message,and the time actually set in the outstation.

○ Fixed at ___________ ms 100 ms

○ Range ________ to _______ ms


● Other, describe: Maximum

1.10.4 Maximum delay measurement error (ms): The difference between the time reported in the delay measurement response andthe actual time between receipt of the delay measurement request and issuing the delay measurement reply.

○ Fixed at ___________ ms 50 ms

○ Range ________ to _______ ms



1.10.5 Maximum response time (ms): The amount of time an outstation will take to respond upon receipt of a valid request. This doesnot include the message transmission time.

○ Fixed at ___________ ms 50 ms

○ Range ________ to _______ ms



1.10.6 Maximum time from start-up to IIN 1.4 assertion (ms):

○ Fixed at ___________ ms 120000 ms

○ Range ________ to _______ ms







1.10.7 Maximum event time-tag error for local binary and double bit I/O (ms): The error between the time-tag reported and theabsolute time of the physical event. This error includes the Internal Time Reference Error.Note: The current value of this parameter is available remotely using protocol object Group 0 Variation 217.

○ Fixed at ___________ ms IEC T1 class

○ Range ________ to _______ ms


● Other, describe: IEC T1 class

1.10.8 Maximum event time-tag error for local I/O other than binary and double bit data types (ms):

○ Fixed at ___________ ms IEC T1 class

○ Range ________ to _______ ms


● Other, describe: IEC T1 class

Table 12: Individual field outstation parameters

1.11 Individual field outstation parameters Capabilities Current value If configurable, list methods

1.11.1 User-assigned location name or code string N/A

1.11.2 User-assigned ID code/number string N/A

1.11.3 User-assigned name string for the outstation N/A

1.11.4 Device Serial Number string N/A

Table 13: Security parameters

1.12 Security parameters Capabilities Current value If configurable, listmethods

1.12.1 DNP3 device support for secure authentication: The support for secure authentication is optional in DNP3 devices. Indicate hereif the device supports secure authentication. If the device does not support secure authentication, then ignore the rest of thissection. If the device does support secure authentication, then specify the version(s) that are supported in the device. The versionnumber is an integer value defined in the DNP3 specification. The Secure Authentication procedure defined in IEEE 1815–2010 isversion 2. The Secure Authentication procedure defined in IEEE 1815–2012 is version 5.

● Secure Authentication not supported.If Secure Authentication is supported, whatVersion(s) are supported:

Secure Authenticationnot supported

○ Fixed at ___________




1.13 Broadcastfunctionality

Capabilities Current Value If configurable, listmethods

1.13.1 Support forbroadcast functionality:

○ Disabled● Enabled○ Configurable

1.13.2 Write functions (FC= 2) supported withbroadcast requests:

Write clock (g50v1 withqualifier code 07):○ Disabled● Enabled○ Configurable (describedelsewhere)

Write last recorded time(g50v3 with qualifier code07):○ Disabled● Enabled○ Configurable (describedelsewhere

Clear RESTART (g50v1with qualifier code 00 andindex = 7, value = 0):○ Disabled● Enabled○ Configurable (describedelsewhere

Write of any other group /variation / qualifier code:○ Disabled● Enabled○ Configurable (describedelsewhere

1.13.3 Direct operatefunctions (FC = 5)supported with broadcastrequests:

○ Disabled● Enabled○ Configurable (describedelsewhere

1.13.4 Direct operate, noacknowledgmentfunctions (FC = 6)supported with broadcastrequests:


1.13.5 Immediate freezefunctions (FC = 7)supported with broadcastrequests:

● Disabled○ Enabled○ Configurable (describedelsewhere

1.13.6 Immediate freeze,no acknowledgmentfunctions (FC = 8)supported with broadcastrequests:


1.13.7 Freeze and clearfunctions (FC = 9)supported with broadcastrequests:


1.13.8 Freeze and clear, noacknowledgmentfunctions (FC = 10)supported with broadcastrequests:







1.13.9 Freeze at timefunctions (FC = 11)supported with broadcastrequests:


1.13.10 Freeze at time, noacknowledgmentfunctions (FC = 12)supported with broadcastrequests:


1.13.11 Cold restartfunctions (FC = 13)supported with broadcastrequests:


1.13.12 Warm restartfunctions (FC = 14)supported with broadcastrequests:


1.13.13 Initialize datafunctions (FC = 15)supported with broadcastrequests:


1.13.14 Initializeapplication functions (FC= 16) supported withbroadcast requests:


1.13.15 Start applicationfunctions (FC = 17)supported with broadcastrequests:


1.13.16 Stop applicationfunctions (FC = 18)supported with broadcastrequests:


1.13.17 Save configurationfunctions (FC = 19)supported with broadcastrequests:


1.13.18 Enable unsolicitedfunctions (FC = 20)supported with broadcastrequests:

Enable unsolicited byevent Class (g60v2, g60v3and g60v4 with qualifiercode 06):○ Disabled● Enabled○ Configurable (describedelsewhere

Enable unsolicited for anyother group / variation /qualifier code:● Disabled○ Enabled○ Configurable (describedelsewhere






1.13.19 Disable unsolicitedfunctions (FC = 21)supported with broadcastrequests:

Disable unsolicited byevent Class (g60v2, g60v3and g60v4 with qualifiercode 06):○ Disabled● Enabled○ Configurable (describedelsewhere

Disable unsolicited for anyother group / variation /qualifier code:● Disabled○ Enabled○ Configurable (describedelsewhere

1.13.20 Assign classfunctions (FC = 22)supported with broadcastrequests:


1.13.21 Record currenttime functions (FC = 24)supported with broadcastrequests:


1.13.22 Activateconfiguration (FC = 31)supported with broadcastrequests:


3.1 BINARY INPUTSStatic (Steady-State)Group Number: 1 EventGroup Number: 2

Capabilities(leave tick-boxes blank ifthis data type is notsupported)

Current Value If configurable, listmethods

3.1.1 Static Variation reported when variation 0 requested or in response to Class polls:

● Variation 1 – packedformat

One PST or LHMI (Obj1DefVar)

● Variation 2 – with flag

○ Based on point Index(add column to table inpart 5)

3.1.2 Event Variation reported when variation 0 requested or in response to Class polls: Note: The support forbinary input events can be determined remotely using protocol object Group 0 Variation 237.

● Variation 1 – withouttime

Three PST or LHMI (Obj2DefVar)

● Variation 2 – withabsolute time

● Variation 2 – withrelative time





3.1 BINARY INPUTSStatic (Steady-State)Group Number: 1 EventGroup Number: 2



3.1.3 Event reporting mode: When responding with event data and more than one event has occurred for a datapoint, an Outstation may include all events or only the most recent event. “All events” must be checked to becompliant.

○ Only most recent All events

● All events

3.1.4 Binary Inputs included in Class 0 response:

● Always Always

○ Never

○ Only if the point isassigned to a class


3.1.5 Binary Inputs Event Buffer Organization: When event buffers are allocated per object group (see part 1.7.6),indicate the number of events that can be buffered for Binary Inputs. If event buffers are not allocated per objectgroup then set “Fixed at 0”.

● Fixed at 1000

○ Configurable, range_______ to _______

○ Configurable, selectablefrom ____,____,____

○ Configurable, other,describe:

3.6 DOUBLE-BIT BINARYINPUTS Static (Steady-State) Group Number: 3Event Group Number: 4



3.6.1 Static Variation reported when variation 0 requested or in response to Class polls:Note: The support for double-bit binary inputs can be determined remotely using protocol object Group 0Variation 234.


One PST or LHMI (Obj3DefVar)

● Variation 2 – with flag


3.6.2 Event Variation reported when variation 0 requested or in response to Class polls:




3.6 DOUBLE-BIT BINARYINPUTS Static (Steady-State) Group Number: 3Event Group Number: 4



● Variation 1 – withouttime

Three PST or LHMI (Obj4DefVar)

● Variation 2 – withabsolute time

● Variation 3 – withrelative time


3.6.3 Event reporting mode: When responding with event data and more than one event has occurred for a datapoint, an Outstation may include all events or only the most recent event. “All events” must be checked to becompliant.

○ Only most recent All events

●All events

3.6.4 Double-bit Binary Inputs included in Class 0 response:

● Always Always

○ Never



3.6.5 Double-bit Binary Inputs Event Buffer Organization: When event buffers are allocated per object group (seepart 1.7.6), indicate the number of events that can be buffered for Double-bit Binary Inputs. If event buffers are notallocated per object group then set “Fixed at 0”.

● Fixed at 1000






3.7 BINARY OUTPUTS ANDBINARY OUTPUTCOMMANDSBinary Outputs GroupNumber: 10Binary Output EventsGroup Number: 11Binary Output CommandsGroup Number: 12Binary Output CommandEvents Group Number: 13



3.7.1 Minimum pulse time allowed with Trip, Close, and Pulse On commands:

● Fixed at ______ms(hardware may limit thisfurther)

5, 20 or 100 ms

○ Based on point Index.Comment: Not shorterthan the applicationthread the AutomationBits function block isexecuting in.

3.7.2 Maximum pulse time allowed with Trip, Close, and Pulse On commands:

● Fixed at 4294967296 ms(hardware may limit thisfurther)

4294967296 ms


3.7.3 Binary Output Status included in Class 0 response:

● Always

○ Never



3.7.4 Reports Output Command Event Objects:

● Never

○ Only upon a successfulControl

○ Upon all controlattempts



Two PST or LHMI(Obj10DefVar)

● Variation 2 – outputstatus with flags








3.7.6 Event Variation reported when variation 0 requested or in response to Class polls:Note: The support for binary output events can be determined remotely using protocol object Group 0 Variation222.

○ Variation 1 – statuswithout time

Not Supported

○ Variation 2 – status withtime


3.7.7 Command Event Variation reported when variation 0 requested or in response to Class polls:

○ Variation 1 – commandstatus without time

Not Supported

○ Variation 2 – commandstatus with time


3.7.8 Event reporting mode: When responding with event data and more than one event has occurred for a datapoint, an Outstation may include all events or only the most recent event

○ Only most recent

● All events

3.7.9 Command Event reporting mode: When responding with event data and more than one event has occurredfor a data point, an Outstation may include all events or only the most recent event

○ Only most recent Not Supported

○ All events

3.7.10 Maximum Time between Select and Operate:

○ Not Applicable 30 seconds PST or LHMI(tSelectTimeout)


● Configurable, range 1 to60 seconds

○ Configurable, selectablefrom___,___,___ seconds










3.7.11 Binary Outputs Event Buffer Organization: When event buffers are allocated per object group (see part 1.7.6),indicate the number of events that can be buffered for Binary Outputs. If event buffers are not allocated perobject group then set “Fixed at 0”.

○ Fixed at ___________ Not Supported




3.7.12 Binary Output Commands Event Buffer Organization: When event buffers are allocated per object group (seepart 1.7.6), indicate the number of events that can be buffered for Binary Output Commands. If event buffers arenot allocated per object group then set “Fixed at 0”.





3.8 COUNTERS/FROZENCOUNTERSCounter Group Number: 20Frozen Counter GroupNumber: 21Counter Event GroupNumber: 22Frozen Counter EventGroup Number: 23



3.8.1 Static Counter Variation reported when variation 0 requested or in response to Class polls:

● Variation 1 – 32-bit withflag

Five PST or LHMI(Obj20DefVar)


● Variation 5 – 32-bitwithout flag









3.8.2 Counter Event Variation reported when variation 0 requested or in response to Class polls: Note: The supportfor counter events can be determined remotely using protocol object Group 0 Variation 227.


One PST or LHMI(Obj22DefVar)


● Variation 5 – 32-bit withflag and time

● Variation 6 – 16-bit withflag and time


3.8.3 Counters included in Class 0 response:

● Always

○ Never



3.8.4 Counter Event reporting mode: When responding with event data and more than one event has occurred fora data point, an Outstation may include all events or only the most recent event. Only the most recent event istypically reported for Counters. When reporting “only most recent”, the counter value reported in the responsemay be the value at the time of the original event or it may be the value at the time of the response.

● A: Only most recent(value at time of event)

○ B: Only most recent(value at time ofresponse)

○ C: All events


3.8.5 Static Frozen Counter Variation reported when variation 0 requested or in response to Class polls:







○ Variation 1 – 32-bit withflag

Not Supported


○ Variation 5 – 32-bit withflag and time


○ Variation 9 – 32-bitwithout flag



3.8.6 Frozen Counter Event Variation reported when variation 0 requested or in response to Class polls:Note: The support for frozen counter events can be determined remotely using protocol object Group 0 Variation225


Not Supported





3.8.7 Frozen Counters included in Class 0 response:

○ Always Not Supported

○ Never



3.8.8 Frozen Counter Event reporting mode: When responding with event data and more than one event hasoccurred for a data point, an Outstation may include all events or only the most recent event. All events aretypically reported for Frozen Counters.







○ A: Only most recentfrozen value

Not Supported

○ B: All frozen values


3.8.9 Counters Roll Over at:

○ 16 Bits (65,535)

● 32 Bits (4,294,967,295)

○ Other Fixed Value_________

○ Configurable; range_________ to__________

○ Configurable, selectablefrom ___,___,___



3.8.10 Counters frozen by means of:

○ Master Request Not Supported

○ Freezes itself withoutconcern for time of day

○ Freezes itself andrequires time of day

○ Other, explain:

3.8.11 Counters Event Buffer Organization: When event buffers are allocated per object group (see part 1.7.6),indicate the number of events that can be buffered for Counters. If event buffers are not allocated per objectgroup then set “Fixed at 0”.

● Fixed at ___________




3.8.12 Frozen Counters Event Buffer Organization: When event buffers are allocated per object group (see part1.7.6), indicate the number of events that can be buffered for Frozen Counters. If event buffers are not allocatedper object group then set “Fixed at 0”.











3.8.13 Reports counter events for change of value: Indicate if counter events are created when the counter valuechanges.

● Yes for all counters

○ No for all counters

○ Configurable, based onpoint Index (add columnto table in part 5)

3.9 ANALOG INPUTSStatic (Steady-State)Group Number: 30Static Frozen GroupNumber: 31Event Group Number: 32Frozen Analog Input EventGroup Number: 33Deadband Group Number:34





Three PST or LHMI(Obj30DefVar)




● Variation 5 – single-precision floating pointwith flag

● Variation 6 – double-precision floating pointwith flag








3.9.2 Event Variation reported when variation 0 requested or in response to Class polls: Note: The support foranalog input events can be determined remotely using protocol object Group 0 Variation 231.

● Variation 1 – 32-bitwithout time

One PST or LHMI(Obj32DefVar)

● Variation 2 – 16-bitwithout time

● Variation 3 – 32-bit withtime

● Variation 4 – 16-bit withtime

● Variation 5 – single-precision floating pointw/o time

● Variation 6 – double-precision floating pointw/o time

● Variation 7 – single-precision floating pointwith time

● Variation 8 – double-precision floating pointwith time


3.9.3 Event reporting mode: When responding with event data and more than one event has occurred for a datapoint, an Outstation may include all events or only the most recent event. Only the most recent event is typicallyreported for Analog Inputs. When reporting “only most recent”, the analog value reported in the response may bethe value at the time of the original event or it may be the value at the time of the response.

● A: Only most recent(value at time of event)

Most Recent – Event Time

● B: Only most recent(value at time ofresponse)

● C: All events


3.9.4 Analog Inputs Included in Class 0 response:







● Always

○ Never



3.9.5 How Deadbands are set:

○ A. Global Fixed PST or LHMI

○ B. Configurable throughDNP

○ C. Configurable viaother means

● D. Other, explain: Anydeadbanding is a propertyof the IED’s underlyingdata, and is configuredthrough the IEDconfiguration tools (PCM).

○ Based on point Index -column in part 5 specifieswhich of the optionsapplies, B, C, or D

3.9.6 Analog Deadband Algorithm: simple - just compares the difference from the previous reported valueintegrating - keeps track of the accumulated change other - indicating another algorithm

○ Simple PST or LHMI

○ Integrating

● Other, explain: Anydeadbanding is a propertyof the IED’s underlyingdata, and is configuredthrough the IED


3.9.7 Static Frozen Analog Input Variation reported when variation 0 requested or in response to Class polls:








Not Supported


○ Variation 3 – 32-bit withtime-of-freeze

○ Variation 4 – 16-bit withtime-of-freeze



○ Variation 7 – Single-precision, floating-pointwith flag

○ Variation 8 – Double-precision, floating-pointwith flag


3.9.8 Frozen Analog Input Event Variation reported when variation 0 requested or in response to Class polls:Note: The support for frozen analog input events can be determined remotely using protocol object Group 0Variation 230.







○ Variation 1 – 32-bitwithout time

Not Supported


○ Variation 3 – 32-bit withtime


○ Variation 5 – Single-precision, floating-pointwithout time

○ Variation 6 – Double-precision, floating-pointwithout time

○ Variation 7 – Single-precision, floating-pointwith time

○ Variation 8 – Double-precision, floating-pointwith time


3.9.9 Frozen Analog Inputs included in Class 0 response:


○ Never



3.9.10 Frozen Analog Input Event reporting mode: When responding with event data and more than one event hasoccurred for a data point, an Outstation may include all events or only the most recent event. All events aretypically reported for Frozen Analog Inputs.

○ A: Only most recentfrozen value

Not Supported

○ B: All frozen values


3.9.11 Analog Inputs Event Buffer Organization: When event buffers are allocated per object group (see part 1.7.6),indicate the number of events that can be buffered for Analog Inputs. If event buffers are not







● Fixed at 1000




3.9.12 Frozen Analog Inputs Event Buffer Organization: When event buffers are allocated per object group (seepart 1.7.6), indicate the number of events that can be buffered for Frozen Analog Inputs. If event buffers are notallocated per object group then set “Fixed at 0”.

○ Fixed at 1000 Not Supported






3.10 ANALOG OUTPUTSAND ANALOG OUTPUTCOMMANDS Analog Output StatusGroup Number: 40 AnalogOutputs Group Number: 41Analogue Output EventsGroup Number: 42Analogue OutputCommand Events GroupNumber: 43



3.10.1 Static Analog Output Status Variation reported when variation 0 requested or in response to Class polls:


Not Supported


○ Variation 3 – single-precision floating pointwith flag

○ Variation 4 – double-precision floating pointwith flag


3.10.2 Analog Output Status Included in Class 0 response:


○ Never



3.10.3 Reports Output Command Event Objects:

○ Never Not Supported

○ Only upon a successfulControl

○ Upon all controlattempts

3.10.4 Event Variation reported when variation 0 requested or in response to Class polls:Note: The support for analog output events can be determined remotely using protocol object Group 0 Variation219.








Not Supported




○ Variation 5 – single-precision floating pointw/o time

○ Variation 6 – double-precision floating pointw/o time

○ Variation 7 – single-precision floating pointwith time

○ Variation 8 – double-precision floating pointwith time


3.10.5 Command Event Variation reported when variation 0 requested or in response to Class polls:








Not Supported




○ Variation 5 – single-precision floating pointw/o time

○ Variation 6 – double-precision floating pointw/o time

○ Variation 7 – single-precision floating pointwith time

○ Variation 8 – double-precision floating pointwith time


3.10.6 Event reporting mode: When responding with event data and more than one event has occurred for a datapoint, an Outstation may include all events or only the most recent event.


○ All events

3.10.7 Command Event reporting mode: When responding with event data and more than one event has occurredfor a data point, an Outstation may include all events or only the most recent event.


○ All events

3.10.8 Maximum Time between Select and Operate:







○ Not Applicable Not Supported


○ Configurable, range______ to ______ seconds

○ Configurable, selectablefrom ___,___,___seconds

○ Configurable, other,describe________________

○ Variable, explain_______________________


3.10.9 Analog Outputs Event Buffer Organization: When event buffers are allocated per object group (see part1.7.6), indicate the number of events that can be buffered for Analog Outputs. If event buffers are not allocatedper object group then set “Fixed at 0”.

○ Fixed at _____ Not Supported

○ Fixed at _____



3.10.10 Analog Output Commands Event Buffer Organization: When event buffers are allocated per object group(see part 1.7.6), indicate the number of events that can be buffered for Analog Output Commands. If event buffersare not allocated per object group then set “Fixed at 0”.

○ Fixed at _____ Not Supported

○ Fixed at _____





3.11 FILE CONTROL Group Number: 70


3.11.1 File Transfer Supported:

○ Yes Not Supported

○ No (set 3.7.6 to “Fixed at0” and do not completeother entries in section1.11)

3.2 DNP3 implementation tableGUID-DAF3C524-1298-43C5-AE4A-CAC342300095 v2

The following table identifies which object groups and variations, function codes, and qualifiersthe IED supports in both request messages and in response messages. For static (non-changeevent) objects, requests sent with qualifiers 00, 01, 06, 07 or 08 are responded with qualifiers 00or 01. Requests sent with qualifiers 17 or 28 are responded with qualifiers 17 or 28. For changeevent objects, qualifiers 17 or 28 are always responded.

Table 14: Implementation table

DNP OBJECT GROUP AND VARIATION REQUEST (Slave will parse) RESPONSE (Slave will respond with)

Objectgroup

number

Variation

number DescriptionFunction codes

(dec) Qualifier codes (hex)Function codes

(dec)Qualifier codes

(hex)

1 0 Binary input – anyvariation

1 (read) 00, 01 (start-stop)06 (no range, or all)07, 08 (limited qty)17, 27, 28 (index)

1 1(default)

1)

Binary input – singlebit packed


129 (response) 00, 01 (start-stop)17, 28 (index) 2)

1 2 Binary input – singlebit with flag



2 0 Binary input changeevent – any variation

1 (read) 06 (no range, or all)07, 08 (limited qty)

2 1 Binary input changeevent without time


129 (response) 17, 28 (index)

2 1 Binary input changeevent without time

130 (unsol. resp) 17, 28 (index)

2 2 Binary input changeevent – with absolute

time



2 2 Binary input changeevent – with absolute

time


2 3 1) Binary input changeevent with relative

time







2 3 Binary input changeevent with relative

time


3 0 Double bit input – anyvariation

1 (read) 00, 01 (start-stop)06 (no range, or all)07, 08 (limited qty)17 ,27, 28 (index)

3 1 1) Double bit output –double bit packed



3 2 Double bit input withflag


129 (response) 00, 01 (start-stop)17, 28 (index)2)

4 0 Double bit inputchange event - any

variation


4 1 Double bit inputchange event without

time



4 1 Double bit inputchange event without

time


4 2 Double bit inputchange event with

absolute time




absolute time


4 3 1) Double bit inputchange event with

relative time




relative time


10 0 Binary output — anyvariation

1 (read) 00, 01 (start-stop)06 (no range, or all)07, 08 (limited qty)17, 28 (index)

10 1 Binary output —packed format



10 21) Continuous control —output status with

flags


129 (response) 00, 01 (start-stop)17, 28 (index)2)

12 0 Binary outputcommand (CROB) —

any variation

22 (assign class) 00, 01 (start-stop)06 (no range, or all)07, 08 (limited qty)17, 27, 28 (index)





12 1 Binary outputcommand (CROB) —control relay output

block

3 (select) 17, 27, 28 (index) 129 (response) echo of request


block

4 (operate) 17, 27, 28 (index) 129 (response) echo of request


block

5 (direct op) 17, 27, 28 (index) 129 (response) echo of request


block

6 (direct.op. noack)

17, 27, 28 (index) 129 (response) echo of request

20 0 Counter — anyvariation


20 1 32–bit binary counter(with flag)


129 (response) 00,01 (start-stop)17, 28 (index) 2)

20 2 16–bit binary counter(with flag)



20 51) 32–bit binary counterwithout flag



20 6 16–bit binary counterwithout flag



22 0 Counter change event— any variation


22 11) 32–bit counter changeevent with flag



22 1 32–bit counter changeevent with flag







22 5 32–bit counter changeevent with flag and

time




time







time




time


30 0 Analog input — anyvariation

1 (read) 00, 01 (start-stop)06 (no range, or all)

30 1 32–bit analog inputwith flag



30 2 16–bit analog inputwith flag



30 3 1) 32–bit analog inputwithout flag



30 4 16–bit analog inputwithout flag



30 5 Analog input — singleprecision, floating

point with flag



30 6 Analog input —double precision,

floating point withflag



32 0 Analog input changeevent — any variation


32 11) 32–bit analog inputchange event without

time



32 1 32–bit analog inputchange event without

time



time




time


32 3 32–bit analog inputchange event with

time




time







time




time


32 5 Analog input changeevent — single

precision, floatingpoint without time






32 6 Analog input changeevent — double








precision, floatingpoint with time













50 11) Time and date —absolute time

1 (read) 07, (limited qty = 1) 129 (response) 07 (limited qty =1)

50 1 Time and date —absolute time

2 (write) 07, (limited qty = 1)

50 3 Time and date lastabsolute time at last

recorded time

2 (write) 07 (limited qty= 1)

51 1 Time and date CTO —absolute time,synchronized

129 (response) 07 (limited qty)(qty = 1)

51 1 Time and date CTO —absolute time,synchronized

130 (unsol. resp) 07 (limited qty)(qty = 1)

51 2 Time and date CTO —absolute time,

unsynchronized

129 (response) 07 (limited qty)(qty = 1)





51 2 Time and date CTO —absolute time,

unsynchronized

130 (unsol. resp) 07 (limited qty)(qty = 1)

52 1 Time delay coarse 129 (response) 07 (limited qty)(qty = 1)

52 2 Time delay fine 129 (response) 07 (limited qty)(qty = 1)

60 0 Not defined

60 1 Class objects — class0 data

1 (read) 06 (no range, or all)




20 (enbl. unsol.) 06 (no range, or all)


21 (disable unsol.) 06 (no range, or all)








1 (read) 06 (no range, or all),07, 08 (limited qty)





80 1 Internal indications —packed format

1 (read) 00, 01 (start-stop) 129 (response) 00,01 (start-stop)

80 1 Internal indications —packed format

2 (write) 3) 00 (start-stop)

No object (function code only) 13 (cold restart)

No object (function code only) 14 (warm restart)

No object (function code only) 23 (delay meas.)

No object (function code only) 24 (record currenttime)

1) A default variation refers to the variation responded when variation 0 is requested and/or in class 0, 1, 2 or 3 scans. Defaultvariations are configurable; however, default settings for the configuration parameters are indicated in the table above.

2) For static (non-change event) objects, qualifiers 17 or 28 are only responded when a request is sent with qualifiers 17 or 28.Otherwise, static object requests sent with qualifiers 00, 01, 06, 07 or 08 are responded with qualifiers 00 or 01. (For change eventobjects, qualifiers 17 or 28 are always responded.)

3) Writings of internal indications are only supported for index 7 (Restart IIn1–7).



Section 4 Glossary

4.1 GlossaryM14893-1 v18

AC Alternating current

ACC Actual channel

ACT Application configuration tool within PCM600

A/D converter Analog-to-digital converter

ADBS Amplitude deadband supervision

ADM Analog digital conversion module, with time synchronization

AI Analog input

ANSI American National Standards Institute

AR Autoreclosing

ASCT Auxiliary summation current transformer

ASD Adaptive signal detection

ASDU Application service data unit

AWG American Wire Gauge standard

BBP Busbar protection

BFOC/2,5 Bayonet fiber optic connector

BFP Breaker failure protection

BI Binary input

BIM Binary input module

BOM Binary output module

BOS Binary outputs status

BR External bistable relay

BS British Standards

BSR Binary signal transfer function, receiver blocks

BST Binary signal transfer function, transmit blocks

C37.94 IEEE/ANSI protocol used when sending binary signals between IEDs

CAN Controller Area Network. ISO standard (ISO 11898) for serialcommunication

CB Circuit breaker

CBM Combined backplane module

CCITT Consultative Committee for International Telegraph and Telephony. AUnited Nations-sponsored standards body within the InternationalTelecommunications Union.

1MRK511354-UUS A Section 4Glossary


CCM CAN carrier module

CCVT Capacitive Coupled Voltage Transformer

Class C Protection Current Transformer class as per IEEE/ ANSI

CMPPS Combined megapulses per second

CMT Communication Management tool in PCM600

CO cycle Close-open cycle

Codirectional Way of transmitting G.703 over a balanced line. Involves two twisted pairsmaking it possible to transmit information in both directions

COM Command

COMTRADE Standard Common Format for Transient Data Exchange format forDisturbance recorder according to IEEE/ANSI C37.111, 1999 / IEC 60255-24

Contra-directional Way of transmitting G.703 over a balanced line. Involves four twisted pairs,two of which are used for transmitting data in both directions and two fortransmitting clock signals

COT Cause of transmission

CPU Central processing unit

CR Carrier receive

CRC Cyclic redundancy check

CROB Control relay output block

CS Carrier send

CT Current transformer

CU Communication unit

CVT or CCVT Capacitive voltage transformer

DAR Delayed autoreclosing

DARPA Defense Advanced Research Projects Agency (The US developer of theTCP/IP protocol etc.)

DBDL Dead bus dead line

DBLL Dead bus live line

DC Direct current

DFC Data flow control

DFT Discrete Fourier transform

DHCP Dynamic Host Configuration Protocol

DIP-switch Small switch mounted on a printed circuit board

DI Digital input

DLLB Dead line live bus

DNP Distributed Network Protocol as per IEEE Std 1815-2012

DR Disturbance recorder

DRAM Dynamic random access memory

DRH Disturbance report handler

Section 4 1MRK511354-UUS AGlossary


DSP Digital signal processor

DTT Direct transfer trip scheme

ECT Ethernet configuration tool

EHV network Extra high voltage network

EIA Electronic Industries Association

EMC Electromagnetic compatibility

EMF Electromotive force

EMI Electromagnetic interference

EnFP End fault protection

EPA Enhanced performance architecture

ESD Electrostatic discharge

F-SMA Type of optical fiber connector

FAN Fault number

FCB Flow control bit; Frame count bit

FOX 20 Modular 20 channel telecommunication system for speech, data andprotection signals

FOX 512/515 Access multiplexer

FOX 6Plus Compact time-division multiplexer for the transmission of up to sevenduplex channels of digital data over optical fibers

FPN Flexible product naming

FTP File Transfer Protocol

FUN Function type

G.703 Electrical and functional description for digital lines used by localtelephone companies. Can be transported over balanced and unbalancedlines

GCM Communication interface module with carrier of GPS receiver module

GDE Graphical display editor within PCM600

GI General interrogation command

GIS Gas-insulated switchgear

GOOSE Generic object-oriented substation event

GPS Global positioning system

GSAL Generic security application

GSE Generic substation event

HDLC protocol High-level data link control, protocol based on the HDLC standard

HFBR connector type Plastic fiber connector

HLV circuit Hazardous Live Voltage according to IEC60255-27

HMI Human-machine interface

HSAR High speed autoreclosing

HSR High-availability Seamless Redundancy



HV High-voltage

HVDC High-voltage direct current

IDBS Integrating deadband supervision

IEC International Electrical Committee

IEC 60044-6 IEC Standard, Instrument transformers – Part 6: Requirements forprotective current transformers for transient performance

IEC 60870-5-103 Communication standard for protection equipment. A serial master/slaveprotocol for point-to-point communication

IEC 61850 Substation automation communication standard

IEC 61850–8–1 Communication protocol standard

IEEE Institute of Electrical and Electronics Engineers

IEEE 802.12 A network technology standard that provides 100 Mbits/s on twisted-pairor optical fiber cable

IEEE P1386.1 PCI Mezzanine Card (PMC) standard for local bus modules. References theCMC (IEEE P1386, also known as Common Mezzanine Card) standard forthe mechanics and the PCI specifications from the PCI SIG (Special InterestGroup) for the electrical EMF (Electromotive force).

IEEE 1686 Standard for Substation Intelligent Electronic Devices (IEDs) Cyber SecurityCapabilities

IED Intelligent electronic device

IET600 Integrated engineering tool

I-GIS Intelligent gas-insulated switchgear

IOM Binary input/output module

Instance When several occurrences of the same function are available in the IED,they are referred to as instances of that function. One instance of afunction is identical to another of the same kind but has a differentnumber in the IED user interfaces. The word "instance" is sometimesdefined as an item of information that is representative of a type. In thesame way an instance of a function in the IED is representative of a type offunction.

IP 1. Internet protocol. The network layer for the TCP/IP protocol suite widelyused on Ethernet networks. IP is a connectionless, best-effort packet-switching protocol. It provides packet routing, fragmentation andreassembly through the data link layer.2. Ingression protection, according to IEC 60529

IP 20 Ingression protection, according to IEC 60529, levelIP20- Protected against solid foreign objects of 12.5mm diameter andgreater.

IP 40 Ingression protection, according to IEC 60529, level IP40-Protected againstsolid foreign objects of 1mm diameter and greater.

IP 54 Ingression protection, according to IEC 60529, levelIP54-Dust-protected, protected against splashing water.

IRF Internal failure signal

IRIG-B: InterRange Instrumentation Group Time code format B, standard 200



ITU International Telecommunications Union

LAN Local area network

LIB 520 High-voltage software module

LCD Liquid crystal display

LDCM Line data communication module

LDD Local detection device

LED Light-emitting diode

LNT LON network tool

LON Local operating network

MCB Miniature circuit breaker

MCM Mezzanine carrier module

MIM Milli-ampere module

MPM Main processing module

MVAL Value of measurement

MVB Multifunction vehicle bus. Standardized serial bus originally developed foruse in trains.

NCC National Control Centre

NOF Number of grid faults

NUM Numerical module

OCO cycle Open-close-open cycle

OCP Overcurrent protection

OEM Optical Ethernet module

OLTC On-load tap changer

OTEV Disturbance data recording initiated by other event than start/pick-up

OV Overvoltage

Overreach A term used to describe how the relay behaves during a fault condition. Forexample, a distance relay is overreaching when the impedance presentedto it is smaller than the apparent impedance to the fault applied to thebalance point, that is, the set reach. The relay “sees” the fault but perhapsit should not have seen it.

PCI Peripheral component interconnect, a local data bus

PCM Pulse code modulation

PCM600 Protection and control IED manager

PC-MIP Mezzanine card standard

PELV circuit Protected Extra-Low Voltage circuit type according to IEC60255-27

PMC PCI Mezzanine card

POR Permissive overreach

POTT Permissive overreach transfer trip



Process bus Bus or LAN used at the process level, that is, in near proximity to themeasured and/or controlled components

PRP Parallel redundancy protocol

PSM Power supply module

PST Parameter setting tool within PCM600

PTP Precision time protocol

PT ratio Potential transformer or voltage transformer ratio

PUTT Permissive underreach transfer trip

RASC Synchrocheck relay, COMBIFLEX

RCA Relay characteristic angle

RISC Reduced instruction set computer

RMS value Root mean square value

RS422 A balanced serial interface for the transmission of digital data in point-to-point connections

RS485 Serial link according to EIA standard RS485

RTC Real-time clock

RTU Remote terminal unit

SA Substation Automation

SBO Select-before-operate

SC Switch or push button to close

SCL Short circuit location

SCS Station control system

SCADA Supervision, control and data acquisition

SCT System configuration tool according to standard IEC 61850

SDU Service data unit

SELV circuit Safety Extra-Low Voltage circuit type according to IEC60255-27

SFP Small form-factor pluggable (abbreviation)Optical Ethernet port (explanation)

SLM Serial communication module.

SMA connector Subminiature version A, A threaded connector with constant impedance.

SMT Signal matrix tool within PCM600

SMS Station monitoring system

SNTP Simple network time protocol – is used to synchronize computer clocks onlocal area networks. This reduces the requirement to have accuratehardware clocks in every embedded system in a network. Each embeddednode can instead synchronize with a remote clock, providing the requiredaccuracy.

SOF Status of fault



SPA Strömberg Protection Acquisition (SPA), a serial master/slave protocol forpoint-to-point and ring communication.

SRY Switch for CB ready condition

ST Switch or push button to trip

Starpoint Neutral/Wye point of transformer or generator

SVC Static VAr compensation

TC Trip coil

TCS Trip circuit supervision

TCP Transmission control protocol. The most common transport layer protocolused on Ethernet and the Internet.

TCP/IP Transmission control protocol over Internet Protocol. The de factostandard Ethernet protocols incorporated into 4.2BSD Unix. TCP/IP wasdeveloped by DARPA for Internet working and encompasses both networklayer and transport layer protocols. While TCP and IP specify two protocolsat specific protocol layers, TCP/IP is often used to refer to the entire USDepartment of Defense protocol suite based upon these, including Telnet,FTP, UDP and RDP.

TEF Time delayed gound-fault protection function

TLS Transport Layer Security

TM Transmit (disturbance data)

TNC connector Threaded Neill-Concelman, a threaded constant impedance version of aBNC connector

TP Trip (recorded fault)

TPZ, TPY, TPX, TPS Current transformer class according to IEC

TRM Transformer Module. This module transforms currents and voltages takenfrom the process into levels suitable for further signal processing.

TYP Type identification

UMT User management tool

Underreach A term used to describe how the relay behaves during a fault condition. Forexample, a distance relay is underreaching when the impedance presentedto it is greater than the apparent impedance to the fault applied to thebalance point, that is, the set reach. The relay does not “see” the fault butperhaps it should have seen it. See also Overreach.

UTC Coordinated Universal Time. A coordinated time scale, maintained by theBureau International des Poids et Mesures (BIPM), which forms the basis ofa coordinated dissemination of standard frequencies and time signals.UTC is derived from International Atomic Time (TAI) by the addition of awhole number of "leap seconds" to synchronize it with Universal Time 1(UT1), thus allowing for the eccentricity of the Earth's orbit, the rotationalaxis tilt (23.5 degrees), but still showing the Earth's irregular rotation, onwhich UT1 is based. The Coordinated Universal Time is expressed using a24-hour clock, and uses the Gregorian calendar. It is used for aeroplane andship navigation, where it is also sometimes known by the military name,"Zulu time." "Zulu" in the phonetic alphabet stands for "Z", which stands forlongitude zero.

UV Undervoltage



WEI Weak end infeed logic

VT Voltage transformer

X.21 A digital signalling interface primarily used for telecom equipment

3IO Three times zero-sequence current.Often referred to as the residual or theground-fault current

3VO Three times the zero sequence voltage. Often referred to as the residualvoltage or the neutral point voltage



93

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