Communication Protocol3-349-656-031/11.11 - PDF document

Communication Protocol3-349-656-031/11.1
Communication Protocol3-349-656-031/11.11 Communication Protocol3-349-656-031/11.11M-Bus communication protocol 59EnglishM-Bus communication protocol 57EnglishParameter SetValue (BValue (HEX)DPS611111111FFPhase 1, 2, 3 Exported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)3-Phase Exported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)Phase 1, 2, 3 Imported Capacitive Energy Total (Reactive from PS0 bit 1)3-Phase Imported Capacitive Energy Total (Reactive from PS0 bit 1)Phase 1, 2, 3 Exported Capacitive Energy Total (Reactive from PS0 bit 1)3-Phase Exported Capacitive Energy Total (Reactive from PS0 bit 1)Phase 1, 2, 3 Imported Capacitive Energy Tariff 1 (Reactive from PS0 bit 1)3-Phase Imported Capacitive Energy Tariff 1 (Reactive from PS0 bit 1)PS7011111117FPhase 1, 2, 3 Exported Capacitive Energy Tariff 1 (Reactive from PS0 bit 1)3-Phase Exported Capacitive Energy Tariff 1 (Reactive from PS0 bit 1)Phase 1, 2, 3 Imported Capacitive Energy Tariff 2 (Reactive from PS0 bit 1)3-Phase Imported Capacitive Energy Tariff 2 (Reactive from PS0 bit 1)Phase 1, 2, 3 Exported Capacitive Energy Tariff 2 (Reactive

from PS0 bit 1)3-Phase Exported Capaci
from PS0 bit 1)3-Phase Exported Capacitive Energy Tariff 2 (Reactive from PS0 bit 1)All Energy Balance (Reactive from PS0 bit 1)Table C9 – Reactive Mask ProleAnd so the Prole Reactive mask in HEX will be:00 42 18 00 C0 FF FF 7F- Setting the Prole APPARENT mask:Parameter SetValue (BValue (HEX)DPS00000001103From Bit 39 to Bit 50 Apparent Values has to be takenFrom Bit 51 to Bit 64 Apparent Values has to be takenPS10100000141Phase 1, 2, 3 Apparent PowerFrequencyPS20001100018Error CodeOut Of rangePS30000000000No one valuePS411000000C0Phase 1, 2, 3 Imported Inductive Energy Total (Apparent from PS0 bit 0)3-Phase Imported Inductive Energy Total (Apparent from PS0 bit 0)PS511111111FFPhase 1, 2, 3 Exported Inductive Energy Total (Apparent from PS0 bit 0)3-Phase Exported Inductive Energy Total (Apparent from PS0 bit 0)Phase 1, 2, 3 Imported Inductive Energy Tariff 1 (Apparent from PS0 bit 0)3-Phase Imported Inductive Energy Tariff 1 (Apparent from PS0 bit 0)Phase 1, 2, 3 Exported Inductive Energy Tariff 1 (Apparent from PS0 bit 0)3-Phase Exported Inductive Energy Tariff 1 (Apparent from PS0 bit

0)Phase 1, 2, 3 Imported Inductive Ene
0)Phase 1, 2, 3 Imported Inductive Energy Tariff 2 (Apparent from PS0 bit 0)3-Phase Imported Inductive Energy Tariff 2 (Apparent from PS0 bit 0)PS611111111FFPhase 1, 2, 3 Exported Inductive Energy Tariff 2 (Apparent from PS0 bit 0)3-Phase Exported Inductive Energy Tariff 2 (Apparent from PS0 bit 0)Phase 1, 2, 3 Imported Capacitive Energy Total (Apparent from PS0 bit 1)3-Phase Imported Capacitive Energy Total (Apparent from PS0 bit 1)Phase 1, 2, 3 Exported Capacitive Energy Total (Apparent from PS0 bit 1)3-Phase Exported Capacitive Energy Total (Apparent from PS0 bit 1)Phase 1, 2, 3 Imported Capacitive Energy Tariff 1 (Apparent from PS0 bit 1)3-Phase Imported Capacitive Energy Tariff 1 (Apparent from PS0 bit 1)56 M-Bus communication protocolEnglish- Setting the Prole ACTIVE mask:Parameter SetValue (BValue (HEX)DPS01000000080Phase 1, 2, 3 Active PowerPS10100000040FrequencyPS20001100018Error CodeOut Of rangePS311111111FFPhase 1, 2, 3 Imported Active Energy Total3-Phase Imported Active Energy TotalPhase 1, 2, 3 Exported Active Energy Total3-Phase Exported Active Energy TotalPhase 1, 2, 3 Imported Act

ive Energy Tariff 13-Phase Imported Act
ive Energy Tariff 13-Phase Imported Active Energy Tariff 1Phase 1, 2, 3 Exported Active Energy Tariff 13-Phase Exported Active Energy Tariff 1PS4000111111FPhase 1, 2, 3 Imported Active Energy Tariff 23-Phase Imported Active Energy Tariff 2Phase 1, 2, 3 Exported Active Energy Tariff 23-Phase Exported Active Energy Tariff 2All Active Energy BalancePS50000000000No one valuePS60000000000No one valuePS70000000000No one valueTable C8 – Active Mask ProleAnd so the Prole Active mask in HEX will be:80 40 18 FF 1F 00 00 00- Setting the Prole REACTIVE mask:Parameter SetValue (BValue (HEX)DPS00000000000From Bit 39 to Bit 50 Reactive Values has to be takenFrom Bit 51 to Bit 64 Reactive Values has to be takenPS10100001042Phase 1, 2, 3 Reactive PowerFrequencyPS20001100018Error CodeOut Of rangePS30000000000No one valuePS411000000C0Phase 1, 2, 3 Imported Inductive Energy Total (Reactive from PS0 bit 0)3-Phase Imported Inductive Energy Total (Reactive from PS0 bit 0)PS511111111FFPhase 1, 2, 3 Exported Inductive Energy Total (Reactive from PS0 bit 0)3-Phase Exported Inductive Energy Total

(Reactive from PS0 bit 0)Phase 1, 2, 3
(Reactive from PS0 bit 0)Phase 1, 2, 3 Imported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)3-Phase Imported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)Phase 1, 2, 3 Exported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)3-Phase Exported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)Phase 1, 2, 3 Imported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)3-Phase Imported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)M-Bus communication protocol 55EnglishParameter SetValue (BValue (HEX)DPS111111111FFPhase 1, 2, 3 Apparent PowerPhase 1, 2, 3 Reactive PowerPhase 1, 2, 3, Sys VoltageLine 12, 23, 31 VoltagePhase 1, 2, 3, N, Sys CurrentPhase 1, 2, 3, Sys Power FactorFrequencyPhase OrderPS211011111DFActual TariffCT Value, FSA ValuePri/Sec ValueError CodeOut Of rangeSerial Number, FW Release EC, HW Version EC, Model, TypeFW Release and HW Version M-BUS ModulePS30000000000No one valuePS40001000010All Active Energy BalancePS50000000000No one valuePS60000000000No one valuePS70000000000No one valueTable C6 – Real Time Mask ProleAnd so the Prole Real Time

mask in HEX will be:90 FF DF 00 10 00 0
mask in HEX will be:90 FF DF 00 10 00 00 00- Setting the Prole PARTIAL mask:Parameter SetValue (BValue (HEX)DPS00010000020All Apparent and Reactive Energy PartialPS10000000000No one valuePS20011100038Error CodeOut Of rangePartial Counters StatusPS30000000000No one valuePS40010000020All Active Energy PartialPS50000000000No one valuePS60000000000No one valuePS70000000000No one valueTable C7 – Partial Mask ProleAnd so the Prole Partial mask in HEX will be:20 00 38 00 20 00 00 0054 M-Bus communication protocolEnglishAnd so the Prole Tariff 1 mask in HEX will be:04 00 18 F0 00 00 00 00- Setting the Prole TARIFF 2 mask:Parameter SetValue (BValue (HEX)DPS00100000040All Apparent and Reactive Energy Tariff 2PS10000000000No one valuePS20001100018Error CodeOut Of rangePS30000000000No one valuePS4000011110FPhase 1, 2, 3 Imported Active Energy Tariff 23-Phase Imported Active Energy Tariff 2Phase 1, 2, 3 Exported Active Energy Tariff 23-Phase Exported Active Energy Tariff 2PS50000000000No one valuePS60000000000No one valuePS70000000000N

o one valueTable C4 – Tariff 2 M
o one valueTable C4 – Tariff 2 Mask ProleAnd so the Prole Tariff 2 mask in HEX will be:40 00 18 00 F0 00 00 00- Setting the Prole TOTAL ENERGY mask:Parameter SetValue (BValue (HEX)DPS00000100008All Apparent and Reactive Energy TotalPS10000000000No one valuePS20001100018Error CodeOut Of rangePS3000011110FPhase 1, 2, 3 Imported Active Energy Total3-Phase Imported Active Energy TotalPhase 1, 2, 3 Exported Active Energy Total3-Phase Exported Active Energy TotalPS40000000000No one valuePS50000000000No one valuePS60000000000No one valuePS70000000000No one valueTable C5 – Total Energy Mask ProleAnd so the Prole Total Energy mask in HEX will be:08 00 18 0F 00 00 00 00- Setting the Prole REAL TIME mask:Parameter SetValue (BValue (HEX)DPS01001000090All Apparent and Reactive Energy BalancePhase 1, 2, 3 Active PowerM-Bus communication protocol 53EnglishParameter SetValue (BValue (HEX)DPS411001111CFPhase 1, 2, 3 Imported Active Energy Tariff 23-Phase Imported Active Energy Tariff 2Phase 1, 2, 3 Exported Active Energy Tariff 23-Phase Exporte

d Active Energy Tariff 2Phase 1, 2, 3 I
d Active Energy Tariff 2Phase 1, 2, 3 Imported Inductive Energy Total (Reactive from PS0 bit 0)3-Phase Imported Inductive Energy Total (Reactive from PS0 bit 0)PS511111111FFPhase 1, 2, 3 Exported Inductive Energy Total (Reactive from PS0 bit 0)3-Phase Exported Inductive Energy Total (Reactive from PS0 bit 0)Phase 1, 2, 3 Imported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)3-Phase Imported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)Phase 1, 2, 3 Exported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)3-Phase Exported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)Phase 1, 2, 3 Imported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)3-Phase Imported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)PS611111111FFPhase 1, 2, 3 Exported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)3-Phase Exported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)Phase 1, 2, 3 Imported Capacitive Energy Total (Reactive from PS0 bit 0)3-Phase Imported Capacitive Energy Total (Reactive from PS0 bit 0)Phase 1, 2, 3 Exported Capacitive Energy Total (Reactive from PS0 bit 0)3-Phase Exported Capacitive Energy Total (Reacti

ve from PS0 bit 0)Phase 1, 2, 3 Importe
ve from PS0 bit 0)Phase 1, 2, 3 Imported Capacitive Energy Tariff 1 (Reactive from PS0 bit 0)3-Phase Imported Capacitive Energy Tariff 1 (Reactive from PS0 bit 0)PS7001111113FPhase 1, 2, 3 Exported Capacitive Energy Tariff 1 (Reactive from PS0 bit 0)3-Phase Exported Capacitive Energy Tariff 1 (Reactive from PS0 bit 0)Phase 1, 2, 3 Imported Capacitive Energy Tariff 2(Reactive from PS0 bit 0)3-Phase Imported Capacitive Energy Tariff 2 (Reactive from PS0 bit 0)Phase 1, 2, 3 Exported Capacitive Energy Tariff 2 (Reactive from PS0 bit 0)3-Phase Exported Capacitive Energy Tariff 2 (Reactive from PS0 bit 0)Table C2 – Energy T1 & T2 Mask ProleAnd so the Prole Energy T1 e T2 mask in HEX will be:00 00 18 FF CF FF FF 3F- Setting the Prole TARIFF 1 mask:Parameter SetValue (BValue (HEX)DPS00000010004All Apparent and Reactive Energy Tariff 1PS10000000000No one valuePS20001100018Error CodeOut Of rangePS311110000F0Phase 1, 2, 3 Imported Active Energy Tariff 13-Phase Imported Active Energy Tariff 1Phase 1, 2, 3 Exported Active Energy Tariff 13-Phase Exported Active Energy Tariff 1PS40000000000No one valu

ePS50000000000No one valuePS600000
ePS50000000000No one valuePS60000000000No one valuePS70000000000No one valueTable C3 – Tariff 1 Mask Prole52 M-Bus communication protocolEnglishAHere follows the structure of every default mask.- Setting the Prole DEFAULT mask:Parameter SetValue (BValue (HEX)DPS00000000000From Bit 39 to Bit 50 Reactive Values has to be takenFrom Bit 51 to Bit 64 Reactive Values has to be takenPS10000000000No One ValuePS2000111111FActual TariffCT Value, FSA ValuePri/Sec ValueError CodeOut Of rangePS310100000A03-Phase Imported Active Energy Tariff 13-Phase Exported Active Energy Tariff 1PS4000010100A3-Phase Imported Active Energy Tariff 23-Phase Exported Active Energy Tariff 2PS510101000A83-Phase Imported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)3-Phase Exported Inductive Energy Tariff 1 (Reactive from PS0 bit 0)3-Phase Imported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)PS610000010823-Phase Exported Inductive Energy Tariff 2 (Reactive from PS0 bit 0)3-Phase Imported Capacitive Energy Tariff 1 (Reactive from PS0 bit 1)PS7001010102A3-Phase Exported Capacitive Energy

Tariff 1 (Reactive from PS0 bit 1)3-Pha
Tariff 1 (Reactive from PS0 bit 1)3-Phase Imported Capacitive Energy Tariff 2 (Reactive from PS0 bit 1)3-Phase Exported Capacitive Energy Tariff 2 (Reactive from PS0 bit 1)Table C1 – Default Mask ProleAnd so the Prole Default mask in HEX will be:00 00 1F A0 0A A8 82 2A- Setting the Prole ENERGY T1 e T2 mask:Parameter SetValue (BValue (HEX)DPS00000000000From Bit 39 to Bit 50 Reactive Values has to be takenFrom Bit 51 to Bit 64 Reactive Values has to be takenPS10000000000No one valuePS20001100018Error CodeOut Of rangePS311111111FFPhase 1, 2, 3 Imported Active Energy Total3-Phase Imported Active Energy TotalPhase 1, 2, 3 Exported Active Energy Total3-Phase Exported Active Energy TotalPhase 1, 2, 3 Imported Active Energy Tariff 13-Phase Imported Active Energy Tariff 1Phase 1, 2, 3 Exported Active Energy Tariff 13-Phase Exported Active Energy Tariff 1M-Bus communication protocol 51EnglishBit Nr.Bit alueMeasure UnitBitParameter Set41Phase 1, 2, 3 Exported Inductive Energy Total (Reactive or Apparent)0.1varh/0.1VAhxxxx xxx1bPS5423-Phase Exported Inductive Energy Total (Reactive

or Apparent)0.1varh/0.1VAhxxxx xx1xb
or Apparent)0.1varh/0.1VAhxxxx xx1xb43Phase 1, 2, 3 Imported Inductive Energy Tariff 1 (Reactive or Apparent)0.1varh/0.1VAhxxxx x1xxb443-Phase Imported Inductive Energy Tariff 1 (Reactive or Apparent)0.1varh/0.1VAhxxxx 1xxxb45Phase 1, 2, 3 Exported Inductive Energy Tariff 1 (Reactive or Apparent)0.1varh/0.1VAhxxx1 xxxxb463-Phase Exported Inductive Energy Tariff 1 (Reactive or Apparent)0.1varh/0.1VAhxx1x xxxxb47Phase 1, 2, 3 Imported Inductive Energy Tariff 2 (Reactive or Apparent)0.1varh/0.1VAhx1xx xxxxb483-Phase Imported Inductive Energy Tariff 2 (Reactive or Apparent)0.1varh/0.1VAh1xxx xxxxb49Phase 1, 2, 3 Exported Inductive Energy Tariff 2 (Reactive or Apparent)0.1varh/0.1VAhxxxx xxx1bPS6503-Phase Exported Inductive Energy Tariff 2 (Reactive or Apparent)0.1varh/0.1VAhxxxx xx1xb51Phase 1, 2, 3 Imported Capacitive Energy Total (Reactive or Apparent)0.1varh/0.1VAhxxxx x1xxb523-Phase Imported Capacitive Energy Total (Reactive or Apparent)0.1varh/0.1VAhxxxx 1xxxb53Phase 1, 2, 3 Exported Capacitive Energy Total (Reactive or Apparent)0.1varh/0.1VAhxxx1 xxxxb543-Phase Exported Capacitive Energy To

tal (Reactive or Apparent)0.1varh/0.1V
tal (Reactive or Apparent)0.1varh/0.1VAhxx1x xxxxb55Phase 1, 2, 3 Imported Capacitive Energy Tariff 1 (Reactive or Apparent)0.1varh/0.1VAhx1xx xxxxb563-Phase Imported Capacitive Energy Tariff 1 (Reactive or Apparent)0.1varh/0.1VAh1xxx xxxxb57Phase 1, 2, 3 Exported Capacitive Energy Tariff 1 (Reactive or Apparent)0.1varh/0.1VAhxxxx xxx1bPS7583-Phase Exported Capacitive Energy Tariff 1 (Reactive or Apparent)0.1varh/0.1VAhxxxx xx1xb59Phase 1, 2, 3 Imported Capacitive Energy Tariff 2 (Reactive or Apparent)0.1varh/0.1VAhxxxx x1xxb603-Phase Imported Capacitive Energy Tariff 2 (Reactive or Apparent)0.1varh/0.1VAhxxxx 1xxxb61Phase 1, 2, 3 Exported Capacitive Energy Tariff 2 (Reactive or Apparent)0.1varh/0.1VAhxxx1 xxxxb623-Phase Exported Capacitive Energy Tariff 2 (Reactive or Apparent)0.1varh/0.1VAhxx1x xxxxb63All Energy Balance (Reactive or Apparent)0.1varh/0.1VAhx1xx xxxxb64All Energy Partial (Reactive or Apparent)0.1varh/0.1VAh1xxx xxxxbTable B1 –Bit Division of Every Parameter Set Byte50 M-Bus communication protocolEnglishAHere follows the bit division of every Parameter Set byte:Bit N

r.Bit alueMeasure UnitBitParameter
r.Bit alueMeasure UnitBitParameter Set1From Bit 39 To Bit 50 - Reactive (0b) or Apparent (1b)-xxxx xxx1bPS02From Bit 51 To Bit 64 - Reactive (0b) or Apparent (1b)-xxxx xx1xb3All Apparent and Reactive Energy Tariff 1 0.1varh & 0.1VAhxxxx x1xxb4All Apparent and Reactive Energy Total0.1varh & 0.1VAhxxxx 1xxxb5All Apparent and Reactive Energy Balance0.1varh & 0.1VAhxxx1 xxxxb6All Apparent and Reactive Energy Partial0.1varh & 0.1VAhxx1x xxxxb7All Apparent and Reactive Energy Tariff 20.1varh & 0.1VAhx1xx xxxxb8Phase 1, 2, 3, Sys Active PowermW1xxx xxxxb9Phase 1, 2, 3, Sys Apparent PowermVAxxxx xxx1bPS110Phase 1, 2, 3, Sys Reactive Powermvarxxxx xx1xb11Phase 1, 2, 3, Sys VoltagemVxxxx x1xxb12Line 12, 23, 31 VoltagemVxxxx 1xxxb13Phase 1, 2, 3, N, Sys CurrentmAxxx1 xxxxb14Phase 1, 2, 3, Sys Power Factor-xx1x xxxxb15FrequencymHzx1xx xxxxb16Phase Order-1xxx xxxxb17Actual Tariff-xxxx xxx1bPS218CT Value, FSA Value-xxxx xx1xb19Pri/Sec Value-xxxx x1xxb20Error Code-xxxx 1xxxb21Out Of Range-xxx1 xxxxb22Partial Counter Status-xx1x xxxxb23Serial Number, FW Release EC, HW Ver

sion EC, Model, Type-x1xx xxxxb24FW
sion EC, Model, Type-x1xx xxxxb24FW Release, HW Version and Fabrication Number of M-BUS Module-1xxx xxxxb25Phase 1, 2, 3 Imported Active Energy Total0.1Whxxxx xxx1bPS3263-Phase Imported Active Energy Total0.1Whxxxx xx1xb27Phase 1, 2, 3 Exported Active Energy Total0.1Whxxxx x1xxb283-Phase Exported Active Energy Total0.1Whxxxx 1xxxb29Phase 1, 2, 3 Imported Active Energy Tariff 10.1Whxxx1 xxxxb303-Phase Imported Active Energy Tariff 10.1Whxx1x xxxxb31Phase 1, 2, 3 Exported Active Energy Tariff 10.1Whx1xx xxxxb323-Phase Exported Active Energy Tariff 10.1Wh1xxx xxxxb33Phase 1, 2, 3 Imported Active Energy Tariff 20.1Whxxxx xxx1bPS4343-Phase Imported Active Energy Tariff 20.1Whxxxx xx1xb35Phase 1, 2, 3 Exported Active Energy Tariff 20.1Whxxxx x1xxb363-Phase Exported Active Energy Tariff 20.1Whxxxx 1xxxb37All Active Energy Balance0.1Whxxx1 xxxxb38All Active Energy Partial0.1Whxx1x xxxxb39Phase 1, 2, 3 Imported Inductive Energy Total (Reactive or Apparent)0.1varh/0.1VAhx1xx xxxxb403-Phase Imported Inductive Energy Total (Reactive or Apparent)0.1varh/0.1VAh1xxx xxxxb44 M-Bus commu

nication protocolEnglish3.1.4.45 3-Pha
nication protocolEnglish3.1.4.45 3-Phase Active Energy BalanceByte Nr.Size (Byte)Value (HEX)DYY106DIF – 48 Bit Integer, 6 ByteYY + 1182VIF: Active Energy, 0.1Wh; Followed by VIFEYY + 21FFVIFE followed by MANUFACTURER specic VIFEYY + 3183MANUFACTURER specic VIFE: Balance; Followed by VIFEYY + 41FFVIFE followed by MANUFACTURER specic VIFEYY + 7100MANUFACTURER specic VIFE: 3-PhaseYY + 8 – YY + 136xx xx xx xx xx xxValue: 3-Phase Active Energy BalanceTable 3.67 – 3-Phase Active Energy Balancenductive and Capacitive Apparent Energy BalanceByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2140DIFE: Apparent ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4191VIFE: Apparent Energy, 0.1VAh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 6183MANUFACTURER specic VIFE: Balance; Followed by VIFEYY + 71FFVIFE followed by MANUFACTURER specic VIFEYY + 81x4MANUFACTURER specic VIFE:2: 3-Phase Inductive4: 3-Phase Capacitiv

eYY + 9 – YY + 146xx xx xx xx xx
eYY + 9 – YY + 146xx xx xx xx xx xxValue: 3-Phase Inductive and Capacitive Apparent Energy BalanceTable 3.68 – 3-Phase Inductive and Capacitive Apparent Energy Balancenductive and Capacitive Reactive Energy BalanceByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2100DIFE: Reactive ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4193VIFE: Reactive Energy, 0.1varh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 6183MANUFACTURER specic VIFE: Balance; Followed by VIFEYY + 71FFVIFE followed by MANUFACTURER specic VIFEYY + 81x4MANUFACTURER specic VIFE:2: 3-Phase Inductive4: 3-Phase CapacitiveYY + 9 – YY + 146xx xx xx xx xx xxValue: 3-Phase Inductive and Capacitive Reactive Energy BalanceTable 3.69 – 3-Phase Inductive and Capacitive Reactive Energy BalanceM-Bus communication protocol 43EnglishByte Nr.Size (Byte)Value (HEX)DYY + 2140DIFE: Apparent ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4191VIFE: Appar

ent Energy, 0.1VAh; Followed by VIFEYY
ent Energy, 0.1VAh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 6182MANUFACTURER specic VIFE: Partial; Followed by VIFEYY + 71FFVIFE followed by MANUFACTURER specic VIFEYY + 81x0MANUFACTURER specic VIFE:3: 3-Phase Imported Capacitive4: 3-Phase Exported CapacitiveYY + 9 – YY + 146xx xx xx xx xx xxValue: 3-Phase Imported and Exported Capacitive Apparent Energy PartialTable 3.64 – 3-Phase Imported and Exported Capacitive Apparent Energy Partialmported and Exported nductive Reactive Energy PartialByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2100DIFE: Reactive ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4193VIFE: Reactive Energy, 0.1varh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 6182MANUFACTURER specic VIFE: Partial; Followed by VIFEYY + 71FFVIFE followed by MANUFACTURER specic VIFEYY + 81x0MANUFACTURER specic VIFE:1: 3-Phase Imported Inductive2: 3-Phase Exported InductiveYY + 9

50; YY + 146xx xx xx xx xx xxValue: 3
50; YY + 146xx xx xx xx xx xxValue: 3-Phase Imported and Exported Inductive Reactive Energy PartialTable 3.65 – 3-Phase Imported and Exported Inductive Reactive Energy Partialmported and Exported Capacitive Reactive Energy PartialByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2100DIFE: Reactive ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4193VIFE: Reactive Energy, 0.1varh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 6182MANUFACTURER specic VIFE: Partial; Followed by VIFEYY + 71FFVIFE followed by MANUFACTURER specic VIFEYY + 81x0MANUFACTURER specic VIFE:3: 3-Phase Imported Inductive4: 3-Phase Exported InductiveYY + 9 – YY + 146xx xx xx xx xx xxValue: 3-Phase Imported and Exported Capacitive Reactive Energy PartialTable 3.66 – 3-Phase Imported and Exported Capacitive Reactive Energy Partial42 M-Bus communication protocolEnglishByte Nr.Size (Byte)Value (HEX)DYY + 610xMANUFACTURER specic VIFE:0: 3-Phase1: Phase 12: P

hase 23: Phase 3YY + 7 – YY + 12
hase 23: Phase 3YY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Reactive PowerTable 3.61 – 3-Phase, Phase 1, Phase 2 and Phase 3 Reactive Powermported and Exported Active Energy PartialByte Nr.Size (Byte)Value (HEX)DYY106DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1182VIF: Active Energy, 0.1Wh; Followed by VIFEYY + 21FFVIFE followed by MANUFACTURER specic VIFEYY + 318xMANUFACTURER specic VIFE:0: Imported Energy1: Exported EnergyFollowed by VIFEYY + 41FFVIFE followed by MANUFACTURER specic VIFEYY + 5182MANUFACTURER specic VIFE: Partial; Followed by VIFEYY + 61FFVIFE followed by MANUFACTURER specic VIFEYY + 7100MANUFACTURER specic VIFE: 3-PhaseYY + 8 – YY + 136xx xx xx xx xx xxValue: 3-Phase Imported and Exported Active Energy PartialTable 3.62 – 3-Phase Imported and Exported Active Energy Partialmported and Exported nductive Apparent Energy PartialByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2140DIFE: Apparent V

alueYY + 31FFVIF followed by MANUFAC
alueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4191VIFE: Apparent Energy, 0.1VAh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 6182MANUFACTURER specic VIFE: Partial; Followed by VIFEYY + 71FFVIFE followed by MANUFACTURER specic VIFEYY + 81x0MANUFACTURER specic VIFE:1: 3-Phase Imported Inductive2: 3-Phase Exported InductiveYY + 9 – YY + 146xx xx xx xx xx xxValue: 3-Phase Imported and Exported Inductive Apparent Energy PartialTable 3.63 – 3-Phase Imported and Exported Inductive Apparent Energy Partialmported and Exported Capacitive Apparent Energy PartialByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEM-Bus communication protocol 41EnglishByte Nr.Size (Byte)Value (HEX)DYY + 410xMANUFACTURER specic VIFE:0: 3-Phase1: Phase 12: Phase 23: Phase 3YY + 5 – YY + 62xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Power FactorTable 3.58 – 3-Phase, Phase 1, Phase 2 and Phase 3 Power Factor3.1.4.37 3-Phase, Phase 1, Phase 2 and Phas

e 3 Active PowerByte Nr.Size (Byte)Va
e 3 Active PowerByte Nr.Size (Byte)Value (HEX)DYY106DIF – 48 Bit Integer, 6 ByteYY + 11A8VIF: Active Power, mW; Followed by VIFEYY + 21FFVIFE followed by MANUFACTURER specic VIFEYY + 310xMANUFACTURER specic VIFE:0: 3-Phase1: Phase 12: Phase 23: Phase 3YY + 4 – YY + 96xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Active PowerTable 3.59 – 3-Phase, Phase 1, Phase 2 and Phase 3 Active Power3.1.4.38 3-Phase, Phase 1, Phase 2 and Phase 3 Apparent PowerByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2140DIFE: Apparent PowerYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4190VIFE: Apparent Power, mVa; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 610xMANUFACTURER specic VIFE:0: 3-Phase1: Phase 12: Phase 23: Phase 3YY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Apparent PowerTable 3.60 – 3-Phase, Phase 1, Phase 2 and Phase 3 Apparent Power3.1.4.39 3-Phase, Phase 1, Phase 2 and Phas

e 3 Reactive PowerByte Nr.Size (Byte)
e 3 Reactive PowerByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2100DIFE: Reactive PowerYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4192VIFE: Reactive Power, mvar; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFE40 M-Bus communication protocolEnglish3.1.4.33 3-Phase, Phase 1, Phase 2, Phase 3 and Neutral CurrentByte Nr.Size (Byte)Value (HEX)DYY104DIF – 32 Bit Integer, 4 ByteYY + 11FDVIF: Followed by a standard VIFEYY + 21D9VIFE: Current (mA) followed by a VIFEYY + 31FFVIFE followed by MANUFACTURER specic VIFEYY + 410xMANUFACTURER specic VIFE:0: 3-Phase1: Phase 12: Phase 23: Phase 34: NeutralYY + 5 – YY + 74xx xx xx xxValue: 3-Phase, Phase 1, Phase 2, Phase 3 and Nuetral CurrentTable 3.55 – 3-Phase, Phase 1, Phase 2, Phase 3 and Neutral Current3.1.4.34 FrequencyByte Nr.Size (Byte)Value (HEX)DYY102DIF – 16 Bit Integer, 2 ByteYY + 11FFVIF followed by MANUFACTURER specic VIFEYY + 2194MANUFACTURER specic VIFE:

mHzYY + 31FFVIFE followed by MANUFA
mHzYY + 31FFVIFE followed by MANUFACTURER specic VIFEYY + 4150MANUFACTURER specic VIFE: Frequency (mHz)YY + 5 – YY + 62xx xxValue: FrequencyTable 3.56 – Frequency3.1.4.35 Phase OrderByte Nr.Size (Byte)Value (HEX)DYY101DIF – 8 Bit Integer, 1 ByteYY + 11FFVIF followed by MANUFACTURER specic VIFEYY + 2151MANUFACTURER specic VIFE: Phase OrderYY + 31xxValue: Phase Order00: No Phase Order 7B: 12384: 132Table 3.57 – Phase Order3.1.4.36 3-Phase, Phase 1, Phase 2 and Phase 3 Power FactorByte Nr.Size (Byte)Value (HEX)DYY102DIF – 16 Bit Integer, 2 ByteYY + 11FFVIF followed by MANUFACTURER specic VIFEYY + 2184MANUFACTURER specic VIFE: Power Factor; Followed by VIFEYY + 31FFVIFE followed by MANUFACTURER specic VIFE34 M-Bus communication protocolEnglishByte Nr.Size (Byte)Value (HEX)DYY + 614xMANUFACTURER specic VIFE:0: 3-Phase Exported Capacitive1: Phase 1 Exported Capacitive2: Phase 2 Exported Capacitive3: Phase 3 Exported CapacitiveYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 E

xported Capacitive Apparent Energy, Tar
xported Capacitive Apparent Energy, Tariff 1Table 3.38 – 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Capacitive Apparent Energy, Tariff 1mported nductive Reactive Energy, Tariff 1Byte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1190DIFE: Tariff 1; Followed by DIFEYY + 2100DIFE: Reactive ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4193VIFE: Reactive Energy, 0.1varh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 611xMANUFACTURER specic VIFE:0: 3-Phase Imported Inductive1: Phase 1 Imported Inductive2: Phase 2 Imported Inductive3: Phase 3 Imported InductiveYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Inductive Reactive Energy, Tariff 1Table 3.39 – 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Inductive Reactive Energy, Tariff 13.1.4.18 3-Phase, Phase 1, Phase 2 and Phase 3 Exported nductive Reactive Energy, Tariff 1Byte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1190DIFE: Tariff 1; Followed by DIFE

YY + 2100DIFE: Reactive ValueYY + 3
YY + 2100DIFE: Reactive ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4193VIFE: reactive Energy, 0.1varh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 612xMANUFACTURER specic VIFE:0: 3-Phase Exported Inductive1: Phase 1 Exported Inductive2: Phase 2 Exported Inductive3: Phase 3 Exported InductiveYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Inductive Reactive Energy, Tariff 1Table 3.40 – 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Inductive Reactive Energy, Tariff 1mported Capacitive Reactive Energy, Tariff 1Byte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEM-Bus communication protocol 33EnglishByte Nr.Size (Byte)Value (HEX)DYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Inductive Apparent Energy, Tariff 1Table 3.35 – 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Inductive Apparent Energy, Tariff 13.1.4.14 3-Phase, Phase 1, Phase 2 and Phase 3 Exported nductive Apparent Energy, Tariff 1Byte Nr.Size (

Byte)Value (HEX)DYY186DIF – 4
Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1190DIFE: Tariff 1; Followed by DIFEYY + 2140DIFE: Apparent ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4191VIFE: Apparent Energy, 0.1VAh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 612xMANUFACTURER specic VIFE:0: 3-Phase Exported Inductive1: Phase 1 Exported Inductive2: Phase 2 Exported Inductive3: Phase 3 Exported InductiveYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Inductive Apparent Energy, Tariff 1Table 3.36 – 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Inductive Apparent Energy, Tariff 1mported Capacitive Apparent Energy, Tariff 1Byte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1190DIFE: Tariff 1; Followed by DIFEYY + 2140DIFE: Apparent ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4191VIFE: Apparent Energy, 0.1VAh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 613xMANUFACTURER specic VIFE:

0: 3-Phase Imported Capacitive1: Phase
0: 3-Phase Imported Capacitive1: Phase 1 Imported Capacitive2: Phase 2 Imported Capacitive3: Phase 3 Imported CapacitiveYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Capacitive Apparent Energy, Tariff 1Table 3.37 – 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Capacitive Apparent Energy, Tariff 13.1.4.16 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Capacitive Apparent Energy, Tariff 1Byte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1190DIFE: Tariff 1; Followed by DIFEYY + 2140DIFE: Apparent ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4191VIFE: Apparent Energy, 0.1VAh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFE32 M-Bus communication protocolEnglishmported Active Energy, Tariff 1Byte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1110DIFE: Tariff 1YY + 2182VIF: Energy, 0.1Wh; Followed by VIFEYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4180VIFE: Imported Energy; Followed by VIFEYY + 5

1FFVIFE followed by MANUFACTURER speci
1FFVIFE followed by MANUFACTURER specic VIFEYY + 610xMANUFACTURER specic VIFE:0: 3-Phase1: Phase 12: Phase 23: Phase 3YY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Active Energy, Tariff 1Table 3.33 – 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Active Energy, Tariff 13.1.4.12 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Active Energy, Tariff 1Byte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1110DIFE: Tariff 1YY + 2182VIF: Energy, 0.1Wh; Followed by VIFEYY + 31FFVIFE followed by MANUFACTURER specic VIFEYY + 4181VIFE: Exported Energy; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 610xMANUFACTURER specic VIFE:0: 3-Phase1: Phase 12: Phase 23: Phase 3YY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Active Energy, Tariff 1Table 3.34 – 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Active Energy, Tariff 1mported nductive Apparent Energy, Tariff 1Byte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit

Integer, 6 Byte; Followed by DIFEYY +
Integer, 6 Byte; Followed by DIFEYY + 1190DIFE: Tariff 1; Followed by DIFEYY + 2140DIFE: Apparent ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4191VIFE: Apparent Energy, 0.1VAh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 6 – YY + 1111xMANUFACTURER specic VIFE:0: 3-Phase Imported Inductive1: Phase 1 Imported Inductive2: Phase 2 Imported Inductive3: Phase 3 Imported InductiveM-Bus communication protocol 31EnglishByte Nr.Size (Byte)Value (HEX)DYY + 612xMANUFACTURER specic VIFE:0: 3-Phase Exported Inductive1: Phase 1 Exported Inductive2: Phase 2 Exported Inductive3: Phase 3 Exported InductiveYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Inductive Reactive Energy, TotalTable 3.30 – 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Inductive Reactive Energy, Totalmported Capacitive Reactive Energy, TotalByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2100DIFE: Reactive ValueYY + 31FFVIF f

ollowed by MANUFACTURER specic VIFE
ollowed by MANUFACTURER specic VIFEYY + 4193VIFE: Reactive Energy, 0.1varh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 613xMANUFACTURER specic VIFE:0: 3-Phase Imported Capacitive1: Phase 1 Imported Capacitive2: Phase 2 Imported Capacitive3: Phase 3 Imported CapacitiveYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Capacitive Reactive Energy, TotalTable 3.31 – 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Capacitive Reactive Energy, Total3.1.4.10 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Capacitive Reactive Energy, TotalByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2100DIFE: Reactive ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4193VIFE: Reactive Energy, 0.1varh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 614xMANUFACTURER specic VIFE:0: 3-Phase Exported Capacitive1: Phase 1 Exported Capacitive2: Phase 2 Exported Capacitive3: Phase 3 Exported CapacitiveYY + 7&

#150; YY + 126xx xx xx xx xx xxValue:
#150; YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Capacitive Reactive Energy, TotalTable 3.32 – 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Capacitive Reactive Energy, Total30 M-Bus communication protocolEnglishByte Nr.Size (Byte)Value (HEX)DYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Capacitive Apparent Energy, TotalTable 3.27 – 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Capacitive Apparent Energy, Total3.1.4.6 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Capacitive Apparent Energy, TotalByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2140DIFE: Apparent ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4191VIFE: Apparent Energy, 0.1VAh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 614xMANUFACTURER specic VIFE:0: 3-Phase Exported Capacitive1: Phase 1 Exported Capacitive2: Phase 2 Exported Capacitive3: Phase 3 Exported CapacitiveYY + 7 – YY + 126xx xx xx

xx xx xxValue: 3-Phase, Phase 1, Phase
xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Capacitive Apparent Energy, TotalTable 3.28 – 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Capacitive Apparent Energy, Totalmported nductive Reactive Energy, TotalByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 1180DIFE: Total; Followed by DIFEYY + 2100DIFE: Reactive ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4193VIFE: Reactive Energy, 0.1varh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFEYY + 611xMANUFACTURER specic VIFE:0: 3-Phase Imported Inductive1: Phase 1 Imported Inductive2: Phase 2 Imported Inductive3: Phase 3 Imported InductiveYY + 7 – YY + 126xx xx xx xx xx xxValue: 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Inductive Reactive Energy, TotalTable 3.29 – 3-Phase, Phase 1, Phase 2 and Phase 3 Imported Inductive Reactive Energy, Total3.1.4.8. 3-Phase, Phase 1, Phase 2 and Phase 3 Exported Inductive Reactive Energy, TotalByte Nr.Size (Byte)Value (HEX)DYY186DIF – 48 Bit Integer, 6 Byte; Followed by DIFEYY + 118

0DIFE: Total; Followed by DIFEYY + 21
0DIFE: Total; Followed by DIFEYY + 2100DIFE: Reactive ValueYY + 31FFVIF followed by MANUFACTURER specic VIFEYY + 4193VIFE: reactive Energy, 0.1varh; Followed by VIFEYY + 51FFVIFE followed by MANUFACTURER specic VIFE24 M-Bus communication protocolEnglishHere follows the command, using the Secondary Address of the Slave:Byte Nr.Size (Byte)Value (HEX)D1168Start character long query2111L-Field3111L-Field Ripetition4168Start character long query ripetition5173C-Field SND_UD61FDA-Field, Primary Address = 253, i.e. take the secondary address7151CI-Field8 – 158xx xx xx xx xx xx xx xxSecondary Address UD (See the relative paragraph)16101DIF: 8 Bit Integer, 1 Byte171FFVIF followed by manufacturer specic VIFE18182VIFE: Partial Counters191FFVIFE followed by manufacturer specic VIFE20172VIFE: Stop Counters211xxValue: Kind of Energy00: Imported Active Energy01: Exported Active Energy02: Imported Inductive Apparent Energy03: Exported Inductive Apparent Energy04: Imported Capacitive Apparent Energy05: Exported Capacitive Apparent Energy06: Imported I

nductive Reactive Energy07: Exported In
nductive Reactive Energy07: Exported Inductive Reactive Energy08: Imported Capacitive Reactive Energy09: Exported Capacitive Reactive Energy0A: ALL partial counters221xxCS Checksum, summed from C-Field to Selected Parameter of Parameter Set 19 (byt�e 5 byte 21)23116Stop characterTable 3.16 – SND_UD command: Stop Partial Energy Counter Using Secondary AddressAnswer of the Slave: E5h3.1.2.8 Select a Slave Using Secondary AddressHere follows the command to select a Slave by Secondary Address:Byte Nr.Size (Byte)Value (HEX)D1168Start character long query210BL-Field310BL-Field Ripetition4168Start character long query ripetition5173C-Field SND_UD61FDA-Field, Primary Address = 253, i.e. take the secondary address7152CI-Field8 – 158xx xx xx xx xx xx xx xxSecondary Address UD (See the relative paragraph)M-Bus communication protocol 23EnglishByte Nr.Size (Byte)Value (HEX)D211xxValue: Kind of Energy00: Imported Active Energy01: Exported Active Energy02: Imported Inductive Apparent Energy03: Exported Inductive Apparent Energy04: Imported Capacitive Apparent Energy05: Exp

orted Capacitive Apparent Energy06: Imp
orted Capacitive Apparent Energy06: Imported Inductive Reactive Energy07: Exported Inductive Reactive Energy08: Imported Capacitive Reactive Energy09: Exported Capacitive Reactive Energy0A: ALL partial counters221xxCS Checksum, summed from C-Field to Selected Parameter of Parameter Set 19 (byt�e 5 byte 21)23116Stop characterTable 3.14 – SND_UD command: Start Partial Energy Counter Using Secondary AddressAnswer of the Slave: E5h3.1.2.7 Stop Partial Energy CountersHere follows the command, using the Primary Address of the Slave:Byte Nr.Size (Byte)Value (HEX)D1168Start character long query2109L-Field3109L-Field Ripetition4168Start character long query ripetition5173C-Field SND_UD61xxA-Field, Primary Address (00-FF = 0-255)7151CI-Field8101DIF: 8 Bit Integer, 1 Byte91FFVIF followed by manufacturer specic VIFE10182VIFE: Partial Counters111FFVIFE followed by 3E specic VIFE12172Manufacturer specic VIFE: Stop Counter131xxValue: Kind of Energy00: Imported Active Energy01: Exported Active Energy02: Imported Inductive Apparent Energy03: Exported Inductive A

pparent Energy04: Imported Capacitive A
pparent Energy04: Imported Capacitive Apparent Energy05: Exported Capacitive Apparent Energy06: Imported Inductive Reactive Energy07: Exported Inductive Reactive Energy08: Imported Capacitive Reactive Energy09: Exported Capacitive Reactive Energy0A: ALL partial counters141xxCS Checksum, summed from C-Field to Selected Parameter of Parameter Set 19 (byt�e 5 byte 13)15116Stop characterTable 3.15 – SND_UD command: Stop Partial Energy Counter Using Primary Address22 M-Bus communication protocolEnglish3.1.2.6 Start Partial Energy CountersHere follows the command, using the Primary Address of the Slave:Byte Nr.Size (Byte)Value (HEX)D1168Start character long query2109L-Field3109L-Field Ripetition4168Start character long query ripetition5173C-Field SND_UD61xxA-Field, Primary Address (00-FF = 0-255)7151CI-Field8101DIF: 8 Bit Integer, 1 Byte91FFVIF followed by manufacturer specic VIFE10182VIFE: Partial Counters111FFVIFE followed by 3E specic VIFE12171Manufacturer specic VIFE: Start Counter131xxValue: Kind of Energy00: Imported Active Energy01: Exp

orted Active Energy02: Imported Inducti
orted Active Energy02: Imported Inductive Apparent Energy03: Exported Inductive Apparent Energy04: Imported Capacitive Apparent Energy05: Exported Capacitive Apparent Energy06: Imported Inductive Reactive Energy07: Exported Inductive Reactive Energy08: Imported Capacitive Reactive Energy09: Exported Capacitive Reactive Energy0A: ALL partial counters141xxCS Checksum, summed from C-Field to Selected Parameter of Parameter Set 19 (byt�e 5 byte 13)15116Stop characterTable 3.13 – SND_UD command: Start Partial Energy Counter Using Primary AddressHere follows the command, using the Secondary Address of the Slave:Byte Nr.Size (Byte)Value (HEX)D1168Start character long query2111L-Field3111L-Field Ripetition4168Start character long query ripetition5173C-Field SND_UD61FDA-Field, Primary Address = 253, i.e. take the secondary address7151CI-Field8 – 158xx xx xx xx xx xx xx xxSecondary Address UD (See the relative paragraph)16101DIF: 8 Bit Integer, 1 Byte171FFVIF followed by manufacturer specic VIFE18182VIFE: Partial Counters191FFVIFE followed by manufacturer speci

;c VIFE20171VIFE: Start CountersM-B
;c VIFE20171VIFE: Start CountersM-Bus communication protocol 21EnglishByte Nr.Size (Byte)Value (HEX)D131xxValue: Kind of Energy00: Imported Active Energy01: Exported Active Energy02: Imported Inductive Apparent Energy03: Exported Inductive Apparent Energy04: Imported Capacitive Apparent Energy05: Exported Capacitive Apparent Energy06: Imported Inductive Reactive Energy07: Exported Inductive Reactive Energy08: Imported Capacitive Reactive Energy09: Exported Capacitive Reactive Energy0A: ALL partial counters141xxCS Checksum, summed from C-Field to Selected Parameter of Parameter Set 19 (byt�e 5 byte 13)15116Stop characterTable 3.11 – SND_UD command: Reset Partial Energy Counter Using Primary AddressHere follows the command, using the Secondary Address of the Slave:Byte Nr.Size (Byte)Value (HEX)D1168Start character long query2111L-Field3111L-Field Ripetition4168Start character long query ripetition5173C-Field SND_UD61FDA-Field, Primary Address = 253, i.e. take the secondary address7151CI-Field8 – 158xx xx xx xx xx xx xx xxSecondary Address UD (See the relati

ve paragraph)16101DIF: 8 Bit Integer
ve paragraph)16101DIF: 8 Bit Integer, 1 Byte171FFVIF followed by manufacturer specic VIFE18182VIFE: Partial Counters191FFVIFE followed by manufacturer specic VIFE20170VIFE: Reset Counters211xxValue: Kind of Energy00: Imported Active Energy01: Exported Active Energy02: Imported Inductive Apparent Energy03: Exported Inductive Apparent Energy04: Imported Capacitive Apparent Energy05: Exported Capacitive Apparent Energy06: Imported Inductive Reactive Energy07: Exported Inductive Reactive Energy08: Imported Capacitive Reactive Energy09: Exported Capacitive Reactive Energy0A: ALL partial counters221xxCS Checksum, summed from C-Field to Selected Parameter of Parameter Set 19 (byt�e 5 byte 21)23116Stop characterTable 3.12 – SND_UD command: Reset Partial Energy Counter Using Secondary AddressAnswer of the Slave: E5h20 M-Bus communication protocolEnglishHere follows the command, using the Secondary Address of the Slave:Byte Nr.Size (Byte)Value (HEX)D1168Start character long query210FL-Field310FL-Field Ripetition4168Start character long query ripetition5173C-

Field SND_UD61FDA-Field, Primary Add
Field SND_UD61FDA-Field, Primary Address = 253, i.e. take the secondary address7151CI-Field8 – 158xx xx xx xxxx xx xx xxSecondary Address16101DIF: 8 Bit Integer, 1 Byte171FFVIF followed by manufacturer specic VIFE18170Manufacturer specic VIFE: Reset Counter19 1xxValue: Kind of Energy Counters00: Reset Total Energy Counters01: Reset Tariff 1 Energy Counters02: Reset Tariff 2 Energy Counters03: Reset ALL Energy Counters201xxCS Checksum, summed from C-Field to Selected Parameter of Parameter Set 19 (byt�e 5 byte 19)21116Stop characterTable 3.10 – SND_UD command: Reset Active Energy Counters Using Secondary AddressAnswer of the Slave: E5h3.1.2.5 Reset Partial Energy CountersHere follows the command, using the Primary Address of the Slave:Byte Nr.Size (Byte)Value (HEX)D1168Start character long query2109L-Field3109L-Field Ripetition4168Start character long query ripetition5173C-Field SND_UD61xxA-Field, Primary Address (00-FF = 0-255)7151CI-Field8101DIF: 8 Bit Integer, 1 Byte91FFVIF followed by manufacturer specic VIFE10182VIFE: Partial

Counters111FFVIFE followed by 3E sp
Counters111FFVIFE followed by 3E specic VIFE12170Manufacturer specic VIFE: Reset Counter14 M-Bus communication protocolEnglishVIVIDUnit0001001123Phase 3 Exported Inductive Energy0.1VAh or 0.1varh00100100243-Phase Inductive Energy0.1VAh or 0.1varh00110000303-Phase Imported Capacitive Energy0.1VAh or 0.1varh0011000131Phase 1 Imported Capacitive Energy0.1VAh or 0.1varh0011001032Phase 2 Imported Capacitive Energy0.1VAh or 0.1varh0011001133Phase 3 Imported Capacitive Energy0.1VAh or 0.1varh01000000403-Phase Exported Capacitive Energy0.1VAh or 0.1varh0100000141Phase 1 Exported Capacitive Energy0.1VAh or 0.1varh0100001042Phase 2 Exported Capacitive Energy0.1VAh or 0.1varh0100001143Phase 3 Exported Capacitive Energy0.1VAh or 0.1varh01000100443-Phase Capacitive Energy0.1VAh or 0.1varh0101000050FrequencymHz0101000151Phase OrderDimensionless0101001052CT ValueDimensionless0101001153PT ValueDimensionless0101010054Actual TariffDimensionless0101010155Serial NumberDimensionless0101011056ModelDimensionless0101011157TypeDimensionless0101100058Firmware ReleaseD

imensionless0101100159Hardware Releas
imensionless0101100159Hardware ReleaseDimensionless0110000060Wiring ModeDimensionless0110000161Primary or Secondary ValueDimensionless0110001062Error CodeDimensionless0110001163Out Of RangeDimensionless0110010064FSA ValueA0111000070Reset CounterDimensionless0111000171Start CounterDimensionless0111001072Stop CounterDimensionless0111001173Partial Counter StatusDimensionless1000000080Imported Energy0.1Wh1000000181Exported Energy0.1Wh1000001082PartialDimensionless1000001183BalanceDimensionless1000010084Power FactorDimensionless1001000090Unit Volt-Ampere * 10-3mVA1001000191Unit Volt-Ampere per hour * 10-10.1VAh1001001092Unit Reactive Volt-Ampere * 10-3mvar1001001193Unit Reactive Volt-Ampere per hour * 10-10.1varh1001010094Unit Hertz (cycle per second) * 10-3MHzTable 2.14 –Manufacturer Specic Value Information Field Extension UsedIf Bit No. 7 in the Specic Value Information Field Extension (VIFE) is set to 1, another VIFE Byte follows. If Bit 7 is set to 0, the rst Data Byte follows next.M-Bus communication protocol 13EnglishThe coding of VIF

E is:BitNameD7Extension BitSpeci&#
E is:BitNameD7Extension BitSpecies if a VIFE Byte follows: 0 = No1 = Yes6 - 0Value InformationContains Information on the single Value, such as Unit, Multiplicator, etc…Table 2.11 – Value Information Field Extension Structure2.2.2.3 Standard nformation Field (VIVIDUnit1000001082Energy0.1Wh0111100179Set Secondary AddressDimensionless011110107ASet Primary AddressDimensionless10101000A8PowermW11111101FDA standard VIFE from extension table followsDimensionless11111111FFA further manufacturer specic VIFE followsDimensionlessTable 2.12 – Standard Value Information Field Used2.2.2.4 Standard nformation Field Extension (VIVIDUnit000010110BParameter Set IdenticationDimensionless000011000CFirmware VersionDimensionless000011010DHardware VersionDimensionless11001100CCVoltagemV11011001D9CurrentmATable 2.13– Standard Value Information Field Extension Used2.2.2.5 Manufacturer Specic nformation Field Extension (VIVIDUnit00000000003-Phase0.1Wh, mV, mA, mW, mVA or mvar0000000101Phase 10.1Wh, mV, mA, mW, mVA or mvar0000001002Phase 20.1Wh, mV, mA,

mW, mVA or mvar0000001103Phase 30.1W
mW, mVA or mvar0000001103Phase 30.1Wh, mV, mA, mW, mVA or mvar0000010004NeutralmA0000010105Line 12mV0000011006Line 23mV0000011107Line 31mV00010000103-Phase Imported Inductive Energy0.1VAh or 0.1varh0001000111Phase 1 Imported Inductive Energy0.1VAh or 0.1varh0001001012Phase 2 Imported Inductive Energy0.1VAh or 0.1varh0001001113Phase 3 Imported Inductive Energy0.1VAh or 0.1varh00100000203-Phase Exported Inductive Energy0.1VAh or 0.1varh0001000121Phase 1 Exported Inductive Energy0.1VAh or 0.1varh0001001022Phase 2 Exported Inductive Energy0.1VAh or 0.1varh12 M-Bus communication protocolEnglishata nformation Block (The Data Information Block (DIB) contains as a minimum one Data Information Field (DIF). This byte can be extended by a further 10 Data Information Field Extension Bytes (DIFE).The coding of DIF for this protocol is:BitNameD7Extension BitSpecies if a DIFE Byte follows: 0 = No1 = Yes6LSB of Storage NumberAlways at 0, i.e. not used5 - 4Functions FieldSpecies the kind of the value, always at:00 = Instantaneous Value3 - 0Data FieldLength and Coding of Data:0001:

8 Bit Integer0010: 16 Bit Integer0011
8 Bit Integer0010: 16 Bit Integer0011: 24 Bit Integer0100: 32 Bit Integer0110: 48 Bit Integer0111: 64 Bit Integer1100: 8 digit BCD 1101: Variable LengthTable 2.8 – Data Information Field StructureThe coding of DIFE for this protocol is:BitNameD7Extension BitSpecies if a DIFE Byte follows: 0 = No1 = Yes6UnitSpecies the kind of Energy or Power when Bit 7 is set to 1: 0 = Reactive1 = Apparent5 - 4TariffSpecies which tariff the values are related:00 = Total Value01 = Tariff 102 = Tariff 23 - 0Storage NumberAlways at 0000Table 2.9 – Data Information Field Extension StructureIf Bit 7 is set to 0, the following Data Byte are related to Active Energy or Power. So, if the rst DIFE is followed by another DIFE (i.e. Bit 7 is set to 1), the following Data Byte are related to Reactive or Apparent Energy or Power, depending on Bit 6 value.nformation Block (The Value Information Block (VIB) contains as a minimum one Value Information Field (VIF). This byte can be extended by a further 10 Value Information Field Extension Bytes (DIFE).The coding of VIF is:BitNameD7Extension BitSpecies if a

VIFE Byte follows: 0 = No1 = Yes6 -
VIFE Byte follows: 0 = No1 = Yes6 - 0Value InformationContains Information on the single Value, such as Unit, Multiplicator, etc…Table 2.10 – Value Information Field StructureM-Bus communication protocol 11EnglishCPrimary AddressBASet Baud Rate to 1200 bpsBBSet Baud Rate to 2400 bpsBCSet Baud Rate to 4800 bpsBDSet Baud Rate to 9600 bpsBESet Baud Rate to 19200 bpsBFSet Baud Rate to 38400 bpsTable 2.5 – Value of CI Field2.1.4 L FIThe Length Field (L Field) denes the number of bytes (expressed in hex value) of the Active Data making up the telegram, plus 3 byte for the C, A and Cl Fields.This eld is always transmitted twice in Long Telegrams.2.1.5 CS FIThe Checksum (CS Field) serves to recognize transmission and synchronization faults, and is congured from specic parts of telegram. The checksum is calculated from the arithmetical sum of the data mentioned above plus the Active Data, i.e. from C Field to CS Field (excluded).2.2 Active dataThe Active Data (0 – 246 bytes) in Long Telegrams include the data to be read from the M-BUS Master (Read-Out Data), or Command Informatio

n transmitted by the Master to the Slave
n transmitted by the Master to the Slave.CTDATATODATAEach block of Active Data transmitted by the Slave to the Master starts with the following Fixed Data Record Header (FDH):Byte Nr.Size (Byte)alue (Hex)D1 – 44xx xx xx xxM-BUS Interface Identication Number5 – 62xx xxManufacturer’s ID71xxVersion Number of M-BUS Interface Firmware (00 – FF)8102Medium: Electricity91xxAcces�s Number (00 – FF 00)101xxM-BUS Interface Status (00 = Energy Counter Unreachable, 01 = Energy Counter Reachable)11 – 1220000Signature (always 0000, i.e. not used)Table 2.6 – Fixed Data Record HeaderThe Identication Number is a changeable number by the customer and runs from 00000000 to 99999999.The Access Number has unsigned binary coding, and is incremented (modulo 256) by one after each RSP_UD from the Slave.CTDATATODATAEvery Data Record sent by Slave to the Master consist of the following Data Record Header (DRH) :ata nformation Block (nformation Block (DIFDIFEVIFVIFEData1 Byte0 – 10 Byte(s)1 Byte0 – 10 Byte(s)0 – n BytesTable 2.7 – Data Records Structure10

M-Bus communication protocolEng
M-Bus communication protocolEnglish2.1.1 C FIThe Control Field (C Field) contains information on the direction of the exchange of communication, the success of the actual operation of communication and the proper function of the telegram.Bit Number76543210Master � Slave01FCBFCVF3F2F1F0Slave � Master00ACDDFCF3F2F1F0Table 2.2 – C Field Bit DivisionThe Bit Nr 6 is set to 1 if the communication has the direction Mast�er Slave; viceversa it is set to 0.In the Master � Slave direction, if the frame count bit valid (FCV - Bit Nr 4) is set to 1, then the frame count bit (FCB – Bit Nr 5) has not to be ignored.The FCB is used to indicate successful transmission procedure. A Master shall toggle the bit after a successful reception of a reply from the Slave. After this, if the Slave answer is multi-telegram, the Slave has to send the next telegram of the multi-telegram answer.If the expected reply is missing, or the reception faults, the master resends the same telegram with the same FCB. The Bits Nr 3 – 0 are the function code of the message.The C Field used here, are

:Telegram NameC Field (BC Field (HEX)
:Telegram NameC Field (BC Field (HEX)TelegramDSND_NKE0100000040Short FrameInitialization of the SlaveSND_UD01x1001153 / 73Long FrameMaster send data to SlaveREQ_UD201x110115B / 7BShort FrameMaster requests Class 2 Data to SlaveRSP_UD000x100008 / 18Long FrameData transfer from Slave to MasterTable 2.3 – C Field of the commands used in this protocol2.1.2 A FIThe Address Field (A Field) is used to address the recipient in the calling direction, and to identify the sender of information in the receiving direction.The size of this eld is one byte, and it can assume the value between 0 – 255, divided in this way:A Field (HEX)Primary AddressRemarks000Default Address Given by Manufacturer01 – FA1 – 250Primary Address SettableFB, FC251, 252Reserved for Future UseFD253Used for Secondary Address ProceduresFE254Use to Transmit Information to All Partecipants in the M-BUS SystemFF255Use to Transmit Information to All Partecipants in the M-BUS SystemTable 2.4 – Value of Address FieldUsing the address 254 (FEh) every Slave answer with the acknowledging (E5h) or with their primary addre

ss.Using the address 255 (FFh) no one S
ss.Using the address 255 (FFh) no one Slave replies.2.1.3 CThe Control Information (CI Field) contains information for the receiver of the telegram.The CI Field values used here, are:CPrimary Address51The telegram contains data for the Slave52Selection of the Slave72The telegram contains data for the MasterB8Set Baud Rate to 300 bpsB9Set Baud Rate to 600 bpsM-Bus communication protocol 9English1. M-Bus interfaceThe M-BUS Interface (1 module wide, DIN rail mount) is developed to connect the Energy Counter to M-BUS.The interface receives the measurement data from the Energy Counter using infrared port available on the side of the counter, and gets the power supply from the bus.1.1 OverviewM-BUS Interface complying with EN13757-2 and EN13757-3šCircuiting by means of drilled two-wires cablesš2 screw clamps on M-BUS InterfacešCurrent consumption of M-BUS Interface: š 4 mA. This corresponds to 3 standard loads.The data transmission speed is selectable between 300, 600, 1200, 2400, 4800, 9600, 115200 and 38400 baudšThe default speed is 2400 ba

udšThe default Primary
udšThe default Primary Address is 000š2. Telegram formatsThe telegram formats are three, identied by the rst character.ByteSingle character (HEX)Short Telegram (HEX)Long Telegram (HEX)1E510682C FieldL Field3A FieldL Field (Ripetition)4CS (Checksum)68516C Field6A Field7CI Field8 - YYData (0 – 246 Bytes)YY + 1CS (Checksum)YY + 216Table 2.1 – The M-BUS Telegram FormatsSingle Character: This telegram format consists of the single character E5h and is used to acknowledge the telegram received.Short Telegram: This telegram is identied by the start character 10h and consists of ve character. It’s used by the M-BUS Master to command the transmission of data from the M-BUS Slave.Long Telegram: This telegram is identied by the start character 68h and consists of a variable number of characters, in which are present also the active data. It’s used by the M-BUS Master to transmits commands to the M-BUS Slave, and by the M-BUS Slave to send the read-out Data from the M-BUS Master.2.1 Telegram eldsThe telegram elds (C, A, CI Fields, L

and CS) have a xed length of one by
and CS) have a xed length of one byte (8 bit) and serve predetermined effects in the M-BUS communication. The L Field denes the number of bytes of the active data.3.1.4.35 ...............................................................................................................................40ACTOR ...................................................................40CTIV ....................................................................413.1.4.38 3-ARWE ..............................................................41ACTIV ................................................................41CTIVGY PARTIAL ..............................................................42CTIVGY PARTIAL .....................................42ACITIVGY PARTIAL ...................................42CTIVACTIVGY PARTIAL ......................................43ACITIVACTIVGY PARTIAL .....................................43CTIVGY B .........................................................................................................44CTIVACITIVGY B ...................................................44CTIVACITIVACTI

VGY B .................................
VGY B .....................................................443.1.4.48 CT V ...............................................................................................................................453.1.4.49 ALUE ...............................................................................................................................45CT ...............................................................................................................................453.1.4.51 SE ...............................................................................................................................453.1.4.52 M ...............................................................................................................................453.1.4.53 TYPE ...............................................................................................................................46GY C ..................................................................................................46GY C .................................................................................................46DAR .................

........................................
.............................................................................................473.1.4.57 ...............................................................................................................................473.1.4.58 OU ...............................................................................................................................47ABRICATIO..............................................................................................................................483.1.4.60 M-BAR ......................................................................................................483.1.4.61 M-BWAR .....................................................................................................48PARTIALTAT .......................................................................................................................483.1.4.63 FSA V ...............................................................................................................................48ANNEX A ..........................................................................................49ANNEX B

........................................
..........................................................................................50ANNEX C ..........................................................................................52TARTPARTIALGY C ..........................................................................................................22TOPARTIALGY C ............................................................................................................23CTLAVDARSS .........................................................................................24PARAM ...........................................................................................................................253.1.3 R ............................................................................................................................273.1.4 RS 27CTIVGY, TOTAL ......................................28CTIVGY, TOTAL ......................................28CTIVGY, TOTAL .............29CTIVGY, TOTAL .............29ACITIVGY, TOTAL ............29ACITIVGY, TOTAL............30CTIVACTIVGY, TOTAL ...............30ACITIVACTIVGY, TOTAL ..........

....31ACITIVACTIVGY, TOTAL .........
....31ACITIVACTIVGY, TOTAL ...........31CTIVGY, T ................................32CTIVGY, T ................................32CTIVGY, T .......32CTIVGY, T .......33ACITIVGY, T ......33ACITIVGY, T .....33CTIVACTIVGY, T .........34CTIVACTIVGY, T .........34ACITIVACTIVGY, T .......34ACITIVACTIVGY, T .......35CTIVGY, T ................................35CTIVGY, T ................................36CTIVGY, T .......36CTIVGY, T .......36ACITIVGY, T ......37ACITIVGY, T .....37CTIVACTIVGY, T .........37CTIVACTIVGY, T .........38ACITIVACTIVGY, T .......38ACITIVACTIVGY, T .......39OLTA ..............................................................................39OLTA ...................................................................................................393.1.4.33 3- ...........................................................403.1.4.34 FY ...............................................................................................................................40INDEX1. M-Bus interface ..........................................................

...................91.1 Overview ....
...................91.1 Overview ..........................................................................................................................92. Telegram formats ..........................................................................92.1 Telegram elds ...............................................................................................................92.1.1 C Field ...............................................................................................................................102.1.2 A Field ...............................................................................................................................102.1.3 CI Field ...............................................................................................................................102.1.4 L Field ...............................................................................................................................112.1.5 CS Field (Checksum) ...........................................................................................................112.2 Active data ............................

........................................
.........................................................................................112.2.1 Coding of Active Data Transmitted From Slave to Master: Fixed Data Record Header ......112.2.2 Coding of Active Data Transmitted From Slave to Master: Data Records ...........................11ATAFORMATIOLOC ................................................................................................................12FORMATIOLOC ..............................................................................................................12TADARDFORMATIO ..................................................................................13TADARDFORMATIO ............................................................13FACTFORMATIO ..................................133. Communication process...............................................................153.1 Send / conrm procedure .............................................................................................153.1.1 S ............................................................................................................................153.1.2 S

........................................
..............................................................................................................................15SS ..............................................................................................................................16DARSS .........................................................................................................................17AT ...............................................................................................................................18OTALGY C ......................................................................19PARTIALGY C ..........................................................................................................20Edited in Germany Subject to change without notice A pdf version is available on the InternetGMC-I Messtechnik GmbH 90449 Nürnberg €GermanyPhone+49 911 8602-111Telefax+49 911 8602-777E-Mailinfo@gossenmetrawatt.comwww.gossenmetrawatt.comEdited in Germany Subject to change without notice A pdf version is available on the InternetGMC-I Messtechnik GmbH 90449 Nürnberg €GermanyPhone+49 911 8602-111Telefax+49 911 8602-777E-Ma