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�71M6513/71M6513H� Demo� Board� User’s� Manual�
�2.2.2� CALIBRATION� PROCEDURE� WITH� FIVE� MEASUREMENTS�
�The� calibration� procedure� is� as� follows:�
�1)�
�2)�
�3)�
�4)�
�5)�
�6)�
�7)�
�8)�
�9)�
�All� calibration� factors� are� reset� to� their� default� values,� i.e.� CAL_IA� =� CAL_VA� =� 16384,� and� PHADJ_A�
�=� 0.�
�An� RMS� voltage� V� ideal� consistent� with� the� meter’s� nominal� voltage� is� applied,� and� the� RMS� reading�
�V� actual� of� the� meter� is� recorded.� The� voltage� reading� error� Axv� is� determined� as�
�Axv� =� (V� actual� -� V� ideal� )� /� V� ideal�
�Apply� the� nominal� load� current� at� phase� angles� 0°,� 60°,� 180°� and� –60°� (-300°).� Measure� the� Wh�
�energy� each� time� and� record� the� errors� E� 0� ,� E� 60� ,� E� 180� ,� and� E� 300� .�
�Calculate� the� new� calibration� factors� CAL_IA,� CAL_VA,� and� PHADJ_A,� using� the� formulae� presented�
�in� section� 2.1.2� or� using� the� spreadsheet� presented� in� section� 2.2.4.�
�Apply� the� new� calibration� factors� CAL_IA,� CAL_VA,� and� PHADJ_A� to� the� meter.� The� memory� locations�
�for� these� factors� are� given� in� section� 1.9.1.�
�Test� the� meter� at� nominal� current� and,� if� desired,� at� lower� and� higher� currents� and� various� phase�
�angles� to� confirm� the� desired� accuracy.�
�Store� the� new� calibration� factors� CAL_IA,� CAL_VA,� and� PHADJ_A� in� the� flash� memory� of� the� meter.� If�
�a� Demo� Board� is� calibrated,� the� methods� shown� in� sections� 1.9.3� and� 1.9.4� can� be� used.�
�Repeat� the� steps� 1� through� 7� for� each� phase.�
�For� added� temperature� compensation,� read� the� value� in� CE� RAM� location� 0x54� and� write� it� to� CE� RAM�
�location� 0x11.� If� Demo� Code� 3.05� or� later� is� used,� this� will� automatically� calculate� the� correction�
�coefficients� PPMC� and� PPMC2� from� the� nominal� temperature� entered� in� CE� location� 0x11� and� from�
�the� characterization� data� contained� in� the� on-chip� fuses.�
�Tip:� Step� 2� and� the� energy� measurement� at� 0°� of� step� 3� can� be� combined� into� one� step.�
�2.2.3� CALIBRATION� PROCEDURE� FOR� ROGOWSKI� COIL� SENSORS�
�Demo� Code� containing� CE� code� that� is� compatible� with� Rogowski� coils� is� available� from� TERIDIAN� Semi-�
�conductor.�
�Rogowski� coils� generate� a� signal� that� is� the� derivative� of� the� current.� The� CE� code� implemented� in� the�
�Rogowski� CE� image� digitally� compensates� for� this� effect� and� has� the� usual� gain� and� phase� calibration�
�adjustments.� Additionally,� calibration� adjustments� are� provided� to� eliminate� voltage� coupling� from� the� sensor�
�input.�
�Current� sensors� built� from� Rogowski� coils� have� a� relatively� high� output� impedance� that� is� susceptible� to�
�capacitive� coupling� from� the� large� voltages� present� in� the� meter.� The� most� dominant� coupling� is� usually�
�capacitance� between� the� primary� of� the� coil� and� the� coil’s� output.� This� coupling� adds� a� component� proportional�
�to� the� derivative� of� voltage� to� the� sensor� output.� This� effect� is� compensated� by� the� voltage� coupling� calibration�
�coefficients.�
�As� with� the� CT� procedure,� the� calibration� procedure� for� Rogowski� sensors� uses� the� meter’s� display� to� calibrate�
�the� voltage� path� and� the� pulse� outputs� to� perform� the� remaining� energy� calibrations.� The� calibration� procedure�
�must� be� done� to� each� phase� separately,� making� sure� that� the� pulse� generator� is� driven� by� the� accumulated� real�
�energy� for� just� that� phase.� In� other� words,� the� pulse� generator� input� should� be� set� to� WhA,� WhB,� or� WhC,�
�depending� on� the� phase� being� calibrated.�
�In� preparation� of� the� calibration,� all� calibration� parameters� are� set� to� their� default� values.� VMAX� and� IMAX� are�
�set� to� reflect� the� system� design� parameters.� WRATE� and� PUSE_SLOW� ,� PULSE_FAST� are� adjusted� to� obtain�
�the� desired� Kh.�
�Page:� 48� of� 112�
�?� 2005-2006� TERIDIAN� Semiconductor� Corporation�
�Revision� 5.6�
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