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| 型号: | 71M6543F-IGTR/F |
| 厂商: | Maxim Integrated |
| 文件页数: | 89/154页 |
| 文件大小: | 0K |
| 描述: | IC ENERGY METER 64K FLSH 100LQFP |
| 标准包装: | 1,000 |
| 系列: | * |
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�71M6543F/71M6543G� Data� Sheet�
�4.5.3�
�Temperature� Coefficients� for� the� 71M6xx3�
�Refer� to� the� 71M6xxx� Data� sheet� for� the� equations� that� are� applicable� to� each� 71M6xx3� part� number� and�
�the� corresponding� temperature� coefficients.�
�4.5.4�
�Temperature� Compensation� for� VREF� and� Shunt� Sensors�
�10� ?� TEMP� _� X� ?� PPMC� 100� ?� TEMP� _� X� 2� ?� PPMC� 2�
�2� 14�
�2� 23�
�the� sample� in� each� corresponding� sensor� channel.� A� GAIN_ADJx� value� of� 16,384� (i.e.,� 2� )corresponds� to�
�In� the� above� equation,� TEMP_X� is� the� deviation� from� nominal� or� calibration� temperature� expressed� in�
�multiples� of� 0.1� °C.� The� 10x� and� 100x� factors� seen� in� the� above� equation� are� due� to� 0.1� C� scaling� of�
�TEMP_X� .� For� example,� if� the� calibration� (reference)� temperature� is� 22� C� and� the� measured� temperature�
�is� 27� C,� then� 10*� TEMP_X� =� (27-22)� x� 10� =� 50� (decimal),� which� represents� a� +5� C� deviation� from� 22� C.�
�This� section� discusses� metrology� temperature� compensation� for� the� meter� designs� where� current� shunt�
�sensors� are� used� in� conjunction� with� the� 71M6xx3� remote� isolated� sensors,� as� shown� in� Figure� 31.�
�Sensors� that� are� directly� connected� to� the� 71M6543� are� affected� by� the� voltage� variation� in� the� 71M6543�
�VREF� due� to� temperature.� On� the� other� hand,� shunt� sensors� that� are� connected� to� 71M6xx3� remote�
�sensor� are� affected� by� the� VREF� in� the� 71M6xx3.� The� VREF� in� both� the� 71M6543� and� 71M6xx3� can� be�
�compensated� digitally� using� a� second-order� polynomial� function� of� temperature.� The� 71M6543� and�
�71M6xx3� feature� temperature� sensors� for� the� purposes� of� temperature� compensating� their� corresponding�
�VREF.� The� compensation� computations� must� be� implemented� in� MPU� firmware.�
�Referring� to� Figure� 31� ,� the� VADC8� (VA),� VADC9� (VB)� and� VADC10� (VC)� voltage� sensors� are� always�
�directly� connected� to� the� 71M6543.� Thus,� the� precision� of� the� voltage� sensors� is� primarily� affected� by�
�VREF� in� the� 71M6543.� The� temperature� coefficient� of� the� resistors� used� to� implement� the� voltage� dividers�
�for� the� voltage� sensors� (see� Figure� 27� )� determine� the� behavior� of� the� voltage� division� ratio� with� respect� to�
�temperature.� It� is� recommended� to� use� resistors� with� low� temperature� coefficients,� while� forming� the� entire�
�voltage� divider� using� resistors� belonging� to� the� same� technology� family,� in� order� to� minimize� the� temperature�
�dependency� of� the� voltage� division� ratio.� The� resistors� must� also� have� suitable� voltage� ratings.�
�The� 71M6543� also� may� have� one� local� current� shunt� sensor� that� is� connected� directly� to� it� via� the� IADC0-�
�IADC1� input� pins,� and� therefore� this� local� current� sensor� is� also� affected� by� the� VREF� in� the� 71M6543.�
�The� shunt� current� sensor� resistance� has� a� temperature� dependency,� which� also� may� require�
�compensation,� depending� on� the� required� accuracy� class.�
�The� IADC2-IADC3,� IADC4-IADC5� and� IADC6-IADC7� current� sensors� are� isolated� by� the� 71M6xx3� and�
�depend� on� the� VREF� of� the� 71M6xx3,� plus� the� variation� of� the� corresponding� remote� shunt� current� sensor�
�with� temperature.�
�The� MPU� has� the� responsibility� of� computing� the� necessary� sample� gain� compensation� values� required� for�
�each� sensor� channel� based� on� the� sensed� temperature.� Maxim� provides� demonstration� code� that�
�implements� the� GAIN_ADJx� compensation� equation� shown� below.� The� resulting� GAIN_ADJx� values� are�
�stored� by� the� MPU� in� five� CE� RAM� locations� GAIN_ADJ0-GAIN_ADJ5� (� CE� RAM� 0x40-0x44� ).� The�
�demonstration� code� thus� provides� a� suitable� implementation� of� temperature� compensation,� but� other�
�methods� are� possible� in� MPU� firmware� by� utilizing� the� on-chip� temperature� sensors� while� storing� the�
�sample� gain� adjustment� results� in� the� CE� RAM� GAIN_ADJx� storage� locations� for� use� by� the� CE.� The�
�demonstration� code� maintains� five� separate� sets� of� PPMC� and� PPMC2� coefficients� and� computes� five�
�separate� GAIN_ADJx� values� based� on� the� sensed� temperature� using� the� equation� below:�
�GAIN� _� ADJx� =� 16385� +� +�
�The� GAIN_ADJx� values� stored� by� the� MPU� in� CE� RAM� are� used� by� the� CE� to� gain� adjust� (i.e.,� multiply)�
�14�
�unity� gain,� while� values� less� than� 16,384� attenuate� the� samples� and� values� greater� than� 16,384� amplify�
�the� samples.�
�o�
�o�
�o� o� o�
�In� the� demonstration� code,� TEMP_X� is� calculated� in� the� MPU� from� the� STEMP[10:0]� temperature� sensor�
�reading� using� the� equation� provided� below� and� is� scaled� in� 0.1°C� units.� See� 2.5.5� 71M6543� Temperature�
�Sensor� on� page� 53� for� the� equation� to� calculate� temperature� in� degrees� °C� from� the� STEMP[10:0]� value.�
�Table� 66� shows� the� five� GAIN_ADJx� equation� output� storage� locations� and� the� voltage� or� current� sensor�
�channels� for� which� they� compensate� for� the� 1� Local� /� 3� Remote� configuration� shown� in� Figure� 31� .�
�v2�
�89�
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