71M6543F Datasheet, PDF(92/157 Page) Maxim Integrated Products – Selectable Gain of 1 or 8 for One Current Energy Meter ICs Metrology Compensation

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71M6543F Datasheet, PDF (92/157 Pages) Maxim Integrated Products – Selectable Gain of 1 or 8 for One Current Energy Meter ICs Metrology Compensation

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71M6543F/H and 71M6543G/GH Data Sheet

GAIN_ADJ4

0x44

IADC6-IADC7

VREF in 71M6xx3 and Shunt

(Phase C)

In the demonstration code, the shape of the temperature compensation second-order parabolic curve is

determined by the values stored in the PPMC (1st order coefficient) and PPMC2 (2nd order coefficient),

which are typically setup by the MPU at initialization time from values that are stored in EEPROM.

To disable temperature compensation in the demonstration code, PPMC and PPMC2 are both set to zero

for each of the five GAIN_ADJx channels. To enable temperature compensation, the PPMC and PPMC2

coefficients are set with values that match the expected temperature variation of the shunt current sensor

(if required) and the corresponding VREF voltage reference (summed together).

The shunt sensor requires a second order polynomial compensation which is determined by the PPMC

and PPMC2 coefficients for the corresponding current measurement channel. The corresponding VREF

voltage reference also requires the PPMC and PPMC2 coefficients to match the second order

temperature behavior of the voltage reference. The PPMC and PPMC2 values associated with the shunt

and with the corresponding VREF are summed together to obtain the compensation coefficients for a

given current-sensing channel (i.e., the 1st order PPMC coefficients are summed together, and the 2nd

order PPMC2 coefficients are summed together).

In the 71M6543F and 71M6543G, the required VREF compensation coefficients PPMC and PPMC2 are

calculated from readable on-chip non-volatile fuses (see 4.5.2 Temperature Coefficients for the

71M6543F). These coefficients are designed to achieve Â±40 ppm/Â°C for VREF in the 71M6543F and

71M6543G. PPMC and PPMC2 coefficients are similarly calculated for the 71M6xx3 remote sensor

(see 4.5.4 Temperature Coefficients for the 71M6xx3).

For the 71M6543H and 71M6543GH (Â±0.1% energy accuracy), coefficients specific to each individual

device can be calculated from values read from additional on-chip fuses that characterize the VREF

behavior of each individual part across industrial temperatures (see 4.5.3 Temperature Coefficients for

the 71M6543H). The resulting tracking of the reference VREF voltage is within Â±10 ppm/Â°C.

For the current channels, to determine the PPMC and PPMC2 coefficients for the shunt current

sensors, the designer must either know the average temperature curve of the shunt from its

manufacturerâs data sheet or obtain these coefficients by laboratory characterization of the shunt used

in the design.

4.5.6 Temperature Compensation of VREF and Current Transformers

This section discusses metrology temperature compensation for meter designs where Current

Transformer (CT) sensors are used, as shown in Figure 32.

Sensors that are directly connected to the 71M6543 are affected by the voltage variation in the 71M6543

VREF due to temperature. The VREF in the 71M6543 can be compensated digitally using a second-

order polynomial function of temperature. The 71M6543 features a temperature sensor for the purposes

of temperature compensating its VREF. The compensation computations must be implemented in MPU

firmware and written to the corresponding GAIN_ADJx CE RAM location.

Referring to Figure 32, the VADC8 (VA), VADC9 (VB) and VADC10 (VC) voltage sensors are 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 Current Transformers are directly connected to the 71M6543 and are therefore primarily affected by the

VREF temperature dependency in the 71M6543. For best performance, it is recommended to use the

differential signal conditioning circuit, as shown in Figure 29, to connect the CTs to the 71M6543. Current

transformers may also require temperature compensation. The copper wire winding in the CT has dc

resistance with a temperature coefficient, which makes the voltage delivered to the burden resistor

temperature dependent, and the burden resistor also has a temperature coefficient. Thus, each CT sensor

channel needs to compensate for the 71M6543 VREF, and optionally for the temperature dependency of the

CT and its burden resistor depending on the required accuracy class.

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