71M6515H_11 Datasheet, PDF(25/60 Page) Teridian Semiconductor Corporation – Up to 10ppmC precision ultra-stable voltage reference Digital temperature compensation

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71M6515H_11 Datasheet, PDF (25/60 Pages) Teridian Semiconductor Corporation – Up to 10ppmC precision ultra-stable voltage reference Digital temperature compensation

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71M6515H

A Maxim Integrated Products Brand

Energy Meter IC

DATA SHEET

JULY 2011

General Notes on Calibration

Positive

direction

Voltage

Current lags

voltage

(inductive)

+60Â°

Current

-60Â°

Current leads

voltage

(capacitive)

Generating Energy

Voltage

Using Energy

The calibration procedures described below should be followed after

interfacing the voltage and current sensors to the 71M6515H chip. When

properly interfaced, the V3P3 power supply is connected to the meter

neutral and is the DC reference for each input. Each voltage and current

waveform, as seen by the 6515H, is scaled to be less than 250mV

(peak).

Each meter phase must be calibrated individually. The procedures below

show how to calibrate a meter phase with either three or five

measurements. Note that there is no need to calibrate for VARh if the

Wh measurement is calibrated correctly. Note that positive load angles

correspond to lagging current (see Figure 12).

For a typical calibration, a meter calibration system is used to apply a

calibrated load, e.g. 240V at 30A, while interfacing the voltage and

current sensors to the 71M6515H. This load should result in an ob-

servable pulse rate at the PULSEW output depending on the selected

energy per pulse. For example, 7.2kW will result in an energy rate

corresponding to 7200Wh/3600s = 2Wh/s, i.e., when 7.2kW are applied

per phase (resulting in a total power of 21.6kW, equivalent to 6Wh/s) and

a Kh of 3.2 (Wh/pulse) has been configured, a pulse rate of 6Wh/3.2Whs

= 1.875Hz will be established.

Figure 12: Definition of Load Angles

It is entirely possible to calibrate piece-wise, i.e. in segments, to compensate for non-linear sensors. For example, one set of

calibration factors can be applied by the host when the current is below 0.5A, while another set is applied when the current is

at or above 0.5A.

Calibration Procedure for CT and Resistive Shunt

A typical meter has phase and gain errors as shown by ÏS, AXI, and AXV in Figure 13. Following the typical meter convention of

current phase being in the lag direction, the small amount of phase lead in a typical current sensor is represented as -ÏS. The

errors shown in Figure 13 represent the sum of all gain and phase errors. They include errors in voltage attenuators, current

sensors, signal conditioning circuits, and in ADC gains. In other words, no errors are made in the âinputâ or âmeterâ boxes.

INPUT

ÏL

ÏL is phase lag

ERRORS

âÏS

A XI

ÏS is phase lead

METER

I RMS

IDEAL = I , ACTUAL = I AXI

W IDEAL = IV cos(ÏL )

ACTUAL = IV AXI AXV cos(ÏL â ÏS )

AXV

V RMS

IDEAL = V , ACTUAL = V AXV

ERROR â¡ ACTUAL â IDEAL = ACTUAL â1

IDEAL

Figure 13: Watt Meter with Gain and Phase Errors.

During the calibration phase, we measure errors and then introduce correction factors to nullify their effect. With three

unknowns to determine, we must make at least three measurements. If we make more measurements, we can average the

results.

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