ade7753 Analog Devices, Inc., ade7753 Datasheet - Page 21

ade7753

Manufacturer Part Number

ade7753

Description

Active And Apparent Energy Metering Ic With Di/dt Sensor Interface

Manufacturer

Analog Devices, Inc.

Datasheet

1.ADE7753.pdf (38 pages)

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With full-scale sinusoidal signals on the analog inputs and the

WGAIN register set to 000h, the average word value from

each LPF2 is CCCCDh - see Figure 31. The maximum

positive value which can be stored in the internal 47-bit

the integration time under these conditions with WDIV=0 is

calculated as follows:

When WDIV is set to a value different from 0, the integration

time varies as shown on Equation 8.

Time = Time

REV. PrF 10/02

POWER OFFSET CALIBRATION

The ADE7753 also incorporates an Active Power Offset

bit register which can be used to remove offsets in the active

power calculation—see Figure 33. An offset may exist in the

power calculation due to cross talk between channels on the

PCB or in the IC itself. The offset calibration will allow the

contents of the Active Power register to be maintained at zero

when no power is being consumed.

Two hundred fifty six LSBs (APOS=0100h) written to the

Active Power Offset register are equivalent to 1 LSB in the

Waveform Sample register. Assuming the average value

outputs from LPF2 is CCCCDh (838,861 in Decimal) when

inputs on Channels 1 and 2 are both at full-scale. At -60dB

down on Channel 1 (1/1000 of the Channel 1 full-scale

input), the average word value outputs from LPF2 is 838.861

(838,861/1,000). 1 LSB in the LPF2 output has a measure-

ment error of 1/838.861

value. The Active Power Offset register has a resolution

equal to 1/256 LSB of the Waveform register, hence the

power offset correction resolution is 0.00047%/LSB (0.119%/

256) at -60dB.

ENERGY TO FREQUENCY CONVERSION

ADE7753 also provides energy to frequency conversion for

calibration purposes. After initial calibration at manufactur-

ing, the manufacturer or end customer will often verify the

energy meter calibration. One convenient way to verify the

meter calibration is for the manufacturer to provide an output

frequency which is proportional to the energy or active power

under steady load conditions. This output frequency can

provide a simple, single wire, optically isolated interface to

external calibration equipment. Figure 37 illustrates the

Energy-to-Frequency conversion in the ADE7753.

Energy

A Digital to Frequency Converter (DFC) is used to generate

the CF pulsed output. The DFC generates a pulse each time

one LSB in the Active Energy register is accumulated. An

Time

Figure 37– ADE7753 Energy to Frequency Conversion

FFF

AENERGY[23:0]

- 1 or 7FFF,FFFF,FFFFh before it overflows,

CCCCDh

WDIV=0

FFFF

x WDIV

FFFFh

100% = 0.119% of the average

PRELIMINARY TECHNICAL DATA

DFC

. 1

s µ

CFNUM[11:0]

CFDEN[11:0]

187

5 .

(8)

. 3

min

–21–

output pulse is generated when (CFDEN+1)/(CFNUM+1)

number of pulses are generated at the DFC output. Under

steady load conditions the output frequency is proportional to

the Active Power.

The maximum output frequency, with AC input signals at

full-scale and CFNUM=00h & CFDEN=00h, is approxi-

mately 23 kHz.

The ADE7753 incorporates two registers, CFNUM[11:0]

and CFDEN[11:0], to set the CF frequency. These are

unsigned 12-bit registers which can be used to adjust the CF

frequency to a wide range of values. These frequency scaling

registers are 12-bit registers which can scale the output

frequency by 1/2

If the value zero is written to any of these registers, the value

one would be applied to the register. The ratio (CFNUM+1)/

(CFDEN+1) should be smaller than one to assure proper

operation. If the ratio of the registers (CFNUM+1)/

(CFDEN+1) is greater than one, the register values would

be adjust to a ratio (CFNUM+1)/(CFDEN+1) of one.

For example if the output frequency is 1.562kHz while the

contents of CFDENare zero (000h), then the output frequency

can be set to 6.1Hz by writing FFh to the CFDEN register.

Note that for values where CFDEN>CFNUM, the

performance of the CF frequency is not guaranteed. CFNUM

should always be set to a value less than CFDEN.

The output frequency will have a slight ripple at a frequency

equal to twice the line frequency. This is due to imperfect

filtering of the instantaneous power signal to generate the

Active Power signal – see Active Power Calculation. Equation 3

gives an expression for the instantaneous power signal. This

is filtered by LPF2 which has a magnitude response given by

Equation 9.

The Active Power signal (output of LPF2) can be rewritten

as.

where f

From Equation 6

From Equation 11 it can be seen that there is a small ripple

in the energy calculation due to a sin(2 t) component. This

is shown graphically in Figure 38. The Active Energy

calculation is shown by the dashed straight line and is equal

(

)

VIt

is the line frequency (e.g., 60Hz)

9 .

to 1 with a step of 1/2

cos

9 .

sin

ADE7753

(11)

(9)

(10)

ade7753 Analog Devices, Inc., ade7753 Datasheet - Page 21

ade7753

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