AD ADE7752BARW

Preliminary Technical Data
Polyphase Energy Metering IC with Pulsed
Output
ADE7752B
FEATURES
The no-load threshold and reverse polarity indication are based
on the sum of the three phase energies in the ADE7752B. The
ADE7752B specifications surpass the accuracy requirements as
quoted in the IEC62053-21 standard.
The only analog circuitry used in the ADE7752B is in the
analog-to-digital converters (ADCs) and reference circuit. All
other signal processing (for example, multiplication, filtering,
and summation) is carried out in the digital domain. This
approach provides superior stability and accuracy over
extremes in environmental conditions and over time.
High accuracy supports 50 Hz/60 Hz IEC62053-21
Less than 0.1% error over a dynamic range of 500 to 1
Compatible with 3-phase 3-wire delta and 3-phase 4-wire Wye
configurations
Supplies average active power on the frequency outputs F1 and F2
High frequency output (CF) is intended for calibration and
supplies instantaneous active power
Logic output REVP indicates a potential miswiring or negative
power on the sum of all phases
Direct drive for electromechanical counters and 2-phase stepper
motors (F1 and F2)
Proprietary ADCs and DSP provide high accuracy over large
variations in environmental conditions and time
On-chip power supply monitoring
On-chip creep protection (no load threshold) based on the sum
of the three phases
On-chip reference 2.4 V ± 8% (25 ppm/°C typical) with external
overdrive capability
Single 5 V supply, low power (TBD mW typical)
Low cost CMOS process
The ADE7752B supplies average active power information on
the low frequency outputs, F1 and F2. These logic outputs can
be used to directly drive an electromechanical counter or to
interface with an MCU. The CF logic output gives
instantaneous active power information. This output is
intended to be used for calibration purposes.
GENERAL DESCRIPTION
The ADE7752B includes a power supply monitoring circuit on
the VDD pin. The ADE7752B remains inactive until the supply
voltage on VDD reaches 4 V. If the supply falls below 4 V, the
ADE7752B also resets and no pulses are issued on F1, F2, and CF.
The ADE7752B1 is an accurate active energy measurement IC
intended for use in any 3-phase distribution system and has
enhanced features that make it better suited for 3-phase 3-wire
applications compared to the ADE7752/52A.
Internal phase matching circuitry ensures that the voltage and
current channels are phase matched. An internal no load
threshold ensures the ADE7752B does not exhibit any creep
when there is no load.
The ADE7752B is available in a 24-lead SOIC package.
1
Patent pending.
FUNCTIONAL BLOCK DIAGRAM
IAP 5
ADC
IAN 6
ADC
3
POWER
SUPPLY
MONITOR
LPF
Φ
PHASE
CORRECTION
IBP
7
IBN
8
ADE7752B
ADC
VBP 15
ICP
ADC
Σ
X
HPF
2
DGND
Φ
19
CLKIN
PHASE
CORRECTION
20
CLKOUT
LPF
9
ADC
ICN 10
X
HPF
VCP 14
ADC
VN 13
2.4V REF
LPF
Φ
DIGITAL-TO-FREQUENCY CONVERTER
PHASE
CORRECTION
4kΩ
11
12
4
18
21
22
23
24
1
AGND
REFIN/OUT
REVP
SCF
S0
S1
F2
F1
CF
05905-001
VAP
VDD
17
X
HPF
16
ABS
Figure 1.
Rev. PrA
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Fax: 781.461.3113
© 2006 Analog Devices, Inc. All rights reserved.
ADE7752B
Preliminary Technical Data
TABLE OF CONTENTS
Features .............................................................................................. 1
Current Channel Connection................................................... 16
General Description ......................................................................... 1
Voltage Channels Connection .................................................. 16
Table of Contents .............................................................................. 2
Meter Connections..................................................................... 16
Specifications..................................................................................... 3
Power Supply Monitor ................................................................... 18
Timing Characteristics ................................................................ 5
HPF and Offset Effects .................................................................. 19
Absolute Maximum Ratings............................................................ 6
Digital-to-Frequency Conversion ................................................ 20
ESD Caution.................................................................................. 6
Power Measurement Considerations....................................... 21
Pin Configuration and Function Descriptions............................. 7
Mode Selection of the Sum of the Three Active Energies..... 21
Typical Performance Characteristics ............................................. 9
Transfer Function ........................................................................... 22
Terminology .................................................................................... 11
Frequency Outputs F1 and F2 .................................................. 22
Test Circuit ...................................................................................... 12
Frequency Output CF ................................................................ 23
Theory of Operation ...................................................................... 13
Selecting a Frequency for an Energy Meter Application........... 24
Power Factor Considerations.................................................... 13
Frequency Outputs..................................................................... 24
Nonsinusoidal Voltage and Current ........................................ 14
No Load Threshold .................................................................... 24
Analog Inputs.................................................................................. 15
Negative Power Information..................................................... 25
Current Channels ....................................................................... 15
Outline Dimensions ....................................................................... 26
Voltage Channels ........................................................................ 15
Ordering Guide .......................................................................... 26
Typical Connection Diagrams ...................................................... 16
Rev. PrA | Page 2 of 27
Preliminary Technical Data
ADE7752B
SPECIFICATIONS
VDD = 5 V ± 5%, AGND = DGND = 0 V, on-chip reference, CLKIN = 10 MHz, TMIN to TMAX = −40°C to +85°C, unless otherwise noted.
Table 1.
Parameter
ACCURACY1, 2
Measurement Error on
Current Channel
Phase Error Between
Channels
PF = 0.8 Capacitive
PF = 0.5 Capacitive
AC Power Supply Rejection
Output Frequency
Variation (CF)
DC Power Supply Rejection
Output Frequency
Variation (CF)
ANALOG INPUTS
Maximum Signal Levels
Input Impedance (DC)
Bandwidth (−3 dB)
ADC Offset Error1, 2
Gain Error
REFERENCE INPUT
REFIN/OUT Input Voltage
Range
Conditions
Min
Max
0.1
Voltage channel with full-scale signal (±500 mV),
25°C, over a dynamic range of 500 to 1
SCF = 0, S0 = S1 = 1
IA = IB = IC = 100 mV rms,
VA = VB = VC = 100 mV rms @ 50 Hz,
Ripple on VDD of 200 mV rms @ 100 Hz
S1 = 1; S0 = SCF = 0
V1 = 100 mV rms, V2 = 100 mV rms,
VDD = 5 V ± 250 mV
See Analog Inputs section
VAP – VN, VBP – VN, VCP – VN, IAP – IAN, IBP – IBN, ICP – ICN
CLKIN = 10 MHz
CLKIN/256, CLKIN = 10 MHz
% Reading
0.1
% Reading
410
14
±25
External 2.5 V reference, IA = IB = IC = 500 mV dc
Degrees
Degrees
0.01
±0.5
370
Unit
% Reading
±0.1
±0.1
±9
2.4 V + 8%
2.4 V − 8%
Input Impedance
Input Capacitance
ON-CHIP REFERENCE
Reference Error
Temperature Coefficient
CLKIN
Input Clock Frequency
LOGIC INPUTS3
ACF, S0, S1, and ABS
Input High Voltage, VINH
Input Low Voltage, VINL
Input Current, IIN
Input Capacitance, CIN
LOGIC OUTPUTS3
F1 and F2
Output High Voltage, VOH
Output Low Voltage, VOL
CF and NEGP
Output High Voltage, VOH
Output Low Voltage, VOL
LED_CTRL
Output Frequency
Output High Voltage
Output Low Voltage
Typ
V peak
difference
kΩ
kHz
mV
% Ideal
2.6
V
10
V
kΩ
pF
2.2
3.3
Nominal 2.4 V
±200
25
mV
ppm/°C
10
MHz
All specifications for CLKIN of 10 MHz
VDD = 5 V ± 5%
VDD = 5 V ± 5%
Typically 10 nA, VIN = 0 V to VDD
2.4
ISOURCE = 10 mA, VDD = 5 V
ISINK = 10 mA, VDD = 5 V
4.5
VDD = 5 V, ISOURCE = 5 mA
VDD = 5 V, ISINK = 5 mA
VDD = 5 V, CLKIN = 10 MHz
4.5
VDD = 5 V, ISOURCE = 10 mA
VDD = 5 V, ISINK = 10 mA
4.5
0.8
±3
10
V
V
μA
pF
0.5
V
V
0.5
V
V
TBD
kHz
V
V
17.39
Rev. PrA | Page 3 of 27
ADE7752B
Parameter
LED_A, LED_B, LED_C
Output Low ISINK
Output High Source
POWER SUPPLY
VDD
IDD
Preliminary Technical Data
Conditions
Min
VDD = 4.75 V
VDD = 4.75 V
For specified performance
5 V ± 5%
TBD
TBD
Typ
TBD
See the Terminology section for explanation of specifications.
See the plots in the Typical Performance Characteristics section.
3
Sample tested during initial release and after any redesign or process changes that might affect this parameter.
2
Rev. PrA | Page 4 of 27
Unit
mA
mA
4.75
1
Max
5.25
TBD
V
mA
Preliminary Technical Data
ADE7752B
TIMING CHARACTERISTICS
VDD = 5 V ± 5%, AGND = DGND = 0 V, on-chip reference, CLKIN = 10 MHz, TMIN to TMAX = −40°C to +85°C, unless otherwise noted.
Table 2.
Parameter1,2
t1 3
t2
Conditions
F1 and F2 pulse width (logic high)
Output pulse period (see the Transfer Function section)
Specification
120
See Figure 2
Unit
ms
sec
t3
Time between F1 falling edge and F2 falling edge
1/2 t2
sec
t43, 4
CF pulse width (logic high)
90
ms
t55
CF pulse period (see the Transfer Function section)
See Table 7
sec
t6
Minimum time between F1 and F2 pulse
4/CLKIN
sec
1
Sample tested during initial release and after any redesign or process changes that might affect this parameter.
See Figure 2.
3
The pulse widths of F1, F2, and CF are not fixed for higher output frequencies (see the Frequency Outputs section).
4
CF is not synchronous to F1 or F2 frequency outputs.
5
The CF pulse is always 1 μs in the high frequency mode (see the Frequency Outputs section).
2
t1
F1
t6
t2
t3
t4
t5
05757-002
F2
CF
Figure 2. Timing Diagram for Frequency Outputs
Rev. PrA | Page 5 of 27
ADE7752B
Preliminary Technical Data
ABSOLUTE MAXIMUM RATINGS
TA = 25°C, unless otherwise noted.
Stresses above those listed under Absolute Maximum Ratings
may cause permanent damage to the device. This is a stress
rating only; functional operation of the device at these or any
other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute
maximum rating conditions for extended periods may affect
device reliability.
Table 3.
Parameter
VDD to AGND
VDD to DGND
Analog Input Voltage to AGND
VAP, VBP, VCP, VN, IAP, IAN, IBP, IBN, ICP,
and ICN
Reference Input Voltage to AGND
Digital Input Voltage to DGND
Digital Output Voltage to DGND
Operating Temperature Range
Industrial
Storage Temperature Range
Junction Temperature
28-Lead SOIC, Power Dissipation
θJA Thermal Impedance
Lead Temperature, Soldering
Vapor Phase (60 sec)
Infrared (15 sec)
Rating
−0.3 V to +7 V
−0.3 V to +7 V
−6 V to +6 V
−0.3 V to VDD + 0.3 V
−0.3 V to VDD + 0.3 V
−0.3 V to VDD + 0.3 V
−40°C to +85°C
−65°C to +150°C
150°C
63 mW
55°C/W
215°C
220°C
ESD CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily accumulate on
the human body and test equipment and can discharge without detection. Although this product features
proprietary ESD protection circuitry, permanent damage may occur on devices subjected to high energy
electrostatic discharges. Therefore, proper ESD precautions are recommended to avoid performance
degradation or loss of functionality.
Rev. PrA | Page 6 of 27
Preliminary Technical Data
ADE7752B
PIN CONFIGURATION AND FUNCTION DESCRIPTIONS
1
24
F1
DGND 2
23
F2
VDD
3
22
S1
REVP
4
21
S0
20
CLKOUT
CF
IAP 5
ADE7752B
19
IBN 8
17
ABS
ICP 9
16
VAP
ICN 10
15
VBP
AGND 11
14
VCP
REFIN/OUT 12
13
VN
05905-004
CLKIN
TOP VIEW
IBP 7 (Not to Scale) 18 SCF
IAN 6
Figure 3. Pin Configuration
Table 4. Pin Function Descriptions
Pin No.
1
Mnemonic
CF
2
DGND
3
VDD
4
REVP
5, 6;
7, 8;
9, 10
IAP, IAN;
IBP, IBN;
ICP, ICN
11
AGND
12
REFIN/OUT
13, 14, 15,
16
VN, VCP, VBP, VAP
17
ABS
18
SCF
19
CLKIN
Description
Calibration Frequency Logic Output. The CF logic output gives instantaneous active power information.
This output is intended to be used for calibration purposes.
This provides the ground reference for the digital circuitry in the ADE7752B, that is, multiplier, filters,
and digital-to-frequency converter. Because the digital return currents in the ADE7752B are small, it is
acceptable to connect this pin to the analog ground plane of the whole system.
Power Supply. This pin provides the supply voltage for the digital circuitry in the ADE7752B. The supply
voltage should be maintained at 5 V ± 5% for specified operation. This pin should be decoupled to
DGND with a 10 μF capacitor in parallel with a 100 nF ceramic capacitor.
This logic output goes logic high when negative power is detected on the sum of the three phase
powers. This output is not latched and resets when positive power is once again detected (see the
Negative Power Information section).
Analog Inputs for Current Channels. These channels are intended for use with current transducers and
are referenced in this document as current channels. These inputs are fully differential voltage inputs
with maximum differential input signal levels of ±0.5 V (see the Analog Inputs section). Both inputs
have internal ESD protection circuitry; in addition, an overvoltage of ±6 V can be sustained on these
inputs without risk of permanent damage.
This pin provides the ground reference for the analog circuitry in the ADE7752B (ADCs and reference).
This pin should be tied to the analog ground plane or the quietest ground reference in the system. This
quiet ground reference should be used for all analog circuitry, such as, anti-aliasing filters and current
and voltage transducers. To keep ground noise around the ADE7752B to a minimum, the quiet ground
plane should only connect to the digital ground plane at one point. It is acceptable to place the entire
device on the analog ground plane.
This pin provides access to the on-chip voltage reference. The on-chip reference has a nominal value of
2.4 V ±8% and a typical temperature coefficient of 25 ppm/°C. An external reference source can also be
connected at this pin. In either case, this pin should be decoupled to AGND with a 1 μF ceramic
capacitor.
Analog Inputs for the Voltage Channels. These channels are intended for use with voltage transducers
and are referenced in this document as voltage channels. These inputs are single-ended voltage inputs
with a maximum signal level of ±0.5 V with respect to VN for specified operation. All inputs have
internal ESD protection circuitry; in addition, an overvoltage of ±6 V can be sustained on these inputs
without risk of permanent damage.
This logic input is used to select the method by which the three active energies from each phase are
summed. It selects between the arithmetical sum of the three energies (ABS logic high) or the sum of
the absolute values (ABS logic low). See the Mode Selection of the Sum of the Three Active Energies
section.
Select Calibration Frequency. This logic input is used to select the frequency on the calibration output
CF. Table 7 shows how the calibration frequencies are selected.
Master Clock for the ADCs and Digital Signal Processing. An external clock can be provided at this logic
input. Alternatively, a parallel resonant AT crystal can be connected across CLKIN and CLKOUT to
provide a clock source for the ADE7752B. The clock frequency for the specified operation is 10 MHz.
Ceramic load capacitors between 22 pF and 33 pF should be used with the gate oscillator circuit. Refer
to the crystal manufacturer’s data sheet for the load capacitance requirements.
Rev. PrA | Page 7 of 27
ADE7752B
Pin No.
20
Mnemonic
CLKOUT
21, 22
S0, S1
23, 24
F2, F1
Preliminary Technical Data
Description
A crystal can be connected across this pin and CLKIN as described previously to provide a clock source
for the ADE7752B. The CLKOUT pin can drive one CMOS load when an external clock is supplied at
CLKIN or when a crystal is being used.
These logic inputs are used to select one of four possible frequencies for the digital-to-frequency
conversion for design flexibility.
Low Frequency Logic Outputs. F1 and F2 supply average active power information. The logic outputs
can be used to drive electromechanical counters and 2-phase stepper motors directly (see the Transfer
Function section).
Rev. PrA | Page 8 of 27
Preliminary Technical Data
ADE7752B
TYPICAL PERFORMANCE CHARACTERISTICS
Figure 4. Error as a Percent of Reading
with Internal Reference (Wye Connection)
Figure 7. Error as a Percent of Reading over Temperature
with Internal Reference (Wye Connection)
Figure 5. Error as a Percent of Reading over Power Factor
with Internal Reference (Wye Connection)
Figure 8. Error as a Percent of Reading over Power Factor
with Internal Reference (Delta Connection)
Figure 6. Error as a Percent of Reading over Power Factor
with External Reference (Wye Connection)
Figure 9. Error as a Percent of Reading over Temperature
with External Reference (Wye Connection)
Rev. PrA | Page 9 of 27
ADE7752B
Preliminary Technical Data
Figure 10. Error as a Percent of Reading over Frequency
with an Internal Reference (Wye Connection)
Figure 12. Channel 1 Offset Distribution
Figure 11. Error as a Percent of Reading over Power Supply
with External Reference (Wye Connection)
Figure 13. Error as a Percent of Reading over Power Supply
with Internal Reference (Wye Connection)
Rev. PrA | Page 10 of 27
Preliminary Technical Data
ADE7752B
TERMINOLOGY
Measurement Error
The error associated with the energy measurement made by the
ADE7752B is defined by the following formula:
⎧ Energy Registered by ADE7762 – True Energy ⎫
Percentage Error = ⎨
⎬ × 100%
True Energy
⎩
⎭
Error between Channels
The high-pass filter (HPF) in the current channel has a phase
lead response. To offset this phase response and equalize the
phase response between channels, a phase correction network is
placed in the current channel. The phase correction network
ensures a phase match between the current channels and
voltage channels to within ±0.1° over a range of 45 Hz to 65 Hz
and ±0.2° over a range of 40 Hz to 1 kHz (see Figure 25 and
Figure 26).
ADC Offset Error
This refers to the dc offset associated with the analog inputs to
the ADCs. It means that with the analog inputs connected to
AGND, the ADCs still see an analog input signal offset.
However, because the HPF is always present, the offset is
removed from the current channel and the power calculation is
not affected by this offset.
Gain Error
The gain error of the ADE7752B is defined as the difference
between the measured output frequency (minus the offset) and
the ideal output frequency. The difference is expressed as a
percentage of the ideal frequency. The ideal frequency is
obtained from the ADE7752B transfer function (see the
Transfer Function section).
Power Supply Rejection (PSR)
This quantifies the ADE7752B measurement error as a
percentage of reading when the power supplies are varied.
For the ac PSR measurement, a reading at a nominal supply
(5 V) is taken. A 200 mV rms/100 Hz signal is then introduced
onto the supply and a second reading is obtained under the
same input signal levels. Any error introduced is expressed as a
percentage of reading. See definition for Measurement Error.
For the dc PSR measurement, a reading at nominal supplies
(5 V) is taken. The supply is then varied ±5% and a second
reading is obtained with the same input signal levels. Any error
introduced is again expressed as a percentage of reading.
Rev. PrA | Page 11 of 27
ADE7752B
Preliminary Technical Data
TEST CIRCUIT
VDD
100nF
3
1kΩ
RB
VDD
5 IAP
33nF
17
F2 23
ADE7752B
1kΩ
6
K7
ABS F1 24
TO FREQ.
COUNTER
825Ω
CF 1
IAN
22pF
33nF
K8
CLKOUT 20
SAME AS
IAP, IAN
SAME AS
IAP, IAN
7
IBP
8
IBN
9
ICP
10
ICN
CLKIN 19
22pF
S0 21
S1 22
1kΩ
1kΩ
SCF 18
1MΩ
220V
16
VAP
SAME AS VAP
15
VBP
SAME AS VAP
14
VCP
33nF
PS2501-1
10MHz
VDD
REFIN/OUT 12
100nF
10μF
REVP 4 NOT
CONNECTED
VN AGND DGND
13
11
2
1kΩ
33nF
Figure 14. Test Circuit for Performance Curves
Rev. PrA | Page 12 of 27
05905-015
10μF
ILOAD
Preliminary Technical Data
ADE7752B
THEORY OF OPERATION
The six signals from the current and voltage transducers are
digitized with ADCs. These ADCs are 16-bit second-order ∑-Δ
with an oversampling rate of 833 kHz. This analog input
structure greatly simplifies transducer interface by providing a
wide dynamic range and bipolar input for direct connection to
the transducer. High-pass filters in the current channels remove
the dc component from the current signals. This eliminates any
inaccuracies in the active power calculation due to offsets in the
voltage or current signals (see the HPF and Offset Effects
section).
The low frequency output of the ADE7752B is generated by
accumulating the total active power information. This low
frequency inherently means a long accumulation time between
output pulses. The output frequency is therefore proportional to
the average active power. This average active power information
can, in turn, be accumulated (for example, by a counter) to
generate active energy information. Because of its high output
frequency and therefore shorter integration time, the CF output
is proportional to the instantaneous active power. This pulse is
useful for system calibration purposes that would take place
under steady load conditions.
The active power calculation is derived from the instantaneous
power signal. The instantaneous power signal is generated by a
direct multiplication of the current and voltage signals of each
phase. In order to extract the active power component, the dc
component, the instantaneous power signal is low-pass filtered
on each phase. Figure 15 illustrates the instantaneous active
power signal and shows how the active power information can
be extracted by low-pass filtering the instantaneous power
signal. This method is used to extract the active power
information on each phase of the polyphase system. The total
active power information is then obtained by adding the
individual phase active power. This scheme correctly calculates
active power for nonsinusoidal current and voltage waveforms
at all power factors. All signal processing is carried out in the
digital domain for superior stability over temperature and time.
p(t) = i(t) × v(t)
WHERE:
v(t) = V × cos (ωt)
i(t) = I × cos (ωt)
p(t) = V × I
{1+ cos (2ωt)}
2
V×I
V×I
2
TIME
INSTANTANEOUS
POWER SIGNAL - p(t)
ADC
⎛ V × 1 ⎞ × cos(60°)
⎜
⎟
⎝ 2 ⎠
ABS
INSTANTANEOUS
TOTAL
POWER SIGNAL
LPF
|X|
ADC
DIGITAL-TOFREQUENCY
HPF
IBP
IBN
LPF
|X|
MULTIPLIER
VBP
F1
F2
Σ
ADC
(1)
INSTANTANEOUS
VA × IA + VB × IB +
ACTIVE POWER SIGNAL
VC × IC
2
MULTIPLIER
VAP
Low-pass filtering, the method used to extract the active power
information from the individual instantaneous power signal, is
still valid when the voltage and current signals of each phase are
not in phase. Figure 16 displays the unity power factor
condition and a displacement power factor (DPF) = 0.5, that is,
current signal lagging the voltage by 60°, for one phase of the
polyphase. Assuming that the voltage and current waveforms
are sinusoidal, the active power component of the instantaneous
power signal (the dc term) is given by
V×I
2
HPF
IAP
IAN
POWER FACTOR CONSIDERATIONS
Σ
ADC
DIGITAL-TOFREQUENCY
Σ
CF
HPF
ADC
MULTIPLIER
VCP
VN
LPF
|X|
05757-016
ICP
ICN
ADC
Figure 15. Signal Processing Block Diagram
Rev. PrA | Page 13 of 27
ADE7752B
Preliminary Technical Data
This is the correct active power calculation.
INSTANTANEOUS
POWER SIGNAL
i (t ) = I O + 2 ×
∞
∑ V I × sin (nωt β )
n
n
(3)
n=0
INSTANTANEOUS
ACTIVE POWER SIGNAL
where:
i(t) is the instantaneous current.
IO is the dc component.
In is the rms value of current harmonic n.
βn is the phase angle of the current harmonic.
V× I
2
0V
CURRENT
VOLTAGE
INSTANTANEOUS
POWER SIGNAL
Using Equations 2 and 3, the active power, P, can be expressed
in terms of its fundamental active power (P1) and harmonic
active power (PH).
INSTANTANEOUS
ACTIVE POWER SIGNAL
P = P1 + PH
V× I
× cos(60°)
2
where:
0V
P1 = V 1 × I1 cos φ1
60°
05757-017
VOLTAGE
φ1 = α1 − β1
CURRENT
∞
PH =
Figure 16. DC Component of Instantaneous Power Signal
∑V
n
n =1
The active power calculation method also holds true for nonsinusoidal current and voltage waveforms. All voltage and
current waveforms in practical applications have some
harmonic content. Using the Fourier Transform, instantaneous
voltage and current waveforms can be expressed in terms of
their harmonic content
∞
∑V
n
× sin (nωt + α n )
n=0
× I n cos φ n
(5)
φn = α n − β n
NONSINUSOIDAL VOLTAGE AND CURRENT
v (t ) = Vo + 2 ×
(4)
(2)
As can be seen from Equation 5, a harmonic active power
component is generated for every harmonic, provided that
harmonic is present in both the voltage and current waveforms.
The power factor calculation has been shown to be accurate in
the case of a pure sinusoid. Therefore, the harmonic active
power also correctly accounts for power factor since harmonics
are made up of a series of pure sinusoids. A limiting factor on
harmonic measurement is the bandwidth. On the ADE7752B,
the bandwidth of the active power measurement is 14 kHz with
a master clock frequency of 10 MHz.
where:
v(t) is the instantaneous voltage.
VO is the average value.
Vn is the rms value of voltage harmonic n.
and α n is the phase angle of the voltage harmonic.
Rev. PrA | Page 14 of 27
Preliminary Technical Data
ADE7752B
ANALOG INPUTS
CURRENT CHANNELS
VOLTAGE CHANNELS
The voltage outputs from the current transducers are connected
to the ADE7752B current channels, which are fully differential
voltage inputs. IAP, IBP, and ICP are the positive inputs for IAN,
IBN, and ICN, respectively.
The output of the line voltage transducer is connected to the
ADE7752B at this analog input. Voltage channels are a pseudodifferential voltage input. VAP, VBP, and VCP are the positive
inputs with respect to VN.
The maximum peak differential signal on the current channel
should be less than ±500 mV (353 mV rms for a pure sinusoidal
signal) for the specified operation.
The maximum peak differential signal on the voltage channel is
±500 mV (353 mV rms for a pure sinusoidal signal) for specified operation.
IAP–IAN
Figure 18 illustrates the maximum signal levels that can be
connected to the ADE7752B voltage channels.
+500mV
IAP
VAP–VN
IA
IAN
+500mV
VCM
–500mV
VAP
VCM
AGND
DIFFERENTIAL INPUT
±500mV MAX PEAK
05757-018
COMMON-MODE
±25mV MAX
COMMON-MODE
±25mV MAX
Figure 17. Maximum Signal Levels, Current Channel
–500mV
The maximum signal levels on IAP and IAN are shown in
Figure 17. The maximum differential voltage between IAP and
IAN is ±500 mV. The differential voltage signal on the inputs
must be referenced to a common mode, for example, AGND.
The maximum common-mode signal shown in Figure 17 is
±25 mV.
VA
VN
VCM
VCM
AGND
05757-019
DIFFERENTIAL INPUT
±500mV MAX PEAK
Figure 18. Maximum Signal Levels, Voltage Channel
Voltage channels must be driven from a common-mode voltage,
that is, the differential voltage signal on the input must be referenced to a common mode (usually AGND). The analog inputs
of the ADE7752B can be driven with common-mode voltages of
up to 25 mV with respect to AGND. However, best results are
achieved using a common mode equal to AGND.
Rev. PrA | Page 15 of 27
ADE7752B
Preliminary Technical Data
TYPICAL CONNECTION DIAGRAMS
CURRENT CHANNEL CONNECTION
METER CONNECTIONS
Figure 19 shows a typical connection diagram for the current
channel (IA). A current transformer (CT) is the current transducer selected for this example. Notice the common-mode
voltage for the current channel is AGND and is derived by
center tapping the burden resistor to AGND. This provides the
complementary analog input signals for IAP and IAN. The CT
turns ratio and burden resistor Rb are selected to give a peak
differential voltage of ±500 mV at maximum load.
In 3-phase service, two main power distribution services exist:
3-phase 4-wire or 3-phase 3-wire. The additional wire in the
3-phase 4-wire arrangement is the neutral wire. The voltage
lines have a phase difference of ±120° (±2π/3 radians) between
each other (see Equation 6).
V A (t ) = 2 × V A × cos (ω l t )
In theory it is better to center tap Rb; however, this requires
very careful attention to the layout and matching of the resistors
to ensure that the channels have the same resistance. A single
resistor may be more practical and is a valid design choice.
Rf
CT
IAP
Cf
Rf
IP
The current inputs are represented by
I A (t ) = 2 I A × cos (ω l t + φ A )
IAN
±500mV
Cf
PHASE NEUTRAL
I B (t ) = 2 I B × cos ⎧⎨ω l t +
⎩
I C (t ) = 2 I C × cos ⎧⎨ω l t +
⎩
Figure 19. Typical Connection for Current Channels
VOLTAGE CHANNELS CONNECTION
Cf
The instantaneous powers can then be calculated as follows:
PA(t) = VA(t) × IA(t)
PB(t) = VB(t) × IB(t)
PC(t) = VC(t) × IC(t)
Then:
PA (t ) = VA × I A × cos(φ A ) − VA × I A × cos (2ωlt + φ A )
4π
PB (t ) = VB × I B × cos(φB ) − VB × I B × cos ⎛⎜ 2ωlt +
+ φB ⎞⎟
3
⎠
⎝
8π
⎛
+ φC ⎞⎟
PC (t ) = VC × IC × cos(φC ) − VC × IC × cos ⎜ 2ωlt +
3
⎝
⎠
VN
±500mV
Rf
Cf
VR*
VAP
±500mV
VN
Rf
Cf
PHASE NEUTRAL
* Ra >> Rf + VR; * Rb + VR = Rf
05757-021
Rb*
(8)
As shown in Equation 8, in the ADE7752B, the active power
calculation per phase is made when current and voltage inputs
of one phase are connected to the same channel (A, B, or C).
Then the summation of each individual active power calculation gives the total active power information, P(t) = PA(t) +
PB(t) + PC(t).
Cf
PHASE NEUTRAL
Ra*
(7)
IA, IB, and IC represent the rms value of the current of each
phase.
φA, φB, and φC represent the phase difference of the current and
voltage channel of each phase.
VAP
Rf
AGND
2π
+ φ B ⎫⎬
3
⎭
4π
+ φ C ⎫⎬
3
⎭
where:
Figure 20 shows two typical connections for the voltage channel. The first option uses a potential transformer (PT) to provide complete isolation from the main voltage. In the second
option, the ADE7752B is biased around the neutral wire, and a
resistor divider is used to provide a voltage signal proportional
to the line voltage. Adjusting the ratio of Ra, Rb, and VR is a
convenient way of carrying out a gain calibration on the meter.
VR can be implemented using either a potentiometer or a
binary weighted series of resistors. Either configuration works,
however, the potentiometer is subject to noise over time. Two
fixed value resistors can be used in place of VR to minimize the
noise.
PT
(6)
where VA, VB, and VC represent the voltage rms values of the
different phases.
05757-020
Rb
2π ⎞
V B (t ) = 2 × V B × cos ⎛⎜ ω l t +
⎟
3 ⎠
⎝
4π ⎞
V C (t ) = 2 × VC × cos ⎛⎜ ω l t +
⎟
3 ⎠
⎝
Figure 20. Typical Connections for Voltage Channels
Rev. PrA | Page 16 of 27
Preliminary Technical Data
ADE7752B
Figure 21 shows the connections of the ADE7752B analog
inputs with the power lines in a 3-phase 3-wire delta service.
Ra*
Figure 22 shows the connections of the ADE7752B analog
inputs with the power lines in a 3-phase 4-wire Wye service.
Cf
Ra*
Cf
Rb*
Rb*
VAP
IAP
VR*
VAP
VR*
IAP
ANTIALIASING
FILTERS
CT
IAN
Rb*
IAN
Rb*
ANTIALIASING
FILTERS
CT
CT
PHASE A
PHASE A
PHASE C
SOURCE
SOURCE
Cf
PHASE C
CT
Rb*
ANTIALIASING
FILTERS
IBP
IBN
VBP
VR*
ANTIALIASING
FILTERS
Rb*
VR*
IBP
Ra*
IBN
Rb*
VBP
VR*
* Ra >> Rf + VR; * Rb + VR = Rf
Cf
Rb*
ANTIALIASING
FILTERS
ICP
LOAD
ICN
VCP
Rf
VN
Figure 21. 3-Phase 3-Wire Meter Connection with ADE7752B
CF
* Ra >> Rf + VR; * Rb + VR = Rf
Figure 22. 3-Phase 4-Wire Meter Connection with ADE7752B
Note that only two current inputs and two voltage inputs of the
ADE7752B are used in this case. The active power calculated by
the ADE7752B does not depend on the selected channels.
Rev. PrA | Page 17 of 27
05757-023
Rb*
05757-022
Cf
Cf
CT
PHASE B
Ra*
Ra*
Rb*
LOAD
VN
Rf
PHASE B
ADE7752B
Preliminary Technical Data
POWER SUPPLY MONITOR
The ADE7752B contains an on-chip power supply monitor. The
power supply (VDD) is monitored continuously by the ADE7752B.
At power up, when the supply is less than 4V ±2% and VREF is less
than 1.9 V (typ), the outputs of the ADE7752B are inactive and
the data path is held in reset. Once VDD is greater than 4V ±2%
and VREF is greater than 1.9 V (typ), the chip is active and energy
accumulation begins. At power-down, when VDD falls below 4 V
or VREF falls below 1.9 V (typ), the data path is again held in reset.
This implementation ensures correct device operation at powerup and at power-down. The power supply monitor has built-in
hysteresis and filtering. This gives a high degree of immunity to
false triggering due to noisy supplies.
4V
VREF
2.4V
1.9V
0V
INTERNAL
INACTIVE
RESET
Rev. PrA | Page 18 of 27
ACTIVE
INACTIVE
Figure 23. On-Chip Power Supply Monitor
05757-024
The power supply and decoupling for the part should be such
that the ripple at VDD does not exceed ±5% as specified for
normal operation.
VDD
5V
ADE7752B
Preliminary Technical Data
HPF AND OFFSET EFFECTS
Figure 24 shows the effect of offsets on the active power
calculation. An offset on the current channel and voltage
channel contributes a dc component after multiplication as
shown in Figure 24. Since this dc component is extracted by the
LPF and is used to generate the active power information for
each phase, the offsets can contribute a constant error to the
total active power calculation. The HPF in the current channels
avoids this problem easily. By removing the offset from at least
one channel, no error component can be generated at dc by the
multiplication. Error terms at cos(ωt) are removed by the LPF
and the digital-to-frequency conversion (see the Digital-toFrequency Conversion) section.
The ADE7752B is phase compensated up to 1 kHz as shown. This
ensures correct active harmonic power calculation even at low
power factors.
{V cos(ωt ) + VOS }× {I cos(ωt ) + I OS } =
V ×I
+ VOS × I OS + VOS × I cos(ωt ) + I OS × V cos(ωt ) (9)
2
V ×I
+
× cos(2ωt )
2
Figure 25. Phase Error between Channels (0 Hz to 1 kHz)
DC COMPONENT (INCLUDING ERROR TERM)
IS EXTRACTED BY THE LPF FOR REAL
POWER CALCULATION
VOS × IOS
V× I
2
0
ω
2ω
FREQUENCY – RAD/S
05757-026
IOS × V
VOS × I
Figure 24. Effect of Channel Offset on the Active Power Calculation
The HPF in the current channels has an associated phase response
that is compensated for on-chip. Figure 25 and Figure 26 show the
phase error between channels with the compensation network.
Rev. PrA | Page 19 of 27
Figure 26. Phase Error Between Channels (40 Hz to 70 Hz)
ADE7752B
Preliminary Technical Data
DIGITAL-TO-FREQUENCY CONVERSION
After multiplication, the digital output of the low-pass filter
contains the active power information of each phase. However,
since this LPF is not an ideal brick wall filter implementation, the
output signal also contains attenuated components at the line
frequency and its harmonics, that is, cos(hωt), where h = 1, 2, 3 ….
The average value of a sinusoidal signal is zero. Thus, the
frequency generated by the ADE7752B is proportional to the
average active power. Figure 27 shows the digital-to-frequency
conversion for steady load conditions, that is, constant voltage
and current.
The magnitude response of the filter is given by
The frequency output CF varies over time, even under steady load
conditions (see Figure 27). This frequency variation is primarily
due to the cos(2ωt) components in the instantaneous active power
signal. The output frequency on CF can be up to 160× higher than
the frequency on F1 and F2. The higher output frequency is
generated by accumulating the instantaneous active power signal
over a much shorter time, while converting it to a frequency. This
shorter accumulation period means less averaging of the cos(2ωt)
component. Therefore, some of this instantaneous power signal
passes through the digital-to-frequency conversion.
1
⎧f⎫
1+ ⎨ ⎬
⎩8⎭
(10)
2
where the −3 dB cutoff frequency of the low-pass filter is 8 Hz.
For a line frequency of 50 Hz, this would give an attenuation of
the 2ω(100 Hz) component of approximately −22 dB. The
dominating harmonic is twice the line frequency, that is,
cos(2ωt), due to the instantaneous power signal. Figure 27
shows the instantaneous active power signal at the output of the
CF, which still contains a significant amount of instantaneous
power information, cos(2ωt).
Where CF is used for calibration purposes, the frequency counter
should average the frequency to remove the ripple and obtain a
stable frequency. If CF is being used to measure energy, for
example, in a microprocessor-based application, the CF output
should also be averaged to calculate power. Because the outputs F1
and F2 operate at a much lower frequency, significant averaging of
the instantaneous active power signal is carried out. The result is a
greatly attenuated sinusoidal content and a virtually ripple-free
frequency output on F1 and F2, which are used to measure energy
in a stepper-motor based meter.
This signal is then passed to the digital-to-frequency converter
where it is integrated (accumulated) over time to produce an
output frequency. This accumulation of the signal suppresses or
averages out any non-dc component in the instantaneous active
power signal.
ABS
VA
LPF
|X|
FREQUENCY
F1
IA
DIGITAL-TOFREQUENCY
F1
F2
Σ
VB
LPF
MULTIPLIER
TIME
|X|
Σ
IB
CF
DIGITAL-TOFREQUENCY
Σ
CF
VC
TIME
LPF
MULTIPLIER
|X|
V× I
2
IC
LPF TO EXTRACT
REAL POWER
(DC TERM)
cos(2ωt)
ATTENUATED BY LPF
0
ω
2ω
FREQUENCY – RAD/S
INSTANTANEOUS REAL POWER SIGNAL
(FREQUENCY DOMAIN)
Figure 27. Active Power-to-Frequency Conversion
Rev. PrA | Page 20 of 27
05757-029
MULTIPLIER
FREQUENCY
|H ( f )| =
Preliminary Technical Data
ADE7752B
POWER MEASUREMENT CONSIDERATIONS
Calculating and displaying power information always have some
associated ripple that depends on the integration period used in the
MCU to determine average power as well as the load. For example,
at light loads, the output frequency can be 10 Hz. With an integration period of two seconds, only about 20 pulses are counted. The
possibility of missing one pulse always exists since the ADE7752B
output frequency is running asynchronously to the MCU timer.
This would result in a 1-in-20 or 5% error in the power measurement. To remedy this, an appropriate integration time should be
considered to achieve the desired accuracy.
MODE SELECTION OF THE SUM OF THE THREE
ACTIVE ENERGIES
The ADE7752B can be configured to execute the arithmetic
sum of the three active energies, Wh = WhΦA + WhΦB + WhΦC,
or the sum of the absolute value of these energies, Wh = |WhΦA|
+ |WhΦB| + |WhΦC|. The selection between the two modes can
be made by setting the ABS pin. Logic high and logic low
applied on the ABS pin correspond to the arithmetic sum and
the sum of absolute values, respectively.
When the sum of the absolute values is selected, the active
energy from each phase is always counted positive in the total
active energy. It is particularly useful in 3-phase 4-wire
instillation where the sign of the active power should always be
the same. If the meter is misconnected to the power lines, that
is, CT connected in the wrong direction then the total active
energy recorded without this solution can be reduced by twothirds.
The sum of the absolute values assures that the active energy
recorded represents the actual active energy delivered.
Regardless of the mode selected using this pin, the reverse
power pin still detects when negative power is present on the
sum of the three phase inputs.
Rev. PrA | Page 21 of 27
ADE7752B
Preliminary Technical Data
TRANSFER FUNCTION
FREQUENCY OUTPUTS F1 AND F2
Example 1
The ADE7752B calculates the product of six voltage signals (on
current channel and voltage channel) and then low-pass filters
this product to extract active power information. This active
power information is then converted to a frequency. The
frequency information is output on F1 and F2 in the form of
active high pulses. The pulse rate at these outputs is relatively
low, for example, 2.01 Hz maximum for ac signals with SCF =
S0 = 0; S1 = 1 (see Table 6). This means that the frequency at
these outputs is generated from active power information
accumulated over a relatively long period. The result is an
output frequency that is proportional to the average active
power. The averaging of the active power signal is implicit to
the digital-to-frequency conversion. The output frequency or
pulse rate is related to the input voltage signals by the following
equation:
Thus, if full-scale differential dc voltages of +500 mV are
applied to VA, VB, VC, IA, IB, and IC, respectively (500 mV is
the maximum differential voltage that can be connected to
current and voltage channels), then the expected output
frequency is calculated as follows:
Freq =
6.181 × (VAN × I A + VBN × I B + VCN × IC ) × F 1− 7
VREF 2
(11)
where:
Freq = output frequency on F1 and F2 (Hz).
VAN, VBN, and VCN = differential rms voltage signal on voltage
channels (V).
IA, IB, and IC = differential rms voltage signal on current channels
(V).
VREF = the reference voltage (2.4 V ±8%) (V).
F1–7 = one of seven possible frequencies selected by using the
logic inputs SCF, S0, and S1 (see Table 5).
Table 5. F1–7 Frequency Selection1
1
SCF
0
S1
0
S0
0
F1–7 (Hz)
2.30
1
0
0
4.61
0
0
1
1.15
1
0
1
4.61
0
1
0
5.22
1
1
0
1.15
0
1
1
0.58
1
1
1
0.58
F1–7 is a fraction of the master clock and therefore varies if the specified
CLKIN frequency is altered.
F1–7 = 0.58 Hz, SCF = S0 = S1 = 1
VAN = VBN = VCN = IA = IB = IC
= 500 mV dc = 0.5 V(rms of dc = dc)
VREF = 2.4 V (nominal reference value)
Note that if the on-chip reference is used, actual output
frequencies can vary from device to device due to reference
tolerance of ±8%.
Freq = 3 ×
6.181 × 0.5 × 0.5 × 0.58
2.4 2
= 0.467 Hz
(12)
Example 2
In this example, with ac voltages of ±500 mV peak applied to
the voltage channels and current channels, the expected output
frequency is calculated as follows:
F1− 7 = 0.58 Hz, SCF = S0 = S1 = 1
VAN = VBN = VCN = IA = IB = IC
= 500 mV peak AC =
0.5
(13)
Vrms
2
VREF = 2.4 V (nominal reference value)
Note that if the on-chip reference is used, actual output frequencies can vary from device to device due to reference
tolerance of ±8%.
Freq = 3 ×
6.181 × 0.5 × 0.5 × 0.58
2 × 2 × 2.4 2
= 0.233 Hz
(14)
As can be seen from these two example calculations, the maximum
output frequency for ac inputs is always half of that for dc input
signals. The maximum frequency also depends on the number of
phases connected to the ADE7752B. In a 3-phase 3-wire delta service, the maximum output frequency is different from the maximum output frequency in a 3-phase 4-wire Wye service. The
reason is that there are only two phases connected to the analog
inputs, but also that in a delta service, the current channel input
and voltage channel input of the same phase are not in phase in
normal operation.
Rev. PrA | Page 22 of 27
Preliminary Technical Data
ADE7752B
Example 3
In this example, the ADE7752B is connected to a 3-phase 3wire delta service as shown in Figure 21. The total active energy
calculation processed in the ADE7752B can be expressed as
Note that if the on-chip reference is used, actual output
frequencies can vary from device to device due to reference
tolerance of ±8%.
Freq = 2 ×
6.181 × 0.5 × 0.5 × 0.60
2 × 2 × 2.4 2
Total Active Power = (VA – VC) × IA + (VB – VC) × IB
×
3
= 0.139 Hz
2
where:
Table 6 shows a complete listing of all maximum output
frequencies when using all three channel inputs.
VA, VB, and VC represent the voltage on phase A, phase B, and
phase C, respectively.
IA and IB represent the current on phase A and phase B,
respectively.
Table 6: Maximum Output Frequency on F1 and F2
SCF
0
S1
0
S0
0
Maximum
Frequency for AC
Inputs (Hz)
0.93
1
0
1
1.86
3.71
(IAP − IAN ) + (VB − VC ) × (IBP − IBN )
0
0
1
0.46
0.93
4π ⎞ ⎞
⎛
P = ⎜ 2 × V A × cos(ωl t ) − 2 × VC × cos⎛⎜ ω l t +
⎟⎟
3 ⎠⎠
⎝
⎝
× 2 × I A × cos(ωl t )
1
0
1
1.86
3.71
0
1
0
2.10
4.20
1
1
0
0.46
0.93
0
1
1
0.23
0.47
1
1
1
0.23
0.47
As the voltage and current inputs respect Equations 5 and 6, the
total active power (P) is
P = (VA − VC )
(15)
2π
4π ⎞ ⎞
⎛
+ ⎜ 2 × V B × cos⎛⎜ ω l t + ⎞⎟ − v 2 × VC × cos⎛⎜ ωl t +
⎟⎟
3 ⎠
3 ⎠⎠
⎝
⎝
⎝
2π ⎞
× 2 × I B × cos⎛⎜ ωl t +
⎟
3 ⎠
⎝
(16)
P then becomes
2π
2π ⎞
⎛
P = VAN × I A × ⎜ sin⎛⎜ ⎞⎟ + sin⎛⎜ 2ω l t + ⎞⎟ ⎟
3 ⎠⎠
⎝
⎝ ⎝ 3 ⎠
(17)
π
π ⎞
⎛
+ VBN × I B × ⎜ sin⎛⎜ ⎞⎟ + sin⎛⎜ 2ω l t + ⎞⎟ ⎟
3 ⎠⎠
⎝
⎝ ⎝3⎠
where:
The pulse output calibration frequency (CF) is intended for use
during calibration. The output pulse rate on CF can be up to 64×
the pulse rate on F1 and F2. Table 7 shows how the two
frequencies are related, depending on the states of the logic
inputs S0, S1, and SCF. Because of its relatively high pulse rate,
the frequency at this logic output is proportional to the
instantaneous active power. As is the case with F1 and F2, the
frequency is derived from the output of the low-pass filter after
multiplication. However, since the output frequency is high, this
active power information is accumulated over a much shorter
time. Thus, less averaging is carried out in the digital-tofrequency conversion. The CF output is much more responsive
to power fluctuations with much less averaging of the active
power signal (see Figure 15).
Table 7. Maximum Output Frequency on CF
VAN = V × sin(2π/3).
VBN = V × sin(π/3).
As the LPF on each channel eliminates the 2ωl component of
the equation, the active power measured by the ADE7752B is
P = V AN × I A ×
Maximum
Frequency for DC
Inputs (Hz)
1.85
FREQUENCY OUTPUT CF
For simplification, assume that ΦA = ΦB = ΦC = 0 and
VA = VB = VC = V. The preceding equation becomes
2π
2π
P = 2 × V × I A × sin⎛⎜ ⎞⎟ × sin⎛⎜ ω l t + ⎞⎟ × cos(ω l t )
3 ⎠
⎝ 3 ⎠
⎝
π⎞
2π
⎛
+ 2 × V × I B × sin⎜ ⎟ × sin(ω l t + π)× cos⎛⎜ ω l t + ⎞⎟
3 ⎠
⎝3⎠
⎝
(20)
3
3
+ V BN × I B ×
2
2
(18)
If full-scale ac voltage of ±500 mV peak is applied to the voltage
channels and current channels, the expected output frequency
is calculated as follows:
SCF
0
1
0
1
0
1
0
1
F1− 7 = 0.60Hz, SCF = S0 = S1 = 1
VAN = VBN = IA = IB = IC = 500 mV peak ac =
0.5
2
V rms
(19)
VCN = IC = 0
VREF = 2.4V nominal reference value
Rev. PrA | Page 23 of 27
S1
0
0
0
0
1
1
1
1
S0
0
0
1
1
0
0
1
1
F1–7 (Hz)
2.3
4.61
1.15
4.61
5.22
1.15
0.58
0.58
CF Maximum for AC Signals (Hz)
16 × F1, F2 = 14.88
8 × F1, F2 = 14.88
32 × F1, F2 = 14.88
16 × F1, F2 = 29.76
160 × F1, F2 = 336
16 × F1, F2 = 7.36
32 × F1, F2 = 7.36
16 × F1, F2 = 3.68
Preliminary Technical Data
ADE7752B
SELECTING A FREQUENCY FOR AN ENERGY METER APPLICATION
As shown in Table 5, the user can select one of seven
frequencies. This frequency selection determines the maximum
frequency on F1 and F2. These outputs are intended to be used
to drive the energy register (electromechanical or other). Since
seven different output frequencies can be selected, the available
frequency selection has been optimized for a 3-phase 4-wire
service with a meter constant of 100 imp/kWhr and a
maximum current of between 10 A and 100 A. Table 8 shows
the output frequency for several maximum currents (IMAX) with
a line voltage of 220 V (phase neutral). In all cases, the meter
constant is 100 imp/kWhr.
Table 8. F1 and F2 Frequency at 100 imp/kWhr
IMAX (A)
10
25
40
60
80
100
F1 and F2 (Hz)
0.18
0.46
0.73
1.10
1.47
1.83
The F1–7 frequencies allow complete coverage of this range of
output frequencies on F1 and F2. When designing an energy
meter, the nominal design voltage on the voltage channels
should be set to half scale to allow for calibration of the meter
constant. The current channel should also be no more than half
scale when the meter sees maximum load. This allows
overcurrent signals and signals with high crest factors to be
accommodated. Table 9 shows the output frequency on F1 and
F2 when all six analog inputs are half scale.
Table 9. F1 and F2 Frequency with Half-Scale AC Inputs
SCF
0
1
0
1
0
1
0
1
S1
0
0
0
0
1
1
1
1
S0
0
0
1
1
0
0
1
1
F1–7 (Hz)
2.3
4.61
1.15
4.61
5.22
1.15
0.58
0.58
Frequency on F1 and F2
(Half-Scale AC Inputs) (Hz)
0.23
0.46
0.12
0.46
0.53
0.12
0.06
0.06
When selecting a suitable F1–7 frequency for a meter design, the
frequency output at IMAX (maximum load) with a 100 imp/kWhr
meter constant should be compared with Column 5 of Table 9. The
frequency that is closest in Table 9 determines the best choice of
frequency (F1–7). For example, if a 3-phase 4-wire Wye meter with a
25 A maximum current is being designed, the output frequency on
F1 and F2 with a 100 imp/kWhr meter constant is 0.46 Hz at 25 A
and 220 V (see Table 8). Looking at Table 9, the closest frequency to
0.46 Hz in Column 5 is 0.53 Hz. Therefore, F1–7 = 5.22 Hz is
selected for this design.
FREQUENCY OUTPUTS
Figure 2 shows a timing diagram for the various frequency
outputs. The outputs F1 and F2 are the low frequency outputs
that can be used to directly drive a stepper motor or electromechanical impulse counter. The F1 and F2 outputs provide
two alternating high going pulses. The pulse width (t1) is set at
120 ms, and the time between the rising edges of F1 and F2 (t3)
is approximately half the period of F1 (t2). If, however, the
period of F1 and F2 falls below 550 ms (1.81 Hz), the pulse
width of F1 and F2 is set to half of their period. The maximum
output frequencies for F1 and F2 are shown in Table 6.
The high frequency CF output is intended to be used for
communications and calibration purposes. CF produces a 90 mswide active high pulse (t4) at a frequency proportional to active
power. The CF output frequencies are given in Table 7. As in the
case of F1 and F2, if the period of CF (t5) falls below 190 ms, the CF
pulse width is set to half the period. For example, if the CF
frequency is 20 Hz, the CF pulse width is 25 ms.
NO LOAD THRESHOLD
The ADE7752B includes no load threshold and start-up current
circuitry features that eliminate any creep effects in the meter.
The circuit is designed to issue a minimum output frequency.
Any load generating a frequency lower than this minimum
output frequency does not cause a pulse to be issued on F1, F2, or
CF. The no-load threshold is determined by the sum of all phases.
The minimum output frequency is given as 0.0075% of the fullscale output frequency for each of the F1–7 frequency selections, or
approximately 0.0029% of the F1–7 frequency (see Table 10). For
example, for an energy meter with a 100 imp/kWhr meter
constant using F1–7 (4.61 Hz), the minimum output frequency at
F1 or F2 would be 13.35 × 10–5 Hz. This would be 2.13 × 10–3 Hz
at CF (16 × F1 Hz). In this example, the no load threshold would
be equivalent to 4.8 W of load or a start-up current of 20.03 mA
at 240 V.
Rev. PrA | Page 24 of 27
Preliminary Technical Data
ADE7752B
Table 10. CF, F1, and F2 Minimum Frequency at No Load
Threshold
SCF
0
1
0
1
0
1
0
1
S1
0
0
0
0
1
1
1
1
S0
0
0
1
1
0
0
1
1
F1, F2 Minimum (Hz)
6.94E − 05
1.39E − 04
3.47E − 05
1.39E − 04
1.58E − 04
3.47E − 05
1.75E − 05
1.75E − 05
CF Minimum (Hz)
1.11E − 03
1.11E − 03
1.11E − 03
2.23E − 03
2.52E − 02
5.55E − 04
5.60E − 04
2.80E − 04
NEGATIVE POWER INFORMATION
The ADE7752B detects when total power, calculated as the sum
of the three phases, is negative. This mechanism can detect an
incorrect connection of the meter or generation of negative
active energy. The REVP pin output goes active high when
negative power is detected on the sum of the three phase inputs.
If positive active power is detected on the sum of three phases,
then REVP pin output is low.
The REVP pin output changes state at the same time as a pulse
is issued on CF. If the sum of the phases measure negative
power, then the REVP pin output stays high until the sum of the
phases measures positive power.
Rev. PrA | Page 25 of 27
ADE7752B
Preliminary Technical Data
OUTLINE DIMENSIONS
15.60 (0.6142)
15.20 (0.5984)
24
13
7.60 (0.2992)
7.40 (0.2913)
1
12
10.65 (0.4193)
10.00 (0.3937)
2.65 (0.1043)
2.35 (0.0925)
0.75 (0.0295)
× 45°
0.25 (0.0098)
0.30 (0.0118)
0.10 (0.0039)
COPLANARITY 1.27 (0.0500)
BSC
0.10
0.51 (0.020)
0.31 (0.012)
8°
SEATING
0.33 (0.0130) 0°
PLANE
0.20 (0.0079)
1.27 (0.0500)
0.40 (0.0157)
COMPLIANT TO JEDEC STANDARDS MS-013-AD
CONTROLLING DIMENSIONS ARE IN MILLIMETERS; INCH DIMENSIONS
(IN PARENTHESES) ARE ROUNDED-OFF MILLIMETER EQUIVALENTS FOR
REFERENCE ONLY AND ARE NOT APPROPRIATE FOR USE IN DESIGN.
Figure 28. 24-Lead Standard Small Outline Package [SOIC_W]
Wide Body
(RW-24)
Dimensions shown in millimeters and (inches)
ORDERING GUIDE
Model
ADE7752BARWZ1
ADE7752BARWZ-RL1
ADE7752BARW
ADE7752BARW-RL
EVAL-ADE7752BEB
1
2
Package Description
28-Lead Standard Small Outline Package [SOIC_W]
28-Lead Standard Small Outline Package [SOIC_W]
28-Lead Standard Small Outline Package [SOIC_W]
28-Lead Standard Small Outline Package [SOIC_W]
ADE7752B Evaluation Board
Z = Pb-free part.
RW = small outline wide body package in tubes.
Rev. PrA | Page 26 of 27
Package Option
RW-282
RW-28 on 13" Reels
RW-28
RW-28 on 13" Reels
Preliminary Technical Data
ADE7752B
NOTES
© 2006 Analog Devices, Inc. All rights reserved. Trademarks and
registered trademarks are the property of their respective owners.
PR05905-0-1/06(PrA)
Rev. PrA | Page 27 of 27