EVAL-ADE7759E Ver la hoja de datos (PDF) - Analog Devices
Número de pieza
componentes Descripción
Fabricante
EVAL-ADE7759E Datasheet PDF : 32 Pages
| |||
ADE7759
ALIASING EFFECTS
IMAGE
FREQUENCIES
SAMPLING
FREQUENCY
0
2
447
894
FREQUENCY – kHz
Figure 21. ADC and Signal Processing in Channel 1
For a di/dt sensor such as a Rogowski coil, however, the sensor
has 20 dB per decade gain. This will neutralize the –20 dB per
decade attenuation produced by this simple LPF and nullifies the
antialias filter. Therefore, when using a di/dt sensor, measure
should be taken to offset the 20 dB per decade gain coming from
the di/dt sensor and produce sufficient attenuation to eliminate
any aliasing effect. One simple approach is to cascade two RC
filters to produce –40 dB per decade attenuation. The transfer
function for a cascaded filter is the following:
H(s) =
1
1 + sR1C1 + sR2C2 + sR1C2 + s2R1C1R2C2
where R1C1 represents the RC used in the first stage of the
cascade and R2C2 in that of the second stage. The s2 term in the
transfer function produces a –40 dB/decade attenuation. Note
that to minimize the measurement error, especially at low power
factor, it is important to match the phase angle between the voltage
and the current channel. The small phase mismatch in the exter-
nal antialias filter can be corrected using the Phase Calibration
register (PHCAL[7:0])—see Phase Compensation section.
ADC Transfer Function
Below is an expression which relates the output of the LPF in
the sigma-delta ADC to the analog input signal level. Both
ADCs in the ADE7759 are designed to produce the same out-
put code for the same input signal level.
Code( ADC ) = 3.0492 × VIN × 262, 144
VREF
Therefore, with a full-scale signal on the input of 0.5 V and an
internal reference of 2.42 V, the ADC output code is nominally
165,151 or 2851Fh. The maximum code from the ADC is
±262,144, which is equivalent to an input signal level of ± 0.794 V.
However, for specified performance it is not recommended that
the full-scale input signal level of 0.5 V be exceeded.
Reference Circuit
Shown in Figure 22 is a simplified version of the reference out-
put circuitry. The nominal reference voltage at the REFIN/OUT
pin is 2.42 V. This is the reference voltage used for the ADCs in
the ADE7759. However, Channel 1 has three input range selec-
tions, which are selected by dividing down the reference value
used for the ADC in Channel 1. The reference value used for
Channel 1 is divided down to 1/2 and 1/4 of the nominal value
by using an internal resistor divider as shown in Figure 22.
PTAT
MAXIMUM
LOAD = 10A
60A
2.5V
1.7k⍀
OUTPUT
IMPEDANCE
6k⍀
REFIN/OUT
2.42V
12.5k⍀
12.5k⍀
12.5k⍀
12.5k⍀
REFERENCE INPUT
TO ADC CHANNEL 1
(RANGE SELECT)
2.42V, 1.21V, 0.6V
Figure 22. ADC and Reference Circuit Output
The REFIN/OUT pin can be overdriven by an external source,
e.g., an external 2.5 V reference. Note that the nominal refer-
ence value supplied to the ADCs is now 2.5 V not 2.42 V. This
has the effect of increasing the nominal analog input signal
range by 2.5/2.42 ϫ 100% = 3%, or from 0.5 V to 0.5165 V.
The internal voltage reference on the ADE7759 has a tempera-
ture drift associated with it—see ADE7759 Specifications for the
temperature coefficient specification (in ppm°C). The value of
the temperature drift varies slightly from part to part. Since the
reference is used for the ADCs in both Channel 1 and 2, any x%
drift in the reference will result in 2x% deviation of the meter
reading. The reference drift resulting from temperature changes
is usually very small and it is typically much smaller than the
drift of other components on a meter. However, if guaranteed
temperature performance is needed, one needs to use an exter-
nal voltage reference. Alternatively, the meter can be calibrated
at multiple temperatures. Real-time compensation can be achieved
easily using the on-chip temperature sensor.
CHANNEL 1 ADC
Figure 23 shows the ADC and signal processing chain for Chan-
nel 1. In waveform sampling mode the ADC outputs a signed
two’s complement 20-bit data word at a maximum of 27.9 kSPS
(CLKIN/128). The output of the ADC can be scaled by ± 50%
to perform an overall power calibration or to calibrate the ADC
output. While the ADC outputs a 20-bit two’s complement value,
the maximum full-scale positive value from the ADC is limited
to 40,000h (+262,144 decimal). The maximum full-scale negative
value is limited to C0000h (–262,144 decimal). If the analog
inputs are over-ranged, the ADC output code will clamp at these
values. With the specified full-scale analog input signal of 0.5 V
(or 0.25 V or 0.125 V—see Analog Inputs section) the ADC will
produce an output code that is approximately 63% of its full-scale
value. This is illustrated in Figure 23. The diagram in Figure 23
shows a full-scale voltage signal being applied to the differential
inputs V1P and V1N. The ADC output swings between D7AE1h
(–165,151) and 2851Fh (+165,151). This is approximately 63%
of the full-scale value 40,000h (262,144). Over-ranging the
analog inputs with more than 0.5 V differential (0.25 or 0.125,
depending on Channel 1 full-scale selection) will cause the ADC
output to increase towards its full-scale value. However, for speci-
fied operation the differential signal on the analog inputs should
not exceed the recommended value of 0.5 V.
REV. 0
–17–
Share Link: 