CS5461-IS 查看數據表(PDF) - Cirrus Logic
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CS5461-IS Datasheet PDF : 45 Pages
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CS5461
be set to a value much higher than the EOUT pulse
rate.
The FOUT pin outputs negative and positive ener-
gy, but has no energy direction indicator. The max-
imum FOUT pulse frequency is set by the value in
the PulseRateF Register.
5.4 Anti-Creep for the Pulse Outputs
Anti-Creep can be enabled/disabled for both
EOUT/EDIR and FOUT pulse output systems in
the Control Register. Anti-creep allows the elec-
tronic meter to maintain a “buffer” energy band,
defined by positive/negative energy threshold lev-
els, such that when the magnitude of the accumu-
lated energy is below this level, no energy pulses
are issued. The anti-creep feature is especially use-
ful when the meter demands that the energy pulse
outputs are set to relatively high frequency. A high-
er frequency pulse rate means that less energy reg-
istration is required to generate a pulse; and so it is
more likely that random noise present in the power
line and/or current-sense circuit can generate a
pulse that does not represent billable energy.
5.5 Design Examples
EXAMPLE #1: For a power line with maximum
rated levels of 250 V (RMS) and 20 A (RMS), the
pulse-frequency on the EOUT pin needs to be
‘IR’ = 100 pulses-per-second (100 Hz) when the
RMS-voltage and RMS-current levels on the power
line are 220 V and 15 A respectively. To meet this
requirement, the pulse-rate frequency (‘PR’) in the
Pulse-Rate Register must be set accordingly.
After calibration, the first step to finding the value
of ‘PR’ is to set the voltage and current sensor gain
constants, KV and KI, such that there will be accept-
able voltage levels on the CS5461 inputs when the
power line voltage and current levels are at the
maximum values of 250 V and 20 A. KV and KI are
needed to determine the appropriate ratios of the
voltage/current transformers and/or shunt resistor
values to use in the front-end voltage/current sen-
sor networks.
For a sinewave, the largest RMS value that can be
accurately measured (without over-driving the in-
puts) will register ~0.707 of the maximum DC in-
put level. Since power signals are often not
perfectly sinusoidal in real-world situations, and to
provide for some over-range capability, the RMS
Voltage Register and RMS Current Register is set
to measure 0.6 when the RMS-values of the
line-voltage and line-current levels are 250 V and
20 A. Therefore, when the RMS registers measure
0.6, the voltage level at the inputs will be
0.6 x 250 mV = 150 mV. The sensor gain con-
stants, KV and KI, are determined by demanding
that the voltage and current channel inputs should
be 150 mV RMS when the power line voltage and
current are at the maximum values of 250 V and
20 A.
KV = 150 mV / 250 V = 0.0006
KI = 150 mV / 20 A = 0.0075 Ω
These sensor gain constants are used to calculate
what the input voltage levels will be on the CS5461
inputs when the line-voltage and line-current are
220 V and 15 A. These values are VVnom and VIn-
om.
VVnom = KV * 220 V = 132 mV
VInom = KI * 15 A = 112.5 mV
The pulse rate on EOUT will be at ‘PR’ pulses per
second (Hz) when the RMS-levels of voltage/cur-
rent inputs are at 250 mV. When the voltage/cur-
rent inputs are set at VVnom and VInom, the pulse
rate needs to be ‘IR’ = 100 pulses per second. IR
will be some percentage of PR. The percentage is
defined by the ratios of VVnom/250 mV and
VInom/250 mV with the following formula:
PulseRate
=
IR
=
PR
⋅
--V----V---n---o---m----
250mV
⋅
--V-----I-n---o---m-----
250mV
DS546F2
25
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