PS810 查看數據表(PDF) - Microchip Technology
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PS810 Datasheet PDF : 46 Pages
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3.0 OPERATIONAL DESCRIPTION
3.1 A/D Operation
The PS810 A/D converter measures current, voltage
and temperature and integrates the current over time to
calculate State-Of-Charge. Cell voltage is measured
with a direct connection to the battery cell without
requiring an external voltage divider. Using an external
sense resistor, current is monitored during both charge
and discharge and is integrated over time using the on-
chip oscillator as the time base. Temperature is
measured from the on-chip temperature sensor or an
optional external thermistor. Voltage, current and
temperature can be calibrated for accuracy over the
operational range. The A/D converter performs
sampling using a 32 kHz clock.
3.1.1 CURRENT MEASUREMENT
The A/D input channels for current measurement are the
SR and GND pins. The voltage drop across the sense
resistor is measured and converted mathematically into
a current measurement. The current is also integrated
over time to get the amount of charge entering or leaving
the battery.
A sense resistor is connected to SR and GND. The
maximum input voltage that can be measured at SR is
+/-150 mV. The sense resistor should be properly sized
to accommodate the lowest and highest expected
charge and discharge currents, including suspend and/
or standby currents.
The parameter NullCurr represents the zero-zone
current of the battery. This is provided as a calibration
guardband for reading zero current. Currents below
+/- NullCurr (in mA) limit are read as zero and not
included in the capacity algorithm calculations. A
typical value for NullCurr is 3 mA, therefore, currents
between -3 mA and +3 mA will be reported as zero and
not included in the capacity calculations. This feature is
provided so that electrical noise on the battery module
current path is not interpreted as actual charge entering
or leaving the battery.
PS810
3.1.1.1
Sense Resistor Selection and
Current Measurement Range
The current resolution is based on the smallest amount
of voltage the A/D converter can measure across the
sense resistor. Since this measurement uses 13 bits
(plus sign) and the reference used is the internal
150 mV reference, the smallest voltage across the
sense resistor that can be measured is:
EQUATION 3-1:
150 mV/(2 ^ 13 – 1) = 150 mV/32767 = 18.3 μV
Thus, the smallest current that can be measured is:
18.3 μV/RSENSE (mΩ)
The largest current that can be measured is:
150 mV/RSENSE (mΩ)
Example: a 20 milliohm sense resistor will measure
from:
18.3 μV/20 mΩ = 0.915 mA
(though will be recorded as zero if < NullCurr)
up to:
150 mV/20 mΩ = 7.5 Amps
3.1.1.2 Current Calibration
In-circuit calibration of the current is done using the
communication interface (SMBus/I2C or SPS) at time
of manufacture to obtain optimal accuracy. A correction
is calculated and stored for both offset and slope.
COD is a constant that is measured at calibration time
and contains the offset due to external PCB
components.
CFCurr is the “Correction Factor for Current” which
compensates the A/D gain and any variances in the
actual sense resistance over varying currents. It is
multiplied against the raw A/D measurement.
COCurr is the “Correction Offset for Current” which is
updated in real time by the A/D shorting the inputs and
comparing any result to zero. This is added to COD and
compensates for any offset that varies over time, such
as temperature dependent offsets.
Figure 3-1 shows the relationship of the COCurr and
CFCurr values.
© 2006 Microchip Technology Inc.
DS21904C-page 7
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