ACT8933
Rev 3, 15-Nov-12
FUNCTIONAL DESCRIPTION
I2C Interface
voltage
level
interrupt
is
unmasked
(nSYSLEVMSK[ ]=1) and VVSYS falls below the
programmable threshold, the ACT8933 asserts
nIRQ, providing a software “under-voltage alarm”.
The response to this interrupt is controlled by the
CPU, but will typically initiate a controlled shutdown
sequence either or alert the user that the battery is
low. In this case the interrupt is cleared when VVSYS
rises up again above the SYSLEV rising threshold
and nSYSSTAT[-] is read via I2C.
The ACT8933 features an I2C interface that allows
advanced programming capability to enhance overall
system performance. To ensure compatibility with a
wide range of system processors, the I2C interface
supports clock speeds of up to 400kHz (“Fast-Mode”
operation) and uses standard I2C commands. I2C
write-byte commands are used to program the
ACT8933, and I2C read-byte commands are used to
read the ACT8933’s internal registers. The ACT8933
always operates as a slave device, and is addressed
using a 7-bit slave address followed by an eighth bit,
which indicates whether the transaction is a read-
operation or a write-operation, [1011011x].
2) If nSYSMODE[-] = 0, when VVSYS falls below the
programmable threshold the ACT8933 shuts down,
immediately disabling all regulators. This option is
useful for implementing a programmable “under-
voltage lockout” function that forces the system off
when the battery voltage falls below the SYSLEV
threshold voltage. Since this option does not support
a controlled shutdown sequence, it is generally used
as a "fail-safe" to shut the system down when the
battery voltage is too low.
SDA is a bi-directional data line and SCL is a clock
input. The master device initiates a transaction by
issuing a START condition, defined by SDA
transitioning from high to low while SCL is high. Data
is transferred in 8-bit packets, beginning with the
MSB, and is clocked-in on the rising edge of SCL.
Each packet of data is followed by an “Acknowledge”
(ACK) bit, used to confirm that the data was
transmitted successfully.
Table 6:
SYSLEV Falling Threshold
SYSLEV Falling Threshold
SYSLEV[3:0]
For more information regarding the I2C 2-wire serial
interface, go to the NXP website: http://www.nxp.com.
(Hysteresis = 200mV)
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
2.3
2.4
2.5
2.6
2.7
2.8
2.9
3.0
3.1
3.2
3.3
3.4
3.5
3.6
3.7
3.8
Voltage Monitor and Interrupt
Programmable System Voltage Monitor
The ACT8933 features a programmable system-
voltage monitor, which monitors the voltage at VSYS
and compares it to a programmable threshold
voltage. The programmable voltage threshold is
programmed by SYSLEV[3:0], as shown in Table 6.
SYSLEV[ ] is set to 3.0V by default. There is a
200mV rising hysteresis on SYSLEV[ ] threshold
such that VVSYS needs to be 3.2V(typ) or higher in
order to power up the IC.
The nSYSSTAT[-] bit reflects the output of an
internal voltage comparator that monitors VVSYS
relative to the SYSLEV[-] voltage threshold, the
value of nSYSTAT[-] = 1 when VVSYS is lower than
the SYSLEV[-] voltage threshold, and nSYSTAT[-] =
0 when VVSYS is higher than the SYSLEV[-] voltage
threshold. Note that the SYSLEV[-] voltage threshold
is defined for falling voltages, and that the
comparator produces about 200mV of hysteresis at
VSYS. As a result, once VVSYS falls below the
SYSLEV threshold, its voltage must increase by
more than about 200mV to clear that condition.
Precision Voltage Detector
The LBI input connects to one input of a precision
voltage comparator, which can be used to monitor a
system voltage such as the battery voltage. An
external resistive-divider network can be used to set
voltage monitoring thresholds, as shown in
Functional Block Diagram. The output of the
comparator is present at the nLBO open-drain
output.
After the IC is powered up, the ACT8933 responds in
one of two ways when the voltage at VSYS falls
below the SYSLEV[-] voltage threshold:
1) If nSYSMODE[-] = 1 (default case), when system
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