TS7001
DESCRIPTION OF OPERATION
The TS7001 is
single/dual-channel,
a
single-supply, low-power,
12-bit successive-
analog input on one side and REF on the other, the
analog signal is acquired. During the acquisition
phase, the inputs to the comparator are balanced
since both inputs are connected to REF.
approximation ADC with an easy-to-use serial
interface. The ADC can be operated from a 3V
supply (2.7V to 3.6V). When operated from either a
3V, the TS7001 can operate at throughput rates up
to 187.5ksps when an external 3 MHz clock is
applied.
During the conversion phase as shown in the
equivalent circuit in Figure 2, Switch SW1 is moved
from Position A to GND at Position B and Switch
SW2 is opened. At this point in time, the inputs to
In a 8-pin MSOP package, the TS7001 integrates a
2.5-V reference,
a
high-speed track/hold,
a
successive-approximation ADC, and a serial digital
interface. An external serial clock is used to transfer
data to/from the ADC and controls the TS7001’s
conversion process. The TS7001 can be configured
for single- or two-channel operation. When
configured as a single-channel ADC, the analog
input range is 0 to VREF (where an externally
applied VREF, if used, can range between 1.2 V and
VDD). When the TS7001 is configured for two-
channel applications, the analog input range on
each channel is set internally from 0V to VDD.
Figure 2: TS7001’s Conversion Phase Equivalent Circuit
the comparator become unbalanced. The TS7001’s
control logic and the charge-redistribution DAC work
together to add or subtract fixed packets of charge
from the sampling capacitor to balance once again
the comparator input terminals. At the time when the
comparator is rebalanced, the conversion process is
complete and the ADC’s control logic generates the
ADC serial output conversion data.
If the TS7001 is configured for single-channel
operation, the TS7001 can be operated in a read-
only mode by applying a logic LOW at all times to
the DIN pin (Pin 6) or by hard-wiring the DIN pin
permanently to GND. For maximum flexibility to
address multiple configurations based on the
application, the DIN input can be used to load ADC
configuration data from a host processor into the
TS7001’s 8-bit Control Register.
Figure 3 illustrates the ideal transfer function for the
TS7001 where the output data is coded straight
binary. Thus, the designed code transitions occur at
successive integer LSB values (that is, at 1 LSB, at
2 LSBs, etc) where the LSB size is VREF/4096.
TS7001 Operation and Transfer Function
The TS7001 is a successive-approximation ADC,
the core of which is a charge-redistribution DAC.
Figure 1 illustrates an equivalent circuit for the
TS7001 in signal acquisition phase. Here, Switch
SW1 is in Position A and Switch SW2 is closed. With
the sampling capacitor’s terminals connected to the
Figure 1:TS7001’s Acquisition Phase Equivalent Circuit
Figure 3: TS7001’s Unipolar Transfer Function for
Straight Binary Digital Data.
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TS7001DS r1p0
RTFDS