datasheetbank_Logo
Integrated circuits, Transistor, Semiconductors Search and Datasheet PDF Download Site

TC7109 View Datasheet(PDF) - TelCom Semiconductor Inc => Microchip

Part Name
Description
View to exact match
TC7109
TelCom-Semiconductor
TelCom Semiconductor Inc => Microchip TelCom-Semiconductor
TC7109 Datasheet PDF : 21 Pages
1 2 3 4 5 6 7 8 9 10 Next Last
12-BIT µP-COMPATIBLE
ANALOG-TO-DIGITAL CONVERTERS
TC7109
TC7109A
Zero-Integrator Phase
The ZI phase only occurs when an input overrange
condition exists. The function of the ZI phase is to eliminate
residual charge on the integrator capacitor after an overrange
measurement. Unless removed, the residual charge will be
transferred to the auto-zero capacitor and cause an error in
the succeeding conversion.
The ZI phase virtually eliminates hysteresis or "cross
talk" in multiplexed systems. An overrange input on one
channel will not cause an error on the next channel mea-
sured. This feature is especially useful in thermocouple
measurements, where unused (or broken thermocouple)
inputs are pulled to the positive supply rail.
During ZI, the reference capacitor is charged to the
reference voltage. The signal inputs are disconnected from
the buffer and integrator. The comparator output is con-
nected to the buffer input, causing the integrator output to be
driven rapidly to 0V (Figure 3). The ZI phase only occurs
following an overrange and lasts for a maximum of 1024
clock periods.
Differential Input
The TC7109A has been optimized for operation with
analog common near digital ground. With +5V and –5V
power supplies, a full ±4V full-scale integrator swing maxi-
mizes the analog section's performance.
A typical CMRR of 86 dB is achieved for input differential
voltages anywhere within the typical common-mode range
of 1V below the positive supply to 1.5V above the negative
supply. However, for optimum performance, the IN HI and IN
LO inputs should not come within 2V of either supply rail.
Since the integrator also swings with the common-mode
voltage, care must be exercised to ensure the integrator
output does not saturate. A worst-case condition is near a
full-scale negative differential input voltage with a large
positive common-mode voltage. The negative input signal
drives the integrator positive when most of its swing has
been used up by the positive common-mode voltage. In
such cases, the integrator swing can be reduced to less than
the recommended ±4V full-scale value, with some loss of
accuracy. The integrator output can swing to within 0.3V of
either supply without loss of linearity.
Differential Reference
The reference voltage can be generated anywhere
within the power supply voltage of the converter. Roll-over
voltage is the main source of common-mode error, caused
by the reference capacitor losing or gaining charge due to
stray capacity on its nodes. With a large common-mode
voltage, the reference capacitor can gain charge (increase
voltage) when called upon to deintegrate a positive signal
and lose charge (decrease voltage) when called upon
to deintegrate a negative input signal. This difference in
3-98
reference for (+) or (–) input voltages will cause a roll-over
error. This error can be held to less than 0.5 count worst case
by using a large reference capacitor in comparison to the
stray capacitance. To minimize roll-over error from these
sources, keep the reference common-mode voltage near or
at analog common.
Digital Section
The digital section is shown in the block diagram (Fig-
ure 4) and includes the clock oscillator and scaling circuit,
a 12-bit binary counter with output latches and TTL com-
patible three-state output drivers, UART handshake logic,
polarity, overrange, and control logic. Logic levels are re-
ferred to as LOW or HIGH.
Inputs driven from TTL gates should have 3 kto 5 k
pull-up resistors added for maximum noise immunity. For
minimum power consumption, all inputs should swing from
GND (LOW) to V+ (HIGH).
STATUS Output
During a conversion cycle, the STATUS output goes
HIGH at the beginning of signal integrate and goes LOW
one-half clock period after new data from the conversion has
been stored in the output latches (see Figure 3). The signal
may be used as a "data valid" flag to drive interrupts, or for
monitoring the status of the converter. (Data will not change
while status is LOW.)
MODE Input
The output mode of the converter is controlled by the
MODE input. The converter is in its "direct" output mode,
when the MODE input is LOW or left open. The output data
is directly accessible under the control of the chip and byte
enable inputs (this input is provided with a pull-down resistor
to ensure a LOW Level when the pin is left open). When the
MODE input is pulsed high, the converter enters the UART
handshake mode and outputs the data in 2 bytes, then
returns to "direct" mode. When the MODE input is kept
HIGH, the converter will output data in the handshake mode
at the end of every conversion cycle. With MODE = 0 (direct
bus transfer), the send input should be tied to V+. (See
"Handshake Mode.")
RUN/HOLD Input
With the RUN/HOLD input high, or open, the circuit
operates normally as a dual-slope ADC, as shown in Figure
3. Conversion cycles operate continuously with the output
latches updated after zero crossing in the deintegrate mode.
An internal pull-up resistor is provided to ensure a HIGH
level with an open input.
TELCOM SEMICONDUCTOR, INC.
 

Share Link: 

datasheetbank.com [ Privacy Policy ] [ Request Datasheet ] [ Contact Us ]