TC7109ACPL Microchip Technology, TC7109ACPL Datasheet - Page 8

TC7109ACPL

Manufacturer Part Number

TC7109ACPL

Description

IC ADC 12BIT HANDSHAKE 40DIP

Manufacturer

Microchip Technology

Datasheet

1.TC7109CKW.pdf (30 pages)

Specifications of TC7109ACPL

Number Of Bits

Data Interface

Serial, Parallel

Number Of Converters

Voltage Supply Source

Dual ±

Operating Temperature

0°C ~ 70°C

Mounting Type

Through Hole

Package / Case

40-DIP (0.600", 15.24mm)

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Other names

158-1130
158-1130

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

TC7109ACPL

Manufacturer:

Microchi

Quantity:

5 000

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

TC7109ACPL

Manufacturer:

MICROCHIP

Quantity:

12 000

Company:

Meier Automation Equipment Co., Limited

Part Number:

TC7109ACPL

Manufacturer:

MICROCHIP/微芯

Quantity:

20 000

Current page: 8 of 30
Download datasheet (480Kb)

TC7109/A

3.0

(All Pin Designations Refer to 40-Pin DIP.)

3.1

The Typical Application diagram on page 3 shows a

block diagram of the analog section of the TC7109A.

The circuit will perform conversions at a rate deter-

mined by the clock frequency (8192 clock periods per

cycle), when the RUN/HOLD input is left open or

connected to V+. Each measurement cycle is divided

into four phases, as shown in Figure 3-1. They are:

(1) Auto-Zero (AZ), (2) Signal Integrate (INT), (3)

Reference De-integrate (DE), and (4) Zero Integrator

(ZI).

3.1.1

The buffer and the integrator inputs are disconnected

from input high and input low and connected to analog

common. The reference capacitor is charged to the ref-

erence voltage. A feedback loop is closed around the

system to charge the auto-zero capacitor, C

pensate for offset voltage in the buffer amplifier, inte-

grator, and comparator. Since the comparator is

included in the loop, the AZ accuracy is limited only by

the noise of the system. The offset referred to the input

is less than 10μV.

3.1.2

The buffer and integrator inputs are removed from com-

mon and connected to input high and input low. The

auto-zero loop is opened. The auto-zero capacitor is

placed in series in the loop to provide an equal and

opposite compensating offset voltage. The differential

voltage between input high and input low is integrated

for a fixed time of 2048 clock periods. At the end of this

phase, the polarity of the integrated signal is

determined. If the input signal has no return to the

converter’s power supply, input low can be tied to

analog common to establish the correct Common

mode voltage.

3.1.3

Input high is connected across the previously charged

reference capacitor and input low is internally

connected to analog common. Circuitry within the chip

ensures the capacitor will be connected with the correct

polarity to cause the integrator output to return to the

zero crossing (established by auto-zero), with a fixed

slope. The time, represented by the number of clock

periods counted for the output to return to zero, is

proportional to the input signal.

DS21456C-page 8

DETAILED DESCRIPTION

Analog Section

AUTO-ZERO PHASE

SIGNAL INTEGRATE PHASE

DE-INTEGRATE PHASE

, to com-

3.1.4

The ZI phase only occurs when an input over range

condition exists. The function of the ZI phase is to

eliminate residual charge on the integrator capacitor

after an over range 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 over range input on

one channel will not cause an error on the next channel

measured. This feature is especially useful in thermo-

couple measurements, where unused (or broken

thermocouple) inputs are pulled to the positive supply

rail.

During ZI, the reference capacitor is charged to the ref-

erence voltage. The signal inputs are disconnected

from the buffer and integrator. The comparator output is

connected to the buffer input, causing the integrator

output to be driven rapidly to 0V (Figure 3-1). The ZI

phase only occurs following an over range and lasts for

a maximum of 1024 clock periods.

3.1.5

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

maximizes the analog section’s performance.

A typical CMRR of 86dB is achieved for input differen-

tial voltages anywhere within the typical Common

mode range of 1V below the positive supply, to 1.5V

above the negative supply. However, for optimum per-

formance, 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 sat-

urate. A worst-case condition is near a full scale nega-

tive 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 volt-

age. 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.

ZERO INTEGRATOR PHASE

DIFFERENTIAL INPUT

TC7109ACPL Microchip Technology, TC7109ACPL Datasheet - Page 8

TC7109ACPL

Specifications of TC7109ACPL

Available stocks

Related parts for TC7109ACPL