Intersil ICL7129CM44 4â½ digit lcd, single-chip a/d converter Datasheet

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Features
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41/2 Digit LCD,
Single-Chip A/D Converter
Description
The Intersil ICL7129 is a very high performance 41/2-digit,
analog-to-digital converter that directly drives a multiplexed
liquid crystal display. This single chip CMOS integrated
circuit requires only a few passive components and a
reference to operate. It is ideal for high resolution hand-held
digital multimeter applications.
±19,999 Count A/ D Converter Accurate to ±4 Count
10µV Resolution on 200mV Scale
110dB CMRR
Direct LCD Display Drive
True Differential Input and Reference
Low Power Consumption
Decimal Point Drive Outputs
Overrange and Underrange Outputs
Low Battery Detection and Indication
10:1 Range Change Input
The performance of the ICL7129 has not been equaled
before in a single chip A/D converter. The successive integration technique used in the ICL7129 results in accuracy better
than 0.005% of full scale and resolution down to 10µV/count.
Ordering Information
PART NUMBER
TEMP.
RANGE ( oC)
ICL7129CPL
0 to 70
PACKAGE
The ICL7129, drawing only 1mA from a 9V battery, is well
suited for battery powered instruments. Provision has been
made for the detection and indication of a “LOW/BATTERY”
condition. Autoranging instruments can be made with the
ICL7129 which provides overrange and underrange outputs
and 10:1 range changing input. The ICL7129 instantly checks
for continuity, giving both a visual indication and a logic level
output which can enable an external audible transducer. These
features and the high performance of the ICL7129 make it an
extremely versatile and accurate instrument-on-a-chip.
PKG. NO.
40 Ld PDIP
E40.6
ICL7129RCPL
0 to 70
40 Ld PDIP
E40.6
ICL7129CM44
0 to 70
44 Ld MQFP
Q44.10x10
NOTE: “R” indicates device with reversed leads.
Pinouts
32 IN LO
B3 , C3 , MINUS 10
31 BUFF
A3 , G3 , D 3 11
30 CREF-
F3 , E3 , DP3 12
29 CREF+
B4 , C4 , BC 5 13
28 COMMON
27 CONTINUITY
26 INT OUT
BP3 16
25 INT IN
BP2 17
24 V+
BP1 18
23 V-
INT IN
INT OUT
CONTINUITY
CREF+
COMMON
BUFF
CREF-
IN LO
DP2
3
31
NC
DP1
4
30
OSC 2
5
29
OSC 1
6
28
NC
LATCH/
HOLD
DP3 /UR
OSC 3
7
27
DP4 /OR
NC
8
26
VDISP
NC
ANNUNCE
DRIVE
B1 , C1 , CONT
9
25
BP1
24
10
23
11
12 13 14 15 16 17 18 19 20 21 22
BP2
RANGE
1
V-
BP3
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
1-888-INTERSIL or 321-724-7143 | Intersil (and design) is a registered trademark of Intersil Americas Inc.
Copyright © Intersil Americas Inc. 2002. All Rights Reserved
1
F4 , E4 , DP4
A4 , D4 , G4
B4 , C4 , BC5
A3 , G3 , D3
21 DP3 / UR
F3 , E3 , DP3
22 LATCH/HOLD
B3 , C3 , MINUS
DP4 /OR 20
V+
DGND
34 REF HI
F2 , E2 , DP2 9
VDISP 19
44 43 42 41 40 39 38 37 36 35 34
33
2
32
35 REF LO
33 IN HI
F4 , E4 , DP4 15
IN HI
36 DGND
A2 , G2 , D 2 8
A4 , D4 , G4 14
REF LO
37 RANGE
F2 , E2 , DP2
B2 , C2 , LO BAT 7
38 DP2
A2 , G2 , D2
DISPLAY OUTPUT LINES
F1 , E1 , DP1 6
39 DP1
B2 , C2 , LO BAT
A1 , G1 , D 1 5
40 OSC2
A1 , G1 , D1
OSC3 2
ANNUNCIATOR 3
DRIVE
B1 , C 1 , CONT 4
F1 , E1 , DP1
OSC1 1
ICL7129 (MQFP)
TOP VIEW
REF HI
ICL7129 (PDIP)
TOP VIEW
File Number
3085.2
ICL7129
Functional Block Diagram
LOW BATTERY CONTINUITY
BACKPLANE
DRIVES
SEGMENT DRIVES
ANNUNCIATOR DRIVE
LATCH, DECODE DISPLAY MULTIPLEXER
VDISP
OSC1
OSC2
UP/DOWN RESULTS COUNTER
OSC3
SEQUENCE COUNTER/DECODER
CONTROL LOGIC
ANALOG SECTION
RANGE L/H
CONT
V+
V-
DGND
OR
DP3
UR
DP3
DP2
DP1
Typical Application Schematic
LOW BATTERY CONTINUITY
V+
5pF (MICA)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
120kHz
ICL7129
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
270K
560pF
10pF (MICA)
1.2kΩ
0.1µF
+
20K
1.0µF
0.1µF
150kΩ
+
10kΩ
9V
-
6.8µF
100kΩ
-
VIN
2
+
ICL8069
V+
ICL7129
Absolute Maximum Ratings
Thermal Information
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15V
Reference Voltage (REF HI or REF LO) . . . . . . . . . . . . . . . V+ to VInput Voltage (Note 1), IN HI or IN LO . . . . . . . . . . . . . . . . . V+ to VVDISP . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .DGND -0.3V to V+
Digital Input Pins
1, 2, 19, 20, 21, 22, 27, 37, 38, 39, 40 . . . . . . . . . . . . . DGND to V+
Thermal Resistance (Typical, Note 2)
θJA (oC/W)
PDIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
50
MQFP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
80
Maximum Junction Temperature. . . . . . . . . . . . . . . . . . . . . .150oC
Maximum Storage Temperature Range . . . . . . . . . . -65oC to 150oC
Maximum Lead Temperature (Soldering 10s). . . . . . . . . . . . . 300oC
(MQFP - Lead Tips Only)
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation
of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
NOTES:
1. Input voltages may exceed the supply voltages provided that input current is limited to 1400mA. Currents above this value may result in
valid display readings but will not destroy the device if limited to ±1mA.
2. θJA is measured with the component mounted on an evaluation PC board in free air.
Electrical Specifications
V- to V+ = 9V, V REF = 1.00V, TA = 25oC, fCLK = 120kHz, Unless Otherwise Specified
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
Zero Input Reading
VIN = 0V, 200mV Scale
-0000
0000
+0000
Counts
Zero Reading Drift
VIN = 0V, 0oC To 70oC
-
±0.5
-
µV/oC
Ratiometric Reading
VIN = VREF = 1000mV, RANGE = 2V
9996
9999
10000
Counts
Range Change Accuracy
VIN = 0.10000V on Low,
Range ≈ VIN = 1.0000V on High Range
0.9999
1.0000
1.0001
Ratio
Rollover Error
-VIN = +VIN = 199mV
-
1.5
3.0
Counts
Linearity Error
200mV Scale
-
1.0
-
Counts
Input Common-Mode Rejection Ratio
VCM = 1V,VIN = 0V, 200mV Scale
-
110
-
dB
Input Common-Mode Voltage Range
VIN = 0V, 200mV Scale
-
(V-) +1.5
(V+) -1.0
-
V
Noise (Peak-To-Peak Value not Exceeded 95% of
Time)
VIN = 0V 200mV Scale
-
14
-
µV
Input Leakage Current
VIN = 0V, Pin 32, 33
-
1
10
pA
Scale Factor Tempco
VIN = 199mV 0oC To 70oC
External VREF = 0ppm/oC
-
2
7
ppm/oC
COMMON Voltage
V+ to Pin 28
2.8
3.2
3.5
V
COMMON Sink Current
∆Common = + 0.1V
-
0.6
-
mA
COMMON Source Current
∆Common = -0.1V
DGND VoItage
V+ to Pin 36, V+ to V- = 9V
DGND Sink Current
-
10
-
µA
4.5
5.3
5.8
V
∆DGND = +0.5V
-
1.2
-
mA
Supply Voltage Range
V+ to V- (Note 3)
6
9
12
V
Supply Current Excluding COMMON Current
V+ to V- = 9V
-
1.0
1.5
mA
Clock Frequency
(Note 3)
-
120
360
kHz
VDISP Resistance
VDISP to V+
-
50
-
kΩ
Low Battery Flag Activation Voltage
V+ to V-
6.3
7.2
7.7
V
CONTINUITY Comparator Threshold Voltages
VOUT Pin 27 = HI
100
200
-
mV
VOUT Pin 27 = LO
-
200
400
mV
Pull-Down Current
Pins 37, 38, 39
-
2
10
µA
“Weak Output” Current Sink/Source
Pins 20, 21 Sink/Source
-
3/3
-
µA
Pin 27 Sink/Source
-
3/9
-
µA
Pin 22 Source Current
-
40
-
µA
Pin 22 Sink Current
-
3
-
µA
3
ICL7129
Electrical Specifications
V- to V+ = 9V, V REF = 1.00V, TA = 25oC, fCLK = 120kHz, Unless Otherwise Specified
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
NOTE:
3. Device functionality is guaranteed at the stated Min/Max limits. However, accuracy can degrade under these conditions.
Pin Descriptions
PIN
SYMBOL
1
OSC1
Input to first clock inverter.
2
OSC3
Output of second clock inverter.
3
ANNUNCIATOR
DRIVE
4
B1 , C1 , CONT
Output to display segments.
5
A1 , G1 , D 1
Output to display segments.
6
F1 , E1 , DP1
Output to display segments.
7
DESCRIPTION
DESCRIPTION
22
LATCH/HOLD
INPUT: When floating, A/D converter
operates in the free-run mode. When
pulled HI, the last displayed reading is
held. When pulled LO, the result
counter
contents
are
shown
incrementing during the de-integrate
phase of cycle.
OUTPUT: Negative going edge
occurs when the data latches are
updated. Can be used for converter
status signal.
B 2 , C 2 , LO BATT Output to display segments.
A2 , G2 , D 2
Output to display segments.
9
F2 , E2 , DP2
Output to display segments.
10
B3 , C3 , MINUS
Output to display segments.
11
A3 , G3 , D 3
Output to display segments.
12
F3 , E3 , DP3
Output to display segments.
13
B 4 , C 4 , BC5
Output to display segments.
14
A4 , D4 , G4
Output to display segments.
15
F4 , E4 , DP4
Output to display segments.
16
BP 3
Backplane #3 output to display.
17
BP 2
Backplane #2 output to display.
18
BP 1
Backplane #1 output to display.
19
VDlSP
Negative rail for display drivers.
20
DP4 /OR
23
V-
Negative power supply terminal.
24
V+
Positive power supply terminal, and
positive rail for display drivers.
25
INT IN
26
INT OUT
27
CONTINUITY
Input to integrator amplifier.
Output of integrator amplifier.
INPUT: When LO, continuity flag on
the display is off. When HI,
continuity flag is on.
OUTPUT: HI when voltage between
inputs is less than +200mV. LO
when voltage between inputs is
more than +200mV.
INPUT: When HI, turns on most
significant decimal point.
OUTPUT: Pulled HI when result
count exceeds ±19,999.
DP3 /UR
SYMBOL
Backplane squarewave output for
driving annunciators.
8
21
PIN
INPUT: Second most significant
decimal point on when HI.
OUTPUT: Pulled HI when result
count is less than ±1,000.
4
28
COMMON
Sets common-mode voltage of 3.2V
below V+ for DE, 10X, etc., Can be
used as pre-regulator for external
reference.
29
CREF+
Positive side of external reference
capacitor.
30
C REF-
Negative side of external reference
capacitor.
31
BUFFER
32
IN LO
Negative input voltage terminal.
33
IN HI
Positive input voltage terminal.
34
REF HI
Positive reference voltage input
terminal.
35
REF LO
Negative reference voltage input
terminal.
36
DGND
Ground reference for digital section.
Output of buffer amplifier.
ICL7129
PIN
SYMBOL
DESCRIPTION
PIN
SYMBOL
DESCRIPTION
37
RANGE
3µA pull-down for 200mV scale.
Pulled HIGH externally for 2V scale.
39
DP1
Internal 3µA pull-down. When HI,
decimal point 1 will be on.
38
DP2
Internal 3µA pull-down. When HI,
decimal point 2 will be on.
40
OSC2
Output of first clock inverter. Input of
second clock inverter.
CREF
REF HI
DE
RINT
REF LO
CINT
BUFFER
INT , IN
INT OUT
DE
X10
INT1
DE-
DE+
DE+
DE-
INT1 , INT2
INT
IN LO
+
Detailed Description
100
BUFFER
INTEGRATOR
Z1, X10
COMMON
COMPARATOR 1
+
+
IN HI
10
-
-
+
-
TO DIGITAL
SECTION
COMPARATOR 2
REST, INT2
FIGURE 1. ANALOG BLOCK DIAGRAM
ZERO-INTEGRATE
AND LATCH
INT1
INTEGRATE
DE1
DE-INTEGRATE REST X10
1000 CLOCKS
2000
CLOCKS
X10
DE3 ZERO-INTEGRATE
INTEGRATOR
RESIDUE
VOLTAGE
NOTE: Shaded area greatly expanded
in time and amplitude.
10,000 CLOCKS
DE2 REST
1000 CLOCKS
FIGURE 2. INTEGRATOR WAVEFORM FOR NEGATIVE INPUT VOLTAGE SHOWING SUCCESSIVE INTEGRATION PHASES AND
RESIDUE VOLTAGE
capability of the DGND pin. If more supply current is
required, the buffer in Figure 5 can be used to keep the loading on DGND to a minimum. COMMON can source approxi-
COMMON, DGND, and “Low Battery”
The COMMON and DGND (Digital GrouND) outputs of the
ICL7129 are generated from internal zener diodes
(Figure 3). COMMON is included primarily to set the common-mode voltage for battery operation or for any system
where the input signals float with respect to the power supplies. It also functions as a pre-regulator for an external precision reference voltage source. The voltage between
DGND and V+ is the supply voltage for the logic section of
the ICL7129 including the display multiplexer and drivers.
Both COMMON and DGND are capable of sinking current
from external loads, but caution should be taken to ensure
that these outputs are not overloaded. Figure 4 shows the
connection of external logic circuitry to the ICL7129. This
connection will work providing that the supply current
requirements of the logic do not exceed the current sink
5
ICL7129
not desired in an application it can easily be overridden by
connecting the pin to V+ (HI) or DGND (LO). This connection
will not damage the device because the output impedance of
these pins is quite high. A simplified schematic of these
input/output pins is shown in Figure 6. Since there is approximately 500kΩ in series with the output driver, the pin (when
used as an output) can only drive very light loads such as
4000 series, 74CXX type CMOS logic, or other high input
impedance devices. The output drive capability of these four
pins is limited to 3µA, nominally, and the input switching
threshold is typically DGND + 2V.
mately 12mA while DGND has no source capability.
24
V+
3.2V
-
N
+
5V
LOGIC
SECTION
“LOW
BATTERY”
28 COMMON
36
P
DGND
N
23
≈500kΩ
V-
DP4/OR PIN 20
DP3/UR PIN 21
LATCH/HOLD PIN 22
CONTINUITY PIN 27
FIGURE 3. BIASING STRUCTURE FOR COMMON AND DGND
V+
FIGURE 6. “WEAK OUTPUT”
24
LATCH/HOLD, Overrange, and Underrange Timing
EXTERNAL
LOGIC
36
The LATCH/HOLD output (pin 22) will be pulled low during
the last 100 clock cycles of each full conversion cycle. During this time the final data from the ICL7129 counter is
latched and transferred to the display decoder and multiplexer. The conversion cycle and LATCH/HOLD timing are
directly related to the clock frequency. A full conversion
cycle takes 30,000 clock cycles which is equivalent to
60,000 oscillator cycles. OverRange (OR pin 20) and UnderRange (UR pin 21) outputs are latched on the falling edge of
LATCH/HOLD and remain in that state until the end of the
next conversion cycle. In addition, digits 1 through 4 are
blanked during overrange. All three of these pins are “weak
outputs” and can be overridden with external drivers or pullup resistors to enable their input functions as described in
the Pin Description table.
ICL7129
DGND
ILOGIC
23
V-
FIGURE 4. DGND SINK CURRENT
V+
24
EXTERNAL
LOGIC
EXTERNAL
LOGIC
CURRENT
ICL7129
-
+
36
ICL7129
Instant Continuity
DGND
A comparator with a built-in 200mV offset is connected
directly between INPUT HI and INPUT LO of the ICL7129
(Figure 7). The CONTINUITY output (pin 27) will be pulled
high whenever the voltage between the analog inputs is less
than 200mV. This will also turn on the “CONTINUITY”
annunciator on the display. The CONTINUITY output may
be used to enable an external alarm or buzzer, thereby giv-
23
V-
FIGURE 5. BUFFERED DGND
The “LOW BATTERY” annunciator of the display is turned
on when the voltage between V+ and V- drops below 7.2V
typically. The exact point at which this occurs is determined
by the 6.3V zener diode and the threshold voltage of the
N-Channel transistor connected to the V- rail in Figure 3. As
the supply voltage decreases, the N-Channel transistor
connected to the V-rail eventually turns off and the “LOW
BATTERY” input to the logic section is pulled HIGH, turning
on the “LOW BATTERY” annunciator.
I/O Ports
Four pins of the ICL7129 can be used as either inputs or outputs. The specific pin numbers and functions are described
in the Pin Description table. If the output function of the pin is
6
ICL7129
display. This type of display has three backplanes and is driven
in a multiplexed format similar to the ICM7231 display driver
family. The specific display format is shown in Figure 8. Notice
that the polarity sign, decimal points, “LOW BATTERY”, and
“CONTINUITY” annunciators are directly driven by the
ICL7129. The individual segments and annunciators are
addressed in a manner similar to row-column addressing. Each
backplane (row) is connected to one-third of the total number of
segments. BP1 has all F, A, and B segments of the four least
significant digits. BP2 has all of the C, E, and G segments. BP3
has all D segments, decimal points, and annunciators. The
segment lines (columns) are connected in groups of three
bringing all segments of the display out on just 12 lines.
ing the ICL7129 an audible continuity checking capability.
-
+
IN HI
BUFFER
COMMON
IN LO
200mV
- V +
Annunciator Drive
500kΩ
-
+
A special display driver output is provided on the ICL7129
which is intended to drive various kinds of annunciators on
custom multiplexed liquid crystal displays. The ANNUNClATOR DRIVE output (pin 3) is a squarewave signal running at
the backplane frequency, approximately 100Hz. This signal
swings from VDISP to V+ and is in sync with the three backplane outputs BP1, BP2, and BP3. Figure 9 shows these
four outputs on the same time and voltage scales.
TO DISPLAY
DRIVER
(NOT LATCHED)
CONTINUITY
FIGURE 7. “INSTANT CONTINUITY” COMPARATOR AND
OUTPUT STRUCTURE
Since the CONTINUITY output is one of the four “weak outputs” of the ICL7129, the “continuity” annunciator on the display can be driven by an external source if desired. The
continuity function can be overridden with a pull-down resistor
connected between CONTINUITY pin and DGND (pin 36).
Any annunciator associated with any of the three backplanes
can be turned on simply by connecting it to the ANNUNClATOR DRIVE pin. To turn an annunciator off connect if to its
backplane. An example of a display and annunciator drive
scheme is shown in Figure 10.
Display Configuration
The ICL7129 is designed to drive a triplexed liquid crystal
LOW BATTERY CONTINUITY
f
a
f
a
b
f
g
c
e
e
a
b
f
g
c
e
d
a
b
f
g
c
e
d
b
g
c
e
d
c
BP1
BP2
BACKPLANE
CONNECTIONS
d
BP3
LOW BATTERY CONTINUITY
f
a
f
a
b
f
g
c
e
e
f
g
c
d
a
b
e
a
b
f
g
c
e
d
c
d
F4, E4, DP4
b
g
e
c
d
B1, C1, CONTINUITY
A4, G4, D4
A1, G1, D1
B4, C4, BC5
F1, E1, DP1
F3, E3, DP3
B2, C2, LOW BATTERY
A3, G3, D3
A2, G2, D2
B3, C3, MINUS
F2, E2, DP2
FIGURE 8. TRIPLEXED LIQUID CRYSTAL DISPLAY LAYOUT FOR ICL7129
7
ICL7129
compensation will depend upon the type of liquid crystal used.
Display manufacturers can supply the temperature compensation requirements for their displays. Figure 11 shows two
circuits that can be adjusted to give a temperature compensation of ≈ +10mV/ oC between V+ and VDISP . The diode
between DGND and VDISP should have a low turn-on voltage
to assure that no forward current is injected into the chip if
VDISP is more negative than DGND.
BP1
BP2
Component Selection
BP3
There are only three passive components around the
ICL7129 that need special consideration in selection. They
are the reference capacitor, integrator resistor, and integrator capacitor. There is no auto-zero capacitor like that found
in earlier integrating A/D converter designs.
ON SEG.
The integrating resistor is selected to be high enough to
assure good current Iinearity from the buffer amplifier and
integrator and low enough that PC board leakage is not a
problem. A value of 150kΩ should be optimum for most applications. The integrator capacitor is selected to give an optimum integrator swing at full-scale. A large integrator swing
will reduce the effect of noise sources in the comparator but
will affect rollover error if the swing gets too close to the positive rail (≈0.7V). This gives an optimum swing of ≈2.5V at fullscale. For a 150kΩ integrating resistor and 2 conversions per
second the value is 0.1µF. For different conversion rates, the
value will change in inverse proportion. A second requirement
for good linearity is that the capacitor have low dielectric
absorption. Polypropylene caps give good performance at a
reasonable price. Finally the foil side of the cap should be
connected to the integrator output to shield against pickup.
FIGURE 9. TYPICAL BACKPLANE AND ANNUNCIATOR
DRIVE WAVEFORM
ANNUNCIATOR
µ
m
K
M
LOW BATTERY CONTINUITY
BACKPLANE
ANNUNCIATOR
AMPS
VOLTS
Ω
BACKPLANE
FIGURE 10. MULTIMETER EXAMPLE SHOWING USE OF
ANNUNCIATOR DRIVE OUTPUT
The only requirement for the reference cap is that it be low
leakage. In order to reduce the effects of stray capacitance,
a 1µF value is recommended.
Display Temperature Compensation
Clock Oscillator
For most applications an adequate display can be obtained by
connecting VDlSP (pin 19) to DGND (pin 36). In applications
where a wide temperature range is encountered, the voltage
drive levels for some triplexed liquid crystal displays may need
to vary with temperature in order to maintain good display
contrast and viewing angle. The amount of temperature
The ICL7129 achieves its digital range changing by integrating the input signal for 1000 clock pulses (2,000 oscillator
cycles) on the 2V scale and 10,000 clock pulses on the
200mV scale. To achieve complete rejection of 60Hz on
both scales, an oscillator frequency of 120kHz is required,
giving two conversions per second.
V+
V+
1N4148
39K
39K
24
200K
-
5K
ICL7611
2N2222
20K
19
+
36
75K
24
19
VDISP
ICL7129
36
DGND
VDISP
ICL7129
DGND
18K
23
23
V-
V-
FIGURE 11. TWO METHODS FOR TEMPERATURE COMPENSATING THE LIQUID CRYSTAL DISPLAY
8
ICL7129
It is important to notice that in Figure 13, digital ground of the
ICL7129 (DGND pin 36) is not directly connected to power
supply ground. DGND is set internally to approximately 5V
less than the V+ terminal and is not intended to be used as a
power input pin. It may be used as the ground reference for
external logic, as shown in Figure 4 and 5. In Figure 4, DGND
is used as the negative supply rail for external logic provided
that the supply current for the external logic does not cause
excessive loading on DGND. The DGND output can be buffered as shown in Figure 5. Here, the logic supply current is
shunted away from the ICL7129 keeping the load on DGND
low. This treatment of the DGND output is necessary to insure
compatibility when the external logic is used to interface
directly with the logic inputs and outputs of the ICL7129.
In low resolution applications, where the converter uses only
31/2 digits and 100µV resolution, an R-C type oscillator is adequate. In this application a C of 51pF is recommended and the
resistor value selected from fOSC = 0.45/RC. However, when
the converter is used to its full potential (41/2 digits and 10µV
resolution) a crystal oscillator is recommended to prevent the
noise from increasing as the input signal is increased due to frequency jitter of the R-C oscillator. Both R-C and crystal oscillator circuits are shown in Figure 12.
ICL7129
1
40
2
75kΩ
When a battery voltage between 3.8V and 6V is desired for
operation, a voltage doubling circuit should be used to bring
the voltage on the ICL7129 up to a level within the power supply voltage range. This operating mode is shown in Figure 14.
51pF
ICL7129
1
40
2
27kΩ
5pF
10pF
120kHz
V-
V+
24
CRYSTAL MODE:
PARALLEL
RS < 50kΩ
CL < 12pF
CO < 5pF
V+
REF HI
REF LO
+
3.8V TO
6V
FIGURE 12. RC AND CRYSTAL OSCILLATOR CIRCUITS
-
Powering the ICL7129
36
8
IN HI
2
The ICL7129 may be operated as a battery powered hand-held
instrument or integrated into larger systems that have more
sophisticated power supplies. Figures 13, 14, and 15 show
various powering modes that may be used with the ICL7129.
3
+
4
ICL7660
10µF
5
IN LO
V-
24
0.1µF
36
COM
DGND
IN HI
0.1µF
IN LO
+
VIN
32
-
10µF
+5V
V+
REF LO
ICL7129
33
Again measurements are made with respect to COMMON
since the entire system is floating. Voltage doubling is
accomplished by using an ICL7660 CMOS voltage converter
and two inexpensive electrolytic capacitors. The same principle applies in Figure 15 where the ICL7129 is being used in
a system with only a single +5V power supply. Here measurements are made with respect to power supply ground.
+5V
0.1µF
28
FIGURE 14. POWERING THE ICL7129 FROM A 3.8V TO 6V BAT-
The power connection for systems with +5V and -5V supplies available is shown in Figure 13. Notice that measurements are with respect to ground. COMMON is also tied to
INLO to remove any common-mode voltage swing on the
integrator amplifier inputs.
REF HI
35
23
+
The standard supply connection using a 9V battery is shown
in the Typical Application Schematic.
ICL7129
DGND COM
34
24
34
V+
ICL8089
34
35
ICL8089
0.1µF
35
28
0.1µF
33
32
36
ICL7129
8
33
2
VIN
+
3
V-
ICL7660
4
10µF
5
23
28
32
V23
+
10µF
-5V
FIGURE 15. POWERING THE ICL7129 FROM A SINGLE
POLARITY POWER SUPPLY
FIGURE 13. POWERING THE ICL7129 FROM +5V AND -5V
9
+
VIN
-
ICL7129
A single polarity power supply can be used to power the
ICL7129 in applications where battery operation is not
appropriate or convenient only if the power supply is isolated
from system ground. Measurements must be made with
respect to COMMON or some other voltage within its input
common-mode range.
Integrate Resistor
RINT = VINFS/IINT
RINT (Typ) = 150kΩ
Integrate Capacitor
(t
)(I
)
INT INT
C INT = ---------------------------------V INT
Voltage References
Integrator Output Voltage Swing
The COMMON output of the ICL7129 has a temperature
coefficient of ±80ppm/ oC typically. This voltage is only suitable as a reference voltage for applications where ambient
temperature variations are expected to be minimal. When
the ICL7129 is used in most environments, other voltage references should be considered. The diagram in the Typical
Application Schematic and Figure 15 show the ICL8069
1.2V band-gap voltage source used as the reference for the
ICL7129, and the COMMON output as its pre-regulator. The
reference voltage for the ICL7129 is set to 1.000V for both
2V and 200mV full-scale operation.
V
INT
( tINT ) ( I INT )
= ---------------------------------C
INT
VINT Maximum Swing:
(V- + 0.5V) < VINT < (V+ - 0.7V)
Display Count
V IN
COUNT = 10, 000 × ----------------- ( Range = 1 )
V REF
(2V Range)
V × 10
IN
COUNT = 10, 000 × ----------------------- ( Range = 0 )
V
REF
(200mV Range)
Multiple Integration A/D Converter
Equations
Minimum VREF: 500mV
Oscillator Frequency
Common Mode Input Voltage
(V- + 1V) < VIN < (V+ - 0.5V)
fOSC = 0.45/RC
COSC > 50pF; ROSC > 50kΩ
fOSC (Typ) = 120kHz
or
fOSC = 120kHz Crystal (Recommended)
Auto Zero Capacitor: CAZ not used
Reference Capacitor: 0.1µF < C REF < 1µF
VCOM
Oscillator Period
Biased Between V+ and V-.
VCOM ≅ V+ -2.9V
Regulation lost when V+ to V- < ≅ 6.4V.
If VCOM is externally pulled down to (V+ to V-)/2, the
VCOM circuit will turn off.
tOSC = 1/ fOSC
Integration Clock Period
tCLOCK = 2*tOSC
Power Supply: Single 9V
Integration Period
tINT(2V) = 1000*tCLOCK
tINT(200mV) = 10,000*tCLOCK
V+ - V- = 9V
Digital supply is generated internally
VGND ≅ V+ - 4.5V
(Range = 1)
(Range = 0)
60/50Hz Rejection Criterion
Display: Triplexed LCD
tINT / t60Hz or tINT /t50Hz = Integer
Continuity Output On if
VINHI to VINLO < 200mV
Optimum Integration Current
IINT = 13µA
Conversion Cycle (In Both Ranges)
Full Scale Analog Input Voltage
tCYC = tCLOCK x 30,000
VINFS (Typ) = 200mV or 2V
ZERO-INTEGRATE
AND LATCH
INT1
INTEGRATE
DE1
DE-INTEGRATE REST X10
1000 CLOCKS
2000
CLOCKS
X10
INTEGRATOR
RESIDUE
VOLTAGE
NOTE: Shaded area greatly expanded
in time and amplitude.
10,000 CLOCKS
DE2 REST
1000 CLOCKS
10
DE3 ZERO-INTEGRATE