ETC ICL7135CPL

ICL7135
TM
Data Sheet
December 2000
File Number
3093.2
4 1/2 Digit, BCD Output, A/D Converter
Features
The Intersil ICL7135 precision A/D converter, with its
multiplexed BCD output and digit drivers, combines dualslope conversion reliability with ±1 in 20,000 count accuracy
and is ideally suited for the visual display DVM/DPM market.
The 2.0000V full scale capability, auto-zero, and autopolarity are combined with true ratiometric operation, almost
ideal differential linearity and true differential input. All
necessary active devices are contained on a single CMOS
lC, with the exception of display drivers, reference, and a
clock.
• Accuracy Guaranteed to ±1 Count Over Entire ±20000
Counts (2.0000V Full Scale)
The ICL7135 brings together an unprecedented combination
of high accuracy, versatility, and true economy. It features
auto-zero to less than 10µV, zero drift of less than 1µV/oC,
input bias current of 10pA (Max), and rollover error of less
than one count. The versatility of multiplexed BCD outputs is
increased by the addition of several pins which allow it to
operate in more sophisticated systems. These include
STROBE, OVERRANGE, UNDERRANGE, RUN/HOLD and
BUSY lines, making it possible to interface the circuit to a
microprocessor or UART.
• Guaranteed Zero Reading for 0V Input
• 1pA Typical Input Leakage Current
• True Differential Input
• True Polarity at Zero Count for Precise Null Detection
• Single Reference Voltage Required
• Overrange and Underrange Signals Available for AutoRange Capability
• All Outputs TTL Compatible
• Blinking Outputs Gives Visual Indication of Overrange
• Six Auxiliary Inputs/Outputs are Available for Interfacing to
UARTs, Microprocessors, or Other Circuitry
• Multiplexed BCD Outputs
Ordering Information
PART NUMBER
ICL7135CPI
TEMP.
RANGE (oC)
0 to 70
PACKAGE
28 Ld PDIP
PKG.
NO.
E28.6
Pinout
ICL7135
(PDIP)
TOP VIEW
V- 1
REFERENCE 2
ANALOG COMMON 3
INT OUT 4
AZ IN 5
27 OVERRANGE
26 STROBE
25 R/H
24 DIGITAL GND
BUFF OUT 6
23 POL
REF CAP - 7
22 CLOCK IN
REF CAP + 8
21 BUSY
IN LO 9
20 (LSD) D1
IN HI 10
19 D2
V+ 11
18 D3
(MSD) D5 12
17 D4
(LSB) B1 13
16 (MSB) B8
B2 14
1
28 UNDERRANGE
15 B4
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 trademark of Intersil Corporation. | Copyright © Intersil Corporation 2000
ICL7135
Typical Application Schematic
SET VREF = 1.000V
-5V
VREF IN
100kΩ
ANALOG
GND
0.47µF
100kΩ
27Ω
1µF
100kΩ
28
2
27
3
26
4
25
5
24
6
23
22
7
1µF
SIGNAL
INPUT
1
8
100K
0.1µF
+5V
2
ICL7135
CLOCK IN
120kHz
0V
ANODE
DRIVER
TRANSISTORS
6
21
9
20
10
19
11
18
12
17
13
16
14
15
SEVEN
SEG.
DECODE
DISPLAY
ICL7135
Absolute Maximum Ratings
Thermal Information
Thermal Resistance (Typical, Note 2) . . . . . . . . . . . . . θJA (oC/W)
PDIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
55
Maximum Junction Temperature . . . . . . . . . . . . . . . . . . . . . . .150oC
Maximum Storage Temperature Range . . . . . . . . . . -65oC to 150oC
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . .300oC
Supply Voltage V+ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +6V
V- . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -9V
Analog Input Voltage (Either Input) (Note 1) . . . . . . . . . . . . V+ to VReference Input Voltage (Either Input). . . . . . . . . . . . . . . . . V+ to VClock Input Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . GND to V+
Operating Conditions
Temperature Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0oC to 70oC
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 the input current is limited to +100µA.
2. θJA is measured with the component mounted on a low effective thermal conductivity test board in free air. See Tech Brief TB379 for details.
V+ = +5V, V- = -5V, TA = 25oC, fCLK Set for 3 Readings/s, Unless Otherwise Specified
Electrical Specifications
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
UNITS
-00000
+00000
+00000
Counts
ANALOG (Notes 3, 4)
Zero Input Reading
VlN = 0V, VREF = 1.000V
Ratiometric Error (Note 4)
VlN = VREF = 1.000V
-3
0
+3
Counts
Linearity Over ± Full Scale (Error of Reading from Best Straight Line)
-2V ≤ VIN ≤ +2V
-
0.5
1
LSB
Differential Linearity (Difference Between Worse Case Step of
Adjacent Counts and Ideal Step)
-2V ≤ VIN ≤ +2V
-
0.01
-
LSB
Rollover Error (Difference in Reading for Equal Positive and
Negative Voltage Near Full Scale)
-VlN ≡ +VlN ≈ 2V
-
0.5
1
LSB
Noise (Peak-to-Peak Value Not Exceeded 95% of Time), eN
VlN = 0V, Full scale = 2.000V
-
15
-
µV
Input Leakage Current, IILK
VlN = 0V
-
1
10
pA
Zero Reading Drift (Note 7)
VlN = 0V, 0oC to 70oC
-
0.5
2
µV/oC
Scale Factor Temperature Coefficient, TC (Notes 5 and 7)
VlN = +2V, 0oC to 70oC
Ext. Ref. 0ppm/oC
-
2
5
ppm/oC
V
DIGITAL INPUTS
Clock In, Run/Hold (See Figure 2)
VINH
2.8
2.2
-
VINL
-
1.6
0.8
V
IINL
VIN = 0V
-
0.02
0.1
mA
IINH
VIN = +5V
-
0.1
10
µA
DIGITAL OUTPUTS
All Outputs, VOL
IOL = 1.6mA
-
0.25
0.40
V
B1, B2, B4, B8, D1, D2, D3, D4, D5, VOH
IOH = -1mA
2.4
4.2
-
V
BUSY, STROBE, OVERRANGE, UNDERRANGE, POLARITY, VOH
IOH = -10µA
4.9
4.99
-
V
+4
+5
+6
V
SUPPLY
+5V Supply Range, V+
-5V Supply Range, V-
-3
-5
-8
V
-
1.1
3.0
mA
fC = 0
-
0.8
3.0
mA
vs Clock Frequency
-
40
-
pF
DC
2000
1200
kHz
+5V Supply Current, I+
fC = 0
-5V Supply Current, IPower Dissipation Capacitance, CPD
CLOCK
Clock Frequency (Note 6)
NOTES:
3. Tested in 41/2 digit (20.000 count) circuit shown in Figure 3. (Clock frequency 120kHz.)
4. Tested with a low dielectric absorption integrating capacitor, the 27Ω INT OUT resistor shorted, and RlNT = 0. See Component Value Selection
Discussion.
5. The temperature range can be extended to 70oC and beyond as long as the auto-zero and reference capacitors are increased to absorb the
higher leakage of the ICL7135.
6. This specification relates to the clock frequency range over which the lCL7135 will correctly perform its various functions See “Max Clock
Frequency” section for limitations on the clock frequency range in a system.
7. Parameter guaranteed by design or characterization. Not production tested.
3
ICL7135
SET VREF = 1.000V
ICL7135
VREF IN
1 V-
-5V
UNDERRANGE 28
OVERRANGE 27
2 REF
100kΩ
3 ANALOG GND STROBE 26
ANALOG
GND
100kΩ
RUN/HOLD 25
4 INT OUT
0.47µF
27Ω
DIGITAL GND 24
5 A-Z IN
1µF
6 BUF OUT
100kΩ
1µF
BUSY 21
8 REF CAP 2
0.1µF
+5V
9 IN LO-
LSD DI 20
10 IN HI+
D2 19
11 V+
D3 18
12 MSD D5
D4 17
13 LSB B1
MSB B8 16
V+
CLOCK
IN
120kHz
7 REF CAP 1 CLOCK IN 22
100K
SIGNAL
INPUT
0V
POLARITY 23
PAD
B4 15
14 B2
DIG GND
FIGURE 1. ICL7135 TEST CIRCUIT
FIGURE 2. ICL7135 DIGITAL LOGIC INPUT
CREF
CREF+
8
CAZ
RINT
REF HI
CREF
2
7
BUFFER
6
V+
11
CINT
INT
AUTO
ZERO
5
4
INTEGRATOR
-
+
AZ
IN HI
-
+
INPUT
HIGH
ZEROCROSSING
DETECTOR
AZ
10
INT
DE(-)
COMPARATOR
DE(+)
ZI
A/Z
AZ
INPUT
LOW
3
DE(+)
ANALOG
COMMON
IN LO
+
9
DE(-)
A/Z, DE(±), ZI
INT
1
V-
FIGURE 3. ANALOG SECTION OF ICL7135
4
POLARITY
F/F
ICL7135
Detailed Description
Analog Section
Figure 3 shows the Block Diagram of the Analog Section for
the ICL7135. Each measurement cycle is divided into four
phases. They are (1) auto-zero (AZ), (2) signal-integrate
(INT), (3) de-integrate (DE) and (4) zero-integrator (Zl).
Auto-Zero Phase
During auto-zero, three things happen. First, input high and low
are disconnected from the pins and internally shorted to analog
COMMON. Second, the reference capacitor is charged to the
reference voltage. Third, a feedback loop is closed around the
system to charge the auto-zero capacitor CAZ to compensate
for offset voltages in the buffer amplifier, integrator, and
comparator. Since the comparator is included in the loop, the
AZ accuracy is limited only by the noise of the system. In any
case, the offset referred to the input is less than 10µV.
Signal Integrate Phase
During signal integrate, the auto-zero loop is opened, the
internal short is removed, and the internal input high and low
are connected to the external pins. The converter then
integrates the differential voltage between IN HI and IN LO for a
fixed time. This differential voltage can be within a wide
common mode range; within one volt of either supply. If, on the
other hand, the input signal has no return with respect to the
converter power supply, IN LO can be tied to analog COMMON
to establish the correct common-mode voltage. At the end of
this phase, the polarity of the integrated signal is latched into
the polarity F/F.
However, since the integrator also swings with the common
mode voltage, care must be exercised to assure the integrator
output does not saturate. A worst case condition would be a
large positive common-mode voltage with a near full scale
negative differential input voltage. The negative input signal
drives the integrator positive when most of its swing has been
used up by the positive common mode voltage. For these
critical applications the integrator swing can be reduced to
less than the recommended 4V full scale swing with some
loss of accuracy. The integrator output can swing within 0.3V
of either supply without loss of linearity.
Analog COMMON
Analog COMMON is used as the input low return during autozero and de-integrate. If IN LO is different from analog
COMMON, a common mode voltage exists in the system and
is taken care of by the excellent CMRR of the converter.
However, in most applications IN LO will be set at a fixed
known voltage (power supply common for instance). In this
application, analog COMMON should be tied to the same
point, thus removing the common mode voltage from the
converter. The reference voltage is referenced to analog
COMMON.
Reference
The reference input must be generated as a positive voltage
with respect to COMMON, as shown in Figure 4.
V+
De-Integrate Phase
6.8V
ZENER
REF HI
The third phase is de-integrate or reference integrate. Input
low is internally connected to analog COMMON and input
high is connected across the previously charged reference
capacitor. Circuitry within the chip ensures that the capacitor
will be connected with the correct polarity to cause the integrator output to return to zero. The time required for the output to return to zero is proportional to the input signal.
Specifically the digital reading displayed is:
ICL7135
IZ
COMMON
V-
FIGURE 4A.
 V IN 
OUTPUT COUNT = 10,000  --------------- .
 V REF
V+
Zero Integrator Phase
The final phase is zero integrator. First, input low is shorted
to analog COMMON. Second, a feedback loop is closed
around the system to input high to cause the integrator
output to return to zero. Under normal condition, this phase
lasts from 100 to 200 clock pulses, but after an overrange
conversion, it is extended to 6200 clock pulses.
Differential Input
6.8kΩ
V+
REF HI
20kΩ
ICL7135
ICL8069
1.2V
REFERENCE
COMMON
The input can accept differential voltages anywhere within the
common mode range of the input amplifier; or specifically
from 0.5V below the positive supply to 1V above the negative
supply. In this range the system has a CMRR of 86dB typical.
5
FIGURE 4B.
FIGURE 4. USING AN EXTERNAL REFERENCE
ICL7135
previous signal was overrange) but no additional STROBE
pulses will be sent until a new measurement is available.
Digital Section
Figure 5 shows the Digital Section of the ICL7135. The
ICL7135 includes several pins which allow it to operate
conveniently in more sophisticated systems. These include:
BUSY (Pin 21)
BUSY goes high at the beginning of signal integrate and
stays high until the first clock pulse after zero crossing (or
after end of measurement in the case of an overrange). The
internal latches are enabled (i.e., loaded) during the first
clock pulse after busy and are latched at the end of this clock
pulse. The circuit automatically reverts to auto-zero when
not BUSY, so it may also be considered a (Zl + AZ) signal. A
very simple means for transmitting the data down a single
wire pair from a remote location would be to AND BUSY with
clock and subtract 10,001 counts from the number of pulses
received - as mentioned previously there is one “NO-count”
pulse in each reference integrate cycle.
Run/HOLD (Pin 25)
When high (or open) the A/D will free-run with equally
spaced measurement cycles every 40,002 clock pulses. If
taken low, the converter will continue the full measurement
cycle that it is doing and then hold this reading as long as
R/H is held low. A short positive pulse (greater than 300ns)
will now initiate a new measurement cycle, beginning with
between 1 and 10,001 counts of auto zero. If the pulse
occurs before the full measurement cycle (40,002 counts) is
completed, it will not be recognized and the converter will
simply complete the measurement it is doing. An external
indication that a full measurement cycle has been completed
is that the first strobe pulse (see below) will occur 101 counts
after the end of this cycle. Thus, if Run/HOLD is low and has
been low for at least 101 counts, the converter is holding and
ready to start a new measurement when pulsed high.
OVERRANGE (Pin 27)
This pin goes positive when the input signal exceeds the
range (20,000) of the converter. The output F/F is set at the
end of BUSY and is reset to zero at the beginning of
reference integrate in the next measurement cycle.
STROBE (Pin 26)
UNDERRANGE (Pin 28)
This is a negative going output pulse that aids in transferring
the BCD data to external latches, UARTs, or
microprocessors. There are 5 negative going STROBE
pulses that occur in the center of each of the digit drive
pulses and occur once and only once for each measurement
cycle starting 101 clock pulses after the end of the full
measurement cycle. Digit 5 (MSD) goes high at the end of
the measurement cycle and stays on for 201 counts. In the
center of this digit pulse (to avoid race conditions between
changing BCD and digit drives) the first STROBE pulse goes
negative for 1/2 clock pulse width. Similarly, after digit 5, digit
4 goes high (for 200 clock pulses) and 100 pulses later the
STROBE goes negative for the second time. This continues
through digit 1 (LSD) when the fifth and last STROBE pulse
is sent. The digit drive will continue to scan (unless the
V + POLARITY
POLARlTY (Pin 23)
This pin is positive for a positive input signal. It is valid even
for a zero reading. In other words, +0000 means the signal is
positive but less than the least significant bit. The converter
can be used as a null detector by forcing equal frequency of
(+) and (-) readings. The null at this point should be less than
0.1 LSB. This output becomes valid at the beginning of
reference integrate and remains correct until it is revalidated
for the next measurement.
D4
D5
23
11
This pin goes positive when the reading is 9% of range or
less. The output F/F is set at the end of BUSY (if the new
reading is 1800 or less) and is reset at the beginning of
signal integrate of the next reading.
12
17
D3
D2
18
19
MULTIPLEXER
POLARITY
FF
LATCH
LATCH
LATCH
ZERO
CROSS.
DET.
20
13
LSB 14
15
16
MSB
ANALOG
SECTION
D1
LATCH
LATCH
COUNTERS
CONTROL LOGIC
24
DIGITAL
GND
22
CLOCK
IN
25
RUN/
HOLD
27
28
26
OVER UNDER STROBE BUSY
RANGE RANGE
FIGURE 5. DIGITAL SECTION OF THE ICL7135
6
21
B1
B2
B4
B8
ICL7135
Digit Drives (Pins 12, 17, 18, 19 and 20)
Auto-Zero and Reference Capacitor
Each digit drive is a positive going signal that lasts for 200 clock
pulses. The scan sequence is D5 (MSD), D4, D3, D2, and D1
(LSD). All five digits are scanned and this scan is continuous
unless an overrange occurs. Then all digit drives are blanked
from the end of the strobe sequence until the beginning of
Reference Integrate when D5 will start the scan again. This can
give a blinking display as a visual indication of overrange.
The physical size of the auto-zero capacitor has an influence
on the noise of the system. A larger capacitor value reduces
system noise. A larger physical size increases system noise.
The reference capacitor should be large enough such that
stray capacitance to ground from its nodes is negligible.
BCD (Pins 13, 14, 15 and 16)
The Binary coded Decimal bits B8, B4, B2, and B1 are
positive logic signals that go on simultaneously with the digit
driver signal.
Component Value Selection
The dielectric absorption of the reference cap and auto-zero
cap are only important at power-on or when the circuit is
recovering from an overload. Thus, smaller or cheaper caps
can be used here if accurate readings are not required for
the first few seconds of recovery.
Reference Voltage
The analog input required to generate a full scale output is
VlN = 2VREF.
For optimum performance of the analog section, care must
be taken in the selection of values for the integrator capacitor
and resistor, auto-zero capacitor, reference voltage, and
conversion rate. These values must be chosen to suit the
particular application.
The stability of the reference voltage is a major factor in the
overall absolute accuracy of the converter. For this reason, it
is recommended that a high quality reference be used where
high-accuracy absolute measurements are being made.
Integrating Resistor
Rollover Resistor and Diode
The integrating resistor is determined by the full scale input
voltage and the output current of the buffer used to charge
the integrator capacitor. Both the buffer amplifier and the
integrator have a class A output stage with 100µA of
quiescent current. They can supply 20µA of drive current
with negligible non-linearity. Values of 5µA to 40µA give
good results, with a nominal of 20µA, and the exact value of
integrating resistor may be chosen by:
A small rollover error occurs in the ICL7135, but this can be
easily corrected by adding a diode and resistor in series
between the INTegrator OUTput and analog COMMON or
ground. The value shown in the schematics is optimum for
the recommended conditions, but if integrator swing or clock
frequency is modified, adjustment may be needed. The
diode can be any silicon diode such as 1N914. These
components can be eliminated if rollover error is not
important and may be altered in value to correct other
(small) sources of rollover as needed.
full scale voltage
R INT = -------------------------------------------- .
20µA
Max Clock Frequency
Integrating Capacitor
The product of integrating resistor and capacitor should be
selected to give the maximum voltage swing which ensures
that the tolerance built-up will not saturate the integrator
swing (approx. 0.3V from either supply). For ±5V supplies
and analog COMMON tied to supply ground, a ±3.5V to ±4V
full scale integrator swing is fine, and 0.47µF is nominal. In
general, the value of ClNT is given by:
 10,000 × clock period × I INT ,
C INT =  ----------------------------------------------------------------------------------
 integrator output voltage swing 
(10,000) (clock period) (20µA)
= --------------------------------------------------------------------------------- .
integrator output voltage swing
A very important characteristic of the integrating capacitor is
that it has low dielectric absorption to prevent roll-over or
ratiometric errors. A good test for dielectric absorption is to
use the capacitor with the input tied to the reference.
This ratiometric condition should read half scale 0.9999, and
any deviation is probably due to dielectric absorption.
Polypropylene capacitors give undetectable errors at
reasonable cost. Polystyrene and polycarbonate capacitors
may also be used in less critical applications.
7
The maximum conversion rate of most dual-slope A/D
converters is limited by the frequency response of the
comparator. The comparator in this circuit follows the
integrator ramp with a 3µs delay, and at a clock frequency of
160kHz (6µs period) half of the first reference integrate clock
period is lost in delay. This means that the meter reading will
change from 0 to 1 with a 50µV input, 1 to 2 with a 150µV
input, 2 to 3 with a 250µV input, etc. This transition at midpoint is considered desirable by most users; however, if the
clock frequency is increased appreciably above 160kHz, the
instrument will flash “1” on noise peaks even when the input
is shorted.
For many dedicated applications where the input signal is
always of one polarity, the delay of the comparator need not
be a limitation. Since the non-linearity and noise do not
increase substantially with frequency, clock rates of up to
~1MHz may be used. For a fixed clock frequency, the extra
count or counts caused by comparator delay will be constant
and can be subtracted out digitally.
The clock frequency may be extended above 160kHz
without this error, however, by using a low value resistor in
ICL7135
series with the integrating capacitor. The effect of the
resistor is to introduce a small pedestal voltage on to the
integrator output at the beginning of the reference integrate
phase. By careful selection of the ratio between this resistor
and the integrating resistor (a few tens of ohms in the
recommended circuit), the comparator delay can be
compensated and the maximum clock frequency extended
by approximately a factor of 3. At higher frequencies, ringing
and second order breaks will cause significant nonlinearities in the first few counts of the instrument. See
Application Note AN017.
The minimum clock frequency is established by leakage on
the auto-zero and reference caps. With most devices,
measurement cycles as long as 10s give no measurable
leakage error.
To achieve maximum rejection of 60Hz pickup, the signal
integrate cycle should be a multiple of 60Hz. Oscillator
frequencies of 300kHz, 200kHz, 150kHz, 120kHz, 100kHz,
40kHz, 331/3kHz, etc. should be selected. For 50Hz
rejection, oscillator frequencies of 250kHz, 1662/3kHz,
125kHz, 100kHz, etc. would be suitable. Note that 100kHz
(2.5 readings/sec) will reject both 50Hz and 60Hz.
The clock used should be free from significant phase or
frequency jitter. Several suitable low-cost oscillators are
shown in the Typical Applications section. The multiplexed
output means that if the display takes significant current from
the logic supply, the clock should have good PSRR.
Zero-Crossing Flip-Flop
The flip-flop interrogates the data once every clock pulse
after the transients of the previous clock pulse and half-clock
pulse have died down. False zero-crossings caused by clock
pulses are not recognized. Of course, the flip-flop delays the
true zero-crossing by up to one count in every instance, and
if a correction were not made, the display would always be
one count too high. Therefore, the counter is disabled for
one clock pulse at the beginning of phase 3. This one-count
delay compensates for the delay of the zero-crossing
flip-flop, and allows the correct number to be latched into the
display. Similarly, a one-count delay at the beginning of
phase 1 gives an overload display of 0000 instead of 0001.
No delay occurs during phase 2, so that true ratiometric
readings result.
Evaluating The Error Sources
Errors from the “ideal” cycle are caused by:
1. Capacitor droop due to leakage.
INTEGRATOR
OUTPUT
2. Capacitor voltage change due to charge “suck-out” (the
reverse of charge injection) when the switches turn off.
AUTO SIGNAL REFERENCE
ZERO
INT.
INTEGRATE
10,001/ 10,000/
20,001/
COUNTS COUNTS COUNTS MAX.
FULL MEASUREMENT
CYCLE 40,002 COUNTS
3. Non-linearity of buffer and integrator.
4. High-frequency limitations of buffer, integrator, and
comparator.
BUSY
5. Integrating capacitor non-linearity (dielectric absorption).
OVER-RANGE
WHEN APPLICABLE
6. Charge lost by CREF in charging CSTRAY.
7. Charge lost by CAZ and ClNT to charge CSTRAY.
UNDER-RANGE
WHEN APPLICABLE
DIGIT SCAN
FOR OVER-RANGE
Each error is analyzed for its error contribution to the
converter in application notes listed on the back page,
specifically Application Note AN017 and Application Note
AN032.
EXPANDED SCALE
BELOW
D5
D4
D3
D2
D1
†FIRST D5 OF AZ AND
REF INT ONE COUNT LONGER
1000†/
COUNTS
STROBE
DIGIT SCAN
FOR OVER-RANGE
AUTO ZERO
SIGNAL INTEGRATE
D5
REFERENCE
INTEGRATE
D4
Noise
The peak-to-peak noise around zero is approximately 15µV
(peak-to-peak value not exceeded 95% of the time). Near full
scale, this value increases to approximately 30µV. Much of
the noise originates in the auto-zero loop, and is proportional
to the ratio of the input signal to the reference.
Analog And Digital Grounds
D3
Extreme care must be taken to avoid ground loops in the
layout of ICL7135 circuits, especially in high-sensitivity
circuits. It is most important that return currents from digital
loads are not fed into the analog ground line.
D2
D1
FIGURE 6. TIMING DIAGRAM FOR OUTPUTS
8
ICL7135
Power Supplies
decoder. The 2-gate clock circuit should use CMOS gates to
maintain good power supply rejection.
The ICL7135 is designed to work from ±5V supplies.
However, in selected applications no negative supply is
required. The conditions to use a single +5V supply are:
A suitable circuit for driving a plasma-type display is shown
in Figure 8. The high voltage anode driver buffer is made by
Dionics. The 3 AND gates and caps driving “BI” are needed
for interdigit blanking of multiple-digit display elements, and
can be omitted if not needed. The 2.5kΩ and 3kΩ resistors
set the current levels in the display. A similar arrangement
can be used with Nixie® tubes.
1. The input signal can be referenced to the center of the
common mode range of the converter.
2. The signal is less than ±1.5V.
See “differential input” for a discussion of the effects this will
have on the integrator swing without loss of linearity.
The popular LCD displays can be interfaced to the outputs of
the ICL7135 with suitable display drivers, such as the
ICM7211A as shown in Figure 9. A standard CMOS 4030
QUAD XOR gate is used for displaying the 1/2 digit, the
polarity, and an “overrange” flag. A similar circuit can be
used with the ICL7212A LED driver and the ICM7235A
vacuum fluorescent driver with appropriate arrangements
made for the “extra” outputs. Of course, another full driver
circuit could be ganged to the one shown if required. This
would be useful if additional annunciators were needed. The
Figure shows the complete circuit for a 41/2 digit (±2.000V)
A/D.
Typical Applications
The circuits which follow show some of the wide variety of
possibilities and serve to illustrate the exceptional versatility
of this A/D converter.
Figure 7 shows the complete circuit for a 41/2 digit (±2.000V)
full scale) A/D with LED readout using the ICL8069 as a
1.2V temperature compensated voltage reference. It uses
the band-gap principal to achieve excellent stability and low
noise at reverse currents down to 50µA. The circuit also
shows a typical R-C input filter. Depending on the
application, the time-constant of this filter can be made
faster, slower, or the filter deleted completely. The 1/2 digit
LED is driven from the 7 segment decoder, with a zero
reading blanked by connecting a D5 signal to RBl input of the
Figure 10 shows a more complicated circuit for driving LCD
displays. Here the data is latched into the ICM7211 by the
STROBE signal and “Overrange” is indicated by blanking the
4 full digits.
+5V
VREF =
1.000V
5
1 V-
1
(NOTE 1)
ICL7135
2 REF
2
10kΩ
ANALOG
3 COMMON
27Ω
ANALOG
4 INT OUT
GND
0.47µF
5 AZIN
100kΩ
1µF
6 BUF OUT
100kΩ
7 RC1
1µF
100K
SIGNAL
8 RC2
INPUT
9 INPUT LO
0.1µF
10 INPUT HI
+5V
UR 28
4
3
1
150Ω
OR 27
7447
150Ω
150Ω
STROBE 26
R/H 25
2
A
B
C
D
E
F
G
4.7K
DIG. GND 24
POL 23
CLOCK 22
B1
B2
B4
B8
RBI
BUSY 21
D1 20
47K
D2 19
11 V+
D3 18
12 D5
D4 17
13 B1
B8 16
14 B2
B4 15
C
RC NETWORK
R
NOTE:
1. For finer resolution on scale factor adjust, use a 10 turn pot or a small pot in series with
a fixed resistor.
FIGURE 7. 41/2 DIGIT A/D CONVERTER WITH A MULTIPLEXED COMMON ANODE LED DISPLAY
9
ƒOSC = 0.45/RC
GEORGE SAME OFFER
ICL8069
+5V
-5V
6.8kΩ
ICL7135
A
V+
+5
DM
8880
G RB0 PROG
RBI BI D
A
3K
A
POL
G
HI VOLTAGE BUFFER D1 505
+5V
5K
0V
47K
The ICL7135 is designed to work from ±5V supplies.
However, if a negative supply is not available, it can be
generated with an ICL7660 and two capacitors (Figure 12).
POL D5
0.02µF
0.02µF
GATES
ARE
7409
0.02µF
0.02µF
2.5K
Interfacing with UARTs and
Microprocessors
0.02µF
D1
B8
B1
V+
DGND
ICL7135
+5
0V
FIGURE 8. ICL7135 PLASMA DISPLAY CIRCUIT
41/2 DIGIT LCD DISPLAY
+5V
BP
23 POL
1/ CD4030
2
CD4081
20 D1
5 BP
1/4 CD4030
31 D1
19 D2
32 D2
18 D3
33 D3
17 D4
34 D4
CD4071
16 B8
30 B3
15 B4
29 B2
14 B2
28 B1
13 B1
27 B0
12 D5
26 STROBE
This shift occurs during the reference integrate phase of
conversion causing a low display reading just after overrange
recovery. Both of the above circuits have considerable current
flowing in the digital supply from drivers, etc. A clock source
using an LM311 voltage comparator with positive feedback
(Figure 11) could minimize any clock frequency shift problem.
CD4011 ICM7211A
Figure 13 shows a very simple interface between a
free-running ICL7135 and a UART. The five STROBE pulses
start the transmission of the five data words. The digit 5 word is
0000XXXX, digit 4 is 1000XXXX, digit 3 is 0100XXXX, etc. Also
the polarity is transmitted indirectly by using it to drive the Even
Parity Enable Pin (EPE). If EPE of the receiver is held low, a
parity flag at the receiver can be decoded as a positive signal,
no flag as negative. A complex arrangement is shown in Figure
14. Here the UART can instruct the A/D to begin a
measurement sequence by a word on RRl. The BUSY signal
resets the Data Ready Reset (DRR). Again STROBE starts the
transmit sequence. A quad 2 input multiplexer is used to
superimpose polarity, over-range, and under-range onto the D5
word since in this instance it is known that B2 = B4 = B8 = 0.
For correct operation it is important that the UART clock be fast
enough that each word is transmitted before the next STROBE
pulse arrives. Parity is locked into the UART at load time but
does not change in this connection during an output stream.
Circuits to interface the ICL7135 directly with three popular
microprocessors are shown in Figure 15 and Figure 16. The
8080/8048 and the MC6800 groups with 8-bit buses need to
have polarity, over-range and under-range multiplexed onto
the Digit 5 Sword - as in the UART circuit. In each case the
microprocessor can instruct the A/D when to begin a
measurement and when to hold this measurement.
Application Notes
27 OR
NOTE #
ICL7135
+5V
1/ CD4030
4
FIGURE 9. LCD DISPLAY WITH DIGIT BLANKING ON
OVERRANGE
A problem sometimes encountered with both LED and plasmatype display driving is that of clock source supply line variations.
Since the supply is shared with the display, any variation in
voltage due to the display reading may cause clock supply
voltage modulation. When in overrange the display alternates
between a blank display and the 0000 overrange indication.
10
DESCRIPTION
AnswerFAX
DOC. #
AN016
“Selecting A/D Converters”
9016
AN017
“The Integrating A/D Converter”
9017
AN018
“Do’s and Don’ts of Applying A/D
Converters”
9018
AN023
“Low Cost Digital Panel Meter Designs”
9023
AN028
“Building an Auto-Ranging DMM Using
the 8052A/7103A A/D Converter Pair”
9028
AN030
“The ICL7104 - A Binary Output A/D
Converter for Microprocessors”
9030
AN032
“Understanding the Auto-Zero and
Common Mode Performance of the
ICL7136/7/9 Family”
9032
ICL7135
41/2 DIGIT LCD DISPLAY
REF
VOLTAGE
-5V
0.47µF
1µF
100kΩ
1µF
100kΩ
INPUT
0.1µF
UR 28
ICL7135
OR 27
2 REF
ANALOG
3 COMMON
STROBE 26
R/H 25
4 INT OUT
27Ω
ANALOG
GND
100kΩ
28 SEGMENTS D1-D4
+5V
1 V-
+5V
1 161514 12 5 3 4
CD4054A
7 8 1311 10 9 2 6
DIG. GND 24
5 AZIN
POL 23
6 BUF OUT
7 RC1
CLOCK 22
8 RC2
BUSY 21
BACKPLANE
120kC = 3 READINGS/SEC
CLOCK IN
9 INPUT LO
D1 20
5BP ICM7211A
31 D1
10 INPUT HI
D2 19
32 D2
11 V+
D3 18
33 D3
12 D5
D4 17
34 D4
13 B1
B8 16
30 B3
14 B2
B4 15
29 B2
28 B1
27 B0
35 V-
300pF
2,3,4
6-26
37-40
OPTIONAL
CAPACITOR
OSC 36
22-100pF
+5V
V+ 1
0V
+5V
FIGURE 10. DRIVING LCD DISPLAYS
+5V
1kΩ
16kΩ
+5V
56kΩ
2
0.22µF
3
+
1
8
7
LM311
-
4
1
2
+
30kΩ
16kΩ
390pF
FIGURE 11. LM311 CLOCK SOURCE
11
8
10µF
-
7
ICL7660
3
6
4
5
10µF
VOUT = -5V
+
FIGURE 12. GENERATING A NEGATIVE SUPPLY FROM +5V
ICL7135
EPE
TRO
1
2
3
4
5
D3
D2
4
5
6
7
D1
B1 B2 B4
7
8
TBRL
1Y 2Y 3Y
8
74C157
1A 2A 3A
D5
STROBE
D5
ICL7135
ICL7135
RUN/HOLD
POL
1B 2B 3B
B8
D4 D3 D2 D1 B1 B2 B4 B8
NC
ENABLE
OVER
3
6
UNDER
D4
2
DR
TBRL
TBR
TBR
1
DRR
POL
UART
IM6402/3
EPE
RRI
IM6402/3
SELECT
TRO
SERIAL OUTPUT
TO RECEIVING UART
STROBE
+5V
RUN/HOLD
BUSY
+5V
100pF
FIGURE 13. ICL7135 TO UART INTERFACE
2Y
PA1
EN
74C157
PA2
3Y
MC680X
OR
MCS650X
1A 2A 3A
RUN/
HOLD STROBE
PA0
2Y
PA1
3Y
PA2
1A 2A 3A
MC6820
D5 B8 B4 1Y
B2 B1
ICL7135
1Y
PA3
D1
PA4
D2
PA5
D3
PA6
D4
PA7
CA1
POL
UNDER
POL
OVER
PA3
1B 2B 3B
SELECT
PA0
D5 B8 B4 B21Y
B1
ICL7135
RUN/
HOLD STROBE
CA2
FIGURE 15. ICL7135 TO MC6800, MCS650X INTERFACED
12
UNDER
1B 2B 3B
1Y
FIGURE 14. COMPLEX ICL7135 TO UART INTERFACE
OVER
74C157
SELECT
EN
10K
80C48
8080
8085,
ETC.
8255
(MODE1)
D1
PA4
D2
PA5
D3
PA6
D4
PA7
STBA PB0
FIGURE 16. ICL7135 TO MCS-48, -80, -85 INTERFACE
ICL7135
Design Information Summary Sheet
• DISPLAY COUNT
• CLOCK INPUT
The ICL7135 does not have an internal oscillator. It
requires an external clock.
fCLOCK (Typ) = 120kHz
• CLOCK PERIOD
V IN
COUNT = 10, 000 × ----------------V REF
• CONVERSION CYCLE
tCYC = tCL0CK x 40002
when fCLOCK = 120kHz, tCYC = 333ms
tCLOCK = 1/fCLOCK
• INTEGRATION PERIOD
• COMMON MODE INPUT VOLTAGE
tINT = 10,000 x tCLOCK
(V- + 1V) < VlN < (V+ - 0.5V)
• 60/50Hz REJECTION CRITERION
• AUTO-ZERO CAPACITOR
tINT /t60Hz or tINT /t50Hz = Integer
0.01µF < CAZ < 1µF
• OPTIMUM INTEGRATION CURRENT
• REFERENCE CAPACITOR
IINT = 20µA
0.1µF < CREF < 1µF
• POWER SUPPLY: DUAL ±5V
• FULL-SCALE ANALOG INPUT VOLTAGE
VlNFS (Typ) = 200mV or 2V
V+ = +5V to GND
V- = -5V to GND
• INTEGRATE RESISTOR
• OUTPUT TYPE
V INFS
R INT = ----------------I INT
4 BCD Nibbles with Polarity and Overrange Bits
There is no internal reference available on the ICL7135. An
external reference is required due to the ICL7135’s 41/2
digit resolution.
• INTEGRATE CAPACITOR
( t INT ) ( I INT )
C INT = -------------------------------V INT
• INTEGRATOR OUTPUT VOLTAGE SWING
( t INT ) ( I INT )
V INT = -------------------------------C INT
• VINT MAXIMUM SWING:
(V- + 0.5) < VINT < (V+ - 0.5V)
VINT Typically = 2.7V
Typical Integrator Amplifier Output Waveform (INT Pin)
AUTO ZERO PHASE
(COUNTS)
30001 - 10001
INTEGRATE
PHASE FIXED
10000 COUNTS
DE-INTEGRATE PHASE
1 - 20001 COUNTS
TOTAL CONVERSION TIME = 40002 x tCLOCK
13
ICL7135
Die Characteristics
DIE DIMENSIONS:
PASSIVATION:
(120 mils x 130 mils) x 525µm ±25µm
Type: Nitride/Silox Sandwich
Thickness: 8k Nitride over 7k Silox
METALLIZATION:
Type: Al
Thickness: 10kÅ ±1kÅ
Metallization Mask Layout
ICL7135
V+
IN HI
IN LO
REF
CAP+
REF
CAP+
BUFF
OUT
AZ
IN
INT OUT
ANALOG COMMON
REFERENCE
(MSD) D5
V-
(LSB) B1
UNDERRANGE
B2
OVERRANGE
B4
(MSB) B8
D4
D3
STROBE
D2
14
(LSD)D1 BUSY
CLOCK IN
POL
DIGITAL
GND
R/H
ICL7135
Dual-In-Line Plastic Packages (PDIP)
E28.6 (JEDEC MS-011-AB ISSUE B)
N
28 LEAD DUAL-IN-LINE PLASTIC PACKAGE
E1
INDEX
AREA
1 2 3
INCHES
N/2
SYMBOL
-B-
-C-
A2
SEATING
PLANE
B1
A1
D1
e
eC
B
0.010 (0.25) M
C A B S
MAX
NOTES
-
0.250
-
6.35
4
0.015
-
0.39
-
4
A2
0.125
0.195
3.18
4.95
-
B
0.014
0.022
0.356
0.558
-
C
L
B1
0.030
0.070
0.77
1.77
8
eA
C
0.008
0.015
0.204
0.381
-
D
1.380
1.565
D1
0.005
-
A
L
D1
MIN
A
E
D
MAX
A1
-ABASE
PLANE
MILLIMETERS
MIN
C
eB
NOTES:
1. Controlling Dimensions: INCH. In case of conflict between English and
Metric dimensions, the inch dimensions control.
2. Dimensioning and tolerancing per ANSI Y14.5M-1982.
3. Symbols are defined in the “MO Series Symbol List” in Section 2.2 of
Publication No. 95.
4. Dimensions A, A1 and L are measured with the package seated in
JEDEC seating plane gauge GS-3.
5. D, D1, and E1 dimensions do not include mold flash or protrusions.
Mold flash or protrusions shall not exceed 0.010 inch (0.25mm).
6. E and eA are measured with the leads constrained to be perpendicular to datum -C- .
7. eB and eC are measured at the lead tips with the leads unconstrained.
eC must be zero or greater.
8. B1 maximum dimensions do not include dambar protrusions. Dambar
protrusions shall not exceed 0.010 inch (0.25mm).
9. N is the maximum number of terminal positions.
10. Corner leads (1, N, N/2 and N/2 + 1) for E8.3, E16.3, E18.3, E28.3,
E42.6 will have a B1 dimension of 0.030 - 0.045 inch (0.76 - 1.14mm).
35.1
39.7
5
-
5
0.13
E
0.600
0.625
15.24
15.87
6
E1
0.485
0.580
12.32
14.73
5
e
0.100 BSC
2.54 BSC
-
eA
0.600 BSC
15.24 BSC
6
eB
-
0.700
-
17.78
7
L
0.115
0.200
2.93
5.08
4
N
28
28
9
Rev. 1 12/00
All Intersil semiconductor products are manufactured, assembled and tested under ISO9000 quality systems certification.
Intersil semiconductor products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design and/or specifications at any time without notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate and
reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which may result
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