ETC ICL8052/ICL7104

ICL7104
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November 2000
Features
Description
• 16-Bit/14-Bit Binary Three-State Latched Outputs Plus
Polarity and Overrange
The ICL7104, combined with the ICL8052 or ICL8068,
forms a member of Intersil’ high performance A/D converter
family. The ICL7104-16, performs the analog switching and
digital function for a 16-bit binary A/D converter, with full
three-state output, UART handshake capability, and other
outputs for easy interfacing. The ICL7014-14 is a 14-bit
version. The analog section, as with all Intersil’ integrating
converters, provides fully precise Auto-Zero, Auto-Polarity
(including ±0 null indication), single reference operation,
very high input impedance, true input integration over a
constant period for maximum EMI rejection, fully
rationmetric operation, over-range indication, and a
medium quality built-in reference. The chip pair also offers
optional input buffer gain for high sensitivity applications, a
built-in clock oscillator, and output signals for providing an
external Auto-Zero capability in preconditioning circuitry,
synchronizing external multiplexers, etc.
• Ideally Suited for Interface to UARTs and
Microprocessors
• Conversion on Demand or Continuously
• Guaranteed Zero Reading for 0V Input
• True Polarity at Zero Count for Precise Null Detection
• Single Reference Voltage for True Ratiometric
Operation
• Onboard Clock and Reference
• Auto-Zero, Auto-Polarity
• Accuracy Guaranteed to 1 Count
• All Outputs TTL Compatible
Part Number Information
• ±4V Analog Input Range
• Status Signal Available for External Sync, A/Z in
Preamp, Etc.
PART NUMBER
TEMP.
RANGE ( oC)
PKG.
NO.
PACKAGE
ICL7104-14CPL
0 to 70
40 Ld PDIP
E40.6
lCL7104-16CPL
0 to 70
40 Ld PDIP
E40.6
Pinouts
ICL7104 (PDIP)
TOP VIEW
ICL7104-16
V++
ICL7104-14
40 V-
ICL7104-14
V++
1
DIG GND
DIG GND
2
39 COMP IN
STTS
STTS
3
38 REFCAP 1
POL
POL
4
37 VREF
OR
OR
5
BIT 16
BIT 14
6
BIT 15
BIT 13
7
36 AZ
35 ANALOG
GND
34 REFCAP 2
BIT 14
BIT 12
8
33 BUF IN
BIT 13
BIT 11
9
32 ANALOG I/P
BIT 12
BIT 10
10
BIT 11
BIT 9
11
BIT 10
ICL7104-16
NC
31 V+
ICL7104-14
(OUTLINE DWGS DL,
30 CE/LD
JL, PL)
12
29 SEN
BIT 9
NC
13
28 R/H
BIT 8
BIT 8
14
27 MODE
BIT 7
BIT 7
15
26 CLK 2
BIT 6
BIT 6
16
25 CLK 1
BIT 5
BIT 5
17
24 CLK 3
HBEN
BIT 4
BIT 4
18
23 HBEN
MBEN
BIT 3
BIT 3
19
22 LBEN
BIT 2
BIT 2
20
21 BIT 1
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
File Number
3091.2
ICL7104
Functional Block Diagram
RINT
CINT
-BUF IN
BUF OUT
-INT IN
10
BUFFER
9
+15V -15V
REF
OUT
8
6
7
1
INT.
3 REF.
-
8052/8068
+INT IN 12
A3
+
4
6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21
COMP
OUT
-
A2
+
10µF
5
COMP.
-1.2V
+BUF IN 13
OR POL 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1
14
-
A1
+
300pF
5kΩ
10kΩ 5
11
INTEG.
BITS
INT OUT
THREE-STATE OUTPUTS
24 HBEN
+5V
2
-15V
22 LBEN
CAZ
+BUF IN
AZ
33
VREF
ANALOG
INPUT
ANALOG
GND
37
36
39
SW5
ZERO
CROSSING
DETECTOR
SW8
SW1
SW2
30 CE/LD
300kΩ
7104
SW6
32
COUNTER
COMP IN
SW3
SW4
23 MBEN
LATCHES
50kΩ
29 SEN
27 MODE
CONTROL LOGIC
28 R/H
SW7
SW9
35
38
34
REF CAP (1)
1
REF CAP (2)
+15V
CREF
31
+5V
2
40
25
26
3
-15V CLOCK CLOCK STTS
(1)
(2)
FIGURE 1. ICL8052A (8068A)/ICL7104 16-BIT/14-BIT A/D CONVERTER FUNCTIONAL DIAGRAM
Pin Descriptions
PIN NO.
SYMBOL
1
V++
OPTION
Positive Supply Voltage: Nominally +15V.
DESCRIPTION
2
GND
Digital Ground: 0V, ground return.
3
STTS
Status Output: HI during integrate and deintegrate until data is latched. LO when analog section
is in auto-zero configuration.
4
POL
5
OR
6
BIT 16
BIT 14
-16
-14
7
BIT 15
BIT 13
-16
-14
8
BIT 14
BIT 12
-16
-14
9
BIT 13
BIT 11
-16
-14
10
BIT 12
BIT 10
-16
-14
11
BIT 11
BIT 9
-16
-14
12
BIT 10
NC
-16
-14
13
BIT 9
NC
-16
-14
14
BIT 8
15
BIT 7
16
BIT 6
17
BIT 5
18
BIT 4
19
BIT 3
20
BIT 2
Polarity: Three-state output. HI for positive input.
Over Range: Three-state output.
Most Significant Bit (MSB).
DATA Bits: Three-state outputs. See Table 3 for format of ENABLES and bytes. HIGH = true.
2
ICL7104
Pin Descriptions
(Continued)
PIN NO.
SYMBOL
21
BIT 1
Least Significant Bit (LSB).
22
LBEN
LOW BYTE ENABLE: If not in handshake mode (see pin 27) when LO (with CE/LD, pin 30)
activates low-order byte outputs, BITS 1-8. When in handshake mode (see pin 27), serves as a
low byte flag output. See Figures 11, 12, 13.
23
MBEN
-16
MID BYTE ENABLE: Activates Bits 9-16, see LBEN (pin 22)
HBEN
-14
HIGH BYTE ENABLE: Activates Bits 9-14, POL, OR, see LBEN (pin 22)
HBEN
-16
HIGH BYTE ENABLE: Activates POL, OR, see LBEN (pin 22).
CLOCK3
-14
RC oscillator pin: Can be used as clock output.
24
OPTION
DESCRIPTION
25
CLOCK 1
Clock Input: External clock or ocsillator.
26
CLOCK 2
Clock Output: Crystal or RC oscillator.
27
MODE
INPUT LO: Direct output mode where CE/LD, HBEN, MBEN and LBEN act as inputs directly
controlling byte outputs. If pulsed HI causes immediate entry into handshake mode (see Figure
13). If HI, enables CE/LD, HBEN, MBEN and LBEN as outputs. Handshake mode will be entered
and data output as in Figures 11 and 12 at conversion completion.
28
R/H
RUN/HOLD: Input HI conversions continuously performed every 217(-16) or 215(-14) clock
pulses. Input LO conversion in progress completed, converter will stop in Auto-Zero 7 counts
before input integrate.
29
SEN
SEND ENABLE: Input controls timing of byte transmission in handshake mode. HI indicates
‘send’.
30
CE/LD
CHIP ENABLE/ LOAD: WITH MODE (PIN 27) LO, CE/LD serves as a master output enable;
when HI, the bit outputs and POL, OR are disabled. With MODE HI, pin serves as a LOAD strobe
(-ve going) used in handshake mode. See Figures 11 and 12.
31
V+
32
AN I/P
Positive Logic Supply Voltage: Nominally +5V.
Analog Input: High Side.
33
BUF IN
Buffer Input: Buffer Analog to analog chip (ICL8052 or ICL8086).
34
REFCAP2
Reference Capacitor: Negative Side.
35
AN. GND
Analog Ground: Input low side and reference low side.
36
A-Z
37
VREF
38
REFCAP1
39
COMP-IN
40
V-
Auto-Zero node.
Voltage Reference: Input (positive side).
Reference Capacitor: Positive side.
Comparator Input: From 8052/8068.
Negative Supply Voltage: Nominally -15V.
3
ICL7104
Absolute Maximum Ratings
Thermal Information
V+ Supply (GND to V+) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12V
V++ to V- . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32V
Positive Supply Voltage (GND to V++). . . . . . . . . . . . . . . . . . . . 17V
Negative Supply Voltage (GND to V-) . . . . . . . . . . . . . . . . . . . . -17V
Analog Input Voltage (Pins 32 - 39)(Note 4). . . . . . . . . . . . V++ to VDigital Input Voltage
(Pins 2 - 30) (Note 5) . . . . . . . . . . . . (GND - 0.3V) to (V+ + 0.3V)
Thermal Resistance (Typical, Note 1)
θJA ( oC/W)
40 Ld PDIP Package . . . . . . . . . . . . . .
60
Maximum Junction Temperature (Plastic Package) . . . . . . . . 150oC
Maximum Storage Temperature Range . . . . . . . . . . -65oC to 150oC
Maximum Lead Temperature (Soldering, 10s) . . . . . . . . . . . . 300oC
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. θJA is measured with the component mounted on an evaluation PC board in free air.
2. For supply voltages less than ±15V, the absolute maximum input voltage is equal to the supply voltage.
3. Short circuit may be to ground or either supply. Rating applies to 70oC ambient temperature.
4. Input voltages may exceed the supply voltages provided the input current is limited to ±100µA.
5. Connecting any digital inputs or outputs to voltages greater than V+ or less than GND may cause destructive device latchup. For this
reason it is recommended that the power supply to the ICL7104 be established before any inputs from sources not on that supply are
applied.
ICL7104 Electrical Specifications V+ = +5V, V++ = +15V, V- = -15V, TA = 25oC, fCLOCK = 200kHz
PARAMETER
TEST
CONDITIONS
MIN
TYP
MAX
Clock Input, CLK 1
IIN
VIN = +5V to 0V
±2
±7
±30
µA
Comparator I/P, COMP IN (Note 6)
IIN
VIN = 0V to +5V
-10
±0.001
10
µA
Inputs with Pulldown, MODE
IIH
VIN = +5V
1
5
30
µA
IIL
VIN = 0V
-10
±0.01
10
µA
Inputs with Pullups
SEN, R/H
LBEN, MBEN, HBEN, CE/LD (Note 7)
IIH
VIN = +5V
-10
±0.01
10
µA
IIL
VIN = 0V
-30
-5
-1
µA
Input High Voltage, All Digital Inputs
VIH
2.5
2.0
-
V
Input Low Voltage, All Digital Inputs
V IL
-
1.5
1.0
V
V
Digital Outputs Three-Stated On,
LBEN, MBEN (16 Only), HBEN, CE/LD
BIT n, POL, OR (Note 8)
Digital Outputs Three-Stated Off
Bit n, POL, OR
Non Three-State Digital Output
STTS
Clock 2
Clock 3 (-14 Only)
Switch
Switch 1
SYMBOL
UNITS
VOL
IOL = 1.6mA
-
0.27
0.4
VOH
IOH = -10µA
-
4.5
-
V
VOH
IOH = -240µA
2.4
3.5
-
V
IOL
0 ≤ VOUT ≤ V+
-10
±0.001
+10
µA
VOL
IOL = 3.2mA
-
0.3
0.4
V
VOH
IOH = -400µA
2.4
3.3
-
V
VOL
IOL= 320µA
-
0.5
-
V
VOH
IOH = -320µA
-
4.5
-
V
VOL
IOL = 1.6mA
-
0.27
0.4
V
VOH
IOH = -320µA
2.4
3.5
-
V
rDS(ON)
-
25k
-
Ω
Switches 2, 3
rDS(ON)
-
4k
20k
Ω
Switches 4, 5, 6, 7, 8, 9
rDS(ON)
-
2k
10k
Ω
Switch Leakage
ID(OFF)
-
15
-
pA
fCLOCK
DC
200
400
kHz
-
200
600
µA
Clock Frequency (Note 9)
Supply Currents
+5V Supply Current
All outputs high impedance
I+
Frequency = 200kHz
+5V Supply Current
I++
Frequency = 200kHz
-
0.3
1.0
mA
-5V Supply Current
I-
Frequency = 200kHz
-
25
200
µA
4
ICL7104
ICL7104 Electrical Specifications V+ = +5V, V++ = +15V, V- = -15V, TA = 25oC, fCLOCK = 200kHz (Continued)
PARAMETER
TEST
CONDITIONS
SYMBOL
MIN
TYP
MAX
UNITS
4
-
11
V
10
-
16
V
-
-10
V
Supply Voltage Range
Logic Supply
V+
Positive Supply
V++
Negative Supply
V-
-16
Note 10
NOTES:
6. This specification applies when not in Auto-Zero phase.
7. Apply only when these pins are inputs, i.e., the mode pin is low, and the 7104 is not in handshake mode.
8. Apply only when these pins are outputs, i.e., the mode pin is high, or the 7104 is in handshake mode.
9. Clock circuit shown in Figures 14 and 15.
10. V+ must not be more positive than V++.
System Electrical Specifications: ICL8068/ICL7104 V++ = +15V, V+ = +5V, V- = -15V, fCLOCK = 200kHz (Note 16)
ICL8068A/ICL7104-14
ICL8068A/ICL7104-16
TEST
CONDITIONS
MIN
TYP
MAX
MIN
TYP
MAX
UNITS
Zero Input Reading
VIN = 0V, VREF = 2V
-00000
±00000
+00000
-00000
±00000
+00000
Counts
Ratiometric Error (Note 13)
VIN = VREF = 2V
-1
0
1
-1
0
1
LSB
Linearity Over ± Full Scale (Error of
Reading from Best Straight Line)
-4V ≤ VIN ≤ +4V
-
0.5
1
-
0.5
1
LSB
Differential Linearity (Difference
between Worst Case Step of Adjacent
Counts and Ideal Step)
-4V ≤ VIN ≤ +4V
-
0.01
-
-
0.01
-
LSB
Rollover Error (Difference in Reading
for Equal Positive & Negative Voltage
Near Full Scale)
-VIN = +VIN ≅ 4V
-
0.5
1
-
0.5
1
LSB
Noise (P-P Value Not Exceeded 95% of
Time)
VIN = 0V,
Full Scale = 4V
-
2
-
-
2
-
µV
Leakage Current at Input (Note 14)
VIN = 0V
-
100
165
-
100
165
pA
Zero Reading Drift
VIN = 0V,
0oC to 70oC
-
0.5
-
-
0.5
-
µV/oC
Scale Factor Temperature Coefficient
(Note 15)
VIN = 4V,
0oC to 50oC
ext. ref. 0ppm/oC
-
2
5
-
2
5
ppm/oC
PARAMETER
System Electrical Specifications: ICL8052/ICL7104 V++ = +15V, V+ = +5V, V- = -15V, fCLOCK = 200kHz
(Note 16)
PARAMETER
ICL8052A/ICL7104-14
ICL8052A/ICL7104-16
TEST
CONDITIONS
MIN
TYP
MAX
MIN
TYP
MAX
UNITS
Zero Input Reading
VIN = 0V, VREF = 2V
-00000
±00000
+00000
-00000
±00000
+00000
Counts
Ratiometric Error (Note 15)
VIN = VREF = 2V
-1
0
1
-1
0
1
LSB
Linearity Over ± Full Scale (Error of
Reading from Best Straight Line)
-4V ≤ VIN ≤ +4V
-
0.5
1
-
0.5
1
LSB
Differential Linearity (Difference
between Worst Case Step of Adjacent
Counts and Ideal Step)
-4V ≤ VIN ≤ +4V
-
0.01
-
-
0.01
-
LSB
Rollover Error (Difference in Reading
for Equal Positive and Negative Voltage
Near Full Scale)
-VIN = +VIN ≈ 4V
-
0.5
1
-
0.5
1
LSB
Noise (Peak-to-Peak Value Not
Exceeded 95% of Time)
VIN = 0V,
Full Scale = 4V
-
30
-
-
30
-
µV
5
ICL7104
System Electrical Specifications: ICL8052/ICL7104 V++ = +15V, V+ = +5V, V- = -15V, fCLOCK = 200kHz
(Note 16) (Continued)
TEST
CONDITIONS
PARAMETER
ICL8052A/ICL7104-14
ICL8052A/ICL7104-16
MIN
TYP
MAX
MIN
TYP
MAX
UNITS
Leakage Current at Input (Note 14)
VIN = 0V
-
20
30
-
20
30
pA
Zero Reading Drift
VIN = 0V,
0oC to 70oC
-
0.5
-
-
0.5
-
µV/oC
Scale Factor Temperature Coefficient
VIN = 4V,
0oC to 50oC
ext. ref. 0ppm/oC
-
2
-
-
2
-
ppm/oC
NOTES:
11. Tested with low dielectric absorption integrating capacitor.
12. The input bias currents are junction leakage currents which approximately double for every 10oC increase in the junction temperature,
TJ . Due to limited production test time, the input bias currents are measured with junctions at ambient temperature. In normal operation
the junction temperature rises above the ambient temperature as a result of internal power dissipation, PD. TJ = TA + RθJAPD where
RθJA is the thermal resistance from junction to ambient. A heat sink can be used to reduce temperature rise.
13. The temperature range can be extended to 70oC and beyond if the Auto-Zero and Reference capacitors are increased to absorb the high
temperature leakage of the 8068. See note 14 above.
14. System Electrical Specifications are not tested; for reference only.
CONTROL
CONVERT
MODE
R/H
OR
≥18
POL
7104 -16
MSB
8052A/
8068A
18
LSB
CE/LD HBEN MBEN LBEN
OR CHIP SELECT 2
CHIP SELECT 1
FIGURE 2. FULL 18-BIT THREE-STATE OUTPUT
CONVERT
MODE CE/LD
POL
7104
MODE CE/LD
R/H
OR
8052A/
8068A
CONVERT
MSB
8
POL
8052A/
8068A
7104
MODE CE/LD
R/H
OR
2
CONVERT
R/H
OR
2
POL
MSB
8052A/
8068A
7104
MSB
10
16
LSB
8
LSB
LSB
HBEN MBEN LBEN
HBEN MBEN LBEN
HBEN MBEN LBEN
CONTROL
CONTROL
CONTROL
FIGURE 3. VARIOUS COMBINATIONS OF BYTE DISABLES
6
8
ICL7104
tCEA
CE/LD
AS INPUT
tBEA
HBEN
AS INPUT
MBEN
AS INPUT
LBEN
AS INPUT
tDAB
HIGH BYTE
DATA
tDHB
DATA
VALID
DATA
VALID
tDAC
MIDDLE
BYTE
ENABLE
DATA
VALID
tDHC
DATA
VALID
LOW BYTE
ENABLE
DATA
VALID
= HIGH IMPEDANCE
FIGURE 4. DIRECT MODE TIMING DIAGRAM
TABLE 1. DIRECT MODE TIMING REQUIREMENTS (Note: Not tested in production)
SYMBOL
DESCRIPTION
MIN
TYP
MAX
UNIT
tBEA
XBEN (Min) Pulse Width.
-
300
-
ns
tDAB
Data Access Time from XBEN.
-
300
-
ns
tDHB
Data Hold Time from XBEN.
-
200
-
ns
tCEA
CE/LD Min. Pulse Width.
-
350
-
ns
tDAC
Data Access Time from CE/LD.
-
350
-
ns
tDHC
Data Hold Time from CE/LD.
-
280
-
ns
tCWH
CLOCK 1 High Time.
-
1000
-
ns
TABLE 2. HANDSHAKE TIMING REQUIREMENTS (Note: Not tested in production)
SYMBOL
DESCRIPTION
MIN
TYP
MAX
UNIT
-
20
-
ns
Mode Pin Set-Up Time.
-
-150
-
ns
Mode Pin High to Low Z CE/LD High Delay.
-
200
-
ns
tMW
Mode Pulse (Min).
tSM
tME
tMB
Mode Pin High to XBEN Low Z (High) Delay.
-
200
-
ns
tCEL
Clock 1 High to CE/LD Low Delay.
-
700
-
ns
tCEH
Clock 1 High to CE/LD High Delay.
-
600
-
ns
tCBL
Clock 1 High to XBEN Low Delay.
-
900
-
ns
tCBH
Clock 1 High to XBEN High Delay.
-
700
-
ns
tCDH
Clock 1 High to Data Enabled Delay.
-
1100
-
ns
tCDL
Clock 1 Low to Data Disabled Delay.
-
1100
-
ns
Send ENABLE Set-Up Time.
-
-350
-
ns
tSS
tCBZ
Clock 1 High to XBEN Disabled Delay.
-
2000
-
ns
tCEZ
Clock 1 High to CE/LD Disabled Delay.
-
2000
-
ns
tCWH
Clock 1 High Time.
1250
1000
-
ns
7
ICL7104
CLOCK 1 H
(PIN 25) L
tCWH
tSM
tMW
EITHER: H
MODE PIN L
OR
INTERNAL
LATCH PULSE IF
MODE “HI”
INTERNAL UART
MODE NORM
CE/LD
SEN
(EXTERNAL
SIGNAL)
HBEN
H
L
H
DON’T CARE
L
H
L
DON’T CARE
IGNORED
tCEL
tME
IGNORED
tCEH
EXT
tCEZ
tSS
EXT
DON’T CARE
tMB
tCBL
O/R, POL H
01-14 L
LBEN
STABLE
tCBH
tCDL
tCDH
H
L
DATA VALID, STABLE
BITS 1-5
HANDSHAKE MODE
TRIGGERED BY
tCBZ
DATA VALID, STABLE
OR
THREE-STATE
-16 HAS EXTRA (MBEN) PHASE
THREE-STATE WITH PULLUP
FIGURE 5. HANDSHAKE MODE TIMING DIAGRAM
Detailed Description
ANALOG SECTION
unbalanced condition exists compared to the Auto-Zero
phase, and the integrator will generate a ramp whose slope
is proportional to VIN . At the end of this phase, the sign of
the ramp is latched into the polarity F/F.
Figure 6 shows the equivalent Circuit of the Analog Section
of both the ICL7104/8052 and the ICL7104/8068 in the 3
different phases of operation. If the Run/Hold pin is left open
or tied to V+, the system will perform conversions at a rate
determined by the clock frequency: 131,072 for - 16 and
32,368 for - 14 clock periods per cycle (see Figure 8
conversion timing).
Deintegrate Phase III (Figures 6C and 6D)
During the Deintegrate phase, the switch drive logic uses the
output of the polarity F/F in determining whether to close
switches 6 and 9 or 7 and 8. If the input signal was positive,
switches 7 and 8 are closed and a voltage which is V REF
more negative than during Auto-Zero is impressed on the
buffer input. Negative inputs will cause +VREF to be applied
to the buffer input via switches 6 and 9. Thus, the reference
capacitor generates the equivalent of a (+) reference or a (-)
reference from the single reference voltage with negligible
error. The reference voltage returns the output of the integrator to the zero-crossing point established in Phase I. The
time, or number of counts, required to do this is proportional
to the input voltage. Since the Deintegrate phase can be
twice as long as the Input integrate phase, the input voltage
required to give a full scale reading = 2VREF .
Auto-Zero Phase I (Figure 6A)
During Auto-Zero, the input of the buffer is shorted to analog
ground thru switch 2, and switch 1 closes a loop around the
integrator and comparator. The purpose of the loop is to
charge the Auto-Zero capacitor until the integrator output no
longer changes with time. Also, switches 4 and 9 recharge
the reference capacitor to VREF .
Input Integrate Phase II (Figure 6B)
During input integrate the Auto-Zero loop is opened and the
analog input is connected to the buffer input thru switch 3.
(The reference capacitor is still being charged to V REF
during this time.) If the input signal is zero, the buffer,
integrator and comparator will see the same voltage that
existed in the previous sate (Auto-Zero). Thus the integrator
output will not change but will remain stationary during the
entire Input Integrate cycle. If VIN is not equal to zero, an
NOTE: Once a zero crossing is detected, the system automatically
reverts to Auto-Zero phase for the leftover Deintegrate time (unless
RUN/HOLD is manipulated, see RUN/HOLD input in detailed
description, digital section).
8
ICL7104
RINT
AN
I/P
BUFFER
INTEGRATOR
-
3
COMP.
-
A1
+
8
CINT
-
A2
+
2
6
ZERO
CROSS.
DET.
A3
+
D
CAZ
CL
7
9
1
-
+
CL
POL
VREF
4
CREF
Q
ZERO
CROSSING
F/F
FIGURE 6A. PHASE I AUTO-ZERO
RINT
AN
I/P
BUFFER
-
3
9
D
INTEGRATOR
-
A2
+
D
CAZ
+
CL
CL
POL
VREF
4
CREF
Q
ZERO
CROSSING
F/F
7
1
-
Q
FIGURE 6B. PHASE II INTEGRATE INPUT
RINT
+AN
I/P
BUFFER
-
3
A1
+
8
9
6
CINT
INTEGRATOR
COMP.
-
-
A2
+
A3
+
2
ZERO
CROSS.
DET.
D
Q
ZERO
CROSSING
F/F
CAZ
CL
7
1
-
+
CREF
4
POL
VREF
FIGURE 6C. PHASE III + DEINTEGRATE
9
POL
PHASE II
ZERO
CROSS.
DET.
A3
+
2
6
POL
F/F
CL
COMP.
-
A1
+
8
CINT
CL
ICL7104
RINT
-AN
I/P
BUFFER
INTEGRATOR
-
3
9
COMP.
-
A1
+
8
CINT
-
A2
+
2
6
ZERO
CROSS.
DET.
A3
+
Q
ZERO
CROSSING
F/F
CAZ
CL
7
1
-
D
+
VREF
4
CREF
CL
POL
FIGURE 6D. PHASE III DEINTEGRATE
TABLE 3. THREE-STATE BYTE FORMATS AND ENABLE PINS
CE/LD
HBEN
ICL7104-16 POL
O/R
MBEN
B16
B15
B14
B13
POL
O/R
B14
B13
B12
LBEN
B11
B10
B9
B8
B7
B6
B5
B11
B10
B9
B8
B7
B6
B5
B12
B3
B2
B1
B3
B2
B1
LBEN
HBEN
ICL7104-14
B4
B4
TABLE 4. TYPICAL COMPONENT VALUES (V++ = +15V, V+ = 5V, V- = 5V, V- = -15V, fCLOCK = 200kHz)
ICL8052/8068 WITH
Full scale VIN
ICL7104-16
200
800
ICL7104-14
4000
100
UNIT
4000
mV
Buffer Gain
10
1
1
10
1
V/V
RINT
100
43
200
47
180
kΩ
CINT
0.33
0.33
0.33
0.1
0.1
µF
CAZ
1
1
1
1
1
µF
CREF
10
1
1
10
1
µF
VREF
100
400
2000
50
2000
mV
Resolution
3.1
12
61
6.1
244
µV
Buffer Gain
ICL8052 vs ICL8068
At the end of the auto-zero interval, the instantaneous noise
voltage on the auto-zero capacitor is stored, and subtracts from
the input voltage while adding to the reference voltage during
the next cycle. The result is that this noise voltage effectively is
somewhat greater than the input noise voltage of the buffer
itself during integration. By introducing some voltage gain into
the buffer, the effect of the auto-zero noise (referred to the
input) can be reduced to the level of the inherent buffer noise.
This generally occurs with a buffer gain of between 3 and 10.
Further increase in buffer gain merely increases the total offset
to be handled by the auto-zero loop, and reduces the available
buffer and integrator swings, without improving the noise performance of the system. The circuit recommended for doing
this with the ICL8068/ICL7104 is shown in Figure 7. With careful layout, the circuit shown can achieve effective input noise
voltages on the order of 1 to 2µV, allowing full 16-bit use with
full scale inputs of a low as 150mV. Note that at this level, thermoelectric EMFs between PC boards, IC pins, etc., due to local
temperature changes can be very troublesome. For further discussion, see Application Note AN030.
The ICL8052 offers significantly lower input leakage currents
than the ICL8068, and may be found preferable in systems
with high input impedances. However, the ICL8068 has
substantially lower noise voltage, and for systems where
system noise is a limiting factor, particularly in low signal
level conditions, will give better performance.
Component Value Selection
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.
10
ICL7104
10-50K
RINT
CINT
-BUF IN
BUF OUT
-INT IN
10
BUFFER
9
100kΩ
+15V -15V
REF
OUT
300pF
6
8
7
INT.
3 REF.
1
-
A1
+
5kΩ
10kΩ
5
11
INTEG.
INT OUT
14
COMP.
-
+BUF IN 13
-
A2
+
8068
+INT IN 12
COMP
OUT
-1.2V
+5V
A3
+
2
-15V
TO ICL7104
FIGURE 7. ADDING BUFFER GAIN TO ICL8068
COUNTS
PHASE I
PHASE II
PHASE III
-16
32768
32768
65536
-14
8192
8192
16384
POLARITY
DETECTED
INTEGRATOR
OUTPUT
ZERO CROSSING
OCCURS
ZERO CROSSING
DETECTED
AZ PHASE I
INT PHASE II
DEINT PHASE III
AZ
INTERNAL CLOCK
INTERNAL LATCH
STATUS OUTPUT
AFTER ZERO CROSSING,
ANALOG SECTION WILL
BE IN AUTOZERO
CONFIGURATION
NUMBER OF COUNTS TO ZERO CROSSING
PROPORTIONAL TO VIN
FIGURE 8. CONVERSION TIMING
to give 9 volt swing for full scale inputs. This is a compromise
between possibly saturating the integrator (at +14 volts) due
to tolerance build-up between the resistor, capacitor and
clock and the errors a lower voltage swing could induce due
to offsets referred to the output of the comparator. In
general, the value of CINT is given by:
Integrating Resistor
The integrating resistor is determined by the full scale input
voltage and the output current of the buffer used to charge
the integrator capacitor. This current should be small
compared to the output short circuit current such that
thermal effects are kept to a minimum and linearity is not
affected. Values of 5 to 40µA give good results with a
nominal of 20µA. The exact value may be chosen by:
 (32768 for - 16)
 (8192 for -14) 
× 20µA × clock period
C I NT = ---------------------------------------------------------------------------------------------------------Integrator Output Voltage Swing
A very important characteristic of the integrating capacitor is
that it have 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.
full scale voltage (see note)
R I NT = ------------------------------------------------------------------------20µA
NOTE: If gain is used in the buffer amplifier then
( Bu fferGa in ) (full scale voltage)
R IN T = ---------------------------------------------------------------------------------------20µA
This ratiometric condition should read half scale (100...000)
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.
Integrating Capacitor
The product of integrating resistor and capacitor is selected
11
ICL7104
and control logic and UART handshake logic, as shown in
the Block Diagram Figure 9 (16-bit version shown).
Auto-Zero and Reference Capacitor
The size of the auto-zero capacitor has some influence on
the noise of the system, a large capacitor giving less noise.
The reference capacitor should be large enough such that
stray capacitance to ground from its nodes is negligible.
Throughout this description, logic levels will be referred to as
“low” or “high”. The actual logic levels are defined under
“ICL7104 Electrical Specification”. For minimum power consumption, all inputs should swing from GND (low) to V+
(high). Inputs driven from TTL gates should have 3 - 5kΩ
pullup resistors added for maximum noise immunity.
NOTE: When gain is used in the buffer amplifier the reference
capacitor should be substantially larger than the auto-zero capacitor.
As a rule of thumb, the reference capacitor should be approximately
the gain times the value of the auto-zero capacitor. 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.
MODE Input
The MODE input is used to control the output mode of the
converter. When the MODE pin is connected to GND or left
open (this input is provided with a pulldown resistor to
ensure a low level when the pin is left open), the converter is
in its “Direct” output mode, where the output data is directly
accessible under the control of the chip and byte enable
inputs. When the MODE input is pulsed high, the converter
enters the UART handshake mode and outputs the data in
three bytes for the 7104-16 or two bytes for the 7104-14 then
returns to “direct” mode. When the MODE input is left high,
the converter will output data in the handshake mode at the
end of every conversion cycle. (See section entitled “Handshake Mode” for further details).
Reference Voltage
The analog input required to generate a full scale output is
VIN = 2VREF .
The stability of the reference voltage is a major factor in the
overall absolute accuracy of the converter. The resolution of
the ICL7104 at 16 bits is one part in 65536, or 15.26ppm.
Thus, if the reference has a temperature coefficient of
50ppm/C (on board reference) a temperature change of 1/3C
will introduce a one-bit absolute error. For this reason, it is recommended that an external high quality reference be used
where the ambient temperature is not controlled or where
high-accuracy absolute measurements are being made.
STATUS Output
During a conversion cycle, the STATUS output goes high at
the beginning of Input Integrate (Phase II), and goes low
one-half clock period after new data from the conversion has
been stored in the output latches. See Figure 8 for details of
this timing. This signal may be used as a “data valid” flag
(data never changes while STATUS is low) to drive interrupts, or for monitoring the status of the converter.
Detailed Description
DIGITAL SECTION
The digital section includes the clock oscillator circuit, a
16-bit or 14-bit binary counter with output latches and TTLcompatible three-state output drivers, polarity, over-range
TABLE 5. THREE-STATE BYTE FORMATS AND ENABLE PINS
CE/LD
HBEN
ICL7104-16 POL
O/R
MBEN
B16
B15
B14
B13
B12
LBEN
B11
B10
B9
B8
B7
B6
POL
O/R
B14
B13
B12
B4
B3
B2
B1
B3
B2
B1
LBEN
HBEN
ICL7104-14
B5
B11
12
B10
B9
B8
B7
B6
B5
B4
ICL7104
18/16 THREE-STATE OUTPUTS
HBEN
18/16 LATCHES
INITIAL
CLEAR
MBEN
(-16 ONLY)
18/16 BIT COUNTER
LBEN
LATCH
CLOCK
TO
ANALOG
SECTION
COMP OUT
AZ
INT
DEINT(+)
DEINT(-)
CONVERSION
CONTROL
LOGIC
2
OSCILLATOR
AND CLOCK
CIRCUITRY
26
STATUS
R/H
24
23
CE/LD
HANDSHAKE
LOGIC
25
21
27
CLOCK CLOCK CLOCK
(2)
(3)
(1)
MODE
SEND
FIGURE 9. DIGITAL SECTION
INTEGRATOR
OUTPUT
OPTION
-14
-16
MIN
7161
28665
MAX
8185
32761
DEINT TERMINATED
AT ZERO CROSSING
DETECTION
STATIC IN
HOLD STATE
INT
PHASE
7 COUNTS
INTERNAL
CLOCK
INTERNAL
LATCH
STATUS
OUTPUT
RUN/HOLD
INPUT
FIGURE 10. RUN/HOLD OPERATION
Run/Hold Input
at Run/Hold. See Figure 10 for details.
When the Run/Hold input is connected to V+ or left open
(this input has pullup resistor to ensure a high level when the
pin is left open), the circuit will continuously perform
conversion cycles, updating the output latches at the end of
every Deintegrate (Phase III) portion of the conversion cycle
(See Figure 8). (See under “Handshake Mode” for
exception.) In this mode of operation, the conversion cycle
will be performed in 131,072 for 7104-16 and 32768 for
7104-14 clock periods, regardless of the resulting value.
Using the Run/Hold input in this manner allows an easy
“convert on demand” interface to be used. The converter
may be held at idle in Auto-Zero with Run/Hold low. When
Run/Hold goes high the conversion is started, and when the
STATUS output goes low the new data is valid (or transferred) to the UART - see Handshake Mode). Run/Hold may
now go low terminating Deintegrate and ensuring a minimum
Auto-Zero time before stopping to wait for the next
conversion. Alternately, Run/Hold can be used to minimize
conversion time by ensuring that it goes low during Deintegrate, after zero crossing, and goes high after the hold point
is reached. The required activity on the Run/Hold input can
be provided by connecting it to the CLOCK3 (-14), CLOCK2
(-16) Output. In this mode the conversion time is dependent
on the input value measured. Also refer to Intersil Application Bulletin A030 for a discussion of the effects this will have
on Auto-Zero performance.
If Run/Hold goes low at any time during Deintegrate (Phase
III) after the zero crossing has occurred, the circuit will
immediately terminate Deintegrate and jump to Auto-Zero.
This feature can be used to eliminate the time spent in
Deintegrate after the zero-crossing. If Run/Hold stays or
goes low, the converter will ensure a minimum Auto-Zero
time, and then wait in Auto-Zero until the Run/Hold input
goes high. The converter will begin the Integrate (Phase II)
portion of the next conversion (and the STATUS output will
go high) seven clock periods after the high level is detected
If the Run/Hold input goes low and stays low during AutoZero (Phase I), the converter will simply stop at the end of
13
ICL7104
the MODE input is high, the chip and byte ENABLE terminals become TTL-compatible outputs which provide the control signals for the output cycle. The Send ENABLE pin
(SEN) (pin 29) is used as an indication of the ability of the
external device to receive data. The condition of the line is
sensed once every clock pulse, and if it is high, the next (or
first) byte is enabled on the next rising CLOCK 1 (pin 25)
clock edge, the corresponding byte ENABLE line goes low,
and the CHIP ENABLE / LOAD pin (pin 30) (CE/LD) goes
low for one full clock pulse only, returning high.
the Auto-Zero and wait for Run/Hold to go high. As above,
Integrate (Phase II) begins seven clock periods after the
high level is detected.
Direct Mode
When the MODE pin is left at a low level, the data outputs
[bits 1 through 8 low order byte, See Table 3 for format of
middle (-16) and high order bytes] are accessible under
control of the byte and CHIP ENABLE terminals as inputs.
These ENABLE inputs are all active low, and are provided
with pullup resistors to ensure an inactive high level when
left open. When the CHIP ENABLE input is low, taking a
byte ENABLE input low will allow the outputs of that byte to
become active (three-stated on). This allows a variety of
parallel data accessing techniques to be used. The timing
requirements for these outputs are shown under AC
Specifications and Table 1.
On the next falling CLOCK 1 clock pulse edge, if SEN
remains high, or after it goes high again, the byte output
lines will be put in the high impedance state (or three-stated
off). One half pulse later, the byte ENABLE pin will be
cleared high, and (unless finished) the CE/LD and the next
byte ENABLE pin will go low. This will continue until all three
(2 in the case of the 14-bit device) bytes have been sent.
The bytes are individually put into the low impedance state
i.e.: three-stated on during most of the time that their byte
ENABLE pin is (active) low. When receipt of the last byte
has been acknowledged by a high SEN, the handshake
mode will be cleared, re-enabling data latching from conversion, and recognizing the condition of the MODE pin again.
The byte and CHIP ENABLE will be three-stated off, if
MODE is low, but held by their (weak) pullups. These timing
relationships are illustrated in Figures 11, 12, and 13, and
Table 2.
It should be noted that these control inputs are asynchronous with respect to the converter clock - the data may be
accessed at any time. Thus it is possible to access the data
while it is being updated, which could lead to scrambled
data. Synchronizing the access of data with the conversion
cycle by monitoring the STATUS output will prevent this.
Data is never updated while STATUS is low. Also note the
potential bus conflict described under “Initial Clear Circuitry”.
Handshake Mode
Figure 11 shows the sequence of the output cycle with SEN
held high. The handshake mode (Internal MODE high) is
entered after the data latch pulse (since MODE remains high
the CE/LD, LBEN, MBEN and HBEN terminals are active as
outputs). The high level at the SEN input is sensed on the
same high to low internal clock edge. On the next to high
internal clock edge, the CE/LD and the HBEN outputs
assume a low level and the high-order byte (POL and OR,
and except for -16, Bits 9 - 14) outputs are enabled. The
CE/LD output remains low for one full internal clock period
only, the data outputs remain active for 11/2 internal clock
periods, and the high byte ENABLE remains low for two
clock periods. Thus the CE/LD output low level or low to high
edge may be used as a synchronizing signal to ensure valid
data, and the byte ENABLE as an output may be used as a
byte identification flag. With SEN remaining high the converter completes the output cycle using CE/LD, MBEN and
LBEN while the remaining byte outputs (see Table 3) are
activated. The handshake mode is terminated when all bytes
are sent (3 for -16, 2 for -14).
The handshake output mode is provided as an alternative
means of interfacing the ICL7104 to digital systems, where
the A/D converter becomes active in controlling the flow of
data instead of passively responding to chip and byte
ENABLE inputs. This mode is specifically designed to allow
a direct interface between the ICL7104 and industry-standard UARTs (such as the Intersil CMOS UARTs, IM6402/3)
with no external logic required. When triggered into the
handshake mode, the ICL7104 provides all the control and
flag signals necessary to sequence the three (ICL7106-16)
or two (ICL7104-14) bytes of data into the UART and initiate
their transmission in serial form. This greatly eases the task
and reduces the cost of designing remote data acquisition
stations using serial data transmission to minimize the
number of lines to the central controlling processor.
Entry into the handshake mode will occur if either of two
conditions are fulfilled; first, if new data is latched (i.e., a
conversion is completed) while MODE pin (pin 27) is high, in
which case entry occurs at the end of the latch cycle; or
secondly, if the MODE pin goes from low to high, when entry
will occur immediately (if new data is being latched, entry is
delayed to the end of the latch cycle). While in the
handshake mode, data latching is inhibited, and the MODE
pin is ignored. (Note that conversion cycles will continue in
the normal manner). This allows versatile initiation of handshake operation without danger of false data generation; if
the MODE pin is held high, every conversion (other than
those completed during handshake operations) will start a
new handshake operation, while if the MODE pin is pulsed
high, handshake operations can be obtained “on demand.”
Figure 12 shows an output sequence where the SEN input is
used to delay portions of the sequence, or handshake, to
ensure correct data transfer. This timing diagram shows the
relationships that occur using an industry-standard IM6402/3
CMOS UART to interface to serial data channels. In this
interface, the SEN input to the ICL7104 is driven by the
TBRE (Transmitter Buffer Register Empty) output of the
UART, and the CE/LD terminal of the ICL7104 drives the
TBRL (Transmitter Buffer Register Load) input to the UART.
The data outputs are paralleled into the eight Transmitter
Buffer Register inputs.
When the converter enters the handshake mode, or when
Assuming the UART Transmitter Buffer Register is empty,
14
ICL7104
LBEN. One-half internal clock later, the handshake mode will
be cleared, and the chip and byte ENABLE terminals return
high and stay active (as long as MODE stays high).
the SEN input will be high when the handshake mode is
entered after new data is stored. The CE/LD and HBEN terminals will go low after SEN is sensed, and the high order
byte outputs become active. When CE/LD goes high at the
end of one clock period, the high order byte data is clocked
into the UART Transmitter Buffer Register. The UART TBRE
output will now go low, which halts the output cycle with the
HBEN output low, and the high order byte outputs active.
When the UART has transferred the data to the Transmitter
Register and cleared the Transmitter Buffer Register, the
TBRE returns high. On the next ICL7104 internal clock high
to low edge, the high order byte outputs are disabled, and
one-half internal clock later, the HBEN output returns high.
At the same time, the CE/LD and MBEN (-16) or LBEN outputs go low, and the corresponding byte outputs become
active. Similarly, when the CE/LD returns high at the end of
one clock period, the enabled data is clocked into the UART
Transmitter Buffer Register, and TBRE again goes low.
When TBRE returns to a high it will be sensed on the next
ICL7104 internal clock high to low edge, disabling the data
outputs. For the 16-bit device, the sequence is repeated for
With the MODE input remaining high as in these examples,
the converter will output the results of every conversion
except those completed during a handshake operation. By
triggering the converter into handshake mode with a low to
high edge on the MODE input, handshake output sequences
may be performed on demand. Figure 13 shows a
handshake output sequence triggered by such an edge. In
addition, the SEN input is shown as being low when the converter enters handshake mode. In this case, the whole output sequence is controlled by the SEN input, and the
sequence for the first (high order) byte is similar to the
sequence for the other bytes. This diagram also shows the
output sequence taking longer than a conversion cycle. Note
that the converter still makes conversions, with the STATUS
output and Run/Hold input functioning normally. The only
difference is that new data will not be latched when in
handshake mode, and is therefore lost.
ZERO-CROSSING OCCURS
INTEGRATOR OUTPUT
ZERO-CROSSING DETECTED
FOR -16 MBEN SEQUENCE INSERTED HERE
INTERNAL CLOCK
INTERNAL LATCH
STATUS OUTPUT
MODE INPUT
INTERNAL MODE
UART
NORM
SEN
SENSED
SEN
SENSED
TERMINATES
UART MODE
SEN INPUT
CE/LOAD
HBEN
HIGH BYTE DATA
DATA VALID
MODE LOW NOT IN HANDSHAKE MODE
DISABLES OUTPUTS CE/LD, HBEN, MBEN, LBEN
LBEN
LOW BYTE DATA
LBEN
LOW BYTE DATA
DATA VALID
MODE HIGH ACTIVATES
CE/LD, HBEN, LBEN
DON’T CARE
DATA VALID
THREE-STATE HIGH IMPEDANCE
FIGURE 11. HANDSHAKE WITH SEN HELD POSITIVE
15
THREE-STATE WITH PULLUP
ICL7104
ZERO-CROSSING OCCURS
INTEGRATOR
OUTPUT
ZERO-CROSSING DETECTED
INTERNAL
CLOCK
INTERNAL
LATCH
STATUS
OUTPUT
MODE
INPUT
INTERNAL
MODE
SEN INPUT
(UART TBRE)
CE/LOAD
(UART TBRL)
HBEN
UART
NORM
HIGH BYTE
DATA
DATA VALID
MBEN
MIDDLE
BYTE DATA
DATA VALID
LBEN
LOW BYTE
DATA
DATA VALID
DON’T CARE
THREE-STATE HIGH IMPEDANCE
FIGURE 12. HANDSHAKE - TYPICAL UART INTERFACE TIMING
16
ICL7104
ZERO-CROSSING OCCURS
POSITIVE TRANSITION
CAUSES ENTRY INTO
UART MODE
ZERO-CROSSING DETECTED
INTERNAL
CLOCK
INTERNAL
LATCH
LATCH PULSE INHIBITED
IN UART MODE
STATUS
OUTPUT
MODE
INPUT
INTERNAL UART
MODE NORM
STATUS OUTPUT UNAFFECTED
BY UART MODE
DEINT PHASE III
SEN INPUT
CE/LOAD
AS OUTPUT
HBEN
HIGH BYTE
DATA
DATA VALID
MBEN
MIDDLE
BYTE DATA
DATA VALID
LBEN
LOW BYTE
DATA
DATA VALID
DON’T CARE
THREE-STATE HIGH IMPEDANCE
THREE-STATE WITH PULLUP
FIGURE 13. HANDSHAKE TRIGGERED BY MODE
Initial Clear Circuitry
The internal logic of the 7104 is supplied by an internal
regulator between V++ and Digital Ground. The regulator
includes a low-voltage detector that will clear various
registers. This is intended to ensure that on initial power-up,
the control logic comes up in Auto-Zero, with the 2nd, 3rd,
and 4th MSB bits cleared, and the “mode” F/F cleared (i.e.,
in “direct” mode). This, however, will also clear these registers if the supply voltage “glitches” to a low enough value.
Additionally, if the supply voltage comes up too fast, this
clear pulse may be too narrow for reliable clearing. In general, this is not a problem, but if the UART internal “MODE”
F/F should come up set, the byte and chip ENABLE lines will
become active outputs. In many systems this could lead to
bus conflicts, especially in non-handshake systems. In any
case, SEN should be high (held high for non-handshake systems) to ensure that the MODE F/F will be cleared as fast as
possible (see Figure 11 for timing). For these and other
reasons, adequate supply bypass is recommended.
25
24
26
CLOCK
1
CLOCK
2
R
C
CLOCK
3
fOSC = 0.45/RC
NOTE: Clock 3 has the same output drive as the bit outputs.
FIGURE 14. RC OSCILLATOR (ICL7104-14 ONLY)
As a result of pin count limitations, the ICL7104-16 has only
CLOCK 1 and CLOCK 2 available, and cannot be used as
an RC oscillator. The internal clock will correspond to the
inverse of the signal on CLOCK 2. Figure 15 shows a crystal
oscillator circuit, which can be used with both 7104 versions.
If an external clock is to be used, it should be applied to
CLOCK 1. This internal clock will correspond to the signal
applied to this pin.
Oscillator
The ICL7104-14 is provided with a versatile three terminal
oscillator to generate the internal clock. The oscillator may
be overdriven, or may be operated as an RC or crystal
oscillator.
V+
Figure 14 shows the oscillator configured for RC operation.
The internal clock will be of the same frequency and phase
as the voltage on the CLOCK 3 pin. The resistor and
capacitor should be connected as shown. The circuit will
oscillate at a frequency given by f = 0.45/RC. A 50 - 100kΩ
resistor is recommended for useful ranges of frequency. For
optimum 60Hz line rejection, the capacitor value should be
chosen such that 32768 (-16), 8192 (-14) clock periods is
close to an integral multiple of the 60Hz period.
25
CLOCK
1
26
CLOCK
2
†
†CAPACITOR VALUE
DEPENDS ON CRYSTAL
TYP 0-30pF
CRYSTAL
FIGURE 15. CRYSTAL OSCILLATOR
17
ICL7104
Power Supply Sequencing
digital loads are not fed into the analog ground line. A recommended connection sequence for the ground lines is
shown in Figure 16.
Because of the nature of the CMOS process used to
fabricate the ICL7104, and the multiple power supplies
used, there are certain conditions of these supplies under
which a disabling and potentially damaging SCR action can
occur. All of these conditions involve the V+ supply (Norm
+5V) being more positive than the V++ supply. If there is
any possibility of this occurring during start-up, shut down,
under transient conditions during operation, or when inserting a PC board into a “hot” socket, etc., a diode should be
placed between V+ and V++ to prevent it. A germanium or
Schottky rectifier diode would be best, but in most cases a
silicon rectifier is adequate.
Application Notes
Some application notes that may be found useful are listed
here:
NOTE #
AN016
“Selecting A/D Converters”, by Dave Fullagar
AN017
“The Integrating A/D Converter”, by Lee Evans
AN018
“Do’s and Don’ts of Applying A/D Converters,” by
Peter Bradshaw and Skip Osgood
AN030
“Building a Battery-Operated Auto Ranging DVM
with the ICL7106”
Analog and Digital Grounds
Extreme care must be taken to avoid ground loops in the
layout of ICL7104 circuits, especially in 16-bit and high sensitivity circuits. It is most important that return currents from
REF
VOLTAGE
BUFF
OUT
+
VIN
-
I/P
FILTER
CAP
PIN 35
ICL7104
AN GND
CAZ
BUFF
-IN
(IF USED)
DESCRIPTION
EXTERNAL
REFERENCE
(IF USED)
VREF
8068 PIN 2
COMP
DIGITAL
LOGIC
DIG GND
ICL7104
PIN 2
+5V SUPPLY BYPASS CAPACITOR(S)
FIGURE 1. GROUNDING SEQUENCE
IC L7104 - 14
IC L7104 - 16
-15V
BOARD
EDGE
DEVICE PIN
AUTOZERO
(COUNT)
24,576 - 8,193
98,304 - 32,769
+15V
PIN 35
ICL7104
AN GND
INTEGRATE
(FIXED COUNT)
8192
32768
DEINTEGRATE
(COUNT)
0 - 16383
0 - 65535
CONVERSION T IME (IN CONTINUOUS MODE):
32,768 † t O SC (7104 - 14)
131,072
† t O SC (7104 - 16)
18
SUPPLY
RETURN
ICL7104
ICL7104 with ICL8052/8068 Integrating A/D Converter Equations
• Oscillator
CRYSTAL or RC (RC on -14 Part Only)
fOSC (Typ) 200kHz
fOSC = 0.45/RC (ICL7104-14 Only)
COSC > 50pF and ROSC > 50K
VIN
Count = 32768 × --------------- (7104-16)
V R EF
• Oscillator Period
tOSC = 1/fOSC
• Integration Clock Frequency
V++ = +15V
V- = -15V
V+ = +5V
VREF ≅ 1.75V
If VREF not used, float output pin.
fCLOCK = fOSC
• Integration Period
tINT = 8192 x tOSC (7104-14)
tINT = 32768 x tOSC (7104-16)
• Auto Zero Capacitor Values
• 60/50Hz Rejection Criterion
0.01µF < C AZ < 1µF
tINT/t60Hz or tINT/t50Hz = Integer
• Reference Capacitor Value
• Optimum Integration Current
• C REF = (Buffer Gain) x C AZ
IINT = 20µA
• Full Scale Analog Input Voltage
VINFS (Typ) = 200mV to 2V = 2V REF
• Integrate Resistor
( BufferG ain ) × VIN FS
R I NT = ------------------------------------------------------------II NT
• Integrate Capacitor
( tIN T ) ( I I NT )
C INT = -------------------------------VIN T
• Integrator Output Voltage
( tIN T ) ( I I NT )
VINT = -------------------------------C IN T
VINT (Typ) = 9V
• Output Count
V IN
Count = 8192 × --------------- (7104-14)
VR EF
• Output Type:
Binary Amplitude with Polarity and Overrange Bits.
• Power Supply: ±15V, +5V
19