INTERSIL HI1-574AKD-5

HI-574A, HI-674A
TM
Data Sheet
June 2001
Complete, 12-Bit A/D Converters with
Microprocessor Interface
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File Number
3096.5
Features
• Complete 12-Bit A/D Converter with Reference and Clock
The HI-X74(A) is a complete 12-bit, Analog-to-Digital
Converter, including a +10V reference clock, three-state
outputs and a digital interface for microprocessor control.
Successive approximation conversion is performed by two
monolithic dice housed in a 28 lead package. The bipolar
analog die features the Intersil Dielectric Isolation process,
which provides enhanced AC performance and freedom
from latch-up.
Custom design of each IC (bipolar analog and CMOS digital)
has yielded improved performance over existing versions of
this converter. The voltage comparator features high PSRR
plus a high speed current-mode latch, and provides precise
decisions down to 0.1 LSB of input overdrive. More than 2X
reduction in noise has been achieved by using current
instead of voltage for transmission of all signals between the
analog and digital ICs. Also, the clock oscillator is current
controlled for excellent stability over temperature.
• Full 8-Bit, 12-Bit or 16-Bit Microprocessor Bus Interface
• Bus Access Time . . . . . . . . . . . . . . . . . . . . . . . . . . . 150ns
• No Missing Codes Over Temperature
• Minimal Setup Time for Control Signals
• Fast Conversion Times
- HI-574A (Max) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 25µs
- HI-674A (Max) . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15µs
• Low Noise, via Current-Mode Signal Transmission
Between Chips
• Byte Enable/Short Cycle (AO Input)
- Guaranteed Break-Before-Make Action, Eliminating Bus
Contention During Read Operation. Latched by Start
Convert Input (To Set the Conversion Length)
• Supply Voltage . . . . . . . . . . . . . . . . . . . . . . ±12V to ±15V
The HI-X74(A) offers standard unipolar and bipolar input
ranges, laser trimmed for specified linearity, gain and offset
accuracy. The low noise buried zener reference circuit is
trimmed for minimum temperature coefficient.
Applications
Power requirements are +5V and ±12V to ±15V, with typical
dissipation of 385mW (HI-574A/674A) at 12V.
• Process Control Systems
• Military and Industrial Data Acquisition Systems
• Electronic Test and Scientific Instrumentation
Pinout
(PDIP, SBDIP)
TOP VIEW
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dem
1
+5V SUPPLY, VLOGIC
1
28 STATUS, STS
DATA MODE SEL, 12/8
2
27 DB11
CHIP SEL, CS
3
26 DB10
BYTE ADDR/SHORT
CYCLE, AO
4
25 DB9
READ/CONVERT, R/C
5
24 DB8
CHIP ENABLE, CE
6
23 DB7
+12V/+15V SUPPLY, VCC
7
22 DB6
+10V REF, REF OUT
8
21 DB5
ANALOG
COMMON, AC
MSB
DIGITAL
DATA
OUTPUTS
9
20 DB4
REFERENCE INPUT 10
19 DB3
-12V/-15V SUPPLY, VEE 11
18 DB2
BIPOLAR OFFSET 12
BIP OFF
17 DB1
10V INPUT 13
16 DB0
20V INPUT 14
15 DIG COMMON,
DC
LSB
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 Americas Inc. | Copyright © Intersil Americas Inc. 2001
HI-574A, HI-674A
Ordering Information
INL
TEMPERATURE RANGE
(oC)
HI3-574AJN-5
±1.0 LSB
0 to 75
28 Ld PDIP
E28.6
HI3-574AKN-5
±0.5 LSB
0 to 75
28 Ld PDIP
E28.6
HI1-574AJD-5
±1.0 LSB
0 to 75
28 Ld SBDIP
D28.6
HI1-574AKD-5
±0.5 LSB
0 to 75
28 Ld SBDIP
D28.6
HI1-574ASD-2
±1.0 LSB
-55 to 125
28 Ld SBDIP
D28.6
HI1-574ATD-2
±0.5 LSB
-55 to 125
28 Ld SBDIP
D28.6
HI1-574ASD/883
±1.0 LSB
-55 to 125
28 Ld SBDIP
D28.6
HI1-574ATD/883
±0.5 LSB
-55 to 125
28 Ld SBDIP
D28.6
HI3-674AJN-5
±1.0 LSB
0 to 75
28 Ld PDIP
E28.6
HI3-674AKN-5
±0.5 LSB
0 to 75
28 Ld PDIP
E28.6
HI1-674AJD-5
±1.0 LSB
0 to 75
28 Ld SBDIP
D28.6
HI1-674AKD-5
±0.5 LSB
0 to 75
28 Ld SBDIP
D28.6
HI1-674ASD-2
±1.0 LSB
-55 to 125
28 Ld SBDIP
D28.6
HI1-674ATD/883
±0.5 LSB
-55 to 125
28 Ld SBDIP
D28.6
PART NUMBER
PACKAGE
PKG. NO.
Functional Block Diagram
BIT OUTPUTS
MSB
12/8
CS
AO
LSB
NIBBLE A (NOTE)
CONTROL
LOGIC
NIBBLE B (NOTE)
NIBBLE C (NOTE)
THREE-STATE BUFFERS AND CONTROL
R/C
CE
VLOGIC
POWER-UP RESET
DIGITAL
COMMON
12 BITS
CLK
STS
SAR
OSCILLATOR
STROBE
DIGITAL CHIP
ANALOG CHIP
12 BITS
VCC
VEE
COMP
DAC
-
+
VREF IN
10K
VREF OUT
5K
+
+10V
REF
-
5K
2.5K
10K
5K
ANALOG
COMMON
NOTE: “Nibble” is a 4-bit digital word.
2
BIP
OFF
20V
10V
INPUT INPUT
HI-574A, HI-674A
Absolute Maximum Ratings
Thermal Information
Supply Voltage
VCC to Digital Common . . . . . . . . . . . . . . . . . . . . . . 0V to +16.5V
VEE to Digital Common . . . . . . . . . . . . . . . . . . . . . . . 0V to -16.5V
VLOGIC to Digital Common . . . . . . . . . . . . . . . . . . . . . . 0V to +7V
Analog Common to Digital Common. . . . . . . . . . . . . . . . . . . . . . ±1V
Control Inputs
(CE, CS, AO, 12/8, R/C) to Digital Common . . -0.5V to VLOGIC +0.5V
Analog Inputs
(REFIN, BIPOFF, 10VIN) to Analog Common . . . . . . . . . . ±16.5V
20VIN to Analog Common . . . . . . . . . . . . . . . . . . . . . . . . . . ±24V
REFOUT . . . . . Indefinite Short To Common, Momentary Short To VCC
Thermal Resistance (Typical, Note 1)
θJA (oC/W) θJC ( oC/W)
SBDIP Package. . . . . . . . . . . . . . . . . .
55
18
PDIP Package . . . . . . . . . . . . . . . . . . .
60
N/A
Maximum Junction Temperature
PDIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150oC
SBDIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 175oC
Maximum Storage Temperature Range
PDIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40oC to 85oC
SBDIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . -65oC to 150oC
Maximum Lead Temperature (Soldering, 10s) . . . . . . . . . . . . 300oC
Die Characteristics
Operating Conditions
Temperature Range
HI3-574Axx-5, HI1-674Axx-5 . . . . . . . . . . . . . . . . . . . 0oC to 75oC
HI1-574AxD-2, HI1-674AxD-2 . . . . . . . . . . . . . . . -55oC to 125oC
Transistor Count
HI-574A, HI-674A . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .1117
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.
NOTE:
1. θJA is measured with the component mounted on a low effective thermal conductivity test board in free air. See Tech Brief TB379 for details.
DC and Transfer Accuracy Specifications Typical at 25oC with VCC = +15V or +12V, VLOGIC = +5V, VEE = -15V or -12V,
Unless Otherwise Specified
TEMPERATURE RANGE
-5 (0oC to 75oC)
PARAMETER
J SUFFIX
K SUFFIX
UNITS
12
12
Bits
±1
±1/2
LSB
±1
±1/2
LSB
25oC
12
12
Bits
TMIN to TMAX
11
12
Bits
±2
±1.5
LSB
±4
±4
LSB
±0.15
±0.1
% of FS
25oC (Max), With Fixed 50Ω Resistor From REF OUT To REF IN
(Adjustable to Zero)
±0.25
±0.25
% of FS
TMIN to TMAX (No Adjustment At 25oC)
±0.475
±0.375
% of FS
TMIN to TMAX (With Adjustment To Zero 25oC)
±0.22
±0.12
% of FS
Unipolar Offset
±2
±1
LSB
Bipolar Offset
±2
±1
LSB
Full Scale Calibration
±9
±2
LSB
DYNAMIC CHARACTERISTICS
Resolution (Max)
Linearity Error
25oC (Max)
0oC to 75oC (Max)
Max Resolution For Which No Missing Codes Is Guaranteed
Unipolar Offset (Max)
Adjustable to Zero
Bipolar Offset (Max)
VIN = 0V (Adjustable to Zero)
VIN = -10V
Full Scale Calibration Error
Temperature Coefficients
Guaranteed Max Change, TMIN to TMAX (Using Internal Reference)
3
HI-574A, HI-674A
DC and Transfer Accuracy Specifications Typical at 25oC with VCC = +15V or +12V, VLOGIC = +5V, VEE = -15V or -12V,
Unless Otherwise Specified (Continued)
TEMPERATURE RANGE
-5 (0oC to 75oC)
PARAMETER
J SUFFIX
K SUFFIX
UNITS
±2
±1
LSB
±1/2
±1/2
LSB
±2
±1
LSB
Power Supply Rejection Max Change In Full Scale Calibration
+13.5V < VCC < +16.5V or +11.4V < VCC < +12.6V
+4.5V < VLOGIC < +5.5V
-16.5V < VEE < -13.5V or -12.6V < VEE < -11.4V
ANALOG INPUTS
Input Ranges
Bipolar
-5 to +5 (Note 3)
V
-10 to +10 (Note 4)
V
0 to +10 (Note 3)
V
0 to +20 (Note 4)
V
10V Span
5K, ±25%
Ω
20V Span
10K, ±25%
Ω
+4.5 to +5.5
V
VCC
+11.4 to +16.5
V
VEE
-11.4 to -16.5
V
ILOGIC
7 Typ, 15 Max
mA
ICC +15V Supply
11 Typ, 15 Max
mA
IEE -15V Supply
21 Typ, 28 Max
mA
±15V, +5V
515 Typ, 720 Max
mW
±12V, +5V
385 Typ
mW
+10.00 ±0.05 Max
V
2.0 Max
mA
Unipolar
Input Impedance
POWER SUPPLIES
Operating Voltage Range
VLOGIC
Operating Current
Power Dissipation
Internal Reference Voltage
TMIN to TMAX
Output Current, Available For External Loads (External Load Should Not
Change During Conversion).
8
DC and Transfer Accuracy SpecificationsTypical at 25oC with VCC = +15V or +12V, VLOGIC = +5V, VEE = -15V or -12V,
Unless Otherwise Specified (Continued)
TEMPERATURE RANGE
-2 (-55oC to 125oC)
PARAMETER
S SUFFIX
T SUFFIX
UNITS
12
12
Bits
DYNAMIC CHARACTERISTICS
Resolution (Max)
4
HI-574A, HI-674A
DC and Transfer Accuracy SpecificationsTypical at 25oC with VCC = +15V or +12V, VLOGIC = +5V, VEE = -15V or -12V,
Unless Otherwise Specified (Continued)
TEMPERATURE RANGE
-2 (-55oC to 125oC)
S SUFFIX
T SUFFIX
UNITS
25oC
±1
±1/2
LSB
-55oC to 125oC (Max)
±1
±1
LSB
25oC
12
12
Bits
TMIN to TMAX
11
12
Bits
±2
±1.5
LSB
±4
±4
LSB
±0.15
±0.1
% of FS
25oC (Max), With Fixed 50Ω Resistor From REF OUT To REF IN
(Adjustable To Zero)
±0.25
±0.25
% of FS
TMIN to TMAX (No Adjustment At 25oC)
±0.75
±0.50
% of FS
TMIN to TMAX (With Adjustment To Zero At 25oC)
±0.50
±0.25
% of FS
Unipolar Offset
±2
±1
LSB
Bipolar Offset
±2
±2
LSB
Full Scale Calibration
±20
±10
LSB
±2
±1
LSB
±1/2
±1/2
LSB
±2
±1
LSB
PARAMETER
Linearity Error
Max Resolution For Which No Missing Codes Is Guaranteed
Unipolar Offset (Max)
Adjustable to Zero
Bipolar Offset (Max)
VIN = 0V (Adjustable to Zero)
VIN = -10V
Full Scale Calibration Error
Temperature Coefficients
Guaranteed Max Change, TMIN to TMAX (Using Internal Reference)
Power Supply Rejection Max Change In Full Scale Calibration
+13.5V < VCC < +16.5V or +11.4V < VCC < +12.6V
+4.5V < VLOGIC < +5.5V
-16.5V < VEE < -13.5V or -12.6V < VEE < -11.4V
ANALOG INPUTS
Input Ranges
Bipolar
-5 to +5 (Note 3)
V
-10 to +10 (Note 4)
V
0 to +10 (Note 3)
V
0 to +20 (Note 4)
V
10V Span
5K, ±25%
Ω
20V Span
10K, ±25%
Ω
+4.5 to +5.5
V
VCC
+11.4 to +16.5
V
VEE
-11.4 to -16.5
V
Unipolar
Input Impedance
POWER SUPPLIES
Operating Voltage Range
VLOGIC
5
HI-574A, HI-674A
DC and Transfer Accuracy SpecificationsTypical at 25oC with VCC = +15V or +12V, VLOGIC = +5V, VEE = -15V or -12V,
Unless Otherwise Specified (Continued)
TEMPERATURE RANGE
-2 (-55oC to 125oC)
S SUFFIX
PARAMETER
T SUFFIX
UNITS
Operating Current
7 Typ, 15 Max
mA
ICC +15V Supply
11 Typ, 15 Max
mA
IEE -15V Supply
21 Typ, 28 Max
mA
±15V, +5V
515 Typ, 720 Max
mW
±12V, +5V
385 Typ
mW
+10.00 ±0.05 Max
V
2.0 Max
mA
ILOGIC
Power Dissipation
Internal Reference Voltage
TMIN to TMAX
Output current, available for external loads (external load should not
change during conversion).
Digital Specifications All Models, Over Full Temperature Range
PARAMETER
MIN
TYP
MAX
Logic “1”
+2.4V
-
+5.5V
Logic “0”
-0.5V
-
+0.8V
Current
-
±0.1µA
±5µA
Capacitance
-
5pF
-
-
-
+0.4V
Logic “1” (ISOURCE - 500µA)
+2.4V
-
-
Logic “1” (ISOURCE - 10µA)
+4.5V
-
-
Leakage (High-Z State, DB11-DB0 Only)
-
±0.1µA
±5µA
Capacitance
-
5pF
-
Logic Inputs (CE, CS, R/C, AO,12/8)
Logic Outputs (DB11-DB0, STS)
Logic “0” (ISINK - 1.6mA)
Timing Specifications (HI-574A) 25oC, Note 2, Unless Otherwise Specified
SYMBOL
PARAMETER
MIN
TYP
MAX
UNITS
-
-
200
ns
CONVERT MODE
tDSC
STS Delay from CE
tHEC
CE Pulse Width
50
-
-
ns
tSSC
CS to CE Setup
50
-
-
ns
tHSC
CS Low During CE High
50
-
-
ns
tSRC
R/C to CE Setup
50
-
-
ns
tHRC
R/C Low During CE High
50
-
-
ns
tSAC
AO to CE Setup
0
-
-
ns
tHAC
AO Valid During CE High
50
-
-
ns
12-Bit Cycle TMIN to TMAX
15
20
25
µs
8-Bit Cycle TMIN to TMAX
10
13
17
µs
tC
Conversion Time
6
HI-574A, HI-674A
Timing Specifications (HI-574A) 25oC, Note 2, Unless Otherwise Specified (Continued)
SYMBOL
PARAMETER
MIN
TYP
MAX
UNITS
-
75
150
ns
25
-
-
ns
-
100
150
ns
READ MODE
tDD
Access Time from CE
tHD
Data Valid After CE Low
tHL
Output Float Delay
tSSR
CS to CE Setup
50
-
-
ns
tSRR
R/C to CE Setup
0
-
-
ns
tSAR
AO to CE Setup
50
-
-
ns
tHSR
CS Valid After CE Low
0
-
-
ns
tHRR
R/C High After CE Low
0
-
-
ns
tHAR
AO Valid After CE Low
50
-
-
ns
STS Delay After Data Valid
300
-
1200
ns
MIN
TYP
MAX
UNITS
-
-
200
ns
tHS
Timing Specifications (HI-674A) 25oC, Note 2, Unless Otherwise Specified
SYMBOL
PARAMETER
CONVERT MODE
tDSC
STS Delay from CE
tHEC
CE Pulse Width
50
-
-
ns
tSSC
CS to CE Setup
50
-
-
ns
tHSC
CS Low During CE High
50
-
-
ns
tSRC
R/C to CE Setup
50
-
-
ns
tHRC
R/C Low During CE High
50
-
-
ns
tSAC
AO to CE Setup
0
-
-
ns
tHAC
AO Valid During CE High
50
-
-
ns
12-Bit Cycle TMIN to TMAX
9
12
15
µs
8-Bit Cycle TMIN to TMAX
6
8
10
µs
-
75
150
ns
25
-
-
ns
-
100
150
ns
tC
Conversion Time
READ MODE
tDD
Access Time from CE
tHD
Data Valid After CE Low
tHL
Output Float Delay
tSSR
CS to CE Setup
50
-
-
ns
tSRR
R/C to CE Setup
0
-
-
ns
tSAR
AO to CE Setup
50
-
-
ns
tHSR
CS Valid After CE Low
0
-
-
ns
tHRR
R/C High After CE Low
0
-
-
ns
tHAR
AO Valid After CE Low
50
-
-
ns
STS Delay After Data Valid
25
-
850
ns
tHS
NOTES:
2. Time is measured from 50% level of digital transitions. Tested with a 50pF and 3kΩ load.
3. For the “10V Input”, Pin 13.
4. For the “20V Input”, Pin 14.
7
HI-574A, HI-674A
Pin Descriptions
DESCRIPTION
The HI-X74AK grade is guaranteed for maximum nonlinearity
of ±1/2 LSB. For this grade, this means that an analog value
which falls exactly in the center of a given code width will result
in the correct digital output code. Values nearer the upper or
lower transition of the code width may produce the next upper
or lower digital output code. The HI-X74AJ is guaranteed to ±1
LSB max error. For this grade, an analog value which falls
within a given code width will result in either the correct code for
that region or either adjacent one.
PIN
SYMBOL
1
VLOGIC
2
12/8
Data Mode Select - Selects between 12bit and 8-bit output modes.
3
CS
Chip Select - Chip Select high disables
the device.
4
AO
Byte Address/Short Cycle - See Table 1
for operation.
5
R/C
Read/Convert - See Table 1 for operation.
6
CE
Chip Enable - Chip Enable low disables
the device.
7
VCC
8
REF OUT
+10V Reference
9
AC
Analog Common
10
REF IN
Reference Input
11
VEE
12
BIP OFF
Bipolar Offset
13
10V Input
10V Input - Used for 0V to 10V and -5V to
+5V input ranges.
14
20V Input
20V Input - Used for 0V to 20V and -10V to
+10V input ranges.
15
DC
Digital Common
16
DB0
Data Bit 0 (LSB)
17
DB1
Data Bit 1
18
DB2
Data Bit 2
19
DB3
Data Bit 3
20
DB4
Data Bit 4
21
DB5
Data Bit 5
22
DB6
Data Bit 6
23
DB7
Data Bit 7
24
DB8
Data Bit 8
25
DB9
Data Bit 9
26
DB10
Data Bit 10
27
DB11
Data Bit 11 (MSB)
Full Scale Calibration Error
28
STS
Status Bit - Status high implies a conversion
is in progress.
The last transition (from 1111 1111 1110 to 1111 1111
1111) should occur for an analog value 11/2 LSB below the
nominal full scale (9.9963V for 10.000V full scale). The full
scale calibration error is the deviation of the actual level at
the last transition from the ideal level. This error, which is
typically 0.05 to 0.1% of full scale, can be trimmed out as
shown in Figures 2 and 3. The full scale calibration error
over temperature is given with and without the initial error
trimmed out. The temperature coefficients for each grade
indicate the maximum change in the full scale gain from the
initial value using the internal 10V reference.
Logic supply pin (+5V)
Positive Supply (+12V/+15V)
Negative Supply (-12V/-15V).
Definitions of Specifications
Linearity Error
Linearity error refers to the deviation of each individual code
from a line drawn from “zero” through “full scale”. The point
used as “zero” occurs 1/2 LSB (1.22mV for 10V span) before
the first code transition (all zeros to only the LSB “on”). “Full
scale” is defined as a level 11/2 LSB beyond the last code
transition (to all ones). The deviation of a code from the true
straight line is measured from the middle of each particular
code.
8
Note that the linearity error is not user-adjustable.
Differential Linearity Error (No Missing Codes)
A specification which guarantees no missing codes requires
that every code combination appear in a monotonic
increasing sequence as the analog input level is increased.
Thus every code must have a finite width. For the HI-X74AK
grade, which guarantees no missing codes to 12-bit
resolution, all 4096 codes must be present over the entire
operating temperature ranges. The HI-X74AJ grade
guarantees no missing codes to 11-bit resolution over
temperature; this means that all code combinations of the
upper 11 bits must be present; in practice very few of the 12bit codes are missing.
Unipolar Offset
The first transition should occur at a level 1/2 LSB above analog
common. Unipolar offset is defined as the deviation of the
actual transition from that point. This offset can be adjusted as
discussed on the following pages. The unipolar offset
temperature coefficient specifies the maximum change of the
transition point over temperature, with or without external
adjustment.
Bipolar Offset
Similarly, in the bipolar mode, the major carry transition
(0111 1111 1111 to 1000 0000 0000) should occur for an
analog value 1/2 LSB below analog common. The bipolar
offset error and temperature coefficient specify the initial
deviation and maximum change in the error over
temperature.
Temperature Coefficients
The temperature coefficients for full-scale calibration,
unipolar offset, and bipolar offset specify the maximum
HI-574A, HI-674A
change from the initial (25oC) value to the value at TMIN or
TMAX .
Power Supply Rejection
The standard specifications for the HI-X74A assume use of
+5.00V and ±15.00V or ±12.00V supplies. The only effect of
power supply error on the performance of the device will be
a small change in the full scale calibration. This will result in
a linear change in all lower order codes. The specifications
show the maximum change in calibration from the initial
value with the supplies at the various limits.
Code Width
A fundamental quantity for A/D converter specifications is
the code width. This is defined as the range of analog input
values for which a given digital output code will occur. The
nominal value of a code width is equivalent to 1 least
significant bit (LSB) of the full scale range or 2.44mV out of
10V for a 12-bit ADC.
Quantization Uncertainty
Analog-to-digital converters exhibit an inherent quantization
uncertainty of ±1/2 LSB. This uncertainty is a fundamental
characteristic of the quantization process and cannot be
reduced for a converter of given resolution.
Left-Justified Data
The data format used in the HI-X74A is left-justified. This
means that the data represents the analog input as a
fraction of full-scale, ranging from 0 to 4095 . This implies a
4096
binary point to the left of the MSB.
Power Supplies
Supply voltages to the HI-X74A (+15V, -15V and +5V) must be
“quiet” and well regulated. Voltage spikes on these lines can
affect the converter’s accuracy, causing several LSBs to flicker
when a constant input is applied. Digital noise and spikes from
a switching power supply are especially troublesome. If
switching supplies must be used, outputs should be carefully
filtered to assure “quiet” DC voltage at the converter terminals.
Further, a bypass capacitor pair on each supply voltage
terminal is necessary to counter the effect of variations in
supply current. Connect one pair from pin 1 to 15 (VLOGIC
supply), one from pin 7 to 9 (V CC to Analog Common) and
one from pin 11 to 9 (VEE to Analog Common). For each
capacitor pair, a 10µF tantalum type in parallel with a 0.1µF
ceramic type is recommended.
Ground Connections
Pins 9 and 15 should be tied together at the package to
guarantee specified performance for the converter. In
addition, a wide PC trace should run directly from pin 9 to
(usually) +15V common, and from pin 15 to (usually) the +5V
Logic Common. If the converter is located some distance from
the system’s “single point” ground, make only these
connections to pins 9 and 15: Tie them together at the
package, and back to the system ground with a single path.
This path should have low resistance. (Code dependent
currents flow in the VCC , VEE and VLOGIC terminals, but not
through the HI-X74A’s Analog Common or Digital Common).
Analog Signal Source
Applying the HI-X74A
HI-574A and HI-674A
For each application of this converter, the ground
connections, power supply bypassing, analog signal source,
digital timing and signal routing on the circuit board must be
optimized to assure maximum performance. These areas
are reviewed in the following sections, along with basic
operating modes and calibration requirements.
The device chosen to drive the HI-X74A analog input will see a
nominal load of 5kΩ (10V range) or 10kΩ (20V range).
However, the other end of these input resistors may change
±400mV with each bit decision, creating abrupt changes in
current at the analog input. Thus, the signal source must
maintain its output voltage while furnishing these step changes
in load current, which occur at 1.6µs and 950ns intervals for the
HI-574A and HI-674A, respectively. This requires low output
impedance and fast settling by the signal source.
Physical Mounting and Layout Considerations
LAYOUT
Unwanted, parasitic circuit components, (L, R, and C) can
make 12-bit accuracy impossible, even with a perfect A/D
converter. The best policy is to eliminate or minimize these
parasitics through proper circuit layout, rather than try to
quantify their effects.
The recommended construction is a double-sided printed
circuit board with a ground plane on the component side.
Other techniques, such as wire-wrapping or point-to-point
wiring on vector board, will have an unpredictable effect on
accuracy.
In general, sensitive analog signals should be routed between
ground traces and kept well away from digital lines. If analog
and digital lines must cross, they should do so at right angles.
9
The output impedance of an op amp, for example, has an
open loop value which, in a closed loop, is divided by the
loop gain available at a frequency of interest. The amplifier
should have acceptable loop gain at 600kHz for use with the
HI-X74A. To check whether the output properties of a signal
source are suitable, monitor the HI-X74A’s input (pin 13 or
14) with an oscilloscope while a conversion is in progress.
Each of the twelve disturbances should subside in 1µs or
less for the HI-574A and 500ns or less for the HI-674A. (The
comparator decision is made about 1.5µs and 850ns after
each code change from the SAR for the HI-574A and
HI-674A, respectively.)
If the application calls for a Sample/Hold to precede the
converter, it should be noted that not all Sample/Holds are
compatible with the HI-574A in the manner described above.
HI-574A, HI-674A
These will require an additional wideband buffer amplifier to
lower their output impedance. A simpler solution is to use the
Intersil HA-5320 Sample/Hold, which was designed for use
with the HI-574A.
STS 28
2 12/8
CS
HIGH BITS
24-27
4 AO
MIDDLE BITS
3
20-23
OFFSET
R1
100K
5 R/C
LOW BITS
+15V
-15V
6 CE
16-19
GAIN
R2
10 REF IN
100K
8 REF OUT
100Ω
12 BIP OFF
+5V 1
0V TO +10V
13 10VIN
+15V 7
14 20VIN†
-15V 11
0V TO +20V
DIG COM 15
9 ANA
COM
† When driving the 20V (pin 14) input, minimize capacitance on pin 13.
FIGURE 1. UNIPOLAR CONNECTIONS
2 12/8
STS 28
3 CS
HIGH BITS
24-27
4 AO
MIDDLE BITS
20-23
5 R/C
LOW BITS
GAIN
10 REF IN
100Ω
8 REF OUT
100Ω
±5V
ANALOG
INPUTS
12 BIP OFF
OFFSET
13 10VIN
14 20VIN†
+5V 1
+15V 7
-15V 11
±10V
9 ANA
COM
DIG COM 15
† When driving the 20V (pin 14) input, minimize capacitance on pin 13.
FIGURE 2. BIPOLAR CONNECTIONS
10
Whether controlled by a processor or operating in the standalone mode, the HI-X74A offers four standard input ranges:
0V to +10V, 0V to +20V, ±5V and ±10V. The maximum errors
for gain and offset are listed under Specifications. If required,
however, these errors may be adjusted to zero as explained
below. Power supply and ground connections have been
discussed in an earlier section.
Refer to Figure 2. The resistors shown (see Note below)
are for calibration of offset and gain. If this is not required,
replace R2 with a 50Ω, 1% metal film resistor and remove
the network on pin 12. Connect pin 12 to pin 9. Then,
connect the analog signal to pin 13 for the 0V to 10V range,
or to pin 14 for the 0V to 20V range. Inputs to +20V (5V
over the power supply) are no problem - the converter
operates normally.
Calibration consists of adjusting the converter’s most
negative output to its ideal value (offset adjustment), then,
adjusting the most positive output to its ideal value (gain
adjustment). To understand the procedure, note that in
principle, one is setting the output with respect to the
midpoint of an increment of analog input, as denoted by
two adjacent code changes. Nominal value of an increment
is one LSB. However, this approach is impractical because
nothing “happens” at a midpoint to indicate that an
adjustment is complete. Therefore, calibration is performed
in terms of the observable code changes instead of the
midpoint between code changes.
16-19
6 CE
R2
R1
The HI-X74A is a “complete” A/D converter, meaning it is fully
operational with addition of the power supply voltages, a Start
Convert signal, and a few external components as shown in
Figure 2 and Figure 3. Nothing more is required for most
applications.
Unipolar Connections and Calibration
100Ω
ANALOG
INPUTS
Range Connections and Calibration Procedures
For example, midpoint of the first LSB increment should be
positioned at the origin, with an output code of all 0’s. To do
this, apply an input of +1/2 LSB (+1.22mV for the 10V range;
+2.44mV for the 20V range). Adjust the Offset potentiometer
R1 until the first code transition flickers between
0000 0000 0000 and 0000 0000 0001.
Next, perform a Gain Adjust at positive full scale. Again, the
ideal input corresponding to the last code change is applied.
This is 11/2 LSBs below the nominal full scale (+9.9963V for
10V range; +19.9927V for 20V range). Adjust the Gain
potentiometer R2 for flicker between codes 1111 1111 1110
and 1111 1111 1111.
Bipolar Connections and Calibration
Refer to Figure 3. The gain and offset errors listed under
Specifications may be adjusted to zero using
potentiometers R1 and R2 (see Note below). If this isn’t
required, either or both pots may be replaced by a 50Ω, 1%
metal film resistor.
HI-574A, HI-674A
Connect the Analog signal to pin 13 for a ±5V range, or to
pin 14 for a ±10V range. Calibration of offset and gain is
similar to that for the unipolar ranges as discussed above.
First apply a DC input voltage 1/2 LSB above negative full
scale (i.e., -4.9988V for the ±5V range, or -9.9976V for the
±10V range). Adjust the offset potentiometer R1 for flicker
between output codes 0000 0000 0000 and 0000 0000
0001. Next, apply a DC input voltage 11/2 LSBs below
positive full scale (+4.9963V for ±5V range; +9.9927V for
±10V range). Adjust the Gain potentiometer R2 for flicker
between codes 1111 1111 1110 and 1111 1111 1111.
NOTE: The 100Ω potentiometer R2 provides Gain Adjust for the 10V
and 20V ranges. In some applications, a full scale of 10.24V (LSB
equals 2.5mV) or 20.48V (LSB equals 5.0mV) is more convenient.
For these, replace R2 by a 50Ω, 1% metal film resistor. Then, to provide Gain Adjust for the 10.24V range, add a 200Ω potentiometer in
series with pin 13. For the 20.48V range, add a 500Ω potentiometer
in series with pin 14.
Controlling the HI-X74A
The HI-X74A includes logic for direct interface to most
microprocessor systems. The processor may take full
control of each conversion, or the converter may operate in
the “stand-alone” mode, controlled only by the R/C input.
Full control consists of selecting an 8-bit or 12-bit
conversion cycle, initiating the conversion, and reading the
output data when ready-choosing either 12 bits at once or 8
followed by 4, in a left-justified format. The five control
inputs are all TTL/CMOS-compatible: (12/8, CS, AO , R/C
and CE). Table 1 illustrates the use of these inputs in
controlling the converter’s operations. Also, a simplified
schematic of the internal control logic is shown in Figure 7.
HI-574A STAND-ALONE MODE TIMING
SYMBOL
PARAMETER
MIN
TYP
MAX UNITS
Time is measured from 50% level of digital transitions. Tested with
a 50pF and 3kΩ load.
HI-674A STAND-ALONE MODE TIMING
SYMBOL
PARAMETER
MIN
TYP
MAX UNITS
tHRL
Low R/C Pulse Width
50
-
-
ns
tDS
STS Delay from R/C
-
-
200
ns
Data Valid after R/C Low
25
-
-
ns
tHS
STS Delay after Data
Valid
25
-
850
ns
tHRH
High R/C Pulse Width
150
-
-
ns
tDDR
Data Access Time
-
-
150
ns
tHDR
Time is measured from 50% level of digital transitions. Tested with
a 50pF and 3kΩ load.
Conversion Length
A Convert Start transition (see Table 1) latches the state of
AO , which determines whether the conversion continues for
12 bits (AO low) or stops with 8 bits (AO high). If all 12 bits are
read following an 8-bit conversion, the last three LSBs will
read ZERO and DB3 will read ONE. AO is latched because it
is also involved in enabling the output buffers (see “Reading
the Output Data”). No other control inputs are latched.
TABLE 1. TRUTH TABLE FOR HI-X74A CONTROL INPUTS
CE
CS
R/C
12/8
AO
“Stand-Alone Operation”
0
X
X
X
X
None
The simplest control interface calls for a single control line
connected to R/C. Also, CE and 12/8 are wired high, CS and
AO are wired low, and the output data appears in words of
12 bits each.
X
1
X
X
X
None
↑
0
0
X
0
Initiate 12-bit conversion
↑
0
0
X
1
Initiate 8-bit conversion
The R/C signal may have any duty cycle within (and
including) the extremes shown in Figures 8 and 9. In
general, data may be read when R/C is high unless STS is
also high, indicating a conversion is in progress. Timing
parameters particular to this mode of operation are listed
below under “Stand-Alone Mode Timing”.
1
↓
0
X
0
Initiate 12-bit conversion
1
↓
0
X
1
Initiate 8-bit conversion
1
0
↓
X
0
Initiate 12-bit conversion
1
0
↓
X
1
Initiate 8-bit conversion
1
0
1
1
X
Enable 12-bit Output
1
0
1
0
0
Enable 8 MSBs Only
1
0
1
0
1
Enable 4 LSBs Plus 4 Trailing
Zeroes
HI-574A STAND-ALONE MODE TIMING
SYMBOL
PARAMETER
MIN
TYP
MAX UNITS
OPERATION
tHRL
Low R/C Pulse Width
50
-
-
ns
tDS
STS Delay from R/C
-
-
200
ns
Conversion Start
Data Valid after R/C Low
25
-
-
ns
tHS
STS Delay after Data
Valid
300
-
1200
ns
tHRH
High R/C Pulse Width
150
-
-
ns
tDDR
Data Access Time
-
-
150
ns
A conversion may be initiated as shown in Table 1 by a logic
transition on any of three inputs: CE, CS or R/C. The last of
the three to reach the correct state starts the conversion, so
one, two or all three may be dynamically controlled. The
nominal delay from each is the same, and if necessary, all
three may change state simultaneously. However, to ensure
tHDR
11
HI-574A, HI-674A
that a particular input controls the start of conversion, the
other two should be set up at least 50ns earlier. See the
HI-X74A Timing Specifications, Convert Mode.
This variety of HI-X74A control modes allows a simple
interface in most system applications. The Convert Start
timing relationships are illustrated in Figure 4.
The output signal STS indicates status of the converter by
going high only while a conversion is in progress. While STS
is high, the output buffers remain in a high impedance state
and data cannot be read. Also, an additional Start Convert
will not reset the converter or reinitiate a conversion while
STS is high.
Reading the Output Data
The 12/8 input will be tied high or low in most applications,
though it is fully TTL/CMOS-compatible. With 12/8 high, all
12 output lines become active simultaneously, for interface to
a 12-bit or 16-bit data bus. The AO input is ignored.
CS
R/C
BYTE 1
•
X
X
X
X
X
BYTE 2
X
X
X
X
tHEC
X
X
0
0
0
Further, AO may be toggled at any time without damage to
the converter. Break-before-make action is guaranteed
between the two data bytes, which assures that the outputs
strapped together in Figure 6 will never be enabled at the
same time.
A read operation usually begins after the conversion is
complete and STS is low. For earliest access to the data,
however, the read should begin no later than (tDD + tHS)
before STS goes low. See Figure 5.
CS
tSSR
tHSC
tHSR
tHRR
R/C
tHRC
AO
AO
tSAC
STS
tHAC
STS
tC
tDSC
HIGH IMPEDANCE
DB11-DB0
See HI-X74A Timing Specifications for more information.
FIGURE 3. CONVERT START TIMING
12
0
LSB
CE
tSSC
tSRC
X
MSB
The output data buffers remain in a high impedance state
until four conditions are met: R/C high, STS low, CE high and
CS low. At that time, data lines become active according to
the state of inputs 12/8 and AO . Timing constraints are
illustrated in Figure 5.
CE
With 12/8 low, the output is organized in two 8-bit bytes,
selected one at a time by AO . This allows an 8-bit data bus
to be connected as shown in Figure 6. AO is usually tied to
the least significant bit of the address bus, for storing the
HI-X74A output in two consecutive memory locations. (With
AO low, the 8 MSBs only are enabled. With AO high, 4 MSBs
are disabled, bits 4 through 7 are forced low, and the 4 LSBs
are enabled). This two byte format is considered “left justified
data,” for which a decimal (or binary!) point is assumed to the
left of byte 1:
tSRR
tSAR
tHAR
tHS
DB11-DB0
HIGH IMPEDANCE
tDD
tHD
DATA
VALID
tHL
See HI-X74A Timing Specifications for more information.
FIGURE 4. READ CYCLE TIMING
HI-574A, HI-674A
AO
ADDRESS BUS
STS 28
1
2 12/8
DB11 (MSB) 27
3
26
4 AO
25
5
24
6
23
22
7
8
DATA
BUS
HI-X74A
21
9
20
10
19
11
18
12
17
13
DB0 (LSB) 16
DIG. 15
COM.
14
FIGURE 5. INTERFACE TO AN 8-BIT DATA BUS
NIBBLE B ZERO
OVERRIDE
NIBBLE A, B
INPUT BUFFERS
12/8
NIBBLE C
READ CONTROL
CS
AO
STATUS
R/C
CE
CONVERT
EOC9
CONTROL
CURRENT
CONTROLLED
OSCILLATOR
STROBE
CLOCK
CK
D
POWER UP
RESET
Q
Q
AO LATCH
EOC13
FIGURE 6. HI-X74A CONTROL LOGIC
13
RESET
HI-574A, HI-674A
tHRL
R/C
tDS
STS
tC
tHDR
DB11-DB0
tHS
DATA
VALID
DATA
VALID
FIGURE 7. LOW PULSE FOR R/C - OUTPUTS ENABLED AFTER CONVERSION
R/C
tHRH
tDS
STS
tDDR
DB11-DB0
HIGH-Z
tHDR
DATA
VALID
tC
HIGH-Z
FIGURE 8. HIGH PULSE FOR R/C - OUTPUTS ENABLED WHILE R/C HIGH, OTHERWISE HIGH-Z
14
HI-574A, HI-674A
Die Characteristics
DIE DIMENSIONS:
PASSIVATION:
Analog: 3070mm x 4610mm
Digital: 1900mm x 4510mm
METALLIZATION:
Type: Nitride Over Silox
Nitride Thickness: 3.5kÅ ±0.5kÅ
Silox Thickness: 12kÅ ±1.5kÅ
WORST CASE CURRENT DENSITY:
Digital Type: Nitrox
Thickness: 10kÅ ±2kÅ
1.3 x 105 A/cm 2
Metal 1: AlSiCu
Thickness: 8kÅ ±1kÅ
Metal 2: AlSiCu
Thickness: 16kÅ ±2kÅ
Analog Type: Al
Thickness: 16kÅ ±2kÅ
Metallization Mask Layout
DB11
STS
VLOGIC
VLOGIC
12/8
CS
AO
HI-574A, HI-674A
R/C
DB10
CE
VCC
DB9
VREFOUT
ANALOG
COMMON
DB8
ANALOG
COMMON
DB7
ANALOG
COMMON
DB6
VREFIN
DB5
DB4
DB3
DB2
15
DB1
DB0
DIGITAL
COMMON
10V
IN
20V
IN
BIPOLAR
OFFSET
VEE
HI-574A, HI-674A
Ceramic Dual-In-Line Metal Seal Packages (SBDIP)
c1
-A-
BASE
METAL
E
-BC A-B S
SECTION A-A
D S
D
BASE
PLANE
Q
S2
-C-
SEATING
PLANE
A
L
S1
eA
A A
b2
b
e
eA/2
c
aaa M C A - B S D S
ccc M C A - B S D S
NOTES:
1. Index area: A notch or a pin one identification mark shall be located adjacent to pin one and shall be located within the shaded
area shown. The manufacturer’s identification shall not be used
as a pin one identification mark.
2. The maximum limits of lead dimensions b and c or M shall be
measured at the centroid of the finished lead surfaces, when
solder dip or tin plate lead finish is applied.
3. Dimensions b1 and c1 apply to lead base metal only. Dimension
M applies to lead plating and finish thickness.
4. Corner leads (1, N, N/2, and N/2+1) may be configured with a
partial lead paddle. For this configuration dimension b3 replaces
dimension b2.
5. Dimension Q shall be measured from the seating plane to the
base plane.
6. Measure dimension S1 at all four corners.
7. Measure dimension S2 from the top of the ceramic body to the
nearest metallization or lead.
8. N is the maximum number of terminal positions.
9. Braze fillets shall be concave.
10. Dimensioning and tolerancing per ANSI Y14.5M - 1982.
11. Controlling dimension: INCH.
16
INCHES
(c)
b1
M
(b)
M
bbb S
D28.6 MIL-STD-1835 CDIP2-T28 (D-10, CONFIGURATION C)
28 LEAD CERAMIC DUAL-IN-LINE METAL SEAL PACKAGE
LEAD FINISH
-D-
SYMBOL
MILLIMETERS
MIN
MAX
MIN
MAX
A
-
b
0.014
b1
b2
NOTES
0.232
-
5.92
-
0.026
0.36
0.66
2
0.014
0.023
0.36
0.58
3
0.045
0.065
1.14
1.65
-
b3
0.023
0.045
0.58
1.14
4
c
0.008
0.018
0.20
0.46
2
c1
0.008
0.015
0.20
0.38
3
D
-
1.490
-
37.85
-
E
0.500
0.610
12.70
15.49
-
e
0.100 BSC
2.54 BSC
-
eA
0.600 BSC
15.24 BSC
-
eA/2
0.300 BSC
7.62 BSC
-
L
0.125
0.200
3.18
5.08
-
Q
0.015
0.060
0.38
1.52
5
S1
0.005
-
0.13
-
6
S2
0.005
-
0.13
-
7
α
90o
105o
90o
105o
-
aaa
-
0.015
-
0.38
-
bbb
-
0.030
-
0.76
-
ccc
-
0.010
-
0.25
-
M
-
0.0015
-
0.038
2
N
28
28
8
Rev. 0 5/18/94
HI-574A, HI-674A
Dual-In-Line Plastic Packages (PDIP)
E28.6 (JEDEC MS-011-AB ISSUE B)
28 LEAD DUAL-IN-LINE PLASTIC PACKAGE
N
E1
INDEX
AREA
1 2 3
INCHES
N/2
SYMBOL
-B-AE
D
BASE
PLANE
-C-
A2
SEATING
PLANE
A
L
D1
e
B1
D1
A1
eC
B
MAX
MIN
MAX
NOTES
A
-
A1
0.015
0.250
-
6.35
4
-
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
-
C
eB
0.010 (0.25) M C A B S
MILLIMETERS
MIN
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.
D
1.380
1.565
D1
0.005
-
35.1
0.13
39.7
5
-
5
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
17.78
7
5.08
4
3. Symbols are defined in the “MO Series Symbol List” in Section 2.2 of
Publication No. 95.
eB
-
0.700
-
L
0.115
0.200
2.93
4. Dimensions A, A1 and L are measured with the package seated in
JEDEC seating plane gauge GS-3.
N
28
28
9
Rev. 1 12/00
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).
All Intersil products are manufactured, assembled and tested utilizing ISO9000 quality systems.
Intersil Corporation’s quality certifications can be viewed at website www.intersil.com/design/quality/iso.asp.
Intersil 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 from its use.
No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.
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1130 Brussels, Belgium
TEL: (32) 2.724.2111
FAX: (32) 2.724.22.05
NORTH AMERICA
Intersil Corporation
2401 Palm Bay Rd.
Palm Bay, FL 32905
TEL: (321) 724-7000
FAX: (321) 724-7240
17
ASIA
Intersil Ltd.
8F-2, 96, Sec. 1, Chien-kuo North,
Taipei, Taiwan 104
Republic of China
TEL: 886-2-2515-8508
FAX: 886-2-2515-8369