Sipex HS7541A 12-bit cmos multiplying dac Datasheet

HS7541A
®
12–Bit CMOS Multiplying DAC
■ ±0.5 LSB DNL and INL
■ High Stability, Segmented Architecture
(3 MSB’s)
■ Proprietary, Low TCR Thin–Film
Resistor Technology
■ Low Sensitivity to Output Amplifier
Offset
■ 2KV ESD Protection on All Digital
Inputs
■ Operates With +5V to +15V Power
Supplies
■ AD7541/7541A Replacement
■ Low Cost
DESCRIPTION…
The HS7541A is a low–cost, high stability monolithic 12–bit CMOS 4–quadrant multiplying DAC.
It is constructed using a proprietary low–TCR thin–film process that requires no laser–trimming
to achieve 12–bit performance. The HS7541A is a superior pin–compatible replacement for the
industry standard 7541 and AD7541A. It is available in both commercial and industrial
temperature ranges. It operates with +5V to +15V power supply voltages. It is available in 18–
pin plastic DIP and SOIC, and 20–pin PLCC packages.
VREF [17]
20KΩ
D11 (MSB) [4]
20KΩ
D10 [5]
20KΩ
D9 [6]
20KΩ
D8 [7]
20KΩ
D7 [8]
20KΩ
D6 [9]
20KΩ
D5 [10]
20KΩ
D4 [11]
20KΩ
D3 [12]
20KΩ
D2 [13]
20KΩ
D1 [14]
20KΩ
D0 (LSB) [15]
10KΩ
10KΩ
10KΩ
10KΩ
10KΩ
10KΩ
10KΩ
10KΩ
10KΩ
10KΩ
10KΩ 20KΩ
IO2 [2]
IO1 [1]
10KΩ
RFB [18]
VDD [16] GND [3]
HS7541A
12-Bit CMOS Multiplying DAC
1
© Copyright 2000 Sipex Corporation
ABSOLUTE MAXIMUM RATINGS
(TA = 25°C unless otherwise noted.)
These are stress ratings only and functional operation of the device
at these or any other above those indicated in the operation
sections of the specifications below is not implied. Exposure to
absolute maximum rating conditions for extended periods of time
may affect reliability.
CAUTION:
ESD (ElectroStatic Discharge) sensitive
device. Permanent damage may occur on
unconnected devices subject to high energy
electrostatic fields. Unused devices must be
stored in conductive foam or shunts.
Personnel should be properly grounded prior
to handling this device. The protective foam
should be discharged to the destination
socket before devices are removed.
VDD to GND .................................................................. –0.3V, +17V
Digital Input Voltage to GND ................................. –0.3V, VDD+0.3V
VREF or VRFB to GND ................................................................ ±25V
Output Voltage (Pin 1, Pin 2) ................................ –0.3V, VDD+0.3V
Power Dissipation (Any Package to +75°C) ........................ 450mW
Derates above 75°C by ...................................................... 6mW/°C
Dice Junction Temperature ................................................. +150°C
Storage Temperature ............................................ –65°C to +150°C
Lead Temperature (Soldering, 60 seconds) ........................ +300°C
SPECIFICATIONS
(TA=25°C; VDD =+15V, VREF = +10V; IO1 = IO2 = GND = 0V; unipolar unless otherwise noted.)
PARAMETER
STATIC PERFORMANCE
Resolution
Integral Non-Linearity
-AJ, -AA
-AK, -AB
Differential Non-Linearity
-AJ, -AA
-AK, -AB
Gain Error
-AJ, -AA
MIN.
TYP.
MAX.
UNIT
12
CONDITIONS
Bits
-AK, -AB
Output Leakage Current
±1.0
±0.5
LSB
LSB
±1.0
±0.5
LSB
LSB
±6
±8
±3
±5
±5
±10
LSB
LSB
LSB
LSB
nA
nA
Note 6
Note 5; 11-bit relative accuracy
Note 5; 12-bit relative accuracy
Note 7
Note 5; Monotonic to 12-bits
Note 5; Monotonic to 12-bits
Note 17
Note 5
Note 5
At IO1 (Pin 1); Note 18
Note 5
AC PERFORMANCE CHARACTERISTICS
Propagation Delay
Current Settling Time
Output Capacitance
CIO1 (Pin 16)
CIO2 (Pin 15)
CIO1 (Pin 16)
CIO2 (Pin 15)
Glitch Energy
Multiplying Feedthrough Error
STABILITY
Gain Error TC
INL TC
DNL TC
Power Supply Rejection Ratio
REFERENCE INPUT
Input Resistance
Input Resistance TC
Voltage Range
HS7541A
100
0.6
ns
µs
200
70
70
200
7
1,000
1.0
pF
pF
pF
pF
nVs
mVP-P
0.1
mVP-P
±1.0
±0.1
±0.1
ppm/°C
ppm/°C
ppm/°C
%/%
10
±150
±0.02
15
±25
KΩ
ppm/°C
Volts
12-Bit CMOS Multiplying DAC
2
Output Amplifier HOS-050;
Note 8
Note 9
Full scale transition; Note 10
Note 5; data inputs VIH
Note 5; data inputs VIH
Note 5; data inputs VIL
Note 5; data inputs VIL
Note 11
Measured at output IO1;
Note 12
Measured at output IO1;
Note 13
VDD = 14 to 16V
Pin 19 to GND
Note 5 and 14
© Copyright 2000 Sipex Corporation
SPECIFICATIONS (continued)
(TA=25°C; VDD =+15V, VREF = +10V; IO1 = IO2 = GND = 0V; unipolar unless otherwise noted.)
PARAMETER
DIGITAL INPUTS
Logic Levels
VIH
VIL
MIN.
TYP.
2.4
VDD
2.4
0.8
0.8
±1.0
±10
-0.3
Input Current
Input Capacitance
Bits 1—12
Coding
Unipolar
Bipolar
POWER REQUIREMENTS
Voltage Range
Supply Current
MAX.
8
UNIT
Volts
Volts
Volts
Volts
µA
µA
pF
CONDITIONS
Note 5
Note 5
VIN = 0V or VDD
Note 5 and 15
VIN = 0; Note 5 and 14
Note 5
Binary
Offset Binary
+5
2.0
0.2
+15
+16
2.5
2.5
Volts
Volts
mA
mA
0.5
mA
1.0
mA
Note 16
Note 5
All digital inputs VIL or VIH
Note 5; all digital inputs VIL or
VIH
All digital inputs 0V or 5V to
VDD
Note 5; all digital inputs 0V or
5V to VDD
ENVIRONMENTAL AND MECHANICAL
Operating Temperature
-AK, -AJ
0
+70
°C
-AB, -AA
-40
+85
°C
Storage Temperature
-65
+150
°C
Package
-AK, -AJ
18-pin plastic DIP, 20-pin PLCC, 18–pin SOIC
Notes and Cautions:
1.
Do not apply voltages higher than VDD or less than GND potential on any terminal other than VREF or VRFB.
2.
The digital inputs are diode-clamp protected against ESD damage. However, permanent damage may occur
on unprotected units from high-energy electrostatic fields. Keep units in conductive foam at all times until
ready to use.
3.
Use proper anti-static handling procedures.
4.
Stresses above those listed under “Absolute Maximum Ratings” may cause permanent damage to the
device. This is a stress rating only and functional operation at or above these specifications is not implied.
Exposure to the above maximum rated conditions for extended periods may affect device reliability.
5.
From TMIN to TMAX.
6.
Integral Non-linearity is measured as the arithmetic mean value of the magnitudes of the greatest positive
deviation and the greatest negative deviation from the theoretical value of any given input combination.
7.
Differential Non-linearity is the deviation of an output step from the theoretical value of 1 LSB for any two
adjacent digital input codes.
8.
AC performance characteristics are included for design guidance only and are subject to sample testing only.
9.
RL = 100Ω, CEXT = 13pF; all data inputs 0V to VDD or VDD to 0V; from 50% digital input change to 90% of final
analog output.
10.
Settling to ±0.01% FSR (strobed); all data inputs 0V to VDD or VDD to 0V.
11.
VREF = 0V, DAC register alternatively loaded with all 0’s and all 1’s.
12.
VREF = 20VP-P; F = 10kHz sinewave.
13.
VREF = 20VP-P; F = 1kHz sinewave.
14.
Guaranteed by design, but not production tested.
15.
Logic inputs are MOS gates. IIN typically is less than 1nA @ 25°C.
16.
Accuracy is guaranteed at VDD = +15V only.
17.
Measured using internal feedback resistor with DAC loaded with all 1’s.
18.
All digital inputs = 0V.
HS7541A
12-Bit CMOS Multiplying DAC
3
© Copyright 2000 Sipex Corporation
Pin 16 — D0 (LSB) — Data Bit 0 (Least Significant Bit).
Pin 17 — N.C. — No Connection.
Pin 18 — VDD— +5V to +15V Power Supply.
Pin 19 — VREF— Voltage Reference Input.
Pin 20 — RFB— Feedback Resistor.
PIN ASSIGNMENTS
18–Pin Plastic DIP and SOIC
Pin 1 — IO1 — Inverted Current Output.
Pin 2 — IO2 — Current Output.
Pin 3 — GND — Analog Ground.
Pin 4 — D11 (MSB) — Data Bit 11 (Most Significant
Bit).
Pin 5 — D10 — Data Bit 10.
Pin 6 — D9 — Data Bit 9.
Pin 7 — D8 — Data Bit 8.
Pin 8 — D7 — Data Bit 7.
Pin 9 — D6 — Data Bit 6.
Pin 10 — D5— Data Bit 5.
Pin 11 — D4— Data Bit 4.
Pin 12 — D3— Data Bit 3.
Pin 13 — D2— Data Bit 2.
Pin 14 — D1— Data Bit 1.
Pin 15 — D0 (LSB) — Data Bit 0 (Least Significant
Bit).
Pin 16 — VDD— +5V to +15V Power Supply.
Pin 17 — VREF— Voltage Reference Input.
Pin 18 — RFB— Feedback Resistor.
FEATURES…
The HS7541A is a low–cost, high stability monolithic 12–bit CMOS 4–quadrant multiplying
DAC. It is constructed using a proprietary low–
TCR thin–film process that requires no laser–
trimming to achieve 12–bit performance. With
its inherent high stability and a segmented (decoded) DAC architecture, the HS7541A retains
its performance over time and temperature. To
further improve reliability, all digital inputs are
protected against 2KV ESD. Each DAC is fully
characterized by all–codes testing to eliminate
any hidden errors.
The HS7541A consists of a highly stable thin–
film R–2R ladder network and twelve NMOS
current switches (please refer to the Block Diagram on the first page of this data sheet). The
switches are temperature compensated, and their
“on” resistances are binarily scaled so that the
voltage drop across each switch is identical,
which contributes to the stability of the DAC.
The internal feedback resistor used in the output
current–to–voltage conversion by an external
op amp is matched to the R–2R ladder.
20–Pin Plastic LCC
Pin 1 — IO1 — Inverted Current Output.
Pin 2 — IO2 — Current Output.
Pin 3 — GND — Analog Ground.
Pin 4 — N.C. — No Connection.
Pin 5 — D11 (MSB) — Data Bit 11 (Most
Significant Bit).
Pin 6 — D10 — Data Bit 10.
Pin 7 — D9 — Data Bit 9.
Pin 8 — D8 — Data Bit 8.
Pin 9 — D7 — Data Bit 7.
Pin 10 — D6 — Data Bit 6.
Pin 11 — D5— Data Bit 5.
Pin 12 — D4— Data Bit 4.
Pin 13 — D3— Data Bit 3.
Pin 14 — D2— Data Bit 2.
Pin 15 — D1— Data Bit 1.
HS7541A
CIRCUIT DESCRIPTION
General
The HS7541A is a 12-bit multiplying D/A converter consisting of a highly stable, SiChrome
thin-film R-2R resistor ladder network, and
twelve pairs of NMOS current-steering switches
on a monolithic chip.
A simplified circuit of the HS7541A is shown in
Figure 1. The R-2R inverted ladder binarily
divides the input currents that are switched
between the IOUT1 and IOUT2 bus lines. This switching allows a constant current to be maintained in
each ladder leg independent of the input code.
12-Bit CMOS Multiplying DAC
4
© Copyright 2000 Sipex Corporation
10KΩ
10KΩ
10KΩ
RFEEDBACK
VREF
20KΩ
20KΩ
S0
20KΩ
IREF
20KΩ
S2
S1
S11
R = 10KΩ
20KΩ
R = 10KΩ
VREF
IOUT1
1/4096
ILEAKAGE
85pF
ILEAKAGE
30pF
IOUT2
IOUT1
IOUT2
RFB
D11 (MSB)
D1
D2
D0 (LSB)
Switches shown for digital inputs "high"
Figure 1. Simplified DAC Circuit
Figure 3. Equivalent Circuit – All Inputs High
The twelve output current-steering switches are
in series with the R-2R ladder, and therefore,
can introduce bit errors. It is essential then, that
the switch “on” resistance be binarily scaled so
that the voltage drop across each switch remains
constant. If, for example, switch S0 of Figure 1
was designed with an “on” resistance of 10
ohms, switch S1 for 20 ohms, etc., then with a
10V reference input, the current through S0 is
0.5mA, S1 is 0.25mA, etc.; a constant 5mV drop
will then be maintained across each switch.
2001V ESD Protection
In the design of the HS7541A’s data inputs,
2001V ESD resistance has been incorporated
through careful layout and the inclusion of input
protection circuitry.
Equivalent Circuit Analysis
Figures 2 and 3 show the equivalent circuits for all
digital inputs LOW and HIGH respectively. The
reference current is switched to IOUT2 when all inputs
are LOW, and to IOUT1 when all inputs are HIGH.
The ILEAKAGE current source is the combination of
surface and junction leakages to the substrate; the
1/4096 current source represents the constant 1-bit
current drain through the ladder terminating resistor. The output capacitance is dependent upon the
digital input code, and therefore varies between the
low and high values.
To further insure accuracy across the full temperature range, permanently “on” MOS switches
are included in series with the feedback resistor
and the R-2R ladder’s terminating resistor. These
series switches are equivalently scaled to two
times switch S11 (MSB) and to switch S0 (LSB)
respectively to maintain constant relative voltage drops with varying temperature. During any
testing of the resistor ladder or RFB (such as
incoming inspection), VDD must be present to
turn “on” these series switches.
Output Impedance
The output resistance, as in the case of the output
capacitance, varies with the digital input code.
The resistance, looking back into the IOUT1 ter-
+15V
GAIN TRIM
RFEEDBACK
VREF (–10V)
R = 10KΩ
D11 (MSB)
IOUT1
ILEAKAGE
17
VREF
16
VDD
RFB
18
IO1 1
INPUT
DATA
HS7541A
GAIN TRIM
1KΩ
+15V
15pF
–
+
VOUT
R = 10KΩ
IOUT2
1/4096
ILEAKAGE
–15V
85pF
D0 (LSB)
Figure 2. Equivalent Circuit – All Inputs Low
HS7541A
4
30pF
IREF
VREF
2KΩ
15
GND
3
IO2 2
Figure 4. Unipolar Operation
12-Bit CMOS Multiplying DAC
5
© Copyright 2000 Sipex Corporation
GAIN TRIM
VREF (–10V)
+15V
2KΩ
4
D11 (MSB)
17
VREF
16
VDD
RFB
18
1KΩ
IO1 1
INPUT
DATA
–
HS7541A
VOUT
+
10KΩ
15
D0 (LSB)
GND
3
IO2 2
390Ω
10KΩ
–
+
10KΩ
500Ω
Figure 5. Bipolar Operation
As shown in the figure, the output current of the
HS7541A is typically connected to an external
op amp, with its non-inverting input tied to
ground. The amplifier should be selected for
low input bias current and low drift over temperature. To maintain the specified linearity, the
amplifier’s input offset voltage should be mulled
to less than ±200µV (0.1 LSB).
minal, may be anywhere between 10kΩ (the
feedback resistor alone when all digital inputs
are LOW) and 7.5kΩ (the feedback resistor in
parallel with approximately 30kΩ of the R-2R
ladder network resistance when any single bit is
HIGH). Static accuracy and dynamic performance will be affected by these variations.
UNIPOLAR OPERATION
Figure 4 shows the connections to implement
digital unipolar operation of the HS7541A. The
reference voltage applied to VREF (pin17) may be
positive or negative. The 2KΩ potentiometer
tied to VREF, and the 1KΩ resistor in the feedback loop are both optional; they are needed
only when gain error must be trimmed to less
than 0.3% FSR. They should track each other to
better than 0.1%. It is not necessary that they
track the resistors internal to the HS7541A.
DIGITAL INPUT
1111 1111 1111
1000 0000 0000
0111 1111 1111
0000 0000 0000
BIPOLAR OPERATION
Figure 5 shows the connections for bipolar
operation of the HS7541A. The digital input
coding is offset binary as shown in Table 2. As
is the case for unipolar operation, the gain trim
resistors can be omitted if minimum gain error
is not required. The op amp selection criteria
and offset nulling are the same as for unipolar
operation.
DIGITAL INPUT
1111 1111 1111
1000 0000 0001
1000 0000 0000
0100 0000 0000
0000 0000 0000
I
-0.99975 x V
-0.50000 x V
-0.49975 x V
0V
0UT
REF
REF
REF
Table 1. Unipolar Input Coding
HS7541A
I
-0.99951 x V
-0.00049 x V
0V
+0.50000 x V
+1.00000 x V
0UT
REF
REF
REF
REF
Table 2. Bipolar Input Coding
12-Bit CMOS Multiplying DAC
6
© Copyright 2000 Sipex Corporation
ORDERING INFORMATION
Model .............................................................................................. Relative Accuracy .......................................................................... Package
0°C to +70°C Operating Temperature:
HS7541AKN ........................................................................................... ±0.5 LSB ............................................................... 18-Pin, 0.3" Plastic DIP
HS7541AJN ............................................................................................ ±1.0 LSB ............................................................... 18-Pin, 0.3" Plastic DIP
HS7541AKP ............................................................................................ ±0.5 LSB ................................................................................ 20-Pin PLCC
HS7541AJP ............................................................................................ ±1.0 LSB ................................................................................ 20-Pin PLCC
HS7541AKS ............................................................................................ ±0.5 LSB ........................................................................ 18-Pin, 0.3" SOIC
HS7541AJS ............................................................................................ ±1.0 LSB ........................................................................ 18-Pin, 0.3" SOIC
–40°C to +85°C Operating Temperature:
HS7541ABN ........................................................................................... ±0.5 LSB ............................................................... 18-Pin, 0.3" Plastic DIP
HS7541AAN ........................................................................................... ±1.0 LSB ............................................................... 18-Pin, 0.3" Plastic DIP
HS7541ABP ............................................................................................ ±0.5 LSB ................................................................................ 20-Pin PLCC
HS7541AAP ............................................................................................ ±1.0 LSB ................................................................................ 20-Pin PLCC
HS7541ABS ............................................................................................ ±0.5 LSB ........................................................................ 18-Pin, 0.3" SOIC
HS7541AAS ............................................................................................ ±1.0 LSB ........................................................................ 18-Pin, 0.3" SOIC
Corporation
SIGNAL PROCESSING EXCELLENCE
Sipex Corporation
Headquarters and
Sales Office
22 Linnell Circle
Billerica, MA 01821
TEL: (978) 667-8700
FAX: (978) 670-9001
e-mail: [email protected]
Sales Office
233 South Hillview Drive
Milpitas, CA 95035
TEL: (408) 934-7500
FAX: (408) 935-7600
Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the
application or use of any product or circuit described hereing; neither does it convey any license under its patent rights nor the rights of others.
HS7541A
12-Bit CMOS Multiplying DAC
7
© Copyright 2000 Sipex Corporation
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