AD7541JN - Harris Semiconductor - Datasheet.Technology

CAUTION: These devices are sensitive to electrostatic discharge. Users should follow proper I.C. Handling Procedures.

SEMICONDUCTOR

AD7541

12-Bit Multiplying D/A Converter

Description

The AD7541 is a monolithic, low cost, high performance, 12-

bit accurate, multiplying digital-to-analog converter (DAC).

Harris’ wafer level laser-trimmed thin-ﬁlm resistors on CMOS

circuitry provide true 12-bit linearity with TTL/CMOS compat-

ible operation.

Special tabbed-resistor geometries (improving time stability),

full input protection from damage due to static discharge by

diode clamps to V+ and ground, large IOUT1 and IOUT2 bus

lines (improving superposition errors) are some of the fea-

tures offered by Harris AD7541.

Pin compatible with AD7521, this DAC provides accurate

four quadrant multiplication over the full military temperature

range.

Features

• 12-Bit Linearity 0.01%

• Pretrimmed Gain

• Low Gain and Linearity Tempcos

• Full Temperature Range Operation

• Full Input Static Protection

• TTL/CMOS Compatible

• +5V to +15V Supply Range

• 20mW Low Power Dissipation

• Current Settling Time 1µs to 0.01% of FSR

• Four Quadrant Multiplication

File Number 3107

December 1993

Ordering Information

PART NUMBER NONLINEARITY TEMPERATURE RANGE PACKAGE

AD7541AD 0.02% (11-Bit) -25oC to +85oC 18 Lead Plastic DIP

AD7541BD 0.01% (12-Bit) -25oC to +85oC 18 Lead Plastic DIP

AD7541JN 0.02% (11-Bit) 0oC to +70oC 18 Lead Plastic DIP

AD7541KN 0.01% (12-Bit) 0oC to +70oC 18 Lead Plastic DIP

AD7541LN 0.01% (12-Bit) Guaranteed Monotonic 0oC to +70oC 18 Lead Plastic DIP

AD7541SD 0.02% (11-Bit) -55oC to +125oC 18 Lead Plastic DIP

AD7541TD 0.01% (12-Bit) -55oC to +125oC 18 Lead Plastic DIP

Pinout

AD7541

(PDIP)

TOP VIEW

Functional Diagram

Switches shown are for Digital Inputs “High”

1RFEEDBACK

V+

BIT 12 (LSB)

BIT 11

BIT 10

BIT 9

BIT 8

VREF IN

BIT 7

IOUT1

IOUT2

GND

BIT 1 (MSB)

BIT 2

BIT 3

BIT 5

BIT 4

BIT 6

MSB

(4)

20kΩ

(3)

BIT 3BIT 2

VREF IN

20kΩ20kΩ20kΩ20kΩ20kΩ

10kΩ10kΩ10kΩ10kΩ

SPDT

NMOS

10kΩ

IOUT2 (2)

IOUT1 (1)

RFEEDBACK

(17)

SWITCHES

(18)

(5) (6)

8-22

Speciﬁcations AD7541

Absolute Maximum Ratings Thermal Information

Supply Voltage (V+ to GND). . . . . . . . . . . . . . . . . . . . . . . . . . . +17V

VREF . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±25V

Digital Input Voltage Range . . . . . . . . . . . . . . . . . . . . . . .V+ to GND

Output Voltage Compliance . . . . . . . . . . . . . . . . . . . . -100mV to V+

Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . -65oC to +150oC

Lead Temperature (Soldering 10s). . . . . . . . . . . . . . . . . . . . +300oC

Thermal Resistance θJA

Plastic DIP Package . . . . . . . . . . . . . . . . . . . . . . . . . . . .90oC/W

Operating Temperature

JN, KN, LN Versions . . . . . . . . . . . . . . . . . . . . . . . . 0oC to +70oC

AD, BD Versions . . . . . . . . . . . . . . . . . . . . . . . . . .-25oC to +85oC

SD, TD Version . . . . . . . . . . . . . . . . . . . . . . . . . .-55oC to +125oC

Maximum Power Dissipation

Plastic DIP Package up to +70oC . . . . . . . . . . . . . . . . . . . 670mW

Junction Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +150oC

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.

Electrical Speciﬁcations V+ = +15V, VREF = +10V, VOUT1 = VOUT2 = 0V, TA = +25oC, Unless Otherwise Speciﬁed

PARAMETER TEST CONDITIONS

TA +25oCT

MIN-MAX

UNITSMIN TYP MAX MIN MAX

SYSTEM PERFORMANCE

Resolution 12 - - 12 - Bits

Nonlinearity A, S, J -10V ≤ VREF ≤ +10V

VOUT1 = VOUT2 = 0V

See Figure 3

(Note 4)

--±0.024 - ±0.024 % of FSR

B, T, K - - ±0.012 - ±0.012 % of FSR

L--±0.012 - ±0.012 % of FSR

Monotonicity Guaranteed

Gain Error -10V ≤ VREF ≤ +10V (Note 4) - - ±0.3 - ±0.4 % of FSR

Output Leakage Current

(Either Output) VOUT1 = VOUT2 = 0 - - ±50 - ±200 nA

DYNAMIC CHARACTERISTICS

Power Supply Rejection V+ = 14.5V to 15.5V

See Figure 5, (Note 4) --±0.005 - ±0.01 % of FSR/% of

∆V+

Output Current Settling Time To 0.1% of FSR

See Figure 9, (Note 5) --1-1 µs

Feedthrough Error VREF = 20VPP, 10kHz

All Digital Inputs Low

See Figure 8, (Note 5)

--1-1mV

P-P

REFERENCE INPUTS

Input Resistance All Digital Inputs High

IOUT1 at Ground 5 10 20 5 20 kΩ

ANALOG OUTPUT

Voltage Compliance Both Outputs, See Maximum

Ratings (Note 6) -100mV to V+

Output Capacitance COUT1 All Digital Inputs High

See Figure 7, (Note 5) - - 200 - 200 pF

COUT2 - - 60 - 60 pF

COUT1 All Digital Inputs Low)

See Figure 7, (Note 5) - - 60 - 60 pF

COUT2 - - 200 - 200 pF

Output Noise (Both Outputs) See Figure 6 Equivalent to 10kΩ Johnson Noise

DIGITAL INPUTS

Low State Threshold, VIL (Note 1, 5) - - 0.8 - 0.8 V

High State Threshold, VIH 2.4 - - 2.4 - V

8-23

Speciﬁcations AD7541

Input Current VIN = 0V or V+ (Note 5) - - ±1-±1µA

Input Coding See Tables 1 & 2 (Note 5) Binary/Offset Binary

Input Capacitance (Note 5) - - 8 - 8 pF

POWER SUPPLY CHARACTERISTICS

Power Supply Voltage Range Accuracy is not guaranteed over

this range +5 to +16 V

I+ All Digital Inputs High or Low

(Excluding Ladder Network) - - 2.0 - 2.5 mA

Total Power Dissipation (Including Ladder Network) - 20 - - - mW

NOTES:

1. The digital control inputs are zener protected; however, permanent damage may occur on unconnected units under high energy electro-

static ﬁelds. Keep unused units in conductive foam at all times.

2. Do not apply voltages higher than VDD or less than GND potential on any terminal except VREF and RFEEDBACK.

3. Full scale range (FSR) is 10V for unipolar and ±10V for bipolar modes.

4. Using internal feedback resistor, RFEEDBACK.

5. Guaranteed by design or characterization and not production tested.

6. Accuracy not guaranteed unless outputs at ground potential.

Electrical Speciﬁcations V+ = +15V, VREF = +10V, VOUT1 = VOUT2 = 0V, TA = +25oC, Unless Otherwise Speciﬁed (Continued)

PARAMETER TEST CONDITIONS

TA +25oCT

MIN-MAX

UNITSMIN TYP MAX MIN MAX

Deﬁnition of Terms

Nonlinearity: Error contributed by deviation of the DAC

transfer function from a “best ﬁt straight line” function. Nor-

mally expressed as a percentage of full scale range. For a

multiplying DAC, this should hold true over the entire VREF

range.

Resolution: Value of the LSB. For example, a unipolar

converter with n bits has a resolution of LSB = (VREF)/2-N. A

bipolar converter of n bits has a resolution of LSB = (VREF)/

2-(N-1). Resolution in no way implies linearity.

Settling Time: Time required for the output function of the

DAC to settle to within 1/2 LSB for a given digital input

stimulus, i.e., 0 to Full Scale.

Gain Error: Ratio of the DAC’s operational ampliﬁer output

voltage to the nominal input voltage value.

Feedthrough Error: Error caused by capacitive coupling

from VREF to output with all switches OFF.

Output Capacitance: Capacitance from IOUT1, and IOUT2

terminals to ground.

Output Leakage Current: Current which appears on IOUT1,

terminal when all digital inputs are LOW or on IOUT2 terminal

when all inputs are HIGH.

Detailed Description

The AD7541 is a 12-bit, monolithic, multiplying D/A converter.

A highly stable thin ﬁlm R-2R resistor ladder network and

NMOS SPDT switches form the basis of the converter circuit.

CMOS level shifters provide low power TTL/CMOS compati-

ble operation. An external voltage or current reference and an

operational ampliﬁer are all that is required for most voltage

output applications. A simpliﬁed equivalent circuit of the DAC

is shown on page 1, (Functional Diagram). The NMOS SPDT

switches steer the ladder leg currents between IOUT1 and

IOUT2 buses which must be held at ground potential. This con-

ﬁguration maintains a constant current in each ladder leg

independent of the input code. Converter errors are further

eliminated by using wider metal interconnections between the

major bits and the outputs. Use of high threshold switches

reduces the offset (leakage) errors to a negligible level.

Each circuit is laser-trimmed, at the wafer level, to better than

12-bits linearity. For the ﬁrst four bits of the ladder, special

trim-tabbed geometries are used to keep the body of the

resistors, carrying the majority of the output current, undis-

turbed. The resultant time stability of the trimmed circuits is

comparable to that of untrimmed units.

The level shifter circuits are comprised of three inverters with

a positive feedback from the output of the second to ﬁrst

(Figure 1). This conﬁguration results in TTL/COMS compati-

ble operation over the full military temperature range. With

the ladder SPDT switches driven by the level shifter, each

switch is binary weighted for an “ON” resistance proportional

to the respective ladder leg current. This assures a constant

voltage drop across each switch, creating equipotential ter-

minations for the 2R ladder resistor, resulting in accurate leg

currents.

8-24

AD7541

FIGURE 1. CMOS SWITCH

Typical Applications

General Recommendations

Static performance of the AD7541 depends on IOUT1 and

IOUT2 (pin 1 and pin 2) potentials being exactly equal to GND

(pin3).

The output ampliﬁer should be selected to have a low input

bias current (typically less than 75nA), and a low drift

(depending on the temperature range). The voltage offset of

the ampliﬁer should be nulled (typically less than ±200µV).

The bias current compensation resistor in the ampliﬁer’s

non-inverting input can cause a variable offset. Non-inverting

input should be connected to GND with a low resistance

wire.

Ground-loops must be avoided by taking all pins going to

GND to a common point, using separate connections.

The V+ (pin 18) power supply should have a low noise level

and should not have any transients exceeding +17V.

Unused digital inputs must be connected to GND or VDD for

proper operation.

A high value resistor (~1MΩ) can be used to prevent static

charge accumulation, when the inputs are open-circuited for

any reason.

When gain adjustment is required, low tempco (approxi-

mately 50ppm/oC) resistors or trim-pots should be selected.

Unipolar Binary Operation

The circuit conﬁguration for operating the AD7541 in unipo-

lar mode is shown in Figure 2. With positive and negative

VREF values the circuit is capable of 2-Quadrant multiplica-

tion. The “Digital Input Code/Analog Output Value” table for

unipolar mode is given in Table 1. A Schottky diode

(HP5082-2811 or equivalent) prevents IOUT1 from negative

excursions which could damage the device. This precaution

is only necessary with certain high speed ampliﬁers.

V+

TTL/CMOS

INPUT

13 4

TO LADDER

IOUT2 IOUT1

FIGURE 2. UNIPOLAR BINARY OPERATION

(2-QUADRANT MULTIPLICATION)

Zero Offset Adjustment

1. Connect all digital inputs to GND.

2. Adjust the offset zero adjust trimpot of the output opera-

tional ampliﬁer for 0V ±0.5mV (max) at VOUT.

Gain Adjustment

1. Connect all digital inputs to VDD.

2. Monitor VOUT for a -VREF (1 - 1/212) reading.

3. T o increase VOUT, connect a series resistor, (0Ω to 250Ω),

in the IOUT1 ampliﬁer feedback loop.

4. T o decrease VOUT, connect a series resistor, (0Ω to 250Ω),

between the reference voltage and the VREF terminal.

Bipolar (Offset Binary) Operation

The circuit conﬁguration for operating the AD7541 in the

bipolar mode is given in Figure 3. Using offset binary digital

input codes and positive and negative reference voltage val-

ues Four-Quadrant multiplication can be realized. The “Digi-

tal Input Code/Analog Output Value” table for bipolar mode is

given in Table 2.

TABLE 1. CODE TABLE - UNIPOLAR BINARY OPERATION

DIGITAL INPUT ANALOG OUTPUT

111111111111 -VREF (1 - 1/212)

100000000001 -VREF (1/2 + 1/212)

100000000000 -VREF/2

011111111111 -VREF (1/2 - 1/212)

000000000001 -VREF (1/212)

000000000000 0

17 18

15 32

AD7541

BIT 1 (MSB)

BIT 12 (LSB)

+15V

VREF

GND

IOUT1

IOUT2 6

VOUT

RFEEDBACK

DIGITAL

INPUT CR1

±10V

8-25

AD7541

A “Logic 1” input at any digital input forces the corresponding

ladder switch to steer the bit current to IOUT1 bus. A “Logic 0”

input forces the bit current to IOUT2 bus. For any code the

IOUT1 and IOUT2 bus currents are complements of one

another. The current ampliﬁer at IOUT2 changes the polarity

of IOUT2 current and the transconductance ampliﬁer at IOUT1

output sums the two currents. This conﬁguration doubles the

output range of the DAC. The difference current resulting at

zero offset binary code, (MSB = “Logic 1”, All other bits =

“Logic 0”), is corrected by using an external resistive divider,

from VREF to IOUT2.

Offset Adjustment

1. Adjust VREF to approximately +10V.

2. Set R4 to zero.

3. Connect all digital inputs to “Logic 1”.

4. Adjust IOUT1 ampliﬁer offset zero adjust trimpot for 0V

±0.1mV at IOUT2 ampliﬁer output.

5. Connect a short circuit across R2.

6. Connect all digital inputs to “Logic 0”.

7. Adjust IOUT2 ampliﬁer offset zero adjust trimpot for 0V±0.1mV

at IOUT1 ampliﬁer output.

8. Remove short circuit across R2.

9. Connect MSB (Bit 1) to “Logic 1” and all other bits to “Logic 0”.

10. Adjust R4 for 0V ±0.2mV at VOUT.

Gain Adjustment

1. Connect all digital inputs to VDD.

2. Monitor VOUT for a -VREF (1 - 1/211) volts reading.

3. T o increase VOUT, connect a series resistor, (0Ω to 250Ω),

in the IOUT1 ampliﬁer feedback loop.

4. To decrease VOUT, connect a series resistor , (0Ω to 250Ω),

between the reference voltage and the VREF terminal.

TABLE 2. CODE TABLE - BIPOLAR (OFFSET BINARY)

OPERATION

DIGITAL INPUT ANALOG OUTPUT

111111111111 -VREF (1 - 1/211)

100000000001 -VREF (1/211)

100000000000 0

011111111111 VREF (1/211)

000000000001 VREF (1 - 1/211)

000000000000 VREF

FIGURE 3. BIPOLAR OPERATION (4-QUADRANT MULTIPLICATION)

IOUT2

IOUT1

17 18

15 32

AD7541

BIT 1 (MSB)

BIT 12 (LSB)

+15V

VREF

DIGITAL

INPUT

10V

R1 10K

R5 10K

VOUT

+A1

+A2

GND

R2 10K R3

390k

500Ω

NOTE: R1 AND R2 SHOULD BE 0.01%, LOW-TCR RESISTORS

8-26

AD7541

Test Circuits

FIGURE 4. NONLINEARITY TEST CIRCUIT

FIGURE 5. POWER SUPPLY REJECTION TEST CIRCUIT

FIGURE 6. NOISE TEST CIRCUIT

HA2600

CLOCK

14-BIT

REFERENCE

DAC

HA2600

12-BIT

BINARY

COUNTER AD7541

AD7541

17 16

LINEARITY

ERROR X 100

10K 0.01%

10K

0.01%

IOUT1

IOUT2

RFEEDBACK

1MΩ

+15V

VREF

BIT 1 (MSB)

BIT 12

(LSB)

VREF

GND

BIT 1

(MSB)

BIT 12

BIT 13

BIT 14

HA2600

AD7541

17 16

VREF +10V

BIT 1 (MSB)

BIT 12

(LSB)

GND

RFEEDBACK

IOUT1

IOUT2

+15V

UNGROUNDED

SINE WAVE

GENERATION

40Hz 1.0VP-P

5K 0.01%

500K

VERROR X 100

101ALN

QUAN

TECH

MODEL

134D

WAVE

ANALYZER

AD7541

17 16

+11V (ADJUST FOR VOUT = 0V)

+15V

15µFIOUT2

IOUT1

100Ω10K

VOUT

1K50K

0.1µF

-50V

F = 1KHz

BW = 1Hz

8-27

AD7541

FIGURE 7. OUTPUT CAPACITANCE TEST CIRCUIT FIGURE 8. FEEDTHROUGH ERROR TEST CIRCUIT

FIGURE 9. OUTPUT CURRENT SETTLING TIME TEST CIRCUIT

Test Circuits

(Continued)

SCOPE

AD7541

17 16

BIT 1 (MSB)

BIT 12 (LSB)

+15V NC +15V

100mVPP

1MHz HA2600

AD7541

17 16

+15V

VOUT

IOUT1

IOUT2

GND

VREF = 20VPP 10kHz SINE WAVE

BIT 1 (MSB)

BIT 12 (LSB)

VREF +15V

+10V

BIT 1 (MSB)

BIT 12 (LSB)

AD7541

EXTRAPOLATE

+100mV

100Ω

IOUT2

GND

+5V

DIGITAL INPUT

17 16

4OSCILLOSCOPE

3t: 5% SETTLING

9t: 0.01% SETTLING

Dynamic Performance

The dynamic performance of the DAC, also depends on the

output ampliﬁer selection. For low speed or static applica-

tions, AC speciﬁcations of the ampliﬁer are not very critical.

For high-speed applications slew-rate, settling-time, open-

loop gain and gain/phase-margin speciﬁcations of the ampli-

ﬁer should be selected for the desired performance.

The output impedance of the AD7541 looking into IOUT1 var-

ies between 10kΩ (RFEEDBACK alone) and 5KΩ (RFEEDBACK

in parallel with the ladder resistance).

Similarly the output capacitance varies between the mini-

mum and the maximum values depending on the input code.

These variations necessitate the use of compensation

capacitors, when high speed ampliﬁers are used.

A capacitor in parallel with the feedback resistor (as shown

in Figure 10) provides the necessary phase compensation to

critically damp the output.

A small capacitor connected to the compensation pin of the

ampliﬁer may be required for unstable situations causing

oscillations. Careful PC board layout, minimizing parasitic

capacitances, is also vital.

FIGURE 10. GENERAL DAC CIRCUIT WITH COMPENSATION CAPACITOR, CC

VREF

+15V

+10V

BIT 1 (MSB)

BIT 12 (LSB)

AD7541

RFEEDBACK

IOUT2

GND

17 16

BIT 2 18

IOUT1

+VOUT