REV. 0

Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices for its
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which may result from its use. No license is granted by implication or
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AD7839

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 781/329-4700

World Wide Web Site: http://www.analog.com

Fax: 781/326-8703

© Analog Devices, Inc., 1999

Octal 13-Bit, Parallel Input,

Voltage-Output DAC

FUNCTIONAL BLOCK DIAGRAM

DAC
REG

INPUT

REG

DAC E

AD7839

DB12

DB0

LDAC

DAC
REG

INPUT

REG

DAC
REG

INPUT

REG

DAC
REG

INPUT

REG

DAC
REG

INPUT

REG

DAC
REG

INPUT

REG

DAC
REG

INPUT

REG

DAC
REG

INPUT

REG

DAC D

DAC C

DAC F

DAC B

DAC A

DAC G

DAC H

REF

(+)

REF

()

DUTGND

OUT

DUTGND

REF

()

CDEF

REF

(+)

CDEF

REF

()

REF

(+)

GND

CLR

ADDRESS

DECODE

FEATURES
Eight 13-Bit DACs in One Package
Voltage Outputs
Offset Adjust for Each DAC Pair
Reference Range of 5 V
Maximum Output Voltage Range of 10 V
Clear Function to User-Defined Voltage
44-Lead MQFP Package

APPLICATIONS
Automatic Test Equipment
Process Control
General Purpose Instrumentation

GENERAL DESCRIPTION

The AD7839 contains eight 13-bit DACs on one monolithic
chip. It has output voltages with a full-scale range of

10 V

from reference voltages of

5 V.

The AD7839 accepts 13-bit parallel loaded data from the exter-
nal bus into one of the input registers under the control of the
WR, CS and DAC channel address pins, A0A2.

The DAC outputs are updated on reception of new data into
the DAC registers. All the outputs may be updated simulta-
neously by taking the

LDAC input low.

Each DAC output is buffered with a gain-of-two amplifier into
which an external DAC offset voltage can be inserted via the
DUTGNDx pins.

The AD7839 is available in a 44-lead MQFP package.

REV. 0

AD7839SPECIFICATIONS

= +5 V 5%; V

= +15 V 5%; V

= 15 V 5%; GND = DUTGND = 0 V;

= 5 k

and C

= 50 pF to GND, T

= T

MIN

to T

MAX

, unless otherwise noted.)

Parameter

A Version

Units

Test Conditions/Comments

ACCURACY

Resolution

Bits

Relative Accuracy

LSB max

Typically

0.5 LSB

Differential Nonlinearity

0.9

LSB max

Guaranteed Monotonic Over Temperature

Zero-Scale Error

LSB max

REF

(+) = +5 V, V

REF

() = 5 V. Typically within

1 LSB

Full-Scale Error

LSB max

REF

(+) = +5 V, V

REF

() = 5 V. Typically within

1 LSB

Gain Error

LSB typ

REF

(+) = +5 V, V

REF

() = 5 V

Gain Temperature Coefficient

0.5

ppm FSR/

C typ

ppm FSR/

C max

DC Crosstalk

120

V max

See Terminology. Typically 75

REFERENCE INPUTS

DC Input Impedance

100

typ

Input Current

A max

Per Input. Typically

0.03

REF

(+) Range

0/+5

V min/max

REF

() Range

5/0

V min/max

REF

(+) V

REF

()]

+2/+10

V min/max

For Specified Performance. Can Go as Low as 0 V, but
Performance Not Guaranteed

DUTGND INPUTS

DC Input Impedance

typ

Max Input Current

0.3

mA typ

Per Input

Input Range

2/+2

V min/max

OUTPUT CHARACTERISTICS

Output Voltage Swing

V min

REF

() + [V

REF

(+) V

REF

()]

D) V

DUTGND

Short Circuit Current

mA max

Resistive Load

min

To 0 V

Capacitive Load

pF max

To 0 V

DC Output Impedance

0.5

max

DIGITAL INPUTS

INH

, Input High Voltage

2.4

V min

INL

, Input Low Voltage

0.8

V max

INH

, Input Current

Total for All Pins

@ +25

A max

MIN

to T

MAX

A max

, Input Capacitance

pF max

POWER REQUIREMENTS

+4.75/+5.25

V min/max

For Specified Performance

+14.25/+15.75 V min/max

For Specified Performance

14.25/15.75

V min/max

For Specified Performance

Power Supply Sensitivity

Full Scale/

dB typ

Full Scale/

dB typ

0.5

mA max

INH

= V

, V

INL

= GND. Dynamic Current

mA max

Outputs Unloaded. Typically 8 mA

mA max

Outputs Unloaded. Typically 8 mA

NOTES

Temperature range for A Version: 40

C to +85

Guaranteed by characterization. Not production tested.

The AD7839 is functional with power supplies of

12 V

10% with reduced output range. At 12 V it is recommended to restrict reference range to

4 V due to

output amplifier headroom limitations

Specifications subject to change without notice.

REV. 0

AD7839

(These characteristics are included for Design Guidance and are not subject
to production testing.)

AC PERFORMANCE CHARACTERISTICS

Parameter

Units

Test Conditions/Comments

DYNAMIC PERFORMANCE

Output Voltage Settling Time

s typ

Full-Scale Change to

1/2 LSB. DAC Latch Contents Alternately

s max

Loaded with All 0s and All 1s

Slew Rate

0.7

s typ

Digital-to-Analog Glitch Impulse

230

nV-s typ

Measured with V

REF

(+) = +5 V, V

REF

() = 5 V. DAC Latch

Alternately Loaded with 0FFF Hex and 1000 Hex. Not Dependent
on Load Conditions

Channel-to-Channel Isolation

dB typ

See Terminology

DAC-to-DAC Crosstalk

nV-s typ

See Terminology

Digital Crosstalk

0.2

nV-s typ

Feedthrough to DAC Output Under Test Due to Change in Digital
Input Code to Another Converter

Digital Feedthrough

0.1

nV-s typ

Effect of Input Bus Activity on DAC Output Under Test

Output Noise Spectral Density

@ 1 kHz

200

nV/

typ

All 1s Loaded to DAC. V

REF

(+) = V

REF

() = 0 V

Specifications subject to change without notice.

TIMING SPECIFICATIONS

1, 2

Parameter

Limit at T

MIN,

MAX

Units

Description

ns min

Address to

WR Setup Time

ns min

Address to

WR Hold Time

ns min

CS Pulsewidth Low

ns min

WR Pulsewidth Low

ns min

CS to WR Setup Time

ns min

WR to CS Hold Time

ns min

Data Setup Time

ns min

Data Hold Time

s typ

Settling Time

300

ns max

CLR Pulse Activation Time

ns min

LDAC Pulsewidth Low

NOTES

All input signals are specified with tr = tf = 5 ns (10% to 90% of 5 V) and timed from a voltage level of 1.6 V.

Rise and fall times should be no longer than 50 ns.

Specifications subject to change without notice.

LDAC

CLR

A0, A1, A2

DATA

OUT

Figure 1. Timing Diagram

= +5 V 5%; V

= +15 V 5%; V

= 15 V 5%; GND = DUTGND = 0 V)

AD7839

REV. 0

ABSOLUTE MAXIMUM RATINGS

1, 2

= +25

C unless otherwise noted)

to GND

. . . . . . . . . . . . . . . 0.3 V, +7 V or V

+ 0.3 V

(Whichever Is Lower)

to GND . . . . . . . . . . . . . . . . . . . . . . . . . . . 0.3 V, +17 V

to GND . . . . . . . . . . . . . . . . . . . . . . . . . . . . +0.3 V, 17 V

Digital Inputs to GND . . . . . . . . . . . . . . 0.3 V, V

+ 0.3 V

REF

(+) to V

REF

() . . . . . . . . . . . . . . . . . . . . . . 0.3 V, +18 V

REF

(+) to GND . . . . . . . . . . . . . . . V

0.3 V, V

+ 0.3 V

REF

() to GND . . . . . . . . . . . . . . . V

0.3 V, V

+ 0.3 V

DUTGND to GND . . . . . . . . . . . . . V

0.3 V, V

+ 0.3 V

OUT

(AH) to GND . . . . . . . . . . . . V

0.3 V, V

+ 0.3 V

Operating Temperature Range

Industrial (A Version) . . . . . . . . . . . . . . . . 40

C to +85

Storage Temperature Range . . . . . . . . . . . . 65

C to +150

Junction Temperature (T

max) . . . . . . . . . . . . . . . . . . +150

MQFP Package

Power Dissipation . . . . . . . . . . . . . . . . . . (T

max T

)

Thermal Impedance . . . . . . . . . . . . . . . . . . . . . 95

C/W

Lead Temperature, Soldering

Vapor Phase (60 sec) . . . . . . . . . . . . . . . . . . . . . . . . +215

Infrared (15 sec) . . . . . . . . . . . . . . . . . . . . . . . . . . . +220

ESD Rating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . >4000 V

NOTES

Stresses above those listed under Absolute Maximum Ratings may cause perma-

nent damage to the device. This is a stress rating only; functional operation of the
device at these or any other conditions above those indicated in the operational
section of this specification is not implied. Exposure to absolute maximum rating
conditions for extended periods may affect device reliability.

Transient currents of up to 100 mA will not cause SCR latch-up.

must not exceed V

by more than 0.3 V. If it is possible for this to happen

during power supply sequencing, the following diode protection scheme will ensure
protection.

ORDERING GUIDE

Linearity

Temperature

Error

DNL

Package

Model

Range

(LSBs)

Option*

AD7839AS

C to +85

S-44

*S = Plastic Quad Flatpack (MQFP).

PIN CONFIGURATION

PIN 1
IDENTIFIER

TOP VIEW

(Not to Scale)

DUTGND_GH

OUT

REF

()GH

REF

(+)GH

CLR

DB12

AD7839

DUTGND_AB

OUT

REF

()AB

REF

(+)AB

LDAC

DB11

DB10

DB9

DB8

DB4

OUT

DUTGND_CD

OUT

DUTGND_EF

OUT

DB7

DB5

DB6

DB2

GND

DB0

DB1

DB3

REF

()CDEF

REF

(+)CDEF

AD7839

IN4148

HP5082-2811

AD7839

REV. 0

PIN FUNCTION DESCRIPTIONS

Pin
No.

Mnemonic

Description

DUTGND_AB

Device Sense Ground for DACs A and B. V

OUT

A and V

OUT

B are referenced to the voltage

applied to this pin.

2, 44, 43,

OUT

A . . V

OUT

DAC Outputs.

41, 37, 35,
34, 32

4, 3

REF

(+)AB, V

REF

()AB

Reference Inputs for DACs A and B. These reference voltages are referred to GND.

Positive Analog Power Supply; +15 V

5%.

Negative Analog Power Supply; 15 V

5%.

LDAC

Load DAC Logic Input (active low). When this logic input is taken low the contents of the
input registers are transferred to their respective DAC registers.

LDAC can be tied perma-

nently low enabling the outputs to be updated on the rising edge of

WR.

10, 9, 8

A0, A1, A2

Address inputs. A0, A1 and A2 are decoded to select one of the eight input registers for a
data transfer.

Level-Triggered Chip Select Input (active low). The device is selected when this input is low.

Level-Triggered Write Input (active low), used in conjunction with

CS to write data to the

AD7839 input registers. Data is latched into the selected input register on the rising edge of
WR.

Logic Power Supply; +5 V

5%.

GND

Ground.

1527

DB0 . . DB12

Parallel Data Inputs. The AD7839 can accept a straight 13-bit parallel word on DB0 to DB12
where DB12 is the MSB and DB0 is the LSB.

CLR

Asynchronous Clear Input (level sensitive, active low). When this input is low, all analog
outputs are switched to the externally set potential on the relevant DUTGND pin. The con-
tents of input registers and DAC registers A to H are not affected when the

CLR pin is taken

low. When

CLR is brought back high, the DAC outputs revert to their original outputs as

determined by the data in their DAC registers.

30, 31

REF

(+)GH, V

REF

()GH

Reference Inputs for DACs G and H. These reference voltages are referred to GND.

DUTGND_GH

Device Sense Ground for DACs G and H. V

OUT

G and V

OUT

H are referenced to the voltage

applied to this pin.

DUTGND_EF

Device Sense Ground for DACs E and F. V

OUT

E and V

OUT

F are referenced to the voltage

applied to this pin.

REF

(+)CDEF

Reference Inputs for DACs C, D, E and F. These reference voltages are referred to GND.

REF

()CDEF

DUTGND_CD

Device Sense Ground for DACs C and D. V

OUT

C and V

OUT

D are referenced to the voltage

applied to this pin.

AD7839

REV. 0

TERMINOLOGY
Relative Accuracy

Relative accuracy or endpoint linearity is a measure of the max-
imum deviation from a straight line passing through the end-
points of the DAC transfer function. It is measured after adjust-
ing for zero error and full-scale error and is normally expressed
in Least Significant Bits.

Differential Nonlinearity

Differential nonlinearity is the difference between the measured
change and the ideal 1 LSB change between any two adjacent
codes. A specified differential nonlinearity of 1 LSB maximum
ensures monotonicity.

DC Crosstalk

Although the common input reference voltage signals are inter-
nally buffered, small IR drops in the individual DAC reference
inputs across the die can mean that an update to one channel
can produce a dc output change in one or another of the chan-
nel outputs.

The eight DAC outputs are buffered by op amps that share
common V

and V

power supplies. If the dc load current

changes in one channel (due to an update), this can result in a
further dc change in one or another of the channel outputs. This
effect is most obvious at high load currents and reduces as the
load currents are reduced. With high impedance loads the effect
is virtually unmeasurable.

Output Voltage Settling Time

This is the amount of time it takes for the output to settle to a
specified level for a full-scale input change.

Digital-to-Analog Glitch Impulse

This is the amount of charge injected into the analog output
when the inputs change state. It is specified as the area of the
glitch in nV-secs. It is measured with V

REF

(+) = +5 V and

REF

() = 5 V and the digital inputs toggled between 0FFFH and

1000H.

Channel-to-Channel Isolation

Channel-to-channel isolation refers to the proportion of input
signal from one DAC's reference input that appears at the out-
put of another DAC. It is expressed in dBs.

DAC-to-DAC Crosstalk

DAC-to-DAC crosstalk is defined as the glitch impulse that
appears at the output of one converter due to both the digital
change and subsequent analog O/P change at another converter.
It is specified in nV-secs.

Digital Crosstalk

The glitch impulse transferred to the output of one converter
due to a change in digital input code to the other converter is
defined as the digital crosstalk and is specified in nV-secs.

Digital Feedthrough

When the device is not selected, high frequency logic activity on
the device's digital inputs can be capacitively coupled both
across and through the device to show up as noise on the V

OUT

pins. This noise is digital feedthrough.

DC Output Impedance

This is the effective output source resistance. It is dominated by
package lead resistance.

Full-Scale Error

This is the error in DAC output voltage when all 1s are loaded
into the DAC latch. Ideally the output voltage, with all 1s loaded
into the DAC latch, should be 2 V

REF

(+) 1 LSB.

Zero-Scale Error

Zero-scale error is the error in the DAC output voltage when all
0s are loaded into the DAC latch. Ideally the output voltage,
with all 0s in the DAC latch should be equal to 2 V

REF

(). Zero-

scale error is mainly due to offsets in the output amplifier.

Gain Error

Gain Error is defined as (Full-Scale Error) (Zero-Scale Error).

GENERAL DESCRIPTION
DAC Architecture--General

Each channel consists of a straight 13-bit R-2R voltage-mode
DAC. The full-scale output voltage range is equal to twice the
reference span of V

REF

(+) V

REF

(). The DAC coding is straight

binary; all 0s produces an output of 2 V

REF

(); all 1s produces

an output of 2 V

REF

(+) 1 LSB.

The analog output voltage of each DAC channel reflects the
contents of its own DAC register. Data is transferred from the
external bus to the input register of each DAC on a per channel
basis.

Bringing the

CLR line low switches all the signal outputs, V

OUT

to V

OUT

H, to the voltage level on the DUTGND pin. When the

CLR signal is brought back high, the output voltages from the
DACs will reflect the data stored in the relevant DAC registers.

Data Loading to the AD7839

Data is loaded into the AD7839 in straight parallel 13-bit wide
words.

The DAC output voltages, V

OUT

A V

OUT

H are updated to

reflect new data in the DAC registers.

The actual input register being written to is determined by the
logic levels present on the device's address lines, as shown in
Table I.

Table I. Address Line Truth Table

DAC Selected

INPUT REG A (DAC A)

INPUT REG B (DAC B)

INPUT REG C (DAC C)

INPUT REG D (DAC D)

INPUT REG E (DAC E)

INPUT REG F (DAC F)

INPUT REG G (DAC G)

INPUT REG H (DAC H)

AD7839

REV. 0

Typical Performance Characteristics

INL ERROR LSBs

CODE

0.75

1.0

2048

0.50

0.0

0.50

0.75

0.25

4096

6144

8191

1.0

0.25

= +15V

= 15V

REF(+)

= +5V

REF()

= 5V

= +25 C

Figure 2. Typical INL Plot

DNL ERROR LSBs

1.0

0.75

0.25

0.50

0.75

1.0

0.25

0.50

TEMPERATURE C

40

100

20

= +15V

= 15V

REF(+)

= +5V

REF()

= 5V

MAX DNL

MIN DNL

Figure 5. Typical DNL Error vs.
Temperature

0.6

0.1

0.2

VOLTS

0.1

0.2

0.3

0.4

0.5

50 150 200

300

250

400

500

350

450

550

Figure 8. Typical Digital-to-Analog
Glitch Impulse

CODE

0.50

2048

4096

6144

8192

DNL ERROR LSBs

0.25

0.0

0.50

0.25

= +15V

= 15V

REF(+)

= +5V

REF()

= 5V

= +25 C

Figure 3. Typical DNL Plot

ERROR LSBs

TEMPERATURE C

2.0

1.0

2.0

1.0

40

20

100

= +15V

= 15V

REF(+)

= +5V

REF()

= 5V

1.5

0.5

1.5

0.5

FULL-SCALE ERROR

ZERO-SCALE ERROR

Figure 6. Zero-Scale and Full-Scale
Error vs. Temperature

OUT

 Volts

10.19

10.17

10.16

10.18

SETTLING TIME s

Figure 9. Settling Time (+)

INL ERROR LSBs

TEMPERATURE C

2.0

1.0

40

20

100

= +15V

= 15V

REF(+)

= +5V

REF()

= 5V

1.5

1.0

0.5

0.0

0.5

1.5

MAX INL

MIN INL

Figure 4. Typical INL Error vs.
Temperature

TEMPERATURE C

40

100

20

 mA

= +5V

= +15V

= 15V

DIGITAL INPUTS @ SUPPLIES

DIGITAL INPUTS @
THRESHOLDS

Figure 7. I

vs. Temperature

40

20

 mA

TEMPERATURE °C

100

= +15V

= 15V

= +5V

Figure 10. I

, I

vs. Temperature

AD7839

REV. 0

Unipolar Configuration

Figure 11 shows the AD7839 in the unipolar binary circuit
configuration. The V

REF

(+) input of the DAC is driven by the

AD586, a +5 V reference. V

REF

() is tied to ground. Table II

gives the code table for unipolar operation of the AD7839.
Other suitable references include the REF02, a precision +5 V
reference, and the REF195, a low dropout, micropower preci-
sion +5 V reference.

AD7839*

REF

(+)

OUT

DUTGND

GND

REF

()

SIGNAL

GND

15V

OUT

(0 TO +10V)

+5V

+15V

AD586

R1
10k

1 F

SIGNAL

GND

*ADDITIONAL PINS OMITTED FOR CLARITY

Figure 11. Unipolar +10 V Operation

Offset and gain may be adjusted in Figure 11 as follows: To
adjust offset, disconnect the V

REF

() input from 0 V, load the

DAC with all 0s and adjust the V

REF

() voltage until V

OUT

= 0 V.

For gain adjustment, the AD7839 should be loaded with all 1s
and R1 adjusted until V

OUT

= 2 V

REF

(+) 1 LSB = 10 V(8191/

8192) = 9.99878 V.

Many circuits will not require these offset and gain adjustments.
In these circuits R1 can be omitted. Pin 5 of the AD586 may be
left open circuit and Pin 2 (V

REF

()) of the AD7839 tied to 0 V.

Table II. Code Table for Unipolar Operation

Binary Number in DAC Register

Analog Output

MSB

LSB

OUT

)

1111

2 V

REF

(8191/8192) V

0000

2 V

REF

(4096/8192) V

1111

2 V

REF

(4095/8192) V

0000

0001

2 V

REF

(1/8192) V

0000

0 V

NOTES
V

REF

= V

REF

(+); V

REF

() = 0 V for unipolar operation.

For V

REF

(+) = +5 V, 1 LSB = +10 V/2

= +10 V/8192 = 1.22 mV.

Bipolar Configuration

Figure 12 shows the AD7839 set up for

10 V operation. The

AD588 provides precision

5 V tracking outputs that are fed to

the V

REF

(+) and V

REF

() inputs of the AD7839. The code table

for bipolar operation of the AD7839 is shown in Table III.

In Figure 12, full-scale and bipolar zero adjustments are pro-
vided by varying the gain and balance on the AD588. R2 varies
the gain on the AD588 while R3 adjusts the offset of both the
+5 V and 5 V outputs together with respect to ground.

For bipolar-zero adjustment, the DAC is loaded with
1000 . . . 0000 and R3 is adjusted until V

OUT

= 0 V. Full

scale is adjusted by loading the DAC with all 1s and adjusting
R2 until V

OUT

= 10(4095/4096) V = 9.997559 V.

When bipolar-zero and full-scale adjustment are not needed, R2
and R3 can be omitted. Pin 12 on the AD588 should be con-
nected to Pin 11 and Pin 5 should be left floating.

AD7839*

REF

(+)

OUT

DUTGND

GND

REF

()

SIGNAL

GND

15V

OUT

(10V TO +10V)

+5V

+15V

*ADDITIONAL PINS OMITTED FOR CLARITY

39k

1 F

100k

AD588

8 13

Figure 12. Bipolar

10 V Operation

Table III. Code Table for Bipolar Operation

Binary Number in DAC
Register

Analog Output

MSB LSB

OUT

)

1111

2[V

REF

() + V

REF

(8191/8192)] V

0000

0001

2[V

REF

() + V

REF

(4097/8192)] V

0000

2[V

REF

() + V

REF

(4096/8192)] V

1111

2[V

REF

() + V

REF

(4095/8192)] V

0000

0001

2[V

REF

() + V

REF

(1/8192)] V

0000

2[V

REF

()] V

NOTES
V

REF

= (V

REF

(+) V

REF

()).

For V

REF

(+) = +5 V, and V

REF

() = 5 V, V

REF

= 10 V, 1 LSB = 2 V

REF

V/2

20 V/8192 = 2.44 mV.

CONTROLLED POWER-ON OF THE OUTPUT STAGE

A block diagram of the output stage of the AD7839 is shown in
Figure 13. It is capable of driving a load of 5 k

in parallel with

50 pF. G

to G

are transmission gates used to control the

power on voltage present at V

OUT

. On power up G

and G

are

also used in conjunction with the

CLR input to set V

OUT

to the

user defined voltage present at the DUTGND pin. When

CLR

is taken back high, the DAC outputs reflect the data in the DAC
registers.

DUTGND

OUT

R = 60k

14k

DAC

Figure 13. Block Diagram of AD7839 Output Stage

AD7839

REV. 0

Power-On with

CLR Low

The output stage of the AD7839 has been designed to allow
output stability during power-on. If

CLR is kept low during

power-on, then just after power is applied to the AD7839, the
situation is as depicted in Figure 14. G

, G

and G

are open

while G

, G

and G

are closed.

DUTGND

OUT

14k

DAC

Figure 14. Output Stage with V

< 7 V or V

> 3 V;

CLR Low

OUT

is kept within a few hundred millivolts of DUTGND via

and a 14 k

resistor. This thin-film resistor is connected in

parallel with the gain resistors of the output amplifier. The
output amplifier is connected as a unity gain buffer via G

, and

the DUTGND voltage is applied to the buffer input via G

. The

amplifier's output is thus at the same voltage as the DUTGND
pin. The output stage remains configured as in Figure 14 until
the voltage at V

exceeds 7 V and V

is more negative than

3 V. By now the output amplifier has enough headroom to
handle signals at its input and has also had time to settle. The
internal power-on circuitry opens G

and G

and closes G

and

. This situation is shown in Figure 15. Now the output ampli-

fier is configured in its noise gain configuration via G

and G

The DUTGND voltage is still connected to the noninverting
input via G

and this voltage appears at V

OUT

DUTGND

OUT

14k

DAC

Figure 15. Output Stage with V

> 7 V and V

< 3 V;

CLR Low

OUT

has been disconnected from the DUTGND pin by the

opening of G

, but will track the voltage present at DUTGND

via the configuration shown in Figure 15.

When

CLR is taken back high, the output stage is configured as

shown in Figure 16. The internal control logic closes G

and

opens G

. The output amplifier is connected in a noninverting

gain-of-two configuration. The voltage that appears on the V

OUT

pins is determined by the data present in the DAC registers.

DUTGND

OUT

14k

DAC

Figure 16. Output Stage After

CLR Is Taken High

Power-On with

CLR High

CLR is high on the application of power to the device, the

output stages of the AD7839 are configured as in Figure 17
while V

is less than 7 V and V

is more positive than 3 V.

is closed and G

is open, thereby connecting the output of the

DAC to the input of its output amplifier. G

and G

are closed

while G

and G

are open, thus connecting the output amplifier as

a unity gain buffer. V

OUT

is connected to DUTGND via G

through a 14 k

resistor until V

exceeds 7 V and V

is more

negative than 3 V.

DUTGND

OUT

14k

DAC

Figure 17. Output Stage Powering Up with

CLR High

While V

< 7 V or V

> 3 V

When the difference between the supply voltages reaches +10 V,
the internal power-on circuitry opens G

and G

and closes G

and G

configuring the output stage as shown in Figure 18.

DUTGND

OUT

14k

DAC

Figure 18. Output Stage Powering Up with

CLR High;

> 7 V and V

< 3 V

AD7839

REV. 0

DUTGND Voltage Range

During power-on, the V

OUT

pins of the AD7839 are connected

to the relevant DUTGND pins via G

and the 14 k

thin-film

resistor. The DUTGND potential must obey the max ratings at
all times. Thus, the voltage at DUTGND must always be within
the range V

0.3 V, V

+ 0.3 V. However, in order that the

voltages at the V

OUT

pins of the AD7839 stay within

2 V of the

relevant DUTGND potential during power-on, the voltage
applied to DUTGND should also be kept within the range
GND 2 V, GND + 2 V.

Once the AD7839 has powered on and the on-chip amplifiers
have settled, any voltage that is now applied to the DUTGND
pin is subtracted from the DAC output, which has been gained
up by a factor of two. Thus, for specified operation, the maxi-
mum voltage that can be applied to the DUTGND pin in-
creases to the maximum allowable 2 V

REF

(+) voltage, and the

minimum voltage that can be applied to DUTGND is the
minimum 2 V

REF

() voltage. After the AD7839 has fully

powered on, the outputs can track any DUTGND voltage within
this minimum/maximum range.

Power Supply Sequencing

When operating the AD7839, it is important that ground be
connected at all times to avoid high current states. The recom-
mended power-up sequence is V

followed by V

. If V

can exceed V

on power-up, the diode scheme shown in the

absolute max ratings will ensure protection. The reference in-
puts and digital inputs should be powered up last. Should the
references exceed V

on power-up, current limiting resis-

tors should be inserted in series with the reference inputs to
limit the current to 20 mA. Logic inputs should not be applied
before V

. Current limiting resistors (470

), in series with the

logic inputs, should be inserted if these inputs come up before V

MICROPROCESSOR INTERFACING
Interfacing the AD7839--16-Bit Interface

The AD7839 can be interfaced to a variety of 16-bit micro-
controllers or DSP processors. Figure 19 shows the AD7839
interfaced to a generic 16-bit microcontroller/DSP processor.
The lower address lines from the processor are connected to A0,
A1 and A2 on the AD7839 as shown. The upper address lines
are decoded to provide a chip select signal or an

LDAC signal

for the AD7839. The fast interface timing of the AD7839 allows
direct interface to a wide variety of microcontrollers and DSPs
as shown in Figure 19.

AD7839

CONTROLLER/

DSP PROCESSOR*

ADDRESS

DECODE

D12

DATA

BUS

UPPER BITS OF

ADDRESS BUS

*ADDITIONAL PINS OMITTED FOR CLARITY

D12

LDAC

Figure 19. AD7839 Parallel Interface

APPLICATIONS
Power Supply Bypassing and Grounding

In any circuit where accuracy is important, careful consideration
of the power supply and ground return layout helps to ensure
the rated performance. The printed circuit board on which the
AD7839 is mounted should be designed such that the analog
and digital sections are separated and confined to certain areas
of the board. This facilitates the use of ground planes that can
be easily separated. A minimum etch technique is generally best
for ground planes as it gives the best shielding. Digital and ana-
log ground planes should be joined at only one place. The GND
pin of the AD7839 should be connected to the AGND of the
system. If the AD7839 is in a system where multiple devices
require an AGND-to-DGND connection, the connection should
be made at one point only, a star ground point that should be
established as close as possible to the AD7839.

Digital lines running under the device should be avoided as
these will couple noise onto the die. The analog ground plane
should be allowed to run under the AD7839 to avoid noise
coupling. The power supply lines of the AD7839 should use as
large a trace as possible to provide low impedance paths and
reduce the effects of glitches on the power supply line. Fast
switching signals like clocks should be shielded with digital
ground to avoid radiating noise to other parts of the board and
should never be run near the analog inputs.

Avoid crossover of digital and analog signals. Traces on opposite
sides of the board should run at right angles to each other. This
reduces the effects of feedthrough through the board. A micro-
strip technique is by far the best but not always possible with a
double sided board. In this technique, the component side of
the board is dedicated to ground plane while signal traces are
placed on the solder side.

The AD7839 should have ample supply bypassing located as
close to the package as possible, ideally right up against the
device. Figure 20 shows the recommended capacitor values of
10

F in parallel with 0.1

F on each of the supplies. The 10

capacitors are the tantalum bead type. The 0.1

F capacitor

should have low Effective Series Resistance (ESR) and Effective
Series Inductance (ESI), such as the common ceramic types,
which provide a low impedance path to ground at high frequen-
cies to handle transient currents due to internal logic switching.

10 F

0.1 F

10 F

0.1 F

10 F

0.1 F

AD7839

Figure 20. Recommended Decoupling Scheme for AD7839

AD7839

REV. 0

Automated Test Equipment

The AD7839 is particularly suited for use in an automated test
environment. Figure 21 shows the AD7839 providing the neces-
sary voltages for the pin driver and the window comparator in a
typical ATE pin electronics configuration. AD588s are used to
provide reference voltages for the AD7839. In the configuration
shown, the AD588s are configured so that the voltage at Pin 1 is
5 V greater than the voltage at Pin 9 and the voltage at Pin 15 is
5 V less than the voltage at Pin 9.

AD7839*

REF

(+)AB

OUT

DUTGND GH

OUT

GND

DUTGND AB

*ADDITIONAL PINS OMITTED FOR CLARITY

OUT

REF

()AB

REF

(+)GH

REF

()GH

TO TESTER

WINDOW

COMPARATOR

OUT

DEVICE
GND

15V

+15V

PIN

DRIVER

AD588

0.1 F

OFFSET

+15V 15V

AD588

+15V 15V

10
11
12

1 F

DEVICE
GND

1 F

Figure 21. ATE Application

One of the AD588s is used as a reference for DACs A and B.
These DACs are used to provide high and low levels for the pin
driver. The pin driver may have an associated offset. This can
be nulled by applying an offset voltage to Pin 9 of the AD588.
First, the code 1000 . . . 0000 is loaded into the DACA latch
and the pin driver output is set to the DACA output. The
V

OFFSET

voltage is adjusted until 0 V appears between the pin

driver output and DUT GND. This causes both V

REF

(+) and

REF

() to be offset with respect to GND by an amount equal to

OFFSET

. However, the output of the pin driver will vary from

10 V to +10 V with respect to DUTGND as the DAC input
code varies from 000 . . . 000 to 111 . . . 111. The V

OFFSET

voltage is also applied to the DUTGND pins. When a clear is
performed on the AD7839, the output of the pin driver will be
0 V with respect to DUTGND.

The other AD588 is used to provide a reference voltage for
DACs G and H. These provide the reference voltages for the
window comparator shown in the diagram. Note that Pin 9 of
this AD588 is connected to Device GND. This causes V

REF

(+)GH

and V

REF

()GH to be referenced to Device GND. As DAC G

and DAC H input codes vary from 000 . . . 000 to 111 . . . 111,
V

OUT

G and V

OUT

H vary from 10 V to +10 V with respect to

Device GND. Device GND is also connected to DUTGND.
When the AD7839 is cleared, V

OUT

G and V

OUT

H are cleared to

0 V with respect to Device GND.

TrimDAC is a registered trademark of Analog Devices, Inc.

Programmable Reference Generation for the AD7839 in an
ATE Application

The AD7839 is particularly suited for use in an automated test
environment. The reference input for the AD7839 octal 13-bit
DAC requires three differential references for the eight DACs.
Programmable references may be a requirement in some ATE
applications as the offset and gain errors at the output of a DAC
can be adjusted by varying the voltages on the reference pins of
the DAC. To trim offset errors, the DAC is loaded with the
digital code 000 . . . 000 and the voltage on the V

REF

() pin is

adjusted until the desired negative output voltage is obtained.
To trim out gain errors, first the offset error is trimmed. Then
the DAC is loaded with the code 111 . . . 111 and the voltage
on the V

REF

(+) pin is adjusted until the desired full-scale voltage

minus one LSB is obtained.

It is not uncommon in ATE design, to have other circuitry at
the output of the AD7839 that can have offset and gain errors of
up to say

300 mV. These offset and gain errors can be easily

removed by adjusting the reference voltages of the AD7839.
The AD7839 uses nominal reference values of

5 V to achieve

an output span of

10 V. Since the AD7839 has a gain of two

from the reference inputs to the DAC output, adjusting the
reference voltages by

150 mV will adjust the DAC offset and

gain by

300 mV.

There are a number of suitable 8- and 10-bit DACs available
that would be suitable to drive the reference inputs of the
AD7839, such as the AD7804, a quad 10-bit digital-to-analog
converter with serial load capabilities. The voltage output from
this DAC is in the form of V

BIAS

SWING

and rail-to-rail opera-

tion is achievable. The voltage reference for this DAC can be
internally generated or provided externally. This DAC also
contains an 8-bit SUB DAC which can be used to shift the
complete transfer function of each DAC around the V

BIAS

point.

This can be used as a fine trim on the output voltage. In this
application two AD7804s are required to provide programmable
reference capability for all eight DACs. One AD7804 is used to
drive the V

REF

(+) pins and the second package used to drive the

REF

() pins.

Another suitable DAC for providing programmable reference
capability is the AD8803. This is an octal 8-bit trimDAC

and

provides independent control of both the top and bottom ends
of the trimDAC. This is helpful in maximizing the resolution of
devices with a limited allowable voltage control range.

The AD8803 has an output voltage range of GND to V

(0 V

to +5 V). To trim the V

REF

(+) input, the appropriate trim range

on the AD8803 DAC can be set using the V

REFL

and V

REFH

pins

allowing 8 bits of resolution between the two points. This will
allow the V

REF

(+) pin to be adjusted to remove gain errors.

To trim the V

REF

() voltage, some method of providing a trim

voltage in the required negative voltage range is required. Nei-
ther the AD7804 or the AD8803 can provide this range in nor-
mal operation as their output range is 0 V to +5 V. There are
two methods of producing this negative voltage. One method is
to provide a positive output voltage and then to level shift that
analog voltage to the required negative range. Alternatively

AD7839

REV. 0

C316824/99

PRINTED IN U.S.A.

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

44-Lead MQFP (S-44)

0.548 (13.925)

0.546 (13.875)

TOP VIEW

(PINS DOWN)

0.033 (0.84)

0.029 (0.74)

0.398 (10.11)

0.390 (9.91)

0.016 (0.41)

0.012 (0.30)

0.083 (2.11)

0.077 (1.96)

0.040 (1.02)

0.032 (0.81)

0.040 (1.02)

0.032 (0.81)

SEATING

PLANE

0.096 (2.44)

MAX

0.037 (0.94)

0.025 (0.64)

8°

0.8°

GND

8/10-BIT

DAC

GND

8/10-BIT

DAC

LOGIC LEVEL

SHIFT

+5V

SCLK

D IN

FSIN/CS

SCLK

D IN

FSIN/CS

0V TO +5V

0V TO 5V

REF

(+)AB

A0, A1, A2

OUT

REF

( )AB

AD7839*

GND

DATA BUS

ADDR

DECODER

ADDR BUS

SDATA

SCLK

DATA BUS

CONTROLLER

*ADDITIONAL PINS OMITTED FOR CLARITY

Figure 22. Programmable Reference Generation for the AD7839

these DACs can be operated with supplies of 0 V and 5 V, with
the V

pin connected to 0 V and the GND pin connected to

5 V. Now these can be used to provide the negative reference
voltages for the V

REF

() inputs on the AD7839. However, the

digital signals driving the DACs need to be level-shifted from
the 0 V to +5 V range to the 5 V to 0 V range. Figure 22 shows
a typical application circuit to provide programmable reference
capabilities for the AD7839.

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