REV. B

Information furnished by Analog Devices is believed to be accurate and
reliable. However, no responsibility is assumed by Analog Devices 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 Analog Devices.

MOS Quad 8-Bit DAC

with Separate Reference Inputs

AD7225

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.
Tel: 617/329-4700

Fax: 617/326-8703

FUNCTIONAL BLOCK DIAGRAM

GENERAL DESCRIPTION

The AD7225 contains four 8-bit voltage output digital-to-
analog converters, with output buffer amplifiers and interface
logic on a single monolithic chip. Each D/A converter has a
separate reference input terminal. No external trims are re-
quired to achieve full specified performance for the part.

The double-buffered interface logic consists of two 8-bit regis-
ters per channelan input register and a DAC register. Control
inputs A0 and A1 determine which input register is loaded when
WR

goes low. Only the data held in the DAC registers deter-

mines the analog outputs of the converters. The double-
buffering allows simultaneous update of all four outputs under
control of LDAC. All logic inputs are TTL and CMOS (5 V)
level compatible and the control logic is speed compatible with
most 8-bit microprocessors.

Specified performance is guaranteed for input reference voltages
from +2 V to +12.5 V when using dual supplies. The part is also
specified for single supply operation using a reference of +10 V.
Each output buffer amplifier is capable of developing +10 V
across a 2 k

load.

The AD7225 is fabricated on an all ion-implanted high-speed
Linear Compatible CMOS (LC

MOS) process which has been

specifically developed to integrate high speed digital logic cir-
cuits and precision analog circuitry on the same chip.

FEATURES
Four 8-Bit DACs with Output Amplifiers
Separate Reference Input for Each DAC

P Compatible with Double-Buffered Inputs

Simultaneous Update of All Four Outputs
Operates with Single or Dual Supplies
Extended Temperature Range Operation
No User Trims Required
Skinny 24-Pin DIP, SOIC and 28-Terminal Surface

Mount Packages

PRODUCT HIGHLIGHTS

1. DACs and Amplifiers on CMOS Chip

The single-chip design of four 8-bit DACs and amplifiers al-
lows a dramatic reduction in board space requirements and
offers increased reliability in systems using multiple convert-
ers. Its pinout is aimed at optimizing board layout with all
analog inputs and outputs at one end of the package and all
digital inputs at the other.

2. Single or Dual Supply Operation

The voltage-mode configuration of the AD7225 allows single
supply operation. The part can also be operated with dual
supplies giving enhanced performance for some parameters.

3. Versatile Interface Logic

The AD7225 has a common 8-bit data bus with individual
DAC latches, providing a versatile control architecture for
simple interface to microprocessors. The double-buffered in-
terface allows simultaneous update of the four outputs.

4. Separate Reference Input for Each DAC

The AD7225 offers great flexibility in dealing with input sig-
nals with a separate reference input provided for each DAC
and each reference having variable input voltage capability.

REV. B

AD7225SPECIFICATIONS

DUAL SUPPLY

K, B

L, C

Parameter

Versions

T Version

U Version

Units

Conditions/Comments

STATIC PERFORMANCE

Resolution

Bits

Total Unadjusted Error

LSB max

= +15 V

5%, V

REF

= +10 V

Relative Accuracy

1/2

LSB max

Differential Nonlinearity

LSB max

Guaranteed Monotonic

Full-Scale Error

1/2

LSB max

Full-Scale Temp. Coeff.

ppm/

C typ

= 14 V to 16.5 V, V

REF

= +10 V

Zero Code Error @ 25

mV max

MIN

to T

MAX

mV max

Zero Code Error Temp Coeff.

C typ

REFERENCE INPUT

Voltage Range

2 to (V

V min to V max

Input Resistance

min

Input Capacitance

100

pF max

Occurs when each DAC is loaded with all 1s.

Channel-to-Channel Isolation

dB min

REF

= 10 V p-p Sine Wave @ 10 kHz

AC Feedthrough

dB max

REF

= 10 V p-p Sine Wave @ 10 kHz

DIGITAL INPUTS

Input High Voltage, V

INH

2.4

V min

Input Low Voltage, V

INL

0.8

V max

Input Leakage Current

A max

= 0 V or V

Input Capacitance

pF max

Input Coding

Binary

DYNAMIC PERFORMANCE

Voltage Output Slew Rate

2.5

s min

Voltage Output Settling Time

Positive Full-Scale Change

s max

REF

= +10 V; Settling Time to

1/2 LSB

Negative Full-Scale Change

s max

REF

= +10 V; Settling Time to

1/2 LSB

Digital Feedthrough

nV secs typ

Code transition all 0s to all 1s.

Digital Crosstalk

nV secs typ

Code transition all 0s to all 1s.

Minimum Load Resistance

min

OUT

= +10 V

POWER SUPPLIES

Range

11.4/16.5

V min to V max For Specified Performance

mA max

Outputs Unloaded; V

= V

INL

or V

INH

mA max

Outputs Unloaded; V

= V

INL

or V

INH

SWITCHING CHARACTERISTICS

3, 4

@ 25

ns min

Write Pulse Width

MIN

to T

MAX

120

150

ns min

@ 25

ns min

Address to Write Setup Time

MIN

to T

MAX

ns min

@ 25

ns min

Address to Write Hold Time

MIN

to T

MAX

ns min

@ 25

ns min

Data Valid to Write Setup Time

MIN

to T

MAX

ns min

@ 25

ns min

Data Valid to Write Hold Time

MIN

to T

MAX

ns min

@ 25

ns min

Load DAC Pulse Width

MIN

to T

MAX

120

150

ns min

NOTES

Maximum possible reference voltage.

Temperature ranges are as follows:

K, L Versions: 40

C to +85

B, C Versions: 40

C to +85

T, U Versions: 55

C to +125

Sample Tested at 25

C to ensure compliance.

Switching characteristics apply for single and dual supply operation.

Specifications subject to change without notice.

= 11.4 V to 16.5 V, V

= 5 V 10%; AGND = DGND = O V; V

REF

= +2 V to (V

 4 V)

unless otherwise noted.

All specifications T

MIN

to T

MAX

unless otherwise noted.)

ORDERING GUIDE

Total

Temperature

Unadjusted

Package

Model

Range

Error

Option

AD7225KN

C to +85

2 LSB

N-24

AD7225LN

C to +85

1 LSB

N-24

AD7225KP

C to +85

2 LSB

P-28A

AD7225LP

C to +85

1 LSB

P-28A

AD7225KR

C to +85

2 LSB

R-24

AD7225LR

C to +85

1 LSB

R-24

AD7225BQ

C to +85

2 LSB

Q-24

AD7225CQ

C to +85

1 LSB

Q-24

Total

Temperature

Unadjusted

Package

Model

Range

Error

Option

AD7225TQ

C to +125

2 LSB

Q-24

AD7225UQ

C to +125

1 LSB

Q-24

AD7225TE

C to +125

2 LSB

E-28A

AD7225UE

C to +125

1 LSB

E-28A

NOTES

To order MIL-STD-883 processed parts, add /883B to part number. Contact your

local sales office for military data sheet.

E = Leadless Ceramic Chip Carrier; N = Plastic DIP;

P = Plastic Leaded Chip Carrier; Q = Cerdip; R = SOIC.

AD7225

REV. B

SINGLE SUPPLY

K, B

L, C

Parameter

Versions

T Version

U Version

Units

Conditions/Comments

STATIC PERFORMANCE

Resolution

Bits

Total Unadjusted Error

LSB max

Differential Nonlinearity

LSB max

Guaranteed Monotonic

REFERENCE INPUT

Input Resistance

min

Input Capacitance

100

pF max

Occurs when each DAC is loaded with all 1s.

Channel-to-Channel Isolation

3, 4

dB min

REF

= 10 V p-p Sine Wave @ 10 kHz

AC Feedthrough

3, 4, 5

dB max

REF

= 10 V p-p Sine Wave @ 10 kHz

DIGITAL INPUTS

Input High Voltage, V

INH

2.4

V min

Input Low Voltage, V

INL

0.8

V max

Input Leakage Current

A max

= 0 V or V

Input Capacitance

pF max

Input Coding

Binary

DYNAMIC PERFORMANCE

Voltage Output Slew Rate

s min

Voltage Output Settling Time

Positive Full-Scale Change

s max

Settling Time to

1/2 LSB

Negative Full-Scale Change

s max

Settling Time to

1/2 LSB

Digital Feedthrough

3, 4

nV secs typ

Code transition all 0s to all 1s.

Digital Crosstalk

3, 4

nV secs typ

Code transition all 0s to all 1s.

Minimum Load Resistance

min

OUT

= +10 V

POWER SUPPLIES

Range

14.25/15.75

V min to V

max

For Specified Performance

mA max

Outputs Unloaded; V

= V

INL

or V

INH

SWITCHING CHARACTERISTICS

@ 25

ns min

Write Pulse Width

MIN

to T

MAX

120

150

ns min

@ 25

ns min

Address to Write Setup Time

MIN

to T

MAX

ns min

@ 25

ns min

Address to Write Hold Time

MIN

to T

MAX

ns min

@ 25

ns min

Data Valid to Write Setup Time

MIN

to T

MAX

ns min

@ 25

ns min

Data Valid to Write Hold Time

MIN

to T

MAX

ns min

@ 25

ns min

Load DAC Pulse Width

MIN

to T

MAX

120

150

ns min

NOTES

Maximum possible reference voltage.

Temperature ranges are as follows:

K, L Versions: 40

C to +85

B, C Versions: 40

C to +85

T, U Versions: 55

C to +125

= +15 V 5%; V

= AGND = DGND = O V; V

REF

= +10 V

unless otherwise noted.

All specifications T

MIN

to T

MAX

unless otherwise noted.)

Sample Tested at 25

C to ensure compliance.

Switching characteristics apply for single and dual supply operation.

Specifications subject to change without notice.

AD7225

REV. B

ABSOLUTE MAXIMUM RATINGS

to AGND . . . . . . . . . . . . . . . . . . . . . . . . . . 0.3 V, +17 V

to DGND . . . . . . . . . . . . . . . . . . . . . . . . . . 0.3 V, +17 V

to V

. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0.3 V, +24 V

AGND to DGND . . . . . . . . . . . . . . . . . . . . . . . . 0.3 V, V

Digital Input Voltage to DGND . . . . . . . 0.3 V, V

+ 0.3 V

REF

to AGND . . . . . . . . . . . . . . . . . . . . 0.3 V, V

+ 0.3 V

OUT

to AGND

. . . . . . . . . . . . . . . . . . . . . . . . . . . . V

, V

Power Dissipation (Any Package) to +75

C . . . . . . . . 500 mW

Derates above 75

C by . . . . . . . . . . . . . . . . . . . . . 2.0 mW/

Operating Temperature

Commercial (K, L Versions) . . . . . . . . . . . 40

C to +85

Industrial (B, C Versions) . . . . . . . . . . . . . 40

C to +85

Extended (T, U Versions) . . . . . . . . . . . . 55

C to +125

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

C to +150

Lead Temperature (Soldering, 10 secs) . . . . . . . . . . . +300

NOTES

Stresses above those listed under "Absolute Maximum Ratings" may cause

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

Outputs may be shorted to any voltage in the range V

to V

provided that the

power dissipation of the package is not exceeded. Typical short circuit current for
a short to AGND or V

is 50 mA.

WARNING!

ESD SENSITIVE DEVICE

CAUTION
ESD (electrostatic discharge) sensitive device. Electrostatic charges as high as 4000 V readily
accumulate on the human body and test equipment and can discharge without detection.
Although the AD7225 features proprietary ESD protection circuitry, permanent damage may
occur on devices subjected to high energy electrostatic discharges. Therefore, proper ESD
precautions are recommended to avoid performance degradation or loss of functionality.

PIN CONFIGURATIONS

DIP and SOIC

LCCC

PLCC

TERMINOLOGY
TOTAL UNADJUSTED ERROR

Total Unadjusted Error is a comprehensive specification which
includes full-scale error, relative accuracy, and zero code error.
Maximum output voltage is V

REF

1 LSB (ideal), where 1 LSB

(ideal) is V

REF

/256. The LSB size will vary over the V

REF

range.

Hence the zero code error will, relative to the LSB size, increase
as V

REF

decreases. Accordingly, the total unadjusted error,

which includes the zero code error, will also vary in terms of
LSBs over the V

REF

range. As a result, total unadjusted error is

specified for a fixed reference voltage of +10 V.

RELATIVE ACCURACY

Relative Accuracy or endpoint nonlinearity is a measure of the
maximum deviation from a straight line passing through the
endpoints of the DAC transfer function. It is measured after al-
lowing for zero code error and full-scale error and is normally
expressed in LSBs or as a percentage of full-scale reading.

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 max over

the operating temperature range ensures monotonicity.

DIGITAL FEEDTHROUGH

Digital Feedthrough is the glitch impulse transferred to the out-
put of the DAC due to a change in its digital input code. It is
specified in nV secs and is measured at V

REF

= 0 V.

DIGITAL CROSSTALK

Digital Crosstalk is the glitch impulse transferred to the output
of one converter (not addressed) due to a change in the digital
input code to another addressed converter. It is specified in
nV secs and is measured at V

REF

= 0 V.

AC FEEDTHROUGH

AC Feedthrough is the proportion of reference input signal
which appears at the output of a converter when that DAC is
loaded with all 0s.

CHANNEL-TO-CHANNEL ISOLATION

Channel-to-channel isolation is the proportion of input signal
from the reference of one DAC (loaded with all 1s) which ap-
pears at the output of one of the other three DACs (loaded with
all 0s) The figure given is the worst case for the three other out-
puts and is expressed as a ratio in dBs.

FULL-SCALE ERROR

Full-Scale Error is defined as:

Measured Value Zero Code Error Ideal Value

AD7225

REV. B

CIRCUIT INFORMATION

D/A SECTION

The AD7225 contains four, identical, 8-bit voltage mode
digital-to-analog converters. Each D/A converter has a separate
reference input. The output voltages from the converters have
the same polarity as the reference voltages, allowing single sup-
ply operation. A novel DAC switch pair arrangement on the
AD7225 allows a reference voltage range from +2 V to +12.5 V
on each reference input.

Each DAC consists of a highly stable, thin-film, R-2R ladder
and eight high speed NMOS, single-pole, double-throw
switches. The simplified circuit diagram for channel A is shown
in Figure 7. Note that AGND (Pin 6) is common to all four
DACs.

Figure 7. D/A Simplified Circuit Diagram

The input impedance at any of the reference inputs is code de-
pendent and can vary from 11 k

minimum to infinity. The

lowest input impedance at any reference input occurs when that
DAC is loaded with the digital code 01010101. Therefore, it is
important that the reference presents a low output impedance
under changing load conditions. The nodal capacitance at the
reference terminals is also code dependent and typically varies
from 15 pF to 35 pF.

Each V

OUT

pin can be considered as a digitally programmable

voltage source with an output voltage of:

OUTX

= D

· V

REFX

where D

is fractional representation of the digital input code

and can vary from 0 to 255/256.

The output impedance is that of the output buffer amplifier.

OP-AMP SECTION

Each voltage mode D/A converter output is buffered by a unity
gain noninverting CMOS amplifier. This buffer amplifier is ca-
pable of developing +10 V across a 2 k

load and can drive ca-

pacitive loads of 3300 pF.

The AD7225 can be operated single or dual supply; operating
with dual supplies results in enhanced performance in some pa-
rameters which cannot be achieved with single supply operation.
In single supply operation (V

= 0 V = AGND) the sink capa-

bility of the amplifier, which is normally 400

A, is reduced as

the output voltage nears AGND. The full sink capability of
400

A is maintained over the full output voltage range by tying

to 5 V. This is indicated in Figure 8.

Settling-time for negative-going output signals approaching
AGND is similarly affected by V

. Negative-going settling-time

for single supply operation is longer than for dual supply opera-
tion. Positive-going settling-time is not affected by V

Figure 8. Variation of I

SINK

with V

OUT

Additionally, the negative V

gives more headroom to the out-

put amplifiers which results in better zero code performance and
improved slew rate at the output, than can be obtained in the
single supply mode.

DIGITAL SECTION

The AD7225 digital inputs are compatible with either TTL or
5 V CMOS levels. All logic inputs are static protected MOS
gates with typical input currents of less than 1 nA. Internal in-
put protection is achieved by an on-chip distributed diode be-
tween DGND and each MOS gate. To minimize power supply
currents, it is recommended that the digital input voltages be
driven as close to the supply rails (V

and DGND) as practi-

cally possible.

INTERFACE LOGIC INFORMATION

The AD7225 contains two registers per DAC, an input register
and a DAC register. Address lines A0 and A1 select which input
register will accept data from the input port. When the WR sig-
nal is LOW, the input latches of the selected DAC are transpar-
ent. The data is latched into the addressed input register on the
rising edge of WR. Table I shows the addressing for the input
registers on the AD7225.

Table I. AD7225 Addressing

Selected Input Register

DAC A Input Register

DAC B Input Register

DAC C Input Register

DAC D Input Register

AD7225

REV. B

Only the data held in the DAC register determines the analog
output of the converter. The LDAC signal is common to all four
DACs and controls the transfer of information from the input
registers to the DAC registers. Data is latched into all four DAC
registers simultaneously on the rising edge of LDAC. The
LDAC

signal is level triggered and therefore the DAC registers

may be made transparent by tying LDAC LOW (in this case the
outputs of the converters will respond to the data held in their
respective input latches). LDAC is an asynchronous signal and
is independent of WR. This is useful in many applications.
However, in systems where the asynchronous LDAC can occur
during a write cycle (or vice versa) care must be taken to ensure
that incorrect data is not latched through to the output. In other
words, if LDAC is activated prior to the rising edge of WR (or
WR

occurs during LDAC), then LDAC must stay LOW for t

or longer after WR goes HIGH to ensure correct data is latched
through to the output. Table II shows the truth table for AD7225
operation. Figure 9 shows the input control logic for the part
and the write cycle timing diagram is given in Figure 10.

Table II. AD7225 Truth Table

LDAC

Function

No Operation. Device not selected

Input Register of Selected DAC Transparent

Input Register of Selected DAC Latched

All Four DAC Registers Transparent
(i.e. Outputs respond to data held in respective
input registers)
Input Registers are Latched

All Four DAC Registers Latched

DAC Registers and Selected Input Register
Transparent Output follows Input Data for
Selected Channel.

Figure 9. Input Control Logic

Figure 10. Write Cycle Timing Diagram

GROUND MANAGEMENT AND LAYOUT

Since the AD7225 contains four reference inputs which can be
driven from ac sources (see AC REFERENCE SIGNAL sec-
tion) careful layout and grounding is important to minimize
analog crosstalk between the four channels. The dynamic per-
formance of the four DACs depends upon the optimum choice
of board layout. Figure 11 shows the relationship between input

Figure 11. Channel-to-Channel Isolation

Figure 12. Suggested PCB Layout for AD7225.
Layout Shows Component Side (Top View)

frequency and channel-to-channel isolation. Figure 12 shows a
printed circuit board layout which is aimed at minimizing
crosstalk and feedthrough. The four input signals are screened
by AGND. V

REF

was limited to between 2 V and 3.24 V to

avoid slew rate limiting effects from the output amplifier during
measurements.

AD7225

REV. B

SPECIFICATION RANGES

For the AD7225 to operate to rated specifications, its input ref-
erence voltage must be at least 4 V below the V

power supply

voltage. This voltage differential is the overhead voltage re-
quired by the output amplifiers.

The AD7225 is specified to operate over a V

range from

+12 V

5% to +15 V

10% (i.e., from +11.4 V to +16.5 V)

with a V

of 5 V

10%. Operation is also specified for a single

+15 V

5% V

supply. Applying a V

of 5 V results in im-

proved zero code error, improved output sink capability with
outputs near AGND and improved negative going settling time.

Performance is specified over a wide range of reference voltages
from 2 V to (V

4 V) with dual supplies. This allows a range

of standard reference generators to be used such as the AD580,
a +2.5 V bandgap reference and the AD584, a precision +10 V
reference. Note that an output voltage range of 0 V to +10 V re-
quires a nominal +15 V

5% power supply voltage.

UNIPOLAR OUTPUT OPERATION

This is the basic mode of operation for each channel of the
AD7225, with the output voltage having the same positive
polarity as V

REF

. The AD7225 can be operated single supply

= AGND) or with positive/negative supplies (see op-amp

section which outlines the advantages of having negative V

Connections for the unipolar output operation are shown in Fig-
ure 13. The voltage at any of the reference inputs must never be
negative with respect to DGND. Failure to observe this precau-
tion may cause parasitic transistor action and possible device de-
struction. The code table for unipolar output operation is shown
in Table III.

Figure 13. Unipolar Output Circuit

Table III. Unipolar Code Table

DAC Latch Contents
MSB

LSB

Analog Output

1 1 1 1

REF

255
256

1 0 0 0

0 0 0 1

REF

129

256

1 0 0 0

0 0 0 0

REF

128

256

= +

REF

0 1 1 1

1 1 1 1

REF

127
256

0 0 0 0

0 0 0 1

REF

256

0 0 0 0

0 V

Note: 1 LSB

REF

(

)

( )

REF

256

BIPOLAR OUTPUT OPERATION

Each of the DACs of the AD7225 can be individually config-
ured to provide bipolar output operation. This is possible using
one external amplifier and two resistors per channel. Figure 14
shows a circuit used to implement offset binary coding (bipolar
operation) with DAC A of the AD7225. In this case

OUT

REF

(

)

REF

(

)

With R1 = R2

OUT

= (2 D

1) · V

REF

where D

is a fractional representation of the digital word in

latch A. (0

255/256)

Mismatch between R1 and R2 causes gain and offset errors and,
therefore, these resistors must match and track over tempera-
ture. Once again the AD7225 can be operated in single supply
or from positive/negative supplies. Table IV shows the digital
code versus output voltage relationship for the circuit of Figure
14 with R1 = R2.

AD7225

REV. B

Figure 14. AD7225 Bipolar Output Circuit

Table IV. Bipolar (Offset Binary) Code Table

DAC Latch Contents
MSB

LSB

Analog Output

1 1 1 1

REF

127
128

1 0 0 0

0 0 0 1

REF

128

1 0 0 0

0 0 0 0

0 V

0 1 1 1

1 1 1 1

REF

128

0 0 0 0

0 0 0 1

REF

127
128

0 0 0 0

REF

128
128

REF

AGND BIAS

The AD7225 AGND pin can be biased above system GND
(AD7225 DGND) to provide an offset "zero" analog output
voltage level. Figure 15 shows a circuit configuration to achieve
this for channel A of the AD7225. The output voltage, V

OUT

can be expressed as:

OUT

A = V

BIAS

+ D

)

where D

is a fractional representation of the digital word in

DAC latch A. (0

255/256).

Figure 15. AGND Bias Circuit

For a given V

, increasing AGND above system GND will re-

duce the effective V

REF

which must be at least 4 V to en-

sure specified operation. Note that because the AGND pin is
common to all four DACs, this method biases up the output
voltages of all the DACs in the AD7225. Note that V

and V

of the AD7225 should be referenced to DGND.

AC REFERENCE SIGNAL

In some applications it may be desirable to have ac reference
signals. The AD7225 has multiplying capability within the up-
per (V

4 V) and lower (2 V) limits of reference voltage when

operated with dual supplies. Therefore ac signals need to be ac
coupled and biased up before being applied to the reference in-
puts. Figure 16 shows a sine wave signal applied to V

REF

A. For

input signal frequencies up to 50 kHz the output distortion typi-
cally remains less than 0.1%. The typical 3 dB bandwidth figure
for small signal inputs is 800 kHz.

Figure 16. Applying an AC Signal to the AD7225

APPLICATIONS
PROGRAMMABLE TRANSVERSAL FILTER

A discrete-time filter may be described by either multiplication
in the frequency domain or convolution in the time domain i.e.

( )

or y

kXn k

The convolution sum may be implemented using the special
structure known as the transversal filter (Figure 17). Basically, it
consists of an N-stage delay line with N taps weighted by N co-
efficients, the resulting products being accumulated to form the
output. The tap weights or coefficients h

are actually the non-

zero elements of the impulse response and therefore determine
the filter transfer function. A particular filter frequency response
is realized by setting the coefficients to the appropriate values.
This property leads to the implementation of transversal filters
whose frequency response is programmable.

Figure 17. Transversal Filter

AD7225

REV. B

FILTER

I/P

SAMPLES

Am29520

TLD

AD7820

ADC

SAMPLES

AD7225

QUAD DAC

DELAYED

I/P

AD7226

QUAD DAC

REF

OUT

ACCUMULATOR

O/P

AD585

SHA

FILTER

O/P

TAP WEIGHTS

Am7224

DAC

AD584

REF

GAIN SET

+10V

OUT

REF

FILTER

O/P

FILTER

I/P

n1

n2

n3

REF

OUT

REF

OUT

REF

OUT

Figure 18. Programmable Transversal Filter

A 4-tap programmable transversal filter may be implemented
using the AD7225 (Figure 18). The input signal is first sampled
and converted to allow the tapped delay line function to be pro-
vided by the Am29520. The multiplication of delayed input
samples by fixed, programmable up weights is accomplished by
the AD7225, the four coefficients or reference inputs being set
by the digital codes stored in the AD7226. The resultant prod-
ucts are accumulated to yield the convolution sum output
sample which is held by the AD585.

100

0.5

70

90

0.05

80

40

60

50

30

20

10

0.45

0.4

0.35

0.3

0.25

0.2

0.15

0.1

NORMALIZED FREQUENCY f/fs

GAIN dB

= 0.117

= 0.417

Figure 19. Predicted (Theoretical) Response

Figure 20. Actual Response

Low pass, bandpass and high pass filters may be synthesized us-
ing this arrangement. The particular up weights needed for any
desired transfer function may be obtained using the standard
Remez Exchange Algorithm. Figure 19 shows the theoretical
low pass frequency response produced by a 4-tap transversal

filter with the coefficients indicated. Although the theoretical
prediction does not take into account the quantization of the in-
put samples and the truncation of the coefficients, nevertheless,
there exists a good correlation with the actual performance of
the transversal filter (Figure 20).

DIGITAL WORD MULTIPLICATION

Since each DAC of the AD7225 has a separate reference input,
the output of one DAC can be used as the reference input for
another. This means that multiplication of digital words can be
performed (with the result given in analog form). For example,
if the output from DACA is applied to V

REF

B then the output

from DACB, V

OUT

B, can be expressed as:

OUT

B = D

· D

· V

REF

where D

and D

are the fractional representations of the

digital words in DAC latches A and B respectively.

If D

= D

= D then the result is D

· V

REF

In this manner, the four DACs can be used on their own or in
conjunction with an external summing amplifier to generate
complex waveforms. Figure 21 shows one such application. In
this case the output waveform, Y, is represented by:

Y = (x

+ 2x

+ 3x

+ 2x + 4) · V

where x is the digital code which is applied to all four DAC
latches.

OUT

REF

+15V

AD7225*

DGND

AGND

25k

50k

33k

50k

100k

*DIGITAL INPUTS OMITTED
FOR CLARITY

Figure 21. Complex Waveform Generation

AD7225

REV. B

MICROPROCESSOR INTERFACE

8085A/

8088

A15

ALE

AD0

AD7

ADDRESS

DECODE

LATCH

AD7225*

A0
A1

DB7

DB0

LDAC

ADDRESS BUS

ADDRESS DATA BUS

LINEAR CIRCUITRY OMITTED FOR CLARITY

Figure 22. AD7225 to 8085A/8088 Interface,
Double-Buffered Mode

6809/

6502

A15

E OR

AD7225*

R/W

A0
A1

DB7

DB0

LDAC

ADDRESS BUS

DATA BUS

LINEAR CIRCUITRY OMITTED FOR CLARITY

ADDRESS

DECODE

Figure 23. AD7225 to 6809/6502 Interface,
Single-Buffered Mode

Z-80

A15

AD7225*

A0
A1

DB7

DB0

LDAC

ADDRESS BUS

DATA BUS

LINEAR CIRCUITRY OMITTED FOR CLARITY

ADDRESS

DECODE

MREQ

Figure 24. AD7225 to Z-80 Interface,
Double-Buffered Mode

68008

A23

AD7225*

R/W

A0
A1

DB7

DB0

LDAC

ADDRESS BUS

DATA BUS

LINEAR CIRCUITRY OMITTED FOR CLARITY

ADDRESS

DECODE

DTACK

Figure 25. AD7225 to 68008 Interface,
Single-Buffered Mode

GENERATION

Operating the AD7225 from dual supplies results in enhanced
performance over single supply operation on a number of pa-
rameters as previously outlined. Some applications may require
this enhanced performance, but may only have a single power
supply rail available. The circuit of Figure 26 shows a method of
generating a negative voltage using one CD4049, operated from
a V

of +15 V. Two inverters of the hex inverter chip are used

as an oscillator. The other four inverters are in parallel and used
as buffers for higher output current. The square-wave output is
level translated to a negative-going signal, then rectified and fil-
tered. The circuit configuration shown will provide an output
voltage of 5.1 V for current loadings in the range 0.5 mA to
9 mA. This will satisfy the AD7225 I

requirement over the

commercial operating temperature range.

1/6

CD4049AE

1/6

CD4049AE

1/6

CD4049AE

1/6

CD4049AE

1N4001

510

1/6

CD4049AE

5.1k

1/6

CD4049AE

510k

OUT

5V1

1N4001

0.02

Figure 26. V

Generation Circuit

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