DAC8408GP View Datasheet(PDF) - Analog Devices

Part Name

Description

Manufacturer

DAC8408GP

0-7V; quad 8-bit multiplying CMOS D/A converter with memory. For voltage set points in automatic test equipment

Analog Devices 

DAC8408

BASIC APPLICATIONS

Some basic circuit configurations are shown in Figures 6 and 7.

Figure 6 shows the DAC8408 connected in a unipolar configu-

ration (2-Quadrant Multiplication), and Table I shows the Code

Table. Resistors R1, R2, R3, and R4 are used to trim full scale

output. Full-scale output voltage = VREF –1 LSB = VREF (1–2–8)

or VREF × (255/256) with all digital inputs high. Low tempera-

ture coefficient (approximately 50 ppm/°C) resistors or trim-

mers should be selected if used. Full scale can also be adjusted

using VREF voltage. This will eliminate resistors R1, R2, R3, and

R4. In many applications, R1 through R4 are not required, and

the maximum gain error will then be that of the DAC.

Each DAC exhibits a variable output resistance that is code-

dependent. This produces a code-dependent, differential non-

linearity term at the amplifier’s output which can have a maxi-

mum value of 0.67 × the amplifier’s offset voltage. This differ-

ential nonlinearity term adds to the R-2R resistor ladder differ-

ential-nonlinearity; the output may no longer be monotonic. To

maintain monotonicity and minimize gain and linearity errors, it

is recommended that the op amp offset voltage be adjusted to

less than 10% of 1 LSB (1 LSB = 2–8 × VREF or 1/256 × VREF),

or less than 3.9 mV over the operating temperature range. Zero-

scale output voltage (with all digital inputs low) may be adjusted

using the op amp offset adjustment. Capacitors C1, C2, C3,

and C4 provide phase compensation and help prevent overshoot

and ringing when using high speed op amps.

Figure 7 shows the recommended circuit configuration for the

bipolar operation (4-quadrant multiplication), and Table II shows

the Code Table. Trimmer resistors R17, R18, R19, and R20

are used only if gain error adjustments are required and range

between 50 Ω and 1000 Ω. Resistors R21, R22, R23, and R24

will range betwen 50 Ω and 500 Ω. If these resistors are used, it

is essential that resistor pairs R9–R13, R10–R14, R11–R15,

R12–R16 are matched both in value and tempco. They should

be within 0.01%; wire wound or metal foil types are preferred

for best temperature coefficient matching. The circuits of Figure

6 and 7 can either be used as a fixed reference D/A converter, or

as an attenuator with an ac input voltage.

Table I. Unipolar Binary Code Table (Refer to Figure 6)

DAC Data Input

MSB

LSB

11111111

10000001

10000000

01111111

00000001

00000000

Analog Output

 255 

–VREF  256 

 129 

–VREF  256 

 128  –VIN

–VREF  256  = 2

–VREF

 127 

 256 

–VREF

 1

 256 

 0

–VREF  256  = 0

NOTE

1

1 LSB = (2–8) (VREF) = 256 (VREF)

Figure 6. Quad DAC Unipolar Operation (2-Quadrant Multiplication)

–10–

REV. A

Share Link: