6

®

DAC8043

DISCUSSION OF

SPECIFICATIONS

RELATIVE ACCURACY

This term, also known as end point linearity or integral

linearity, describes the transfer function of analog output to

digital input code. Relative accuracy describes the deviation

from a straight line, after zero and full scale errors have been

adjusted to zero.

DIFFERENTIAL NONLINEARITY

Differential nonlinearity is the deviation from an ideal 1LSB

change in the output when the input code changes by 1LSB.

A differential nonlinearity specification of 1LSB maximum

guarantees monotonicity.

GAIN ERROR

Gain error is the difference between the full-scale DAC

output and the ideal value. The ideal full scale output value

adjusted to zero using external trims as shown in Figure 4.

OUTPUT LEAKAGE CURRENT

The current which appears at I

all zeros.

OUTPUT CAPACITANCE

The parasitic capacitance measured from I

FEEDTHROUGH ERROR

I

OUTPUT CURRENT SETTLING TIME

The time required for the output current to settle to within

+0.01% of final value for a full scale step.

DIGITAL-TO-ANALOG GLITCH ENERGY

The integrated area of the glitch pulse measured in nanovolt-

seconds. The key contributor to digital-to-analog glitch is

charge injected by digital logic switching transients.

CIRCUIT DESCRIPTION

Figure 1 shows a simplified schematic of a DAC8043. The

by 12 single-pole double-throw CMOS switches. This main-

tains a constant current in each leg of the ladder regardless of

the input code. The input resistance at V

constant and can be driven by either a voltage or current, AC

or DC, positive or negative polarity, and have a voltage range

up to

±20V.

A CMOS switch transistor, included in series with the ladder

terminating resistor and in series with the feedback resistor,

tance of the ladder switches.

output capacitance due to the N-channel switches and varies

from about 80pF to 110pF with digital input code. The current

source I

R

with input code.

FB

R

OUT

I

V

REF

I

LKG

R

OUT

C

O

R

GND

D

IN

4096

x

V

REF

R

R

FIGURE 2. Equivalent Circuit for the DAC.

INSTALLATION

ESD PROTECTION

All digital inputs of the DAC8043 incorporate on-chip ESD

protection circuitry. This protection is designed to withstand

2.5kV (using the Human Body Model, 100pF and 1500

Ω).

However, industry standard ESD protection methods should

be used when handling or storing these components. When

not in use, devices should be stored in conductive foam or

rails. The foam or rails should be discharged to the destina-

tion socket potential before devices are removed.

POWER SUPPLY CONNECTIONS

For optimum performance and noise rejection, power supply

application circuits. These capacitors (1

µF tantalum recom-

mended) should be located close to the D/A. Output op amp

analog common (+ input) should be connected as near to the

GND pins of the DAC8043 as possible.

WIRING PRECAUTIONS

To minimize AC feedthrough when designing a PC board,

care should be taken to minimize capacitive coupling be-

of the digital control or data lines might degrade the glitch

without a socket. Sockets add parasitic capacitance (which

can degrade AC performance).

OUT

I

GND

FB

R

2R

2R

2R

2R

2R

RR

R

V

REF

Bit 1

(MSB)

Bit 2

Bit 3

Bit 12

(LSB)

R

FIGURE 1. Simplified Circuit Diagram for the DAC.