AD557 [ADI]

DACPORT, Low-Cost Complete mP-Compatible 8-Bit DAC; DACPORT ，低成本完成MP-兼容的8位DAC


型号：	AD557
厂家：	ADI
描述：	DACPORT, Low-Cost Complete mP-Compatible 8-Bit DAC DACPORT ，低成本完成MP-兼容的8位DAC
文件：	总4页 (文件大小：241K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

DACPORT, Low-Cost Complete

␮P-Compatible 8-Bit DAC

AD557

FUNCTIONAL BLOCK DIAGRAM

FEATURES

Complete 8-Bit DAC

Voltage Output—0 V to 2.56 V

Internal Precision Band-Gap Reference

Single-Supply Operation: +5 V (؎10%)

Full Microprocessor Interface

Fast: 1 ␮s Voltage Settling to ؎1/2 LSB

Low Power: 75 mW

No User Trims Required

Guaranteed Monotonic Over Temperature

All Errors Specified T_MINto T_MAX

Small 16-Pin DIP or 20-Pin PLCC Package

Low Cost

GENERAL DESCRIPTION

PRODUCT HIGHLIGHTS

The AD557 DACPORT® is a complete voltage-output 8-bit

digital-to-analog converter, including output amplifier, full

microprocessor interface and precision voltage reference on a

single monolithic chip. No external components or trims are

required to interface, with full accuracy, an 8-bit data bus to an

analog system.

1. The 8-bit I²L input register and fully microprocessor-

compatible control logic allow the AD557 to be directly con-

nected to 8- or 16-bit data buses and operated with standard

control signals. The latch may be disabled for direct DAC

interfacing.

2. The laser-trimmed on-chip SiCr thin-film resistors are cali-

brated for absolute accuracy and linearity at the factory.

Therefore, no user trims are necessary for full rated accuracy

over the operating temperature range.

The low cost and versatility of the AD557 DACPORT are the re-

sult of continued development in monolithic bipolar technologies.

The complete microprocessor interface and control logic is

implemented with integrated injection logic (I²L), an extremely

dense and low-power logic structure that is process-compatible

with linear bipolar fabrication. The internal precision voltage

reference is the patented low-voltage band-gap circuit which

permits full-accuracy performance on a single +5 V power sup-

ply. Thin-film silicon-chromium resistors provide the stability

required for guaranteed monotonic operation over the entire

operating temperature range, while laser-wafer trimming of

these thin-film resistors permits absolute calibration at the fac-

tory to within ±2.5 LSB; thus, no user-trims for gain or offset

are required. A new circuit design provides voltage settling to

±1/2 LSB for a full-scale step in 800 ns.

3. The inclusion of a precision low-voltage band-gap reference

eliminates the need to specify and apply a separate reference

source.

4. The AD557 is designed and specified to operate from a single

+4.5 V to +5.5 V power supply.

5. Low digital input currents, 100 µA max, minimize bus loading.

Input thresholds are TTL/low voltage CMOS compatible.

6. The single-chip, low power I²L design of the AD557 is inher-

ently more reliable than hybrid multichip or conventional

single-chip bipolar designs.

The AD557 is available in two package configurations. The

AD557JN is packaged in a 16-pin plastic, 0.3"-wide DIP. For

surface mount applications, the AD557JP is packaged in a

20-pin JEDEC standard PLCC. Both versions are specified over

the operating temperature range of 0°C to +70°C.

DACPORT is a registered trademark of Analog Devices, Inc.

Covered by U.S. Patent Nos. 3,887,863; 3,685,045; 4,323,795; other

patents pending.

REV. A

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.

One Technology Way, P.O. Box 9106, Norwood, MA 02062-9106, U.S.A.

Tel: 617/329-4700

Fax: 617/326-8703

AD557–SPECIFICATIONS (@ T_A= +25؇C, V_CC= +5 V unless otherwise noted)

Model

Min

Typ

Max

Units

RESOLUTION

Bits

PIN CONFIGURATIONS

RELATIVE ACCURACY

0 to + 70°C

±1/2

LSB

DIP

OUTPUT

Ranges

0 to + 2.56

Current Source

Sink

LSB BIT 8

BIT 7

OUT

Internal Passive

SENSE A

SENSE B

OUT

Pull-Down to Ground²

BIT 6

OUT

OUTPUT SETTLING TIME³

FULL-SCALE ACCURACY⁴

@ +25°C

0.8

1.5

µs

AD557

TOP VIEW

(Not to Scale)

BIT 5

13 GND

12 GND

BIT 4

±1.5

±2.5

±4.0

LSB

T_MINto T_MAX

BIT 3

ZERO ERROR

@ +25°C

T_MINto T_MAX

BIT 2

±1

±3

LSB

MSB BIT 1

MONOTONICITY⁵

T_MINto T_MAX

Guaranteed

DIGITAL INPUTS

T_MINto T_MAX

Input Current

PLCC

؎100

µA

Data Inputs, Voltage

Bit On—Logic “1”

Bit On—Logic “0”

Control Inputs, Voltage

On—Logic “1”

2.0

0.8

2.0

On—Logic “0”

Input Capacitance

TIMING⁶

20 19

t_WStrobe Pulse Width

225

300

225

300

PIN 1

IDENTIFIER

BIT 6

BIT 5

SENSE B

OUT

T_MINto T_MAX

_DHData Hold Time

T_MINto T_MAX

17 GND

AD557

TOP VIEW

(Not to Scale)

t_DSData Setup Time

T_MINto T_MAX

BIT 4

BIT 3

GND

POWER SUPPLY

Operating Voltage Range (V_CC

2.56 Volt Range

)

10 11 12

+4.5

+5.5

0.03

%/%

Current (I_CC

)

Rejection Ratio

POWER DISSIPATION, V_CC= 5 V

OPERATING TEMPERATURE RANGE

NOTES

125

+70

NC = NO CONNECT

°C

¹Relative Accuracy is defined as the deviation of the code transition points from the

ideal transfer point on a straight line from the zero the the full scale of the device.

²Passive pull-down resistance is 2 kΩ.

ORDERING GUIDE

Temperature Range

³Settling time is specified for a positive-going full-scale step to ±1/2 LSB. Negative-

going steps to zero are slower, but can be improved with an external pull-down.

⁴The full-scale output voltage is 2.55 V and is guaranteed with a +5 V supply.

⁵A monotonic converter has a maximum differential lineraity error of ±1 LSB.

⁶See Figure 7.

Model

Package Option*

AD557JN

AD557JP

0°C to +70°C

N-16

P-20A

Specifications subject to change without notice.

*N = Plastic DIP; P = Plastic Leaded Chip Carrier.

ABSOLUTE MAXIMUM RATINGS^*

V_CCto Ground . . . . . . . . . . . . . . . . . . . . . . . . . . . 0 V to +18 V

Digital Inputs (Pins 1–10) . . . . . . . . . . . . . . . . . .0 V to +7.0 V

V_OUT. . . . . . . . . . . . . . . . . . . . . . . Indefinite Short to Ground

Momentary Short to V_CC

Power Dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . .450 mW

Storage Temperature Range

N/P (Plastic) Packages . . . . . . . . . . . . . . . .–25°C to +100°C

Lead Temperature (Soldering, 10 sec) . . . . . . . . . . . . . . 300°C

Thermal Resistance

CIRCUIT DESCRIPTION

The AD557 consists of four major functional blocks fabricated

on a single monolithic chip (see Figure 1). The main D/A con-

verter section uses eight equally weighted laser-trimmed current

sources switched into a silicon-chromium thin-film R/2R resistor

ladder network to give a direct but unbuffered 0 mV to 400 mV

output range. The transistors that form the DAC switches are

PNPs; this allows direct positive-voltage logic interface and a

zero-based output range.

Junction to Ambient/Junction to Case

N/P (Plastic) Packages . . . . . . . . . . . . . . . . . .140/55°C/W

*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 section of this specification is not implied. Exposure to absolute

maximum rating conditions for extended periods may affect device reliability.

–2–

REV. A

AD557

and offset; therefore, no provisions have been made for such

user trims. If a small increase in scale is required, however, it

may be accomplished by slightly altering the effective gain of the

output buffer. A resistor in series with V_OUTSENSE will

increase the output range. Note that decreasing the scale by put-

ting a resistor in series with GND will not work properly due to

the code-dependent currents in GND. Adjusting offset by

injecting dc at GND is not recommended for the same reason.

Figure 1. Functional Block Diagram

The high-speed output buffer amplifier is operated in the

noninverting mode with gain determined by the user-

connections at the output range select pin. The gain-setting

application resistors are thin film laser trimmed to match and

track the DAC resistors and to assure precise initial calibration

of the output range, 0 V to 2.56 V. The amplifier output stage is

an NPN transistor with passive pull-down for zero-based output

capability with a single power supply.

Figure 2. 0 V to 2.56 V Output Range

BIPOLAR –1.28 V TO +1.28 V OUTPUT RANGE

The AD557 was designed for operation from a single power

supply and is thus capable of providing only a unipolar 0 V to

+2.56 V output range. If a negative supply is available, bipolar

output ranges may be achieved by suitable output offsetting and

scaling. Figure 3 shows how a ±1.28 V output range may be

achieved when a –5 V power supply is available. The offset is

provided by the AD589 precision 1.2 V reference which will

operate from a +5 V supply. The AD711 output amplifier can

provide the necessary ±1.28 V output swing from ±5 V supplies.

Coding is complementary offset binary.

The internal precision voltage reference is of the patented

band-gap type. This design produces a reference voltage of

1.2 V and thus, unlike 6.3 V temperature-compensated Zeners,

may be operated from a single, low-voltage logic power supply.

The microprocessor interface logic consists of an 8-bit data latch

and control circuitry. Low power, small geometry and high

speed are advantages of the I²L design as applied to this section.

I²L is bipolar process compatible so that the performance of the

analog sections need not be compromised to provide on-chip

logic capabilities. The control logic allows the latches to be

operated from a decoded microprocessor address and write sig-

nal. If the application does not involve a µP or data bus, wiring

CS and CE to ground renders the latches “transparent” for

direct DAC access.

Digital Input Code

Hexadecimal

Output

Voltage

Binary

Decimal

0000 0000

0000 0001

0000 0010

0000 1111

0001 0000

0111 1111

1000 0000

1100 0000

1111 1111

127

128

192

255

0.010 V

0.020 V

0.150 V

0.160 V

1.270 V

1.280 V

1.920 V

2.55 V

Figure 3. Bipolar Operation of AD557 from ±5 V Supplies

Applications

GROUNDING AND BYPASSING

All precision converter products require careful application of

good grounding practices to maintain full rated performance.

Because the AD557 is intended for application in microcom-

puter systems where digital noise is prevalent, special care must

be taken to assure that its inherent precision is realized.

CONNECTING THE AD557

The AD557 has been configured for low cost and ease of appli-

cation. All reference, output amplifier and logic connections are

made internally. In addition, all calibration trims are performed

at the factory assuring specified accuracy without user trims.

The only connection decision to be made by the user is whether

the output range desired is unipolar or bipolar. Clean circuit

board layout is facilitated by isolating all digital bit inputs on

one side of the package; analog outputs are on the opposite side.

The AD557 has two ground (common) pins; this minimizes

ground drops and noise in the analog signal path. Figure 4

shows how the ground connections should be made.

It is often advisable to maintain separate analog and digital

grounds throughout a complete system, tying them common in

one place only. If the common tie-point is remote and accidental

disconnection of that one common tie-point occurs due to card

removal with power on, a large differential voltage between the

UNIPOLAR 0 V TO +2.56 V OUTPUT RANGE

Figure 2 shows the configuration for the 0 V to +2.56 V full-

scale output range. Because of its precise factory calibration, the

AD557 is intended to be operated without user trims for gain

REV.A

–3–

AD557

two commons could develop. To protect devices that interface

to both digital and analog parts of the system, such as the

AD557, it is recommended that common ground tie-points

should be provided at each such device. If only one system

ground can be connected directly to the AD557, it is recom-

mended that analog common be selected.

Table I. AD557 Control Logic Truth Table

Latch

Input Data

DAC Data

Condition

“transparent”

latching

latched

previous data

NOTES

X = Does not matter

g = Logic Threshold at Positive-Going Transition

In a level-triggered latch such as that used in the AD557, there

is an interaction between the data setup and hold times and the

width of the enable pulse. In an effort to reduce the time

required to test all possible combinations in production, the

AD557 is tested with T_DS= T_W= 225 ns at 25°C and 300 ns at

Figure 4. Recommended Grounding and Bypassing

USING A “FALSE” GROUND

Many applications, such as disk drives, require servo control

voltages that swing on either side of a “false” ground. This

ground is usually created by dividing the +12 V supply equally

and calling the midpoint voltage “ground.”

T_MINand T_MAX, with T_DH= 10 ns at all temperatures. Failure

to comply with these specifications may result in data not being

latched properly.

Figure 7 shows the timing for the data and control signals, CE

and CS are identical in timing as well as in function.

Figure 5 shows an easy and inexpensive way to implement this.

The AD586 is used to provide a stable 5 V reference from the

system’s +12 V supply. The op amp shown likewise operates

from a single (+12 V) supply available in the system. The result-

ing output at the V_OUTnode is ±2.5 V around the “false”

ground point of 5 V. AD557 input code vs. V_OUTis shown in

Figure 6.

Figure 7. AD557 Timing

Figure 5. Level Shifting the AD557 Output Around a

“False” Ground

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

TIMING AND CONTROL

N (Plastic) Package

The AD557 has data input latches that simplify interface to 8-

and 16-bit data buses. These latches are controlled by Chip

Enable (CE) and Chip Select (CS) inputs. CE and CS are inter-

nally “NORed” so that the latches transmit input data to the

DAC section when both CE and CS are at Logic “0”. If the

application does not involve a data bus, a “00” condition allows

for direct operation of the DAC. When either CE or CS go to

Logic “1,” the input data is latched into the registers and held

until both CE and CS return to “0.” (Unused CE or CS inputs

should be tied to ground.) The truth table is given in Table I.

The logic function is also shown in Figure 6.

P (PLCC) Package

Figure 6. AD557 Input Code vs. Level Shifted Output in a

“False” Ground Configuration

–4–

REV. A

AD557 [ADI]

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