DAC7571IDBVTG4_技术文档

D

A

C

7

5

1

2

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

+2.7 V to +5.5 V, I²C INTERFACE, VOLTAGE OUTPUT, 12-BIT DIGITAL-TO-ANALOG

CONVERTER

FEATURES

DESCRIPTION

•

Micropower Operation: 140 µA @ 5 V

Power-On Reset to Zero

The DAC7571 is a low-power, single channel, 12-bit

buffered voltage output DAC. Its on-chip precision

output amplifier allows rail-to-rail output swing to be

achieved. The DAC7571 utilizes an I²C compatible

two wire serial interface that operates at clock rates

up to 3.4 Mbps with address support of up to two

DAC7571s on the same data bus.

+2.7-V to +5.5 V-Power Supply

Specified Monotonic by Design

Settling Time: 10 µs to ±0.003%FS

I²C™ Interface up to 3.4 Mbps

On-Chip Output Buffer Amplifier, Rail-to-Rail

Operation

Double-Buffered Input Register

Address Support for up to Two DAC7571s

Small 6 Lead SOT Package

The output voltage range of the DAC is set to V_DD

.

The DAC7571 incorporates a power-on-reset circuit

that ensures that the DAC output powers up at zero

volts and remains there until a valid write to the

•

device takes place. The DAC7571 contains

a

power-down feature, accessed via the internal control

register, that reduces the current consumption of the

device to 50 nA at 5 V.

Operation From –40°C to 105°C

APPLICATIONS

The low power consumption of this part in normal

operation makes it ideally suited for portable battery

operated equipment. The power consumption is less

than 0.7 mW at V_DD= 5 V reducing to 1 µW in

power-down mode.

•

Process Control

Data Acquistion Systems

Closed-Loop Servo Control

PC Peripherals

Portable Instrumentation

The DAC7571 is available in a 6-lead SOT 23

package.

V

DD

GND

Power-On

Reset

Ref (+) REF(-)

12-Bit

DAC

Register

Output

Buffer

V

OUT

DAC

2

I C

Control

Logic

Power Down

Control Logic

Resistor

Network

A0

SCL SDA

Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas

Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.

I²C is a trademark of Philips Corporation.

PRODUCTION DATA information is current as of publication date.

Products conform to specifications per the terms of the Texas

Instruments standard warranty. Production processing does not

necessarily include testing of all parameters.

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam

during storage or handling to prevent electrostatic damage to the MOS gates.

PACKAGE/ORDERING INFORMATION

PACKAGE

DESIG-

NATOR

SPECIFIED TEM-

PERATURE RANGE

PACKAGE

MARKING

ORDERING NUM-

BER

PRODUCT PACKAGE

TRANSPORT MEDIA

DAC7571IDBVT

DAC7571IDBVR

250 Piece Small Tape and Reel

3000 Piece Tape and Reel

DAC7571

SOT23-6

DBV

-40°C to +105°C

D771

PIN DESCRIPTION (SOT23-6)

PIN CONFIGURATIONS

NAME

DESCRIPTION

(TOP VIEW)

1

V_OUT

Analog output voltage from DAC

V

A0

6

5

4

1

2

3

OUT

Ground reference point for all

circuitry on the part

2

GND

SCL

SDA

V

3

4

5

6

V_DD

SDA

SCL

A0

Analog Voltage Supply Input

Serial Data Input

DD

(BOTTOM VIEW)

Serial Clock Input

Device Address Select

1

2

3

6

5

4

LOT

TRACE

CODE:

Year (3 = 2003); Month (1–9 = JAN–SEP; A=OCT,

B=NOV, C=DEC); LL– Random code generated

when assembly is requested

Lot Trace Code

ABSOLUTE MAXIMUM RATINGS⁽¹⁾

UNITS

V_DDto GND

-0.3V to +6V

-0.3 V to +V_DD+ 0.3 V

-40°C to + 105°C

-65°C to + 150°C

+ 150°C

Digital Input voltage to GND

V_OUTto GND

Operating temperature range

Storage temperature range

Junction temperature range (T_Jmax)

Power dissipation

(T_Jmax - T_A)R_ΘJA

240°C/W

Thermal impedance, R_ΘJA

Lead temperature, soldering

Vapor phase (60s)

Infrared (15s)

215°C

220°C

(1) Stresses above those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. Exposure to absolute

maximum conditions for extended periods may affect device reliability.

ELECTRICAL CHARACTERISTICS

V_DD= +2.7 V to +5.5 V; R_L= 2 kΩ to GND; C_L= 200 pF to GND; all specifications -40°C to +105°C unless otherwise noted.

DAC7571

PARAMETER

CONDITIONS

UNITS

MIN

TYP

MAX

STATIC PERFORMANCE⁽¹⁾

Resolution

12

Bits

% of FSR

LSB

Relative accuracy

Differential nonlinearity

Zero code error

±0.195

±1

Assured monotonic by design

All zeroes loaded to DAC register

5

20

mV

(1) Linearity calculated using a reduced code range of 48 to 4047; output unloaded.

2

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

ELECTRICAL CHARACTERISTICS (continued)

V_DD= +2.7 V to +5.5 V; R_L= 2 kΩ to GND; C_L= 200 pF to GND; all specifications -40°C to +105°C unless otherwise noted.

DAC7571

PARAMETER

CONDITIONS

UNITS

MIN

TYP

MAX

-1.25

±1.25

Full-scale error

All ones loaded to DAC register

-0.15

% of FSR

Gain error

Zero code error drift

Gain temperature coefficient

OUTPUT CHARACTERISTICS⁽²⁾

Output voltage range

Output voltage settling time

Slew rate

±7

±3

µV/°C

ppm of FSR/°C

0

V_DD

10

V

µ s

V/µs

pF

1/4 Scale to 3/4 scale change (400_Hto C00_H)

8

1

R_L=∞

R_L= 2kΩ

470

1000

20

0.5

1

Capacitive load stability

pF

Code change glitch impulse

Digital feedthrough

1 LSB Change around major carry

nV-s

Ω

DC output impedance

V_DD= +5V

V_DD= +3V

50

20

2.5

5

mA

µ s

Short-circuit current

Coming out of power-down mode, V_DD= +5V

Coming out of power-down mode, V_DD= +3V

Power-up time

LOGIC INPUTS⁽³⁾

Input current

± 1

µ A

V

V_INL, Input low voltage

V_INH, Input high voltage

Pin capacitance

V_DD= +3V

V_DD= +5V

0.3×V_DD

0.7×V_DD

V

3

pF

POWER REQUIREMENTS

V_DD

2.7

5.5

V

I_DD(normal operation)

V_DD= +3.6V to +5.5V

V_DD= +2.7V to +3.6V

I_DD(all power-down modes)

DAC active and excluding load current

V_IH= V_DDand V_IL= GND

135

115

200

160

µ A

V_IH= V_DDand V_IL= GND

V_DD= +3.6 V to +5.5

V

V_IH= V_DDand V_IL= GND

0.2

1

µ A

V_DD= +2.7V to +3.6V

POWER EFFICIENCY

I_OUT/I_DD

0.05

I_LOAD= 2mA, V_DD= +5V

93

%

(2) Specified by design and characterization, not production tested.

(3) Specified by design and characterization, not production tested.

3

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

TIMING CHARACTERISTICS

SYMBOL

PARAMETER

TEST CONDITIONS

Standard mode

MIN

TYP

MAX

UNITS

kHz

MHz

µs

100

400

3.4

1.7

Fast mode

f_SCL

SCL Clock Frequency

High-speed mode, C_B- 100pF max

High-Speed mode, C_B- 400pF max

Standard mode

4.7

1.3

4.0

600

160

4.7

1.3

160

320

4.0

600

60

Bus Free Time Between a STOP

and START Condition

t_BUF

Fast mode

µs

Standard mode

µs

Hold Time (Repeated) START

Condition

t_HD; t_STA

Fast mode

ns

High-speed mode

ns

Standard mode

µs

Fast mode

µs

t_LOW

LOW Period of the SCL Clock

HIGH Period of the SCL Clock

High-speed mode, C_B- 100pF max

High-speed mode, C_B- 400pF max

Standard mode

ns

µs

Fast mode

ns

t_HIGH

High-speed mode, C_B- 100pF max

High-speed mode, C_B- 400pF max

Standard mode

ns

120

4.7

600

160

250

100

10

ns

µs

Setup Time for a Repeated

START Condition

t_SU; t_STA

Fast mode

ns

High-speed mode

ns

Standard mode

ns

t_SU; t_DAT

Data Setup Time

Data Hold Time

Fast mode

ns

High-speed mode

ns

Standard mode

0

3.45

0.9

µs

Fast mode

0

µs

t_HD; t_DAT

High-speed mode, C_B- 100pF max

High-speed mode, C_B- 400pF max

Standard mode

0

70

ns

0

150

1000

300

40

ns

Fast mode

20 + 0.1C_B

ns

t_RCL

Rise Time of SCL Signal

High-speed mode, C_B- 100pF max

High-speed mode, C_B- 400pF max

Standard mode

10

20

ns

80

ns

1000

300

80

ns

Rise Time of SCL Signal After a

Repeated START Condition and

After an Acknowledge BIT

Fast mode

20 + 0.1C_B

ns

t_RCL1

High-speed mode, C_B- 100pF max

High-speed mode, C_B- 400pF max

Standard mode

10

20

ns

160

300

40

ns

Fast mode

20 + 0.1C_B

ns

t_FCL

Fall Time of SCL Signal

Rise Time of SDA Signal

Fall Time of SDA Signal

High-speed mode, C_B- 100pF max

High-speed mode, C_B- 400pF max

Standard mode

10

20

ns

80

ns

1000

300

80

ns

Fast mode

20 + 0.1C_B

ns

t_RDA

High-speed mode, C_B- 100pF max

High-speed mode, C_B- 400pF max

Standard mode

10

20

ns

160

300

80

ns

Fast mode

20 + 0.1C_B

ns

t_FDA

High-speed mode, C_B- 100pF max

High-speed mode, C_B- 400pF max

10

20

ns

160

ns

4

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

TIMING CHARACTERISTICS (continued)

SYMBOL

PARAMETER

TEST CONDITIONS

Standard mode

Fast mode

MIN

4.0

TYP

MAX

UNITS

µs

t_SU; t_STO

Setup Time for STOP Condition

600

160

ns

High-speed mode

ns

C_B

t_SP

Capacitive Load for SDA and SCL

Pulse Width of Spike Suppressed

400

50

pF

Fast mode

High-speed mode

Standard mode

Fast mode

ns

10

ns

Noise Margin at the HIGH Level

for Each Connected Device

(Including Hysteresis)

V_NH

0.2V_DD

0.1V_DD

V

High-speed mode

Standard mode

Fast mode

Noise Margin at the LOW Level for

Each Connected Device

V_NL

(Including Hysteresis)

High-speed mode

5

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

TYPICAL CHARACTERISTICS: V_DD= +5 V

At T_A= +25°C, +V_DD= +5 V, unless otherwise noted.

LINEARITY ERROR AND

DIFFERENTIAL LINEARITY ERROR

vs

CODE (-40°C)

CODE (+25 ° C )

8

6

8

6

4

2

4

2

0

−2

−4

0

−2

−4

−6

−8

−6

−8

1

0.5

0

0.5

0

−0.5

−1

−0.5

−1

0

512

1024

1536 2048 2560

Digital Input Code

3072 3584 4096

0

512

1024

1536 2048 2560 3072

3584 4096

Digital Input Code

Figure 1.

Figure 2.

LINEARITY ERROR AND

DIFFERENTIAL LINEARITY ERROR

vs

CODE (+105° C)

TYPICAL TOTAL UNADJUSTED ERROR

8

6

4

2

0

−2

−4

−6

−8

16

8

0

−8

−16

3584 4096

0

512

1024

1536 2048

2560

3072

1

0.5

0

Digital Input Code

−0.5

−1

0

512

1024 1536 2048 2560 3072 3584 4096

Digital Input Code

Figure 3.

Figure 4.

ZERO-SCALE ERROR

vs

FULL-SCALE ERROR

vs

TEMPERATURE

30

20

10

30

20

10

0

−10

−20

−30

−20

−30

−50

−30

−10

10

30

50

70

90

110

−50

−30

−10

10

30

50

70

90

110

T − Temperature − _C

Figure 5.

Figure 6.

6

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

TYPICAL CHARACTERISTICS: V_DD= +5 V (continued)

At T_A= +25°C, +V_DD= +5 V, unless otherwise noted.

I_DDHISTOGRAM

SOURCE AND SINK CURRENT CAPABILITY

2500

5

4

3

2

1

0

DAC Loaded with FFF_H

2000

1500

1000

500

0

DAC Loaded with 000_H

I

− Supply Current − mA

DD

0

5

10

15

I_SOURCE/SINK(mA)

Figure 7.

Figure 8.

SUPPLY CURRENT

vs

TEMPERATURE

vs

CODE

500

400

300

250

200

150

200

100

0

100

50

0

−50

000

200

600

A00

E00

FFF

H

−30

−10

10

30

50

70

90

110

H

CODE

T − Temperature − _C

Figure 9.

Figure 10.

7

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

TYPICAL CHARACTERISTICS: V_DD= +5 V (continued)

At T_A= +25°C, +V_DD= +5 V, unless otherwise noted.

SUPPLY CURRENT

vs

SUPPLY VOLTAGE

POWER-DOWN CURRENT

vs

SUPPLY VOLTAGE

300

100

90

80

70

60

50

40

30

20

10

0

250

200

150

100

50

+105°C

–40°C

0

2.7

+25°C

3.2

3.7

4.2

4.7

5.2

5.7

V

− Supply Voltage − V

DD

2.7

3.2

3.7

4.2

4.7

5.2

5.7

V_DD(V)

Figure 11.

Figure 12.

SUPPLY CURRENT

vs

LOGIC INPUT VOLTAGE

FULL-SCALE SETTLING TIME

2500

2000

1500

1000

500

CLK (5V/div)

V_OUT(1V/div)

Full-Scale Code Change

000_Hto FFF_H

Output Loaded with

2kΩ and 200pF to GND

0

1

2

3

4

5

Time (1µs/div)

V_LOGIC(V)

Figure 13.

Figure 14.

8

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

TYPICAL CHARACTERISTICS: V_DD= +5 V (continued)

At T_A= +25°C, +V_DD= +5 V, unless otherwise noted.

FULL-SCALE SETTLING TIME

HALF-SCALE SETTLING TIME

CLK (5V/div)

V_OUT(1V/div)

Half-Scale Code Change

400_Hto C00_H

Full-Scale Code Change

FFF_Hto 000_H

Output Loaded with

2kΩ and 200pF to GND

Output Loaded with

2kΩ and 200pF to GND

V_OUT(1V/div)

Time (1µs/div)

Figure 15.

Time (1µs/div)

Figure 16.

POWER-ON RESET TO 0V

HALF-SCALE SETTLING TIME

Loaded with 2kΩ to V_DD

.

CLK (5V/div)

Half-Scale Code Change

C00_Hto 400_H

Output Loaded with

2kΩ and 200pF to GND

V_DD(1V/div)

V_OUT(1V/div)

Time (20µs/div)

Time (1µs/div)

Figure 17.

Figure 18.

EXITING POWER-DOWN

(800_HLoaded)

CODE CHANGE GLITCH

Loaded with 2kΩ

CLK (5V/div)

and 200pF to GND.

Code Change:

800_Hto 7FF_H.

V_OUT(1V/div)

Time (5µs/div)

Time (0.5µs/div)

Figure 19.

Figure 20.

9

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

TYPICAL CHARACTERISTICS: V_DD= +2.7V

At T_A= +25°C, +V_DD= +2.7V, unless otherwise noted.

LINEARITY ERROR AND

DIFFERENTIAL LINEARITY ERROR

vs

CODE (-40 °C)

CODE (+25 °C)

8

6

4

8

6

4

2

0

−2

−4

−2

−4

−6

−8

−6

−8

1

0.5

0

1

0.5

0

−0.5

−1

−0.5

−1

0

512

1024

1536 2048 2560 3072 3584 4096

0

512

1024 1536 2048 2560 3072 3584 4096

Digital Input Code

Figure 21.

Figure 22.

LINEARITY ERROR AND

DIFFERENTIAL LINEARITY ERROR

vs

CODE (+105 °C)

ABSOLUTE ERROR

8

6

4

2

0

−2

−4

16

8

−6

−8

0

−8

1

0.5

0

−0.5

−1

−16

512

0

512

1024

1536

2048

2560 3072

3584 4096

0

1024 1536 2048 2560 3072 3584 4096

Digital Input Code

Figure 23.

Figure 24.

ZERO-SCALE ERROR

vs

FULL-SCALE ERROR

vs

TEMPERATURE

30

20

10

30

20

10

0

−10

−20

−30

−20

−30

−50

−30

−10

10

30

50

70

90

110

−50

−30

−10

10

30

50

70

90

110

T − Temperature − _C

Figure 25.

Figure 26.

10

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

TYPICAL CHARACTERISTICS: V_DD= +2.7V (continued)

At T_A= +25°C, +V_DD= +2.7V, unless otherwise noted.

I_DDHISTOGRAM

SOURCE AND SINK CURRENT CAPABILITY

2500

3

V_DD= +3V

2000

1500

1000

DAC Loaded with FFF_H

2

1

0

500

0

DAC Loaded with 000_H

I

− Supply Current − mA

DD

0

5

10

15

I_SOURCE/SINK(mA)

Figure 27.

Figure 28.

SUPPLY CURRENT

vs

9 TEMPERATURE

vs

CODE

300

250

200

150

100

50

500

400

300

200

100

0

−50

000 02F 200 400 600 800 A00 C00 E00 FCF FFF

−30

−10

10

30

50

70

90

110

H

I

− Supply Current − mA

H

T − Temperature − _C

DD

Figure 29.

Figure 30.

SUPPLY CURRENT

vs

LOGIC INPUT VOLTAGE

FULL SCALE SETTLING TIME

2500

CLK (2.7V/div)

2000

1500

1000

500

0

Full-Scale Code Change

000_Hto FFF_H

Output Loaded with

2kΩ and 200pF to GND

V_OUT(1V/div)

Time (1µs/div)

0

1

2

3

4

5

V_LOGIC(V)

Figure 31.

Figure 32.

11

DAC7571

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TYPICAL CHARACTERISTICS: V_DD= +2.7V (continued)

At T_A= +25°C, +V_DD= +2.7V, unless otherwise noted.

FULL SCALE SETTLING TIME

HALF SCALE SETTLING TIME

CLK (2.7V/div)

Full-Scale Code Change

V_OUT(1V/div)

FFF_Hto 000_H

Output Loaded with

2kΩ and 200pF to GND

Half-Scale Code Change

400_Hto C00_H

Output Loaded with

V_OUT(1V/div)

2kΩ and 200pF to GND

Time (1µs/div)

Figure 33.

Figure 34.

HALF SCALE SETTLING TIME

POWER ON RESET 0 V

CLK (2.7V/div)

Half-Scale Code Change

C00_Hto 400_H

Output Loaded with

2kΩ and 200pF to GND

V_OUT(1V/div)

Time (20µs/div)

Time (1µs/div)

Figure 35.

Figure 36.

EXITING-POWER DOWN (800_HLoaded)

CODE CHANGE GLITCH

Loaded with 2kΩ

CLK (2.7V/div)

and 200pF to GND.

Code Change:

800_Hto 7FF_H.

V_OUT(1V/div)

Time (5µs/div)

Time (0.5µs/div)

Figure 37.

Figure 38.

12

DAC7571

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THEORY OF OPERATION

D/A SECTION

The architecture of the DAC7571 consists of a string DAC followed by an output buffer amplifier. Figure 39

shows a block diagram of the DAC architecture.

V

DD

REF (+)

Resistor

String

DAC Register

V

OUT

Output

REF (-)

Amplifier

GND

Figure 39. R-String DAC Architecture

The input coding to the DAC7571 is unsigned binary, which gives the ideal output voltage as:

D

4096

V

+ V

DD

OUT

where D = decimal equivalent of the binary code that is loaded to the DAC register; it can range from 0 to 4095.

RESISTOR STRING

The resistor string section is shown in Figure 40. It is simply a string of resistors, each of value R. The code

loaded into the DAC register determines at which node on the string the voltage is tapped off to be fed into the

output amplifier by closing one of the switches connecting the string to the amplifier. It is ensured monotonic

because it is a string of resistors. The negative tap of the resistor string is tied to GND. The positive tap of the

resistor string is tied to V_DD

.

V

DD

R

To Output

Amplifier

R

GND

Figure 40. Resistor String

13

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THEORY OF OPERATION (continued)

OUTPUT AMPLIFIER

The output buffer amplifier is capable of generating rail-to-rail voltages on its output which gives an output range

of 0 V to V_DD. It is capable of driving a load of 2kΩ in parallel with 1000 pF to GND. The source and sink

capabilities of the output amplifier can be seen in the typical characteristics. The slew rate is 1V/µs with a

half-scale settling time of 8 µs with the output unloaded.

I²C Interface

The DAC7571 uses an I²C interface as defined by Philips Semiconductor to receive data in slave mode (see

I²C-Bus Specification, Version 2.1, January 2000). The DAC7571 supports the following data transfer modes,

described in the I²C-Bus Specification: Standard Mode (100 kbit/s), Fast Mode (400 kbit/s) and High-Speed

Mode (3.4 Mbit/s). Ten-bit addressing and general call addres are not supported.

For simplicity, standard mode and fast mode are referred to as F/S-mode and high-speed mode is referred tg as

HS-mode.

The 2-wire I²C serial bus protocol operates as follows:

•

The Master initiates data transfer by establishing a Start condition. The Start condition is defined when a

high-to-low transition occurs on the SDA line while SCL is high, as shown in Figure 41. The byte following

the start condition is the address byte consisting of the 7-bit slave address followed by the W bit.

SDA

SCL

SDA

SCL

S

P

Start

Stop

Condition

Figure 41. START and STOP Conditions

•

The addressed Slave responds by pulling the SDA pin low during the ninth clock pulse, termed the

Acknowledge bit (see Figure 42). At this stage all other devices on the bus remain idle while the selected

device waits for data to be written to its shift register.

Data Output

by Transmitter

Not Acknowledge

Data Output

by Receiver

Acknowledge

SCL From

Master

1

2

8

9

S

Clock Pulse for

START

Acknowledgement

Condition

Figure 42. Acknowledge on the I²C Bus

•

Data is transmitted over the serial bus in sequences of nine clock cycles (8 data bits followed by an

acknowledge bit. The transitions on the SDA line must occur during the low period of SCL and remain stable

during the high period of SCL (see Figure 43).

14

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

THEORY OF OPERATION (continued)

SDA

SCL

Data Line

Change of Data Allowed

Stable;

Data Valid

Figure 43. Bit Transfer on the I²C Bus

•

When all data bits have been written, a Stop condition is established (see Figure 44). In writing to the

DAC7571, the master must pull the SDA line high during the tenth clock pulse to establish a Stop condition.

Recognize START or

REPEATED START

Condition

Recognize STOP or

REPEATED START

Condition

Generate ACKNOWLEDGE

Signal

P

SDA

MSB

Acknowledgement

Signal From Slave

Sr

Address

R/W

SCL

1

2

7

8

9

1

2

3 - 8

9

S

or

Sr

or

P

ACK

Clock Line Held Low While

Interrupts are Serviced

START or

Repeated START

Condition

STOP or

Repeated START

Condition

Figure 44. Bus Protocol

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DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

THEORY OF OPERATION (continued)

Standard-and Fast-Mode:

S

SLAVE ADDRESS R/W

A

Ctrl/MS-Byte

A

LS-Byte A/A

P

Data Transferred

(n* Words + Acknowledge)

Word = 16 Bit

”0” (write)

2

From Master to DAC7571

From DAC7571 to Master

DAC7571 I C-SLAVE ADDRESS:

MSB

LSB

1

0

1

0

A0 R/W

A = Acknowledge (SDA LOW)

A = Not Acknowledge (SDA HIGH)

S = START Condition

‘0’ = Write to DAC7571

Factory Preset

‘1’ = Read from DAC7571

2

Sr = Repeated START Condition

P = STOP Condition

A0 = I C Address Pin

High-Speed-Mode (HS-Mode):

F/S-Mode

HS-Mode

Ctrl/MS-Byte

F/S-Mode

S

HS-Master Code

A

Sr Slave Address R/W

A

LS-Byte A/A

P

Data Transferred

(n* Words + Acknowledge)

Word = 16 Bit

”0” (write)

HS-Mode Continues

Sr Slave Address

HS-Mode Master Code:

MSB

LSB

0

1

X

R/W

Ctrl/MS-Byte:

LS-Byte:

MSB

LSB

D8

MSB

LSB

D0

0

PD1 PD2 D11 D10 D9

D7

D6

D5

D4

D3

D2

D1

D11 – D0 = Data Bits

Figure 45. Master Transmitter Addressing DAC7571 as a Slave Receiver With a 7-Bit Address

ADDRESS BYTE

MSB

R/W

1

0

1

0

A0

0

The address byte is the first byte received by the DAC7571 following the START condition from the master

device. The first five bits (MSBs) of the slave address are factory preset to 100110. The next bit of the address

byte is the device select bit, A0. In order for DAC7571 to respond, the logic state of address bit A0 should match

the logic state of address pin A0. A maximum of two devices with the same preset code can therefore be

connected on the same bus at one time. The A0 Address Input can be connected to V_DDor digital ground, or can

be actively driven by TTL or CMOS logic levels. The device address is set by the state of the A0 pin upon

power-up of the DAC7571. The last bit of the address byte (R/W) should always be zero. Following the START

condition, the DAC7571 monitors the SDA bus, checking the device type identifier being transmitted. Upon

receiving the 100110 code, the appropriate device select bit and the R/W bit, the DAC7571 outputs an

acknowledge signal on the SDA line. Upon receipt of a broadcast address 10010000, the DAC7571 responds

regardless of the state of the A0 pin.

16

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

MASTER TRANSMITTER WRITING TO A SLAVE RECEIVER (DAC7571) IN STANDARD/FAST

MODES

I²C protocol starts when the bus is dile, that is, when SDA and SCL lines are stable high. The master then pulls

the SDA line low while SCL is still high indicting that serial data transfer has started. This is called a start

condition, and can only be asserted by the master. After the start conditioin, the master generates the serial

clock and puts out an address byte. While generating the bit stream, the master ensures the timing for valid data.

For each valid I²C bit, the SDA line should remain stable during the entire high period of the SCL line. The

address byte consists of 7 address bits (1001 100, assuming A0=0) and a direction bit (R/W=0). After sending

the address byte, the master generates a ninth SCL pulse and monitors the state of the SDA line during the high

period of this ninth clock cycle.

The SDA line being pulled low by a receiver during the high period of this 9^thclock cylce is called an

acknowledge signal. If the master receives an acknowledge signal, it knows that a DAC7571 successfully

matched the address which the master sent. Upon the receipt of this acknowledge, the master knows that the

communication link with a DAC7571 has been established and more data can be sent. The master continues by

sending a Control/MS-byte, which sets DAC7571 operation mode and specifies the first 4 MSBs of data. After

sending the Control/MS-byte, the master expects an acknowledge signal from the DAC7571. Upon the receipt of

the acknowledge, the master sends an LS-byte that represents the 8 least significant bits of DAC7571's 12-bit

conversion data. After receiving the LS-byte, the DAC7571 sends an acknowledge. At the falling edge of the

acknowledge signal, following the LS-byte, the DAC7571 performs a digital to analog conversion. For further

DAC updates, the master can keep repeating Control/MS-byte and LS-byte sequences expecting an

acknowledge after each byte. After the required number of digital to analog conversions is complete, the master

can break the communication link with the DAC7571 by pulling the SDA line from low to high while SCL line is

high. This is called a stop condition . A stop condition brings the bus back to idle (SDA and SCL both high). A

stop condition indicates that communication with the DAC7571 has ended. All devices on the bus, including the

DAC7571, waits for a new start condition followed by a mtaching address byte. DAC7571 stays in a programmed

state until the receipt of a stop condition.

Table 1. Write Sequence in Standard/Fast Modes

Transmitter

MSB

6

5

4

3

2

1

LSB

Comment

Master

Start

Begin Sequence⁽¹⁾

Write Addressing (LSB=0, R/W =

0)

Master

1

0

1

0

A0

0

DAC7571

Master

DAC7571 Acknowledges

PD0 D11

DAC7571 Acknowledges

D4 D3

0

PD1

D5

D10

D2

D9

D1

D8

D0

Writing Control/MS-Byte

Writing LS-Byte

Done

DAC7571

Master

D7

D6

DAC7571

Master

DAC7571 Acknowledges

Stop or Repeated Start⁽²⁾

(1) Once DAC7571 is addressed, high-byte-low-byte sequences can repeat until a stop condition is received.

(2) Use repeated start to secure bus operation and loop back to the stage of write addressing for next Write.

POWER-ON RESET

The DAC7571 contains a power-on reset circuit that controls the output voltage during power-up. On power-up,

the DAC register is filled with zeros and the output voltage is 0 V. It remains at a zero-code output until a valid

write sequence is made to the DAC. This is useful in applications where it is important to know the state of the

DAC output while it is in the process of powering up.

POWER-DOWN MODES

The DAC7571 contains four separate modes of operation. These modes are programmable via two bits (PD1

and PD0). Table 2 shows how the state of these bits correspond to the mode of operation.

17

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

Table 2. Modes of Operation for the DAC7571

PD1

PD0

OPERATING MODE

Normal Operation

0

1

0

1

0

1

1kΩ to AGND, PWD

100kΩ to AGND, PWD

High Impedance, PWD

When both bits are set to 0, the device works normally with normal power consumption of 150 µA at 5V.

However, for the three power-down modes, the supply current falls to 200 nA at 5V (50 nA at 3 V). Not only does

the supply current fall but the output stage is also internally switched from the output of the amplifier to a resistor

network of known values. This has the advantage that the output impedance of the device is known while in

power-down mode. There are three different options: The output is connected internally to AGND through a 1 kΩ

resistor, a 100 kΩ resistor, or it is left open-circuited (high impedance). The output stage is illustrated in

Figure 46.

Amplifier

Resistor

V

OUT

String DAC

Powerdown

Circuitry

Resistor

Network

Figure 46. Output Stage During Power-Down

All linear circuitry is shut down when the power-down mode is activated. However, the contents of the DAC

register are unaffected when in power-down. The time required to exit power down is typically 2.5 µs for AV_DD

5 V and 5 µs for AV_DD= 3V. See the Typical Characteristics for more information.

=

CURRENT CONSUMPTION

The DAC7571 typically consumes 150 µA at V_DD= 5 V and 120 µA at V_DD= 3 V. Additional current consumption

can occur due to the digital inputs if V_IH<< V_DD. For most efficient power operation, CMOS logic levels are

recommended at the digital inputs to the DAC. In power-down mode, typical current consumption is 200 nA. Ten

to 20 ms after a power-down command is issued, the power-down current typically drops below 10 mA.

DRIVING RESISTIVE AND CAPACITIVE LOADS

The DAC7571 output stage is capable of driving loads of up to 1000 pF while remaining stable. Within the offset

and gain error margins, the DAC7571 can operate rail-to-rail when driving a capacitive load. Resistive loads of 2

kΩ can be driven by the DAC7571 while achieving a typical load regulation of 1%. As the load resistance drops

below 2 kΩ, the load regulation error increases. When the outputs of the DAC are driven to the positive rail under

resistive loading, the PMOS transistor of each Class-AB output stage can enter into the linear region. When this

occurs, the added IR voltage drop deteriorates the linearity performance of the DAC. This may occur within

approximately the top 20 mV of the DAC's digital input-to-voltage output transfer characteristic.

OUTPUT VOLTAGE STABILITY

The DAC7571 exhibits excellent temperature stability of 5 ppm/°C typical output voltage drift over the specified

temperature range of the device. This enables the output voltage to stay within a ±25 µV window for a ±1°C

ambient temperature change. Good power-supply rejection ratio (PSRR) performance reduces supply noise

present on V_DDfrom appearing at the outputs to well below 10 µV-s. Combined with good dc noise performance

and true 12-bit differential linearity, the DAC7571 becomes a perfect choice for closed-loop control applications.

18

DAC7571

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SLAS374A–FEBRUARY 2003–REVISED JANUARY 2004

APPLICATIONS

USING REF02 AS A POWER SUPPLY FOR THE DAC7571

Due to the extremely low supply current required by the DAC7571, a possible configuration is to use a REF02

+5V precision voltage reference to supply the required voltage to the DAC7571's supply input as well as the

reference input, as shown in Figure 47. This is especially useful if the power supply is quite noisy or if the system

supply voltages are at some value other than 5V. The REF02 will output a steady supply voltage for the

DAC7571. If the REF02 is used, the current it needs to supply to the DAC7571 is 150 µA typical and 200 µA max

for V_DD= 5V. When a DAC output is loaded, the REF02 also needs to supply the current to the load. The total

typical current required (with a 5 mW load on a given DAC output) is: 135 µA + (5 mW/5 V) = 1.14 mA.

The load regulation of the REF02 is typically (0.005%×V_DD)/mA, which results in an error of 285 mV for the 1.14

mA current drawn from it. This corresponds to a 0.2 LSB error for a 0 V to 5 V output range.

15 V

5 V

REF02

1.14 mA

A0

SCL

SDA

V

OUT

= 0 V to 5 V

2

I C

DAC7571

Interface

Figure 47. REF02 as Power Supply to DAC7571

LAYOUT

A precision analog component requires careful layout, adequate bypassing, and clean, well-regulated power

supplies.

The power applied to V_DDshould be well regulated and low noise. Switching power supplies and DC/DC

converters will often have high-frequency glitches or spikes riding on the output voltage. In addition, digital

components can create similar high-frequency spikes as their internal logic switches states. This noise can easily

couple into the DAC output voltage through various paths between the power connections and analog output.

As with the GND connection, V_DDshould be connected to a +5V power supply plane or trace that is separate

from the connection for digital logic until they are connected at the power entry point. In addition, the 1 µF to 10

µF and 0.1 µF bypass capacitors are strongly recommended. In some situations, additional bypassing may be

required, such as a 100µF electrolytic capacitor or even a Pi filter made up of inductors and capacitors—all

designed to essentially low-pass filter the +5V supply, removing the high-frequency noise.

19

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型号：	DAC7571IDBVTG4
厂家：	TEXAS INSTRUMENTS
描述：	低功耗轨到轨输出 12 位 I2C 输入 DAC \| DBV \| 6 \| -40 to 105 转换器数模转换器
文件：	总21页 (文件大小：754K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

DAC7571IDBVTG4 [TI]

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