AD421BRZRL_技术文档

Loop-Powered

4 mA to 20 mA DAC

a

AD421

FEATURES

FUNCTIONAL BLOCK DIAGRAM

4 mA to 20 mA Current Output

HART^®Compatible

REF IN

(+2.5V)

REF OUT2

(+2.5V)

REF OUT1

(+1.25V)

16-Bit Resolution and Monotonicity

؎0.01% Integral Nonlinearity

5 V or 3 V Regulator Output

2.5 V and 1.25 V Precision Reference

750 ␮A Quiescent Current max

Programmable Alarm Current Capability

Flexible High Speed Serial Interface

16-Lead SOIC and PDIP Packages

LV

V

CC

75k⍀

112.5k⍀

AD421

134k⍀

DRIVE

COMP

BANDGAP

REFERENCE

121k⍀

BOOST

LOCAL

OSCILLATOR

DATA

INPUT SHIFT

REGISTER

CLOCK

SWITCHED

CURRENT

SOURCES

AND

16-BIT

SIGMA-

DELTA DAC

DAC LATCH

LATCH

40⍀

80k⍀

GENERAL DESCRIPTION

FILTERING

LOOP

RTN

POWER-ON

RESET

The AD421 is a complete, loop-powered, digital to 4 mA to

20 mA converter, designed to meet the needs of smart trans-

mitter manufacturers in the Industrial Control industry. It pro-

vides a high precision, fully integrated, low cost solution in a

compact 16-lead package. The AD421 is ideal for extending the

resolution of smart 4 mA to 20 mA transmitters at very low cost.

COM

C1 C2 C3

PRODUCT HIGHLIGHTS

1. The AD421 is a single chip, high performance, low cost

solution for generating 4 mA to 20 mA signals for smart

industrial control transmitters.

The AD421 includes a selectable regulator that is used to power

itself and other devices in the transmitter. This regulator pro-

vides either a +5 V, +3.3 V or +3 V regulated output voltage.

The part also contains +1.25 V and +2.5 V precision references.

The AD421 thus eliminates the need for a discrete regulator

and voltage reference. The only external components required

are a number of passive components and a pass transistor to

span large loop voltages.

2. The AD421’s regulated supply voltage can be used to power

any additional circuits in the transmitter. The regulated

output value is pin selectable as either +3 V, +3.3 V or +5 V.

3. The AD421’s on-chip references can provide a precision

reference voltage to other devices in the system. This refer-

ence voltage can be either +1.25 V or +2.5 V.

The AD421 can be used with standard HART FSK protocol

communication circuitry without any degradation in specified

performance. The high speed serial interface is capable of oper-

ating at 10 Mbps and allows for simple connection to com-

monly-used microprocessors and microcontrollers via a standard

three-wire serial interface.

4. The AD421 is fully compatible with standard HART cir-

cuitry or other similar FSK protocols.

5. With the addition of a single discrete transistor, the AD421

can be operated from V_CC+ 2 V min to a maximum of the

breakdown voltage of the pass transistor.

The sigma-delta architecture of the DAC guarantees 16-bit

monotonicity while the integral nonlinearity for the AD421 is

0.01%. The part provides a zero scale 4 mA output current

with 0.1% offset error and a 20 mA full-scale output current

with 0.2% gain error.

6. The AD421 converts the digital data to current with 16-bit

resolution and monotonicity. Full-scale settling time to

0.1% typically occurs within 8 ms.

7. The AD421 features a programmable alarm current capabil-

ity that allows the transmitter to send out of range currents to

indicate a transducer fault.

The AD421 is available in a 16-lead, 0.3 inch-wide, plastic DIP

and in a 16-lead, 0.3 inch-wide, SOIC package. The part is speci-

fied over the industrial temperature range of –40°C to +85°C.

HART is a registered trademark of the HART Communication

Foundation.

REV. C

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: 781/329-4700

Fax: 781/326-8703

World Wide Web Site: http://www.analog.com

(Using DN25D¹as pass transistor as per Figure 3;

REF IN = REF OUT2; T = T_MINto T_MAXunless otherwise noted)

AD421–LOOP-POWERED SPECIFICATIONS

A

Parameter

B Versions²

Units

Conditions/Comments

OUTPUT CHARACTERISTICS

Current Loop Voltage Compliance³

V_CC+ 2

V min

350

8

25

2

V max

DN25D Breakdown Voltage

Settling Time to 0.1%, C1 = C2 = 10 nF, C3 = 3.3 nF

Full-Scale Settling Time

Output Impedance

AC Loop Voltage Sensitivity

ms typ

MΩ typ

µA/V typ

1200 Hz to 2200 Hz

VOLTAGE REGULATOR

Output Voltage (V_CC

3 V Mode

3.3 V Mode

5 V Mode

Externally Available Current

Line Regulation

)

2.95/3.05

3.25/3.35

4.95/5.05

3.25

1

15

V min/V max

mA min

µV/V typ

µV/mA typ

3 V Nominal. LV Pin Connected to V_CC

3.3 V Nominal. LV Pin Connected Through 0.01 µF to V_CC

5 V Nominal. LV Pin Connected to COM

Assuming 4 mA Flowing in the Loop

Load Regulation

DAC SPECIFICATIONS ^(V_CC= +3 V to +5 V; REF IN = REF OUT2; T_A= T_MINto T_MAXunless otherwise noted)

Parameter

B Versions²

Units

Conditions/Comments

ACCURACY

Resolution

16

Bits

Monotonicity

16

Bits min

Integral Nonlinearity

Offset (4 mA) @ +25°C⁴

Offset Drift

0.01

0.1

25

0.2

50

% of FS max

FS = Full-Scale Output Current

V_CC= 5 V

ppm of FS/°C max Includes On-Chip Reference Drift

% of FS max V_CC= 5 V

ppm of FS/°C max Includes On-Chip Reference Drift

nA/mV max

Total Output Error (20 mA) @ +25°C⁴

Total Output Drift

V_CCSupply Sensitivity

50

25 nA/mV Typical

VOLTAGE REFERENCE

REF OUT2

Output Voltage

Drift

2.49/2.51

40

V min/V max

ppm/°C max

2.5 V Nominal

20 ppm/°C Typical from –40°C to +25°C and

–2.5 ppm/°C Typical from +25°C to +85°C

Externally Available Current

V_CCSupply Sensitivity

Output Impedance

Noise (0.1 Hz–10 Hz)

REF OUT1

0.5

150

3

mA min

µV/V max

15 µV/V Typical

Ω typ

6

µV (p-p) typ

Output Voltage

Drift

1.24/1.26

50

V min/V max

ppm/°C max

1.25 V Nominal, 100 kΩ Load to COM⁵

20 ppm/°C Typical from –40°C to +25°C and

2 ppm/°C Typical from +25°C to +85°C

Externally Available Current

V_CCSupply Sensitivity

Output Impedance

Noise (0.1 Hz–10 Hz)

REF IN

0.5

150

3

mA min

µV/V max

15 µV/V Typical

Ω typ

4

µV (p-p) typ

Input Resistance

40

kΩ typ

DIGITAL INPUTS

V_IH(Logic 1)

V_IL(Logic 0)

I_IH

0.75 × V_CC

0.25 × V_CC

10

Binary

10

V min

V max

µA max

V_IN= V_CC

V_IN= 0 V

I_IL

Data Coding

Data Rate

Mbps max

POWER SUPPLIES

Operating Range

Quiescent Current

@ V_CC= 3 V

+2.95 to +5.05 V min to V max

Functional to 7 V

650

750

µA max

475 µA Typical

575 µA Typical

@ V_CC= 5 V

NOTES

¹The DN25D is available from Supertex, Inc., 1350 Bordeaux Drive, Sunnyvale, CA 94089.

²Temperature range is –40°C to +85°C.

³The max current loop voltage compliance is determined by the pass transistor breakdown voltage and is 350 V for the DN25D.

⁴With V_CC= 3 V, the transfer function shifts negative by typically 0.25%; a 16 kΩ resistor connected between COM and LOOPRTN will approximately compensate for the V_CC

supply sensitivity in moving from 5 V to 3 V by skewing the gain of the AD421.

⁵100 kΩ resistor only required if this reference is being used in application circuits.

Specifications subject to change without notice.

REV. C

–2–

AD421

TIMING CHARACTERISTICS^{1, 2, 3}

(V_CC= +3 V to +5 V, T_A= T_MINto T_MAXunless otherwise noted)

Parameter

(B Versions)

Units

Conditions/Comments

t_CK

t_CL

t_CH

t_DW

t_DS

t_DH

t_LD

t_LL

100

50

30

0

50

ns min

Data Clock Period

Data Clock Low Time

Data Clock High Time

Data Stable Width

Data Setup Time

Data Hold Time

Latch Delay Time

Latch Low Time

Latch High Time

t_LH

NOTES

¹Guaranteed by characterization at initial product release, not production tested.

²See Figures 1 and 2.

³All input signals are specified with tr = tf = 5 ns (10% to 90% of V_CC) and timed from a voltage level of (V_IN+ V_IL)/2; tr and tf should not exceed 1 µs on any digital

input.

Specifications subject to change without notice.

CLOCK

WORD "N"

WORD "N +1"

1

0

1

0

1

0

1

0

1

0

1

DATA

LATCH

Figure 1. Serial Interface Waveforms (Normal Data Load)

t_CK

t_CL

CLOCK

t_CH

t_DH

t_DS

DATA

t_DW

t_LD

t_LL

LATCH

t_LH

Figure 2. Serial Interface Timing Diagram

–3–

REV. C

AD421

ABSOLUTE MAXIMUM RATINGS*

PIN CONFIGURATION

DIP and SOIC

(T_A= +25°C unless otherwise noted)

DRIVE, BOOST, COMP to COM . . . –0.5 V to V_CC+ 0.5 V

LOOP RTN to COM . . . . . . . . . . . . . . . . . . . –2 V to + 0.5 V

Digital Input Voltage to COM . . . . . . . –0.5 V to V_CC+ 0.5 V

Operating Temperature Range

Commercial (B Version) . . . . . . . . . . . . . . –40°C to +85°C

Storage Temperature Range . . . . . . . . . . . . –65°C to +150°C

Junction Temperature . . . . . . . . . . . . . . . . . . . . . . . . +150°C

Plastic DIP Package, Power Dissipation . . . . . . . . . . 670 mW

1

2

3

4

5

6

7

8

16

15

REF OUT1

REF OUT2

REF IN

V

CC

BOOST

14 COMP

13

AD421

LV

LATCH

DRIVE

C1

12

TOP VIEW

(NOT TO SCALE)

CLOCK

11 C2

θ

_JAThermal Impedance . . . . . . . . . . . . . . . . . . . . 116°C/W

10

9

C3

DATA

Lead Temperature (Soldering, 10 sec) . . . . . . . . . . . . 260°C

LOOP RTN

COM

SOIC Package, Power Dissipation . . . . . . . . . . . . . . . 450 mW

θ

_JAThermal Impedance . . . . . . . . . . . . . . . . . . . . 110°C/W

Lead Temperature, Soldering

Vapor Phase (60 sec) . . . . . . . . . . . . . . . . . . . . . +215°C

Infrared (15 sec) . . . . . . . . . . . . . . . . . . . . . . . . . +220°C

ORDERING GUIDE

^*Stresses above those listed under Absolute Maximum Ratings may cause perma-

nent damage to the device. This is a stress rating only; functional operation of the

device at these or any other conditions above those listed in the operational

sections of this specification is not implied. Exposure to absolute maximum rating

conditions for extended periods may affect device reliability.

Temperature

Range

Package

Option^*

Model

AD421BN

AD421BR

AD421BRRL

EVAL-AD421EB

–40°C to +85°C

Evaluation Board

N-16

R-16

R-16; Reeled SOIC

*N = Plastic DIP, R = SOIC.

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 these devices feature 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.

WARNING!

ESD SENSITIVE DEVICE

–4–

REV. C

AD421

PIN FUNCTION DESCRIPTIONS

No. Mnemonic

Function

1

REF OUT1

Reference Output 1. A precision +1.25 V reference is provided at this pin. It is intended as a precision ref-

erence source for other devices in the transmitter. REF OUT1 is a buffered output capable of providing up

to 0.5 mA to external circuitry. If REF OUT 1 is required to sink current, a resistive load of 100 kΩ to COM

should be added. (See Reference section.)

2

REF OUT2

Reference Output 2. A precision +2.5 V reference is provided at this pin. To operate the AD421 with its

own reference, REF OUT2 should be connected to REF IN. It can also be used as a precision reference

source for other devices in the transmitter. REF OUT2 is a buffered output capable of providing up to

0.5 mA to external circuitry.

3

4

REF IN

LV

Voltage Reference Input. The reference voltage for the AD421 is applied to this pin and it sets the span for

the AD421. The nominal reference voltage for the AD421 is +2.5 V for correct operation. This can be sup-

plied using an external reference source or by using the part’s own REF OUT2 voltage.

Regulated Voltage Control Input. The LV input controls the loop gain of the servo amplifier to set V_CC

.

With LV connected to COM, the regulator voltage is set to 5 V nominal. If the LV input is connected through

0.01 µF to V_CC, the regulated voltage is nominally 3.3 V. With LV connected to V_CCthe regulated voltage,

V

_CC, is 3 V nominal.

5

6

LATCH

CLOCK

DAC Latch Input. Logic Input. A rising edge of the LATCH signal loads the data from the serial input shift

register to the DAC latch and hence updates the output of the DAC. The number of clock cycles provided

between latch pulses determines whether the DAC is in alarm or normal current mode. (See Digital Inter-

face section.)

Data Clock Input. Data on the DATA input is clocked into the shift register on the rising edge of this

CLOCK input. The period of this clock equals the input serial data bit rate. This serial clock rate can be up

to 10 MHz. If 16 clock cycles are provided between LATCH pulses then the data on the DATA input is

accepted as normal 4–20 mA data. If more than 16 clock cycles are provided between LATCH pulses, the

data is assumed to be alarm current data (see Digital Interface section).

7

DATA

Data Input. The data to be loaded to the AD421 input shift register is applied to this input. Data should be

valid on the rising edge of the CLOCK input.

8

9

LOOP RTN

COM

Loop Return Output. LOOP RTN is the return path for current flowing in the current loop.

Common. This is the reference potential for the AD421 analog and digital inputs and outputs and for the

voltage regulator output.

10

C3

Filtering Capacitor. A low dielectric absorption capacitor ceramic capacitor should be connected between

this pin and COM for internal filtering of the switched current sources.

11

12

13

C2

C1

DRIVE

Filtering Capacitor. See C3 description.

Output from the Voltage Regulator Loop. The DRIVE signal controls the external pass transistor to establish and

maintain the correct V_CClevel programmed by the LV inputs while providing the necessary bias as the loop cur-

rent is programmed from 4 mA to 20 mA.

14

15

16

COMP

BOOST

V_CC

Compensation Capacitor Input. A capacitor connected between COMP and DRIVE is required to stabilize

the feedback loop formed with the regulator op amp and the external pass transistor.

This open collector pin sinks the necessary current from the loop so that the current flowing into BOOST

plus the current flowing into COM is equal to the programmed loop current.

Power Supply. V_CCis the power supply input of the AD421 and it also provides the voltage regulator output,

driven by the external pass transistor. It is used both to bias the AD421 itself and to provide power for the

rest of the smart transmitter circuitry. The LV input determines the regulated voltage output to be either

3 V, 3.3 V or 5 V nominal. Alternatively, a separate power supply can be connected to this pin to power the

AD421. V_CCshould be decoupled to COM with a 2.2 µF capacitor.

–5–

REV. C

AD421

CIRCUIT DESCRIPTION

Table I. FET Characteristics

N-Channel Depletion Mode

The AD421 is designed for use in loop-powered 4–20 mA smart

transmitter applications. A smart transmitter, as a remote in-

strument, controls its current output signal on the same pair of

wires from which it receives its power. The AD421 essentially

provides three primary functions in the smart transmitter. These

functions are a DAC function for converting the microprocessor/

microcontroller’s digital data to analog format, a current amp-

lifier which sets the current flowing in the loop and a voltage

regulator to provide a stable operating voltage from the loop

supply. The part also contains a high speed serial interface, two

buffered output references and a clock oscillator circuit. The

different sections of the AD421 are discussed in more detail

below.

FET Type

I_DSS

24 mA min

BV_DS

(V_LOOP– V_CC) min

V_CCmax

V_PINCHOFF

Power Dissipation

24 mA × (V_LOOP– V_CC) min

where V_CCis the operating voltage of the AD421 and V_LOOPis

the loop voltage.

The DN25D FET transistor from Supertex¹meets all the above

requirements for the FET. Other suitable transistors include

ND2020L and ND2410L, both from Siliconix.

Voltage Regulator

There are a number of external components required to com-

pensate the regulator loop and ensure stable operation. The

capacitor from the V_CCpin to the COM pin is required to

stabilize the regulator loop.

The voltage regulator consists of an op amp, bandgap reference

and an external depletion mode FET pass transistor. This cir-

cuit is required to regulate the loop voltage that powers the

AD421 itself and the rest of the transmitter circuitry. Figure 3

shows the voltage regulator section of the AD421 plus the associ-

ated external circuitry for a V_CCof 3.3 V.

To provide additional compensation for the regulator loop, a

compensation capacitor of 0.01 µF should be connected

between the COMP and DRIVE pins and an external circuit

of a 1 kΩ resistor and a 1000 pF capacitor in series should be

connected between DRIVE and COM to stabilize this feed-

back loop formed with the regulator op amp and the external

pass transistor.

LOOP(+)

V

TO EXTERNAL

CIRCUITRY

CC

DN25D

2.2␮F

0.01␮F

LV

COM

V

CC

DAC Section

75k⍀

112.5k⍀

The AD421 contains a 16-bit sigma-delta DAC to convert the

digital information loaded to the input latch into a current. The

sigma-delta architecture is particularly useful for the relatively

low bandwidth requirements of the industrial control environ-

ment because of its inherent monotonicity at high resolution.

The AD421 guarantees monotonicity to the 16-bit level.

AD421

134k⍀

DRIVE

COMP

1.21V

BANDGAP

REFERENCE

0.01␮F

121k⍀

1k⍀

1000pF

The sigma-delta DAC consists of a second order modulator

followed by a continuous time filter. The single bit stream from

the modulator controls a switched current source. This current

source is then filtered by three resistor-capacitor filter sections.

The resistors for each of the filter sections are on-chip while

the capacitors are external on the C1–C3 pins. To meet the

specified full-scale settling on the part, low dielectric absorption

capacitors (NPO) are required. Suitable values for these capacitors

are C1 = 0.01 µF, C2 = 0.01 µF, and C3 = 0.0033 µF.

Figure 3. AD421 Voltage Regulator Circuit to Provide

V_CC= 3.3 V

The signal on the LV pin selects the voltage to which V_CC

regulates by changing the gain of the resistor divider between

the op amp inverting input and the V_CCpin. As the LV pin

varies between COM and V_CC, the voltage from the regulator

loop varies between 3 V and 5 V nominal. With LV connected

to COM, the regulated voltage is 5 V; with LV connected

through a 0.01 µF capacitor to V_CC, the regulated voltage is

3.3 V while if LV is connected to V_CC, the regulated voltage

is 3 V.

Current Amplifier

The DAC output current drives the second section, an opera-

tional amplifier and NPN transistor which acts as a current

amplifier to set the current flowing through the LOOP RTN

pin. Figure 4 shows the current amplifier section of the AD421.

An 80 kΩ resistor connected between the DAC output and loop

return is used as a sampling resistor to determine current. The

base drive to the NPN transistor servos the voltage across the

40 Ω resistor to equal the voltage across the 80 kΩ resistor.

The range of loop voltages that can be used by the configuration

shown in Figure 3 is determined by the FET breakdown and

saturation voltages. The external FET parameters such as Vgs

(off), I_DSSand transconductance must be chosen so that the op

amp output on the DRIVE pin can control the FET operating

point while swinging in the range from V_CCto COM.

The main characteristics for selecting the FET pass transistor

are as follows:

–6–

REV. C

AD421

Reference Section

SWITCHED

CURRENT

SOURCES

The AD421 contains an on-chip 1.21 V bandgap reference

which is used as part of the voltage regulator loop. A bandgap

reference is also used to generate two references voltages

which are available for use external to the AD421. Figure 5

shows the reference section of the AD421. The REF OUT1 pin

provides a buffered +1.25 V reference voltage which can supply

up to 0.5 mA of external current. The REF OUT2 pin provides

a +2.5 V reference voltage which is also capable of providing

0.5 mA of external current. To use the AD421 with its own

reference, simply connect the REF OUT2 pin to the REF IN

pin of the device. Alternatively, the part can be used with an

external reference by connecting the external reference between

REF IN and COM.

AD421

BOOST

80k⍀

40⍀

LOOP RTN

Figure 4. Current Amplifier

The BOOST pin is normally tied to the V_CCpin. As the DAC

input code varies from all zeros to full scale, the output current

from the NPN transistor and thus the total loop current varies

from 4 mA to 20 mA. With BOOST and V_CCtied together, the

external FET (DN25D) has to supply the full range of loop

current (4 mA to 20 mA).

When REF OUT1 and REF OUT2 are used in application

circuits, external 4.7 µF capacitors are required on the reference

pins to provide compensation and ensure stable operation of the

references. These capacitors can be omitted if the internal refer-

ences are not required.

Digital Interface

The digital interface on the AD421 consists of just three wires:

DATA, CLOCK and LATCH. The interface connects directly

to the serial ports of commonly-used microcontrollers without

the need for any external glue logic. Data is loaded MSB first

into an input shift register on the rising edge of the CLOCK

signal and is transferred to the DAC latch on the rising edge of

the LATCH signal. The timing diagrams for the serial interface

are shown in Figure 1 and Figure 2.

4.7␮F

REF OUT1

(1.25V)

REF OUT2

(2.5V)

V

LV

CC

75k⍀

AD421

112.5k⍀

50k⍀

134k⍀

The data to be loaded to the AD421’s input shift register takes

two forms; normal 4 mA to 20 mA data or alarm current data.

The first form is where the AD421 operates over its normal

4 mA to 20 mA output range with 16 bits of resolution between

these endpoints. The second form allows the user to program a

current value outside this range as an indication from the trans-

mitter than there is a problem with the transducer. The AD421

counts the number of clock pulses which it receives between

LATCH signals as a means of determining whether the data

clocked in is 4 mA to 20 mA data or alarm current data.

2.5V

1.21V

DRIVE

BANDGAP

REFERENCE

121k⍀

Figure 5. Reference Section

REF OUT2 is sensed internally, and if more than 0.5 mA is

drawn externally from this reference, the chip goes into a power

on reset state. In this state the sigma-delta DAC is disabled, the

internal oscillator is stopped and the input data latch is cleared.

If there are 16 rising clock edges between successive LATCH

pulses, then the data being loaded to the input shift register is

assumed to be normal 4 mA to 20 mA data. On the rising edge

of the LATCH signal, the input shift register data is transferred

to the DAC latch in a 16-bit parallel transfer. In this case, the

16 bits of data in the DAC latch program the output current

between 4 mA for all 0s and 20 mA for all 1s (see Table II).

Data transferred to the AD421 should be MSB first.

REF OUT1 has limited current sinking capability. If REF

OUT1 is required to sink current, a resistive load of 100 kΩ

to COM should be added in addition to the 4.7 µF capacitor.

USING THE AD421

The AD421 can be programmed for normal 4 mA to 20 mA

operation or for alarm current operation. For normal operation,

the coding is 16-bit straight (natural) binary over an output

current range of 4 mA to 20 mA. For alarm current operation,

the coding is also straight binary but with 17 bits of resolution

over twice the span, 0 mA to 32 mA, although the part should

not be programmed outside the range of 3.5 mA to 24 mA. To

determine whether data written to the part is normal 4 mA to

20 mA data or alarm current data, the number of clock pulses

between two successive LATCH pulses are counted. If the num-

ber of pulses is 0–16 (modulo 32), it chooses normal mode; if it

is 17–31 (modulo 32), it chooses alarm current range.

If there are more than 16 clock pulses between successive

LATCH pulses, then the data being loaded to the input shift

register is assumed to be alarm current data. In this case, the

AD421 accepts 17 bits of data into its shift register. For situa-

tions where there are more than 17 clocks in the serial write

operation (for example, 24 clocks in a 3 × 8-bit transfer from the

serial port of a microcontroller) the AD421 simply accepts the

last 17 bits of the serial write operation. Data transferred in this

serial write operation is LSB last (i.e., the MSB is loaded on the

17th rising clock edge prior to the LATCH pulse). On the rising

edge of the LATCH signal, the input shift register data is trans-

ferred to the DAC latch in a 17-bit parallel transfer. In this

case, the 17 bits of data in the DAC latch program the output

current between 0 mA for all 0s and 32 mA for all 1s (see Table

III). However, in practice the AD421 cannot reliably produce a

current less than 3.5 mA or more than 24 mA.

4 mA to 20 mA Coding

Table II shows the ideal input-code-to-output-current relation-

ship for normal operation of the AD421. The output current

values shown assume a REF IN voltage of +2.5 V. With a

REF IN of +2.5 V, 1 LSB = 16 mA/65,536 = 244 nA. Figure 6

shows a timing diagram for programming the AD421 for normal

4 mA to 20 mA operation, the AD421 outputting a current

–7–

REV. C

AD421

of 11.147 mA. With 16 clock pulses between consecutive latch

signals data written is for normal 4 mA to 20 mA operation.

CLOCK

DATA

WORD "N"

0 0 1 1

Table II. Ideal Input/Output Code Table

for 4 mA to 20 mA Operation

0

1

0

0 0 0 0 0 0 0 0

X X X X X X X

Code

Output Current

0000 0000 0000 0000

0000 0000 0000 0001

0000 0000 0000 0010

4 mA

4.000244 mA

4.000488 mA

LATCH

Figure 7. Write Cycle for Programming Alarm Current

Data

0100 0000 0000 0000

1000 0000 0000 0000

1100 0000 0000 0000

8 mA

12 mA

16 mA

MICROPROCESSOR INTERFACING

AD421 – MC68HC11 (SPI BUS) INTERFACE

Figure 8 shows a typical interface between the AD421 and the

Motorola MC68HC11 SPI (Serial Peripheral Interface) bus.

The SCK, MOSI and SS pins of the 68HC11 are respectively

connected to the CLOCK, DATA IN and LATCH pins of the

AD421.

1111 1111 1111 1101

1111 1111 1111 1110

1111 1111 1111 1111

19.999268 mA

19.999512 mA

19.999756 mA

CLOCK

DATA

WORD "N +1"

WORD "N"

CLOCK

SCK

AD421*

68HC11

1

0

1

0

1

0

1

0

1

0 0 1

MOSI

DATA IN

LATCH

SS

* ADDITIONAL PINS OMITTED FOR CLARITY

LATCH

Figure 8. AD421 to 68HC11 Interface

A typical routine such as the one shown below begins by initializ-

ing the state of the various SPI data and control registers.

Figure 6. Write Cycle for 4 mA to 20 mA Operation

Alarm Current Coding

INIT

LDAA #$2F

;SS = 1; SCK = 0; MOSI = 1

Table III shows the ideal input-code-to-output-current relation-

ship for alarm current programming of the AD421. In this case,

the equivalent span is 0 mA to 32 mA but a reliable operating

span is 3.5 mA to 24 mA. The part may give an indeterminate

output for code values outside the range given in the table. As a

result, the user is advised to restrict the code programmed to the

part in alarm current mode to within the range shown in Table

III. Figure 7 shows a timing diagram for loading an alarm cur-

rent of 3.75 mA to the AD421 with an 8-bit microcontroller

using three 8-bit writes.

STAA PORTD ;SEND TO SPI OUTPUTS

LDAA #$38

STAA DDRD

LDAA #$50

STAA SPCR

;SS, SCK, MOSI = OUTPUTS

;SEND DATA DIRECTION INFO

;DABL INTRPTS, SPI IS MASTER & ON

;CPOL = 0, CPHA = 0, 1MHZ BAUDRATE

;LOAD ACCUM W/UPPER 8 BITS

NEXTPT LDAA MSBY

BSR

JMP

SENDAT ;JUMP TO DAC OUTPUT ROUTINE

NEXTPT ;INFINITE LOOP

SENDAT LDY

#$1000

;POINT AT ON-CHIP REGISTERS

BCLR $08,Y,$20 ;DRIVE SS (LATCH) LOW

STAA SPDR

LDAA SPSR

;SEND MS-BYTE TO SPI DATA REG

;CHECK STATUS OF SPIE

The output current values shown assume a REF IN voltage of

+2.5 V. With a REF IN of +2.5 V, an ideal 1 LSB = 32 mA/

131,072 = 244 nA.

WAIT1

WAIT2

BPL

WAIT1

;POLL FOR END OF X-MISSION

;GET LOW 8 BITS FROM MEMORY

;SEND LS-BYTE TO SPI DATA REG

;CHECK STATUS OF SPIE

LDAA LSBY

STAA SPDR

LDAA SPSR

Table III. Ideal Input/Output Code Table

for Alarm Current Operation

BPL

WAIT2; ;POLL FOR END OF X-MISSION

BSET $08,Y,$20 ;DRIVE SS HIGH TO LATCH DATA

RTS

Code

Output Current

3.5 mA

3.75 mA

4 mA

The SPI data port is configured to process data in 8-bit bytes.

The most significant data byte (MSBY) is retrieved from

memory and processed by the SENDAT routine. The SS pin is

driven low by indexing into the PORTD data register and clear

Bit 5. The MSBY is then sent to the SPI data register where it is

automatically transferred to the AD421 internal shift resistor.

0 0011 1000 0000 0000

0 0011 1100 0000 0000

0 0100 0000 0000 0000

0 1000 0000 0000 0000

1 0000 0000 0000 0000

1 0100 0000 0000 0000

1 0110 0000 0000 0000

1 1000 0000 0000 0000

8 mA

16 mA

20 mA

22 mA

24 mA

–8–

REV. C

AD421

The HC11 generates the requisite eight clock pulses with data

valid on the rising edges. After the MSBY is transmitted, the

least significant byte (LSBY) is loaded from memory and

transmitted in a similar fashion. To complete the transfer, the

LATCH pin is driven high when loading the complete 16-bit

word into the AD421.

V

CC

2.2␮F

0.1␮F

V

CC

10k⍀

V

CC

CLOCK

LATCH

CLOCK

AD421 TO MICROWIRE INTERFACE

CC

AD421*

The flexible serial interface of the AD421 is also compatible

with the National Semiconductor MICROWIRE interface. The

MICROWIRE interface is used in microcontrollers such as the

COP400 and COP800 series of processors. A generic interface

to use the MICROWIRE interface is shown in Figure 9. The

G1, SK, and SO pins of the MICROWIRE interface respec-

tively connect to the LATCH, CLOCK, and DATA IN pins of

the AD421.

10k⍀

LATCH

CC

10k⍀

DATA IN

COM

* ADDITIONAL PINS OMITTED FOR CLARITY

CLOCK

SK

SO

G1

AD421*

MICROWIRE

Figure 10. Opto-Isolated Interface

DATA IN

LATCH

APPLICATIONS SECTION

Basic Operating Configuration

Figure 11 shows the basic connection diagram for the AD421

operating at 5 V. This circuit shows the minimum of external

components to operate the AD421. In the diagram, the AD421’s

regulator loop in conjunction with the DN25D pass transistor

provides the V_CCvoltage for the AD421 itself and for other

devices in the transmitter. The V_CCpin should be well decou-

pled with a 2.2 µF capacitor to ensure regulator stability and to

absorb power glitches on the V_CCline of the AD421 and other

devices in the system. If the AD421 is operated with V_CC= 3 V,

the transfer function shifts negative. To correct for this a 16 kΩ

resistor connected between COM and LOOPRTN will approxi-

mately compensate for the V_CCsupply sensitivity in moving from

5 V to 3 V by adjusting the gain of the AD421.

* ADDITIONAL PINS OMITTED FOR CLARITY

Figure 9. AD421 to MICROWIRE Interface

Opto-Isolated Interface

The AD421 has a versatile serial 3-wire serial interface making

it ideal for minimizing the number of control lines required for

isolation of the digital system from the control loop. In intrinsi-

cally safe applications or due to noise, safety requirements, or

distance, it may be necessary to isolate the AD421 from the

controller. This can easily be achieved by using opto-isolators.

Figure 10 shows an opto-isolated interface to the AD421 where

CLOCK, DATAIN and LATCH are driven from opto-couplers.

Be aware of signal inversion across the opto-couplers. If opto-

couplers with relatively slow rise and fall times are used, Schmitt

triggers may be required on the digital inputs to prevent errone-

ous data being presented to the DAC.

V

TO EXTERNAL

CIRCUITRY

CC

DN25D

2.2␮F

4.7␮F

COM

LV

REF OUT2

REF OUT1

REF IN

V

CC

DRIVE

V

LOOP

0.01␮F

COMP

DATA

CLOCK

1k⍀

AD421

1000pF

BOOST

LATCH

LOOP RTN

COM

C1

C2

C3

0.0033␮F

COM TO EXTERNAL

CIRCUITRY

0.01␮F 0.01␮F

Figure 11. Basic Connection Diagram

–9–

REV. C

AD421

A capacitor of 0.01 µF connected between COMP and DRIVE

is required to stabilize the feedback loop formed with the

regulator op amp and the external pass transistor. An external

snubber circuit of 1 kΩ and 1000 pF is required between the

DRIVE pin and COM and a 0.1 µF cap between COMP and

DRIVE to stabilize the feedback loop formed by the regulator

op amp and the external pass transistor.

Smart Transmitter

The AD421 is intended for use in 4 mA to 20 mA smart trans-

mitters. A smart transmitter is a system that incorporates a

microprocessor system which is used for linearization and

communication. Figure 13 shows a block diagram of a typical

smart transmitter. In this example, the transmitter does not have

any digital communication capabilities.

The internal 2.5 V reference on the AD421 is used as the refer-

ence for the AD421 and this has to be decoupled with a 4.7 µF

capacitor for compensation and stability purposes. The sigma-

delta DAC on the part consists of a second order modulator

followed by a continuous time filter. The resistors for each of

the filter sections are on-chip while the capacitors are external

on the C1 to C3 pins. To meet the specified full-scale settling

on the part, low dielectric absorption capacitors (NPO) are

required. Suitable values for these capacitors are C1 = C2 =

0.01 µF, and C3 = 0.0033 µF.

MEMORY

4mA TO 20mA

A/D

CONVERTER

MICRO-

PROCESSOR

D/A

CONVERTER

SENSORS

MEASUREMENT

CIRCUIT

Figure 13. Typical Smart Transmitter

Figure 14 shows a typical smart transmitter application circuit

using the AD421.

The digital interface on the AD421 consists of just three wires:

DATA, CLOCK and LATCH. The interface connects directly

to the serial ports of commonly-used microcontrollers without

the need for any external glue logic. Data is loaded into an input

shift register on the rising edge of the CLOCK signal and is

transferred to the DAC latch on the rising edge of the LATCH

signal.

The sensor voltage to be measured at the transmitter is con-

verted using a high resolution sigma-delta converter such as

the AD7714 or AD7715. These devices have an on-board PGA

which can provide gains on the analog front end from 1 to 128.

This allows for an analog input range as low as 10 mV which

allows the transducer to be connected directly to the ADC. The

AD7714/AD7715 have digital calibration techniques which are

used to eliminate gain and offset errors. In addition, back-

ground calibration techniques are provided whereby the part

continually calibrates itself and the user does not have to

worry about issuing periodic calibration commands to remove

effects of time and temperature drift.

Reduce Power Load on External FET

Figure 12 shows a circuit where an external NPN transistor is

added to reduce the power loading on the FET. The FET will

supply the V_CCand an external high voltage NPN bipolar tran-

sistor can carry the BOOST current. The BOOST pin sinks the

necessary current from the loop so that the current flowing into

BOOST plus the current flowing into COM is equal to the

programmed loop current. The external NPN transistor reduces

the external power load that the FET has to carry to less than

750 µA if no other components share the V_CCline and to less

than 4 mA in applications that share the same V_CCline as the

AD421.

In normal operation the microprocessor reads the data from the

AD7714/AD7715. After the data is processed by the micro-

controller, the data is transferred from the serial port of the

processor to the AD421 for transmission over the 4 to 20 mA

loop back to the control center.

The AD421 regulates the loop voltage to create power for the

rest of the transmitter circuitry. In Figure 14, the derived V_CC

voltage is 3.3 V which is achieved by connecting the LV pin to

V_CCthrough 0.01 µF. REF OUT2 provides the reference volt-

age for the AD421 itself while REF OUT1 provides the refer-

ence voltage for the AD7714/AD7715.

LOOP(+)

V

TO EXTERNAL

CIRCUITRY

CC

DN25D

BC639/BC337

2.2␮F

COM

LV

V

CC

75k⍀

112.5k⍀

AD421

134k⍀

DRIVE

1.21V

BANDGAP

REFERENCE

0.01␮F

COMP

1k⍀

1000pF

121k⍀

BOOST

80k⍀

40⍀

LOOP RTN

LOOP(–)

Figure 12. External NPN Transistor Reduces Power Load

on FET

–10–

REV. C

AD421

DN25D

3.3V

0.01␮F

2.2␮F

0.1␮F

DV

DD

AV

DD

BOOST

V

LV

CC

SENSORS

RTD

mV ⍀ TC

1.25V

REF OUT1

REF IN

LOOP

REF OUT2

REF IN

4.7␮F

100k⍀

4.7␮F

ANALOG

TO

DIGITAL

CONVERTER

POWER

0.01␮F

V

CC

AMBIENT

TEMP

SENSOR

COMP

DRIVE

CLOCK

LATCH

DATA

AD7714/

AD7715

MICROCONTROLLER

GND

1k⍀

1000pF

MCLK IN

AD421

MCLK OUT

CS

LOOP

RTN

DATA OUT

SCLK

COM

DATA IN

C1

C2

C3

AGND

DGND

Figure 14. AD421 in Smart Transmitter Application

HART Interfacing

Figure 16 shows a block diagram of a smart and intelligent

transmitter. An intelligent transmitter is a transmitter in which

the functions of the microprocessor are shared between deriving

the primary measurement signal, storing information regarding

the transmitter itself, its application data and its location and

also managing a communication system which enables two way

communication to be superimposed on the same circuit that

carries the measurement signal. A smart transmitter incorporat-

ing the HART protocol is an example of a smart intelligent

transmitter.

The HART protocol uses a frequency shift (FSK) keying tech-

nique based on the Bell 202 Communication Standard which is

one of several standards used to transmit digital signals over

the telephone lines. This technique is used to superimpose

digital communication on to the 4 mA to 20 mA current loop

connecting the central system to the transmitter in the field.

Two different frequencies, 1200 Hz and 2200 Hz, are used to

represent binary 1 and 0 respectively, as shown in Figure 15.

These sine wave tones are superimposed on the dc signal at a

low level with the average value of the sine wave signal being

zero. This allows simultaneous analog and digital communica-

tions. Additionally, no dc component is added to the existing

4 mA to 20 mA signal regardless of the digital data being sent

over the line. Consequently, existing analog instruments con-

tinue to work in systems that implement HART as the low-pass

filtering usually present effectively removes the digital signal. A

single pole 10 Hz low-pass filter effectively reduces the commu-

nication signal to a ripple of about 0.01% of the full-scale

signal. The HART protocol specifies that master devices like a

host control system or a hand held terminal transmit a voltage

signal whereas a slave or field device transmits a current signal.

The current signal is converted into a corresponding voltage by

the loop load resistor.

MEMORY

4mA TO 20mA

A/D

CONVERTER

MICRO-

PROCESSOR

D/A

CONVERTER

SENSORS

MEASUREMENT

CIRCUIT

COMMUNICATION

SYSTEM

Figure 16. Smart and Intelligent Transmitter

Figure 17 shows an example of the AD421 in a HART transmit-

ter application. Most of the circuit is as outlined in the smart

transmitter as shown in Figure 14. The HART data transmitted

on the loop is received by the transmitter using a bandpass filter

and modem and the HART data is transferred to the micro-

controller’s UART or asynchronous serial port. HART data to

be transmitted on the loop is sent from the microcontroller’s

UART or asynchronous serial port to the modem. It is then

waveshaped before being coupled onto the AD421’s output at

the C3 pin. The value of the coupling capacitor C_Cis determined

by the waveshaper output and the C3 capacitor of the AD421. The

blocks containing the Bell 202 Modem, waveshaper and bandpass

filter come in a complete solution with the 20C15 from Symbios

Logic, Inc., or HT2012 from SMAR Research Corp.

APPROX

+0.5mA

APPROX

–0.5mA

2200Hz

“0”

1200Hz

“1”

For a more complete AD421-20C15 interface, please refer to

Application Note AN-534 on the Analog Devices’ website

www.analog.com or contact your local sales office.

Figure 15. HART Transmission of Digital Signals

–11–

REV. C

AD421

DN25D

3.3V

0.01␮F

2.2␮F

0.1␮F

DV

DD

AV

DD

BOOST

LV

V

CC

SENSORS

RTD

mV ⍀ TC

1.25V

REF IN

REF OUT1

REF OUT2

REF IN

LOOP

POWER

100k⍀

4.7␮F

ANALOG

TO

DIGITAL

CONVERTER

0.01␮F

V

CC

COMP

DRIVE

AMBIENT

TEMP

SENSOR

CLOCK

LATCH

DATA

AD7714/

AD7715

MICROCONTROLLER

GND

1k⍀

MCLK IN

1000pF

AD421

MCLK OUT

CS

LOOP

RTN

DATA OUT

SCLK

COM

DATA IN

C1

C2

C3

AGND

DGND

C

*

C

WAVEFORM

SHAPER

BANDPASS

FILTER

HART

MODEM

BELL 202

HT20C12/20C15

*FOR SELECTION OF C , REFER TO AN-534

C

Figure 17. AD421 in HART Transmitter Application

Current Source

across R2. The ratio of R1 to R2 determines the current that

flows in the load resistor R_L. I_L= [1 + R1/R2] × I_PROG, where I_L

is the current that flows in the load resistor R_Land I_PROGis the

current programmed to the AD421. R1 and R2 are external to

the AD421 and will need to be matched resistors to obtain a

highly accurate current source.

Figure 18 shows an application circuit for the AD421 being

used as a current source. The current programmed to the

AD421 (4 mA to 20 mA) will develop a voltage across R1.

This same voltage due to negative feedback will be generated

5 VOLT

REGULATOR

+5V

V

OUT

IN

S

2.2␮F

10k⍀

4.7␮F

COM

10k⍀

COM

V

REF IN

DATA

LV

REF OUT2

REF OUT1

CC

10k⍀

DRIVE

COMP

DATA

BOOST

AD421

CLOCK

LATCH

LOOP

RTN

LATCH

C3

C1

C2

COM

R1

R2

0.01␮F

0.0033␮F

R

L

V

RETURN

S

Figure 18. AD421 in Programmable Current Source/Sink

–12–

REV. C

AD421

Battery Backup

Figure 19 shows an application circuit for the AD421 where the

micro and memory sections of the circuitry are protected against

losing data if the loop is broken. The backup circuit switches

from V_CCto battery voltage without a glitch when V_CCpower is

lost. The IRFF9113 acts as a current source during normal

operation and provides a constant charging current to the supercap

or Nicad. The loss of V_CCdrops the IRFF9113’s gate voltage to

zero volts, which allows the battery or supercaps current to flow

through the MOSFETs channel and integral body diode to

provide power for the micro and memory sections. To calibrate

this circuit, connect an ammeter in series with the battery or

supercap. Then with V_CCand the load present adjust the 100 kΩ

potentiometer for the battery charging current recommended by

the battery or supercap manufacturer.

DN25D

IN3611

IRFF9113

0.1␮F

4.7␮F

IN3611

V

LOOP

V

CC

100k⍀

2.2␮F

MICRO/

MEMORY

V

CC

SUPERCAP

GND

DRIVE

AD421*

LOOP

RTN

COM

*ADDITIONAL CIRCUITRY OMITTED FOR CLARITY

Figure 19. Battery Backup Circuit

Nonrechargeable batteries should not be used in this application

due to danger of explosion.

–13–

REV. C

AD421

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

16-Lead Plastic DIP

(N-16)

0.840 (21.34)

0.745 (18.92)

16

1

9

0.280 (7.11)

0.240 (6.10)

8

0.325 (8.26)

0.195 (4.95)

0.115 (2.93)

0.300 (7.62)

PIN 1

0.060 (1.52)

0.015 (0.38)

0.210 (5.33)

MAX

0.130

(3.30)

MIN

0.160 (4.06)

0.115 (2.93)

0.015 (0.381)

0.008 (0.204)

0.070 (1.77) SEATING

0.045 (1.15)

0.100

(2.54)

BSC

0.022 (0.558)

0.014 (0.356)

PLANE

16-Lead (Wide Body) Small Outline Package

(R-16)

0.4133 (10.50)

0.3977 (10.00)

16

9

1

8

0.1043 (2.65)

0.0926 (2.35)

PIN 1

0.0291 (0.74)

0.0098 (0.25)

x 45؇

0.0118 (0.30)

0.0040 (0.10)

0.0500 (1.27)

0.0157 (0.40)

8؇

0؇

0.0500

(1.27)

BSC

0.0192 (0.49)

0.0138 (0.35)

SEATING

PLANE

0.0125 (0.32)

0.0091 (0.23)

–14–

REV. C


型号：	AD421BRZRL
厂家：	ADI
描述：	Loop-Powered 4 mA to 20 mA DAC 回路供电4毫安至20 mA DAC 转换器数模转换器光电二极管
文件：	总14页 (文件大小：172K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

AD421BRZRL [ADI]

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