AD536ASCHIPS [ADI]

Integrated Circuit True RMS-to-DC Converter; 集成电路真RMS至DC转换器


型号：	AD536ASCHIPS
厂家：	ADI
描述：	Integrated Circuit True RMS-to-DC Converter 集成电路真RMS至DC转换器转换器
文件：	总8页 (文件大小：152K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

Integrated Circuit

True RMS-to-DC Converter

AD536A

FEATURES

PIN CONFIGURATIONS AND

True RMS-to-DC Conversion

Laser-Trimmed to High Accuracy

0.2% Max Error (AD536AK)

0.5% Max Error (AD536AJ)

Wide Response Capability:

Computes RMS of AC and DC Signals

450 kHz Bandwidth: V rms > 100 mV

2 MHz Bandwidth: V rms > 1 V

Signal Crest Factor of 7 for 1% Error

dB Output with 60 dB Range

Low Power: 1.2 mA Quiescent Current

Single or Dual Supply Operation

Monolithic Integrated Circuit

–55؇C to +125؇C Operation (AD536AS)

FUNCTIONAL BLOCK DIAGRAMS

TO-100 (H-10A)

Package

TO-116 (D-14) and

Q-14 Package

OUT

ABSOLUTE

VALUE

BUF IN

25k⍀

AD536A

25k⍀

SQUARER

DIVIDER

AD536A

–V

BUF

COM

OUT

CURRENT

MIRROR

BUF

CURRENT

MIRROR

COM

SQUARER

DIVIDER

BUF

OUT

25k⍀

BUF

ABSOLUTE

VALUE

OUT

25k⍀

NC = NO CONNECT

–V

PRODUCT DESCRIPTION

LCC (E-20A) Package

The AD536A is a complete monolithic integrated circuit which

performs true rms-to-dc conversion. It offers performance which

is comparable or superior to that of hybrid or modular units

costing much more. The AD536A directly computes the true

rms value of any complex input waveform containing ac and dc

components. It has a crest factor compensation scheme which

allows measurements with 1% error at crest factors up to 7. The

wide bandwidth of the device extends the measurement capabi-

lity to 300 kHz with 3 dB error for signal levels above 100 mV.

20 19

ABSOLUTE

VALUE

–V

AD536A

17 NC

SQUARER

DIVIDER

25k⍀

CURRENT

MIRROR

15 NC

COM

25k⍀

BUF

10 11 12

An important feature of the AD536A not previously available in

rms converters is an auxiliary dB output. The logarithm of the

rms output signal is brought out to a separate pin to allow the

dB conversion, with a useful dynamic range of 60 dB. Using an

externally supplied reference current, the 0 dB level can be con-

veniently set by the user to correspond to any input level from

0.1 to 2 volts rms.

BUF BUF

OUT IN

NC = NO CONNECT

OUT

PRODUCT HIGHLIGHTS

1. The AD536A computes the true root-mean-square level of a

complex ac (or ac plus dc) input signal and gives an equiva-

lent dc output level. The true rms value of a waveform is a

more useful quantity than the average rectified value since it

relates directly to the power of the signal. The rms value of a

statistical signal also relates to its standard deviation.

The AD536A is laser trimmed at the wafer level for input and

output offset, positive and negative waveform symmetry (dc re-

versal error), and full-scale accuracy at 7 V rms. As a result, no

external trims are required to achieve the rated unit accuracy.

2. The crest factor of a waveform is the ratio of the peak signal

swing to the rms value. The crest factor compensation

scheme of the AD536A allows measurement of highly com-

plex signals with wide dynamic range.

There is full protection for both inputs and outputs. The input

circuitry can take overload voltages well beyond the supply lev-

els. Loss of supply voltage with inputs connected will not cause

unit failure. The output is short-circuit protected.

3. The only external component required to perform measure-

ments to the fully specified accuracy is the capacitor which

sets the averaging period. The value of this capacitor determines

the low frequency ac accuracy, ripple level and settling time.

The AD536A is available in two accuracy grades (J, K) for com-

mercial temperature range (0°C to +70°C) applications, and one

grade (S) rated for the –55°C to +125°C extended range. The

AD536AK offers a maximum total error of 2 mV 0.2% of

reading, and the AD536AJ and AD536AS have maximum errors

of 5 mV 0.5% of reading. All three versions are available in

either a hermetically sealed 14-lead DIP or 10-pin TO-100

metal can. The AD536AS is also available in a 20-leadless her-

metically sealed ceramic chip carrier.

4. The AD536A will operate equally well from split supplies or

a single supply with total supply levels from 5 to 36 volts.

The one milliampere quiescent supply current makes the

device well-suited for a wide variety of remote controllers and

battery powered instruments.

5. The AD536A directly replaces the AD536 and provides im-

proved bandwidth and temperature drift specifications.

REV. B

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

(@ +25

C, and ؎15 V dc unless otherwise noted)

AD536A–SPECIFICATIONS

Model

AD536AJ

Typ

AD536AK

Typ

AD536AS

Typ

Min

Max

Min

Max

Min

V_OUT

Max

Units

TRANSFER FUNCTION

CONVERSION ACCURACY

Total Error, Internal Trim¹(Figure 1)

vs. Temperature, T_MINto +70°C

+70°C to +125°C

)

V_OUT

avg.(V

avg.(V )

V_OUT

avg.(V )

؎5 ؎0.5

0.1 0.01

؎2 ؎0.2

0.05 0.005

؎5 ؎0.5

؎0.1 ؎0.005

؎0.3 ؎0.005

mV % of Reading

mV % of Reading/°C

mV % of Reading/V

% of Reading

vs. Supply Voltage

0.1 0.01

0.2

0.1 0.01

0.1

0.1 0.01

0.2

dc Reversal Error

Total Error, External Trim¹(Figure 2)

0.3

0.1

0.3

mV % of Reading

ERROR VS. CREST FACTOR²

Crest Factor 1 to 2

Specified Accuracy

Crest Factor = 3

Crest Factor = 7

–0.1

–1.0

–0.1

–1.0

–0.1

–1.0

% of Reading

FREQUENCY RESPONSE³

Bandwidth for 1% Additional Error (0.09 dB)

V_IN= 10 mV

120

kHz

V_IN= 100 mV

V_IN= 1 V

3 dB Bandwidth

V_IN= 10 mV

V_IN= 100 mV

V_IN= 1 V

450

2.3

450

2.3

450

2.3

kHz

MHz

AVERAGlNG TlME CONSTANT (Figure 5)

ms/µF CAV

INPUT CHARACTERISTICS

Signal Range, 15 V Supplies

Continuous rms Level

0 to 7

0 to 2

0 to 7

0 to 2

0 to 7

0 to 2

V rms

V peak

V rms

V peak

Peak Transient Input

Continuous rms Level, 5 V Supplies

Peak Transient Input, 5 V Supplies

Maximum Continuous Nondestructive

Input Level (All Supply Voltages)

Input Resistance

V peak

kΩ

13.33

16.67

0.8

13.33

16.67

0.5

13.33

16.67

0.8

Input Offset Voltage

OUTPUT CHARACTERISTICS

Offset Voltage, V_IN= COM (Figure 1)

vs. Temperature

vs. Supply Voltage

Voltage Swing, 15 V Supplies

5 V Supply

0.1

+12.5

0.5

0.1

؎2

؎0.2

mV/°C

mV/V

0.2

+12.5

0 to +11

0 to +2

0 to +11

0 to +2

+12.5

0 to +11

0 to +2

dB OUTPUT (Figure 13)

Error, V_lN7 mV to 7 V rms, 0 dB = 1 V rms

Scale Factor

0.4

–3

؎0.6

0.2

–3

؎0.3

0.5

–3

؎0.6

mV/dB

Scale Factor TC (Uncompensated, see Fig-

ure 1 for Temperature Compensation)

–0.033

+0.33

–0.033

+0.33

–0.033

+0.33

dB/°C

% of Reading/°C

_REFfor 0 dB = 1 V rms

100

µA

I_REFRange

I_OUTTERMINAL

_OUTScale Factor

–V_Sto (+V_S

–2.5 V)

–V_Sto (+V_S

–2.5 V)

–V_Sto (+V_S

–2.5 V)

µA/V rms

I_OUTScale Factor Tolerance

Output Resistance

Voltage Compliance

kΩ

BUFFER AMPLIFIER

Input and Output Voltage Range

–V_Sto (+V_S

–2.5 V)

–V_Sto (+V_S

–2.5 V)

–V_Sto (+V_S

–2.5 V)

Input Offset Voltage, R_S= 25 k

Input Bias Current

Input Resistance

0.5

؎4

0.5

؎4

0.5

؎4

Ω

10⁸

Output Current

(+5 mA,

–130 µA)

Short Circuit Current

Output Resistance

Small Signal Bandwidth

Slew Rate⁴

Ω

MHz

V/µs

0.5

POWER SUPPLY

Voltage Rated Performance

Dual Supply

Single Supply

3.0

+36

3.0

+36

3.0

+36

Quiescent Current

Total V_S, 5 V to 36 V, T_MINto T_MAX

1.2

TEMPERATURE RANGE

Rated Performance

Storage

–55

+70

+150

–55

+70

+150

–55

+125

+150

°C

NUMBER OF TRANSISTORS

NOTES

¹Accuracy is specified for 0 V to 7 V rms, dc or 1 kHz sine wave input with the AD536A connected as in the figure referenced.

²Error vs. crest factor is specified as an additional error for 1 V rms rectangular pulse input, pulsewidth = 200µs.

³Input voltages are expressed in volts rms, and error is percent of reading.

⁴With 2k external pull-down resistor.

Specifications subject to change without notice.

Specifications shown in boldface are tested on all production units at final electrical test. Results from those tests are used to calculate outgoing quality levels. All min and max specifications are guaranteed,

although only those shown in boldface are tested on all production units.

–2–

REV. B

AD536A

ABSOLUTE MAXIMUM RATINGS¹

STANDARD CONNECTION

Supply Voltage

The AD536A is simple to connect for the majority of high accu-

racy rms measurements, requiring only an external capacitor to

set the averaging time constant. The standard connection is

shown in Figure 1. In this configuration, the AD536A will mea-

sure the rms of the ac and dc level present at the input, but will

show an error for low frequency inputs as a function of the filter

capacitor, C_AV, as shown in Figure 5. Thus, if a 4 µF capacitor

is used, the additional average error at 10 Hz will be 0.1%, at

3 Hz it will be 1%. The accuracy at higher frequencies will be

according to specification. If it is desired to reject the dc input, a

capacitor is added in series with the input, as shown in Figure 3,

the capacitor must be nonpolar. If the AD536A is driven with

power supplies with a considerable amount of high frequency

ripple, it is advisable to bypass both supplies to ground with

0.1 µF ceramic discs as near the device as possible.

Dual Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 18 V

Single Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +36 V

Internal Power Dissipation². . . . . . . . . . . . . . . . . . . . 500 mW

Maximum Input Voltage . . . . . . . . . . . . . . . . . . . . 25 V Peak

Buffer Maximum Input Voltage . . . . . . . . . . . . . . . . . . . . . V_S

Maximum Input Voltage . . . . . . . . . . . . . . . . . . . . 25 V Peak

Storage Temperature Range . . . . . . . . . . . . –55°C to +150°C

Operating Temperature Range

AD536AJ/K . . . . . . . . . . . . . . . . . . . . . . . . . . 0°C to +70°C

AD536AS . . . . . . . . . . . . . . . . . . . . . . . . –55°C to +125°C

Lead Temperature Range

(Soldering 60 sec) . . . . . . . . . . . . . . . . . . . . . . . . . . +300°C

ESD Rating . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1000 V

NOTES

¹Stresses 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 indicated in the operational

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

conditions for extended periods may affect device reliability.

²10-Pin Header: θ_JA= 150°C/W; 20-Leadless LCC: θ_JA= 95°C/W; 14-Lead Size

Brazed Ceramic DIP: θ_JA= 95°C/W.

ABSOLUTE

VALUE

AD536A

SQUARER

DIVIDER

–V

CHIP DIMENSIONS AND PAD LAYOUT

Dimensions shown in inches and (mm).

CURRENT

MIRROR

OUT

25k⍀

BUF

25k⍀

AD536A

CURRENT

MIRROR

OUT

BUF

SQUARER

DIVIDER

ABSOLUTE

VALUE

–V

ORDERING GUIDE

Temperature

Range

Package

Description

Package

Option

Model

20 19

AD536AJD

AD536AKD

AD536AJH

AD536AKH

AD536AJQ

AD536AKQ

AD536ASD

AD536ASD/883B

AD536ASE/883B

AD536ASH

AD536ASH/883B

AD536AJCHIPS

AD536AKH/+

AD536ASCHIPS

5962-89805012A

5962-8980501CA

5962-8980501IA

0°C to +70°C

Side Brazed Ceramic DIP D-14

ABSOLUTE

VALUE

–V

0°C to +70°C

AD536A

0°C to +70°C

Header

Cerdip

H-10A

Q-14

SQUARER

DIVIDER

0°C to +70°C

25k⍀

0°C to +70°C

Q-14

CURRENT

MIRROR

–55°C to +125°C

0°C to +70°C

Side Brazed Ceramic DIP D-14

25k⍀

BUF

LCC

E-20A

H-10A

10 11 12

Header

Die

OUT

Figure 1. Standard RMS Connection

0°C to +70°C

Header

Die

LCC

H-10A

E-20A

–55°C to +125°C

Side Brazed Ceramic DIP D-14

Header H-10A

REV. B

–3–

AD536A

The input and output signal ranges are a function of the supply

voltages; these ranges are shown in Figure 14. The AD536A can

also be used in an unbuffered voltage output mode by discon-

necting the input to the buffer. The output then appears unbuf-

fered across the 25 kΩ resistor. The buffer amplifier can then be

used for other purposes. Further the AD536A can be used in a

current output mode by disconnecting the 25 kΩ resistor from

ground. The output current is available at Pin 8 (Pin 10 on the

“H” package) with a nominal scale of 40 µA per volt rms input

positive out.

by using a resistive divider between +V_Sand ground. The values

of the resistors can be increased in the interest of lowered power

consumption, since only 5 mA of current flows into Pin 10

(Pin 2 on the “H” package). AC input coupling requires only

capacitor C2 as shown; a dc return is not necessary as it is

provided internally. C2 is selected for the proper low frequency

break point with the input resistance of 16.7 kΩ; for a cutoff at

10 Hz, C2 should be 1 µF. The signal ranges in this connection

are slightly more restricted than in the dual supply connection.

The input and output signal ranges are shown in Figure 14. The

load resistor, R_L, is necessary to provide output sink current.

OPTIONAL EXTERNAL TRIMS FOR HIGH ACCURACY

If it is desired to improve the accuracy of the AD536A, the

external trims shown in Figure 2 can be added. R4 is used to

trim the offset. Note that the offset trim circuit adds 365 Ω in

series with the internal 25 kΩ resistor. This will cause a 1.5%

increase in scale factor, which is trimmed out by using R1 as

shown. Range of scale factor adjustment is 1.5%.

The trimming procedure is as follows:

1. Ground the input signal, V_IN, and adjust R4 to give zero

volts output from Pin 6. Alternatively, R4 can be adjusted to

give the correct output with the lowest expected value of V_IN.

2. Connect the desired full scale input level to V_IN, either dc or

a calibrated ac signal (1 kHz is the optimum frequency);

then trim R1, to give the correct output from Pin 6, i.e.,

1000 V dc input should give 1.000 V dc output. Of course, a

1.000 V peak-to-peak sine wave should give a 0.707 V dc

output. The remaining errors, as given in the specifications

are due to the nonlinearity.

Figure 3. Single Supply Connection

The major advantage of external trimming is to optimize device

performance for a reduced signal range; the AD536A is inter-

nally trimmed for a 7 V rms full-scale range.

CHOOSING THE AVERAGING TIME CONSTANT

The AD536A will compute the rms of both ac and dc signals.

If the input is a slowly-varying dc signal, the output of the

AD536A will track the input exactly. At higher frequencies, the

average output of the AD536A will approach the rms value of

the input signal. The actual output of the AD536A will differ

from the ideal output by a dc (or average) error and some

amount of ripple, as demonstrated in Figure 4.

Figure 4. Typical Output Waveform for Sinusoidal Input

Figure 2. Optional External Gain and Output Offset Trims

The dc error is dependent on the input signal frequency and the

value of C_AV. Figure 5 can be used to determine the minimum

value of C_AVwhich will yield a given percent dc error above a

given frequency using the standard rms connection.

SINGLE SUPPLY CONNECTION

The applications in Figures l and 2 require the use of approxi-

mately symmetrical dual supplies. The AD536A can also be

used with only a single positive supply down to +5 volts, as

shown in Figure 3. The major limitation of this connection is

that only ac signals can be measured since the differential input

stage must be biased off ground for proper operation. This

biasing is done at Pin 10; thus it is critical that no extraneous

signals be coupled into this point. Biasing can be accomplished

The ac component of the output signal is the ripple. There are

two ways to reduce the ripple. The first method involves using a

large value of C_AV. Since the ripple is inversely proportional to

_AV, a tenfold increase in this capacitance will affect a tenfold

reduction in ripple. When measuring waveforms with high crest

–4–

REV. B

AD536A

The two-pole post-filter uses an active filter stage to provide

even greater ripple reduction without substantially increasing

the settling times over a circuit with a one-pole filter. The values

of C_AV, C2, and C3 can then be reduced to allow extremely fast

settling times for a constant amount of ripple. Caution should

be exercised in choosing the value of C_AV, since the dc error is

dependent upon this value and is independent of the post filter.

factors, (such as low duty cycle pulse trains), the averaging time

constant should be at least ten times the signal period. For

example, a 100 Hz pulse rate requires a 100 ms time constant,

which corresponds to a 4 µF capacitor (time constant = 25 ms

per µF).

The primary disadvantage in using a large C_AVto remove ripple

is that the settling time for a step change in input level is in-

creased proportionately. Figure 5 shows that the relationship

between C_AVand 1% settling time is 115 milliseconds for each

microfarad of C_AV. The settling time is twice as great for de-

creasing signals as for increasing signals (the values in Figure 5

are for decreasing signals). Settling time also increases for low

signal levels, as shown in Figure 6.

For a more detailed explanation of these topics refer to the

RMS to DC Conversion Application Guide 2nd Edition, available

from Analog Devices.

Figure 7. 2-Pole “Post” Filter

Figure 5. Error/Settling Time Graph for Use with the Stan-

dard rms Connection in Figure 1

Figure 6. Settling Time vs. Input Level

Figure 8. Performance Features of Various Filter Types

A better method for reducing output ripple is the use of a

“post-filter.” Figure 7 shows a suggested circuit. If a single-pole

filter is used (C3 removed, R_Xshorted), and C2 is approximately

twice the value of C_AV, the ripple is reduced as shown in Figure

8 and settling time is increased. For example, with C_AV= 1 µF

and C2 = 2.2 µF, the ripple for a 60 Hz input is reduced from

10% of reading to approximately 0.3% of reading. The settling

time, however, is increased by approximately a factor of 3. The

values of C_AVand C2_,can, therefore, be reduced to permit faster

settling times while still providing substantial ripple reduction.

AD536A PRINCIPLE OF OPERATION

The AD536A embodies an implicit solution of the rms equation

that overcomes the dynamic range as well as other limitations

inherent in a straightforward computation of rms. The actual

computation performed by the AD536A follows the equation:











V_IN

V rms = Avg.

V rms 



REV. B

–5–

AD536A

Figure 9 is a simplified schematic of the AD536A; it is subdi-

vided into four major sections: absolute value circuit (active

rectifier), squarer/divider, current mirror, and buffer amplifier.

The input voltage, V_IN, which can be ac or dc, is converted to a

unipolar current I₁, by the active rectifier A₁, A₂. I₁drives one

input of the squarer/divider, which has the transfer function:

The current mirror also produces the output current, I_OUT,

which equals 2I₄. I_OUTcan be used directly or converted to a

voltage with R2 and buffered by A4 to provide a low impedance

voltage output. The transfer function of the AD536A thus

results:

V_OUT= 2R2 I rms = V_INrms

I₄= I₁²/I₃

The dB output is derived from the emitter of Q3, since the

voltage at this point is proportional to –log V_IN. Emitter fol-

lower, Q5, buffers and level shifts this voltage, so that the dB

output voltage is zero when the externally supplied emitter

current (I_REF) to Q5 approximates I₃.

The output current, I₄, of the squarer/divider drives the current

mirror through a low-pass filter formed by R1 and the externally

connected capacitor, C_AV. If the R1, C_AVtime constant is much

greater than the longest period of the input signal, then I₄is

effectively averaged. The current mirror returns a current I₃,

which equals Avg. [I₄], back to the squarer/divider to complete

the implicit rms computation. Thus:

CONNECTIONS FOR dB OPERATION

A powerful feature added to the AD536A is the logarithmic or

decibel output. The internal circuit computing dB works accu-

rately over a 60 dB range. The connections for dB measure-

ments are shown in Figure 10. The user selects the 0 dB level by

adjusting R1, for the proper 0 dB reference current (which is set

to exactly cancel the log output current from the squarer-divider

at the desired 0 dB point). The external op amp is used to pro-

vide a more convenient scale and to allow compensation of the

+0.33%/°C scale factor drift of the dB output pin. The special

T.C. resistor, R2, is available from Tel Labs in Londonderry,

N.H. (model Q-81) or from Precision Resistor Inc., Hillside,

N.J. (model PT146). The averaged temperature coefficients of

resistors R2 and R3 develop the +3300 ppm needed to reverse

compensate the dB output. The linear rms output is available at

Pin 8 on DIP or Pin 10 on header device with an output imped-

ance of 25 kΩ; thus some applications may require an additional

buffer amplifier if this output is desired.

I₄= Avg. I₁/I₄= I₁rms

[

]

dB Calibration:

1. Set V_IN= 1.00 V dc or 1.00 V rms

2. Adjust R1 for dB out = 0.00 V

3. Set V_IN= +0.1 V dc or 0.10 V rms

4. Adjust R5 for dB out = –2.00 V

Any other desired 0 dB reference level can be used by setting

Figure 9. Simplified Schematic

V_INand adjusting R1, accordingly. Note that adjusting R5 for

the proper gain automatically gives the correct temperature

compensation.

Figure 10. dB Connection

–6–

REV. B

AD536A

FREQUENCY RESPONSE

The AD536A utilizes a logarithmic circuit in performing the

implicit rms computation. As with any log circuit, bandwidth is

proportional to signal level. The solid lines in the graph below

represent the frequency response of the AD536A at input levels

from 10 millivolts to 7 volts rms. The dashed lines indicate the

upper frequency limits for 1%, 10%, and 3 dB of reading addi-

tional error. For example, note that a 1 volt rms signal will pro-

duce less than 1% of reading additional error up to 120 kHz. A

10 millivolt signal can be measured with 1% of reading addi-

tional error (100 µV) up to only 5 kHz.

Figure 12. Error vs. Crest Factor

Figure 11. High Frequency Response

AC MEASUREMENT ACCURACY AND CREST FACTOR

Crest factor is often overlooked in determining the accuracy of

an ac measurement. Crest factor is defined as the ratio of the

peak signal amplitude to the rms value of the signal (CF = V_P/

V rms). Most common waveforms, such as sine and triangle

waves, have relatively low crest factors (<2). Waveforms which

resemble low duty cycle pulse trains, such as those occurring in

switching power supplies and SCR circuits, have high crest

factors. For example, a rectangular pulse train with a 1% duty

Figure 13. AD536A Error vs. Pulsewidth Rectangular

Pulse

cycle has a crest factor of 10 (CF = 1

Figure 12 is a curve of reading error for the AD536A for a 1 volt

rms input signal with crest factors from 1 to 11. A rectangular

pulse train (pulsewidth 100 µs) was used for this test since it is

the worst-case waveform for rms measurement (all the energy is

contained in the peaks). The duty cycle and peak amplitude

were varied to produce crest factors from 1 to 11 while main-

taining a constant 1 volt rms input amplitude.

Figure 14. AD536A Input and Output Voltage Ranges

vs. Supply

REV. B

–7–

AD536A

OUTLINE DIMENSIONS

Dimensions shown in inches and (mm).

D-14 Package

TO-116

H-10A Package

TO-100

E-20A Package

LCC

–8–

REV. B

AD536ASCHIPS [ADI]

相关型号：

AD536ASD

AD536ASD/883B

AD536ASE

AD536ASE/883B

AD536ASH

AD536ASH/883B

AD536ASQ

AD536ASQ/883B

AD537

AD537*

AD5370

AD5370BCPZ