AD630 Analog Devices, AD630 Datasheet - Page 7

AD630

Manufacturer Part Number

AD630

Description

Balanced Modulator/Demodulator

Manufacturer

Analog Devices

Datasheet

1.AD630.pdf (8 pages)

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BALANCED DEMODULATOR

The balanced modulator topology described above will also act as

a balanced demodulator if a double sideband suppressed carrier

waveform is applied to the signal input and the carrier signal is

applied to the reference input. The output under these circum-

stances will be the baseband modulation signal. Higher order

carrier components will also be present which can be removed

with a low-pass filter. Other names for this function are synchro-

nous demodulation and phase-sensitive detection.

PRECISION PHASE COMPARATOR

The balanced modulator topologies of Figures 18a and 18b can

also be used as precision phase comparators. In this case, an ac

waveform of a particular frequency is applied to the signal input

and a waveform of the same frequency is applied to the refer-

ence input. The dc level of the output (obtained by low-pass

filtering) will be proportional to the signal amplitude and phase

difference between the input signals. If the signal amplitude is

held constant, then the output can be used as a direct indication

of the phase. When these input signals are 90° out of phase, they

are said to be in quadrature and the AD630 dc output will be zero.

PRECISION RECTIFIER-ABSOLUTE VALUE

If the input signal is used as its own reference in the balanced

modulator topologies, the AD630 will act as a precision recti-

fier. The high frequency performance will be superior to that

which can be achieved with diode feedback and op amps. There

are no diode drops which the op amp must “leap over” with the

commutating amplifier.

MODULATION

CARRIER

INPUT

10V

2.5k

10k

AMP A

AMP B

COMP

ADJ

AD630

10k

–V

10k

20 s

DIFF

ADJ

10k

MODULATION

INPUT

CARRIER

INPUT

OUTPUT

SIGNAL

MODULATED

OUTPUT

SIGNAL

LVDT SIGNAL CONDITIONER

Many transducers function by modulating an ac carrier. A Lin-

ear Variable Differential Transformer (LVDT) is a transducer of

this type. The amplitude of the output signal corresponds to

core displacement. Figure 20 shows an accurate synchronous

demodulation system which can be used to produce a dc voltage

which corresponds to the LVDT core position. The inherent

precision and temperature stability of the AD630 reduce de-

modulator drift to a second order effect.

AC BRIDGE

Bridge circuits which use dc excitation are often plagued by

errors caused by thermocouple effects, 1/f noise, dc drifts in the

electronics, and line noise pick-up. One way to get around these

problems is to excite the bridge with an ac waveform, amplify

the bridge output with an ac amplifier, and synchronously de-

modulate the resulting signal. The ac phase and amplitude

information from the bridge is recovered as a dc signal at the

output of the synchronous demodulator. The low frequency

system noise, dc drifts, and demodulator noise all get mixed to

the carrier frequency and can be removed by means of a low-pass

filter. Dynamic response of the bridge must be traded off against

the amount of attenuation required to adequately suppress these

residual carrier components in the selection of the filter.

Figure 21 is an example of an ac bridge system with the AD630

used as a synchronous demodulator. The oscilloscope photo-

graph shows the results of a 0.05% bridge imbalance caused by

the 1 Meg resistor in parallel with one leg of the bridge. The top

trace represents the bridge excitation, the upper-middle trace is

the amplified bridge output, the lower-middle trace is the out-

put of the synchronous demodulator and the bottom trace is the

filtered dc system output.

This system can easily resolve a 0.5 ppm change in bridge im-

pedance. Such a change will produce a 3.2 mV change in the

low-pass filtered dc output, well above the RTO drifts and noise.

SINUSOIDAL

EXCITATION

2.5kH

2V p-p

BRIDGE

1kHz

SCHAEVITZ

E1000

LVDT

SHIFTER

PHASE

GAIN 1000

SHIFTER

PHASE

AD524

FOLLOWER

AD544

2.5

2 DEMODULATOR

2.5k

10k

AD630

10k

2 DEMODULATOR

10k

AD630

10k

AD630

FILTER

2 F

100k

1 F

2 F

AD630 Analog Devices, AD630 Datasheet - Page 7

AD630

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