AD834JRZ-RL Analog Devices Inc, AD834JRZ-RL Datasheet - Page 14

AD834JRZ-RL

Manufacturer Part Number

AD834JRZ-RL

Description

IC,Analog Multiplier,BIPOLAR,SOP,8PIN,PLASTIC

Manufacturer

Analog Devices Inc

Datasheet

1.AD834JRZ.pdf (20 pages)

Specifications of AD834JRZ-RL

Function

Analog Multiplier

Number Of Bits/stages

4-Quadrant

Package / Case

8-SOIC (3.9mm Width)

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current page: 14 of 20
Download datasheet (359Kb)

AD834

POWER MEASUREMENT (MEAN-SQUARE AND RMS)

The AD834 is well-suited to measurement of average power in

high frequency applications, connected either as a multiplier for

the determination of the V × I product, or as a squarer for use

with a single input. In these applications, the multiplier is followed

by a low-pass filter to extract the long-term average value. Where

the bandwidth extends to several hundred megahertz, the first

pole of this filter should be formed by grounded capacitors

placed directly at the output pins, W1 and W2. This pole can

be at a few kilohertz. The effective multiplication or squaring

bandwidth is then limited solely by the AD834, because the active

circuitry that follows the multiplier is required to process only

low frequency signals. Using the device as a squarer, like the

circuit shown in Figure 8, the wideband output in response to a

sinusoidal stimulus is a raised cosine.

Recall that the full-scale output current (when full-scale input

voltages of 1 V are applied to both X and Y) is 4 mA. In a 50 Ω

system, a sinusoid power of +10 dBm has a peak value of 1 V.

Thus, at this drive level, the peak output voltage across the

differential 50 Ω load in the absence of the filter capacitors is

400 mV (that is, 4 mA × 50 Ω × 2), whereas the average value of

the raised cosine is only 200 mV. The averaging configuration is

useful in evaluating the bandwidth of the AD834, because a dc

voltage is easier to measure than a wideband differential output.

In fact, the squaring mode is an even more critical test than the

direct measurement of the bandwidth of either channel taken

independently (with a dc input on the nonsignal channel),

because the phase relationship between the two channels also

affects the average output. For example, a time delay difference

of only 250 ps between the X and Y channels results in zero

output when the input frequency is 1 GHz, at which frequency

the phase angle is 90 degrees and the intrinsic product is now

between a sine and cosine function, which has zero average value.

The physical construction of the circuitry around the IC is

critical to realizing the bandwidth potential of the device. The

input is supplied from an HP 8656A signal generator (100 kHz

to 990 MHz) via an SMA connector and terminated by an

HP 436A power meter using an HP 8482A sensor head

sin

ωt = (1 − cos 2 ωt)/2

Rev. E | Page 14 of 20

connected via a second SMA connector. Because neither the

generator nor the sensor provide a dc path to ground, a lossy

1 μH inductor, L1, formed by a 22-gauge wire passing through

a ferrite bead (Fair-Rite Type 2743001112) is included. This

provides adequate impedance down to about 30 MHz. The IC

socket is mounted on a ground plane with a clear area in the

rectangle formed by the pins. This is important because significant

transformer action can arise if the pins pass through individual

holes in the board; it can cause an oscillation at 1.3 GHz in

improperly constructed test jigs. The filter capacitors must be

connected directly to the same point on the ground plane via the

shortest possible leads. Parallel combinations of large and small

capacitors are used to minimize the impedance over the full

frequency range. Refer to Figure 4 for mean-square response for

the AD834 in a CERDIP package, using the configuration of

Figure 8.

To provide a square root response and thus generate the rms

value at the output, a second AD834, also connected as a

squarer, can be used, as shown in Figure 20. Note that an

attenuator is inserted both in the signal input and in the feed-

back path to the second AD834. This increases the maximum

input capability to +15 dBm and improves the response flatness

by damping some of the resonances. The overall gain is unity;

that is, the output voltage is exactly equal to the rms value of the

input signal. The offset potentiometer at the AD834 outputs

extends the dynamic range and is adjusted for a dc output of

125.7 mV when a 1 MHz sinusoidal input at −5 dBm is applied.

Additional filtering is provided; the time constants were chosen

to allow operation down to frequencies as low as 1 kHz and to

provide a critically damped envelope response, which settles

typically within 10 ms for a full-scale input (and proportionally

slower for smaller inputs). The 5 μF and 0.1 μF capacitors can

be scaled down to reduce response time if accurate rms opera-

tion at low frequencies is not required. The output op amp must

be specified to accept a common-mode input near its supply.

Note that the output polarity can be inverted by replacing the

NPN transistor with a PNP type.

AD834JRZ-RL Analog Devices Inc, AD834JRZ-RL Datasheet - Page 14

AD834JRZ-RL

Specifications of AD834JRZ-RL

Related parts for AD834JRZ-RL