NARDA 8718B User Manual

Page 128

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127

Appendix B Theory of Operation

This provides for the independence of probe orientation relative

to the polarization of the field. The instantaneous charge

distribution on adjacent cold junction elements produces a

potential difference across the thin-film resistive thermocouples

and a resultant dissipation of energy in these films. As the

frequency increases, the phase difference between the

potentials developed in adjacent junctions also increases the

open circuit voltage.
The Model 8764D operates from 100 kHz to 300 MHz. It contains

three orthogonal displacement energy sensors with diode

detectors. This unique design has much lower impedance than

traditional dipole designs. The major advantage is the greatly

reduced interaction between the meter and probe, the human

body making the measurements, and the RF field.
The Model 8782D uses an “active antenna” design to accurately

measure RF fields as low as 3 kHz over a 60dB dynamic range.
These probes are responsive to the H-Field component. Each

of the three mutually perpendicular coils in every probe has a

diameter of 3.5 inches (8.9 cm), consists of multiple turns and is

series-resonated somewhat below the low frequency end of the

band. The RF current induced by the “H” field dissipates power

in the thermocouple elements, heats the hot junctions and

provides a DC output voltage proportional to the square of the

induced current. Circuitry is added to minimize high frequency

out-of-band responses typical in many H-field probe designs.

Low Frequency

Electric Field

Probes

Low Frequency

Magnetic Field

Probes

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