A Q meter is a piece of equipment used in the testing of

radio frequency Radio frequency (RF) is the oscillation rate of an alternating electric current or voltage or of a magnetic, electric or electromagnetic field or mechanical system in the frequency range from around to around . This is roughly between the ...

circuits. It has been largely replaced in professional laboratories by other types of impedance measuring devices, though it is still in use among radio amateurs. It was developed at Boonton Radio Corporation in

Boonton, New Jersey Boonton is a town in Morris County, New Jersey, United States. As of the 2020 United States census, the town's population was 8,815, an increase of 468 (+5.6%) from the 2010 census count of 8,347, which in turn reflected a decline of 149 (− ...

in 1934 by William D. Loughlin.Boonton Q-Meter Type 160-A, 1946
— HP Virtual Museum

Description

A ''Q'' meter measures the

quality factor In physics and engineering, the quality factor or ''Q'' factor is a dimensionless parameter that describes how underdamped an oscillator or resonator is. It is defined as the ratio of the initial energy stored in the resonator to the energy lo ...

of a circuit, ''Q'', which expresses how much energy is dissipated per cycle in a non-ideal reactive circuit: :

Q = 2 \pi \times \frac. \,

This expression applies to an RF and microwave filter, bandpass

LC filter An LC circuit, also called a resonant circuit, tank circuit, or tuned circuit, is an electric circuit consisting of an inductor, represented by the letter L, and a capacitor, represented by the letter C, connected together. The circuit can ac ...

, or any resonator. It also can be applied to an inductor or capacitor at a chosen frequency. For inductors :

Q = \frac = \frac

Where

X_L

is the reactance of the inductor,

L

is the inductance,

\omega

is the angular frequency and

R

is the resistance of the inductor. The resistance

R

represents the loss in the inductor, mainly due to the resistance of the wire. A ''Q'' meter works on the principle of series resonance. For LC band pass circuits and filters: :

Q = \frac

Where

F

is the resonant frequency (center frequency) and

BW

is the filter bandwidth. In a band pass filter using an LC resonant circuit, when the loss (resistance) of the inductor increases, its ''Q'' factor is reduced, and so the bandwidth of the filter is increased. In a coaxial cavity filter, there are no inductors and capacitors, but the cavity has an equivalent LC model with losses (resistance) and the ''Q'' factor can be applied as well.

Operation

Internally, a minimal ''Q'' meter consists of a tuneable RF generator with a very low (pass) impedance output and a detector with a very high impedance input. There is usually provision to add a calibrated amount of high Q capacitance across the component under test to allow inductors to be measured in isolation. The generator is effectively placed in series with the tuned circuit formed by the components under test, and having negligible output resistance, does not materially affect the ''Q'' factor, while the detector measures the voltage developed across one element (usually the capacitor) and being high impedance in shunt does not affect the ''Q'' factor significantly either. The ratio of the developed RF voltage to the applied RF current, coupled with knowledge of the reactive impedance from the resonant frequency, and the source impedance, allows the ''Q'' factor to be directly read by scaling the detected voltage.

Description

Operation

See also

References

Further reading