Wattmeter

[citation needed] In 1974 Maghar S. Chana, Ramond L. Kraley, Eric A. Hauptmann Barry, and M. Pressman patented an early electronic wattmeter.

The potential coil has, as a general rule, a high-value resistor connected in series with it to reduce the current that flows through it.

For AC power, current and voltage may not be in phase, owing to the delaying effects of circuit inductance or capacitance.

On an AC circuit the deflection is proportional to the average instantaneous product of voltage and current, thus measuring active power, P=VI cos φ.

For each sample, the voltage is multiplied by the current at the same instant; the average over at least one cycle is the real power.

The readings may be displayed on the device, retained to provide a log and calculate averages, or transmitted to other equipment for further use.

Wattmeters vary considerably in correctly calculating energy consumption, especially when real power is much lower than VA (highly reactive loads, e.g. electric motors).

[4] If a laptop computer in sleep mode consumes 5 W, the meter may read anything from 0 to 15.25 W, without taking into account errors due to non-sinusoidal waveform.

In practice accuracy can be improved by connecting a fixed load such as an incandescent light bulb, adding the device in standby, and using the difference in power consumption.

The reduction in current required to maintain temperature is related to the incident RF power.

Wattmeter
Early wattmeter on display at the Historic Archive and Museum of Mining in Pachuca , Mexico
Siemens electrodynamometer, circa 1910, F = Fixed coil, D = Movable coil, S = Spiral spring, T = Torsion head, M = Mercury cups, I = Index needle
Prodigit Model 2000MU (UK version), shown in use and displaying a reading of 10 watts being consumed by the appliance
Itron OpenWay wattmeter with two-way communications for remote reading, in use by DTE Energy