@techreport {1474,
title = {PMU Measurement Technology},
year = {2014},
month = {04/2014},
institution = {Pacific Northwest National Laboratory (PNNL)},
abstract = {Phasor measurements are without doubt extraordinarily valuable and informative. The number of phasor measurement units in service continues to increase, to the great benefit of the power system. And yet the measurement method used is deeply flawed. This report uses an epistemological approach to explain why the measurement of synchrophasors, as it is presently implemented, is unjustified. Fundamentally, the problem is that the definition for the quantities being measured is incorrect. We expect the PMU to furnish values for the three parameters that define a phasor (its amplitude, frequency and phase), when in fact the signals we furnish to the PMU are not phasors. It follows that the best we can expect is an approximation. It also follows that we cannot know the quality of that approximation. As an example of what this means, consider that the PMU is required to furnish a value for the rate of change of frequency, and yet by the definition of a phasor, that rate of change is zero.
The report goes on to present an alternative method of describing the input signals to the measuring system. Instead of imposing the requirement that the signal be described by a phasor, the assumption of stationarity is relaxed, and the value of each of the three parameters is permitted to change during the measurement. The result of changing the definition is that a new measurement technique is possible. As a byproduct of the new definition for the input signal, new (and concrete) definitions emerge for the terms {\textquotedblleft}apparent frequency{\textquotedblright} and {\textquotedblleft}instantaneous frequency.{\textquotedblright}},
keywords = {AA14-001, AARD, CERTS, phasor measurement units (PMUs)},
issn = {PNNL-23334},
author = {Harold Kirkham and Jeffery E. Dagle and Sun, Y.}
}