Systems and methods for performing analysis of a multi-tone signal

Abstract

Representative embodiments are directed to systems and methods for processing analyzer trace data of a multi-tone signal to more accurately estimate the frequencies and amplitudes of the tones of the multi-tone signal. Specifically, trace data may be processed to determine peak trace points. For each identified peak point, an error minimization algorithm minimizes the sum of differences between a plurality of trace points surrounding the respective peak point and the predicted Fourier transform through a raised-cosine window of a theoretical tone. The result of the minimization algorithm identifies the amplitude and frequency of a tone of the multi-tone signal with an appreciable degree of accuracy.

Description

TECHNICAL FIELD The present invention is related to frequency analysis of a signal and, more particularly, to identification of the frequencies and amplitudes of tones in a multi-tone signal. BACKGROUND A number of devices are commercially available that analyze signals to facilitate the design, manufacturing, and calibration of electronic and communication devices and systems. Examples of signal analyzers include the Agilent Technologies, Inc.'s 89400 and 89600 series vector signal analyzers (VSA). When analyzing signals on a signal analyzer, the measured signal is typically presented in the form of a trace representing the frequency domain output of a Fourier transform calculated from samples of the measured signal. The trace consists of the individual points in the frequency domain. In general, an odd number of points are used so that the center point will lie exactly at the center frequency of the frequency span. For simple single-tone measurements, if the exact tone frequenc...

AI Technical Summary

Benefits of technology

This approach achieves accurate amplitude and frequency measurements with reduced errors, improving upon traditional methods by providing amplitude accuracy within 0.001 dB and frequency accuracy of the order of RBW / 30000, while maintaining practical measurement times.

Problems solved by technology

Accordingly, a simple marker measurement is unsuitable for measuring multi-tone signals.

The measurement of any single-tone that does not lie exactly at the analyzer center frequency and the measurement of tone(s) produced by equipment that is not locked to the same frequency as the analyzer present similar complications.

Moreover, the measurement of the accurate amplitude and frequency of each tone of a multi-tone signal where the exact frequencies of the tones are unknown beforehand is quite complicated.

However, the accuracy of the gathered frequency information is limited by the frequency resolution between the analyzer trace points.

Moreover, noise effects may also cause the trace point with the peak amplitude to not be the trace point that is closest to the actual peak point.

Thus, the Flattop Fourier window causes frequency measurement to be quite difficult.

However, this may cause the test time to increase and may cause the measurement to become impractical.

However, this requires multiple sweeps.

This factor may dramatically increase the acquisition time of the analyzer.

However, amplitude accuracy may be lost.

Clearly, this amount of potential deviation is unsuitable if accurate amplitude measurements are necessary for a particular application.

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