The cone-shape distribution function, also known as the ZhaoâÂÂAtlasâÂÂMarks time-frequency distribution, (acronymized as the ZAM distribution or ZAMD), is one of the members of Cohen's class distribution function. It was first proposed by Yunxin Zhao, Les E. Atlas, and Robert J. Marks II in 1990. The distribution's name stems from the twin cone shape of the distribution's kernel function on the plane. The advantage of the cone kernel function is that it can completely remove the cross-term between two components having the same center frequency. Cross-term results from components with the same time center, however, cannot be completely removed by the cone-shaped kernel.
The definition of the cone-shape distribution function is:
where
and the kernel function is
The kernel function in domain is defined as:
Following are the magnitude distribution of the kernel function in domain.
Following are the magnitude distribution of the kernel function in domain with different values.
As is seen in the figure above, a properly chosen kernel of cone-shape distribution function can filter out the interference on the axis in the domain, or the ambiguity domain. Therefore, unlike the Choi-Williams distribution function, the cone-shape distribution function can effectively reduce the cross-term results form two component with same center frequency. However, the cross-terms on the axis are still preserved.
The cone-shape distribution function is in the MATLAB Time-Frequency Toolbox and National Instruments' LabVIEW Tools for Time-Frequency, Time-Series, and Wavelet Analysis
The Cone-Shape Distribution Function (ZAM) possesses specific mathematical properties that distinguish it from other members of Cohen's class. These properties determine the distribution's accuracy in representing signal energy in time and frequency.
For a time-frequency distribution to interpret the signal energy correctly, it is often desired to satisfy the marginal properties:
In the case of the Cone-Shape Distribution:
The ZAM distribution satisfies both time and frequency shift invariance.
These properties are crucial for analyzing signals where events may occur at arbitrary times or frequencies without distorting the representation shape.
Since the kernel function in the time-lag domain satisfies the conjugate symmetry , the resulting distribution is always real-valued. This allows for a straightforward physical interpretation of signal energy, although negative values may still appear (a common trait in Cohen's class excluding the Spectrogram).
A primary motivation for the Cone-Shape Distribution is the suppression of cross-terms (interference terms) that arise in the Wigner Distribution Function (WDF) when analyzing multi-component signals.
In the Ambiguity Domain (), the auto-terms of a signal components are concentrated near the origin , while cross-terms between components are located away from the origin.
Specifically, the ZAM kernel strongly attenuates interference components that result from signals separated in frequency (which appear on the axis in the ambiguity domain) while preserving the resolution of components separated in time. This makes ZAM particularly effective for signals composed of short-duration events occurring at different frequencies.
While the ZAM distribution excels at removing cross-terms formed by components with the same center time but different frequencies ("vertical" cross-terms in the TF plane), it is less effective at removing cross-terms from components with the same frequency but different times ("horizontal" cross-terms), as the kernel does not decay along the axis (frequency shift axis) as strongly as it does along the axis.