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Wigner distribution function

The Wigner distribution function (WDF), also known as the Wigner–Ville distribution in its form, is a time-frequency representation used in to analyze non-stationary signals. It provides a phase-space-like distribution over time and frequency variables, analogous to the in , from which it derives its name. Introduced by in 1932 for and adapted by Jean Ville in 1948 for signal analysis, the WDF allows the representation of a signal's in the joint time-frequency domain. For a complex-valued signal z(t), the Wigner distribution is defined as
W(t, f) = \int_{-\infty}^{\infty} z\left(t + \frac{\tau}{2}\right) z^*\left(t - \frac{\tau}{2}\right) e^{-j 2\pi f \tau} \, d\tau,
where * denotes the . For real signals s(t), it is often computed using the z(t) = s(t) + j \hat{s}(t), with \hat{s}(t) the . The marginal distributions are the time-domain \int W(t, f) \, df = |z(t)|^2 and the frequency-domain power spectrum \int W(t, f) \, dt = |Z(f)|^2, where Z(f) is the of z(t). Unlike classical probability distributions, the WDF is bilinear and can exhibit negative values or terms (cross-terms) due to its quadratic nature, which highlight non-stationarities but complicate interpretation. The WDF satisfies several desirable properties for time-frequency analysis, including real-valuedness, correctness of marginals, and time-frequency shift invariance. It enables the computation of signal moments and expectation values as integrals over the distribution, similar to phase-space methods in . However, cross-terms between signal components often require mitigation through windowing or smoothing techniques. The WDF has been influential in fields such as , , , and biomedical signal analysis, where it reveals instantaneous and group delay for chirps and modulated signals. Extensions include discrete-time versions for digital signals and generalizations to higher dimensions. Its connection to underscores its versatility, though in , it focuses on classical wave phenomena without quantum effects.

Introduction

Definition and motivation

The Wigner distribution function, also known as the Wigner-Ville distribution in contexts, is a that provides a representation of a signal's energy distribution across both time and frequency domains simultaneously. Unlike linear methods such as the , it achieves higher resolution by avoiding the inherent time-frequency uncertainty trade-offs, enabling precise localization of signal components that vary over time. This makes it particularly valuable for analyzing complex waveforms where energy concentration in reveals underlying structures more clearly than one-dimensional spectra. The primary motivation for the Wigner distribution arises from the limitations of traditional representations like the , which assume signal stationarity and fail to track instantaneous frequency changes in non-stationary signals such as chirps or modulated waves. By offering a joint time-frequency view analogous to phase-space formulations in , it allows for a more intuitive depiction of signal dynamics, where position (time) and momentum (frequency) are treated on equal footing. For a real-valued signal f(t) with Fourier transform F(\omega), the distribution maps these into a two-dimensional , facilitating applications in fields like and acoustics where temporal evolution is critical. Named after physicist , who introduced the concept in 1932 for quantum phase-space distributions, it was later adapted by Jean Ville in 1948 for classical signal analysis, earning the combined designation in modern usage. This adaptation addressed the need for a tool that could represent local without smoothing artifacts, though it introduces cross-terms as a for its sharpness.

Historical development

The Wigner distribution function was first introduced by in 1932 as a quasi-probability distribution in , aimed at describing the joint probability of a particle's and to incorporate quantum corrections to classical . This formulation provided a phase-space representation bridging wave mechanics and classical , allowing for the calculation of expectation values akin to classical phase-space integrals. In 1948, French mathematician Jean Ville independently rederived the distribution and adapted it for signal analysis, recognizing its utility in representing the local time-frequency energy of non-stationary signals; he termed it the Wigner-Ville distribution to honor its dual origins. Ville's work emphasized its quadratic nature in the signal, positioning it as an alternative to spectrograms for capturing instantaneous frequency content without the limitations of fixed windows. Following a period of limited attention, the experienced a significant in during the post-1960s era, particularly through the generalization into Cohen's class of time-frequency distributions, which encompassed the Wigner-Ville as a core member while introducing kernels to address interference issues. Key contributions in this resurgence included the 1980 papers by T. A. C. M. Claasen and W. F. G. Mecklenbräuker, which systematically explored its properties for both continuous- and discrete-time signals, establishing it as a foundational tool for analyzing non-stationary phenomena in applications. This evolution marked a pivotal from its roots in quantum phase-space —where it served theoretical purposes in physics—to a practical for non-stationary in and beyond, enabling high-resolution representations of signals with evolving spectral content. By 2025, the Wigner-Ville distribution had become integrated into computational frameworks, such as MATLAB's Toolbox, where the wvd function facilitates its computation for real-time tasks like instantaneous frequency estimation.

Mathematical formulation

Continuous-time definition

The Wigner distribution function, in the context of continuous-time , provides a time-frequency representation of a signal f(t). For a square-integrable complex-valued signal f(t) \in L^2(\mathbb{R}), the continuous-time Wigner distribution is defined as W_f(t, \omega) = \int_{-\infty}^{\infty} f\left(t + \frac{\tau}{2}\right) f^*\left(t - \frac{\tau}{2}\right) e^{-j \omega \tau} \, d\tau, where f^* denotes the of f, t is the time variable, \omega is the , and \tau is the time lag variable. This localizes the signal's energy in both time and domains simultaneously. The definition arises from the Fourier transform of the signal's instantaneous autocorrelation function. The instantaneous autocorrelation R_f(t, \tau) is given by R_f(t, \tau) = f\left(t + \frac{\tau}{2}\right) f^*\left(t - \frac{\tau}{2}\right), which measures the correlation of the signal with a time-shifted version of itself centered at time t. The Wigner distribution is then the of this autocorrelation with respect to the lag \tau: W_f(t, \omega) = \mathcal{F}_\tau \left\{ R_f(t, \tau) \right\} (\omega) = \int_{-\infty}^{\infty} R_f(t, \tau) e^{-j \omega \tau} \, d\tau. This connection to the in and applications further underscores its origins in generalized . The assumes familiarity with the , defined as \mathcal{F}\{g(t)\}(\omega) = \int_{-\infty}^{\infty} g(t) e^{-j \omega t} \, dt for a function g(t). In practice, to avoid negative frequencies and ensure a proper energy representation, the signal f(t) is often taken as the , which is f_a(t) = f(t) + j \hat{f}(t), where \hat{f}(t) is the of f(t). This representation, introduced in the context of Wigner distributions for signal , filters out the negative frequency components of real signals. For real-valued signals, the Wigner distribution yields a real-valued output, W_f(t, \omega) \in \mathbb{R}, due to the conjugate symmetry in the autocorrelation term. Additionally, integrating over time recovers the squared magnitude of the signal's : \int_{-\infty}^{\infty} W_f(t, \omega) \, dt = |F(\omega)|^2, where F(\omega) = \mathcal{F}\{f(t)\}(\omega), linking the distribution directly to classical .

Discrete-time definition

The discrete-time Wigner distribution provides a practical adaptation of the continuous Wigner distribution for digitally sampled signals, enabling computational analysis in time-frequency domains for applications such as and . For a discrete-time signal f, where n is the time index, the distribution is defined as W[n, k] = \sum_{m} f[n + m] f^{*}[n - m] e^{-j 2\pi k m / N}, where k denotes the discrete frequency index, N represents the signal length or window size, and the summation over lag m is taken over all integers such that both n + m and n - m lie within the valid signal indices (typically $0 \leq n + m, n - m < N). This formulation builds upon the continuous-time version by discretizing the time-lag integral into a finite sum and incorporating discrete Fourier transform conventions for the frequency exponent, ensuring compatibility with digital implementation. For finite-length signals, the limited range of indices introduces edge effects, where terms near the signal boundaries may be incomplete due to unavailable samples outside the defined length. To address these, zero-padding extends the signal with zeros beyond its original length, allowing the summation to proceed without truncation for central time indices, while periodic extension assumes the signal repeats indefinitely, which simplifies FFT-based computation but can impose artificial periodicity. These techniques are essential for accurate representation, though they require careful selection to minimize distortions. The discrete Wigner distribution is typically computed by evaluating the Fourier transform of the local autocorrelation f[n + m] f^{*}[n - m] at each time n, leveraging the fast Fourier transform (FFT) for efficiency, which yields an overall computational complexity of O(N^2 \log N) for an N-point signal. However, if the signal sampling rate is insufficient—such as not oversampling by at least a factor of two—aliasing can arise in the frequency domain, manifesting as unwanted replicas that degrade the time-frequency resolution.

Properties

Marginal and moment properties

The Wigner distribution exhibits key marginal properties that link its joint time-frequency representation directly to the signal's temporal and spectral characteristics, providing a foundation for interpreting signal energy distribution. Specifically, the integration over frequency recovers the instantaneous power of the signal f(t): \int_{-\infty}^{\infty} W(t, \omega) \, d\omega = |f(t)|^2. This property arises from the definition of the Wigner distribution as the Fourier transform of the signal's autocorrelation function with respect to the lag variable \tau. Integrating over \omega effectively yields a Dirac delta function \delta(\tau) due to the inverse Fourier transform property, selecting the zero-lag autocorrelation value, which equals the instantaneous power |f(t)|^2. By symmetry in the time-frequency domain, the frequency marginal integrates the distribution over time to obtain the energy spectral density: \int_{-\infty}^{\infty} W(t, \omega) \, dt = |F(\omega)|^2, where F(\omega) is the Fourier transform of f(t). This follows analogously from the Fourier transform properties, confirming that the Wigner distribution preserves the total signal energy in the frequency domain as given by the power spectrum. These marginals ensure that the Wigner distribution maintains consistency with classical one-dimensional signal representations while enabling joint analysis. Beyond marginals, the Wigner distribution supports the computation of signal moments, particularly those related to local frequency content. The conditional mean frequency at fixed time t, or instantaneous frequency, is the first moment: \langle \omega \rangle_t = \frac{1}{|f(t)|^2} \int_{-\infty}^{\infty} \omega \, W(t, \omega) \, d\omega, which equals the derivative of the signal's phase, providing a measure of local oscillation rate. Similarly, the group delay, as the first moment in time at fixed frequency \omega, is \langle t \rangle_\omega = \frac{1}{|F(\omega)|^2} \int_{-\infty}^{\infty} t \, W(t, \omega) \, dt, corresponding to the negative derivative of the spectral phase. These moments are derived by differentiating under the integral in the autocorrelation-based definition and applying Fourier transform differentiation properties, yielding physically meaningful averages weighted by the local energy. Unlike true probability densities, the Wigner distribution does not guarantee non-negativity and can exhibit negative values, particularly due to its quadratic nature; however, its marginals and moments still accurately recover the correct signal energy and frequency characteristics, underscoring its utility despite this limitation.

Symmetry and invariance properties

The Wigner distribution function exhibits several fundamental symmetry properties that underscore its mathematical structure in time-frequency analysis. For a real-valued signal f(t), the distribution W(t, \omega) is real-valued, ensuring that it provides a physically interpretable energy density without imaginary components. Additionally, it possesses even symmetry in the frequency domain: W(t, \omega) = W(t, -\omega), which reflects the symmetric nature of the underlying ambiguity function and facilitates computational efficiency in implementations. These symmetries extend to invariance properties under common signal transformations, preserving the distribution's utility for analyzing shifted or scaled signals. Under a time shift, f(t - t_0) transforms the distribution to W(t - t_0, \omega), maintaining the time-frequency localization relative to the shift. Similarly, a frequency shift via modulation, f(t) e^{j \omega_0 t}, results in W(t, \omega - \omega_0), ensuring invariance in the frequency direction. For scaling, if the signal is dilated as f(at) with a \neq 0, the distribution becomes \frac{1}{|a|} W\left( \frac{t}{a}, a \omega \right), which adjusts the time-frequency scaling while preserving the overall energy measure up to the factor |a|. A key uniqueness property arises from Moyal's formula, which links the Wigner distributions of two signals f and g to their inner product: \iint W_f(t, \omega) W_g(t, \omega) \, dt \, d\omega = |\langle f, g \rangle|^2. This identity ensures that the integral of the product of two Wigner distributions recovers the squared magnitude of the signals' inner product, thereby preserving orthogonality and energy relations in the time-frequency plane. For finite-energy signals in L^2(\mathbb{R}), the Wigner distribution integrates to the signal's total energy, \iint W(t, \omega) \, dt \, d\omega = \|f\|^2, confirming its role as a valid energy representation without extending to infinite support in a manner that violates boundedness.

Cross-terms and limitations

Origin and characteristics of cross-terms

The bilinear nature of the (WDF), also known as the (WVD) in signal processing contexts, leads to the appearance of cross-terms when applied to multi-component signals. Specifically, for a signal composed of the sum of two components x(t) = f(t) + g(t), the WDF decomposes as W_x(t, \omega) = W_f(t, \omega) + W_g(t, \omega) + 2 \Re \{ W_{f,g}(t, \omega) \}, where W_f and W_g are the auto-terms corresponding to each individual component, and the cross-term is given by the cross-Wigner distribution W_{f,g}(t, \omega) = \int f(t + \tau/2) g^*(t - \tau/2) e^{-j \omega \tau} d\tau. This interference arises because the WDF is quadratic in the signal, producing additive cross-interactions between distinct components rather than simply superimposing their individual representations. Cross-terms exhibit distinct characteristics that often manifest as artifacts in time-frequency representations. They are typically oscillatory, with their location positioned midway between the auto-terms of the interacting components in the time-frequency plane. The amplitude of these cross-terms is comparable to—or even twice that of—the auto-terms, which can obscure the true signal structure and introduce misleading energy concentrations. Furthermore, the oscillation frequency of cross-terms is proportional to the separation between the auto-terms, occurring in a direction orthogonal to the line connecting the component locations. In specific signal configurations, cross-terms display unique geometric behaviors relative to the auto-components. For equal-frequency signals, such as two sinusoids sharing the same frequency but differing in phase or timing, the cross-terms appear parallel to the auto-components, extending along lines of constant frequency while exhibiting rapid oscillations. In contrast, for chirp signals with linear frequency modulation, cross-terms manifest as diagonal ridges midway between the auto-terms, mirroring the slope of the chirp trajectories. A detailed analysis for two sinusoids illustrates these features explicitly. Consider the signal x(t) = \cos(2\pi f_1 t) + \cos(2\pi f_2 t); the cross-term in the WVD takes the form $2 \cos(2\pi (f_1 + f_2) t / 2) \cos(2\pi (f_1 - f_2) t / 2), revealing beating patterns where the envelope modulates at the difference frequency (f_1 - f_2)/2 and the carrier at the average frequency (f_1 + f_2)/2. This results in oscillatory interference centered at the midpoint frequency, with the beating underscoring the artifactual nature of the cross-term.

Strategies for cross-term suppression

One primary strategy for mitigating cross-terms in the Wigner distribution, which arise due to its bilinear nature, involves applying time-frequency smoothing through convolution with a two-dimensional kernel. This approach averages out the oscillatory cross-term components while aiming to preserve the concentration of auto-terms around the signal's instantaneous frequency. The smoothing kernel, typically low-pass in both time and frequency directions, reduces the interference by suppressing high-frequency oscillations characteristic of cross-terms, as detailed in foundational analyses of quadratic time-frequency representations. Another technique employs windowing either in the time domain or the lag domain to limit the extent of bilinearity, thereby constraining the range over which cross-terms can manifest. Time windowing segments the signal, effectively reducing the lag integration limits and diminishing distant cross-term contributions, while lag windowing directly truncates the autocorrelation to focus on local signal components. This method trades some frequency resolution for reduced interference, particularly effective for signals with separated components. More advanced suppression is achieved through kernel methods within Cohen's class of time-frequency distributions, where a generalized kernel \phi(\tau, \nu) modulates the ambiguity function to selectively attenuate cross-terms. The distribution is formulated as: W(t, \omega) = \iint \phi(\tau, \nu) A(\tau, \nu) e^{j 2\pi (\nu t - \tau \omega)} \, d\tau \, d\nu, where the ambiguity function is A(\tau, \nu) = \int_{-\infty}^{\infty} x(u + \tau/2) x^*(u - \tau/2) e^{-j 2\pi \nu u} \, du, with the kernel designed to approach unity for auto-terms (\tau \approx 0, \nu \approx 0) and zero for cross-term locations. A seminal example is the Choi-Williams exponential kernel, \phi(\tau, \nu) = e^{-\alpha \tau^2 \nu^2}, where \alpha > 0 controls the suppression strength; higher \alpha enhances cross-term reduction but may introduce slight blurring. This kernel satisfies key properties like time-frequency shift covariance and preserves marginals for certain choices. A fundamental in these strategies is that increased or kernel diminishes cross-terms at the expense of blurring auto-terms, potentially reducing time-frequency ; the optimal kernel selection thus depends on the signal's characteristics, such as component separation and levels. Recent advancements include adaptive methods for kernel design in Cohen's class, such as least-squares adaptive filtering that adjusts kernels to minimize mean-square error for denoising and cross-term suppression in the WVD domain, outperforming some static approaches.

Examples in time-frequency analysis

Responses to basic signals

The Wigner distribution function, when applied to basic deterministic signals, reveals its ability to provide perfect time-frequency localization for single-component auto-terms, without the interference of cross-terms that arise in multi-component scenarios. For a constant signal f(t) = 1, the distribution is given by W(t, \omega) = \delta(\omega), which is independent of time t and represents an impulse at zero frequency, illustrating uniform energy distribution across all time at DC. This form highlights the Wigner distribution's capacity to capture stationary, frequency-pure components with infinite resolution in the frequency domain. For the Dirac delta signal f(t) = \delta(t), the Wigner distribution simplifies to W(t, \omega) = \delta(t), localized as an impulse in time at t = 0 and uniform (constant) across all frequencies \omega, reflecting the instantaneous nature of the signal with energy spread equally over the frequency spectrum. This response demonstrates the distribution's ideal time resolution for transient events, where the lack of duration leads to complete frequency uncertainty. A complex sinusoid f(t) = e^{j \omega_0 t} yields W(t, \omega) = \delta(\omega - \omega_0), a horizontal line constant over all time t at the fixed \omega_0, showcasing perfect frequency localization for monochromatic signals. For a real sinusoid f(t) = \cos(\omega_0 t), the distribution includes symmetric components: W(t, \omega) = \frac{1}{2} \left[ \delta(\omega - \omega_0) + \delta(\omega + \omega_0) \right], with energy split between positive and negative frequencies, independent of time. These cases exemplify the Wigner distribution's bilinear nature, which concentrates auto-term energy precisely along the signal's instantaneous trajectory. For a rectangular , or boxcar signal f(t) = 1 for |t| \leq T/2 and 0 otherwise, the distribution within the signal's time is W(t, \omega) = T \operatorname{sinc}^2 \left( \frac{\omega T}{2} \right) for |t| \leq T/2, and zero outside, where \operatorname{sinc}(x) = \sin(\pi x)/(\pi x). This produces a sinc-like profile in that is constant in time over the duration, with broader spread for shorter pulses T, underscoring the between time and localization inherent in finite-duration signals. In all these single-component examples, the absence of cross-terms ensures unadulterated representation of the signal's , affirming the Wigner distribution's theoretical optimality for such ideal cases.

Responses to composite signals

The Wigner distribution for a composite signal consisting of two sinusoids, f(t) = e^{j \omega_1 t} + e^{j \omega_2 t}, reveals two parallel auto-terms appearing as horizontal ridges at \omega_1 and \omega_2 across the entire time axis, representing the individual energy concentrations of each component. Between these auto-terms, an oscillating cross-term emerges at the average (\omega_1 + \omega_2)/2, modulating in time with a frequency equal to |\omega_1 - \omega_2|, which introduces interference that can obscure the true signal structure in the time-frequency plane. For a linear signal f(t) = e^{j \pi k t^2}, which serves as a single-component but non-stationary example within composite analyses, the Wigner produces a clean curved ridge tracing the instantaneous \omega(t) = 2\pi k t, demonstrating ideal localization without cross-terms due to the quadratic phase structure aligning perfectly with the 's bilinear nature. In the case of a Gaussian-windowed sinusoid, the Wigner-Ville spreads the auto-term along the time direction due to the finite support, resulting in a rectangular-like centered at the sinusoid's , while for composite versions with multiple components, minor cross-terms appear primarily at the edges, where overlap and boundary effects amplify . A key characteristic in multi-component signals is that for orthogonal components, such as sinusoids with distant frequencies, the cross-terms decay effectively through rapid temporal oscillations, reducing their visibility in averaged or smoothed representations; this highlights the inherent between high time-frequency and artifacts, as visualized in time-frequency plots where closely spaced components show prominent wavy cross-ridges, while distant ones exhibit nearly vanishing oscillations. techniques can further suppress these cross-terms, as explored in related strategies.

Windowed variants

Pseudo Wigner-Ville distribution

The pseudo Wigner-Ville distribution (PWVD) is a windowed variant of the Wigner-Ville distribution designed to enhance time localization for finite-duration or non-stationary signals while preserving resolution. It incorporates a window to truncate the infinite inherent in the standard Wigner-Ville distribution, making it computationally practical and better suited for analyzing signals with abrupt changes. The PWVD is mathematically defined as \begin{equation} PW(t, \omega) = \int_{-\infty}^{\infty} h(\tau) f\left(t + \frac{\tau}{2}\right) f^*\left(t - \frac{\tau}{2}\right) e^{-j \omega \tau} , d\tau, \end{equation} where f(t) is the analyzed signal, f^*(t) denotes its complex conjugate, \tau is the lag variable, and h(\tau) is a real, even, low-pass lag window function, such as a Hamming or rectangular window, that limits the extent of the correlation. The choice of h(\tau) controls the trade-off between time sharpness and the suppression of artifacts, with shorter windows providing better time resolution at the cost of some frequency smearing. By applying the lag window, the PWVD maintains the excellent frequency resolution of the original Wigner-Ville distribution but significantly improves time locality, particularly for signals with evolving content. This sharpening of auto-terms in the time dimension allows for clearer depiction of transient events, such as frequency shifts or impulses, without introducing additional time smoothing that could blur rapid changes. Cross-terms, arising from the bilinear nature of the distribution, persist in the PWVD but are spatially confined closer to the auto-terms due to the window's filtering , reducing their spread across the time-frequency plane compared to the unwindowed case. This property makes the PWVD especially useful for resolving transients in signals like pulses, where edge discontinuities produce localized energy concentrations that highlight abrupt onsets and offsets. In discrete implementations, the PWVD is computed efficiently by first forming the windowed local autocorrelation (short-time correlation) for each time index and then applying the (FFT) along the lag dimension to obtain the frequency content. This approach leverages standard FFT algorithms, ensuring numerical efficiency for sampled signals, and builds on the basic discrete Wigner-Ville formulation by inserting the lag window prior to transformation.

Smoothed Wigner-Ville distribution

The smoothed Wigner-Ville (SWVD) is a time-frequency designed to address the cross-term inherent in the Wigner-Ville distribution by applying separable in both time and variables. It is particularly useful for analyzing multi-component non-stationary signals where cross-terms can obscure individual auto-components. The distribution is obtained by convolving the Wigner-Ville distribution with a two-dimensional separable , resulting in reduced interference while preserving much of the high resolution. The mathematical definition of the SWVD is given by SW(t, \omega) = \iint g(s) h(\tau) R(t - s, \tau) e^{-j \omega \tau} \, ds \, d\tau, where R(t, \tau) = z\left(t + \frac{\tau}{2}\right) z^*\left(t - \frac{\tau}{2}\right) is the signal's local function, g(s) is a low-pass time-smoothing centered at t, and h(\tau) is a low-pass lag that limits the extent of the autocorrelation . This form corresponds to a Cohen's class distribution with a separable kernel \Phi(\tau, \nu) = H(\tau) G(\nu), where H(\tau) and G(\nu) are the Fourier transforms of h(\tau) and g(t), respectively. The smoothing in the time domain averages the local autocorrelation over a window around t, while the lag truncates distant correlations, effectively filtering out oscillations from cross-terms. The primary effect of this smoothing is a slight broadening of the auto-terms, which introduces minor resolution loss, but it significantly suppresses cross-terms located far from the auto-components in the time-frequency plane, as the kernel attenuates high-frequency components in the ambiguity domain associated with interference. This makes the SWVD suitable for signals with separated components, such as pairs of frequency-modulated signals, where it provides clearer separation compared to the unsmoothed Wigner-Ville distribution. A notable special case occurs when the time window g(t) = \delta(t), reducing the SWVD to the Wigner-Ville distribution, which applies only lag smoothing. As one of the strategies for cross-term suppression, the SWVD balances resolution and interference reduction through careful window selection. Implementation of the SWVD can be performed efficiently via direct computation of the double integral for analytic signals or, more practically, through 2D -based filtering of the Wigner-Ville distribution, leveraging the for separability. This approach is computationally advantageous for applications, with complexity dominated by the FFT size matching the window lengths.

Applications

Signal processing uses

The Wigner distribution function (WDF), also known as the Wigner-Ville distribution, serves as a key tool in time-frequency decomposition for non-stationary signals in , providing high-resolution representations that reveal evolving frequency content over time. This capability is particularly valuable for analyzing frequency-modulated () signals, where the instantaneous frequency (IF) varies nonlinearly, such as in signals briefly exemplified by linear FM sweeps. Seminal work has established the WDF's utility in capturing these dynamics through its bilinear structure, enabling precise localization in the time-frequency plane compared to linear transforms like the . Instantaneous frequency estimation for FM signals often employs ridge tracking on the WDF, identifying energy concentrations along IF curves to mitigate cross-terms and noise interference. Ridge extraction algorithms, such as those based on the or Hough transforms applied to the WDF, track these ridges efficiently in polynomial time, achieving robust IF estimates even in high-noise environments by selecting the maximum energy path in the time-frequency domain. For instance, in multicomponent FM signals, variants enhance ridge visibility, allowing separation of individual components. This approach has been integrated into adaptive linear estimation frameworks, improving accuracy for signals with varying modulation rates. In denoising applications, the WDF facilitates adaptive filtering by thresholding negative regions or applying wavelet-based soft-thresholding to suppress noise while preserving signal energy concentrations. The distribution's sensitivity to additive noise is addressed through post-processing techniques that zero out low-amplitude artifacts in the time-frequency plane, effectively reducing in reconstructed signals in noisy environments. This method leverages the WDF's ability to highlight auto-terms over cross-terms, enabling selective reconstruction of clean signal components via inverse transforms. The WDF finds practical use in radar systems for pulse compression and target detection, where it analyzes accelerating targets in cluttered environments by detecting IF trajectories in received echoes, enhancing detection probability in low-SNR scenarios. In audio processing, it supports tracking and speech estimation by resolving time-varying harmonics in voiced segments. As of 2025, integrations with deep learning have advanced automatic classification in WDF-based spectrograms, using convolutional neural networks (CNNs) to classify multicomponent signals from time-frequency images, achieving accuracies around 95% in partial discharge applications. These hybrid frameworks treat WDF outputs as input spectrograms for DL models like ResNet, automating ridge segmentation and noise rejection without manual thresholding. A typical workflow for signal analysis involves computing the discrete WDF of the input signal, applying ridge extraction to identify primary IF paths, and reconstructing the signal via inverse filtering along those ridges, which has demonstrated effective separation of FM components in radar and audio datasets.

Extensions to other fields

The Wigner distribution function originated in as a quasi-probability distribution in , providing a representation of the density operator for quantum states and enabling the of in terms akin to classical . This formulation allows for the computation of expectation values of observables through integrals over , bridging quantum and classical descriptions without relying on wave functions or operators directly. In optics, the Wigner function describes the phase-space properties of partially coherent light beams, facilitating the analysis of paraxial propagation through optical systems and the characterization of beam coherence. It models the evolution of light fields under free-space propagation or through lenses by treating the Wigner function as a transportable entity, similar to ray optics but incorporating quantum-like interference effects. Extensions to image processing employ the two-dimensional Wigner distribution for texture analysis, where it captures joint spatial-frequency content to distinguish patterns in textured regions. In () imaging, the pseudo-Wigner-Ville variant addresses ambiguities and speckle noise by providing a localized representation that aids in segmentation and feature extraction for terrain . Post-2020 applications in leverage the Wigner distribution for feature extraction from time-series data, such as electroencephalogram (EEG) signals, by generating time-frequency representations that enhance tasks like staging or disease detection. These methods integrate the distribution with models, such as convolutional neural networks, to process smoothed pseudo-Wigner-Ville transforms for robust in biomedical signals. Generalizations to higher dimensions extend this utility to multivariate data analysis, improving interpretability in inputs. Recent advancements as of 2025 apply the Wigner function in for state tomography, particularly in continuous-variable systems, where it reconstructs quantum states from measurement data to verify entanglement and non-classicality. This approach supports efficient characterization of or qumode states in noisy intermediate-scale quantum devices, aiding error mitigation and algorithm validation.

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