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Revitalizing AR Process Simulation of Non-Gaussian Radar Clutter via Series-Based Analytic Continuation

Xingxing Liao, Junhao Xie

Abstract

Due to the conceptual simplicity, the linear filtering framework, notably the autoregressive (AR) process, has a long history in simulating clutter sequences with specified probability density functions (PDFs) and autocorrelation functions (ACFs). However, linear filtering inevitably distorts the input distribution, which may lead to inaccurate PDF reproduction or restrict applicability to very simple ACFs. To address these challenges, this study proposes a series-based analytic continuation strategy that revitalizes AR process clutter simulation by accurately precomputing the input pre-distortion required to compensate for AR filtering. First, the moments and cumulants of the AR input are derived based on the input-output relationship of the AR process, facilitating the moment and cumulant expansions of the Laplace transform (LT) and the logarithmic LT around zero, respectively. Second, both series expansions are analytically continued via the Padé approximation (PA) to recover the LT over the full complex plane. Notably, the PA-based continuation of the moment expansion, a conventional choice, can be highly inaccurate when the LT exhibits strong oscillations. By contrast, given the logarithmic LT generally has a simpler structure, the continuation of the cumulant expansion provides a more stable and accurate alternative. Third, the LT recovered from the cumulant expansion facilitates fast simulation of the AR input non-Gaussian white sequence via a random variable transformation method, thereby enabling an efficient AR process. Finally, simulations demonstrate that the proposed strategy enables accurate and fast simulation of non-Gaussian correlated clutter sequences.

Revitalizing AR Process Simulation of Non-Gaussian Radar Clutter via Series-Based Analytic Continuation

Abstract

Due to the conceptual simplicity, the linear filtering framework, notably the autoregressive (AR) process, has a long history in simulating clutter sequences with specified probability density functions (PDFs) and autocorrelation functions (ACFs). However, linear filtering inevitably distorts the input distribution, which may lead to inaccurate PDF reproduction or restrict applicability to very simple ACFs. To address these challenges, this study proposes a series-based analytic continuation strategy that revitalizes AR process clutter simulation by accurately precomputing the input pre-distortion required to compensate for AR filtering. First, the moments and cumulants of the AR input are derived based on the input-output relationship of the AR process, facilitating the moment and cumulant expansions of the Laplace transform (LT) and the logarithmic LT around zero, respectively. Second, both series expansions are analytically continued via the Padé approximation (PA) to recover the LT over the full complex plane. Notably, the PA-based continuation of the moment expansion, a conventional choice, can be highly inaccurate when the LT exhibits strong oscillations. By contrast, given the logarithmic LT generally has a simpler structure, the continuation of the cumulant expansion provides a more stable and accurate alternative. Third, the LT recovered from the cumulant expansion facilitates fast simulation of the AR input non-Gaussian white sequence via a random variable transformation method, thereby enabling an efficient AR process. Finally, simulations demonstrate that the proposed strategy enables accurate and fast simulation of non-Gaussian correlated clutter sequences.
Paper Structure (29 sections, 51 equations, 12 figures, 2 tables)

This paper contains 29 sections, 51 equations, 12 figures, 2 tables.

Table of Contents

  1. Introduction
  2. Characteristics of Sea Clutter
  3. Amplitude Distribution
  4. Temporal Correlation of the Speckle and Texture Components
  5. Review of the ZMNL and the Linear Filtering via AR Process
  6. ZMNL
  7. Inverse transform for desired output distribution
  8. Correlation predistortion for desired output correlation
  9. Linear Filtering via AR process
  10. AR process for desired output correlation
  11. Distribution predistortion for desired output distribution
  12. Proposed Series-Based Analytic Continuation for AR input's Statistics
  13. Series Expansion of AR Input's LT
  14. Series-based Analytic Continuation for AR Input's LT & PDF
  15. Analytic continuation of moment expansion (\ref{['eq-AR-U-cum-LP-series']}): conventional way
  16. ...and 14 more sections

Figures (12)

  • Figure 1: Comparison of the simulation procedure of two conventional real-valued sequence simulation frameworks. (a) ZMNL via correlation distortion; (b) linear filtering via distribution distortion.
  • Figure 2: Comparison of the LT and logarithmic LT of the PT$\alpha$S distribution with parameters $\alpha=0.95$, $\gamma = 2$, $\eta=4$. (a) Real part; (b) Imaginary part.
  • Figure 3: Comparison of the gamma LT recovery performance via the PA-based continuations of different series. (a) Real part of the LTs; (b) Imaginary part of the LTs.
  • Figure 4: Comparison of the PT$\alpha$S LT recovery performance via the PA-based continuations of different series. (a) Real part of the LTs; (b) Imaginary part of the LTs.
  • Figure 5: Comparison of the gamma PDF recovery performance via the PA-based continuations of different series. (a) Linear scale; (b) Logarithmic scale.
  • ...and 7 more figures