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Pattern Synthesis Design of Linear Array Antenna with Unequal Spacing Based on Improved Dandelion Optimization

Jianhui Li1, Yan Liu1, Wanru Zhao1

  • 1School of Physics and Electronic Information, Yunnan Normal University, Kunming 650500, China.

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A new chaos exchange nonlinear dandelion optimization (CENDO) algorithm improves antenna array patterns by reducing sidelobe levels and creating deep nulls. This enhanced method outperforms existing algorithms in complex electromagnetic environments.

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CENDO algorithmlogistic–tent chaotic mappingnonlinear control factorsynthesis of unequally spaced linear arrays

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Area of Science:

  • Electromagnetism
  • Antenna Theory
  • Optimization Algorithms

Background:

  • Complex electromagnetic environments necessitate advanced radar systems.
  • Array antennas are crucial for enhancing radar capabilities against interference and detection.
  • Existing optimization algorithms struggle with precision and convergence for antenna pattern optimization.

Purpose of the Study:

  • To introduce the Chaos Exchange Nonlinear Dandelion Optimization (CENDO) algorithm for optimizing non-equidistant antenna array patterns.
  • To enhance antenna performance by minimizing sidelobe levels (SLL) and achieving deep nulls.
  • To evaluate the CENDO algorithm's effectiveness against other leading optimization techniques.

Main Methods:

  • Development of the CENDO algorithm, an improved version of the Dandelion Optimization (DO) algorithm.
  • Simulation of five experimental examples to test CENDO's performance in optimizing non-equidistant antenna arrays.
  • Comparative analysis of CENDO against algorithms like DO, PSO, WOA, GOA, SSA, and others.

Main Results:

  • CENDO achieved the lowest SLL in three simulation examples optimizing non-equidistant arrays.
  • CENDO demonstrated superior performance in simultaneously reducing SLL and achieving deep nulls in two additional examples.
  • The algorithm consistently outperformed all compared methods across five experimental simulations.

Conclusions:

  • The CENDO algorithm offers superior optimization capabilities for non-equidistant antenna array patterns.
  • CENDO effectively reduces sidelobe levels and deepens nulls, crucial for radar system performance.
  • This algorithm presents a strong candidate for solving complex electromagnetic problems.