A novel algorithm for optimal waveform design based on dual mutual information for radar systems

Mutual Information Model of Adaptive Waveform Design

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.460-461.207 ◽

2011 ◽

Vol 460-461 ◽

pp. 207-212

Author(s):

Bin Wang ◽

Jin Kuan Wang ◽

Xin Song

Keyword(s):

Mutual Information ◽

Working Conditions ◽

Information Model ◽

Waveform Design ◽

Radar Systems ◽

Simulation Results

Traditional radar systems are lack of adaptivity to the environment. Modern radar systems should transmit different waveforms according to different environment. In this paper, mutual information model of adaptive waveform design is proposed. With this model, different waveforms can be designed adaptively under different radar working conditions. Simulation results demonstrate the validity of our model. Finally, the whole paper is summarized.

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Waveform design for TDM-MIMO radar systems

Signal Processing ◽

10.1016/j.sigpro.2019.107307 ◽

2020 ◽

Vol 167 ◽

pp. 107307

Author(s):

M. Bagher Alaie ◽

Seyed Ahmad Olamaei

Keyword(s):

Waveform Design ◽

Mimo Radar ◽

Radar Systems

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Waveform Design for Beampattern Shaping in 4D-imaging MIMO Radar Systems

2021 21st International Radar Symposium (IRS) ◽

10.23919/irs51887.2021.9466196 ◽

2021 ◽

Author(s):

Ehsan Raei ◽

Mohammad Alaee-Kerahroodi ◽

Bhavani M. R. Shankar

Keyword(s):

Waveform Design ◽

Mimo Radar ◽

Radar Systems ◽

4D Imaging

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Robust Waveform Design Based on Bisection and Maximum Marginal Allocation Methods with the Concept of Information Entropy

Mathematical Problems in Engineering ◽

10.1155/2020/3529858 ◽

2020 ◽

Vol 2020 ◽

pp. 1-23

Author(s):

Bin Wang ◽

Xiaolei Hao

Keyword(s):

Mutual Information ◽

Optimization Design ◽

Waveform Design ◽

Observation Time ◽

Cognitive Radar ◽

Bisection Algorithm ◽

Water Filling ◽

Water Filling Algorithm ◽

Concept Of Information ◽

Transmitted Waveform

Cognitive radar can overcome the shortcomings of traditional radars that are difficult to adapt to complex environments and adaptively adjust the transmitted waveform through closed-loop feedback. The optimization design of the transmitted waveform is a very important issue in the research of cognitive radar. Most of the previous studies on waveform design assume that the prior information of the target spectrum is completely known, but actually the target in the real scene is uncertain. In order to simulate this situation, this paper uses a robust waveform design scheme based on signal-to-interference-plus-noise ratio (SINR) and mutual information (MI). After setting up the signal model, the SINR and MI between target and echo are derived based on the information theory, and robust models for MI and SINR are established. Next, the MI and SINR are maximized by using the maximum marginal allocation (MMA) algorithm and the water-filling method which is improved by bisection algorithm. Simulation results show that, under the most unfavorable conditions, the robust transmitted waveform has better performance than other waveforms in the improvement degree of SINR and MI. By comparing the robust transmitted waveform based on SINR criterion and MI criterion, the influence on the variation trend of SINR and MI is explored, and the range of critical value of Ty is found. The longer the echo observation time is, the better the performance of the SINR-based transmitted waveform over the MI-based transmitted waveform is. For the mutual information between the target and the echo, the performance of the MMA algorithm is better than the improved water-filling algorithm.

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Pixel-Level Image Fusion Based on Programmable GPU

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.347-350.3872 ◽

2013 ◽

Vol 347-350 ◽

pp. 3872-3876

Author(s):

Hong Li ◽

Gao Feng Tang ◽

Fen Xia Wu ◽

Cong E Tan

Keyword(s):

Mutual Information ◽

Image Fusion ◽

Parallel Algorithm ◽

Rapid Development ◽

General Purpose ◽

Kernel Functions ◽

Regional Energy ◽

Novel Algorithm ◽

Evaluation Accuracy

A novel algorithm which is image fusion based on GPU is proposed. The fused rule is regional energy. In recent years, the power of the computing of GPU has been greatly improved, which results that using it for the general-purpose computing has a rapid development. The essay researches on implementing the oriental field algorithm on GPU, including selecting GPU memories and dividing blocks and threads of GPU kernel functions. The results of experiment on the GPU of NVIDIA GTX560 are given, which shows that our proposed algorithm can be applied to the field of image fusion. Experiment shows the proposed algorithm has faster calcu-lation velocity and higher evaluation accuracy. The speed of the parallel algorithm is 200 times faster than that of the CPU-based implementation. Meanwhile the mutual information and QAB/F parameters are higher than that of the CPU-based algorithm.

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Mutual Information-Based Waveform Design for MIMO Radar Space-Time Adaptive Processing

IEEE Transactions on Geoscience and Remote Sensing ◽

10.1109/tgrs.2020.3008320 ◽

2020 ◽

pp. 1-13

Author(s):

Guohao Sun ◽

Zishu He ◽

Jun Tong ◽

Xianxiang Yu ◽

Shengnan Shi

Keyword(s):

Mutual Information ◽

Waveform Design ◽

Mimo Radar ◽

Space Time ◽

Adaptive Processing ◽

Space Time Adaptive Processing

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FSMI: Fast computation of Shannon mutual information for information-theoretic mapping

The International Journal of Robotics Research ◽

10.1177/0278364920921941 ◽

2020 ◽

Vol 39 (9) ◽

pp. 1155-1177

Author(s):

Zhengdong Zhang ◽

Theia Henderson ◽

Sertac Karaman ◽

Vivienne Sze

Keyword(s):

Mutual Information ◽

Fundamental Problem ◽

Information Theoretic ◽

Efficient Data ◽

3D Environments ◽

Information Metric ◽

Computational Difficulty ◽

First Time ◽

Efficient Data Structures ◽

Novel Algorithm

Exploration tasks are embedded in many robotics applications, such as search and rescue and space exploration. Information-based exploration algorithms aim to find the most informative trajectories by maximizing an information-theoretic metric, such as the mutual information between the map and potential future measurements. Unfortunately, most existing information-based exploration algorithms are plagued by the computational difficulty of evaluating the Shannon mutual information metric. In this article, we consider the fundamental problem of evaluating Shannon mutual information between the map and a range measurement. First, we consider 2D environments. We propose a novel algorithm, called the fast Shannon mutual information (FSMI). The key insight behind the algorithm is that a certain integral can be computed analytically, leading to substantial computational savings. Second, we consider 3D environments, represented by efficient data structures, e.g., an OctoMap, such that the measurements are compressed by run-length encoding (RLE). We propose a novel algorithm, called FSMI-RLE, that efficiently evaluates the Shannon mutual information when the measurements are compressed using RLE. For both the FSMI and the FSMI-RLE, we also propose variants that make different assumptions on the sensor noise distribution for the purpose of further computational savings. We evaluate the proposed algorithms in extensive experiments. In particular, we show that the proposed algorithms outperform existing algorithms that compute Shannon mutual information as well as other algorithms that compute the Cauchy–Schwarz quadratic mutual information (CSQMI). In addition, we demonstrate the computation of Shannon mutual information on a 3D map for the first time.

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