Energy‐efficient compressive sensing for multi‐target tracking in wireless visual sensor networks

Najimi, Maryam; Sadeghi, Vahideh Sadat

doi:10.1002/dac.5307

Cited by 2 publications

(2 citation statements)

References 35 publications

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“…Of which:𝑋 ̃is the set of localized target states in the sensor network model, containing variables such as the number of tracked targets and state parameters, and in case of multi-target tracking [26], then, the𝑋 ̃= {𝑋 ̃1, 𝑋 ̃𝑚}, denotes the existence of multiple goals, and the state variables of the goals satisfy𝑋 ̃1 ≠ 𝑋 ̃𝑚；𝑍 𝑡 indicates the target observations acquired by all sensor nodes at the time𝑡, the𝑍 (𝑡) indicates all observations prior to the time 𝑡 , i.e., the 𝑍 (𝑡) = 𝑍 1 , ⋯ , 𝑍 𝑡 ； 𝐿 𝑍,𝑡 (𝑋 ̃) = 𝑓 𝑦 (𝑍|𝑋 ̃) is the observed likelihood function; the 𝑓(𝑋 ̃|𝑞) 𝑡+1|𝑡 is the multiobjective state set Markov state transfer density; the𝑓(𝑋 ̃|𝑍 (𝑡) ) 𝑡 |𝑡 is the posterior probability density of the set of multi-objective states at the moment𝑘; the𝜆is the normalization parameter, which is calculated as follows:…”

Section: B Target State Tracking Based On Probabilistic Hypothesis De...mentioning

confidence: 99%

A Study on Wireless Sensor Node Localization and Target Tracking Based on Improved Locust Algorithm

SONGHE,

2024

ijacsa

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To improve the positioning accuracy of wireless sensor nodes and ensure the target tracking effect, a wireless sensor node positioning and target tracking method based on an improved locust algorithm is proposed. The DV Hop algorithm is used to calculate the minimum hops and average hops distance between the unknown node and each anchor node to obtain the location of the unknown node, realize the rough positioning of wireless sensor nodes, and analyze the positioning error to determine the positioning accuracy target function; The improved locust algorithm is used to solve the positioning accuracy objective function to obtain the sensor node positioning results with the minimum error; The target tracking model and the target is calculated. According to the target observation information obtained by all sensor nodes, the target state in the wireless sensor network model is tracked using the probability hypothesis density filtering algorithm. The test results show that the algorithm has better performance, the spatial evaluation index results are all lower than 0.020, and the individual distribution in the solution set is better; The location of each unknown node in different node distribution states can be obtained; The positioning error under the surface and plane is less than 0.012; The maximum error of target tracking is 0.142m; It can track single target and multiple targets.

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Section: B Target State Tracking Based On Probabilistic Hypothesis De...mentioning

confidence: 99%

A Study on Wireless Sensor Node Localization and Target Tracking Based on Improved Locust Algorithm

SONGHE,

2024

ijacsa

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“…In the modern world, advanced gadgets exist like solar cells to generate electricity, [1,2] high-power batteries [3,4] to store them, and even sensors to save electricity at the least. [5,6] While DOI: 10.1002/adom.202203126 marching forward with available resources is essential, an eye must be kept to not exhaust them such as inviting an energy crisis soon. With the increasing signs of an upcoming shortage of energy like global warming and melting of glaciers, researchers and scientists have already begun damage control work in the form of technologies like electric vehicles, [7,8] supercapacitors, [9,10] and electrochromic (EC) [11][12][13] smart windows.…”

Section: Introductionmentioning

confidence: 99%

Recipe for Fabricating Optimized Solid‐State Electrochromic Devices and Its Know‐How: Challenges and Future

Ghosh

Kandpal

Rani

et al. 2023

Advanced Optical Materials

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Electrochromism, a well‐defined phenomenon of bias‐induced reversible color switching, has led to real applications in several smart devices including smart windows and self‐powered batteries and solar panels. For these applications, the electrochromic (EC) materials need to be integrated as solid‐state devices. Deciphering ways to recreate a conventional device requires understanding of basic structure and its working. A thorough discussion is provided here regarding various materials that can act as chromophores when treated with some electric bias in addition to a few parameters that dictatehow fairly the device performs. The next important aspect is the device design, the skeleton of which usually includes conducting substrates, EC active materials, and an electrolyte. Step‐by‐step, various available device paradigms are discussed starting from a single EC electrode then joining a blank substrate to fabricate a monolayer electrochromic device (ECD) moving onto bi‐layer ECDs, and finally, all‐in‐one EC gel, which is devoid of any proper layered pattern. A thorough discussion regarding various application‐oriented structural modifications is provided. Challenges and the areas that need to be addressed in immediate future are discussed.

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Energy‐efficient compressive sensing for multi‐target tracking in wireless visual sensor networks

Cited by 2 publications

References 35 publications

A Study on Wireless Sensor Node Localization and Target Tracking Based on Improved Locust Algorithm

A Study on Wireless Sensor Node Localization and Target Tracking Based on Improved Locust Algorithm

Recipe for Fabricating Optimized Solid‐State Electrochromic Devices and Its Know‐How: Challenges and Future

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