Implementation of grey wolf optimization controller for multiple humanoid navigation

Muni, Manoj Kumar; Parhi, Dayal R.; Kumar, Priyadarshi Biplab

doi:10.1002/cav.1919

Cited by 13 publications

(6 citation statements)

References 48 publications

(45 reference statements)

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“…Feature selection is a very important part of artificial intelligence based prediction models [33] [34]. Fig.…”

Section: F Feature Selection Using Enhanced Gwo Methodsmentioning

confidence: 99%

Fish Species Classification using Optimized Deep Learning Model

Mol¹,

Jose²

2022

IJACSA

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Classification of fish species in aquatic pictures is a growing field of research for researchers and image processing experts. Classification of fish species in aquatic images is critical for fish analytical purposes, such as ecological auditing balance, observing fish populations, and saving threatened animals. However, ocean water scattering and absorption of light result in dim and low contrast pictures, making fish classification laborious and challenging. This paper presents an efficient scheme of fish classification, which helps the biologist understand varieties of fish and their surroundings. This proposed system used an improved deep learning-based auto encoder decoder method for fish classification. Optimal feature selection is a major issue with deep learning models generally. To solve this problem efficiently, an enhanced grey wolf optimization technique (EGWO) has been introduced in this study. The accuracy of the classification system for aquatic fish species depends on the essential texture features. Accordingly, in this study, the proposed EGWO has selected the most optimal texture features from the features extracted by the auto encoder. Finally, to prove the efficacy of the proposed method, it is compared to existing deep learning models such as AlexNet, Res Net, VGG Net, and CNN. The proposed method is analysed by varying iterations, batches, and fully connected layers. The analysis of performance criteria such as accuracy, sensitivity, specificity, precision, and F1 score reveals that AED-EGWO gives superior performance.

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“…Feature selection is a very important part of artificial intelligence based prediction models [33] [34]. Fig.…”

Section: F Feature Selection Using Enhanced Gwo Methodsmentioning

confidence: 99%

Fish Species Classification using Optimized Deep Learning Model

Mol¹,

Jose²

2022

IJACSA

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“…Kumar et al [25] perform navigational analysis using their developed intelligent motion planner on a humanoid robot. Muni et al [26][27][28][29][30][31] introduced and successfully implemented various artificial intelligence algorithms toward motion planning analysis of legged robots in obstacle-prone environments.…”

Section: Introductionmentioning

confidence: 99%

Tailoring the motion planning of humanoids in complex arena: a regression-firefly-based approach

Sahu,

Parhi,

Muni

et al. 2024

Robotica

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In the current investigation, a two-stage hybridization model has been used for the motion planning of humanoids in complex environmental conditions using regression analysis and the firefly algorithm. In the first step, sensory outputs are fed to the regression model, and an initial turning angle (ITA) is obtained. In the second step, the ITA is again fed as input to the firefly model along with other required inputs, and the final turning angle (FTA) is obtained. The FTA serves as the guiding parameter for the humanoids to reach their desired destinations. The developed motion planning scheme has been implemented on NAO humanoid robots in simulation and experimental platforms. A Petri-Net control strategy has been integrated along with the hybrid scheme while negotiating multiple humanoids in a common platform. The results obtained from the motion planning analysis in simulation and experimental arenas are compared against each other in terms of selected navigational parameters and observed satisfactory agreements. Finally, the proposed hybrid controller is also tested against another standard navigational model and substantial enhancement in the performance has been noticed.

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“…Kumar et al 33 have presented hybrid controller of sine-cosine and ant colony algorithm for path optimization. Muni et al [34][35][36] have presented different AI technique, hybridized with fuzzy controller for navigational control of humanoid robots. Kumar 37 have presented hybrid regression fuzzy controller for navigation of humanoid robots.…”

Section: Introductionmentioning

confidence: 99%

Static and dynamic path optimization of multiple mobile robot using hybridized fuzzy logic-whale optimization algorithm

Kumar

Parhi

Kashyap

et al. 2021

Proceedings of the Institution of Mechanical Engineers, Part C:

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Fuzzy logic is widely known as a value-based technique. Whale optimization algorithm (WOA), on the other hand, is a nature-inspired optimization technique. Hybridization of these two techniques is proposed for path planning and control, over multiple mobile robots in static and dynamic environments. The effectiveness of the resulting technique, known as ‘Fuzzy-WOA’, is tested through MATLAB simulation coupled with real-time experiments. Upon testing, a good agreement is observed between these platforms. Furthermore, the proposed technique is found to be more efficient when compared to other existing techniques, with a significant improvement of about 20.63% in terms of path lengths.

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Implementation of grey wolf optimization controller for multiple humanoid navigation

Cited by 13 publications

References 48 publications

Fish Species Classification using Optimized Deep Learning Model

Fish Species Classification using Optimized Deep Learning Model

Tailoring the motion planning of humanoids in complex arena: a regression-firefly-based approach

Static and dynamic path optimization of multiple mobile robot using hybridized fuzzy logic-whale optimization algorithm

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