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Robot Path Planning in Unknown Environments Based on Learning-Guided Optimization Approach
Tsinghua Science and Technology
Published: 14 July 2026
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A learning-guided optimization approach, i.e., a Q-Learning-guided Memetic Algorithm (QLMA), is proposed to solve path planning problems in unknown environments. Traditional path planning algorithms in unknown environments have the disadvantages of low efficiency and stability problems. Integrating learning strategies into a memetic algorithm is a natural way to enhance search performance. The proposed algorithm can be divided into two stages: learning and optimization. A Q-learning algorithm implements the learning stage, while the optimization stage is implemented by hybridization of a Genetic Algorithm (GA) and Simulated Annealing (SA) algorithm, i.e., a memetic algorithm. The learning stage aims to acquire information from current search states. The Q-learning algorithm’s environmental learning capability is formed by rewards received from changes in distance to the target. Therefore, the path strategy could be adjusted continually, and effective paths could be identified. The optimization stage aims to utilize the obtained information and enhance the quality of known paths. A GA improves the global search ability, while an SA algorithm enhances the local search ability. The experimental study was conducted on 30 test scenarios with three types of index points. The proposed algorithm outperforms the other two algorithms significantly in the test scenarios.

Open Access Issue
Hybrid Improved Brain Storm Optimization with Support Vector Machine for Cardiovascular Diseases Classification
Tsinghua Science and Technology 2026, 31(1): 142-161
Published: 25 August 2025
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Most existing classification algorithms for cardiovascular disease are limited to specific diseases and cannot categorize the severity of the diseases. These algorithms still need to be improved in terms of accuracy and generalizability. Therefore, a hybrid Improved Brain Storm Optimization with Support Vector Machine (IBSO-SVM) for cardiovascular disease classification is proposed. In this study, a knowledge-driven intelligent initialization method is proposed to enhance the optimization capability of IBSO and the accuracy of IBSO-SVM. Experimental evaluations are conducted on multiple real-world datasets, and the results demonstrate the superior performance of IBSO-SVM in cardiac disease datasets. The accuracy of BSO-SVM reaches 100% on the Heart Failure and Heart Disease datasets, and the accuracy of IBSO-SVM reaches 99% on the Stroke dataset and 88% on the Cardiovascular disease dataset.

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