Abstract
Biomimetic robotic fish systems have attracted huge attention due to the advantages of flexibility and adaptability. They are typically complex systems that involve many disciplines. The design of robotic fish is a multi-objective multidisciplinary design optimization problem. However, the research on the design optimization of robotic fish is rare. In this paper, by combining an efficient multidisciplinary design optimization approach and a novel multi-objective optimization algorithm, a multi-objective multidisciplinary design optimization (MMDO) strategy named IDF-DMOEOA is proposed for the conceptual design of a three-joint robotic fish system. In the proposed IDF-DMOEOA strategy, the individual discipline feasible (IDF) approach is adopted. A novel multi-objective optimization algorithm, disruption-based multi-objective equilibrium optimization algorithm (DMOEOA), is utilized as the optimizer. The proposed MMDO strategy is first applied to the design optimization of the robotic fish system, and the robotic fish system is decomposed into four disciplines: hydrodynamics, propulsion, weight and equilibrium, and energy. The computational fluid dynamics (CFD) method is employed to predict the robotic fish’s hydrodynamics characteristics, and the backpropagation neural network is adopted as the surrogate model to reduce the CFD method’s computational expense. The optimization results indicate that the optimized robotic fish shows better performance than the initial design, proving the proposed IDF-DMOEOA strategy’s effectiveness.
Highlights
Most conventional autonomous underwater vehicles (AUVs) use propellers for propulsion [1], but this propulsion mode has some disadvantages, such as poor concealment and low efficiency
This paper presented a multi-objective multidisciplinary design optimization strategy called individual discipline feasible (IDF)-disruption-based multi-objective equilibrium optimization algorithm (DMOEOA) to solve the conceptual design problem of a three-joint robotic fish system
The robotic fish system is divided into four disciplines, including hydrodynamics discipline, propulsion discipline, weight and equilibrium discipline and energy discipline
Summary
Most conventional autonomous underwater vehicles (AUVs) use propellers for propulsion [1], but this propulsion mode has some disadvantages, such as poor concealment and low efficiency. Zhang et al [14] applied a concurrent subspace design (CSD) approach to establish the MDO architecture of an intelligent ocean exploration underwater vehicle, and they applied the surrogate model to reduce the computational cost of the MDO problem. Wang et al [23] developed a multi-objective multidisciplinary design optimization (MMDO) strategy for the shape design optimization of an AUV This strategy utilized a CSD approach as the MDO architecture, and the unified-objective method was utilized to change the multi-objective optimization problem into a single-objective optimization problem. This paper presented a multi-objective multidisciplinary design optimization strategy called IDF-DMOEOA to solve the conceptual design problem of a three-joint robotic fish system.
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