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Abstract
Battery-hybrid power source architectures can reduce fuel consumption and emissions for ships with diverse operation profiles. However, conventional control strategies may fail to improve performance if the future operation profile is unknown to the controller. This paper proposes a guidance, navigation, and control (GNC) function that integrates trajectory generation and hybrid power source supervisory control. We focus on time and fuel optimal path-constrained trajectory planning. This problem is a nonlinear and nonconvex optimal control problem, which means that it is not readily amenable to efficient and reliable solution onboard. We propose a nonlinear change of variables and constraint relaxations that transform the nonconvex planning problem into a convex optimal control problem. The nonconvex three-degree-of-freedom dynamics, hydrodynamic forces, fixed pitch propeller, battery, and general energy converter (e.g., fuel cell or generating set) dissipation constraints are expressed in convex functional form. A condition derived from Pontryagin's Minimum Principle guarantees that, when satisfied, the solution of the relaxed problem provides the solution to the original problem. The validity and effectiveness of this approach are numerically illustrated for a battery-hybrid vessel in model scale. First, the convex hydrodynamic hull and rudder force models are validated with towing tank test data. Second, optimal trajectories and supervisory control schemes are evaluated under varying mission requirements. The convexification scheme in this work lays the path for the employment of mature, computationally robust convex optimization methods and creates a novel possibility for real-time optimization onboard future smart and unmanned surface vehicles.
Original language | English |
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Number of pages | 24 |
Journal | arXiv.org |
DOIs | |
Publication status | Accepted/In press - 12 Jul 2023 |
MoE publication type | B1 Non-refereed journal articles |
Keywords
- convex optimisation
- fixed pitch propellers
- optimal control
- hybrid power source
- energy management
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Dive into the research topics of 'Integrated supervisory control and fixed path speed trajectory generation for hybrid electric ships via convex optimization'. Together they form a unique fingerprint.Projects
- 1 Finished
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-: CPT Tammi
Tammi, K. (Principal investigator), Ritari, A. (Project Member), Jayawickrama, N. (Project Member), Kivekäs, K. (Project Member), Pirhonen, J. (Project Member) & Sahoo, S. (Project Member)
01/02/2021 → 31/12/2023
Project: Business Finland: Strategic centres for science, technology and innovation (SHOK)