Spacecraft Electrical Energy Systems: Architectures, Design, and Optimization
Author(s): Reinhard Röder (Author)
- Publisher: Wiley
- Publication Date: July 27 2026
- Edition: 1st
- Language: English
- Print length: 448 pages
- ISBN-10: 1394376960
- ISBN-13: 9781394376964
Book Description
Top-down approach to EPS architecture for spacecraft electrical power systems
Filling a gap in the existing literature, Spacecraft Electrical Energy Systems guides readers through the design and development of Electrical Power Systems (EPS) for spacecraft using a top-down approach.
The book opens by introducing the function of EPS for spacecraft and giving an overview of the different types of EPS technologies available. It then takes readers through the detailed design and development parameters for EPS, with a focus on requirements and standards from the ECSS and NASA, enabling readers to make more informed decisions as they work on real-world spacecraft projects. It explains the functionality of all common types of spacecraft power bus technologies and compares their advantages and disadvantages.
Spacecraft Electrical Energy Systems also discusses:
- Methods of generation of electrical power and energy, covering photovoltaics, solar dynamics, nuclear power, radioisotope thermal generation, and regenerative fuel cells
- Specific EPS design constraints, including compilation and management of the system power budget and power and energy margins
- Solar cell types for space flight, including silicon, gallium arsenide, multiple junction, thin film, indium phosphide, and tandem
- Environmental loads on solar arrays in space, covering thermal cycles, stress on cell interconnectors, debris and micrometeoroids, particle flux, and radiation
- Lithium-based energy storage, covering lithium-ion, lithium-ion-polymer, solid-state lithium-ion, and lithium-sulfur
Spacecraft Electrical Energy Systems delivers important cutting-edge knowledge for professional aerospace engineers, as well as electrical engineers working within the space industry and early-career engineers who are new to the field. The book can also be used by students and instructors in graduate-level specialty courses.
Editorial Reviews
From the Back Cover
Top-down approach to EPS architecture for spacecraft electrical power systems
Filling a gap in the existing literature, Spacecraft Electrical Energy Systems guides readers through the design and development of Electrical Power Systems (EPS) for spacecraft using a top-down approach.
The book opens by introducing the function of EPS for spacecraft and giving an overview of the different types of EPS technologies available. It then takes readers through the detailed design and development parameters for EPS, with a focus on requirements and standards from the ECSS and NASA, enabling readers to make more informed decisions as they work on real-world spacecraft projects. It explains the functionality of all common types of spacecraft power bus technologies and compares their advantages and disadvantages.
Spacecraft Electrical Energy Systems also discusses:
- Methods of generation of electrical power and energy, covering photovoltaics, solar dynamics, nuclear power, radioisotope thermal generation, and regenerative fuel cells
- Specific EPS design constraints, including compilation and management of the system power budget and power and energy margins
- Solar cell types for space flight, including silicon, gallium arsenide, multiple junction, thin film, indium phosphide, and tandem
- Environmental loads on solar arrays in space, covering thermal cycles, stress on cell interconnectors, debris and micrometeoroids, particle flux, and radiation
- Lithium-based energy storage, covering lithium-ion, lithium-ion-polymer, solid-state lithium-ion, and lithium-sulfur
Spacecraft Electrical Energy Systems delivers important cutting-edge knowledge for professional aerospace engineers, as well as electrical engineers working within the space industry and early-career engineers who are new to the field. The book can also be used by students and instructors in graduate-level specialty courses.
About the Author
Reinhard Röder is a space power engineering consultant with over 35 years of experience in spacecraft design and development. His industry work has focused on electrical power system engineering at the spacecraft level. He frequently conducts workshops on electrical power systems (EPS). He has contributed to various leading industry texts.
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