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Space Systems Engineering Course by Tonex

Space systems engineering is the process of designing, developing and verifying a space system as an integrated system able to fulfil the objectives of a mission within acceptable technical and programmatic frames.

The step-by-step design process is guided by considering what the space system seeks to achieve.

Space systems engineers design, construct and test aircraft, spacecraft, missiles, satellites and equipment. Space systems engineers are responsible for making sure that all of the subsystems in a spacecraft work together so that the spacecraft meets its objectives.

Space systems engineers maintain the focus on the space system as a whole rather than a collection of functional elements through regular project reviews occurring during subsequent Phase C/D development, production and testing. These serve to ensure the mission remains on track.

Space systems engineering has grown and evolved since the launching of the first U.S. satellite. In would appear that the future of space systems engineering is model based. Traditional systems engineering for a mission is based around documentation. MBSE (Model Based Systems Engineering) seeks to improve on that approach by using digital models instead to describe all the different subsystems and elements, and their relations with each other.

Space systems engineering trends are significant and need the attention of current as well as new personnel involved in the space sector.

Smart propulsion, space robotics, and space traffic management are gaining traction. AI has also become an important modality.

From autonomous systems and data analysis to planetary exploration and beyond, industry use cases showcase the remarkable impact of AI in the realm of space systems engineering.

One of the most popular industry use cases is SpaceX which has deployed an AI autopilot system for its Falcon 9 spacecraft. It allows the rocket to perform extraordinary autonomous feats, like flawless docking with the International Space Station (ISS).

This intelligent system calculates intricate trajectories, considering factors like fuel consumption, atmospheric disturbances, and even the peculiar movement of liquids within the engine.

Space Systems Engineering Course by Tonex

The Space Systems Engineering Course provides a comprehensive understanding of the principles and practices involved in the design, development, and operation of space systems. This course covers various aspects of space systems engineering, including spacecraft design, mission planning, orbital mechanics, and space environment considerations. Through a combination of theoretical knowledge, practical exercises, and case studies, students will gain insights into the challenges and complexities of space systems engineering and develop the skills necessary to design and manage space missions.

Audience:

The Space Systems Engineering Course is suitable for:

  • Professionals involved in the design, development, or operations of space systems.
  • Engineers and technicians working in the aerospace industry.
  • Researchers and scientists involved in space-related projects.
  • Individuals interested in gaining specialized knowledge in space systems engineering for career advancement or space exploration initiatives.

Learning Objectives:

Upon completion of the course, students will be able to:

  • Understand the principles and concepts of space systems engineering.
  • Analyze the space environment and apply orbital mechanics for mission planning.
  • Design and integrate spacecraft subsystems for space missions.
  • Plan and manage space missions from concept development to operations.
  • Perform testing and verification of spacecraft components and systems.
  • Apply mission assurance and risk management techniques in space systems engineering.

Course Outline:

Introduction to Space Systems Engineering

  • Overview of space systems engineering principles and concepts
  • Historical perspective and milestones in space exploration
  • Space mission life cycle and system engineering processes

Space Environment and Orbital Mechanics

  • Characteristics of the space environment and its impact on space systems
  • Orbital dynamics and celestial mechanics
  • Determining orbits and mission trajectories

Spacecraft Design and Subsystems

  • Design considerations for spacecraft structures, power, and propulsion systems
  • Communication and telemetry systems for space missions
  • Onboard data handling, navigation, and control subsystems

Space Mission Planning and Operations

  • Mission analysis and concept development
  • Launch vehicle selection and integration
  • Space mission operations, including ground segment and satellite operations

Spacecraft Testing and Verification

  • Environmental testing of spacecraft components and systems
  • Performance testing and verification methodologies
  • Qualification and acceptance testing of space systems

Spacecraft Mission Assurance and Risk Management

  • Risk assessment and management in space systems engineering
  • Reliability and quality assurance practices for space missions
  • Failure analysis and contingency planning

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