Lecture

Aerothermodynamics

This module provides an overview of aerothermodynamics, focusing on thermal and aerodynamic interactions during the Space Shuttle's flight. Students will study the effects of heat transfer and aerodynamic forces on shuttle performance, essential for mission safety and success during atmospheric entry and re-entry phases.


Course Lectures
  • This module introduces students to the origins of the Space Shuttle, providing historical context and insights into its development process. Students will learn about the key figures and decisions that led to its creation. By examining the early concepts and technical challenges, students will appreciate the innovative engineering approaches that shaped the shuttle's design.

  • Space Shuttle History
    Aaron Cohen

    This module delves into the history of the Space Shuttle, detailing its milestones and significant missions. Students will explore the technological advancements that emerged throughout the shuttle program and how these innovations impacted aerospace engineering. The module also highlights the shuttle's role in scientific research and international collaboration in space exploration.

  • This module focuses on the design of the Orbiter's subsystems, exploring the intricate components that ensure its functionality and reliability. Students will learn about the engineering principles behind subsystem integration, including power management, thermal control, and avionics. This knowledge is essential for understanding how different subsystems work together to achieve mission objectives.

  • This module examines the decision-making process involved in the construction of the Space Shuttle. Students will analyze the political, economic, and technical factors that influenced this pivotal choice. By understanding the context of these decisions, students will gain insights into project management and stakeholder engagement in large-scale aerospace projects.

  • This module provides an in-depth look at the Orbiter's structure and its thermal protection system. Students will explore the materials and design considerations that contribute to the shuttle's ability to withstand extreme temperatures during re-entry. Understanding these engineering choices is crucial for ensuring the safety and reliability of orbital missions.

  • This module covers the propulsion systems of the Space Shuttle, specifically the Main Engines. Students will learn about the engineering behind rocket propulsion, including fuel types, combustion processes, and performance metrics. Understanding how these engines operate is vital for comprehending the shuttle's launch and flight dynamics.

  • This module discusses aerodynamics as it pertains to the Space Shuttle's performance across various flight phases. Students will study the effects of airflow and pressure distribution from subsonic to hypersonic speeds. The knowledge gained here is essential for understanding flight stability and control during ascent and re-entry.

  • This module focuses on the landing and mechanical systems of the Space Shuttle. Students will learn about the design and functionality of landing gear, control surfaces, and braking systems. Understanding these systems is crucial for ensuring safe landings and overall mission success.

  • This module examines the Orbital Maneuvering System (OMS), Reaction Control System (RCS), fuel cells, auxiliary power units (APU), and hydraulic systems. Students will learn about the integration and operation of these critical subsystems that support the Shuttle's maneuverability and control during missions, ensuring effective performance in various flight conditions.

  • This module explores the Department of Defense's (DoD) involvement with the Space Shuttle program. Students will analyze the collaboration between NASA and the DoD, focusing on military applications, satellite deployments, and the shuttle's role in national security. Understanding this relationship provides insights into the strategic importance of space missions.

  • This module discusses the utilization of subsystems as a function of different flight phases. Students will learn how various systems operate in the ascent, orbit, and re-entry phases. Understanding this functionality is critical for optimizing performance and ensuring safety throughout the entire mission.

  • This module provides an overview of aerothermodynamics, focusing on thermal and aerodynamic interactions during the Space Shuttle's flight. Students will study the effects of heat transfer and aerodynamic forces on shuttle performance, essential for mission safety and success during atmospheric entry and re-entry phases.

  • This module focuses on the environmental control systems aboard the Space Shuttle. Students will learn about life-support systems, temperature regulation, and air quality control. Understanding these systems is crucial for sustaining crew health and comfort during lengthy missions in space.

  • This module explores the ground operations required for launching the Space Shuttle. Students will learn about the pre-launch checks, vehicle assembly, and the critical role of ground crews in ensuring mission readiness. Understanding these operations is essential for grasping the complexities of space launch procedures.

  • Space Shuttle Accidents
    Sheila Widnall

    This module provides a critical analysis of Space Shuttle accidents, focusing on the causes and consequences of these tragic events. Students will study case studies of notable incidents, learning about safety improvements and lessons learned in aerospace engineering. This knowledge is vital for fostering a culture of safety within the industry.

  • This module covers guidance, navigation, and control systems used in the Space Shuttle. Students will learn about the technologies and algorithms that ensure precise trajectory control and navigation during various mission phases. Mastery of these systems is essential for successful mission execution and safety.

  • Mission Control 1
    Chris Kraft

    This module introduces Mission Control operations for the Space Shuttle. Students will explore the roles and responsibilities of ground control teams during missions, including communication protocols and real-time decision-making. Understanding the dynamics of Mission Control is crucial for appreciating how ground support contributes to mission success.

  • Mission Control 2
    Wayne Hale

    This module continues the exploration of Mission Control operations, emphasizing advanced protocols and technologies used during shuttle missions. Students will examine how data is managed and analyzed by mission controllers to ensure safe and effective operations throughout the flight. This understanding is essential for anyone pursuing a career in aerospace mission management.

  • This module examines the design process related to the Space Shuttle, exploring the methodologies and frameworks utilized in aerospace engineering. Students will learn about the iterative design process, requirements gathering, and stakeholder involvement, which are critical for developing successful aerospace systems.

  • This module explores extravehicular activities (EVA) and robotics utilized during Space Shuttle missions. Students will learn about the technologies enabling astronauts to perform tasks outside the shuttle and the robotic systems that assisted in various operations. Understanding these components enhances knowledge of human-robot interaction in space.

  • This module covers systems engineering principles applied to Space Shuttle payloads. Students will explore how different payloads are integrated into the shuttle, focusing on design, safety, and operational considerations. Understanding these principles is crucial for successful payload management and mission outcomes.

  • This module examines the process of test flying the Space Shuttle, focusing on the strategies used to validate its performance and safety prior to operational missions. Students will learn about pre-flight testing, in-flight evaluations, and data analysis techniques that contribute to ensuring mission success.