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Klaus Drechsler, Dr. Garrow, Laurie, Luis Rodrigues, and Constantinos Antoniou

View the course trailer: https://www.youtube.com/watch?v=EimqY7-0yRs&t=33s

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View the course trailer: https://www.youtube.com/watch?v=EimqY7-0yRs&t=33s

How can the traffic collapse of the global multimillion cities be prevented? One way out could lead upwards: Urban air transport. By 2030, it is estimated that around 60 percent of humanity will live in cities. If it is possible to shift some of the traffic from the roads to the air, researchers believe this could help to further ensure the basic human need for mobility. But there are still some technical, social, and legal preconditions to be met.

The course gives a first introduction to the relatively new field of Urban Air Mobility, explaining the technical background as well as giving an overview of all other necessities such as air traffic management, public acceptance, and ecological sustainability. This course is primarily aimed at master's students and PhD candidates and young professionals interested in exploring new fields in aerospace.

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What's inside

Syllabus

Introduction - What is Urban Air Mobility?
This first course module gives an overview of all aspects that define "Urban Air Mobility". It explains the concept of Urban Air Mobiltiy as well as all crucial factors, such as vehicle and power train design, infrastructure and vertiport design, air traffic management, the ensuring of safety and airworthiness, sustainability, use cases and concept of operations, city integration and ground transport connection and political support and public acceptance. - Dr Kay Plötner (Bauhaus Luftfahrt Munich).
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Urban Air Mobility from an Industry Perspective
In five chapters, Dr. Markus May presents the approach to the topic of Urban Air Mobility from an industry perspective and shows the ideas of Airbus in this context. Dr. May describes the different design ideas that Airbus has developed with Vahana and the CityAirbus. It also explains how Airbus managed to create a creative workings space in a corporate environment.
Political perspectives
In this module, the Federal Ministry for Digital and Transport presents the national policies and the legal framework for Urban Air Mobility in Germany. The course also discusses the German Federal Government's action plan on "Unmanned Aircraft Systems and Innovative Aviation Concepts", as well as the digital platform “dipul” on unmanned aviation. The course will additionally focus on legal requirements, especially with regard to obstacles for the breakthrough of urban air mobility. The module concludes with an interview on what the future of urban air mobility will look like. // The course lecturers are Dr. Jan Dirks, Dipl.-Ing. Christoph Noack, Rahel Jünemann and Dr. Daniel Phiesel.
Demand Modeling for Urban Air Mobility
This course describes different approaches and data used to model travel demand. An introduction to discrete choice models is provided. An example of demand prediction for an air taxi commuting service is provided. The example uses a discrete choice model and location-based data from a telecommunications company to predict demand in the 40 largest cities in the U.S. /// Dr. Laurie Garrow is an expert in air travel behavior and market analysis. She is a Professor and Co-Director of the Center for Urban and Regional Air Mobility at Georgia Tech and owner of Atlanta Analytics. She has more than 20 years of experience in aviation and previously worked at United Airlines.
Aviation Management
Decision makers at airports and airlines face many challenges and require support to deal with these effectively and appropriately. This gives rise to a variety of difficult and interesting problems. This module looks at three big classes of problems and discusses applicable general solution approaches. // Maximilian Moll’s research focuses on reinforcement learning, one of the three areas in machine learning. His particular interest in this area are combinations with classical methods of operations research as well as application opportunities for prescriptive analytics. The latter pushes past predictive analytics in the sense that it does not only try to predict the future but also to suggest optimum actions to be taken now.He leads the research group “Data-Driven Aviation Management” at Munich Aerospace as well as the working group “Simulation and Optimization of Complex Systems” of the German Society for Operations Research.
Traffic Management for Urban Air Mobility
Dr. Bernd Korn (German Aerospace Center Braunschweig): This module is about understanding how traffic management for urban air mobility could work and what conditions need to be designed in an urban environment. A special focus is on the topics of the U-space in Europe, the design of vertidromes and the functioning of ground infrastructure. In addition, the module ventures a look into the future and describes possible traffic scenarios in our cities.
Urban Air Mobility and Urban Planning
Building safe and efficient Urban Air Mobility (UAM) vehicles is quite complex. It is equally challenging integrating vertiports required for UAM vehicles taking off and landing into the urban fabric. While it is possible to include vertiports in transport and land use planning processes, it is quite difficult finding suitable spaces in dense urban areas (where high demand is to be expected) and, at the same time, gaining public acceptance, reducing negative impact such as noise, negative visual effects and safety issues. This module explains the common transport and land use planning processes that are required for building UAM vertiports. Their integration into and competition with existing modes of transport is discussed as well. Inducing demand and simulation results are also explained. // Professor Rolf Moeckel, Associate Professor (Travel Behavior) at Technical University of Munich since 2021; Rudolf Mößbauer Professorship from September 2015 until August 2021; Post-Doctoral Research at National Center for Smart Growth/University of Maryland, USA from August 2013 until August 2015; Doctorate at Institute of Spatial Planning/University of Dortmund, Germany from Julie 2002 until September 2006 (awarded with the 2007 University Dissertation Prize); Diploma at Department of Spatial Planning/University of Dortmund, Germany from October 1998 until August 2000 and from August 2001 until June 2002; Fulbright Scholar (Visiting Graduate Student) at University of Washington/Seattle, USA from September 2000 until July 2001.
Understanding the Acceptance of Urban Air Mobility
This course covers a range of topics related to determining the demand for previously unavailable modes of transport, such as UAM. Collecting user preferences via the stated preference method and using the results of discrete choice models are some examples. User and societal acceptance are other aspects along with practical examples of ways to assess and interpret them. // Constantinos Antoniou is a Full Professor at the Chair of Transportation Systems Engineering at Technical University of Munich (TUM), Germany. He holds a Diploma in Civil Engineering from NTUA (1995), a MS in Transportation (1997) and a PhD in Transportation Systems (2004), both from MIT. His research focuses on modelling and optimization of transportation systems, data analytics and machine learning for transportation systems. He has a proven track record in attracting competitive funding, both on national and international levels as well as serving as PI for several research projects such as H2020 iDREAMS, MOMENTUM, Drive2thefuture, DFG DVanPool and Trampa. He has authored more than 400 scientific publications, including more than 150 papers in international, peer-reviewed journals as well as 250 publications relating to international conference proceedings, 3 books and has contributed to 20 book chapters.
Air Mobility Trajectory Planning
Professor Rodrigues from Concordia University in Montreal presents the basics of trajectory planning, also, he describes how infrastructure, social acceptance, sustainability, flight data and air traffic management, as well as the regulation and certification serve as most important pillars in air mobility. Besides important considerations, he looks at the system architecture and puts a special focus on various aspects such as flight management or trajectory without collisions.
Economics of Urban Air Mobility
For many decades Urban Air Mobility (UAM) has been addressed through the use of conventional helicopters. However, the emergence of eVTOL vehicles signals that UAM is on the verge of radical transformation regarding its scale of operation, mainly due to reduced noise pollution and an improved cost structure. This module discusses some of the economic conditions (cost, demand, finance) that must be met for market viability of eVTOL vehicles in passenger transportation networks. // Humberto Bettini is Professor at the University of São Paulo, Brazil. He is a B.S. and Ph.D. in Economics, and a M.Sc. in Transportation Engineering. He teaches Cost Accounting, Principles of Economics and Microeconomics, while his research concentrates on competitive and innovative aspects of air transportation and the airline industry.

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Know what's good
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Provides a baseline knowledge in urban air mobility for master's students, PhD candidates and professionals in aerospace
Examines key factors for the success of urban air mobility, including vehicle design, infrastructure, air traffic management, safety, sustainability, and public acceptance
Offers insights from industry experts from Airbus on the development and implementation of urban air mobility solutions
Covers legal and policy frameworks for urban air mobility, including the German Federal Government's action plan and the digital platform “dipul” on unmanned aviation
Explores demand modeling for urban air mobility, using discrete choice models and location-based data to predict demand in major cities

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Activities

Be better prepared before your course. Deepen your understanding during and after it. Supplement your coursework and achieve mastery of the topics covered in Urban Air Mobility with these activities:
Review Introduction to Urban Air Mobility
Review the basic concepts of Urban Air Mobility before the course begins to build a strong foundation.
Show steps
  • Read the course syllabus and introductory module materials.
  • Watch the course trailer to get an overview of the topics covered.
  • Review your notes or study materials from previous courses related to aviation or transportation.
Solve practice problems on Urban Air Mobility
Solving practice problems can help you apply the concepts and theories of Urban Air Mobility to real-world scenarios.
Show steps
  • Find practice problems online or in textbooks.
  • Attempt to solve the problems on your own.
  • Check your answers against the provided solutions.
  • Review the solutions and identify areas where you need improvement.
Participate in a study group or online forum on Urban Air Mobility
Participating in a study group or online forum can help you engage with other students, share ideas, and learn from different perspectives.
Show steps
  • Join a study group or online forum dedicated to Urban Air Mobility.
  • Actively participate in discussions and share your thoughts and insights.
  • Ask questions, provide answers, and engage with other members of the group.
Five other activities
Expand to see all activities and additional details
Show all eight activities
Follow tutorials on Urban Air Mobility software or tools
Following tutorials can help you develop practical skills and gain hands-on experience with Urban Air Mobility tools and technologies.
Show steps
  • Identify software or tools that are commonly used in Urban Air Mobility.
  • Search for tutorials or online courses that teach how to use these tools.
  • Follow the tutorials step-by-step and complete the exercises.
Contribute to an open-source project related to Urban Air Mobility
Contributing to an open-source project allows you to collaborate with others, learn from real-world examples, and make a practical impact on the field.
Show steps
  • Identify open-source projects on platforms like GitHub that are related to Urban Air Mobility.
  • Review the project documentation and identify areas where you can contribute.
  • Fork the project, make your changes, and submit a pull request.
  • Work with the project maintainers to get your changes incorporated.
Write a report on a specific topic in Urban Air Mobility
Writing a report on a specific topic can help you deepen your understanding and develop critical thinking skills.
Show steps
  • Choose a specific topic related to Urban Air Mobility that interests you.
  • Research the topic thoroughly using credible sources.
  • Organize your thoughts and ideas into a logical structure.
  • Write a well-structured report that includes an introduction, body, and conclusion.
  • Proofread and edit your report carefully before submitting it.
Participate in a hackathon or competition related to Urban Air Mobility
Participating in a hackathon or competition can challenge your skills, push your limits, and help you learn from others.
Show steps
  • Find a hackathon or competition focused on Urban Air Mobility.
  • Form a team or work individually on a project that addresses the challenge.
  • Develop and implement a solution within the given time frame.
  • Present your project to a panel of judges and receive feedback.
Research the challenges of urban air traffic management
Refine your understanding of complexities and potential solutions for urban air traffic management
Browse courses on Air Traffic Management
Show steps
  • Identify key challenges, such as airspace congestion, low-altitude navigation, and airspace coordination
  • Review existing regulations and industry practices related to urban air traffic management
  • Explore innovative technologies and approaches being developed to address these challenges

Career center

Learners who complete Urban Air Mobility will develop knowledge and skills that may be useful to these careers:
Aerospace Engineer
Aerospace Engineers are responsible for designing, testing, and manufacturing aircraft, spacecraft, and other vehicles that fly. This course can help Aerospace Engineers to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to design and develop these new vehicles.
Avionics Technician
Avionics Technicians are responsible for installing, maintaining, and repairing the electronic systems on aircraft. This course can help Avionics Technicians to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to work on these new vehicles.
Air Traffic Controller
Air Traffic Controllers are responsible for ensuring the safe and efficient flow of air traffic. This course can help Air Traffic Controllers to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to manage this new type of air traffic.
Civil Engineer
Civil Engineers are responsible for designing and building infrastructure, such as roads, bridges, and airports. This course can help Civil Engineers to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to design and build the infrastructure needed to support this new mode of transportation.
Computer Scientist
Computer Scientists are responsible for designing and developing software systems. This course can help Computer Scientists to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to develop the software systems needed to support this new mode of transportation.
Electrical Engineer
Electrical Engineers are responsible for designing and developing electrical systems. This course can help Electrical Engineers to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to design and develop the electrical systems needed to support this new mode of transportation.
Data Analyst
Data Analysts are responsible for collecting, analyzing, and interpreting data. This course can help Data Analysts to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to analyze the data needed to support this new mode of transportation.
Pilot
Pilots are responsible for flying aircraft. This course can help Pilots to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to fly these new vehicles.
Mechanical Engineer
Mechanical Engineers are responsible for designing and building machines. This course can help Mechanical Engineers to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to design and build the vehicles needed to support this new mode of transportation.
Environmental Engineer
Environmental Engineers are responsible for protecting the environment from pollution. This course can help Environmental Engineers to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to assess the environmental impact of this new mode of transportation.
Policy Analyst
Policy Analysts are responsible for developing and analyzing public policy. This course can help Policy Analysts to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to develop the policies needed to support this new mode of transportation.
Industrial Engineer
Industrial Engineers are responsible for designing and improving production systems. This course can help Industrial Engineers to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to design and improve the production systems needed to support this new mode of transportation.
Transportation Planner
Transportation Planners are responsible for planning and designing transportation systems. This course can help Transportation Planners to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to plan and design the systems needed to support this new mode of transportation.
Urban Planner
Urban Planners are responsible for planning and designing cities. This course can help Urban Planners to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to plan and design the cities needed to support this new mode of transportation.
Project Manager
Project Managers are responsible for planning and executing projects. This course can help Project Managers to understand the challenges and opportunities of Urban Air Mobility, and to develop the skills needed to manage the projects needed to support this new mode of transportation.

Reading list

We've selected seven books that we think will supplement your learning. Use these to develop background knowledge, enrich your coursework, and gain a deeper understanding of the topics covered in Urban Air Mobility.
Provides a comprehensive overview of the theory and practice of aircraft design.
Provides a comprehensive overview of the theory and practice of aircraft systems.

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