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Students
Tuition Fee
Start Date
Medium of studying
Duration
Program Facts
Program Details
Degree
Masters
Major
Biomedical Engineering | Mechatronics | Robotics Engineering
Area of study
Engineering
Course Language
English
About Program

Program Overview


The MS in Robotics and Autonomous Systems (Biomedical Engineering) combines robotics, controls, and AI to address healthcare challenges. Students gain expertise in biomedical applications, preparing them for careers in medical device development, rehabilitation robotics, and research. The program emphasizes hands-on learning, research opportunities, and professional skill development. Graduates are equipped to make significant contributions to the advancement of technology in the biomedical field.

Program Outline


Degree Overview: The Master of Science (MS) in Robotics and Autonomous Systems (Biomedical Engineering) is a multidisciplinary program emphasizing robotics, controls, autonomous systems, artificial intelligence, and related fields. It caters specifically to students seeking a focus on applications in biomedical engineering.


Objectives:

  • Equip graduates with the expertise to tackle rapidly evolving fields like robotics and autonomous systems within the context of biomedical engineering and medicine.
  • Contribute to the advancement of health and scientific discovery through technology-driven solutions in the biomedical domain.

Program Description:

This advanced degree program delves into the intersection of technology and medicine, tackling vital challenges in healthcare and scientific advancement. Students gain proficiency in cutting-edge fields like robotics, controls, and autonomous systems, emphasizing their application within the biomedical engineering domain. The program equips graduates with the skills and knowledge necessary to translate theoretical concepts into practical solutions for real-world problems in healthcare and medical research.


Outline:


Coursework:

  • The program necessitates the completion of 30 credit hours, with the option of pursuing a culminating experience in the form of a portfolio, thesis, or applied project course.
  • Required Core: Students must complete 6 credit hours of core courses, including either EGR 501/MAE 501 (Applied Linear Algebra) or EGR 545/MAE 547/RAS 545 (Robotic Systems I).
  • Concentration: An additional 6 credit hours are dedicated to concentration-specific courses relevant to biomedical engineering.
  • Electives or Research: Students can choose between 12-18 credit hours of electives or research opportunities to further personalize their learning experience.
  • Students acquire a strong foundation in the core principles of robotics and control systems before delving into advanced topics specific to biomedical applications. The program culminates in a capstone project or thesis, allowing students to apply their acquired knowledge to a real-world problem.

Modules:

  • The program offers various modules covering topics such as:
  • Robotic Systems
  • Artificial Intelligence
  • Biomedical Engineering Applications
  • Control Systems
  • Design and Development of Medical Devices
  • Robotics and Healthcare
  • Autonomous Systems in Medicine
  • Human-Robot Interaction
  • Surgical Robotics
  • Rehabilitation Robotics
  • Biomechanics

Assessment:


Assessment methods:

  • The program utilizes various assessment methods to evaluate student learning, including:
  • Exams
  • Assignments
  • Projects
  • Presentations
  • Portfolios
  • Theses (for thesis-track students)

Assessment criteria:

  • Student performance is evaluated based on their understanding of concepts, application of knowledge, problem-solving skills, critical thinking abilities, innovation, and communication skills.

Teaching:


Teaching methods:

  • The program employs diverse teaching methods to cater to different learning styles, including:
  • Lectures
  • Interactive sessions
  • Group projects
  • Laboratory exercises
  • Guest lectures
  • Seminars
  • Workshops
  • The program emphasizes hands-on learning through laboratory exercises and project-based coursework.

Faculty:

  • The program features a team of experienced faculty members with expertise in robotics, autonomous systems, biomedical engineering, and related fields.
  • Faculty members are actively involved in research, ensuring students are exposed to cutting-edge advancements and knowledge.

Unique approaches:

  • The program fosters a collaborative learning environment where students work together on projects and assignments.
  • The program provides opportunities for students to engage in research with faculty members, contributing to the advancement of knowledge in their chosen field.
  • The program emphasizes the development of professional skills, such as communication, teamwork, and project management.

Careers:


Career paths:

  • Graduates of this program are prepared for careers in various industries, including:
  • Manufacturing
  • Transportation
  • Aerospace
  • Defense
  • Healthcare
  • Medical device development
  • Pharmaceutical research
  • Rehabilitation robotics
  • Academia
  • The program also prepares graduates for further studies at the doctoral level.

Career opportunities:

  • Specific career opportunities include:
  • Robotics engineer
  • Autonomous systems engineer
  • Biomedical engineer
  • Medical device developer
  • Research scientist
  • Rehabilitation specialist
  • Robotics researcher
  • Academia faculty member

Outcomes:

  • The program equips graduates with the necessary skills and knowledge to excel in their chosen careers.
  • Graduates are prepared to make significant contributions to the advancement of technology in the biomedical field.
  • The program prepares graduates for leadership roles in various industries and research settings.

Other:

  • The program is approved for an Optional Practical Training (OPT) extension for up to 36 months, providing international students with valuable work experience in the United States.
  • # Summary:
  • The MS in Robotics and Autonomous Systems (Biomedical Engineering) is a comprehensive program designed to equip students with the knowledge and skills to excel in this rapidly evolving field. The program offers a unique blend of theoretical and practical learning, providing students with the opportunity to tackle real-world challenges in healthcare and medical research.
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Admission Requirements

Entry Requirements:


EU Home Students:

  • Bachelor's or master's degree in engineering, science, mathematics, or a related field from a regionally accredited institution.
  • Minimum cumulative GPA of 3.00 in the last 60 hours of the first bachelor's degree program or a minimum cumulative GPA of 3.00 in an applicable master's degree program.

International Overseas Students (outside the EU):

  • Bachelor's or master's degree in engineering, science, mathematics, or a related field from a regionally accredited institution.
  • Minimum cumulative GPA of 3.00 in the last 60 hours of the first bachelor's degree program or a minimum cumulative GPA of 3.00 in an applicable master's degree program.
  • Proof of English proficiency.

Additional Requirements for All Applicants:

  • Graduate admission application and application fee.
  • Official transcripts.
  • Letter of intent or written statement.
  • Professional resume.

Language Proficiency Requirements:

Applicants whose native language is not English must provide proof of English proficiency regardless of their current residency. This can be demonstrated through:

  • TOEFL score of at least 80.
  • IELTS score of at least 6.5.
  • PTE Academic score of at least 53.
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