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Bachelor of Mechatronics Engineering (Honours)
Newcastle City
INTAKE: Jul & Feb
Program Overview
The Bachelor of Mechatronics Engineering (Honours) program at the University of Newcastle, Australia, is designed to equip students with the knowledge and skills needed to design, analyze, and control advanced mechatronic systems. Mechatronics integrates mechanical engineering, electrical engineering, computer science, and control systems to create intelligent and autonomous systems with enhanced functionality and performance. Students in this program learn about topics such as robotics, automation, embedded systems, sensors and actuators, and machine learning. The program emphasizes hands-on learning, project-based coursework, and industry-relevant experiences to prepare graduates for careers in fields such as robotics, automation, automotive systems, and smart manufacturing.
Curriculum: The curriculum of the Bachelor of Mechatronics Engineering (Honours) program covers a broad range of subjects relevant to mechatronics engineering. Students study core engineering disciplines such as mechanical engineering, electrical engineering, and computer science, as well as specialized topics such as control theory, signal processing, and artificial intelligence. They learn about mechatronic system design, modeling and simulation, embedded systems programming, and sensor and actuator technologies. The program includes laboratory work, design projects, and industry placements to provide students with practical experience and skills development. The curriculum is regularly updated to reflect the latest advancements in mechatronics and industry best practices.
Research Focus: Research is a fundamental component of the Bachelor of Mechatronics Engineering (Honours) program, with opportunities for students to engage in cutting-edge research projects under the guidance of faculty members. Students have the opportunity to explore topics such as robotics, automation, machine vision, autonomous vehicles, and human-robot interaction. Through research projects, students develop critical thinking skills, problem-solving abilities, and the ability to apply engineering principles to real-world challenges. Research experiences also expose students to the latest developments in mechatronics technology and prepare them for careers in research and development.
Industry Engagement: The University of Newcastle fosters strong industry engagement in its Bachelor of Mechatronics Engineering (Honours) program, providing students with opportunities to gain practical experience and industry insights. Through internships, industry placements, and industry-sponsored projects, students have the opportunity to work with leading companies in the mechatronics sector. They gain hands-on experience, develop professional networks, and apply their skills to real-world engineering projects. The university also collaborates with industry partners to develop relevant curriculum, provide guest lectures, and offer industry-sponsored scholarships and awards to students.
Global Perspective: As a globally focused institution, the University of Newcastle encourages students in the Bachelor of Mechatronics Engineering (Honours) program to develop a global perspective on mechatronics engineering and technology. The program incorporates elements of international engineering standards, global trends in automation and robotics, and cross-cultural communication skills. Students have the opportunity to participate in international study tours, exchange programs, or collaborative research projects with partner institutions around the world. By gaining exposure to different engineering practices, cultural perspectives, and global challenges, students develop the skills and mindset needed to work effectively in a globalized world.
Location
Newcastle City
Score
IELTS 6
Tuition Fee
AUD 39310
Undergraduate Entry Requirements
Academic Qualifications: Applicants for undergraduate programs typically require a minimum academic achievement of 65% or above in their previous academic qualifications.
English Language Proficiency:
- IELTS: Overall band score of 6.0 or 6.5 with a minimum of 5.5 in each component.
- TOEFL: Overall score of 79 with a minimum of 12 in each section.
- PTE (Pearson Test of English): Overall score of 58 with a minimum of 50 in each section.
Students must provide:
- academic marksheets & transcripts
- letters of recommendation
- a personal statement - SOP
- passport
- other supporting documents as required by the university.
It's important to note that entry requirements can vary by program and may change over time. Additionally, some programs may have additional requirements, such as interviews, portfolios, or work experience.
The University of Newcastle, Australia, is making high-quality education accessible to international students. One of the ways it achieves this is by offering a wide range of scholarships designed to support and reward academic excellence, diversity, and achievement among international students.
International Excellence Scholarships: These scholarships are aimed at high-achieving international students who have a strong academic record. They provide financial assistance to cover a portion of tuition fees, making quality education more affordable.
Country-Specific Scholarships: The University of Newcastle offers scholarships tailored to specific countries, ensuring students from various regions have the opportunity to study in Australia. These scholarships may vary in terms of eligibility criteria and benefits.
Women in STEM Scholarships: To promote gender diversity in STEM fields, the university provides scholarships specifically for women pursuing degrees in science, technology, engineering, and mathematics.
Graduates of the Bachelor of Mechatronics Engineering (Honours) program from the University of Newcastle, Australia, are well-prepared to pursue diverse and rewarding career opportunities in various industries that rely on advanced mechatronic systems.
Robotics Engineer: Graduates can work as robotics engineers, designing, developing, and implementing robotic systems for various applications such as manufacturing, healthcare, agriculture, and defense. They design robot kinematics, develop control algorithms, and integrate sensors and actuators to create intelligent and autonomous robots. Robotics engineers work for robotics companies, research institutions, and government agencies, advancing the field of robotics and automation.
Automation Engineer: Graduates can pursue careers as automation engineers, designing and optimizing automated systems and processes in industries such as manufacturing, automotive, aerospace, and logistics. They develop control systems, program PLCs (Programmable Logic Controllers) and SCADA (Supervisory Control and Data Acquisition) systems, and integrate sensors and actuators to automate manufacturing operations and improve efficiency and productivity. Automation engineers work for manufacturing companies, system integrators, and automation solution providers.
Control Systems Engineer: Graduates can work as control systems engineers, designing and analyzing control systems for mechatronic and robotic applications. They develop mathematical models, design feedback control algorithms, and implement control strategies to regulate the behavior and performance of complex systems. Control systems engineers work in industries such as aerospace, automotive, power generation, and process control, ensuring the stability, reliability, and safety of control systems.
Embedded Systems Engineer: Graduates can pursue careers as embedded systems engineers, designing and programming embedded systems for mechatronic applications such as robotics, IoT (Internet of Things) devices, and consumer electronics. They develop software for microcontrollers, design hardware interfaces, and integrate sensors and actuators to create intelligent and connected devices. Embedded systems engineers work for technology companies, consumer electronics manufacturers, and IoT startups, developing innovative products and solutions.
Mechatronics Engineer: Graduates can work as mechatronics engineers, specializing in the design, development, and integration of mechatronic systems and components. They work on interdisciplinary projects that involve mechanical, electrical, and software engineering, collaborating with engineers from different disciplines to create complex systems with enhanced functionality and performance. Mechatronics engineers work in industries such as automotive, aerospace, biomedical, and renewable energy, applying their skills to solve diverse engineering challenges.
Research and Development Engineer: Graduates can pursue careers as research and development (R&D) engineers, working on advanced technology projects in industries such as robotics, automation, and advanced manufacturing. They conduct research, design experiments, and develop prototypes to test new concepts and technologies. R&D engineers work for technology companies, research institutions, and government agencies, pushing the boundaries of innovation and driving technological advancement in mechatronics and related fields.
Systems Integration Engineer: Graduates can work as systems integration engineers, integrating mechatronic systems and components into larger systems and platforms such as vehicles, aircraft, and industrial automation systems. They design interfaces, develop communication protocols, and ensure compatibility and interoperability between different subsystems and components. Systems integration engineers work for engineering firms, system integrators, and OEMs (Original Equipment Manufacturers), ensuring the seamless integration and operation of complex systems.
Consulting Engineer: Graduates can work as consulting engineers, providing expert advice and engineering solutions to clients on mechatronic projects and initiatives. They work for engineering consulting firms, advising clients in industries such as manufacturing, transportation, healthcare, and defense. Consulting engineers conduct feasibility studies, develop technical specifications, and oversee project implementation, helping clients optimize their operations and achieve their engineering objectives.
Entrepreneur: Graduates with entrepreneurial ambitions can start their own businesses or technology startups, leveraging their mechatronics expertise to develop innovative products and solutions. Entrepreneurs in the mechatronics field can explore opportunities in areas such as robotics, automation, IoT, and smart devices. They may develop new products, patent their inventions, and commercialize their ideas, creating value and addressing market needs in diverse industries.
Academic and Researcher: Graduates can pursue careers in academia and research, conducting research and teaching at universities, research institutes, and technical colleges. They can contribute to the advancement of knowledge in mechatronics engineering through research projects, publications, and academic collaborations. Academic and researchers also mentor students, supervise graduate research projects, and contribute to the development of the next generation of mechatronics engineers.
