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Universiti Malaysia Pahang

• This course introduces force vector algebra, equilibrium of forces on particle, equilibrium of forces on single rigid body and force analysis on simple frames and machine structures (multi-rigid bodies) and problems involving dry friction. • Course Outcomes • Solve equilibrium of forces on particle • Problems Solve equilibrium of forces on single rigid body problems • Solve equilibrium of forces on structure problems. • Solve problems on centroid and moment of inertia • Course options • Full Time (4 years) • International fees • RM8,950.00 (US$ 2,142) per year • Domestic fees • RM740 per semester • Start date • 31 October 2016, 13 February 2017, 10 April 2017 • Venue • Universiti Malaysia Pahang (UMP) Lebuhraya Tun Razak, Pahang Darul Makmur, KUANTAN, Pahang, 26300, Malaysia • Domestic Entry Requirements • Students should have a pass in A-Level / High School Certificate (HSC) / Diploma holder / Equivalent qualification with at least GRADE C in 3 subjects. Language requirement, Programme specific requirement (Mathematics, Physics, Chemistry, Biology, Science).

More On Mechatronics Engineering Careers

Mechatronics engineers work in all aspects of the development of the smart machine – from design and testing right through to manufacture. This could be in industries like robotics, medical and assistive technology, human-machine interaction, manufacturing, unmanned aerial and ground vehicles and education.

As a Mechatronics engineer

Here are some things you might be expected to do in your job:

• ·         Develop new solutions to industrial problems using mechanical and electronic processes and computer technology.
• ·         Design and build completely new products by integrating various technologies, for example, developing robotic vehicles for underwater exploration.
• ·         Build and test factory production lines introducing automation to improve existing processes.
• ·         Maintain and improve previous industrial and manufacturing processes and designs, for example, robotic lawn mowers and robot floor cleaners.
• ·         Design, develop, maintain and manage high technology engineering systems for the automation of industrial tasks.
• ·         Apply mechatronics or automated solutions to the transfer of material, components or finished goods.
• ·         Apply advanced control systems, which are usually computer-driven.
• ·         Apply electronic and mechanical processes and computers to tasks where the use of human labour may be dangerous (like underwater exploration, mining or forestry).
• ·         Study the feasibility, cost implications and performance benefits of new mechatronics equipment.
• ·         Carry out modelling, simulation and analysis of complex mechanical, electronic or other engineering systems using computers.

Where do Mechatronics engineers work

Mechatronics engineers work in companies that require hi-tech input into what they are developing. They may work in a laboratory, a processing plant or an engineering office but are also research opportunities in emerging fields like bioengineering, nanotechnology and robotics.

You will find Mechatronics engineers in large global enterprises developing futuristic vehicles, challenging defence technology and revolutionising consumer products. They may also work in smaller innovative ‘high tech’ companies supplying software, parts and equipment. They could be product developers, work in manufacturing, or mining or defence industries, and in government and industry research groups.

Mechatronics Engineers may be required to travel to present at a conference or view a new design idea or innovative technology.

‘Aliases’ for Mechatronics engineering

Mechatronics engineering is an emerging field but it has been around in one form or another for some time. Mechatronics engineers have been cleverly disguised as many of the following: Automation Engineer, Control System Engineer, Data Logging Engineer, Instrumentation Engineer, Project Engineer, Software Engineer, Systems Engineer, and Service Engineer.

Career Opportunities in Mechatronics Engineering

Mechatronics engineers (men and women) may be employed in enterprises of any size. There are numerous small and medium sized enterprises that develop and use mechatronics systems where mechatronics engineers are needed. International trends indicate that the need for mechatronics engineers will increase significantly in the foreseeable future.

·         ​Aerospace industry

·         Automotive industry

·         Chemical Processing

·         Computers

·         Communications

·         Education

·         Electronics

·         Healthcare

·         Manufacturing and automation

·         Marine engineering

·         Research and development

Mechatronics Courses and Classes

In the engineering field of mechatronics, students can enroll in degree and certificate programs at colleges and universities. Common courses cover manufacturing, hydraulics and industrial electronics.

Essential Information

Mechatronics is a multidisciplinary engineering field that combines systems design, computer, electronic, mechanical, and control engineering. Students interested in studying mechatronics can gain hands-on experience working with pneumatics, hydraulics, electricity and manufacturing of mechanical parts and machines through degree and certificate programs at colleges and universities. Mechatronics courses might incorporate any or all of the engineering disciplines that the field comprises. You can find the following subjects in your studies:

• Conveyor belts
• Robots
• Conduits
• Hydraulics in machinery
• Bar code
• Stability
• Process control

List of Courses

Introduction to Mechatronics

Students typically study analog and digital electronics in introductory mechatronics courses. Electrical engineering basics, such as sensors, logic gates, op-maps, controllers and microprocessors are usually covered, often through both lecture and hands-on lab components. Introductory courses are typically among the first in-field classes taken in a mechatronics program.

MECHATRONICS ENGINEERING

Control Systems

Students study control systems topics like the creation, repair and troubleshooting of electrical, thermal, flow and mechanical systems. Topics like digital control help prepare students to work with remote controllers for mechanic-to-human interfaces. The use of computers and stability analysis systems to test mechanical systems may also be covered.

Industrial Electronics

Industrial electronics courses often follow guidelines set by the National Center for Integrated Systems Technology (NCIST) advanced manufacturing curriculum. Students learn industrial electronics topics like the use of alternating circuits (AC) and direct currents (DC) in manufacturing. Other areas of study might include pressure, speed motor control, servo-mechanisms, conduits and timers. Troubleshooting and replacing faulty circuits may also be addressed. Students are typically prepared to take industrial electronics courses after completing basic foundational mechatronics coursework.

Manufacturing

Through this course, students gain familiarity with computed numerically controlled (CNC) machines, conveyor belts, robots and other machines used in manufacturing. Coursework might include examining the reliability of machines and products, comprehension of manufacturing techniques, testing and diagnosing flawed manufacturing components and consideration of environmental factors. Class projects might include the creation of a robot-based bar code or other tasks that use a variety of engineering skills. This course is typically aimed at students who want to work in the manufacturing and sales field of mechatronics.

Hydraulics

This course focuses on topics like the diagnostics, repair and replacement of hydraulic components in a manufacturing machine. Coursework typically focuses on the construction and uses of hydraulics in machinery. Through lab work, students construct hydraulics and learn the assembly and disassembly of these components. Skills and techniques learned in this course may be applicable in many of the engineering areas in a mechatronics curriculum.

Why study Mechatronics Engineering?

Mechatronics engineers design or select sensors and actuators, develop control algorithms and use or develop advanced functional materials for the design of mechanical systems such as chassis stabilising systems, anti-lock brakes, engine control units, disk drives, cameras, service and surgical robots and artificial hearts. Very often mechatronics engineers are generalists rather than specialists.

Introduction

Mechatronics engineering is concerned with the design of automated machines. It is strongly based on a combination of mechanical, electronics and software engineering, but is a distinctly different discipline to all three.

Mechatronics engineering differs from automation engineering in that its practitioners have a deep understanding of the performance analysis and design of complex machines. It differs from mechanical engineering in that its practitioners understand how automations can be designed and integrated into a machine very effectively to achieve an outcome. A on certain domain specific elements such as the mechanical system or the software. An understanding mechatronics engineer is capable of thinking holistically about a mechatronics system, rather than focussing of how to model a system from a power perspective (rather than thinking in terms of voltages or forces) is fundamental to this.

Many mechatronics engineers work with the electronic instrumentation and computer control systems which nearly all machinery relies on for efficient and reliable operation. We take it for granted that automatic systems monitor process plants for leaks and faults, and keep the plant operating all the year round. Mechatronics engineers build and design these systems and need expertise in computing and electronics, core mechanical engineering knowledge, and the ability to bring these together to make working systems which meet the safety and reliability levels we take for granted.

Mechatronics engineers also have roles in project engineering, reliability engineering and power engineering where their cross-disciplinary knowledge gives them an edge on mechanical or electrical engineers.  Mechatronics engineers can work with electrical and mechanical systems together and solve problems that cross discipline boundaries.  Their strength in IT, computer hardware and networking as well as software also helps them to be very versatile problem solvers. Writing and testing software for specialised computer systems and micro-controllers forms a major part of the work of many mechatronics engineers.

Like all engineers, technical collaboration takes most of a mechatronics engineer’s working time.  Mechatronics engineering, by its nature, involves extensive collaboration with people working in more traditional engineering disciplines.  Skills such as teaching, persuasion and negotiation in a technical context are valuable for mechatronics engineers.  Technical coordination, gaining the willing and conscientious collaboration of other people without organisational authority is especially valuable.

Leading mechatronics engineering academics across Australia agreed on the following more formal definition for future revisions of the Engineers Australia competency standards:

“Mechatronics engineering is the engineering discipline concerned with the research, design, implementation and maintenance of intelligent engineered products and processes enabled by the integration of mechanical, electronic, computer, and software engineering technologies”

Specific expertise areas include:

• Artificial Intelligence Techniques
• Avionics
• Computer Hardware and Systems
• Control Systems
• Data Communications and Networks
• Dynamics of Machines and Mechanisms
• Electromagnetic Energy Conversion
• Electronics
• Embedded & Real-time Systems
• Fluid Power and other Actuation Devices
• Human-Machine Interface Engineering and Ergonomics
• Industrial Automation
• Measurement, Instrumentation and Sensors
• Mechanical Design and Material Selection
• Mechatronics Design and System Integration
• Modelling and Simulation
• Motion Control
• Power Electronics
• Process Management, Scheduling, Optimization, and Control
• Process Plant and Manufacturing Systems
• Robotics
• Signal Processing
• Smart Infrastructure
• Software Engineering
• Systems Engineering
• Thermofluids

At the most fundamental level  lies the ability to design, model and test “simple” mechatronics systems comprising mechanical and electrical components connected to a single microcontroller or PLC. An example is a DC motor connected to a gearbox driving a load mass with sensors to enable feedback control of position and speed. Mechatronics engineers are trained to have insight into how larger scale systems may be constructed though application of these fundamental skills. For example they are able to design more complex systems by networking microcontrollers together to achieve distributed control over a larger mechatronics system. Structured systematic design techniques are also important, together with conversation skills to jointly develop solutions with clients in terms of mechatronics engineering possibilities.  Knowing how to conduct rigorous systematic testing is also critically important.

Other areas of specific expertise relevant to the practice of Mechatronics engineering are found within the disciplines of Aeronautical, Engineering, Biomedical Engineering, Communications Engineering, Computer Systems Engineering, Electrical Engineering, Electrical Power Engineering, Electronic engineering, Industrial Engineering, Instrumentation and Control Engineering, Manufacturing and Production Engineering, Mechanical Engineering, Software Engineering and Space Engineering.

There are fewer job vacancies labelled “mechatronics engineer” than other disciplines.  There are still not many experienced mechatronics engineers available, so most employers would not want to restrict the field of applicants by calling only for a mechatronics engineer.  Mechatronics engineering positions are often advertised as:

• Asset Management engineer
• Automation engineer
• Data Logging engineer
• Electrical/Electronic engineer
• Electro mechanical engineer
• Instrumentation engineer
• Maintenance engineer
• Plant engineer
• Process engineer
• Process monitoring and plant systems engineer
• Project engineer
• Software engineer
• Systems engineer

Mechatronics engineering is a formally accredited branch of engineering in Australia, Japan, France, the Netherlands, Germany and several other countries.  However in the USA and Britain competing professional engineering organizations took a decade or more agree on who should provide accreditation and relatively few courses has been accredited so far.  Mechatronics engineers in these countries tend to emerge from post-graduate masters programs after a first degree in mechanical or electrical engineering.

Overview

Mechatronics engineering is a synergistic combination of precision mechanical engineering, electronics and computer systems. A typical mechatronics system is characterized by close integration of the mechanical components, electronic sensors, mechanical and electrical actuators and computer controllers. Mechatronics engineering is an interdisciplinary engineering field that specializes in the control of advanced hybrid systems. These systems are found in numerous industry sectors where mechanical and electronic engineering are interfaced with computer systems, such as aerospace, automotive, chemical processing, computers, communications, electronics, healthcare, manufacturing and mining.

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