1 Semester

60 Hours

Hawthorn, Sarawak

HMS211 Engineering Mathematics 3A

Nil

Credit Points: 12.5 Credit Points

Related Course/s:

A unit of study in Bachelor of Engineering (Mechanical Engineering), and Bachelor of Engineering (Mechanical) / Bachelor of Commerce.

Aims & Objectives:

This unit aims:

• To develop an understanding of the operational behaviour of a wide range of control systems.
• To develop the ability to determine a system's transfer function and performance characteristics using theoretically and experimentally derived data
• To develop the ability to apply classical linear control theory in designing systems and improving steady state and dynamic performance
• To determine transfer functions from response-data for systems having a single input and output

At the completion of this unit students should be able to:

• To develop an understanding of the operational behaviour of a wide range of control systems
• To develop the ability to determine a system's transfer function and performance characteristics using theoretically and experimentally derived data
• To develop the ability to apply classical linear control theory in designing systems and improving steady state and dynamic performance
• To determine transfer functions from response-data for systems having a single input and output

Teaching Methods:

Lectures (24hrs), Tutorials (12hrs), Laboratory (24hrs)

Assessment:

Assignment (20%), Examination (70%), Tests (10%)

Generic Skills Outcomes:

• Ability to apply knowledge of basic science and engineering fundamentals
• Ability to undertake problem identification, formulation and solution
• Ability to utilize a systems approach to design and operational performance
• Ability to function effectively as an individual and in a multi-disciplinary and multi-cultural teams, with the capacity to be a leader or manager as well as an effective team member

Content:

Modelling and performance of control systems

• Overview of on/off and continuous control of mechanical, thermal and chemical systems
• Physical relationships of basic components
• Transfer functions
• Block diagrams and their reduction
• Overall system transfer function

Fluid power control

• Hydraulic and pneumatic components and circuit design
• Design of on/off and electro-hydraulic systems
• Dynamic characteristics

Dynamic response

• Time response - classical solution and Laplace transforms; transient response and steady-state error
• Dominant poles and Root Locus analysis
• Frequency response - Bode diagrams
• Stability analysis in time and frequency domain

Experimental methods

• Determination of transfer functions and stability
  Design and compensation
• Improve steady state and dynamic performance using compensation techniques

Textbooks:

Recommended Reading: