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Unit outline_

MTRX1705: Introduction to Mechatronic Design

Semester 2, 2022 [Normal day] - Remote

This unit of study aims to provide an introduction to the basic hardware elements of mechatronic systems. Basic electrical theory: Ohms law, Kirchoff's voltage and current laws, passive component characteristics (resistors, capacitors and inductors). Number systems and codes; Logic gates and Boolean algebra, universal (NAND) logic gates; Digital arithmetic: operations and circuits, Two's complement addition and subtraction, overflow; Combinational logic circuits; Flip-flops and related devices; Counters and registers, shift register applications; sequential circuits, designs of synchronous, cascadable counters (BCD and binary). Integrated circuit logic families and interfacing; practical issues including, fan out, pull-up/down, grounds, power supplies and decoupling; timing issues, race conditions. Tri-state signals and buses; MSI logic circuits, multiplexers, demultiplexers, decoders, magnitude comparators; Introduction to programmable logic devices. Brushed DC Motors: Introduction to characteristics and control, motor specifications, torque-speed characteristics, power and efficiency, thermal considerations. Introduction to BJTs and FETs as switches. PWM control of DC motors; half- and full-bridge configurations; Feedback and operational amplifiers; selected op-amp applications circuits with an emphasis on sensor and actuator interfacing. The unit of study will include a practical component where students design and implement logic and linear circuits. Purchase of a basic laboratory tool kit as described in classes will be required.

Unit details and rules

Academic unit Aerospace, Mechanical and Mechatronic
Credit points 6
Prerequisites
? 
None
Corequisites
? 
None
Prohibitions
? 
None
Assumed knowledge
? 

None

Available to study abroad and exchange students

No

Teaching staff

Coordinator Donald Dansereau, donald.dansereau@sydney.edu.au
Type Description Weight Due Length
Online task Quiz: Introductory
Online quiz
5% Week 04
Due date: 27 Aug 2022 at 23:00
1 Hour
Outcomes assessed: LO1 LO3
Assignment group assignment Digital Logic Demonstration
Demonstration of various digital logic circuits
10% Week 07 3 hours
Outcomes assessed: LO1 LO3 LO4
Online task Quiz: Sequential Logic
Online quiz
15% Week 07
Due date: 17 Sep 2022 at 23:00
2 hours
Outcomes assessed: LO1 LO3
Assignment group assignment Analog interface demonstration
Analog interface demonstration
20% Week 10 3 hours
Outcomes assessed: LO1 LO2 LO3 LO4
Online task Quiz: Analog Systems
Online quiz
15% Week 10
Due date: 15 Oct 2022 at 23:00
2 hours
Outcomes assessed: LO1 LO2 LO3
Assignment group assignment Major project
Major project (TBA)
20% Week 13 3 hours
Outcomes assessed: LO1 LO2 LO3 LO4
Online task Quiz: Digital Systems
Online quiz
15% Week 13
Due date: 05 Nov 2022 at 23:00
2 Hours
Outcomes assessed: LO1 LO2 LO3
group assignment = group assignment ?

Assessment summary

Lab Demonstrations must be demonstrated on the due day during a student’s scheduled lab session. Each of these assessment tasks must be repeated if a student misses it and is subsequently granted special consideration.

Quizzes must be completed by 23:59 on the due day.

Assessment criteria

The University awards common result grades, set out in the Coursework Policy 2014 (Schedule 1).

As a general guide, a high distinction indicates work of an exceptional standard, a distinction a very high standard, a credit a good standard, and a pass an acceptable standard.

Result name

Mark range

Description

High distinction

85 - 100

 

Distinction

75 - 84

 

Credit

65 - 74

 

Pass

50 - 64

 

Fail

0 - 49

When you don’t meet the learning outcomes of the unit to a satisfactory standard.

For more information see guide to grades.

Late submission

In accordance with University policy, these penalties apply when written work is submitted after 11:59pm on the due date:

  • Deduction of 5% of the maximum mark for each calendar day after the due date.
  • After ten calendar days late, a mark of zero will be awarded.

Academic integrity

The Current Student website provides information on academic integrity and the resources available to all students. The University expects students and staff to act ethically and honestly and will treat all allegations of academic integrity breaches seriously.

We use similarity detection software to detect potential instances of plagiarism or other forms of academic integrity breach. If such matches indicate evidence of plagiarism or other forms of academic integrity breaches, your teacher is required to report your work for further investigation.

Use of generative artificial intelligence (AI) and automated writing tools

You may only use generative AI and automated writing tools in assessment tasks if you are permitted to by your unit coordinator. If you do use these tools, you must acknowledge this in your work, either in a footnote or an acknowledgement section. The assessment instructions or unit outline will give guidance of the types of tools that are permitted and how the tools should be used.

Your final submitted work must be your own, original work. You must acknowledge any use of generative AI tools that have been used in the assessment, and any material that forms part of your submission must be appropriately referenced. For guidance on how to acknowledge the use of AI, please refer to the AI in Education Canvas site.

The unapproved use of these tools or unacknowledged use will be considered a breach of the Academic Integrity Policy and penalties may apply.

Studiosity is permitted unless otherwise indicated by the unit coordinator. The use of this service must be acknowledged in your submission as detailed on the Learning Hub’s Canvas page.

Outside assessment tasks, generative AI tools may be used to support your learning. The AI in Education Canvas site contains a number of productive ways that students are using AI to improve their learning.

Simple extensions

If you encounter a problem submitting your work on time, you may be able to apply for an extension of five calendar days through a simple extension.  The application process will be different depending on the type of assessment and extensions cannot be granted for some assessment types like exams.

Special consideration

If exceptional circumstances mean you can’t complete an assessment, you need consideration for a longer period of time, or if you have essential commitments which impact your performance in an assessment, you may be eligible for special consideration or special arrangements.

Special consideration applications will not be affected by a simple extension application.

Using AI responsibly

Co-created with students, AI in Education includes lots of helpful examples of how students use generative AI tools to support their learning. It explains how generative AI works, the different tools available and how to use them responsibly and productively.

WK Topic Learning activity Learning outcomes
Week 01 1. Intro to mechatronic design; 2. Basic electronics Lecture (2 hr) LO1 LO2
Review mini-lectures for introduction to mechatronic design. Review lab sheets for week 2 lab. Independent study (5 hr) LO1 LO3
Week 02 1. Intro to breadboards and prototyping; 2. Signals and their representation Lecture (2 hr) LO1 LO2 LO4
Basic electrical measurements Computer laboratory (3 hr) LO4
Review mini-lectures on basic logic concepts, review the lab sheet for the week 3 lab. Try building your own circuits at home. Independent study (5 hr) LO1 LO3
Week 03 1. Logic 1 - components for logic; 2. Logic 2 - intro to logic functions Lecture (2 hr) LO1
Generating signals and basic logic circuits Computer laboratory (3 hr) LO1 LO3 LO4
Review mini-lectures on more advanced logic concepts, review the lab sheet for the week 4 lab. Try building your own circuits at home. Independent study (5 hr) LO1 LO3
Week 04 1. Simplifying truth tables; 2. More simplification Lecture (2 hr) LO1
Practical logic design Computer laboratory (3 hr) LO1 LO4
Review lectures for introduction to state machines, digital inputs/outputs. Review the lab notes for week 5. Practice building circuits at home Independent study (5 hr) LO1 LO3 LO4
Week 05 1. Visualising logic tables and Karnaugh maps ; 2. Storing information Lecture (2 hr) LO1 LO3
Introduction to state machines Computer laboratory (3 hr) LO1 LO3 LO4
Review the mini-lectures for capacitors, inductors and op amps. Review the lab notes for week 6. Practice building circuits at home. Independent study (5 hr) LO1 LO2 LO3 LO4
Week 06 1. Sequential logic; 2. State machines Lecture (2 hr) LO1 LO3
Design and development for assignment 1 Computer laboratory (3 hr) LO1 LO3 LO4
Review mini lectures on analog sensors and control. Review the lab sheet for next week. Practice building circuits at home. Independent study (5 hr) LO1 LO2 LO3 LO4
Week 07 1. Real circuits 1; 2. Interfaces 1 Lecture (2 hr) LO1 LO2 LO3
Demonstration of assignment 1 Computer laboratory (3 hr) LO1 LO2 LO3 LO4
Review the mini-lectures on encoders, counters and busses. Review the lab sheet for week 8. Practice building circuits at home Independent study (5 hr) LO1 LO2 LO3 LO4
Week 08 1. Interfaces 2; 2. Real Circuits 2 Lecture (2 hr) LO1 LO2 LO3
Op amp lab Computer laboratory (3 hr) LO2 LO3 LO4
Review mini-lectures on motors and PWM, review the assignment requirements and work on this during the week. Try building your own circuits at home. Independent study (5 hr) LO1 LO2 LO3 LO4
Week 09 Op amp Lecture (2 hr) LO2
Design and development of assignment 2 circuit Computer laboratory (3 hr) LO1 LO2 LO3 LO4
Review mini-lectures on DAC and ADC, review the assignment requirements and work on this during the week. Try building your own circuits at home. Independent study (5 hr) LO1 LO2 LO3 LO4
Week 10 1. Brushless DC motors; 2. Transistors as switches (PWM) Lecture (2 hr) LO2 LO3
Demonstration for assignment 2 Computer laboratory (3 hr) LO1 LO2 LO3 LO4
Review mini-lectures on binary arithmetic, review the assignment requirements and work on this during the week. Try building your own circuits at home. Independent study (5 hr) LO1 LO2 LO3 LO4
Week 11 1. Motor configurations (and datasheets); 2. Feedback control Lecture (2 hr) LO2
Major project week 1 Computer laboratory (3 hr) LO1 LO2 LO3 LO4
Review the online tutorials, work on the major project. Practice building circuits at home. Independent study (5 hr) LO1 LO2 LO3 LO4
Week 12 1. Power supplies; 2. Analogue to digital (and back) Lecture (2 hr) LO1 LO2 LO3
Major project week 2 Computer laboratory (3 hr) LO1 LO2 LO3 LO4
Review the online tutorials, work on the major project. Practice building circuits at home. Independent study (5 hr) LO1 LO2 LO3 LO4
Week 13 1. Review - digital; 2. Review - analog Lecture (2 hr) LO1 LO2 LO3
Demonstration of major project Computer laboratory (3 hr) LO1 LO2 LO3 LO4
Review the online tutorials, work on the major project. Practice building circuits at home. Independent study (5 hr) LO1 LO2 LO3 LO4

Study commitment

Typically, there is a minimum expectation of 1.5-2 hours of student effort per week per credit point for units of study offered over a full semester. For a 6 credit point unit, this equates to roughly 120-150 hours of student effort in total.

Learning outcomes are what students know, understand and are able to do on completion of a unit of study. They are aligned with the University's graduate qualities and are assessed as part of the curriculum.

At the completion of this unit, you should be able to:

  • LO1. analyse and design combinational and sequential logic circuits from basic logic elements
  • LO2. analyse and design applications circuits based on operational amplifiers
  • LO3. read and understand manufacturers' data sheets describing digital and analog electronic circuit elements and DC motors
  • LO4. breadboard, test and troubleshoot practical digital and analog circuits in the laboratory using standard electronics lab instruments and tools.

Graduate qualities

The graduate qualities are the qualities and skills that all University of Sydney graduates must demonstrate on successful completion of an award course. As a future Sydney graduate, the set of qualities have been designed to equip you for the contemporary world.

GQ1 Depth of disciplinary expertise

Deep disciplinary expertise is the ability to integrate and rigorously apply knowledge, understanding and skills of a recognised discipline defined by scholarly activity, as well as familiarity with evolving practice of the discipline.

GQ2 Critical thinking and problem solving

Critical thinking and problem solving are the questioning of ideas, evidence and assumptions in order to propose and evaluate hypotheses or alternative arguments before formulating a conclusion or a solution to an identified problem.

GQ3 Oral and written communication

Effective communication, in both oral and written form, is the clear exchange of meaning in a manner that is appropriate to audience and context.

GQ4 Information and digital literacy

Information and digital literacy is the ability to locate, interpret, evaluate, manage, adapt, integrate, create and convey information using appropriate resources, tools and strategies.

GQ5 Inventiveness

Generating novel ideas and solutions.

GQ6 Cultural competence

Cultural Competence is the ability to actively, ethically, respectfully, and successfully engage across and between cultures. In the Australian context, this includes and celebrates Aboriginal and Torres Strait Islander cultures, knowledge systems, and a mature understanding of contemporary issues.

GQ7 Interdisciplinary effectiveness

Interdisciplinary effectiveness is the integration and synthesis of multiple viewpoints and practices, working effectively across disciplinary boundaries.

GQ8 Integrated professional, ethical, and personal identity

An integrated professional, ethical and personal identity is understanding the interaction between one’s personal and professional selves in an ethical context.

GQ9 Influence

Engaging others in a process, idea or vision.

Outcome map

Learning outcomes Graduate qualities
GQ1 GQ2 GQ3 GQ4 GQ5 GQ6 GQ7 GQ8 GQ9

This section outlines changes made to this unit following staff and student reviews.

In response to feedback from last year, we have established clearer core learning expectations and extensions to challenge more advanced students.

Work, health and safety

In response to the COVID-19 pandemic lectures will be delivered via a combination of videos and Zoom sessions. In-person attendance at lab sessions is preferred, but arrangements will be made for remote work if this is nescessary.

For those attending labs in person, we have made some adjustments to how the Mechatronics Lab is managed:

  • You will only have access to the lab during your scheduled lab sessions.
  • A record of attendance will be kept for contact tracing if required.
  • You must maintain a distance of 1.5 metres from others whenever possible.
  • We have limited student numbers in each lab session to allow this physical distancing to be maintained.
  • The use of hand sanitiser and disinfectant wipes before and after using Lab facilities is mandatory.
  • Personal protective equipment (PPE) in the form of face masks is strongly recommended. Please acquire face masks and bring them to all your classes in the Mechatronics Lab starting from Week 1.
  • Obey all Lab signage including guidelines for sanitising workstations and hardware, PPE, and procedures for entry and exit.
  • If you are feeling unwell, please stay at home.

The COVID situation is still evolving: please monitor email closely for any changes in policy.

Disclaimer

The University reserves the right to amend units of study or no longer offer certain units, including where there are low enrolment numbers.

To help you understand common terms that we use at the University, we offer an online glossary.