Mechatronics

Graduate profile: (What qualities/additional skills learners will achieve by taking this course?)
Imagine it, engineer it, and make it go. Create a micro-computer-controlled Mars Autonomous Rover Vehicle (MARV) to pilot around an obstacle course. Robotics provides students with opportunities to question, think about, and create technological tools, rather than just becoming passive users of technology.

Possible Career/ Vocational Pathway(s): (What career pathways are related to this course?)
https://www.careers.govt.nz/searchresults?q=mechatronics

Learning outcomes/Assessment links:

NCEA Level	Standard Number	Standard Descriptor	Credits	Assessment	Literacy	Numeracy	Vocational Pathways
1	AS91064 05	Design and Visual Communication 1.31 - Produce instrumental, multi-view orthographic drawings that communicate technical features of design ideas	3	External	No	Yes	C&I, M&T, CI
1	AS91065 05	Design and Visual Communication 1.32 - Produce instrumental paraline drawings to communicate design ideas	3	External	No	Yes	C&I, M&T, CI
1	AS91881 01	Digital Technologies 1.5 - Develop an electronics outcome	6	Internal	Yes L1Lit	No	C&I, CI
1	AS91883 01	Digital Technologies 1.7 - Develop a computer programme	4	Internal	No	No	C&I, CI
1	AS91884 01	Digital Technologies 1.8 - Use basic iterative processes to develop a digital outcome	6	Internal	Yes L1Lit	No	C&I, M&T, PI, SI, SC, CI
1	AS91047 04	Generic Technology 1.4 - Undertake development to make a prototype to address a brief ***	6	Internal	No	No	C&I, M&T, PI, CI
		Total Available Credits	28***

Note: Courses are subject to change with the review of courses at the end of each year. Course is endorsable. *** Optional standards = Total of 28 available credits

Progression: (What courses does this course lead to?)
The course will take students through the basic concepts of electronics, DC electrical systems, control programming and interfacing. Students will learn to control simple motors and actuators, and to interface with simple sensors in the building of a robotic device. They will design and build using the 3D printer and the laser cutter to create the body of their MARV.

Students should have the ability to work in a team. Each student will be provided with an individual computer and will share robotics equipment. Preference is given to students who achieved in Year 10 Mechatronics course, have ability in Mathematics or Science and who have a good attendance record and work ethic.

Vocational/Industry links: (What vocational or industry learning experiences will be included in this course?)
https://www.careers.govt.nz/searchresults?q=mechatronics

Contextualised contexts: (What local, cultural, real-life content is involved in this course?)
This course provides an introduction to the world of mechatronics which is more and more a part of our day to day lives with drones and remote vehicles being used in areas as diverse as agriculture, search and rescue, film and television and underwater recovery of resources.

Teaching and Learning Approaches: (How will I learn in this course?)
Students will combine hands-on learning through the creation of their own project bolstered with teaching, through a combination of online assignments and face to face instruction,to provide the theory needed to progress the various stages of their project.

Resource requirements: (What resources will I need to have to learn in this course?)
Students will require a personal USB Drive.

Course Outline

Term 1 02 February - 16 April 2021 (10/11 weeks)	Term 2 03 May - 09 July 2021 (10 weeks)	Term 3 26 July - 01 October 2021 (10 weeks)	Term 4 18 October - early November 2021 (4 weeks)
Research and develop a concept and 3D model of a MARV (Mars Autonomous Rover Vehicle) Produce orthographic and isometric exploded drawings of MARV design Produce SLT 3D print files or laser cut files for producing prototype MARV	Manufacture prototype MARV Develop and demonstrate an understanding of intermediate control programming and interfacing Design, build and test the electronics of MARV Design, build and test Stage 1 Code of MARV	Iteratively build, programme, test and refine prototype code Evaluate projects; its fitness for purpose against the brief	Complete portfolio of work and documentation of project
KEY DATES: Week 6: Rendered image of concept Week 8: Completed Model, orthographic and isometric drawing Week 10: STL and cut files for printing	KEY DATES: Week 5: MARV prototype assembled Week 6: Prototype MARV complete and documented Week 9: Electronics complete and documented	KEY DATES: Week 3: Stage 1 code commpleted and tested with documentation Week 7: Stage 2 code completed and tested with documentation Week 10: - Completion of Project outcome	KEY DATES: Week 3: Completion of project documentation

Term 1
02 February - 16 April 2021
(10/11 weeks)

Term 2
03 May - 09 July 2021
(10 weeks)

Term 3
26 July - 01 October 2021
(10 weeks)

Term 4
18 October - early November 2021
(4 weeks)

Research and develop a concept and 3D model
of a MARV (Mars Autonomous Rover Vehicle)
Produce orthographic and isometric exploded drawings of MARV design
Produce SLT 3D print files or laser cut files for producing prototype MARV

Manufacture prototype MARV
Develop and demonstrate an understanding of intermediate control programming and interfacing
Design, build and test the electronics of MARV
Design, build and test Stage 1 Code of MARV

Iteratively build, programme, test and refine prototype code
Evaluate projects; its fitness for purpose against the brief

Complete portfolio of work and documentation of project

KEY DATES:

Week 6: Rendered image of concept
Week 8: Completed Model, orthographic and
isometric drawing
Week 10: STL and cut files for printing

KEY DATES:

Week 5: MARV prototype assembled
Week 6: Prototype MARV complete and documented
Week 9: Electronics complete and documented

KEY DATES:

Week 3: Stage 1 code commpleted and tested with documentation
Week 7: Stage 2 code completed and tested with documentation
Week 10: - Completion of Project outcome

KEY DATES:

Week 3: Completion of project documentation

______________________________________________________________________________________________________________________________________________________________________________________________________________________

Graduate profile: (What qualities/additional skills learners will achieve by taking this course?)
Imagine it, engineer it, and make it go. Further develop skills with micro-computer controlled robotic vehicles to solve a problem. Create a robot that will work as part of a team. Robotics provides students with opportunities to question, think about, and create technological tools, rather than just becoming passive users of technology.

Possible Career/ Vocational Pathway(s): (What career pathways are related to this course?)
https://www.careers.govt.nz/searchresults?q=mechatronics

Learning outcomes/Assessment links:

NCEA Level	Standard Number	Standard Descriptor	Credits	Assessment	Literacy	Numeracy	Vocational Pathways
2	AS91338 03 ***	Design & Visual Communications 2.31 - Produce working drawings to communicate technical details of a design	4	External	No	No	C&I, M&T, PI, CI
2	AS91890 01	Digital Technologies and Hangarau Matihiko 2.1 - Present a summary of developing a digital outcome	6	Internal	Yes L1LIT	No	C&I, M&T, PI, SI, SC, CI
2	AS91894 01	Digital Technologies and Hangarau Matihiko 2.5 - Use advanced techniques to develop an electronic outcome	6	Internal	No	No	C&I, M&T, CI
2	AS91896 01	Digital Technologiesand Hangarau Matihiko 2.7 - Develop an advanced computer programme	6	Internal	No	No	C&I, M&T, CI
2	AS91897 01	Ditigal Technologies and Hangarau Matihiko 2.8 - Use advanced iteractive processes to plan and develop a digital outcome	6	Internal	No	No	C&I, M&T, PI, SI, SC, CI
2	AS91899 01 *******	Digital Technologies and Hangarau Matihiko 2.10 - Present a summary of developing a digital outcome	3	External	Yes L1LIT	No	C&I, M&T, PI, SI, SC, CI
		Total Available Credits	31

Note: Courses are subject to change with the review of courses at the end of each year and as the new digital standards become more clearly defined. ***Options for endorsement

Progression: (What courses does this course lead to?)
The course will take students through the more advanced concepts of electronics, DC electrical systems, control programming and interfacing. Students will learn to control motors and actuators, interface with sensors and other robots in the enhancement of a robotic device. Students will use skills developed in designing, refining and building (using the 3D printer and the laser cutter) to create a robotic vehicle in answer to a defined problem or context.

Prerequisite: Ability to work in a team. Each student will be provided with an individual computer and will share electronic equipment. Preference is given to students who achieved in Level 1 Mechatronics course, have ability in Mathematics or Science and who have a good attendance record and work ethic.

Vocational/Industry links: (What vocational or industry learning experiences will be included in this course?)
https://www.careers.govt.nz/searchresults?q=mechatronics

Contextualised contexts: (What local, cultural, real-life content is involved in this course?)
This course provides a more in depth look at the world of mechatronics which is more and more a part of our day to day lives with drones and remote vehicles being used in areas as diverse as agriculture, search and rescue, film and television and underwater recovery of resources. Students will identify an area where a drone or remote vehicle can be applied and then develop a solution for the identified problem or need.

Teaching and Learning Approaches: (How will I learn in this course?)
Students will combine hands-on learning through the creation of their own project bolstered with teaching, through a combination of online assignments and face-to-face instruction, to provide the theory needed to progress the various stages of their project.

Resource requirements: (What resources will I need to have to learn in this course?)
Students will require a personal USB Drive.

Course Outline

Term 1 02 February - 16 April 2021 (10/11 weeks)	Term 2 03 May - 09 July 2021 (10 weeks)	Term 3 26 July - 01 October 2021 (10 weeks)	Term 4 18 October - early November 2021 (4 weeks)
Research and develop a concept and 3D model of their project Produce working drawings of their design Produce STL 3D print files or Laser cut files for producing their prototype	Develop and demonstrate an understanding of advanced techniques in control programming and interfacing Produce a plan for the development programme for your project Complete initial development of your project	Iteratively build, programme, test and refine your prototype of the project to determine its fitness for purpose against the brief.	Presentation of your summary of developing a digital outcome
KEY DATES: Week 6: AS91890 - Completion of proposal for project Week 10: AS91338) - Completion of CAD model and working drawings	KEY DATES: Key dates will be dependant on project proposed in Term 1	KEY DATES: Key dates will be dependant on project proposed in Term 1	KEY DATES: Week 2: Completion of portfolio and presentation of final outcome

Term 1
02 February - 16 April 2021
(10/11 weeks)

Term 2
03 May - 09 July 2021
(10 weeks)

Term 3
26 July - 01 October 2021
(10 weeks)

Term 4
18 October - early November 2021
(4 weeks)

Research and develop a concept and 3D model of their project
Produce working drawings of their design
Produce STL 3D print files or Laser cut files for
producing their prototype

Develop and demonstrate an understanding of
advanced techniques in control programming and interfacing
Produce a plan for the development programme
for your project
Complete initial development of your project

Iteratively build, programme, test and refine
your prototype of the project to determine its
fitness for purpose against the brief.

Presentation of your summary of
developing a digital outcome

KEY DATES:

Week 6: AS91890
- Completion of proposal for project
Week 10: AS91338)
- Completion of CAD model and working drawings

KEY DATES:

Key dates will be dependant on project proposed in Term 1

KEY DATES:

Key dates will be dependant on project proposed in Term 1

KEY DATES:

Week 2: Completion of portfolio and presentation of final outcome

______________________________________________________________________________________________________________________________

Graduate profile: (What qualities/additional skills learners will achieve by taking this course?)
Imagine it, engineer it, and make it go. Use skills developed in Level 1 and 2 to develop and refine the project started in Level 2. Students will create a fully functional marketable prototype to fulfil the identified problem or context. Robotics provides students with opportunities to question, think about, and create technological tools, rather than just becoming passive users of technology.

Possible Career/ Vocational Pathway(s): (What career pathways are related to this course?)
https://www.careers.govt.nz/searchresults?q=mechatronics

Learning outcomes/Assessment links:

NCEA Level	Standard Number	Standard Descriptor	Credits	Assessment	Literacy	Numeracy	Vocational Pathways
3	AS91631 03	Design & Visual Communication 3.34 - Produce working drawings to communicate production details for a complex design	6	External	No	No	C&I, M&T, PI, CI
3	AS91904 01	Digital Technologies and Hangarau Matihiko 3.5 - Use complex techniques to develop an electronics outcome	6	Internal	No	No	C&I, M&T, CI
3	AS91906 01	Digital Technologies and Hangarau Matihiko 3.7 - Use complex programming techniques to develop a computer program	6	Internal	No	No	C&I, M&T, CI
3	AS91909 01	Digital Technologies and Hangarau Matihiko 3.10 - Present a reflective analysis of developing a digital outcome	3	External	Yes L1LIT	No	C&I, M&T, PI, SI, SC, CI
		Total Available Credits	21

Progression: (What courses does this course lead to?)
The course will take students through the more advanced concepts of electronics, DC electrical systems, control programming and interfacing. Students will learn to control motors and actuators, interface with sensors and other robots in the enhancement of a robotic device. Students will use skills developed in designing, refining and building (using the 3D printer and the laser cutter) to create a robotic vehicle in answer to a defined problem or context.h

Prerequisite: Ability to work in a team. Each student will be provided with an individual computer and will share electronic equipment. Preference is given to students who achieved in Level 1 Mechatronics course, have ability in Mathematics or Science and who have a good attendance record and work ethic.

Vocational/Industry links: (What vocational or industry learning experiences will be included in this course?)
https://www.careers.govt.nz/searchresults?q=mechatronics

Contextualised contexts: (What local, cultural, real-life content is involved in this course?)
This course provides a more in depth look at the world of mechatronics which is more and more a part of our day to day lives with drones and remote vehicles being used in areas as diverse as agriculture, search and rescue, film and television and underwater recovery of resources. Students will identify an area where a drone or remote vehicle can be applied and then develop a solution for the identified problem or need.

Teaching and Learning Approaches: (How will I learn in this course?)
Students will combine hands-on learning through the creation of their own project bolstered with teaching, through a combination of online assignments and face to face instruction to provide the theory needed to progress the various stages of their project.

Resource requirements: (What resources will I need to have to learn in this course?)
Students will require a personal USB Drive.

Course Outline:

Term 1 02 February - 16 April 2021 (10/11 weeks)	Term 2 03 May - 09 July 2021 (10 weeks)	Term 3 26 July - 01 October 2021 (10 weeks)	Term 4 18 October - early November 2021 (4 weeks)
Research and develop a concept and 3D model of your project Produce working drawings of your design Produce SLT 3D print files or Laser cut files for producing your prototype	Develop and demonstrate an understanding of advanced techniques in control programming and interfacing Produce a plan for the development program for your project Complete initial development of your project	Iteratively build, program, test and refine your prototype of the project to determine its fitness for purpose against the brief	Presentation of your summary of developing a digital outcome
KEY DATES: Week 6: Completion of Proposal for Project (AS91890) Week 10: Completion of CAD Model and Working Drawings (AS91338)	KEY DATES: Key dates will be dependent on project proposed in Term 1	KEY DATES: Key dates will be dependent on project proposed in Term 1	KEY DATES: Week 2: Completion of Portfolio and Presentation of final outcome

Term 1
02 February - 16 April 2021
(10/11 weeks)

Term 2
03 May - 09 July 2021
(10 weeks)

Term 3
26 July - 01 October 2021
(10 weeks)

Term 4
18 October - early November 2021
(4 weeks)

Research and develop a concept and 3D model of your project
Produce working drawings of your design
Produce SLT 3D print files or Laser cut files for producing your prototype

Develop and demonstrate an understanding of advanced techniques in control programming and interfacing
Produce a plan for the development program for your
project
Complete initial development of your project

Iteratively build, program, test and refine your prototype of the project to determine
its fitness for purpose against the brief

Presentation of your summary of developing a digital outcome

KEY DATES:

Week 6: Completion of Proposal for Project (AS91890)
Week 10: Completion of CAD Model
and Working Drawings (AS91338)

KEY DATES:

Key dates will be dependent on
project proposed in Term 1

KEY DATES:

Key dates will be dependent on
project proposed in Term 1

KEY DATES:
Week 2: Completion of Portfolio
and Presentation of final outcome