Physical Computing HS2020

Lecturers: Luke Franzke & Florian Bruggisser

Course Overview

In this course, we will look at physical computing as a method of interaction design. Our definition of Physical Computing refers to the use of hardware and software to make interactive objects that can respond to events in the real world. These events may be general knowledge about the environment (temperature, brightness, etc.) or user interactions (keystroke, motion, speech, etc.). These devices might respond with direct feedback through displays or actuators, or by performing actions in a digital environment. The challenge of physical computing is to make the interface between human and machine as simple and intuitive as possible by taking physical human abilities and habits into account.

Course Goals

The students learn how to handle hardware and software in order to prototype their own ideas. The students develop an understanding of the characteristics of physical interactions and demonstrate them through functional prototypes. From a technical perspective, students learn the basics of electronics, microcontroller programming (Arduino), working with digital and analogue sensors and actuators.

Course Structure

The course takes place in two separate blocks: Physical Computing Basics in the first two weeks and the Main Project in the last two weeks. In the first block, students will work individually through the introductory topics, while the Main Project is in groups of two to three students.

Personal Material

Please bring your personal computer to all classes. If you have a newer MacBook with USB C, bring an adapter to work with standard USB cables. A personal notebook is also recommended.

Expectations and Grading

Grades will be based on group presentations, class participation, home assignments, documentation and final work. An attendance of min. 80% is required to pass the course.

Individual Documentation (weeks 1 and 2)
Group Work (weeks 3 and 4)

Individual Work (40%)

Workbook documentation of all exercises and minor projects from weeks 1 and 2.
Document every circuit you built (or attempted to build) with a photo. Include your code when appropriate, a drawn schematic of each circuit and include notes/observations.
Presentation of Minor Project.

Group Work (60%)

Final Prototype of Object
Final Presentation
Standard IAD Documentation
- Video (Making of, Final Prototype)
- Image selection
- Short Documentation (PDF)

Final Presentation notes:

5 minutes for presentation, and 5 minutes for feedback and discussion
Show the process that brought you to this outcome
Live demonstration of your project

Topic 2020: Robotic Tangible User Interfaces?:

http://www.iaacblog.com/programs/tangible-robot/

https://hackaday.com/2017/02/17/zooids-swarm-user-interface/

Can interactions between human and machines be more effective if we can empathise with the device because of it's anthropomorphic behaviour? Can such devices, in turn, empathise with us? We are social animals, and a large portion of our brain is dedicated to social tasks, from recognising emotions to predicting the thoughts and intentions of other humans and creatures. It, therefore, makes sense that we utilise these capabilities when designing interactions.

But how might everyday interactive devices be improved by anthropomorphic characteristics? Would we be more likely to partake in sustainable consumption of electronics if devices were more sympathetic? This year's Physical Computing project will attempt to answer some of these questions while drawing inspiration from robotics to physically prototype interactive devices with empathetic qualities and anthropomorphic behaviours.

Distinctly non-human forms can be highly evocative of human qualities, and basic geometric forms can convey agency and complex behaviours through motion alone (Heider and Simmel 1944). For this reason, we will focus on primitive forms with expressive behaviour through motion, using simple electromechanical actuators, in combination with sensors and microcontrollers.

2019 Topics Readings

Schedule

Morning: 09:00 - 12:00, Afternoon: 13:30 - 17:00

W1	Tuesday 06.10	Wednesday 07.10	Thursday 08.10	Friday 09.10
Morning	Kick-off Lecture Electricity Basics (LF FB) References: Getting Started with Arduino 3rd Edition: p.37-40 Make: Electronics 2nd edition: p.1-40 Electronic Basics (sparkfun)	Digital Components Digital Interfaces I2C, SPI, UART	Individual Minor Project (inputs)	Individual Minor Project (inputs)
Afternoon	Parallel/Series Circuits Debouncing Pulse Width Modulation Smoothing (Moving average)	Digital Components continued... 15:00 Bits and Atoms Guest Lecturer: Lady Ada?	Individual Minor Project (inputs)	Individual Minor Project (inputs)
W2	Tuesday 14.10	Wednesday 15.10	Thursday 16.10	Friday 17.10
Morning	Digital outputs: Neo Pixels	Capacitors Arduino & Processing	Individual Minor Project (inputs and outputs)	Individual Minor Project (inputs and outputs)
Afternoon	Transistors Motors, Solenoids ICs, datasheets H-Bridges	Individual Minor Project 15:00 Bits and Atoms (data vis)	Individual Minor Project (inputs and outputs)	Individual Minor Project Presentation. 14:30 Cleanup and documentation
W3	Tuesday 21.10	Wednesday 22.10	Thursday 23.10	Friday 24.10
Morning	Networking	Main Project Kickoff Robotics input Main Project Ideation		Prototyping & Design Concept
Afternoon	Serial Communication Soldering Batteries	Topic Presentation 15:00 Bits and Atoms (data vis)	EAGLE CAD & PCB Manufacturing (LCSC EASY EDA?)	13:30 Mentoring (LF & FB)
W4	Tuesday 28.10 (Atelier)	Wednesday 29.10 (Atelier)	Thursday 30.10 (Atelier)	Friday 31.10 (Atelier)
Morning	Prototyping / Mentoring (LF)	Prototyping	Setup Final Presentation	Documentation
Afternoon	Prototyping / Mentoring (LF)	Meeting Jürgen and Karmen 14:00 - 15:00 (5.D02). Prototyping / Mentoring 15:00 Bits and Atoms (data vis)	Final Presentation 14:30 Feedback	Documentation