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IA01 Background Survey - 1/29
IA02 Arduino Graph - 2/13
IA03 Partner Eval for MPA01 - 3/10
IA04 Partner Eval for MPA02 - 4/02
IA05 Partner Eval for MPA03 - 4/21
MPA01 Input Inventions - 3/3
MPA02 High-Low Tech - 3/26
MPA03 Kinects & Motors - 4/16
Semester Project Assignments
SPA01 Project Pitch
SPA02 Project Presentation
SPA03 Project Instructable
SPA04 Project Video
SPA05 Project Artifact
RA01 Tangible Bits - 1/29
RA02 Arduino Intro - 2/3
RA03 Electricity Intro - 2/13
RA04 Switches (p 39-59) - 2/19
RA05 Input Technology - 2/26
RA05 Sensor-Based Input - 2/26
RA06 Prototyping 3/5
Fuzzy Adventure: A Tangible Music Mixer
When watching a musical performance, some people focus simply listening to the sounds while others try to inspect the musicians and discern how each is affecting the overall sound. At an electronic music performance, this can be especially difficult for the second kind of audience member because unlike traditional instruments, electronics are usually positioned on a table facing away fromt the audience. Additionally, some listeners feel “cheated” by not knowing what the producer is controlling or even knowing if they are doing anything but hitting play on a pre-recorded track. In our project, we tried to make the actions of a performer that would result in changes to sound visible to the audience. In this way, the performer has another degree of freedom in which to perform their piece, one of a physical dimension.
Our basic prototype consists of three looping tracks that can be manipulated in various physical ways. Each of the three tracks have a volume control and an effect control.
Crush green flower
Cover blue circle
2 - pressure sensors
2 - touch membrane sensors
1 - photo sensor
1 - proximity sensor
1 - Arduino Uno
2 - breadboards
Some - Conductive fabric
Actuating the pressure sensors:
Building blocks on a platform - One small sensor could not reliably sense the weight of a platform because the pressure was distributed instead of localized on the sensor. We tried multiple methods of focusing the weight, including adding weights to a hanging structure which pulled a focused point down over a pressure sensor. this hack idea sort of worked but was unreliable, and was hard to move.
Solution: Cups - While not as visually appealing as the original idea of stacking blocks on a surface, it was much better looking than the hanging weight and much more reliably actuated the pressure sensor.
De-breadboarding our sensors:
Finding the right kind of connectors
Solution: Making our own connections - We resorted to using tape and popsicle sticks to attach wires to the leads of our sensors so that we could position the sensors away from the breadboard.
False starts with:
Flex sensors - We found it hard to actuate the flex sensors in such a way that the reading used the full analog range in a smooth manner.
Hall-effect, Vibration sensors - We had a difficult time getting either of these sensor types to give us a reading. Finding documentation on the parts was difficult and even having them, it didn’t necessarily tell you how to obtain a reading from the sensor.
The open-endedness assignment gave us freedom to choose a topic that we were interested in while satisfying the prompt. We enjoyed starting with the idea of making music, and then trying to figure out what needs we could satisfy with the input device. We also enjoyed having the opportunity to play with and learn how to use many different types of sensors.
More feedback about the project choice would have been helpful in the very beginning of the project. Since this was our first project, we weren’t really sure how to approach it, and how difficult our ideas would be to implement.
A rough timeline (possible steps to follow if we got stuck) would have been particularly helpful. Our team had a rough idea of what we wanted to do, but it took us time to formulate our concept into a physical set of controls. Sketching out what a final prototype might look like, and thinking about the possible interactions we wanted implement before building would have saved us time.
The timeline would have helped us also realize how much time we needed to leave for building. We figured out most of the sensors by the first week, but quickly realized that we needed a lot of time to actually create the interactions that we wanted. It took us a while, for instance, to get the pressure sensors to reliably measure weights.
Electronic artist mixing music during a concert. What is he doing while he’s performing? How are his actions affecting the music?
Multi-user electronic music instrument with a tabletop tangible user interface. Creating a new way to mix synthesized music, visualizing sound manipulation.
Novation Launchpad Keyboard. Load samples into differents cubes on a touchscreen. Allows you to see visual more easily.
Novation Launchpad iPad App
Minim (Processing Library)
help on how to format text
Turn off "Getting Started"