GMU:Sensor Hacklab/Rachel Smith: Difference between revisions

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[[File:Rsschematic1.png]]
[[File:Rsschematic1.png]]


'''Protoyping Experiments'''
'''Protoyping Experiments'''
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[[https://vimeo.com/169906515 Video showing the development of servo motion]]
[https://vimeo.com/169906515 Video showing the development of servo motion]
 
[https://www.youtube.com/watch?v=tGhcTwIJ4Es Link to a nice (if you mute it) youtube tutorial about how to fold this type of origami]
 
'''Using Muscle Wire'''
 
Here is an experiment with 'Muscle Wire' which shrinks when certain currents are applied. I tried sewing it into the paper to see what kinds of movement could happen. It resulted in subtle, slow movements which were too slight for this project. Muscle wire also turned out to be quite complicated to use. It is easy to burn it out by applying too much current or an appropriate amount of current for too long resulting in it becoming unresponsive. I think it could be an interesting material to work with in the future but needs a lot more research/experimentation. For this reason I went back to working with servo motors.


Here is an experiment with 'Muscle Wire' which shrinks when certain currents are applied. I tried sewing it into the paper to see what kinds of movement could happen. It resulted in subtle, slow movements which were too slight for this project so I looked again at servo motors.
[http://makezine.com/2012/01/31/skill-builder-working-with-shape-memory-alloy/ Link to a Make article about using muscle wire, I found this useful]


[[File:Shrs3.png]]
[[File:Shrs3.png]]
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Schematic for muscle wire
Schematic for muscle wire


[[File:Rsschematic2.png]]
Here the transistor is needed to provide the muscle wire with enough current whilst not drawing too much current from the Arduino and therefore preventing it from breaking.
 
[[File:Rsschematic2.png|385px]]
[[File:schematic2rs.png|300px]]
 
'''Expanding Circles Experiments'''
 
Here is another experiment with mechanisms for opening and closing the origami balls. This time I made expanding circles by fitting together sections of squares - The idea being to place a motor in the middle, twisting the structures. In the end this turned out to be much more complicated than the umbrella idea so I discontinued but I really liked the variety of shapes which were made just from squares.
 
[[File:expandingcirlces.png|600px]]
 
[https://vimeo.com/177207484 Video of this here]
 
 
 
'''
Fitting together umbrellas, servos and origami'''
 
I needed to find a way of translating circular motion (of the servo) into push-pull motion to control the umbrella structure. I made little wooden attachments for the servo propeller which I thought could push directly against the bottom of the internal umbrella structure, moving it up and down regularly in different patterns. It turned out that this approach put too much force onto the servo and caused it to stop turning. Then I attached a wooden stick between the propeller and the bottom 'pushing' part of the umbrella. This worked well but didn't allow enough range of pushing, due to the size of the propeller. I solved this by putting on of my wooden propeller adaptions on, and then connecting the umbrella with this. I found that with a large oval shape a far bigger range could be achieved.
 
[[File:Umbrella8.png]]
 
[[File:Umbrella9.png]]
 
[[File:Umbrella4.png]]
 
[[File:Umbrella5.png]]
 
[[File:Umbrella6.png]]
 
[[File:Umbrella7.png]]
 
[[File:sensorhl1.png]]
 
[[File:sensorhl2.png]]
 
[[File:shrs8.png]]
 
[https://vimeo.com/177210267 Video of servo moving umbrella mechanism]
 
Here I managed to get the servo and umbrella mechanism working with the spaghetti sensor but when I attached the umbrella spokes to the origami, the tension became too much for the motor. To get round this problem I thought of trying to make less tension in the paper by using thinner paper and smaller folds. I have started to fold the structure underneath (which is taking an incredibly long time) and will test this soon.
 
[[File:sensorhl3.png]]
 
[[File:sensorhl4.png]]
 
[[File:sensorhl5.jpg]]
 
[[File:sensorhl6.jpg]]
 
[[File:sensorhl7.jpg]]
 
The full realisation of this project will be documented [https://www.uni-weimar.de/medien/wiki/GMU:Human_and_Nonhuman_Performances_II_SS16/Rachel_Smith here] when complete.

Latest revision as of 12:49, 2 August 2016

Project Overview


Origami2.png Umbrella2.png Origami1.png


In this course I wanted to develop an interactive object for use with the performance platform, the idea being that the tracking system would sense human movement and send this data to the object which, in turn, would respond. Eventually, I want to build a wall/curtain structure which will hang in between two people and act as a medium of communication. I am particularly interested in the small and subconscious movements made by humans while interacting and will concentrate on eye gaze as my sensory input.

The wall will be made up of units, each an origami structure with the ability to move individually in response to the eye movements of the interactors. In this course I have experimented with various ways of achieving this movement and also with various sensory inputs.


Outline of installation in performance platform (12 cameras surrounding for tracking) One continuous origami structure

Rssketch1.png

Units of origami

Rssketch2.png

Link to main project


Technical Implementation

For the sensor I have used an eye tracking processing sketch, developed in a previous course and tweaked it to send messages to arduino when your eyes hit certain targets on the screen. Each target sets off a different motor. The communication between the two programmes works using the serial port.

Link to video of eye tracking programme

Shrs5.png

*Link to processing code 
*Link to Arduino code 


As an alternative sensor, I also made a spaghetti sensor by using the variable resistance inherent in cooked spaghetti as part of a voltage divider. Attached to an analogue Arduino input, I was able to get a motor to respond to my hand moving around in the bowl.

[video here]

I then used the spaghetti sensor in another project [see here], using OSC to send these analogue signals to max msp and Unity.


Shrs1.png

Schematic for spaghetti sensor

Rsschematic1.png


Protoyping Experiments

Shrs2.png Rssh12.png

Rssh10.png Rssh11.png Shrs4.png


Video showing the development of servo motion

Link to a nice (if you mute it) youtube tutorial about how to fold this type of origami

Using Muscle Wire

Here is an experiment with 'Muscle Wire' which shrinks when certain currents are applied. I tried sewing it into the paper to see what kinds of movement could happen. It resulted in subtle, slow movements which were too slight for this project. Muscle wire also turned out to be quite complicated to use. It is easy to burn it out by applying too much current or an appropriate amount of current for too long resulting in it becoming unresponsive. I think it could be an interesting material to work with in the future but needs a lot more research/experimentation. For this reason I went back to working with servo motors.

Link to a Make article about using muscle wire, I found this useful

Shrs3.png

Schematic for muscle wire

Here the transistor is needed to provide the muscle wire with enough current whilst not drawing too much current from the Arduino and therefore preventing it from breaking.

Rsschematic2.png Schematic2rs.png

Expanding Circles Experiments

Here is another experiment with mechanisms for opening and closing the origami balls. This time I made expanding circles by fitting together sections of squares - The idea being to place a motor in the middle, twisting the structures. In the end this turned out to be much more complicated than the umbrella idea so I discontinued but I really liked the variety of shapes which were made just from squares.

Expandingcirlces.png

Video of this here


Fitting together umbrellas, servos and origami

I needed to find a way of translating circular motion (of the servo) into push-pull motion to control the umbrella structure. I made little wooden attachments for the servo propeller which I thought could push directly against the bottom of the internal umbrella structure, moving it up and down regularly in different patterns. It turned out that this approach put too much force onto the servo and caused it to stop turning. Then I attached a wooden stick between the propeller and the bottom 'pushing' part of the umbrella. This worked well but didn't allow enough range of pushing, due to the size of the propeller. I solved this by putting on of my wooden propeller adaptions on, and then connecting the umbrella with this. I found that with a large oval shape a far bigger range could be achieved.

Umbrella8.png

Umbrella9.png

Umbrella4.png

Umbrella5.png

Umbrella6.png

Umbrella7.png

Sensorhl1.png

Sensorhl2.png

Shrs8.png

Video of servo moving umbrella mechanism

Here I managed to get the servo and umbrella mechanism working with the spaghetti sensor but when I attached the umbrella spokes to the origami, the tension became too much for the motor. To get round this problem I thought of trying to make less tension in the paper by using thinner paper and smaller folds. I have started to fold the structure underneath (which is taking an incredibly long time) and will test this soon.

Sensorhl3.png

Sensorhl4.png

Sensorhl5.jpg

Sensorhl6.jpg

Sensorhl7.jpg

The full realisation of this project will be documented here when complete.