crtl-i » Experiments

Cocoon

crtl-i — Tue, 01 Mar 2011 08:14:25 +0000

The saturation of paradox is perhaps the wonder of contemporary society. The world has never been so strikingly contradicting. We are more globally connected, shared, and opened than ever. More spaces are locked, controlled, and surveilled than ever. We are able to communicate with the entire world within a closed room. Cities have never been so crowded. Surfacing images now redefine urban spaces as we know it. We walk in streets of unreality. More and more, we run into faceless strangers we will never see again. We have never felt so isolated. Our true emotions are less relevant. We regain a sense of the real in our dreams. Nothing is absolute. Everything is blurry. It is now difficult to grasp what’s real from what’s visible. Women are men. Men are women. The unreal has never been so real. The real has never been so unreal.

Cocoon is a house in which everything we know of a house ceases to exist. A house divides a space into smaller finite spaces of different events. Cocoon is in itself a space of infinite events. A house is situated somewhere and provides us with the sense of stability that tells us where we belong. Cocoon is nowhere and everywhere. It exudes the sense of identity. It is our body. A house is physical in that it has clear material distinctions among windows, walls, ceilings, and doors. Cocoon is both material and ethereal like light in that it has ambiguous boundaries. A house is fenced and gated in human efforts to ensure security and to protect privacy. Cocoon is a form of human desire to relate and to connect.

with Dong-wook Hwang

in sync

crtl-i — Wed, 12 Jan 2011 05:16:12 +0000

http://dcreative.tistory.com/entry/in-sync-2011

Sub-Dividing

crtl-i — Thu, 25 Mar 2010 09:51:02 +0000

Photocell + 8×8 LED Matrix

crtl-i — Thu, 04 Mar 2010 14:43:07 +0000

This is an example of using 2 photocells and a variable resistor as analog inputs to control 8×8 LED Matrix with PIC18F452, UDN2981, and ULN2803. The input values of the two photocells are compared. When the values are the same, LED lights up randomly within the entire board. Depending on how much darker a photocell is compared to the other, LED lights up within the range that is more focused towards a corner. The variable resistor controls how fast the LEDs blink. This is how the board was set up:

The following is the code:

DEFINE LOADER_USED 1

DEFINE OSC 20

INCLUDE “modedefs.bas”

DEFINE ADC_BITS 10

DEFINE ADC_CLOCK 3

DEFINE ADC_SAMPLEUS 20

ADCON1 = %10000010

trisb =%00000000

trisd =%00000000

trisa =%11111111

trisc =%10000000

an0 var word

an1 var word

an2 var word

an0b var byte

an1b var byte

an2b var byte

portb = 0

portd = 0

rand_max var byte

rand_min var byte

random_word var word

randomdig var byte

main:

GOSUB getadc

IF an1b < an2b THEN

rand_max=an1b

rand_min=0

ENDIF

IF an1b > an2b THEN

rand_max=7

rand_min=7-an2b

ENDIF

IF an2b = an1b THEN

rand_max=7

rand_min=0

ENDIF

GOSUB generate_Random

portb = 1<

GOSUB generate_Random

portd = 1<

PAUSE 10*an0b

gosub bd_off

PAUSE 1*an0b

GOTO main

bd_off:

portb=0 : portd=0

RETURN

getadc:

ADCIN 0,an0

ADCIN 1,an1

ADCIN 2,an2

an0b = (an0*8)>>10

an1b = (an1*8)>>10

an2b = (an2*8)>>10

RETURN

generate_random:

RANDOM random_word

randomdig = random_word DIG 1

IF randomdig > rand_max THEN GOTO generate_random

IF randomdig < rand_min THEN GOTO generate_random

RETURN

Analog / Digital Input, Output

crtl-i — Mon, 22 Feb 2010 06:14:42 +0000

This is an example of using 2 variable resistors as analog inputs and a switch as a digital input to control 8 LEDs with a PIC18F452 chip. Variable resistor 1 is used to control which LEDs light up. The second variable resistor controls how fast the LEDs blink. The switch decides whether the LEDs blink or not. MAX232CPE is used to allow serial communication with a computer. PICBASIC was used to program the chip. This is how the board was set up:

The following is the code:

DEFINE LOADER_USED 1
DEFINE OSC 20
INCLUDE “modedefs.bas”

DEFINE ADC_BITS 10
DEFINE ADC_CLOCK 3
DEFINE ADC_SAMPLEUS 20

ADCON1 = %10000010

TRISA = %11111111
TRISB = %00000000
TRISC = %10001000

adc VAR WORD
adcbyte VAR BYTE

SPEED VAR WORD
SPEEDbyte VAR BYTE

SWITCH VAR PORTC.4

main:

IF SWITCH = 1 THEN

ADCIN 0, adc
adcbyte = adc/140

ADCIN 1, SPEED
SPEEDbyte = SPEED/140

PORTB = %00000001 << adcbyte
PAUSE 100*SPEEDbyte
PORTB = 0
PAUSE 100*SPEEDbyte

ELSE
ADCIN 0, adc
adcbyte = adc/140

PORTB = %00000001 << adcbyte

ENDIF

GOTO main

Catenary – Maya nCloth

crtl-i — Tue, 16 Feb 2010 10:02:55 +0000

Karey (http://kareydarnellhelms.com) showed me a great catenary / structural analysis tool being developed in grasshopper (http://spacesymmetrystructure.wordpress.com/2010/01/21/kangaroo/). Similar ideas can be explored using the nCloth tool in Maya. This is what it looks like.

8×8 LED Matrix

crtl-i — Fri, 29 Jan 2010 07:38:10 +0000

Front side

Cathode rows soldered

Anode rows soldered

Physical Computing – Current Amplification

crtl-i — Sat, 23 Jan 2010 15:00:24 +0000

Today was my first day at a physical computing workshop run by Jin-Yo Mok (http://www.geneo.net). I’m starting from the very basics to understand how every single piece operates at the most fundamental level. The breadboard in the image shows the simplest setup of current amplification using an NPN transistor (2N2222). Hopefully, I’ll be able to design custom circuit boards in the future as I become more comfortable with all these volts and currents :)

Fibrous Art Bridge

crtl-i — Thu, 21 Jan 2010 13:41:07 +0000

These are some images from a recently finished competition.

Fibers 2

crtl-i — Mon, 04 Jan 2010 16:04:24 +0000

Ordered, but random
Random, but ordered