Arc Reactor with a slight difference.........

[ShaunDark80]

Hi All

This is not really a build log, as apart from casting a couple of pieces, this is mostly an off-the-shelf build.

In just over a month, my Sister and her husband are going to have their first baby. I wanted to build them something, so what better than an Arc Reactor?

I managed to convince my wife that this wasn't a completely stupid idea by saying it could double as a night-light and could possibly play one of Rockabye Baby's awesome lullabies.

For the lighting, I was very impressed with Adafruits Neopixel Arc Reactor that was developed for XRobots Hulkbuster project.

I ordered a couple of sets of NeoPixel Rings and a couple of Gemma microcontrollers, and then started looking for something that they could fit inside.

Luckily, Shapeways has a lot of Arc Reactor designs to choose from, and schrodinger555's MK1 Arc Reactor Chest RT was pretty much the right size.

For adding sound to the project, XRobots again had the answer - Adafruit's Ogg/Wav Sound Board.

So with all the parts figured out I began assembly.



At the top left you can see the two lightboxes - The smaller diameter one was cast from a camera lens that I found would fit perfectly inside the heatsink body. Before pouring the water clear polyurethane into the mould, I first inserted a 28mm chrome Tap Aerator. This gave me the mesh for the centre of the reactor, a nice reflective surface to bounce the light outwards and a centre channel to run the data and power cables through so that they would stay hidden.

The larger diameter ring is just a recast of schrodinger555's 3d printed model. I didn't do too much cleanup on this so that the polyurethane had a textured surface to diffuse the light.

At the top right you can see the desk lamp base that I resprayed and slightly weathered to match the Iron man suit I was/am building. I added a couple of buttons (demoed in the video later) and added a 7 pin power connector that I found online. I was originally going to support the reactor on a clear acrylic stand, riveted to this base, but instead found that a heatshrink wrapped piece of coathanger wire looks a bit like a cable, and could support the weight of the reactor, making it look like it was almost floating above the base.

All the 3D printed parts were primed and painted before assembly.

In the middle (ish) of the picture you can see a ring of capacitors mounted on a PCB. I found purely by luck that these capacitors were just the right height to support the smaller NeoPixel ring against the smaller lightbox, with room inside to hide the Gemma.



Here you can see the lower section put together for a test fit.



I assembled the top section, and wrapped it with red coloured copper wire.

I know that there are supposed to be some small copper plates and wires running around the top of the reactor, but I had a hard time soldering to these coils without melting the plastic underneath, so decided to leave as-is. I also could not find the correct bolts to go in the top, so just went with the closest thing I could find in my tin of screws.

And that's pretty much it. I wired the thing up, used epoxy resin to stick the two halves together, and ended up with this;



And here it is working;

 

[renaissance_man]

Nice idea!

 

[ShaunDark80]

I have enough parts to build a second (without sound). Any ideas of what to do with it?

 

[gsupreme]

I think you should build one for me?! Lol

 

[ShaunDark80]

I think you should build one for me?! Lol

Could do. Was hoping keep the second one, but it may end up in the Junkyard.

 

[gsupreme]

let me know if you do as well as what $ your thinking.

 

[schrodinger555]

Hey this is super cool, I'm glad the files I made were useful to you! Awesome job!

 

[gyoung2993]

I need lighting like this for my arc reactor that I am one day going to build...I hope...LOL...I need a lighting kit and a clear back piece like yours ShaunDark80 !!! That's bright and awesome !!!

 

[ShaunDark80]

Well I made the second reactor, and have put it in the Junkyard.

 

[Grummi]

Hi,

i tried to use the hulkbuster code but it did nötig work. Did you changed something in the code?

cheers

 

[ShaunDark80]

Hi,

i tried to use the hulkbuster code but it did nötig work. Did you changed something in the code?

cheers

Can you post a picture of your circuit and the code you're using?

 

[Grummi]

My Problem is that my arduino ide always report an error in the original Hulkbuster code from adafruit. I'm using the version 1.6.12.

thanks for the quick anwser.

/* -----------------------------------------------------------------------
Hulkbuster Unibeam sketch for Adafruit Gemma & NeoPixels.
Requires one 16-pixel NeoPixel ring, one 24-pixel ring, and six single
NeoPixels arranged in a large circle. Gemma pin D1 connects to the 24-
pixel ring first, then the 6-pixel, then 16...but the physical
'stacking order' is 6 (bottom), then 24, then 16 (top). Add momentary
buttons between D1 & GND (mode) and D2 & GND (fire).
Unfortunately this ended up resembling an obfuscated C contest entry,
and beginners reading it probably won't gain much besides a headache,
but I'll comment as best I can. The code is trying to generate some
very fluid animation (I don't care for 8-bit-looking twitchy blinky
stuff) on a very limited microcontroller (about 5K flash space and no
multiply instruction) and thus relies heavily on fixed-point math
(using the most-significant digits of large integers to approximate
the handling of fractions). Ran out of space toward the end, so parts
(like button handling) are a bit slipshod...working but not great.
The core idea is that each NeoPixel ring depicts a triangle wave,
the phase (rotation) and other parameters can be adjusted on a
subpixel basis so it's all buttery smooth. There may be some number
of repetitions of the wave (always integer) around the circumference
of the ring...for example, as written, it's 3, 4 and 2 reps for the
center (16), middle (24) and outer (6 pixel) rings, respectively. If
the circles were 'unrolled,' the waves might resemble:
/\/\/\ /\/\/\/\ /\/\
Each ring then has different colors corresponding to the 'peaks' and
'troughs' of these waves. Those colors change over time...but never
just an abrupt reassignment, there's always a smooth transition from
one set of colors to the next. Other parameters, like rotation phase
and speed, are also interpolated smoothly through those transitions.
Oh, also, there's timer interrupts, another really complicated subject.
Sorry about that.
-----------------------------------------------------------------------*/
#include <Adafruit_NeoPixel.h>
#include <avr/power.h>
#ifdef __AVR_ATtiny85__ // Trinket/Gemma:
#define LEDPIN 1 // NeoPixels connect here
#define MODEPIN 0 // Switch modes w/button between this pin & GND
#define FIREPIN 2 // 'Fire' w/button between this pin & GND
#else // Arduino Uno & everything else:
#define LEDPIN 6 // NeoPixels connect here
#define MODEPIN 4 // Mode button between this & GND
#define FIREPIN 5 // Fire button between this & GND
#endif
// Partial color assignments for various ring states; HSV colorspace,
// not RGB. Hue is always determined by the current mode, so these
// just include saturation and value (brightness).
#define IDLE_PEAK_SAT 255 // "Dim" rings
#define IDLE_PEAK_VALUE 130
#define IDLE_TROUGH_SAT 255
#define IDLE_TROUGH_VALUE 45
#define BRIGHT_PEAK_SAT 80 // Current "bright" ring
#define BRIGHT_PEAK_VALUE 230
#define BRIGHT_TROUGH_SAT 255
#define BRIGHT_TROUGH_VALUE 135
#define AIM_SAT 0 // Ramping up to fire...
#define AIM_PEAK_VALUE 140
#define AIM_TROUGH_VALUE 120
#define FIRE_SAT 0 // Firing
#define FIRE_VALUE 255
#define DEBOUNCE 10 // Counter limit for mode, fire buttons
// Okay, this is just terrible, don't try this at home. I'd been curious
// if one could use the preprocessor, not runtime code, to sum values in
// a struct array. Here, counting the number of pixels in a list of
// NeoPixel rings in order to declare the single Adafruit_NeoPixel strip
// length. List can then change without editing the declaration every
// time; it follows automatically. Short answer: yes, it can be done.
// Long answer: this is a hack and not well-behaved C syntax for anything,
// please don't use as a model for your own code, was just an experiment.
// List rings here -- index of first LED, number of LEDs, number of wave
// repetitions. This is the order in which they're referenced in the
// ring[] array later, and doesn't need to match the order in which they're
// physically connected. They should not overlap, nor should there be any
// gaps. No code is generated here...all just preprocessor shenanigans.
#define RING_TABLE \
ring(30, 16, 3) \
ring( 0, 24, 4) \
ring(24, 6, 2) \
// Don't remove this comment
// Preprocessor trick counts the total number of LEDs in the list.
// Adapted from supercat's code at stackoverflow.com/questions/3539549
#define ring(f,n,r) EN_##n}; enum {EN_SZ_##n=n,EN_TMP_##n=EN_##n+(n-1),
enum {EN_IDX=-1, RING_TABLE N_LEDS};
#undef ring // After enumeration, same macro now inits array defaults:
#define ring(first,n,r) { first, n, r, {128,128,128}, 0, {0,0,0}, {{{0,0,0}, {0,0,0}}, {{0,0,0}, {0,0,0}}, {{0,0,0}, {0,0,0}}} },
// All so we can do this:
Adafruit_NeoPixel strip = Adafruit_NeoPixel(N_LEDS, LEDPIN);
// instead of ring[0].length + ring[1].length + ... + ring[2].length
// Each ring animates based on one or more full cycles of a triangle wave,
// which may be skewed toward a sawtooth wave. RGB colors are interpolated
// between the peaks and troughs of the wave.
struct Ring {
const uint8_t firstLED; // Index of first pixel along full strand
const uint8_t nLEDs; // Number of LEDs in ring
uint8_t reps; // Number of wave cycles around ring
uint8_t peak[3]; // [to/from/current] sawtooth peak offset (0-255)
volatile uint16_t phase; // Offset angle (65536 = 360 degrees)
volatile int16_t spd[3]; // [to/from/current] phase increment per frame
volatile uint8_t color[3][2][3]; // [to/from/current][peak/trough][R,G,B]
} ring[] = {
RING_TABLE // Macro above expands this into data for all rings
};
#define N_RINGS (sizeof(ring) / sizeof(ring[0]))
// Each of three animation modes has a distinct color and a rotation
// speed/direction for each of the rings.
// Clockwise direction is different on 16 pixel ring vs 24 (and the
// arrangement of 6 discrete NeoPixels). On 16 pixel ring: + is clockwise,
// - is counterclockwise. On 24 pixel ring (and our 6 pixel ring), - is
// clockwise, + is counterclockwise.
struct Mode {
const int16_t hue;
const int16_t speed[3];
} modeData[] = {
1100, { 2500, -2000, 1500}, // Blue mode (CW , CW , CCW)
510, { 2500, 2000, -1500}, // Green mode (CW , CCW, CW )
15, { -2500, -2000, -1500}, // Red mode (CCW, CW , CW )
};
#define N_MODES (sizeof(modeData) / sizeof(modeData[0]))
extern const uint8_t gamma[]; // Table at bottom of this file
uint8_t
mode = 0,
brightRing = N_RINGS - 1; // Counts through rings for pulsing effect
volatile uint8_t
interpFrames = 0, // Duration of color/speed transition
interpolating = 0; // Current transition counter, 0=done
// -------------------------------------------------------------------------
void setup() {
#if defined(__AVR_ATtiny85__) && (F_CPU == 16000000L) // 16 MHz Trinket?
clock_prescale_set(clock_div_1);
#endif
strip.begin();
strip.show(); // Initialize all pixels to 'off' ASAP
pinMode(MODEPIN, INPUT_PULLUP);
pinMode(FIREPIN, INPUT_PULLUP);
// Configure "bootup" transition
setRingsToIdleValues();
startInterp(105); // ~3.5 second startup
// Configure Timer/Counter 1 for 30-ish Hz interrupt
#ifdef __AVR_ATtiny85__ // Trinket/Gemma:
#if (F_CPU == 16000000) // 16 MHz:
TCCR1 = _BV(CS13) | _BV(CS12); // 1:2048 prescale
#else // 8 MHz:
TCCR1 = _BV(CS13) | _BV(CS11) | _BV(CS10); // 1:1024 prescale
#endif
GTCCR = 0; // No PWM out
TIMSK = _BV(TOIE1); // Overflow interrupt
#else // Everything else:
TCCR1A = _BV(WGM11) | _BV(WGM10); // Mode 15, no PWM out
TCCR1B = _BV(WGM13) | _BV(WGM12) | _BV(CS11) | _BV(CS10); // 1:64 prescale
OCR1A = F_CPU / 64 / 30; // ~30 Hz cycle
TIMSK1 = _BV(TOIE1); // Overflow interrupt
#endif
// Once the interrupt is enabled, animation (and transitions between
// animation states) all occur automatically. We just monitor the
// 'interpolating' variable to indicate when the current transition is
// done before issuing another.
while(interpolating); // Wait for bootup transition to complete
}
// -------------------------------------------------------------------------
// Don't return until both buttons are released and debounced
void waitForButtonRelease() {
for(uint8_t i=0; {
if((digitalRead(MODEPIN) == LOW) || (digitalRead(FIREPIN) == LOW)) i=0;
else if(++i >= DEBOUNCE) return;
}
}
// Set all rings to 'dim' colors for current mode
void setRingsToIdleValues() {
for(uint8_t r=0; r<N_RINGS; r++) {
setTargetColor(r, modeData[mode].hue,
IDLE_PEAK_SAT, IDLE_PEAK_VALUE, IDLE_TROUGH_SAT, IDLE_TROUGH_VALUE);
setTargetSpeed(r, modeData[mode].speed[r]);
}
}
void nextMode() {
setRingsToIdleValues(); // Bright ring will fade off
for(startInterp(10); interpolating; ); // ~1/3 sec transition
if(++mode >= N_MODES) mode = 0; // Advance/wrap mode counter
setRingsToIdleValues(); // Set new colors/speeds
brightRing = N_RINGS - 1; // Start w/center after transition
for(startInterp(45); interpolating; ); // ~1.5 sec. transition
waitForButtonRelease();
}
void fire() {
uint8_t r;
setRingsToIdleValues(); // Bright ring will fade off
for(startInterp(10); interpolating; ); // ~1/3 sec transition
for(r=0; r<N_RINGS; r++) { // All rings fade to 'aim' state...
setTargetColor(r, modeData[mode].hue,
AIM_SAT, AIM_PEAK_VALUE, AIM_SAT, AIM_TROUGH_VALUE);
setTargetSpeed(r, modeData[mode].speed[r] * 10);
}
for(startInterp(105); interpolating; ); // 3.5 sec warmup transition
for(startInterp( 40); interpolating; ); // 1.3 sec hold
for(r=0; r<N_RINGS; r++) { // All rings fade to 'fire' state...
setTargetColor(r, modeData[mode].hue,
FIRE_SAT, FIRE_VALUE, FIRE_SAT, FIRE_VALUE);
}
for(startInterp(7); interpolating; ); // ~1/4 sec ramp up..."boom"
setRingsToIdleValues(); // Fade back to prior colors
for(startInterp(120); interpolating; ); // ~4 sec cool-down
brightRing = N_RINGS - 1; // Resume @ center after firing
waitForButtonRelease();
}
void loop() {
uint8_t pinState, priorPinState, debounceCounter, nextAction = 0;
// For next transition...first, set bright ring back to idle color...
setTargetColor(brightRing, modeData[mode].hue,
IDLE_PEAK_SAT, IDLE_PEAK_VALUE, IDLE_TROUGH_SAT, IDLE_TROUGH_VALUE);
if(++brightRing >= N_RINGS) brightRing = 0; // Next ring
// ...then set new ring to bright state...
setTargetColor(brightRing, modeData[mode].hue, BRIGHT_PEAK_SAT,
BRIGHT_PEAK_VALUE, BRIGHT_TROUGH_SAT, BRIGHT_TROUGH_VALUE);
startInterp(18); // Start pulse transition, about 2/3 sec
// While the transition takes place, we can do other things, like
// poll the buttons for mode change or fire events...
priorPinState = digitalRead(MODEPIN) + (digitalRead(FIREPIN) << 1);
debounceCounter = 0;
while(interpolating) { // Still transitioning...
if(nextAction) continue; // Once action is decided, stop polling buttons
pinState = digitalRead(MODEPIN) + (digitalRead(FIREPIN) << 1);
if(pinState == priorPinState) {
if(++debounceCounter >= DEBOUNCE) nextAction = pinState;
} else {
debounceCounter = 0;
priorPinState = pinState;
}
}
// Downside is that mode/fire actions don't take place until the prior
// transition ends (worst case, about 2/3 sec.), so this sometimes
// requires a bit of button mashing. I'd been working on making the
// pulse transitions interruptible but ran out of code space. Ah well,
// it's for a fun cosplay thing, not a cure for rocket surgery.
if(nextAction == 1) nextMode();
else if(nextAction == 2) fire();
}
// Set ring colors for the next transition
void setTargetColor(
uint8_t r, int16_t h, // Ring index, hue
uint8_t sPeak , uint8_t vPeak, // Saturation & value @ peak
uint8_t sTrough, uint8_t vTrough) { // Saturation & value @ trough
uint32_t cPeak = hsv2rgb(h, sPeak , vPeak), // Color @ peak
cTrough = hsv2rgb(h, sTrough, vTrough); // Color @ trough
ring[r].color[1][0][0] = cPeak >> 16;
ring[r].color[1][0][1] = cPeak >> 8;
ring[r].color[1][0][2] = cPeak;
ring[r].color[1][1][0] = cTrough >> 16;
ring[r].color[1][1][1] = cTrough >> 8;
ring[r].color[1][1][2] = cTrough;
}
// Set ring speed for the next transition
void setTargetSpeed(uint8_t r, int16_t s) {
ring[r].spd[1] = s;
ring[r].peak[1] = (s > 0) ? 48 : 208;
}
// Begin transition
void startInterp(uint8_t n) {
interpFrames = n;
interpolating = n;
}
// -------------------------------------------------------------------------
// Fixed-point colorspace conversion: HSV (hue-saturation-value) to RGB.
uint32_t hsv2rgb(int16_t h, uint8_t s, uint8_t v) {
uint8_t n, r, g, b;
// Hue circle = 1530 circumference (NOT 1536!)
h %= 1530; // -1529 to +1529
if(h < 0) h += 1530; // 0 to +1529
n = h % 255; // Angle within sextant; 0 to 254 (NOT 255!)
switch(h / 255) { // Sextant number; 0 to 5
case 0 : r = 255 ; g = n ; b = 0 ; break; // R to Y
case 1 : r = 254 - n; g = 255 ; b = 0 ; break; // Y to G
case 2 : r = 0 ; g = 255 ; b = n ; break; // G to C
case 3 : r = 0 ; g = 254 - n; b = 255 ; break; // C to B
case 4 : r = n ; g = 0 ; b = 255 ; break; // B to M
default: r = 255 ; g = 0 ; b = 254 - n; break; // M to R
}
uint32_t v1 = 1 + v; // 1 to 256; allows >>8 instead of /255
uint16_t s1 = 1 + s; // 1 to 256; same reason
uint8_t s2 = 255 - s; // 255 to 0
return ((((((r * s1) >> 8) + s2) * v1) & 0xff00) << 8) | // MAF!
(((((g * s1) >> 8) + s2) * v1) & 0xff00) |
( ((((b * s1) >> 8) + s2) * v1) >> 8);
}
ISR(TIMER1_OVF_vect) { // Timer/Counter 1 overflow, configured for ~30 Hz
uint8_t i, r, y, l, x8;
uint16_t ps, ts, x, xinc, n;
// Refresh the strip with results calculated during the -prior- frame.
// Ensures a uniform frame rate; calc time for each frame may vary.
strip.show();
for(r=0; r<N_RINGS; r++) { // For each ring...
l = ring[r].firstLED; // l = current LED index
x = ring[r].phase; // x = ring rotation (65536 = 360 degrees)
xinc = (uint16_t)(65536L * ring[r].reps / ring[r].nLEDs);
for(i=0; i<ring[r].nLEDs; i++, x += xinc) { // Each LED on current ring...
x8 = x >> 8;
y = (x8 < ring[r].peak[2] ) ? // Which side of triangle wave?
( (uint16_t)x8 * 255) / ring[r].peak[2] : // Rising edge
((256 - (uint16_t)x8) * 255) / (256 - ring[r].peak[2]); // Falling edge
// y is blending factor (0-255) between peak & trough colors
ps = y + 1; // Peak color scale factor (1-256)
ts = 257 - ps; // Trough color scale factor (1-256, inverse of peak)
// Blend peak & trough RGB, process through gamma correction table
strip.setPixelColor(l++, // and store resulting color
pgm_read_byte(&gamma[(ring[r].color[2][0][0] * ps +
ring[r].color[2][1][0] * ts) >> 8]),
pgm_read_byte(&gamma[(ring[r].color[2][0][1] * ps +
ring[r].color[2][1][1] * ts) >> 8]),
pgm_read_byte(&gamma[(ring[r].color[2][0][2] * ps +
ring[r].color[2][1][2] * ts) >> 8]));
}
ring[r].phase += ring[r].spd[2]; // Rotate ring for next frame
}
if(interpolating) { // Frame-to-frame speed & color interpolation
if(!--interpolating) { // Interpolation target reached?
// Set current & prior color & speed to target values
for(r=0; r<N_RINGS; r++) {
for(x=0; x<2; x++) {
for(i=0; i<3; i++) {
ring[r].color[2][x] = ring[r].color[1][x];
ring[r].color[0][x] = ring[r].color[1][x];
}
}
ring[r].spd[2] = ring[r].spd[0] = ring[r].spd[1];
ring[r].peak[2] = ring[r].peak[0] = ring[r].peak[1];
}
} else {
n = 257 - (((uint16_t)interpolating << 8) / interpFrames);
for(r=0; r<N_RINGS; r++) { // For each ring...
ring[r].spd[2] = ring[r].spd[0] +
(((uint32_t)(ring[r].spd[1] - ring[r].spd[0]) * n) >> 8);
ring[r].peak[2] = ring[r].peak[0] +
(((uint32_t)(ring[r].peak[1] - ring[r].peak[0]) * n) >> 8);
for(x=0; x<2; x++) { // Wave peak, trough
for(i=0; i<3; i++) { // R,G,B
ring[r].color[2][x] = ring[r].color[0][x] +
(((ring[r].color[1][x] - ring[r].color[0][x]) * n) >> 8);
}
}
}
}
}
}
const uint8_t PROGMEM
gamma[] = { // x^2.8 improves appearance of midrange colors
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1,
1, 1, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2, 2, 2, 2,
2, 3, 3, 3, 3, 3, 3, 3, 4, 4, 4, 4, 4, 5, 5, 5,
5, 6, 6, 6, 6, 7, 7, 7, 7, 8, 8, 8, 9, 9, 9, 10,
10, 10, 11, 11, 11, 12, 12, 13, 13, 13, 14, 14, 15, 15, 16, 16,
17, 17, 18, 18, 19, 19, 20, 20, 21, 21, 22, 22, 23, 24, 24, 25,
25, 26, 27, 27, 28, 29, 29, 30, 31, 32, 32, 33, 34, 35, 35, 36,
37, 38, 39, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 50,
51, 52, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 66, 67, 68,
69, 70, 72, 73, 74, 75, 77, 78, 79, 81, 82, 83, 85, 86, 87, 89,
90, 92, 93, 95, 96, 98, 99,101,102,104,105,107,109,110,112,114,
115,117,119,120,122,124,126,127,129,131,133,135,137,138,140,142,
144,146,148,150,152,154,156,158,160,162,164,167,169,171,173,175,
177,180,182,184,186,189,191,193,196,198,200,203,205,208,210,213,
215,218,220,223,225,228,231,233,236,239,241,244,247,249,252,255 };



I found my Problem, i just forgot to copy the right line.

thanks

 

[ShaunDark80]

Glad you got it working.

 

[bobatrek]

That's something I would buy - an arc reactor lamp!