adafruit_support_bill

by dmnagy6192 on Thu Aug 22, 2019 11:46 pm

I recently purchased a Rugged Metal RGB Momentary Pushbutton (https://www.adafruit.com/product/3350) for use in my current project. When pressed, it changes the pattern being displayed on a strip of NeoPixels.

My code for the NeoPixels and function of the button is working fine but I am having trouble with the color displayed on the RGB button itself. I would like the RGB button to cycle through a handful of colors (as seen in the "New Product" video it is featured in on YouTube); however it is only displaying White.

Prior to adding this button to my project, I tested it using the RGB LED example code (https://learn.adafruit.com/adafruit-ard ... ino-sketch) and the given colors cycled through as expected.

How would I combine the example code (above) into my current project? I tried to simply cut and paste the example code into my project's code but the RGB only displayed white.

I am very new to programming so I apologize if any of this was confusing or if my code is a bit messy.

I am using an Arduino Uno R3 with the following attached:
5v > Common Cathode
Red Anode > PIN11
Green Anode > PIN10
Blue Anode > PIN9
Button > PIN 2 & Ground
NeoPixels > PIN6

Code: Select all | TOGGLE FULL SIZE: #include <Adafruit_NeoPixel.h> #include <EEPROM.h> #ifdef __AVR__ #include <avr/power.h> #endif #define NUM_LEDS 59 #define PIN 6 Adafruit_NeoPixel strip = Adafruit_NeoPixel(NUM_LEDS, PIN, NEO_GRB + NEO_KHZ800); #define BUTTON 2 //button must be on pin 2 or 3 when used as interrupt! byte selectedEffect=0; //definition of RGB button int redPin = 11; int greenPin = 10; int bluePin = 9; //uncomment this line if using a Common Anode LED //#define COMMON_ANODE void setup() { strip.begin(); strip.show(); // Initialize all pixels to 'off' digitalWrite (BUTTON, HIGH); // internal pull-up resistor attachInterrupt (digitalPinToInterrupt (BUTTON), changeEffect, CHANGE); // pressed pinMode(redPin, OUTPUT); pinMode(greenPin, OUTPUT); pinMode(bluePin, OUTPUT); } // *** REPLACE FROM HERE *** void loop(){ EEPROM.get(0,selectedEffect); if(selectedEffect>18) { selectedEffect=0; EEPROM.put(0,0); } //begin button commands switch(selectedEffect) { case 0 : { // RGBLoop - no parameters RGBLoop(); break; } case 1 : { // FadeInOut - Color (red, green. blue) FadeInOut(0xff, 0x00, 0x00); // red FadeInOut(0xff, 0xff, 0xff); // white FadeInOut(0x00, 0x00, 0xff); // blue break; } case 2 : { // Strobe - Color (red, green, blue), number of flashes, flash speed, end pause Strobe(0xff, 0xff, 0xff, 10, 50, 1000); break; } case 3 : { // HalloweenEyes - Color (red, green, blue), Size of eye, space between eyes, fade (true/false), steps, fade delay, end pause HalloweenEyes(0xff, 0x00, 0x00, 1, 4, true, random(5,50), random(50,150), random(1000, 10000)); HalloweenEyes(0xff, 0x00, 0x00, 1, 4, true, random(5,50), random(50,150), random(1000, 10000)); break; } case 4 : { // CylonBounce - Color (red, green, blue), eye size, speed delay, end pause CylonBounce(0xff, 0x00, 0x00, 4, 10, 50); break; } case 5 : { // NewKITT - Color (red, green, blue), eye size, speed delay, end pause NewKITT(0xff, 0x00, 0x00, 8, 10, 50); break; } case 6 : { // Twinkle - Color (red, green, blue), count, speed delay, only one twinkle (true/false) Twinkle(0xff, 0x00, 0x00, 10, 100, false); break; } case 7 : { // TwinkleRandom - twinkle count, speed delay, only one (true/false) TwinkleRandom(20, 100, false); break; } case 8 : { // Sparkle - Color (red, green, blue), speed delay Sparkle(0xff, 0xff, 0xff, 0); break; } case 9 : { // SnowSparkle - Color (red, green, blue), sparkle delay, speed delay SnowSparkle(0x10, 0x10, 0x10, 20, random(100,1000)); break; } case 10 : { // Running Lights - Color (red, green, blue), wave dealy RunningLights(0xff,0x00,0x00, 50); // red RunningLights(0xff,0xff,0xff, 50); // white RunningLights(0x00,0x00,0xff, 50); // blue break; } case 11 : { // colorWipe - Color (red, green, blue), speed delay colorWipe(0x00,0xff,0x00, 50); colorWipe(0x00,0x00,0x00, 50); break; } case 12 : { // rainbowCycle - speed delay rainbowCycle(20); break; } case 13 : { // theatherChase - Color (red, green, blue), speed delay theaterChase(0xff,0,0,50); break; } case 14 : { // theaterChaseRainbow - Speed delay theaterChaseRainbow(50); break; } case 15 : { // Fire - Cooling rate, Sparking rate, speed delay Fire(55,120,15); break; } // simple bouncingBalls not included, since BouncingColoredBalls can perform this as well as shown below // BouncingColoredBalls - Number of balls, color (red, green, blue) array, continuous // CAUTION: If set to continuous then this effect will never stop!!! case 16 : { // mimic BouncingBalls byte onecolor[1][3] = { {0xff, 0x00, 0x00} }; BouncingColoredBalls(1, onecolor, false); break; } case 17 : { // multiple colored balls byte colors[3][3] = { {0xff, 0x00, 0x00}, {0xff, 0xff, 0xff}, {0x00, 0x00, 0xff} }; BouncingColoredBalls(3, colors, false); break; } case 18 : { // meteorRain - Color (red, green, blue), meteor size, trail decay, random trail decay (true/false), speed delay meteorRain(0xff,0xff,0xff,10, 64, true, 30); break; } } } void changeEffect() { if (digitalRead (BUTTON) == HIGH) { selectedEffect++; EEPROM.put(0, selectedEffect); asm volatile (" jmp 0"); } } // ************************* // ** LEDEffect Functions ** // ************************* void RGBLoop(){ for(int j = 0; j < 3; j++ ) { // Fade IN for(int k = 0; k < 256; k++) { switch(j) { case 0: setAll(k,0,0); break; case 1: setAll(0,k,0); break; case 2: setAll(0,0,k); break; } showStrip(); delay(3); } // Fade OUT for(int k = 255; k >= 0; k--) { switch(j) { case 0: setAll(k,0,0); break; case 1: setAll(0,k,0); break; case 2: setAll(0,0,k); break; } showStrip(); delay(3); } } } void FadeInOut(byte red, byte green, byte blue){ float r, g, b; for(int k = 0; k < 256; k=k+1) { r = (k/256.0)*red; g = (k/256.0)*green; b = (k/256.0)*blue; setAll(r,g,b); showStrip(); } for(int k = 255; k >= 0; k=k-2) { r = (k/256.0)*red; g = (k/256.0)*green; b = (k/256.0)*blue; setAll(r,g,b); showStrip(); } } void Strobe(byte red, byte green, byte blue, int StrobeCount, int FlashDelay, int EndPause){ for(int j = 0; j < StrobeCount; j++) { setAll(red,green,blue); showStrip(); delay(FlashDelay); setAll(0,0,0); showStrip(); delay(FlashDelay); } delay(EndPause); } void HalloweenEyes(byte red, byte green, byte blue, int EyeWidth, int EyeSpace, boolean Fade, int Steps, int FadeDelay, int EndPause){ randomSeed(analogRead(0)); int i; int StartPoint = random( 0, NUM_LEDS - (2*EyeWidth) - EyeSpace ); int Start2ndEye = StartPoint + EyeWidth + EyeSpace; for(i = 0; i < EyeWidth; i++) { setPixel(StartPoint + i, red, green, blue); setPixel(Start2ndEye + i, red, green, blue); } showStrip(); if(Fade==true) { float r, g, b; for(int j = Steps; j >= 0; j--) { r = j*(red/Steps); g = j*(green/Steps); b = j*(blue/Steps); for(i = 0; i < EyeWidth; i++) { setPixel(StartPoint + i, r, g, b); setPixel(Start2ndEye + i, r, g, b); } showStrip(); delay(FadeDelay); } } setAll(0,0,0); // Set all black delay(EndPause); } void CylonBounce(byte red, byte green, byte blue, int EyeSize, int SpeedDelay, int ReturnDelay){ for(int i = 0; i < NUM_LEDS-EyeSize-2; i++) { setAll(0,0,0); setPixel(i, red/10, green/10, blue/10); for(int j = 1; j <= EyeSize; j++) { setPixel(i+j, red, green, blue); } setPixel(i+EyeSize+1, red/10, green/10, blue/10); showStrip(); delay(SpeedDelay); } delay(ReturnDelay); for(int i = NUM_LEDS-EyeSize-2; i > 0; i--) { setAll(0,0,0); setPixel(i, red/10, green/10, blue/10); for(int j = 1; j <= EyeSize; j++) { setPixel(i+j, red, green, blue); } setPixel(i+EyeSize+1, red/10, green/10, blue/10); showStrip(); delay(SpeedDelay); } delay(ReturnDelay); } void NewKITT(byte red, byte green, byte blue, int EyeSize, int SpeedDelay, int ReturnDelay){ RightToLeft(red, green, blue, EyeSize, SpeedDelay, ReturnDelay); LeftToRight(red, green, blue, EyeSize, SpeedDelay, ReturnDelay); OutsideToCenter(red, green, blue, EyeSize, SpeedDelay, ReturnDelay); CenterToOutside(red, green, blue, EyeSize, SpeedDelay, ReturnDelay); LeftToRight(red, green, blue, EyeSize, SpeedDelay, ReturnDelay); RightToLeft(red, green, blue, EyeSize, SpeedDelay, ReturnDelay); OutsideToCenter(red, green, blue, EyeSize, SpeedDelay, ReturnDelay); CenterToOutside(red, green, blue, EyeSize, SpeedDelay, ReturnDelay); } // used by NewKITT void CenterToOutside(byte red, byte green, byte blue, int EyeSize, int SpeedDelay, int ReturnDelay) { for(int i =((NUM_LEDS-EyeSize)/2); i>=0; i--) { setAll(0,0,0); setPixel(i, red/10, green/10, blue/10); for(int j = 1; j <= EyeSize; j++) { setPixel(i+j, red, green, blue); } setPixel(i+EyeSize+1, red/10, green/10, blue/10); setPixel(NUM_LEDS-i, red/10, green/10, blue/10); for(int j = 1; j <= EyeSize; j++) { setPixel(NUM_LEDS-i-j, red, green, blue); } setPixel(NUM_LEDS-i-EyeSize-1, red/10, green/10, blue/10); showStrip(); delay(SpeedDelay); } delay(ReturnDelay); } // used by NewKITT void OutsideToCenter(byte red, byte green, byte blue, int EyeSize, int SpeedDelay, int ReturnDelay) { for(int i = 0; i<=((NUM_LEDS-EyeSize)/2); i++) { setAll(0,0,0); setPixel(i, red/10, green/10, blue/10); for(int j = 1; j <= EyeSize; j++) { setPixel(i+j, red, green, blue); } setPixel(i+EyeSize+1, red/10, green/10, blue/10); setPixel(NUM_LEDS-i, red/10, green/10, blue/10); for(int j = 1; j <= EyeSize; j++) { setPixel(NUM_LEDS-i-j, red, green, blue); } setPixel(NUM_LEDS-i-EyeSize-1, red/10, green/10, blue/10); showStrip(); delay(SpeedDelay); } delay(ReturnDelay); } // used by NewKITT void LeftToRight(byte red, byte green, byte blue, int EyeSize, int SpeedDelay, int ReturnDelay) { for(int i = 0; i < NUM_LEDS-EyeSize-2; i++) { setAll(0,0,0); setPixel(i, red/10, green/10, blue/10); for(int j = 1; j <= EyeSize; j++) { setPixel(i+j, red, green, blue); } setPixel(i+EyeSize+1, red/10, green/10, blue/10); showStrip(); delay(SpeedDelay); } delay(ReturnDelay); } // used by NewKITT void RightToLeft(byte red, byte green, byte blue, int EyeSize, int SpeedDelay, int ReturnDelay) { for(int i = NUM_LEDS-EyeSize-2; i > 0; i--) { setAll(0,0,0); setPixel(i, red/10, green/10, blue/10); for(int j = 1; j <= EyeSize; j++) { setPixel(i+j, red, green, blue); } setPixel(i+EyeSize+1, red/10, green/10, blue/10); showStrip(); delay(SpeedDelay); } delay(ReturnDelay); } void Twinkle(byte red, byte green, byte blue, int Count, int SpeedDelay, boolean OnlyOne) { setAll(0,0,0); for (int i=0; i<Count; i++) { setPixel(random(NUM_LEDS),red,green,blue); showStrip(); delay(SpeedDelay); if(OnlyOne) { setAll(0,0,0); } } delay(SpeedDelay); } void TwinkleRandom(int Count, int SpeedDelay, boolean OnlyOne) { setAll(0,0,0); for (int i=0; i<Count; i++) { setPixel(random(NUM_LEDS),random(0,255),random(0,255),random(0,255)); showStrip(); delay(SpeedDelay); if(OnlyOne) { setAll(0,0,0); } } delay(SpeedDelay); } void Sparkle(byte red, byte green, byte blue, int SpeedDelay) { int Pixel = random(NUM_LEDS); setPixel(Pixel,red,green,blue); showStrip(); delay(SpeedDelay); setPixel(Pixel,0,0,0); } void SnowSparkle(byte red, byte green, byte blue, int SparkleDelay, int SpeedDelay) { setAll(red,green,blue); int Pixel = random(NUM_LEDS); setPixel(Pixel,0xff,0xff,0xff); showStrip(); delay(SparkleDelay); setPixel(Pixel,red,green,blue); showStrip(); delay(SpeedDelay); } void RunningLights(byte red, byte green, byte blue, int WaveDelay) { int Position=0; for(int i=0; i<NUM_LEDS*2; i++) { Position++; // = 0; //Position + Rate; for(int i=0; i<NUM_LEDS; i++) { // sine wave, 3 offset waves make a rainbow! //float level = sin(i+Position) * 127 + 128; //setPixel(i,level,0,0); //float level = sin(i+Position) * 127 + 128; setPixel(i,((sin(i+Position) * 127 + 128)/255)*red, ((sin(i+Position) * 127 + 128)/255)*green, ((sin(i+Position) * 127 + 128)/255)*blue); } showStrip(); delay(WaveDelay); } } void colorWipe(byte red, byte green, byte blue, int SpeedDelay) { for(uint16_t i=0; i<NUM_LEDS; i++) { setPixel(i, red, green, blue); showStrip(); delay(SpeedDelay); } } void rainbowCycle(int SpeedDelay) { byte *c; uint16_t i, j; for(j=0; j<256*5; j++) { // 5 cycles of all colors on wheel for(i=0; i< NUM_LEDS; i++) { c=Wheel(((i * 256 / NUM_LEDS) + j) & 255); setPixel(i, *c, *(c+1), *(c+2)); } showStrip(); delay(SpeedDelay); } } // used by rainbowCycle and theaterChaseRainbow byte * Wheel(byte WheelPos) { static byte c[3]; if(WheelPos < 85) { c[0]=WheelPos * 3; c[1]=255 - WheelPos * 3; c[2]=0; } else if(WheelPos < 170) { WheelPos -= 85; c[0]=255 - WheelPos * 3; c[1]=0; c[2]=WheelPos * 3; } else { WheelPos -= 170; c[0]=0; c[1]=WheelPos * 3; c[2]=255 - WheelPos * 3; } return c; } void theaterChase(byte red, byte green, byte blue, int SpeedDelay) { for (int j=0; j<10; j++) { //do 10 cycles of chasing for (int q=0; q < 3; q++) { for (int i=0; i < NUM_LEDS; i=i+3) { setPixel(i+q, red, green, blue); //turn every third pixel on } showStrip(); delay(SpeedDelay); for (int i=0; i < NUM_LEDS; i=i+3) { setPixel(i+q, 0,0,0); //turn every third pixel off } } } } void theaterChaseRainbow(int SpeedDelay) { byte *c; for (int j=0; j < 256; j++) { // cycle all 256 colors in the wheel for (int q=0; q < 3; q++) { for (int i=0; i < NUM_LEDS; i=i+3) { c = Wheel( (i+j) % 255); setPixel(i+q, *c, *(c+1), *(c+2)); //turn every third pixel on } showStrip(); delay(SpeedDelay); for (int i=0; i < NUM_LEDS; i=i+3) { setPixel(i+q, 0,0,0); //turn every third pixel off } } } } void Fire(int Cooling, int Sparking, int SpeedDelay) { static byte heat[NUM_LEDS]; int cooldown; // Step 1. Cool down every cell a little for( int i = 0; i < NUM_LEDS; i++) { cooldown = random(0, ((Cooling * 10) / NUM_LEDS) + 2); if(cooldown>heat[i]) { heat[i]=0; } else { heat[i]=heat[i]-cooldown; } } // Step 2. Heat from each cell drifts 'up' and diffuses a little for( int k= NUM_LEDS - 1; k >= 2; k--) { heat[k] = (heat[k - 1] + heat[k - 2] + heat[k - 2]) / 3; } // Step 3. Randomly ignite new 'sparks' near the bottom if( random(255) < Sparking ) { int y = random(7); heat[y] = heat[y] + random(160,255); //heat[y] = random(160,255); } // Step 4. Convert heat to LED colors for( int j = 0; j < NUM_LEDS; j++) { setPixelHeatColor(j, heat[j] ); } showStrip(); delay(SpeedDelay); } void setPixelHeatColor (int Pixel, byte temperature) { // Scale 'heat' down from 0-255 to 0-191 byte t192 = round((temperature/255.0)*191); // calculate ramp up from byte heatramp = t192 & 0x3F; // 0..63 heatramp <<= 2; // scale up to 0..252 // figure out which third of the spectrum we're in: if( t192 > 0x80) { // hottest setPixel(Pixel, 255, 255, heatramp); } else if( t192 > 0x40 ) { // middle setPixel(Pixel, 255, heatramp, 0); } else { // coolest setPixel(Pixel, heatramp, 0, 0); } } void BouncingColoredBalls(int BallCount, byte colors[][3], boolean continuous) { float Gravity = -9.81; int StartHeight = 1; float Height[BallCount]; float ImpactVelocityStart = sqrt( -2 * Gravity * StartHeight ); float ImpactVelocity[BallCount]; float TimeSinceLastBounce[BallCount]; int Position[BallCount]; long ClockTimeSinceLastBounce[BallCount]; float Dampening[BallCount]; boolean ballBouncing[BallCount]; boolean ballsStillBouncing = true; for (int i = 0 ; i < BallCount ; i++) { ClockTimeSinceLastBounce[i] = millis(); Height[i] = StartHeight; Position[i] = 0; ImpactVelocity[i] = ImpactVelocityStart; TimeSinceLastBounce[i] = 0; Dampening[i] = 0.90 - float(i)/pow(BallCount,2); ballBouncing[i]=true; } while (ballsStillBouncing) { for (int i = 0 ; i < BallCount ; i++) { TimeSinceLastBounce[i] = millis() - ClockTimeSinceLastBounce[i]; Height[i] = 0.5 * Gravity * pow( TimeSinceLastBounce[i]/1000 , 2.0 ) + ImpactVelocity[i] * TimeSinceLastBounce[i]/1000; if ( Height[i] < 0 ) { Height[i] = 0; ImpactVelocity[i] = Dampening[i] * ImpactVelocity[i]; ClockTimeSinceLastBounce[i] = millis(); if ( ImpactVelocity[i] < 0.01 ) { if (continuous) { ImpactVelocity[i] = ImpactVelocityStart; } else { ballBouncing[i]=false; } } } Position[i] = round( Height[i] * (NUM_LEDS - 1) / StartHeight); } ballsStillBouncing = false; // assume no balls bouncing for (int i = 0 ; i < BallCount ; i++) { setPixel(Position[i],colors[i][0],colors[i][1],colors[i][2]); if ( ballBouncing[i] ) { ballsStillBouncing = true; } } showStrip(); setAll(0,0,0); } } void meteorRain(byte red, byte green, byte blue, byte meteorSize, byte meteorTrailDecay, boolean meteorRandomDecay, int SpeedDelay) { setAll(0,0,0); for(int i = 0; i < NUM_LEDS+NUM_LEDS; i++) { // fade brightness all LEDs one step for(int j=0; j<NUM_LEDS; j++) { if( (!meteorRandomDecay) || (random(10)>5) ) { fadeToBlack(j, meteorTrailDecay ); } } // draw meteor for(int j = 0; j < meteorSize; j++) { if( ( i-j <NUM_LEDS) && (i-j>=0) ) { setPixel(i-j, red, green, blue); } } showStrip(); delay(SpeedDelay); } } // used by meteorrain void fadeToBlack(int ledNo, byte fadeValue) { #ifdef ADAFRUIT_NEOPIXEL_H // NeoPixel uint32_t oldColor; uint8_t r, g, b; int value; oldColor = strip.getPixelColor(ledNo); r = (oldColor & 0x00ff0000UL) >> 16; g = (oldColor & 0x0000ff00UL) >> 8; b = (oldColor & 0x000000ffUL); r=(r<=10)? 0 : (int) r-(r*fadeValue/256); g=(g<=10)? 0 : (int) g-(g*fadeValue/256); b=(b<=10)? 0 : (int) b-(b*fadeValue/256); strip.setPixelColor(ledNo, r,g,b); #endif #ifndef ADAFRUIT_NEOPIXEL_H // FastLED leds[ledNo].fadeToBlackBy( fadeValue ); #endif } // *** REPLACE TO HERE *** // *************************************** // ** FastLed/NeoPixel Common Functions ** // *************************************** // Apply LED color changes void showStrip() { #ifdef ADAFRUIT_NEOPIXEL_H // NeoPixel strip.show(); #endif #ifndef ADAFRUIT_NEOPIXEL_H // FastLED FastLED.show(); #endif } // Set a LED color (not yet visible) void setPixel(int Pixel, byte red, byte green, byte blue) { #ifdef ADAFRUIT_NEOPIXEL_H // NeoPixel strip.setPixelColor(Pixel, strip.Color(red, green, blue)); #endif #ifndef ADAFRUIT_NEOPIXEL_H // FastLED leds[Pixel].r = red; leds[Pixel].g = green; leds[Pixel].b = blue; #endif } // Set all LEDs to a given color and apply it (visible) void setAll(byte red, byte green, byte blue) { for(int i = 0; i < NUM_LEDS; i++ ) { setPixel(i, red, green, blue); } showStrip(); } // *************************************** // ** RGB LED Color Setting ** // *************************************** { setColor(255, 0, 0); // red delay(1000); setColor(0, 255, 0); // green delay(1000); setColor(0, 0, 255); // blue delay(1000); setColor(255, 255, 0); // yellow delay(1000); setColor(80, 0, 80); // purple delay(1000); setColor(0, 255, 255); // aqua delay(1000); setColor(0x48, 0x0, 0x82); // indigo delay(1000); } void setColor(int red, int green, int blue) { #ifdef COMMON_ANODE red = 255 - red; green = 255 - green; blue = 255 - blue; #endif analogWrite(redPin, red); analogWrite(greenPin, green); analogWrite(bluePin, blue); }

by dastels on Fri Sep 13, 2019 4:42 pm

First, you have anode/cathode mixed up. The product page says it's common anode (1 anode, 3 cathodes)

Code: Select all | TOGGLE FULL SIZE: 5v > Common Cathode Red Anode > PIN11 Green Anode > PIN10 Blue Anode > PIN9

Also, this doesn't even compile. It's the "RGB LED Color Setting" code you pasted in. There's a bare block of code... not a function.

But conceptually you need to have your code doing two things at a time: the neopixel effect and the switch LED colour cycling.

The code as it was written can't do that... a neopixel effect function gets called and plays the effect until it's finished, then returns to loop(). It will pretty much have to be rewritten to do both things. This is an example of concurrent computation.

A side note: The switch is a simple pushbutton, and as such is very noisy. When you push it the contacts will bounce for a brief time before settling into a closed position. You can't use that directly to drive an interrupt since you'll get an interrupt with each bounce. If you want to use an interrupt you'll need to electrically debounce the switch. Easier is to use the debounce2 library to debounce it in software and check it regularly. But that, too, would require rewriting it to be concurrent.

Two books to read, both by Simon Monk, are:
Programming Arduino
Programming Arduino: Next Steps

Dave

RGB Push Button Code Moderators: adafruit_support_bill, adafruit

RGB Push Button Code
Moderators: adafruit_support_bill, adafruit