Thank you for your reply! Apologies for taking so long.
Below is the code in its entirety. My problem is that I'm rather new to this and am employing what many people describe as "brute force" coding. No argument here...
So my issue with this is that I have no inkling where to start with your suggestion. Like I stated above, no matter where I put the image code in the block, I get errors. I would be ecstatic if I had a flashing screen as long as the image displayed... then I would be able to parse out your instructions. Can you please help me with this? Thanks so much!
Code: Select all
#include <Adafruit_Arcada.h>
#include <CircularBuffer.h>
#include <Adafruit_Sensor.h>
#include <Adafruit_LSM6DS33.h>
#include <Adafruit_LIS3MDL.h>
#include <Adafruit_SHT31.h>
#include <Adafruit_APDS9960.h>
#include <Adafruit_BMP280.h>
#include <PDM.h>
#include <Arcada_GifDecoder.h>
#include <Adafruit_AMG88xx.h> //8x8 thermal camera
// Thermal camera settings ---------------------------------------
Adafruit_AMG88xx amg;
float px[AMG88xx_PIXEL_ARRAY_SIZE];
const uint16_t dpw = 240/8; //, dph = 120/8; // box width in pixels?
const byte dpw18 = dpw/1.8; // scale down by roughly 2x
byte MAXTEMP[6]={30, 25, 32, 40, 50, 80 };
byte MINTEMP[6]={25, 20, 15, 10, 0, 0 };
byte tempScale = 2; //0-4 for various fixed ranges; 5=auto ranging
Adafruit_Arcada arcada;
Adafruit_LSM6DS33 lsm6ds33;
Adafruit_LIS3MDL lis3mdl;
Adafruit_SHT31 sht30;
Adafruit_APDS9960 apds9960;
Adafruit_BMP280 bmp280;
extern PDMClass PDM;
GifDecoder<ARCADA_TFT_WIDTH, ARCADA_TFT_HEIGHT, 12> decoder;
File file;
#define WHITE_LED 43
// Color definitions
#define BACKGROUND_COLOR __builtin_bswap16(ARCADA_BLACK)
#define BORDER_COLOR __builtin_bswap16(ARCADA_BLUE)
#define PLOT_COLOR_1 __builtin_bswap16(ARCADA_PINK)
#define PLOT_COLOR_2 __builtin_bswap16(ARCADA_GREENYELLOW)
#define PLOT_COLOR_3 __builtin_bswap16(ARCADA_CYAN)
#define TITLE_COLOR __builtin_bswap16(ARCADA_WHITE)
#define TICKTEXT_COLOR __builtin_bswap16(ARCADA_WHITE)
#define TICKLINE_COLOR __builtin_bswap16(ARCADA_DARKGREY)
const uint16_t camColors[] = {
0x0011,0x0031,0x00B2,0x0112,0x0192,0x01F3,0x0273,0x02F3,
0x03F4,0x0514,0x0572,0x058F,0x05AD,0x05C9, 0x05E5,0x0621,
0x2E40,0x4E80,0x76A0,0x9EC0,0xCEE0,0xE660,0xE520,0xEBE0,
0xEB40,0xEAA0,0xF200,0xF140,0xF100,0xF0C0,0xF080,0xF040,0xF800};
// Buffers surrounding the plot area
#define PLOT_TOPBUFFER 20
#define PLOT_LEFTBUFFER 40
#define PLOT_BOTTOMBUFFER 20
#define PLOT_W (ARCADA_TFT_WIDTH - PLOT_LEFTBUFFER)
#define PLOT_H (ARCADA_TFT_HEIGHT - PLOT_BOTTOMBUFFER - PLOT_TOPBUFFER)
// millisecond delay between samples
#define DELAY_PER_SAMPLE 50
void plotBuffer(GFXcanvas16 *_canvas, const char *title,
CircularBuffer<float, PLOT_W> &buffer1,
CircularBuffer<float, PLOT_W> &buffer2,
CircularBuffer<float, PLOT_W> &buffer3);
// Buffer for our plot data
CircularBuffer<float, PLOT_W> data_buffer;
CircularBuffer<float, PLOT_W> data_buffer2;
CircularBuffer<float, PLOT_W> data_buffer3;
int8_t sensornum = 0;
void setup(void) {
Serial.begin(115200);
Serial.print("Hello! Arcada CLUE sensor plotter");
//while (!Serial) yield();
amg.begin();
decoder.setScreenClearCallback(screenClearCallback);
decoder.setUpdateScreenCallback(updateScreenCallback);
decoder.setDrawPixelCallback(drawPixelCallback);
decoder.setDrawLineCallback(drawLineCallback);
decoder.setFileSeekCallback(fileSeekCallback);
decoder.setFilePositionCallback(filePositionCallback);
decoder.setFileReadCallback(fileReadCallback);
decoder.setFileReadBlockCallback(fileReadBlockCallback);
// Start TFT and fill black
if (!arcada.arcadaBegin()) {
Serial.print("Failed to begin");
while (1) delay(10);
}
arcada.displayBegin();
// Turn on backlight
arcada.setBacklight(255);
arcada.filesysBeginMSD();
arcada.filesysBegin();
if (! arcada.createFrameBuffer(ARCADA_TFT_WIDTH, ARCADA_TFT_HEIGHT)) {
Serial.print("Failed to allocate framebuffer");
while (1);
}
if (!apds9960.begin() || !lsm6ds33.begin_I2C() || !lis3mdl.begin_I2C() ||
!sht30.begin(0x44) || !bmp280.begin()) {
Serial.println("Failed to find CLUE sensors!");
arcada.haltBox("Failed to init CLUE sensors");
}
/********** Check MIC */
PDM.onReceive(onPDMdata);
if (!PDM.begin(1, 16000)) {
Serial.println("**Failed to start PDM!");
}
data_buffer.clear();
data_buffer2.clear();
data_buffer3.clear();
pinMode(WHITE_LED, OUTPUT);
digitalWrite(WHITE_LED, LOW);
file = arcada.openFileByIndex("/gifs", 0, O_READ, "GIF");
arcada.display->dmaWait();
arcada.display->endWrite(); // End transaction from any prior callback
decoder.startDecoding();
}
uint32_t timestamp = 0;
void loop() {
timestamp = millis();
arcada.readButtons();
uint8_t justPressed = arcada.justPressedButtons();
uint8_t justReleased = arcada.justReleasedButtons();
if (justReleased & ARCADA_BUTTONMASK_LEFT) {
sensornum--;
data_buffer.clear();
data_buffer2.clear();
data_buffer3.clear();
digitalWrite(WHITE_LED, LOW);
arcada.display->fillScreen(BACKGROUND_COLOR);
}
if (justReleased & ARCADA_BUTTONMASK_RIGHT) {
sensornum++;
data_buffer.clear();
data_buffer2.clear();
data_buffer3.clear();
digitalWrite(WHITE_LED, LOW);
arcada.display->fillScreen(BACKGROUND_COLOR);
}
if (sensornum == 0) {
decoder.decodeFrame();
}
else if (sensornum == 1) {
float t = bmp280.readTemperature();
data_buffer.push(t);
Serial.printf("Temp: %f\n", t);
plotBuffer(arcada.getCanvas(), "TEMP (C)",
data_buffer, data_buffer2, data_buffer3);
}
else if (sensornum == 2) {
float p = bmp280.readPressure();
data_buffer.push(p);
Serial.printf("Pressure: %f Pa\n", p);
plotBuffer(arcada.getCanvas(), "PASCELS",
data_buffer, data_buffer2, data_buffer3);
}
else if (sensornum == 3) {
float h = sht30.readHumidity();
data_buffer.push(h);
Serial.printf("Humid: %f %\n", h);
plotBuffer(arcada.getCanvas(),"HUMIDITY",
data_buffer, data_buffer2, data_buffer3);
}
else if (sensornum == 4) {
uint16_t r, g, b, c;
apds9960.enableColor(true);
//wait for color data to be ready
while(! apds9960.colorDataReady()) {
delay(5);
}
apds9960.getColorData(&r, &g, &b, &c);
data_buffer.push(c);
Serial.printf("Light: %d\n", c);
plotBuffer(arcada.getCanvas(),"LIGHT",
data_buffer, data_buffer2, data_buffer3);
}
else if (sensornum == 5) {
uint16_t r, g, b, c;
digitalWrite(WHITE_LED, HIGH);
apds9960.enableColor(true);
//wait for color data to be ready
while(! apds9960.colorDataReady()) {
delay(5);
}
apds9960.getColorData(&r, &g, &b, &c);
data_buffer.push(r);
data_buffer2.push(g);
data_buffer3.push(b);
Serial.printf("Color: %d %d %d\n", r, g, b);
plotBuffer(arcada.getCanvas(),"COLOR",
data_buffer, data_buffer2, data_buffer3);
}
// double db = 20.0 * log10 (sensorValue +1.);
else if (sensornum == 6) {
uint32_t pdm_vol = getPDMwave(256);
data_buffer.push(pdm_vol);
Serial.print("PDM volume: "); Serial.println(pdm_vol);
plotBuffer(arcada.getCanvas(), "VOLUME",
data_buffer, data_buffer2, data_buffer3);
}
else if (sensornum == 7) {
sensors_event_t accel;
lsm6ds33.getEvent(&accel, NULL, NULL);
float x = accel.acceleration.x;
float y = accel.acceleration.y;
float z = accel.acceleration.z;
data_buffer.push(x);
data_buffer2.push(y);
data_buffer3.push(z);
Serial.printf("Accel: %f %f %f\n", x, y, z);
plotBuffer(arcada.getCanvas(), "ACCEL",
data_buffer, data_buffer2, data_buffer3);
}
else if (sensornum == 8) {
sensors_event_t gyro;
lsm6ds33.getEvent(NULL, &gyro, NULL);
float x = gyro.gyro.x * SENSORS_RADS_TO_DPS;
float y = gyro.gyro.y * SENSORS_RADS_TO_DPS;
float z = gyro.gyro.z * SENSORS_RADS_TO_DPS;
data_buffer.push(x);
data_buffer2.push(y);
data_buffer3.push(z);
Serial.printf("Gyro: %f %f %f\n", x, y, z);
plotBuffer(arcada.getCanvas(), "GYRO",
data_buffer, data_buffer2, data_buffer3);
}
else if (sensornum == 9) {
sensors_event_t mag;
lis3mdl.getEvent(&mag);
float x = mag.magnetic.x;
float y = mag.magnetic.y;
float z = mag.magnetic.z;
data_buffer.push(x);
data_buffer2.push(y);
data_buffer3.push(z);
Serial.printf("Mag: %f %f %f\n", x, y, z);
plotBuffer(arcada.getCanvas(), "MAG",
data_buffer, data_buffer2, data_buffer3);
}
else if (sensornum == 10) { // test arcada plotting functions
amg.readPixels(px);
if ((tempScale % 6)==5){ //auto range
MINTEMP[5]=px[0];
MAXTEMP[5]=px[0];
for(int i=1; i<(AMG88xx_PIXEL_ARRAY_SIZE); i++){
//find min and max temps within frame
if (px[i]<MINTEMP[5]){MINTEMP[5]=px[i];}
if (px[i]>MAXTEMP[5]){MAXTEMP[5]=px[i];}// keep at least a 1 deg diff
}
};
for(int i=0; i<(AMG88xx_PIXEL_ARRAY_SIZE); i++){ // remove -8 ?
byte io8=dpw * (i % 8); //x pos
byte im8=dpw * (i / 8); //y pos
int col1=-1; //use one pixel to the left...
if ((i % 8)==0) {col1=1;} // unless we are in the first col, then use pixel to the right
int pxTmp=myPxTmp(px[i]);
arcada.display->fillRect(190-im8,io8, dpw18, dpw18, camColors[pxTmp]);
pxTmp=myPxTmp((px[i]+px[i+col1])/2);
arcada.display->fillRect(190-im8 + dpw18,io8 , dpw18, dpw18, camColors[pxTmp]);
pxTmp=myPxTmp((px[i]+px[i+8])/2);
arcada.display->fillRect(190-im8 ,io8+ dpw18, dpw18, dpw18, camColors[pxTmp]);
pxTmp=myPxTmp((px[i]+px[i+col1]+px[i+8])/3);
arcada.display->fillRect(190-im8 + dpw18,io8 + dpw18, dpw18, dpw18, camColors[pxTmp]);
}
}
else {
data_buffer.clear();
sensornum = 0;
return;
}
if ((sensornum > 0)&&(sensornum < 10)) {
arcada.blitFrameBuffer(0, 0, false, true);
}
//Serial.printf("Drew in %d ms\n", millis()-timestamp);
}
/**********************************************************************************/
void plotBuffer(GFXcanvas16 *_canvas, const char *title,
CircularBuffer<float, PLOT_W> &buffer1,
CircularBuffer<float, PLOT_W> &buffer2,
CircularBuffer<float, PLOT_W> &buffer3) {
_canvas->fillScreen(BACKGROUND_COLOR);
_canvas->drawLine(PLOT_LEFTBUFFER-1, PLOT_TOPBUFFER,
PLOT_LEFTBUFFER-1, PLOT_H+PLOT_TOPBUFFER, BORDER_COLOR);
_canvas->drawLine(PLOT_LEFTBUFFER-1, PLOT_TOPBUFFER+PLOT_H+1,
ARCADA_TFT_WIDTH, PLOT_TOPBUFFER+PLOT_H+1, BORDER_COLOR);
_canvas->setTextSize(3);
_canvas->setTextColor(TITLE_COLOR);
uint16_t title_len = strlen(title) * 12;
_canvas->setCursor((_canvas->width()-title_len)/2, 0);
_canvas->print(title);
float minY = 0;
float maxY = 0;
if (buffer1.size() > 0) {
maxY = minY = buffer1[0];
}
for (int i=0; i< buffer1.size(); i++) {
minY = min(minY, buffer1[i]);
maxY = max(maxY, buffer1[i]);
}
for (int i=0; i< buffer2.size(); i++) {
minY = min(minY, buffer2[i]);
maxY = max(maxY, buffer2[i]);
}
for (int i=0; i< buffer3.size(); i++) {
minY = min(minY, buffer3[i]);
maxY = max(maxY, buffer3[i]);
}
//Serial.printf("Data range: %f ~ %f\n", minY, maxY);
float MIN_DELTA = 10.0;
if (maxY - minY < MIN_DELTA) {
float mid = (maxY + minY) / 2;
maxY = mid + MIN_DELTA / 2;
minY = mid - MIN_DELTA / 2;
} else {
float extra = (maxY - minY) / 10;
maxY += extra;
minY -= extra;
}
//Serial.printf("Y range: %f ~ %f\n", minY, maxY);
printTicks(_canvas, 5, minY, maxY);
int16_t last_y = 0, last_x = 0;
for (int i=0; i<buffer1.size(); i++) {
int16_t y = mapf(buffer1[i], minY, maxY, PLOT_TOPBUFFER+PLOT_H, PLOT_TOPBUFFER);
int16_t x = PLOT_LEFTBUFFER+i;
if (i == 0) {
last_y = y;
last_x = x;
}
_canvas->drawLine(last_x, last_y, x, y, PLOT_COLOR_1);
last_x = x;
last_y = y;
}
last_y = 0, last_x = 0;
for (int i=0; i<buffer2.size(); i++) {
int16_t y = mapf(buffer2[i], minY, maxY, PLOT_TOPBUFFER+PLOT_H, PLOT_TOPBUFFER);
int16_t x = PLOT_LEFTBUFFER+i;
if (i == 0) {
last_y = y;
last_x = x;
}
_canvas->drawLine(last_x, last_y, x, y, PLOT_COLOR_2);
last_x = x;
last_y = y;
}
last_y = 0, last_x = 0;
for (int i=0; i<buffer3.size(); i++) {
int16_t y = mapf(buffer3[i], minY, maxY, PLOT_TOPBUFFER+PLOT_H, PLOT_TOPBUFFER);
int16_t x = PLOT_LEFTBUFFER+i;
if (i == 0) {
last_y = y;
last_x = x;
}
_canvas->drawLine(last_x, last_y, x, y, PLOT_COLOR_3);
last_x = x;
last_y = y;
}
}
void printTicks(GFXcanvas16 *_canvas, uint8_t ticks, float minY, float maxY) {
_canvas->setTextSize(2);
_canvas->setTextColor(TICKTEXT_COLOR);
// Draw ticks
for (int t=0; t<ticks; t++) {
float v = mapf(t, 0, ticks-1, minY, maxY);
uint16_t y = mapf(t, 0, ticks-1, ARCADA_TFT_HEIGHT - PLOT_BOTTOMBUFFER - 4, PLOT_TOPBUFFER);
printLabel(_canvas, 0, y, v);
uint16_t line_y = mapf(t, 0, ticks-1, ARCADA_TFT_HEIGHT - PLOT_BOTTOMBUFFER, PLOT_TOPBUFFER);
_canvas->drawLine(PLOT_LEFTBUFFER, line_y, ARCADA_TFT_WIDTH, line_y, TICKLINE_COLOR);
}
}
void printLabel(GFXcanvas16 *_canvas, uint16_t x, uint16_t y, float val) {
char label[20];
if (abs(val) < 1) {
snprintf(label, 19, "%0.2f", val);
} else if (abs(val) < 10) {
snprintf(label, 19, "%0.1f", val);
} else {
snprintf(label, 19, "%d", (int)val);
}
_canvas->setCursor(PLOT_LEFTBUFFER-strlen(label)*6-5, y);
_canvas->print(label);
}
/*****************************************************************/
int16_t minwave, maxwave;
short sampleBuffer[256];// buffer to read samples into, each sample is 16-bits
volatile int samplesRead;// number of samples read
int32_t getPDMwave(int32_t samples) {
minwave = 30000;
maxwave = -30000;
while (samples > 0) {
if (!samplesRead) {
yield();
continue;
}
for (int i = 0; i < samplesRead; i++) {
minwave = min(sampleBuffer[i], minwave);
maxwave = max(sampleBuffer[i], maxwave);
//Serial.println(sampleBuffer[i]);
samples--;
}
// clear the read count
samplesRead = 0;
}
return maxwave-minwave;
}
void onPDMdata() {
// query the number of bytes available
int bytesAvailable = PDM.available();
// read into the sample buffer
PDM.read(sampleBuffer, bytesAvailable);
// 16-bit, 2 bytes per sample
samplesRead = bytesAvailable / 2;
}
static float mapf(float x, float in_min, float in_max,
float out_min, float out_max) {
return (x - in_min) * (out_max - out_min) / (in_max - in_min) + out_min;
}
/******************************* Drawing functions */
void updateScreenCallback(void) { }
void screenClearCallback(void) { }
void drawPixelCallback(int16_t x, int16_t y, uint8_t red, uint8_t green, uint8_t blue) {
arcada.display->drawPixel(x, y, arcada.display->color565(red, green, blue));
}
void drawLineCallback(int16_t x, int16_t y, uint8_t *buf, int16_t w, uint16_t *palette, int16_t skip) {
uint16_t maxline = arcada.display->width();
bool splitdisplay = false;
uint8_t pixel;
//uint32_t t = millis();
//x += gif_offset_x;
//y += gif_offset_y;
if (y >= arcada.display->height() || x >= maxline ) {
return;
}
if (x + w > maxline) {
w = maxline - x;
}
if (w <= 0) return;
uint16_t buf565[2][w];
bool first = true; // First write op on this line?
uint8_t bufidx = 0;
uint16_t *ptr;
for (int i = 0; i < w; ) {
int n = 0, startColumn = i;
ptr = &buf565[bufidx][0];
// Handle opaque span of pixels (stop at end of line or first transparent pixel)
if (skip == -1) {// no transparent pixels
while(i < w) {
ptr[n++] = palette[buf[i++]];
}
}
else {
while((i < w) && ((pixel = buf[i++]) != skip)) {
ptr[n++] = palette[pixel];
}
}
if (n) {
arcada.display->dmaWait(); // Wait for prior DMA transfer to complete
if (first) {
arcada.display->endWrite(); // End transaction from prior callback
arcada.display->startWrite(); // Start new display transaction
first = false;
}
arcada.display->setAddrWindow(x + startColumn, y, min(maxline, n), 1);
arcada.display->writePixels(ptr, min(maxline, n), false, true);
bufidx = 1 - bufidx;
}
}
// arcada.display->dmaWait(); // Wait for last DMA transfer to complete
}
bool fileSeekCallback(unsigned long position) {
return file.seek(position);
}
unsigned long filePositionCallback(void) {
return file.position();
}
int fileReadCallback(void) {
return file.read();
}
int fileReadBlockCallback(void * buffer, int numberOfBytes) {
return file.read((uint8_t*)buffer, numberOfBytes); //.kbv
}
byte myPxTmp(float a) {
if (a>100){a=0;}// temps below 0 return as 5xx, perhaps a library error
//moved from 46 element array to 33 element array
//int temp=(45*(a-MINTEMP[tempScale % 6]))/(MAXTEMP[tempScale % 6]-MINTEMP[tempScale % 6]);
//if (temp>45){temp=45;}
int temp=(32*(a-MINTEMP[tempScale % 6]))/(MAXTEMP[tempScale % 6]-MINTEMP[tempScale % 6]);
if (temp>32){temp=32;}
if (temp<0){temp=0;}
return temp;
}