// Gina Sprint // 7/15/2015 // Code to turn each light on // one by one // then turn them off one by one // in an 8 x 8 Adafruit light array // Trinket/Gemma + LED matrix backpack jewelry. Plays animated // sequence on LED matrix. Press reset button to display again, // or add optional momentary button between pin #1 and +V. #define BRIGHTNESS 12 // 0=min, 15=max #define I2C_ADDR 0x70 // Edit if backpack A0/A1 jumpers set #include #include #include static const uint8_t reorder[] = { // Column-reordering table 0x00,0x40,0x20,0x60,0x10,0x50,0x30,0x70,0x08,0x48,0x28,0x68,0x18,0x58,0x38,0x78, 0x04,0x44,0x24,0x64,0x14,0x54,0x34,0x74,0x0c,0x4c,0x2c,0x6c,0x1c,0x5c,0x3c,0x7c, 0x02,0x42,0x22,0x62,0x12,0x52,0x32,0x72,0x0a,0x4a,0x2a,0x6a,0x1a,0x5a,0x3a,0x7a, 0x06,0x46,0x26,0x66,0x16,0x56,0x36,0x76,0x0e,0x4e,0x2e,0x6e,0x1e,0x5e,0x3e,0x7e, 0x01,0x41,0x21,0x61,0x11,0x51,0x31,0x71,0x09,0x49,0x29,0x69,0x19,0x59,0x39,0x79, 0x05,0x45,0x25,0x65,0x15,0x55,0x35,0x75,0x0d,0x4d,0x2d,0x6d,0x1d,0x5d,0x3d,0x7d, 0x03,0x43,0x23,0x63,0x13,0x53,0x33,0x73,0x0b,0x4b,0x2b,0x6b,0x1b,0x5b,0x3b,0x7b, 0x07,0x47,0x27,0x67,0x17,0x57,0x37,0x77,0x0f,0x4f,0x2f,0x6f,0x1f,0x5f,0x3f,0x7f, 0x80,0xc0,0xa0,0xe0,0x90,0xd0,0xb0,0xf0,0x88,0xc8,0xa8,0xe8,0x98,0xd8,0xb8,0xf8, 0x84,0xc4,0xa4,0xe4,0x94,0xd4,0xb4,0xf4,0x8c,0xcc,0xac,0xec,0x9c,0xdc,0xbc,0xfc, 0x82,0xc2,0xa2,0xe2,0x92,0xd2,0xb2,0xf2,0x8a,0xca,0xaa,0xea,0x9a,0xda,0xba,0xfa, 0x86,0xc6,0xa6,0xe6,0x96,0xd6,0xb6,0xf6,0x8e,0xce,0xae,0xee,0x9e,0xde,0xbe,0xfe, 0x81,0xc1,0xa1,0xe1,0x91,0xd1,0xb1,0xf1,0x89,0xc9,0xa9,0xe9,0x99,0xd9,0xb9,0xf9, 0x85,0xc5,0xa5,0xe5,0x95,0xd5,0xb5,0xf5,0x8d,0xcd,0xad,0xed,0x9d,0xdd,0xbd,0xfd, 0x83,0xc3,0xa3,0xe3,0x93,0xd3,0xb3,0xf3,0x8b,0xcb,0xab,0xeb,0x9b,0xdb,0xbb,0xfb, 0x87,0xc7,0xa7,0xe7,0x97,0xd7,0xb7,0xf7,0x8f,0xcf,0xaf,0xef,0x9f,0xdf,0xbf,0xff }; void ledCmd(uint8_t x) { // Issue command to LED backback driver TinyWireM.beginTransmission(I2C_ADDR); TinyWireM.write(x); TinyWireM.endTransmission(); } void clear(void) { // Clear display buffer TinyWireM.beginTransmission(I2C_ADDR); for(uint8_t i=0; i<17; i++) TinyWireM.write(0); TinyWireM.endTransmission(); } uint8_t convert_to_uint8_t(int bin_num[]) { uint8_t total = 0; int value = 128; //2^7 int i = 0; for(i = 0; i < 8; i++) { if(bin_num[i] == 1) total += value; value /= 2; } return total; } void setup() { power_timer1_disable(); // Disable unused peripherals power_adc_disable(); // to save power PCMSK |= _BV(PCINT1); // Set change mask for pin 1 TinyWireM.begin(); // I2C init clear(); // Blank display ledCmd(0x21); // Turn on oscillator ledCmd(0xE0 | BRIGHTNESS); // Set brightness ledCmd(0x81); // Display on, no blink } int fill = 0; int turn_on_lights = 1; void loop() { int i = 0, row = 0, col = 0; uint8_t row_val = 0; int ms_delay = 10; uint8_t anim[9]; // 8 binary numbers for each row plus the delay int frame[8][8]; // build the frame for(i = 0; i < 64; i++) { row = i / 8; col = i % 8; if(i < fill) { frame[row][col] = turn_on_lights; } else // i >= fill { frame[row][col] = !turn_on_lights; } } if(fill == 64) { fill = 0; turn_on_lights = !turn_on_lights; } else { fill++; } // For each frame... TinyWireM.beginTransmission(I2C_ADDR); TinyWireM.write(0); // Start address for(uint8_t j=0; j<8; j++) { // 8 rows... row_val = convert_to_uint8_t(frame[j]); TinyWireM.write(reorder[row_val]); TinyWireM.write(0); } TinyWireM.endTransmission(); delay(ms_delay * 10); } ISR(PCINT0_vect) {} // Button tap