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Shield touch TFT LCD 2,8” para Arduino Keyestudio

REF: KS0257


Este Shield touch TFT LCD 2,8’’, da Keyestudio, possui um chip ILI9325 e é compatível com a placa controladora Arduino UNO R3. Para utilizá-lo, basta empilhá-lo no topo da placa controladora. Além disso, dispõe de um botão de reset (botão branco).

23,52 IVA INCL.

Shield touch TFT LCD

Características

Shield touch TFT LCD 2,8’’

Módulo Matriz Dot transmissivo 240xRGBx320
Driving duty: 1/240
2,8 polegadas (tipo COG)
Ângulo de visão (máximo): 12 horas
Driver LCD ILI9325 ou equivalente
Tensão: 2.8V – 3.3V
Interface de dados: sistema 80 de 8/16 bit bus
Shield TFT LCD: modo 8 bit bus
Painel trouch
Retroiluminação branca (backlight)
Fonte de alimentação: 5V corrente contínua

 

Dimensões

Tamanho do display: 2,8 polegadas
Dimensão do módulo: H/W/D 81×53×15 mm
Área ativa: W/H 43.2×57.6 mm
Número de dots: W/RGB/H 240×3×320-
Tamanho do pixel: W/H 0.18×0.18 mm
Tipo de LCD: TFT
Circuito Integrado: ILI9325
Display de várias cores: 65K

// IMPORTANT: Adafruit_TFTLCD LIBRARY MUST BE SPECIFICALLY
// CONFIGURED FOR EITHER THE TFT SHIELD OR THE BREAKOUT BOARD.
// SEE RELEVANT COMMENTS IN Adafruit_TFTLCD.h FOR SETUP.
//Technical support:goodtft@163.com

#include     // Core graphics library
#include  // Hardware-specific library
#include 
#include 


// The control pins for the LCD can be assigned to any digital or
// analog pins...but we'll use the analog pins as this allows us to
// double up the pins with the touch screen (see the TFT paint example).
#define LCD_CS A3 // Chip Select goes to Analog 3
#define LCD_CD A2 // Command/Data goes to Analog 2
#define LCD_WR A1 // LCD Write goes to Analog 1
#define LCD_RD A0 // LCD Read goes to Analog 0
#define PIN_SD_CS 10 // Adafruit SD shields and modules: pin 10

#define LCD_RESET A4 // Can alternately just connect to Arduino's reset pin

// When using the BREAKOUT BOARD only, use these 8 data lines to the LCD:
// For the Arduino Uno, Duemilanove, Diecimila, etc.:
//   D0 connects to digital pin 8  (Notice these are
//   D1 connects to digital pin 9   NOT in order!)
//   D2 connects to digital pin 2
//   D3 connects to digital pin 3
//   D4 connects to digital pin 4
//   D5 connects to digital pin 5
//   D6 connects to digital pin 6
//   D7 connects to digital pin 7
// For the Arduino Mega, use digital pins 22 through 29
// (on the 2-row header at the end of the board).

// Assign human-readable names to some common 16-bit color values:
#define	BLACK   0x0000
#define	BLUE    0x001F
#define	RED     0xF800
#define	GREEN   0x07E0
#define CYAN    0x07FF
#define MAGENTA 0xF81F
#define YELLOW  0xFFE0
#define WHITE   0xFFFF

Adafruit_TFTLCD tft(LCD_CS, LCD_CD, LCD_WR, LCD_RD, LCD_RESET);
// If using the shield, all control and data lines are fixed, and
// a simpler declaration can optionally be used:
// Adafruit_TFTLCD tft;


#define MAX_BMP         10                      // bmp file num
#define FILENAME_LEN    20                      // max file name length

const int __Gnbmp_height = 320;                 // bmp hight
const int __Gnbmp_width  = 240;                 // bmp width

unsigned char __Gnbmp_image_offset  = 0;        // offset

int __Gnfile_num = 4;                           // num of file

char __Gsbmp_files[4][FILENAME_LEN] =           // add file name here
{
"flower.bmp",
"tiger.bmp",
"tree.bmp",
"RedRose.bmp",
};
File bmpFile;

/*********************************************/
// This procedure reads a bitmap and draws it to the screen
// its sped up by reading many pixels worth of data at a time
// instead of just one pixel at a time. increading the buffer takes
// more RAM but makes the drawing a little faster. 20 pixels' worth
// is probably a good place

#define BUFFPIXEL       60                      // must be a divisor of 240 
#define BUFFPIXEL_X3    180                     // BUFFPIXELx3

void bmpdraw(File f, int x, int y)
{
    bmpFile.seek(__Gnbmp_image_offset);

    uint32_t time = millis();

    uint8_t sdbuffer[BUFFPIXEL_X3];                 // 3 * pixels to buffer

    for (int i=0; i< __Gnbmp_height; i++) {
        for(int j=0; j<(240/BUFFPIXEL); j++) {
            bmpFile.read(sdbuffer, BUFFPIXEL_X3);
            
            uint8_t buffidx = 0;
            int offset_x = j*BUFFPIXEL;
            unsigned int __color[BUFFPIXEL];
            
            for(int k=0; k>3;                        // read
                __color[k] = __color[k]<>2);      // green
                __color[k] = __color[k]<>3);      // blue
                
                buffidx += 3;
            }

      for (int m = 0; m < BUFFPIXEL; m ++) {
              tft.drawPixel(m+offset_x, i,__color[m]);
      }
        }
    }
    
    Serial.print(millis() - time, DEC);
    Serial.println(" ms");
}

boolean bmpReadHeader(File f) 
{
    // read header
    uint32_t tmp;
    uint8_t bmpDepth;
    
    if (read16(f) != 0x4D42) {
        // magic bytes missing
        return false;
    }

    // read file size
    tmp = read32(f);
    Serial.print("size 0x");
    Serial.println(tmp, HEX);

    // read and ignore creator bytes
    read32(f);

    __Gnbmp_image_offset = read32(f);
    Serial.print("offset ");
    Serial.println(__Gnbmp_image_offset, DEC);

    // read DIB header
    tmp = read32(f);
    Serial.print("header size ");
    Serial.println(tmp, DEC);
    
    int bmp_width = read32(f);
    int bmp_height = read32(f);
    
    if(bmp_width != __Gnbmp_width || bmp_height != __Gnbmp_height)  {    // if image is not 320x240, return false
        return false;
    }

    if (read16(f) != 1)
    return false;

    bmpDepth = read16(f);
    Serial.print("bitdepth ");
    Serial.println(bmpDepth, DEC);

    if (read32(f) != 0) {
        // compression not supported!
        return false;
    }

    Serial.print("compression ");
    Serial.println(tmp, DEC);

    return true;
}

/*********************************************/
// These read data from the SD card file and convert them to big endian
// (the data is stored in little endian format!)

// LITTLE ENDIAN!
uint16_t read16(File f)
{
    uint16_t d;
    uint8_t b;
    b = f.read();
    d = f.read();
    d <<= 8;
    d |= b;
    return d;
}

// LITTLE ENDIAN!
uint32_t read32(File f)
{
    uint32_t d;
    uint16_t b;

    b = read16(f);
    d = read16(f);
    d <<= 16;
    d |= b;
    return d;
}

void setup(void) {
  Serial.begin(9600);
  Serial.println(F("TFT LCD test"));

#ifdef USE_ADAFRUIT_SHIELD_PINOUT
  Serial.println(F("Using Adafruit 2.4\" TFT Arduino Shield Pinout"));
#else
  Serial.println(F("Using Adafruit 2.4\" TFT Breakout Board Pinout"));
#endif

  Serial.print("TFT size is "); Serial.print(tft.width()); Serial.print("x"); Serial.println(tft.height());

  tft.reset();

  uint16_t identifier = tft.readID();
  if(identifier==0x0101)
      identifier=0x9341;
  
  if(identifier == 0x9325) {
    Serial.println(F("Found ILI9325 LCD driver"));
  } else if(identifier == 0x4535) {
    Serial.println(F("Found LGDP4535 LCD driver"));
  }else if(identifier == 0x9328) {
    Serial.println(F("Found ILI9328 LCD driver"));
  } else if(identifier == 0x7575) {
    Serial.println(F("Found HX8347G LCD driver"));
  } else if(identifier == 0x9341) {
    Serial.println(F("Found ILI9341 LCD driver"));
  } else if(identifier == 0x8357) {
    Serial.println(F("Found HX8357D LCD driver"));
  } else {
    Serial.print(F("Unknown LCD driver chip: "));
    Serial.println(identifier, HEX);
    Serial.println(F("If using the Adafruit 2.4\" TFT Arduino shield, the line:"));
    Serial.println(F("  #define USE_ADAFRUIT_SHIELD_PINOUT"));
    Serial.println(F("should appear in the library header (Adafruit_TFT.h)."));
    Serial.println(F("If using the breakout board, it should NOT be #defined!"));
    Serial.println(F("Also if using the breakout, double-check that all wiring"));
    Serial.println(F("matches the tutorial."));
    return;
  }
  
  tft.begin(identifier);
  tft.fillScreen(BLUE);
  
  
  
  //Init SD_Card
  pinMode(10, OUTPUT);
   
  if (!SD.begin(10)) {
    Serial.println("initialization failed!");
    tft.setCursor(0, 0);
    tft.setTextColor(WHITE);    
    tft.setTextSize(1);
    tft.println("SD Card Init fail.");   
  }else
  Serial.println("initialization done."); 
}

void loop(void) {
     for(unsigned char i=0; i<__Gnfile_num; i++) {
        bmpFile = SD.open(__Gsbmp_files[i]);
        if (! bmpFile) {
            Serial.println("didnt find image");
            tft.setTextColor(WHITE);    tft.setTextSize(1);
            tft.println("didnt find BMPimage");
            while (1);
        }
   
        if(! bmpReadHeader(bmpFile)) {
            Serial.println("bad bmp");
            tft.setTextColor(WHITE);    tft.setTextSize(1);
            tft.println("bad bmp");
            return;
        }

        bmpdraw(bmpFile, 0, 0);
        bmpFile.close();
        delay(1000);
        delay(1000);
    }
    
}

Resultados

Teste 1

Utilizando o código 1 na placa controladora Arduino UNO R3, coloque as fotografias no cartão SD utilizando um leitor de cartões, introduza-o no Shield Touch TFT 2,8” e empilhe-o na placa. Depois de ligar, poderá ver as imagens no LCD como abaixo:

Teste 2

Utilizando o código 2, empilhe o Shield touch TFT LCD 2,8” na placa controladora Arduino UNO R3. Depois de ligar, poderá fazer vários desenhos no LCD, como mostra a imagem abaixo.

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