Igor Levkov
test
Fork of
ov7670
by 
Edoardo De Marchi
ov7670.cpp
- Committer:
- edodm85
- Date:
- 2013-03-16
- Revision:
- 1:d82dbad9c06b
- Parent:
- 0:810d59d0b843
- Child:
- 2:354a00023f79
File content as of revision 1:d82dbad9c06b:
#include "ov7670.h"
OV7670::OV7670(PinName sda, PinName scl, PinName vs, PinName hr, PinName we, PortName port, int mask, PinName rt, PinName o, PinName rc) : _i2c(sda,scl),vsync(vs),href(hr),wen(we),data(port,mask),rrst(rt),oe(o),rclk(rc)
{
_i2c.stop();
_i2c.frequency(OV7670_I2CFREQ);
vsync.fall(this,&OV7670::VsyncHandler); // interrupt fall edge
href.rise(this,&OV7670::HrefHandler); // interrupt rise edge
CaptureReq = false;
Busy = false;
Done = false;
LineCounter = 0;
rrst = 1;
oe = 1;
rclk = 1;
wen = 0;
}
OV7670::~OV7670()
{
}
// capture request
void OV7670::CaptureNext(void)
{
CaptureReq = true ;
Busy = true ;
}
// capture done? (with clear)
bool OV7670::CaptureDone(void)
{
bool result ;
if (Busy) {
result = false ;
} else {
result = Done ;
Done = false ;
}
return result ;
}
// write to camera
void OV7670::WriteReg(int addr,int data)
{
_i2c.start() ;
_i2c.write(OV7670_WRITE) ;
wait_us(OV7670_WRITEWAIT);
_i2c.write(addr) ;
wait_us(OV7670_WRITEWAIT);
_i2c.write(data) ;
_i2c.stop() ;
}
// read from camera
int OV7670::ReadReg(int addr)
{
int data ;
_i2c.start() ;
_i2c.write(OV7670_WRITE) ;
wait_us(OV7670_WRITEWAIT);
_i2c.write(addr) ;
_i2c.stop() ;
wait_us(OV7670_WRITEWAIT);
_i2c.start() ;
_i2c.write(OV7670_READ) ;
wait_us(OV7670_WRITEWAIT);
data = _i2c.read(OV7670_NOACK) ;
_i2c.stop() ;
return data ;
}
void OV7670::Reset(void) {
WriteReg(0x12,0x80) ; // RESET CAMERA
wait_ms(200) ;
}
int OV7670::Init(char c, int n)
{
if (ReadReg(REG_PID) != 0x76) // check id camera
{
return 0;
}
Reset(); // Resets all registers to default values
Reset(); // Resets all registers to default values
WriteReg(REG_RGB444, 0x00); // Disable RGB444
WriteReg(REG_COM10,0x02); // 0x02 VSYNC negative (http://nasulica.homelinux.org/?p=959)
WriteReg(REG_MVFP,0x27); // mirror image
WriteReg(REG_CLKRC,0x80); // prescaler x1
WriteReg(DBLV,0x0a); // bypass PLL
WriteReg(REG_COM11,0x0A) ;
WriteReg(REG_TSLB,0x04); // 0D = UYVY 04 = YUYV
WriteReg(REG_COM13,0x88); // connect to REG_TSLB
if(c == 'b' || c == 'y') // YUV
{
WriteReg(REG_COM7, 0x00); // YUV
WriteReg(REG_COM17, 0x00); // color bar disable
WriteReg(REG_COM3, 0x04);
WriteReg(REG_COM15, 0xC0); // Set normal rgb with Full range
}else
if(c == 'r') // RGB565
{
WriteReg(REG_COM7, 0x04); // RGB + color bar disable
WriteReg(REG_RGB444, 0x00); // Disable RGB444
WriteReg(REG_COM15, 0x10); // Set rgb565 with Full range 0xD0
WriteReg(REG_COM3, 0x04);
WriteReg(REG_CLKRC,0x80); // prescaler x1
}
WriteReg(0x70, 0x3A); // Scaling Xsc
WriteReg(0x71, 0x35); // Scaling Ysc
WriteReg(0xA2, 0x02); // pixel clock delay
if(n == 19200) // 160*120
{
WriteReg(REG_COM14, 0x1a); // divide by 4
WriteReg(0x72, 0x22); // downsample by 4
WriteReg(0x73, 0xf2); // divide by 4
WriteReg(REG_HSTART,0x16);
WriteReg(REG_HSTOP,0x04);
WriteReg(REG_HREF,0xa4);
WriteReg(REG_VSTART,0x02);
WriteReg(REG_VSTOP,0x7a);
WriteReg(REG_VREF,0x0a);
}
if(n == 76800) // 320*240
{
WriteReg(REG_COM14, 0x19);
WriteReg(0x72, 0x11);
WriteReg(0x73, 0xf1);
WriteReg(REG_HSTART,0x16);
WriteReg(REG_HSTOP,0x04);
WriteReg(REG_HREF,0x24);
WriteReg(REG_VSTART,0x02);
WriteReg(REG_VSTOP,0x7a);
WriteReg(REG_VREF,0x0a);
}
if(n == 307200) // 640*480
{
WriteReg(REG_COM3,0x00); // REG_COM3
WriteReg(0x3e,0x00); // REG_COM14
WriteReg(0x72,0x11); //
WriteReg(0x73,0xf0); //
WriteReg(0x32,0xb6); // HREF
WriteReg(0x17,0x13); // HSTART
WriteReg(0x18,0x01); // HSTOP
WriteReg(0x19,0x02); // VSTART
WriteReg(0x1a,0x7a); // VSTOP
WriteReg(0x03,0x0a); // VREF
WriteReg(0x70, 0x3a); // Scaling Xsc
WriteReg(0x71, 0x35); // Scaling Ysc
WriteReg(0xA2, 0x02); // pixel clock delay
WriteReg(REG_COM1, 0x00);
}
// COLOR SETTING
WriteReg(REG_COM8,0x8F); // AGC AWB AEC Enab
WriteReg(0xAA,0x14); // Average-based AEC algorithm
WriteReg(REG_BRIGHT,0x00); // 0x00(Brightness 0) - 0x18(Brightness +1) - 0x98(Brightness -1)
WriteReg(REG_CONTRAS,0x40); // 0x40(Contrast 0) - 0x50(Contrast +1) - 0x38(Contrast -1)
WriteReg(0xB1,0xB1); // Automatic Black level Calibration
WriteReg(MTX1,0x80);
WriteReg(MTX2,0x80);
WriteReg(MTX3,0x00);
WriteReg(MTX4,0x22);
WriteReg(MTX5,0x5e);
WriteReg(MTX6,0x80);
WriteReg(MTXS,0x9e);
WriteReg(AWBC7,0x88);
WriteReg(AWBC8,0x88);
WriteReg(AWBC9,0x44);
WriteReg(AWBC10,0x67);
WriteReg(AWBC11,0x49);
WriteReg(AWBC12,0x0e);
WriteReg(REG_GFIX,0x00);
WriteReg(GGAIN,0x40);
WriteReg(AWBCTR3,0x0a);
WriteReg(AWBCTR2,0x55);
WriteReg(AWBCTR1,0x11);
WriteReg(AWBCTR0,0x9f);
WriteReg(0xb0,0x84);
return 1;
}
// vsync handler
void OV7670::VsyncHandler(void)
{
// Capture Enable
if (CaptureReq) {
wen = 1 ;
Done = false ;
CaptureReq = false ;
} else {
wen = 0 ;
if (Busy) {
Busy = false ;
Done = true ;
}
}
// Hline Counter
LastLines = LineCounter ;
LineCounter = 0 ;
}
// href handler
void OV7670::HrefHandler(void)
{
LineCounter++ ;
}
// Data Read
int OV7670::ReadOnebyte(void)
{
int B1;
rclk = 1;
B1 = (((data&0x07800000)>>19)|((data&0x078000)>>15));
rclk = 0;
return B1;
}
// Data Start read from FIFO
void OV7670::ReadStart(void)
{
rrst = 0 ;
oe = 0 ;
wait_us(1) ;
rclk = 0 ;
wait_us(1) ;
rclk = 1 ;
wait_us(1) ;
rrst = 1 ;
}
// Data Stop read from FIFO
void OV7670::ReadStop(void)
{
oe = 1 ;
ReadOnebyte() ;
rclk = 1 ;
}