《学习openCV》例程解析 ex_9_3(codeBook模型实现背景减除)

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/**
比平均背景法性能更加良好的方法,codeBook模型实现背景减除

核心代码详细解析和实现 by zcube
*/

/************************************************************************/
/*			A few more thoughts on codebook models
In general, the codebook method works quite well across a wide number of conditions, 
and it is relatively quick to train and to run. It doesn’t deal well with varying patterns of 
light — such as morning, noon, and evening sunshine — or with someone turning lights 
on or off indoors. This type of global variability can be taken into account by using 
several different codebook models, one for each condition, and then allowing the condition 
to control which model is active.		                                */
/************************************************************************/

#include "stdafx.h"
#include 			
#include 
#include 

#define CHANNELS 3		
// 设置处理的图像通道数,要求小于等于图像本身的通道数

///
// 下面为码本码元的数据结构
// 处理图像时每个像素对应一个码本,每个码本中可有若干个码元
// 当涉及一个新领域,通常会遇到一些奇怪的名词,不要被这些名词吓坏,其实思路都是简单的
typedef struct ce {
	uchar	learnHigh[CHANNELS];	// High side threshold for learning
	// 此码元各通道的阀值上限(学习界限)
	uchar	learnLow[CHANNELS];		// Low side threshold for learning
	// 此码元各通道的阀值下限
	// 学习过程中如果一个新像素各通道值x[i],均有 learnLow[i]<=x[i]<=learnHigh[i],则该像素可合并于此码元
	uchar	max[CHANNELS];			// High side of box boundary
	// 属于此码元的像素中各通道的最大值
	uchar	min[CHANNELS];			// Low side of box boundary
	// 属于此码元的像素中各通道的最小值
	int		t_last_update;			// This is book keeping to allow us to kill stale entries
	// 此码元最后一次更新的时间,每一帧为一个单位时间,用于计算stale
	int		stale;					// max negative run (biggest period of inactivity)
	// 此码元最长不更新时间,用于删除规定时间不更新的码元,精简码本
} code_element;						// 码元的数据结构

typedef struct code_book {
	code_element	**cb;
	// 码元的二维指针,理解为指向码元指针数组的指针,使得添加码元时不需要来回复制码元,只需要简单的指针赋值即可
	int				numEntries;
	// 此码本中码元的数目
	int				t;				// count every access
	// 此码本现在的时间,一帧为一个时间单位
} codeBook;							// 码本的数据结构


///
// int updateCodeBook(uchar *p, codeBook &c, unsigned cbBounds)
// Updates the codebook entry with a new data point
//
// p			Pointer to a YUV pixel
// c			Codebook for this pixel
// cbBounds		Learning bounds for codebook (Rule of thumb: 10)
// numChannels	Number of color channels we're learning
//
// NOTES:
//		cvBounds must be of size cvBounds[numChannels]
//
// RETURN
//	codebook index
int cvupdateCodeBook(uchar *p, codeBook &c, unsigned *cbBounds, int numChannels)
{
	if(c.numEntries == 0) c.t = 0;
	// 码本中码元为零时初始化时间为0
	c.t += 1;	// Record learning event
	// 每调用一次加一,即每一帧图像加一
	
	//SET HIGH AND LOW BOUNDS
	int n;
	unsigned int high[3],low[3];
	for (n=0; n 255) high[n] = 255;
		low[n] = *(p+n)-*(cbBounds+n);
		if(low[n] < 0) low[n] = 0;
		// 用p 所指像素通道数据,加减cbBonds中数值,作为此像素阀值的上下限
	}

	//SEE IF THIS FITS AN EXISTING CODEWORD
	int matchChannel;	
	int i;
	for (i=0; ilearnLow[n] <= *(p+n)) && (*(p+n) <= c.cb[i]->learnHigh[n])) //Found an entry for this channel
			// 如果p 像素通道数据在该码元阀值上下限之间
			{	
				matchChannel++;
			}
		}
		if (matchChannel == numChannels)		// If an entry was found over all channels
			// 如果p 像素各通道都满足上面条件
		{
			c.cb[i]->t_last_update = c.t;
			// 更新该码元时间为当前时间
			// adjust this codeword for the first channel
			for (n=0; nmax[n] < *(p+n))
					c.cb[i]->max[n] = *(p+n);
				else if (c.cb[i]->min[n] > *(p+n))
					c.cb[i]->min[n] = *(p+n);
			}
			break;
		}
	}

	// ENTER A NEW CODE WORD IF NEEDED
	if(i == c.numEntries)  // No existing code word found, make a new one
	// p 像素不满足此码本中任何一个码元,下面创建一个新码元
	{
		code_element **foo = new code_element* [c.numEntries+1];
		// 申请c.numEntries+1 个指向码元的指针
		for(int ii=0; iilearnHigh[n] = high[n];
			c.cb[c.numEntries]->learnLow[n] = low[n];
			c.cb[c.numEntries]->max[n] = *(p+n);
			c.cb[c.numEntries]->min[n] = *(p+n);
		}
		c.cb[c.numEntries]->t_last_update = c.t;
		c.cb[c.numEntries]->stale = 0;
		c.numEntries += 1;
	}

	// OVERHEAD TO TRACK POTENTIAL STALE ENTRIES
	for(int s=0; st_last_update;
		// 计算该码元的不更新时间
		if(c.cb[s]->stale < negRun) 
			c.cb[s]->stale = negRun;
	}

	// SLOWLY ADJUST LEARNING BOUNDS
	for(n=0; nlearnHigh[n] < high[n]) 
			c.cb[i]->learnHigh[n] += 1;
		if(c.cb[i]->learnLow[n] > low[n]) 
			c.cb[i]->learnLow[n] -= 1;
	}

	return(i);
}

///
// uchar cvbackgroundDiff(uchar *p, codeBook &c, int minMod, int maxMod)
// Given a pixel and a code book, determine if the pixel is covered by the codebook
//
// p		pixel pointer (YUV interleaved)
// c		codebook reference
// numChannels  Number of channels we are testing
// maxMod	Add this (possibly negative) number onto max level when code_element determining if new pixel is foreground
// minMod	Subract this (possible negative) number from min level code_element when determining if pixel is foreground
//
// NOTES:
// minMod and maxMod must have length numChannels, e.g. 3 channels => minMod[3], maxMod[3].
//
// Return
// 0 => background, 255 => foreground
uchar cvbackgroundDiff(uchar *p, codeBook &c, int numChannels, int *minMod, int *maxMod)
{
	// 下面步骤和背景学习中查找码元如出一辙
	int matchChannel;
	//SEE IF THIS FITS AN EXISTING CODEWORD
	int i;
	for (i=0; imin[n] - minMod[n] <= *(p+n)) && (*(p+n) <= c.cb[i]->max[n] + maxMod[n]))
				matchChannel++; //Found an entry for this channel
			else
				break;
		}
		if (matchChannel == numChannels)
			break; //Found an entry that matched all channels
	}
	if(i == c.numEntries) 
		// p像素各通道值满足码本中其中一个码元,则返回白色
		return(255);

	return(0);
}


//UTILITES/
/
//int clearStaleEntries(codeBook &c)
// After you've learned for some period of time, periodically call this to clear out stale codebook entries
//
//c		Codebook to clean up
//
// Return
// number of entries cleared
int cvclearStaleEntries(codeBook &c)
{
	int staleThresh = c.t >> 1;			// 设定刷新时间
	int *keep = new int [c.numEntries];	// 申请一个标记数组
	int keepCnt = 0;					// 记录不删除码元数目
	//SEE WHICH CODEBOOK ENTRIES ARE TOO STALE
	for (int i=0; istale > staleThresh)	
			// 如码元中的不更新时间大于设定的刷新时间,则标记为删除
			keep[i] = 0; //Mark for destruction
		else
		{
			keep[i] = 1; //Mark to keep
			keepCnt += 1;
		}
	}

	// KEEP ONLY THE GOOD
	c.t = 0;						//Full reset on stale tracking
	// 码本时间清零
	code_element **foo = new code_element* [keepCnt];
	// 申请大小为keepCnt 的码元指针数组
	int k=0;
	for(int ii=0; iistale = 0;		//We have to refresh these entries for next clearStale
			foo[k]->t_last_update = 0;
			k++;
		}
	}
	//CLEAN UP
	delete [] keep;
	delete [] c.cb;
	c.cb = foo;
	// 把foo 头指针地址赋给c.cb 
	int numCleared = c.numEntries - keepCnt;
	// 被清理的码元个数
	c.numEntries = keepCnt;
	// 剩余的码元地址
	return(numCleared);
}



int main()
{
	///
	// 需要使用的变量
	CvCapture*	capture;
	IplImage*	rawImage;
	IplImage*	yuvImage;
	IplImage*	ImaskCodeBook;
	codeBook*	cB;
	unsigned	cbBounds[CHANNELS];
	uchar*		pColor; //YUV pointer
	int			imageLen;
	int			nChannels = CHANNELS;
	int			minMod[CHANNELS];
	int			maxMod[CHANNELS];
	
	//
	// 初始化各变量
	cvNamedWindow("Raw");
	cvNamedWindow("CodeBook");

	capture = cvCreateFileCapture("tree.avi");
	if (!capture)
	{
		printf("Couldn't open the capture!");
		return -1;
	}

	rawImage = cvQueryFrame(capture);
	yuvImage = cvCreateImage(cvGetSize(rawImage), 8, 3);	
	// 给yuvImage 分配一个和rawImage 尺寸相同,8位3通道图像
	ImaskCodeBook = cvCreateImage(cvGetSize(rawImage), IPL_DEPTH_8U, 1);
	// 为ImaskCodeBook 分配一个和rawImage 尺寸相同,8位单通道图像
	cvSet(ImaskCodeBook, cvScalar(255));
	// 设置单通道数组所有元素为255,即初始化为白色图像
	
	imageLen = rawImage->width * rawImage->height;
	cB = new codeBook[imageLen];
	// 得到与图像像素数目长度一样的一组码本,以便对每个像素进行处理
	
	for (int i=0; iimageData);
			// 指向yuvImage 图像的通道数据
			for (int c=0; cimageData); //3 channel yuv image
			uchar *pMask = (uchar *)((ImaskCodeBook)->imageData); //1 channel image
			// 指向ImaskCodeBook 通道数据序列的首元素
			for(int c=0; c


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