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混合高斯模型使用K(基本为3到5个) 个高斯模型来表征图像中各个像素点的特征,在新一帧图像获得后更新混合高斯模型,用当前图像中的每个像素点与混合高斯模型匹配,如果成功则判定该点为背景点, 否则为前景点。每个高斯模型,他主要是有方差和均值两个参数决定,对均值和方差的学习,采取不同的学习机制,将直接影响到模型的稳定性、精确性和收敛性。由于我们是对运动目标的背景提取建模,因此需要对高斯模型中方差和均值两个参数实时更新。为提高模型的学习能力,改进方法对均值和方差的更新采用不同的学习率;为提高在繁忙的场景下,大而慢的运动目标的检测效果,引入权值均值的概念,建立背景图像并实时更新,然后结合权值、权值均值和背景图像对像素点进行前景和背景的分类。具体更新公式如下:
μt= (1 - ρ)μt- 1 +ρxt (1)
σ2t = (1 - ρ)σ2t- 1 +ρ( xt -μt ) T ( xt -μt ) (2)
ρ =αη( xt | μκ,σκ ) (3)
| xt -μt - 1 | ≤ 2. 5σt- 1 (4)
w k , t = (1 - α) w k , t - 1 +αMk , t (5)
式中ρ为学习率,即反映当前图像融入背景的速率。如果想深入了解可以看原文,或者opencv的源代码。
高斯背景建模源代码在“OpenCVcvauxsrccvbgfg_gaussmix.cpp”中。下面是我添加注释的代码。
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CV_IMPL CvBGStatModel*
cvCreateGaussianBGModel( IplImage* first_frame, CvGaussBGStatModelParams* parameters )
{
CvGaussBGModel* bg_model = 0;// 高斯背景状态模型变量
CV_FUNCNAME( "cvCreateGaussianBGModel" );
__BEGIN__;
double var_init; //
CvGaussBGStatModelParams params; // 高斯背景状态模型参数变量
int i, j, k, n, m, p;
//初始化参数,如果参数为空,则进行初始化赋值
if( parameters == NULL )
{
params.win_size = CV_BGFG_MOG_WINDOW_SIZE; //初始化阶段的帧数
params.bg_threshold = CV_BGFG_MOG_BACKGROUND_THRESHOLD;//高斯背景阈值
params.std_threshold = CV_BGFG_MOG_STD_THRESHOLD;//
params.weight_init = CV_BGFG_MOG_WEIGHT_INIT; // 初始权重
params.variance_init = CV_BGFG_MOG_SIGMA_INIT*CV_BGFG_MOG_SIGMA_INIT; // 初始方差
params.minArea = CV_BGFG_MOG_MINAREA; //最小面积
params.n_gauss = CV_BGFG_MOG_NGAUSSIANS;// 高斯模型个数
}
else
{
params = *parameters; //如果parameters非空,则将其参数赋给 params
}
if( !CV_IS_IMAGE(first_frame) )//如果第一帧不是图像,报错
CV_ERROR( CV_StsBadArg, "Invalid or NULL first_frame parameter" );
CV_CALL( bg_model = (CvGaussBGModel*)cvAlloc( sizeof(*bg_model) )); //为bg_model申请内存
memset( bg_model, 0, sizeof(*bg_model) );// 初始化刚申请的内存
bg_model->type = CV_BG_MODEL_MOG; // 背景模型类型是: CV_BG_MODEL_MOG
bg_model->release = (CvReleaseBGStatModel)icvReleaseGaussianBGModel;// 释放调用icvReleaseGaussianBGModel
bg_model->update = (CvUpdateBGStatModel)icvUpdateGaussianBGModel;// 更新调用icvUpdateGaussianBGModel
bg_model->params = params; //参数为 params
//prepare storages
CV_CALL( bg_model->g_point = (CvGaussBGPoint*)cvAlloc(sizeof(CvGaussBGPoint)*
((first_frame->width*first_frame->height) + 256))); //为背景模型bg_model的高斯背景点g_point 分配内存,
CV_CALL( bg_model->background = cvCreateImage(cvSize(first_frame>width, first_frame->height), IPL_DEPTH_8U, first_frame->nChannels));
CV_CALL( bg_model->foreground = cvCreateImage(cvSize(first_frame->width ,first_frame->height), IPL_DEPTH_8U, 1));
CV_CALL( bg_model->storage = cvCreateMemStorage());
//initializing
var_init = 2 * params.std_threshold * params.std_threshold; // 初始化方差
CV_CALL( bg_model->g_point[0].g_values = (CvGaussBGValues*)cvAlloc( sizeof(CvGaussBGValues)*params.n_gauss*(first_frame->width*first_frame->height + 128)));
for( i = 0, p = 0, n = 0; i < first_frame->height; i++ )
{
for( j = 0; j < first_frame->width; j++, n++ ) // n =i*first_frame->width+j
{
bg_model->g_point[n].g_values = bg_model->g_point[0].g_values + n*params.n_gauss;
bg_model->g_point[n].g_values[0].weight = 1; //the first value seen has weight one //首个高斯模型,权值赋予1
bg_model->g_point[n].g_values[0].match_sum = 1; // the sum of matches for a particular gaussian
for( m = 0; m < first_frame->nChannels; m++) // 对每个通道
{
bg_model->g_point[n].g_values[0].variance[m] = var_init; //第0个高斯模型的 第M个通道的方差,
bg_model->g_point[n].g_values[0].mean[m] = (unsigned char)first_frame->imageData[p + m]; //均值,第M通道的值
}
for( k = 1; k < params.n_gauss; k++) //其他高斯模型,
{
bg_model->g_point[n].g_values[k].weight = 0; //第K个高斯模型的权值 0
bg_model->g_point[n].g_values[k].match_sum = 0; //第K个高斯模型的match_sum 0
for( m = 0; m < first_frame->nChannels; m++)
{
bg_model->g_point[n].g_values[k].variance[m] = var_init; //第K个高斯模型 的第m 通道的方差
bg_model->g_point[n].g_values[k].mean[m] = 0; //第K个高斯模型 的第m 通道的均值 0
}
}
p += first_frame->nChannels;//
}
}
bg_model->countFrames = 0; //帧=0
__END__;
if( cvGetErrStatus() < 0 )// 如果有错误
{
CvBGStatModel* base_ptr = (CvBGStatModel*)bg_model;
if( bg_model && bg_model->release )
bg_model->release( &base_ptr );//释放模型
else
cvFree( &bg_model );
bg_model = 0;
}
return (CvBGStatModel*)bg_model; //返回创建的背景模型
}
CV_IMPL void CV_CDECL
icvReleaseGaussianBGModel( CvGaussBGModel** _bg_model ) //返回背景模型
{
CV_FUNCNAME( "icvReleaseGaussianBGModel" );
__BEGIN__;
if( !_bg_model )
CV_ERROR( CV_StsNullPtr, "" );
if( *_bg_model )
{
CvGaussBGModel* bg_model = *_bg_model;
if( bg_model->g_point )
{
cvFree( &bg_model->g_point[0].g_values ); //释放背景点中的值
cvFree( &bg_model->g_point );//释放背景点
}
cvReleaseImage( &bg_model->background );//释放背景模型中的前景
cvReleaseImage( &bg_model->foreground );//释放背景模型中的背景
cvReleaseMemStorage(&bg_model->storage); //释放背景模型中的存储器
memset( bg_model, 0, sizeof(*bg_model) );
cvFree( _bg_model ); //释放背景模型
}
__END__;
}
CV_IMPL int CV_CDECL
icvUpdateGaussianBGModel( IplImage* curr_frame, CvGaussBGModel* bg_model )
{
int i, j, k;
int region_count = 0;
CvSeq *first_seq = NULL, *prev_seq = NULL, *seq = NULL;
bg_model->countFrames++; //每执行一次更新,帧数++
for( i = 0; i < curr_frame->height; i++ )
{
for( j = 0; j < curr_frame->width; j++ ) //对每个像素点 逐点进行运算
{
int match[CV_BGFG_MOG_MAX_NGAUSSIANS]; //CV_BGFG_MOG_MAX_NGAUSSIANS=500,最大高斯模型数目:match[500]
double sort_key[CV_BGFG_MOG_MAX_NGAUSSIANS]; // 排序: sort_key[500]
const int nChannels = curr_frame->nChannels; // 当前帧的通道数
const int n = i*curr_frame->width+j; // 正在处理第几个像素,
const int p = n*curr_frame->nChannels; // 第几个通道,这与图像(BGR,BGR,BGR....)的交叉存储格式有关
// A few short cuts
CvGaussBGPoint* g_point = &bg_model->g_point[n];
const CvGaussBGStatModelParams bg_model_params = bg_model->params;
double pixel[4]; //
int no_match; //
for( k = 0; k < nChannels; k++ )// 获得某个像素的 第K通道的值
pixel[k] = (uchar)curr_frame->imageData[p+k];
no_match = icvMatchTest( pixel, nChannels, match, g_point, &bg_model_params );//判断该像素值是否与背景模型匹配
if( bg_model->countFrames >= bg_model->params.win_size ) //判断已经处理的帧数是否等于初始化阶段帧长,如果是则:?????????
{
icvUpdateFullWindow( pixel, nChannels, match, g_point, &bg_model->params ); //调用正常阶段更新函数进行更新
if( no_match == -1) //如果没有找到匹配的,则调用正常阶段NoMatch情况的更新函数
icvUpdateFullNoMatch( curr_frame, p, match, g_point, &bg_model_params );
}
else //初始化阶段
{
icvUpdatePartialWindow( pixel, nChannels, match, g_point, &bg_model_params );
if( no_match == -1)
icvUpdatePartialNoMatch( pixel, nChannels, match, g_point, &bg_model_params );
}
icvGetSortKey( nChannels, sort_key, g_point, &bg_model_params ); //获得模型的适应度值
icvInsertionSortGaussians( g_point, sort_key, (CvGaussBGStatModelParams*)&bg_model_params ); // 进行排序
icvBackgroundTest( nChannels, n, p, match, bg_model ); //判断是否是背景
}
}
//下面这段是前景滤波,滤掉小块区域。
cvClearMemStorage(bg_model->storage);
//cvMorphologyEx( bg_model->foreground, bg_model->foreground, 0, 0, CV_MOP_OPEN, 1 );
//cvMorphologyEx( bg_model->foreground, bg_model->foreground, 0, 0, CV_MOP_CLOSE, 1 );
cvFindContours( bg_model->foreground, bg_model->storage, &first_seq, sizeof(CvContour), CV_RETR_LIST );
//对前景图像寻找轮廓,
for( seq = first_seq; seq; seq = seq->h_next )
{
CvContour* cnt = (CvContour*)seq;
if( cnt->rect.width * cnt->rect.height < bg_model->params.minArea ) //去掉小的区域
{
//delete small contour
prev_seq = seq->h_prev;
if( prev_seq )
{
prev_seq->h_next = seq->h_next;
if( seq->h_next )
seq->h_next->h_prev = prev_seq;
}
else
{
first_seq = seq->h_next;
if( seq->h_next )
seq->h_next->h_prev = NULL;
}
}//end of if
else
{
region_count++; //否则,区域数++
}
}//end of for
bg_model->foreground_regions = first_seq; //
cvZero(bg_model->foreground);
cvDrawContours(bg_model->foreground, first_seq, CV_RGB(0, 0, 255), CV_RGB(0, 0, 255), 10, -1);
// 绘制前景轮廓
return region_count; //返回轮廓数
}
static void icvInsertionSortGaussians( CvGaussBGPoint* g_point, double* sort_key, CvGaussBGStatModelParams *bg_model_params )
{
int i, j;
for( i = 1; i < bg_model_params->n_gauss; i++ )//对每个高斯背景模型
{
double index = sort_key[i]; // 获得适应度值
for( j = i; j > 0 && sort_key[j-1] < index; j-- ) //sort decending order 降序排列 ,
{
double temp_sort_key = sort_key[j];
sort_key[j] = sort_key[j-1];
sort_key[j-1] = temp_sort_key;
CvGaussBGValues temp_gauss_values = g_point->g_values[j];
g_point->g_values[j] = g_point->g_values[j-1];
g_point->g_values[j-1] = temp_gauss_values;
}
// sort_key[j] = index;
}
}
static int icvMatchTest( double* src_pixel, int nChannels, int* match,
const CvGaussBGPoint* g_point,
const CvGaussBGStatModelParams *bg_model_params )
{
int k;
int matchPosition=-1;
for ( k = 0; k < bg_model_params->n_gauss; k++) //对每个高斯背景模型 ,初始化 match[k]=0;
match[k]=0;
for ( k = 0; k < bg_model_params->n_gauss; k++) //对每个高斯背景模型
{
double sum_d2 = 0.0;
double var_threshold = 0.0; //方差阈值
for(int m = 0; m < nChannels; m++) //对每个通道
{
double d = g_point->g_values[k].mean[m]- src_pixel[m]; //新像素值与背景模型的均值做差
sum_d2 += (d*d); //三个通道的偏差和
var_threshold += g_point->g_values[k].variance[m]; //var_threshold就是背景模型中三个通道的方差的和
} //difference < STD_LIMIT*STD_LIMIT or difference**2 < STD_LIMIT*STD_LIMIT*VAR
var_threshold = bg_model_params->std_threshold*bg_model_params->std_threshold*var_threshold;//
if(sum_d2 < var_threshold) //如果差异小于阈值,
{
match[k] = 1; // 匹配上,
matchPosition = k; //记录匹配位置
break;
}
}//end-of-for-k
return matchPosition; //返回 匹配位置,即是哪个高斯模型匹配。
//如果没有匹配的,则返回的是-1。
}
static void icvUpdateFullWindow( double* src_pixel, int nChannels, int* match,
CvGaussBGPoint* g_point,
const CvGaussBGStatModelParams *bg_model_params )
{
const double learning_rate_weight = (1.0/(double)bg_model_params->win_size); //权重学习速率,1/初始化阶段帧长
for(int k = 0; k < bg_model_params->n_gauss; k++) //对每个高斯背景模型
{
g_point->g_values[k].weight = g_point->g_values[k].weight +
(learning_rate_weight*((double)match[k] -g_point->g_values[k].weight)); // 权重更新
if(match[k])//match[k]==1,表示该模型匹配上
{
double learning_rate_gaussian = (double)match[k]/(g_point->g_values[k].weight*
(double)bg_model_params->win_size);
for(int m = 0; m < nChannels; m++) //均值和方差要对每个通道都进行更新
{
const double tmpDiff = src_pixel[m] - g_point->g_values[k].mean[m];
g_point->g_values[k].mean[m] = g_point->g_values[k].mean[m] +
(learning_rate_gaussian * tmpDiff); // 均值更新
g_point->g_values[k].variance[m] = g_point->g_values[k].variance[m]+
(learning_rate_gaussian*((tmpDiff*tmpDiff) - g_point->g_values[k].variance[m])); // 方差更新
}//end-of-for-m
}
}//end-of-for-k
}
static void icvUpdatePartialWindow( double* src_pixel, int nChannels, int* match,
CvGaussBGPoint* g_point,
const CvGaussBGStatModelParams *bg_model_params )
{
int k, m;
int window_current = 0;//
for( k = 0; k < bg_model_params->n_gauss; k++ )
window_current += g_point->g_values[k].match_sum; //应该是已经处理的帧数,是吗??match_sum[]是什么东西?
for( k = 0; k < bg_model_params->n_gauss; k++ )
{
g_point->g_values[k].match_sum += match[k]; //
double learning_rate_weight = (1.0/((double)window_current + 1.0)); //increased by one since sum
g_point->g_values[k].weight = g_point->g_values[k].weight +
(learning_rate_weight*((double)match[k] - g_point->g_values[k].weight));//权值更新
if( g_point->g_values[k].match_sum > 0 && match[k] )
{
double learning_rate_gaussian = (double)match[k]/((double)g_point->g_values[k].match_sum);
for( m = 0; m < nChannels; m++ )
{
const double tmpDiff = src_pixel[m] - g_point->g_values[k].mean[m]; //均值更新
g_point->g_values[k].mean[m] = g_point->g_values[k].mean[m] +
(learning_rate_gaussian*tmpDiff);
g_point->g_values[k].variance[m] = g_point->g_values[k].variance[m]+
(learning_rate_gaussian*((tmpDiff*tmpDiff) - g_point->g_values[k].variance[m])); //方差更新
}
}
}
}
static void icvUpdateFullNoMatch( IplImage* gm_image, int p, int* match,
CvGaussBGPoint* g_point,
const CvGaussBGStatModelParams *bg_model_params)
{
int k, m;
double alpha;
int match_sum_total = 0;
//new value of last one
g_point->g_values[bg_model_params->n_gauss - 1].match_sum = 1; // 将最后一个高斯模型的match_sum置1
//get sum of all but last value of match_sum
for( k = 0; k < bg_model_params->n_gauss ; k++ )
match_sum_total += g_point->g_values[k].match_sum;//
g_point->g_values[bg_model_params->n_gauss - 1].weight = 1./(double)match_sum_total; //为新的模型赋予权值
for( m = 0; m < gm_image->nChannels ; m++ )
{
// first pass mean is image value
g_point->g_values[bg_model_params->n_gauss - 1].variance[m] = bg_model_params->variance_init; //为新的模型赋予方差
g_point->g_values[bg_model_params->n_gauss - 1].mean[m] = (unsigned char)gm_image->imageData[p + m];//为新的模型赋予均值
}
alpha = 1.0 - (1.0/bg_model_params->win_size);
for( k = 0; k < bg_model_params->n_gauss - 1; k++ ) //对除最后一个模型外的其他模型进行运算
{
g_point->g_values[k].weight *= alpha; //权重
if( match[k] )
g_point->g_values[k].weight += alpha;
}
}
static void
icvUpdatePartialNoMatch(double *pixel,
int nChannels,
int* ,
CvGaussBGPoint* g_point,
const CvGaussBGStatModelParams *bg_model_params)
{
int k, m;
//new value of last one
g_point->g_values[bg_model_params->n_gauss - 1].match_sum = 1; // 将最后一个高斯模型的match_sum置1
//get sum of all but last value of match_sum
int match_sum_total = 0;
for(k = 0; k < bg_model_params->n_gauss ; k++)
match_sum_total += g_point->g_values[k].match_sum;
for(m = 0; m < nChannels; m++)
{
//first pass mean is image value
g_point->g_values[bg_model_params->n_gauss - 1].variance[m] = bg_model_params->variance_init;
g_point->g_values[bg_model_params->n_gauss - 1].mean[m] = pixel[m];
}
for(k = 0; k < bg_model_params->n_gauss; k++)
{
g_point->g_values[k].weight = (double)g_point->g_values[k].match_sum /
(double)match_sum_total;
}
}
static void icvGetSortKey( const int nChannels, double* sort_key, const CvGaussBGPoint* g_point,
const CvGaussBGStatModelParams *bg_model_params )
{
int k, m;
for( k = 0; k < bg_model_params->n_gauss; k++ ) //
{
// Avoid division by zero
if( g_point->g_values[k].match_sum > 0 )
{
// 假设各个高斯分量之间是独立的
double variance_sum = 0.0;
for( m = 0; m < nChannels; m++ )
variance_sum += g_point->g_values[k].variance[m]; //各通道的方差和
sort_key[k] = g_point->g_values[k].weight/sqrt(variance_sum); // 模型的适合度值
}
else
sort_key[k]= 0.0;
}
}
static void icvBackgroundTest( const int nChannels, int n, int p, int *match, CvGaussBGModel* bg_model )
{
int m, b;
uchar pixelValue = (uchar)255; // will switch to 0 if match found,首先假设该点为前景点,
double weight_sum = 0.0;
CvGaussBGPoint* g_point = bg_model->g_point;
for( m = 0; m < nChannels; m++)
bg_model->background->imageData[p+m] = (unsigned char)(g_point[n].g_values[0].mean[m]+0.5); //背景就是模型[0]均值
for( b = 0; b < bg_model->params.n_gauss; b++)
{
weight_sum += g_point[n].g_values[b].weight; //累积权重
if( match[b] ) //??
pixelValue = 0; //像素值为0,成为背景
if( weight_sum > bg_model->params.bg_threshold )//若累积权重大于背景阈值,退出循环,舍掉后面的高斯模型
break;
}
bg_model->foreground->imageData[p/nChannels] = pixelValue; //将像素值赋给该点,0(背景)或者255(前景)
}
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