SIFT特征点匹配与消除错配:BBF,RANSAC

Step1: BBF算法,在KD-tree上找KNN。第一步做匹配咯~

 

1.       什么是KD-treefrom wiki

K-Dimension tree,实际上是一棵平衡二叉树。

一般的KD-tree构造过程:

function kdtree (list of points pointList, int depth)

{

    if pointList is empty

        return nil;

    else {

        // Select axis based on depth so that axis cycles through all valid values

        var int axis := depth mod k;

 

        // Sort point list and choose median as pivot element

        select median by axis from pointList;

 

        // Create node and construct subtrees

        var tree_node node;

        node.location := median;

        node.leftChild := kdtree(points in pointList before median, depth+1);

        node.rightChild := kdtree(points in pointList after median, depth+1);

        return node;

    }

}

 

pointList = [(2,3), (5,4), (9,6), (4,7), (8,1), (7,2)] tree = kdtree(pointList)

SIFT特征点匹配与消除错配:BBF,RANSAC_第1张图片

 

2.       BBF算法,在KD-tree上找KNN ( K-nearest neighbor)

BBF(Best Bin First)算法,借助优先队列(这里用最小堆)实现。从根开始,在KD-tree上找路子的时候,错过的点先塞到优先队列里,自己先一个劲儿扫到leaf;然后再从队列里取出目前key值最小的(这里是是ki维上的距离最小者),重复上述过程,一个劲儿扫到leaf;直到队列找空了,或者已经重复了200遍了停止。

 

Step1: img2featuresKD-tree;  kd_root = kdtree_build( feat2, n2 );在这里,ki是选取均方差最大的那个维度,kv是各特征点在那个维度上的median值,features是你率领的整个儿子孙子特征大军,n是你儿子孙子个数。

/** a node in a k-d tree */

struct kd_node{

     int ki;                      /**< partition key index */

     double kv;                   /**< partition key value */

     int leaf;                    /**< 1 if node is a leaf, 0 otherwise */

     struct feature* features;    /**< features at this node */

     int n;                       /**< number of features */

     struct kd_node* kd_left;     /**< left child */

     struct kd_node* kd_right;    /**< right child */

};

Step2: img1的每个featKD-tree里找k个最近邻,这里k=2

k = kdtree_bbf_knn( kd_root, feat, 2, &nbrs, KDTREE_BBF_MAX_NN_CHKS );

     min_pq = minpq_init();

     minpq_insert( min_pq, kd_root, 0 );

     while( min_pq->n > 0  &&  t < max_nn_chks ) //队列里有东西就继续搜,同时控制在t<200(即200步内)

     {

         expl = (struct kd_node*)minpq_extract_min( min_pq ); //取出最小的,front & pop

         expl = explore_to_leaf( expl, feat, min_pq ); //从该点开始,exploreleaf,路过的“有意义的点”就塞到最小队列min_pq中。

         for( i = 0; i < expl->n; i++ ) //

         {

              tree_feat = &expl->features[i];

              bbf_data->old_data = tree_feat->feature_data;

              bbf_data->d = descr_dist_sq(feat, tree_feat); //feat均方差

              tree_feat->feature_data = bbf_data;

              n += insert_into_nbr_array( tree_feat, _nbrs, n, k ); //按从小到大塞到neighbor数组里,到时候取前k个就是 KNN ~ n 每次加10,表示目前已有的元素个数

         }

         t++;

     }

对“有意义的点”的解释:

struct kd_node* explore_to_leaf( struct kd_node* kd_node, struct feature* feat,

                                     struct min_pq* min_pq )//expl, feat, min_pq

{

     struct kd_node* unexpl, * expl = kd_node;

     double kv;

     int ki;

     while( expl  &&  ! expl->leaf )

     {

         ki = expl->ki;

         kv = expl->kv;

         if( feat->descr[ki] <= kv ) {

              unexpl = expl->kd_right;

              expl = expl->kd_left; //走左边,右边点将被记下来

         }

         else {

              unexpl = expl->kd_left;

              expl = expl->kd_right; //走右边,左边点将被记下来

         }

         minpq_insert( min_pq, unexpl, ABS( kv - feat->descr[ki] ) ) ;//将这些点插入进来,key键值为|kv - feat->descr[ki]| 即第ki维上的差值

     }

     return expl;

}

         Step3: 如果k近邻找到了(k=2),那么判断是否能作为有效特征,d0/d1<0.49就算是咯~

              d0 = descr_dist_sq( feat, nbrs[0] );//计算两特征间squared Euclidian distance

              d1 = descr_dist_sq( feat, nbrs[1] );

              if( d0 < d1 * NN_SQ_DIST_RATIO_THR )//如果d0/d1小于阈值0.49

              {

                   pt1 = cvPoint( cvRound( feat->x ), cvRound( feat->y ) );

                   pt2 = cvPoint( cvRound( nbrs[0]->x ), cvRound( nbrs[0]->y ) );

                   pt2.y += img1->height;

                   cvLine( stacked, pt1, pt2, CV_RGB(255,0,255), 1, 8, 0 );//画线

                   m++;//matches个数

                   feat1[i].fwd_match = nbrs[0];

              }

 

Step2: 通过RANSAC算法来消除错配,什么是RANSAC先?

1.       RANSAC (Random Sample Consensus, 随机抽样一致)  (from wiki)

该算法做什么呢?呵呵,用一堆数据去搞定一个待定模型,这里所谓的搞定就是一反复测试、迭代的过程,找出一个error最小的模型及其对应的同盟军(consensus set)。用在我们的SIFT特征匹配里,就是说找一个变换矩阵出来,使得尽量多的特征点间都符合这个变换关系。

 

算法思想:

input:

data - a set of observations

model - a model that can be fitted to data

n - the minimum number of data required to fit the model

k - the maximum number of iterations allowed in the algorithm

t - a threshold value for determining when a datum fits a model

d - the number of close data values required to assert that a model fits well to data

output:

best_model - model parameters which best fit the data (or nil if no good model is found)

best_consensus_set - data point from which this model has been estimated

best_error - the error of this model relative to the data

 

iterations := 0

best_model := nil

best_consensus_set := nil

best_error := infinity

while iterations < k  //进行K次迭代

    maybe_inliers := n randomly selected values from data

    maybe_model := model parameters fitted to maybe_inliers

    consensus_set := maybe_inliers

 

    for every point in data not in maybe_inliers

        if point fits maybe_model with an error smaller than t //错误小于阈值t

            add point to consensus_set   //成为同盟,加入consensus set

   

    if the number of elements in consensus_set is > d //同盟军已经大于d个人,够了

        (this implies that we may have found a good model,

        now test how good it is)

        better_model := model parameters fitted to all points in consensus_set

        this_error := a measure of how well better_model fits these points

        if this_error < best_error

            (we have found a model which is better than any of the previous ones,

            keep it until a better one is found)

            best_model := better_model

            best_consensus_set := consensus_set

            best_error := this_error

    increment iterations

 

return best_model, best_consensus_set, best_error

 

2.       RANSAC去除错配:

H = ransac_xform( feat1, n1, FEATURE_FWD_MATCH, lsq_homog, 4, 0.01,homog_xfer_err, 3.0, NULL, NULL );

     nm = get_matched_features( features, n, mtype, &matched );

     /* initialize random number generator */

     rng = gsl_rng_alloc( gsl_rng_mt19937 );

     gsl_rng_set( rng, time(NULL) );

 

     in_min = calc_min_inliers( nm, m, RANSAC_PROB_BAD_SUPP, p_badxform ); //符合这一要求的内点至少得有多少个

     p = pow( 1.0 - pow( in_frac, m ), k );

     i = 0;

     while( p > p_badxform )//p>0.01

     {

         sample = draw_ransac_sample( matched, nm, m, rng );

         extract_corresp_pts( sample, m, mtype, &pts, &mpts );

         M = xform_fn( pts, mpts, m );

         if( ! M )

              goto iteration_end;

         in = find_consensus( matched, nm, mtype, M, err_fn, err_tol, &consensus);

         if( in > in_max )  {

              if( consensus_max )

                   free( consensus_max );

              consensus_max = consensus;

              in_max = in;

              in_frac = (double)in_max / nm;

         }

         else

              free( consensus );

         cvReleaseMat( &M );

 

iteration_end:

         release_mem( pts, mpts, sample );

         p = pow( 1.0 - pow( in_frac, m ), ++k );

     }

     /* calculate final transform based on best consensus set */

     if( in_max >= in_min )

     {

         extract_corresp_pts( consensus_max, in_max, mtype, &pts, &mpts );

         M = xform_fn( pts, mpts, in_max );

         in = find_consensus( matched, nm, mtype, M, err_fn, err_tol, &consensus);

         cvReleaseMat( &M );

         release_mem( pts, mpts, consensus_max );

         extract_corresp_pts( consensus, in, mtype, &pts, &mpts );

         M = xform_fn( pts, mpts, in );      

思考中的一些问题:

features间的对应关系,记录在features->fwd_match里(matching feature from forward

imge)。

 

1.       数据是nm个特征点间的对应关系,由它们产生一个3*3变换矩阵(xform_fn = hsq_homog函数,此要>=4对的对应才可能计算出来咯~),此乃模型model

2.       然后开始找同盟军(find_consensus函数),判断除了sample的其它对应关系是否满足这个模型(err_fn = homog_xfer_err函数,<=err_tolOK~),满足则留下。

3.       一旦大于当前的in_max,那么该模型就升级为目前最牛的模型。(最最原始的RANSAC是按错误率最小走的,我们这会儿已经保证了错误率在err_tol范围内,按符合要求的对应数最大走,尽量多的特征能匹配地上)

4.       重复以上3步,直到(1-wm)k <=p_badxform (0.01),模型就算找定~

5.       最后再把模型和同盟军定一下,齐活儿~

 

声明:以上代码参考Rob HessSIFT实现。

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