Image Registration using Bayes Theory and a Maximum Likelihood Framework with an EM Algorithm

Jonghyun Park, Wanhyun Cho, Sun-Worl Kim, Soonyoung Park, Myungeun Lee, C. Jeong, Junsik Lim, Gueesang Lee
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引用次数: 1

Abstract

A novel image registration algorithm that uses two kinds of information is presented: One kind is the shape information of an object and the other kind is the intensity information of a voxel and its neighborhoods consisting of the object. We, first, segment the medical volume data using the Markov random field model and the ICM algorithm and extract the surface region of the object from a segmented volume data. Second, we use the hidden labeling variables and likelihood method to statistically model the intensity distribution of each voxel at the surface region. We adopt the Bernoulli probability model to formulate a prior distribution of the labeling variable for the transformed voxels. The Gaussian mixture model is taken as a probability distribution function for the intensity of the transformed voxel. We use the EM algorithm to get the proper estimators for the parameters of the complete-data log likelihood function. The EM algorithm consists of two steps: the E-step and M-step. In the E-step, we compute the posterior distribution of the labeling variable by taking the expectation for the log-likelihood function. Next, we drive the estimators for all of the parameters by maximizing this function iteratively in the M-step. Then, we define a new registration measure with the Q-function obtained by the EM algorithm. We evaluate the precision of the proposed approach by comparing the registration traces of the Q- function obtained from the original image and its transformed image with respect to x-translation and rotation. The experimental results show that our method has great potential power to register various medical images given by different modalities.
基于贝叶斯理论和极大似然框架的图像配准
提出了一种利用两类信息的图像配准算法:一类是物体的形状信息,另一类是由物体组成的体素及其邻域的强度信息。首先,利用马尔科夫随机场模型和ICM算法对医学体数据进行分割,并从分割后的体数据中提取目标的表面区域;其次,我们使用隐标记变量和似然方法统计建模每个体素在表面区域的强度分布。我们采用伯努利概率模型来给出变换体素的标记变量的先验分布。将高斯混合模型作为变换体素强度的概率分布函数。我们使用EM算法得到完整数据对数似然函数参数的适当估计量。EM算法包括两个步骤:e步和m步。在e步中,我们通过取对数似然函数的期望来计算标记变量的后验分布。接下来,我们通过在m步中迭代地最大化该函数来驱动所有参数的估计量。然后,利用EM算法得到的q函数定义了一种新的配准测度。我们通过比较从原始图像和转换后的图像中获得的Q-函数的配准轨迹关于x平移和旋转来评估所提出方法的精度。实验结果表明,该方法对不同模式的医学图像配准具有很大的潜力。
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