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用于解码的实值的自然体验在fMRI生成模型

Generative Models for Decoding Real-Valued Natural Experience in FMRI
课程网址: http://videolectures.net/fmri06_stephens_gmdrv/  
主讲教师: Greg Stephens
开课单位: 普林斯顿大学
开课时间: 2007-02-25
课程语种: 英语
中文简介:
功能磁共振成像(FMRI)为人类大脑的复杂功能提供了前所未有的窗口,通常详细描述数百个体素在数百个时间点的活动。然而,FMRI的解释很复杂,因为血流动力学反应和神经活动之间的联系未知,以及认知模式本身的未知时空特征。最近的工作利用来自机器学习的技术来找到与脑过程相关的体素活动模式(参见例如[1])。这些技术中的许多涉及解码,推断刺激的值或类别类别!给定体素激活的模式!V。解码通常可以分为两种方式,歧视性和生成性[2]。利用判别模型,通过最小化诸如最小分类错误之类的损失,直接学习条件分布P(!S |!V)。或者,生成方法通过贝叶斯规则获得该条件概率;一个假定并适合P(!S)和P(!V | S)的模型。两种方法都可以可靠地建立足够的解码信息的存在。
课程简介: Functional Magnetic Resonance Imaging (FMRI) provides an unprecedented window into the complex functioning of the human brain, typically detailing the activity of thousands of voxels for hundreds of time points. The interpretation of FMRI is complicated, however, because of the unknown connection between the hemodynamic response and neural activity, and the unknown spatiotemporal characteristics of the cognitive patterns themselves. Recent work has exploited techniques from machine learning to find patterns of voxel activity related to brain processes (see e.g., [1]). Many of these techniques involve decoding, inferring the value or category class of a stimulus !S given a pattern of voxel activations !V . Decoding can generally be split into two approaches, discriminative and generative [2]. With a discriminative model one learns the conditional distribution P(!S |!V ) directly by minimizing a loss such as minimum classification error. Alternatively, the generative approach obtains this conditional probability through Bayes rule; one posits and fits models for P(!S ) and P(!V |S) instead. Both approaches can reliably establish the existence of sufficient decoding information.
关 键 词: 功能磁共振成像; 血流动力学; 神经活动
课程来源: 视频讲座网
最后编审: 2020-10-14:yumf
阅读次数: 62

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