Shen Yuan, Tino Peter, Tsaneva-Atanasova Krasimira
School of Computer Science, The University of Birmingham, Birmingham, United Kingdom and Department of Mathematical Sciences, Xi'an Jiaotong-Liverpool University, Suzhou, China.
School of Computer Science, The University of Birmingham, Birmingham, United Kingdom.
Phys Rev E. 2017 Apr;95(4-1):043303. doi: 10.1103/PhysRevE.95.043303. Epub 2017 Apr 14.
We present a general framework for classifying partially observed dynamical systems based on the idea of learning in the model space. In contrast to the existing approaches using point estimates of model parameters to represent individual data items, we employ posterior distributions over model parameters, thus taking into account in a principled manner the uncertainty due to both the generative (observational and/or dynamic noise) and observation (sampling in time) processes. We evaluate the framework on two test beds: a biological pathway model and a stochastic double-well system. Crucially, we show that the classification performance is not impaired when the model structure used for inferring posterior distributions is much more simple than the observation-generating model structure, provided the reduced-complexity inferential model structure captures the essential characteristics needed for the given classification task.
我们基于在模型空间中学习的理念,提出了一种用于对部分观测动态系统进行分类的通用框架。与现有使用模型参数点估计来表示单个数据项的方法不同,我们采用模型参数的后验分布,从而以一种有原则的方式考虑到由于生成过程(观测和/或动态噪声)和观测过程(时间采样)所导致的不确定性。我们在两个测试平台上评估该框架:一个生物通路模型和一个随机双阱系统。至关重要的是,我们表明,当用于推断后验分布的模型结构比观测生成模型结构简单得多时,只要简化复杂度的推断模型结构捕捉到给定分类任务所需的基本特征,分类性能就不会受到损害。
