Variational Potential Flow: A Novel Probabilistic Framework for Energy-Based Generative Modelling

arXiv - CS - Neural and Evolutionary Computing Pub Date : 2024-07-21 DOI:arxiv-2407.15238

Junn Yong Loo, Michelle Adeline, Arghya Pal, Vishnu Monn Baskaran, Chee-Ming Ting, Raphael C. -W. Phan

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Abstract

Energy based models (EBMs) are appealing for their generality and simplicity in data likelihood modeling, but have conventionally been difficult to train due to the unstable and time-consuming implicit MCMC sampling during contrastive divergence training. In this paper, we present a novel energy-based generative framework, Variational Potential Flow (VAPO), that entirely dispenses with implicit MCMC sampling and does not rely on complementary latent models or cooperative training. The VAPO framework aims to learn a potential energy function whose gradient (flow) guides the prior samples, so that their density evolution closely follows an approximate data likelihood homotopy. An energy loss function is then formulated to minimize the Kullback-Leibler divergence between density evolution of the flow-driven prior and the data likelihood homotopy. Images can be generated after training the potential energy, by initializing the samples from Gaussian prior and solving the ODE governing the potential flow on a fixed time interval using generic ODE solvers. Experiment results show that the proposed VAPO framework is capable of generating realistic images on various image datasets. In particular, our proposed framework achieves competitive FID scores for unconditional image generation on the CIFAR-10 and CelebA datasets.

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变势流：基于能量的生成模型的新型概率框架

基于能量的模型（EBM）因其在数据似然建模中的通用性和简易性而备受青睐，但由于在对比发散训练过程中隐含的 MCMC 采样不稳定且耗时，因此一直难以训练。在本文中，我们提出了一种新颖的基于能量的生成框架--变异势能流（VAPO），它完全不需要隐式 MCMC 采样，也不依赖互补潜模型或合作训练。VAPO 框架旨在学习一个势能函数，该函数的梯度（流）可引导先验样本，从而使其密度演化紧跟近似数据似然同调。然后制定一个能量损失函数，以最小化流量驱动的先验样本密度演化与数据似然同构之间的库尔贝-莱伯勒差分。通过高斯先验初始化样本，并使用通用 ODE 求解器在固定时间间隔内求解支配势流的 ODE，可以在训练势能后生成图像。实验结果表明，所提出的 VAPO 框架能够在各种图像数据集上生成逼真的图像。特别是，我们提出的框架在 CIFAR-10 和 CelebA 数据集上的无条件图像生成中取得了具有竞争力的 FID 分数。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - CS - Neural and Evolutionary Computing

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