Sampling sparse representations with randomized measurement langevin dynamics
Sampling sparse representations with randomized measurement langevin dynamics
Stochastic Gradient Langevin Dynamics (SGLD) have been widely used for Bayesian sampling from certain probability distributions, incorporating derivatives of the log-posterior. With the derivative evaluation of the log-posterior distribution, SGLD methods generate samples from the distribution through performing as a thermostats dynamics that traverses over gradient flows of the log-posterior with certainly controllable perturbation. Even when the density is not known, existing solutions still can first learn the kernel density models from the given datasets, then produce new samples using the SGLD over the kernel density derivatives. In this work, instead of exploring new samples from kernel spaces, a novel SGLD sampler, namely, Randomized Measurement Langevin Dynamics (RMLD) is proposed to sample the high-dimensional sparse representations from the spectral domain of a given dataset.
Specifically, given a random measurement matrix for sparse coding, RMLD first derives a novel likelihood evaluator of the probability distribution from the loss function of LASSO, then samples from the high-dimensional distribution using stochastic Langevin dynamics with derivatives of the logarithm likelihood and Metropolis–Hastings sampling. In addition, new samples in low-dimensional measuring spaces can be regenerated using the sampled high-dimensional vectors and the measurement matrix. The algorithm analysis shows that RMLD indeed projects a given dataset into a high-dimensional Gaussian distribution with Laplacian prior, then draw new sparse representation from the dataset through performing SGLD over the distribution. Extensive experiments have been conducted to evaluate the proposed algorithm using real-world datasets. The performance comparisons on three real-world applications demonstrate the superior performance of RMLD beyond baseline methods.
Wang, Kafeng
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Xiong, Haoyi
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Bian, Jiang
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Zhu, Zhanxing
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Gao, Qian
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Guo, Zhishan
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Xu, Cheng-Zhong
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Huan, Jun
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Dou, Dejing
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Wang, Kafeng
fb760cf5-7bc8-417c-9557-ce1a87aa505f
Xiong, Haoyi
ce4ad3c5-7887-4830-941c-02e593f20dae
Bian, Jiang
905fe333-0e9c-4008-a3c0-19d724086dd2
Zhu, Zhanxing
e55e7385-8ba2-4a85-8bae-e00defb7d7f0
Gao, Qian
5848b057-ce50-40eb-a694-bbd447056921
Guo, Zhishan
f2bf5939-5cd1-4d4f-9462-f05383faa8af
Xu, Cheng-Zhong
fe896c55-47a1-44cd-8d5b-1ca639dccca6
Huan, Jun
0ea4757d-fe12-44b7-9928-6f94e70117ae
Dou, Dejing
dade81b5-d7e7-4bae-b0bc-471e75c3f2d4
Wang, Kafeng, Xiong, Haoyi, Bian, Jiang, Zhu, Zhanxing, Gao, Qian, Guo, Zhishan, Xu, Cheng-Zhong, Huan, Jun and Dou, Dejing
(2021)
Sampling sparse representations with randomized measurement langevin dynamics.
ACM Transactions on Knowledge Discovery from Data, 15 (2), [21].
(doi:10.1145/3427585).
Abstract
Stochastic Gradient Langevin Dynamics (SGLD) have been widely used for Bayesian sampling from certain probability distributions, incorporating derivatives of the log-posterior. With the derivative evaluation of the log-posterior distribution, SGLD methods generate samples from the distribution through performing as a thermostats dynamics that traverses over gradient flows of the log-posterior with certainly controllable perturbation. Even when the density is not known, existing solutions still can first learn the kernel density models from the given datasets, then produce new samples using the SGLD over the kernel density derivatives. In this work, instead of exploring new samples from kernel spaces, a novel SGLD sampler, namely, Randomized Measurement Langevin Dynamics (RMLD) is proposed to sample the high-dimensional sparse representations from the spectral domain of a given dataset.
Specifically, given a random measurement matrix for sparse coding, RMLD first derives a novel likelihood evaluator of the probability distribution from the loss function of LASSO, then samples from the high-dimensional distribution using stochastic Langevin dynamics with derivatives of the logarithm likelihood and Metropolis–Hastings sampling. In addition, new samples in low-dimensional measuring spaces can be regenerated using the sampled high-dimensional vectors and the measurement matrix. The algorithm analysis shows that RMLD indeed projects a given dataset into a high-dimensional Gaussian distribution with Laplacian prior, then draw new sparse representation from the dataset through performing SGLD over the distribution. Extensive experiments have been conducted to evaluate the proposed algorithm using real-world datasets. The performance comparisons on three real-world applications demonstrate the superior performance of RMLD beyond baseline methods.
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Accepted/In Press date: 1 September 2020
e-pub ahead of print date: 10 February 2021
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Local EPrints ID: 486279
URI: http://eprints.soton.ac.uk/id/eprint/486279
PURE UUID: d9be3c9b-b48b-40a7-b6eb-84abfc7dc753
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Date deposited: 16 Jan 2024 17:42
Last modified: 17 Mar 2024 06:51
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Author:
Kafeng Wang
Author:
Haoyi Xiong
Author:
Jiang Bian
Author:
Zhanxing Zhu
Author:
Qian Gao
Author:
Zhishan Guo
Author:
Cheng-Zhong Xu
Author:
Jun Huan
Author:
Dejing Dou
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