An Approach to Image Compression by Using Sparse Approximation Technique

Pati, Nibedita; Pradhan, Annapurna; Kanoje, Lalit; Das, Tanmaya Kumar

doi:10.1016/j.procs.2015.04.213

Cited by 7 publications

(3 citation statements)

References 11 publications

(10 reference statements)

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“…A commonly used criterion is how well one can reconstruct the inputs given the sparse activations and a set of learned basis vectors. Although these studies explain receptive structure in primary visual cortex and lead to practical machine learning algorithms for feature selection (Gui et al, 2016 ) and data compression (Pati et al, 2015 ), the purpose of neural computation is more than preserving information. In this paper, we take a different perspective and ask how computational properties of the HTM spatial pooler contribute to downstream cortical processing in the context of HTM systems.…”

Section: Discussionmentioning

confidence: 99%

The HTM Spatial Pooler—A Neocortical Algorithm for Online Sparse Distributed Coding

Cui

Ahmad

Hawkins

2017

Front. Comput. Neurosci.

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Hierarchical temporal memory (HTM) provides a theoretical framework that models several key computational principles of the neocortex. In this paper, we analyze an important component of HTM, the HTM spatial pooler (SP). The SP models how neurons learn feedforward connections and form efficient representations of the input. It converts arbitrary binary input patterns into sparse distributed representations (SDRs) using a combination of competitive Hebbian learning rules and homeostatic excitability control. We describe a number of key properties of the SP, including fast adaptation to changing input statistics, improved noise robustness through learning, efficient use of cells, and robustness to cell death. In order to quantify these properties we develop a set of metrics that can be directly computed from the SP outputs. We show how the properties are met using these metrics and targeted artificial simulations. We then demonstrate the value of the SP in a complete end-to-end real-world HTM system. We discuss the relationship with neuroscience and previous studies of sparse coding. The HTM spatial pooler represents a neurally inspired algorithm for learning sparse representations from noisy data streams in an online fashion.

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Section: Discussionmentioning

confidence: 99%

The HTM Spatial Pooler—A Neocortical Algorithm for Online Sparse Distributed Coding

Cui

Ahmad

Hawkins

2017

Front. Comput. Neurosci.

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show abstract

“…A commonly used criterion is how well one can reconstruct the inputs given the sparse activations and a set of learned basis vectors. Although these studies explain receptive structure in primary visual cortex and lead to practical machine learning algorithms for feature selection (Gui et al, 2016) and data compression (Pati et al, 2015), the purpose of neural computation is more than preserving information. In this paper, we take a different perspective and ask how computational properties of the HTM spatial pooler contribute to downstream cortical processing in the context of HTM systems.…”

Section: Relationship With Other Sparse Coding Techniquesmentioning

confidence: 99%

The HTM Spatial Pooler – a neocortical algorithm for online sparse distributed coding

Cui

Ahmad

Hawkins

2016

Preprint

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1.AbstractHierarchical temporal memory (HTM) provides a theoretical framework that models several key computational principles of the neocortex. In this paper we analyze an important component of HTM, the HTM spatial pooler (SP). The SP models how neurons learn feedforward connections and form efficient representations of the input. It converts arbitrary binary input patterns into sparse distributed representations (SDRs) using a combination of competitive Hebbian learning rules and homeostatic excitability control. We describe a number of key properties of the spatial pooler, including fast adaptation to changing input statistics, improved noise robustness through learning, efficient use of cells and robustness to cell death. In order to quantify these properties we develop a set of metrics that can be directly computed from the spatial pooler outputs. We show how the properties are met using these metrics and targeted artificial simulations. We then demonstrate the value of the spatial pooler in a complete end-to-end real-world HTM system. We discuss the relationship with neuroscience and previous studies of sparse coding. The HTM spatial pooler represents a neurally inspired algorithm for learning sparse representations from noisy data streams in an online fashion.

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“…Sparse signal representation in overcomplete dictionaries is an analytic tool that has been satisfactorily implemented in multiple signal and image processing applications such as image compression [15], audio denoising [16], and seismic signal pre-processing [17]. Its principle basically consists in representing the signal of interest as a linear combination of a few columns from a previously specified redundant matrix called dictionary, where each column of this matrix is called an atom of the dictionary.…”

Section: State Of the Techniquementioning

confidence: 99%

Interpolation and denoising of seismic signals using orthogonal matching pursuit algorithm: An aplication in VSP and refraction data

Sandoval-Flórez

Paredes

Vivas

et al. 2018

CT&F Cienc. Tecnol. Futuro

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An implementation of the Orthogonal Matching Pursuit (OMP) algorithm was used and the results obtained therefrom are presented for simultaneous interpolation and denoising from seismic signals in the framework of sparse signal representation. OMP is an algorithm for sparse signal representation based on orthogonal projections underlying the signal over an over-complete dictionary. This over-complete dictionary was designed using K-times Singular Values Decomposition (K-SVD). In each iteration, OMP calculates a new signal approximation and the approximation error is used in the next iteration to determine the new element. The new element corresponds to the largest magnitude of the inner products between the current residual and the original elements in the dictionary. The implemented algorithm was applied to VSP seismic data and refraction seismic data; results for the application in restored missing traces and denoise signals are presented.

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An Approach to Image Compression by Using Sparse Approximation Technique

Cited by 7 publications

References 11 publications

The HTM Spatial Pooler—A Neocortical Algorithm for Online Sparse Distributed Coding

The HTM Spatial Pooler—A Neocortical Algorithm for Online Sparse Distributed Coding

The HTM Spatial Pooler – a neocortical algorithm for online sparse distributed coding

Interpolation and denoising of seismic signals using orthogonal matching pursuit algorithm: An aplication in VSP and refraction data

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