Abstract

This paper proposes a new manifold-based dimension reduction algorithm framework. It can deal with the dimension reduction problem of data with noise and give the dimension reduction results with the deviation values caused by noise interference. Commonly used manifold learning methods are sensitive to noise in the data. Mean computation, a denoising method, is an important step in data preprocessing but leads to a loss of local structural information. In addition, it is difficult to measure the accuracy of the dimension reduction of noisy data. Thus, manifold learning methods often transform the data into an approximately smooth manifold structure; however, practical data from the physical world may not meet the requirements. The proposed framework follows the idea of the localization of manifolds and uses graph sampling to determine some local anchor points from the given data. Subsequently, the specific range of localities is determined using graph spectral analysis, and the density within each local range is estimated to obtain the distribution parameters. Then, manifold-based dimension reduction with distribution parameters is established, and the deviation values in each local range are measured and further extended to all data. Thus, our proposed framework gives a measurement method for deviation caused by noise.

Highlights

  • Manifold learning is used for nonlinear dimension reduction of natural and general data. ese data are often assumed to be nonlinear manifolds embedded in low-dimensional space [1]

  • When the data are ideally located on a smooth manifold, manifold-based methods such as ISOMAP [2], local linear embedding (LLE) [3], Laplace embedding (LE) [4], and local tangent space alignment (LTSA) [5] can give effective and accurate low-dimensional structures

  • In order to further achieve the dimension reduction of the overall noisy data and measure the interference effect of noise, based on obtaining the manifold dimension reduction with distribution parameters of the anchor vectors and their local deviation values, the framework in this study provides a distance-weighted method for dimension reduction values of the original noisy data

Read more

Summary

Research Article

A Manifold-Based Dimension Reduction Algorithm Framework for Noisy Data Using Graph Sampling and Spectral Graph. Is paper proposes a new manifold-based dimension reduction algorithm framework. It can deal with the dimension reduction problem of data with noise and give the dimension reduction results with the deviation values caused by noise interference. It is difficult to measure the accuracy of the dimension reduction of noisy data. E proposed framework follows the idea of the localization of manifolds and uses graph sampling to determine some local anchor points from the given data. En, manifold-based dimension reduction with distribution parameters is established, and the deviation values in each local range are measured and further extended to all data. Us, our proposed framework gives a measurement method for deviation caused by noise The specific range of localities is determined using graph spectral analysis, and the density within each local range is estimated to obtain the distribution parameters. en, manifold-based dimension reduction with distribution parameters is established, and the deviation values in each local range are measured and further extended to all data. us, our proposed framework gives a measurement method for deviation caused by noise

Introduction
Part of manifold learning with distribution parameters
Experiments
Original data Anchor vectors
ISOMAP method of dimension reduction of the mean vectors
Nearest neighbors
Findings
LSTA dimension reduction of pants images

Talk to us

Join us for a 30 min session where you can share your feedback and ask us any queries you have

Schedule a call

Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.