Tekil değer ayrışımına dayalı ön koşullamanın sıkıştırmalı sınıflamaya etkisi

Yıl 2022, Cilt: 37 Sayı: 4, 1997 - 2012, 28.02.2022

Özgür Devrim Orman Derya Yılmaz

https://doi.org/10.17341/gazimmfd.839206

Öz

Dünyada depolanmakta ve işlenmekte olan veri miktarının hızla artması nedeniyle, veri saklama ve veriden bilgi üretimi alanlarında yenilikçi çözümlere her geçen gün daha fazla gereksinim duyulmaktadır; Sıkıştırmalı Örnekleme (SÖ) ve Sıkıştırmalı Sınıflama (SS) sırasıyla her iki alan için çözüm sunan iki yaklaşımdır. Veriden sınıflama yoluyla bilgi edinilmesinde SS kullanımı, sınıflamanın doğrudan SÖ ile elde edilen ölçüm uzayında gerçekleştirilebilmesini sağladığı için işlem yükünü düşürür. SÖ, Shannon örnekleme teoreminde gerek duyulan miktardan daha az sayıda örnekle kayıpsız bir geri çatımı yüksek olasılıkla mümkün kılmakta olup, kullanılan ölçüm matrisine Ön koşullama (ÖK) uygulanmasıyla geri çatım için gerekli örnek sayısı, dolayısıyla saklanması gereken veri miktarı daha da azaltılabilmektedir. SÖ’de ölçüm matrisi olarak, ölçüm matrisinden Tekil Değer Ayrışımı (TDA) ile türetilen matrisin kullanımının geri çatım başarımına katkısı literatürde salt deneysel olarak incelenmiştir. Bu çalışmada, literatürde bir ilk olarak, TDA’ya dayalı söz konusu yaklaşımın bir ÖK olduğu (TDA-ÖK) ve SÖ’de geri çatım için gerekli örnek sayısını düşüreceği analitik olarak gösterilmiş olup, bu bulguya ilişkin iki farklı Monte Carlo (MC) benzetimi gerçekleştirilmiştir. Benzetimlerle desteklenen TDA-ÖK başarımı deneysel olarak da iki farklı veri kümesi üzerinde ve üç farklı sınıflayıcı kullanılarak gerçekleştirilen SS uygulamaları ile değerlendirilerek, TDA-ÖK kullanımının SS başarımına etkisi yine literatürde ilk defa bu çalışmada incelenmiştir.

Anahtar Kelimeler

Ön koşullama, Tekil değer ayrışımı, Sıkıştırmalı örnekleme, Sıkıştırmalı sınıflama, Wielandt eşitsizliği

Effect of singular value decomposition based preconditioning on compressive classification

Öz

Due to the rapid increase in the amount of data being stored and processed in the world, innovative solutions in the fields of data storage and data processing are increasingly needed; Compressive Sampling (CS) and Compressive Classification (CC) are two approaches that provide solutions for both areas, respectively. The use of CC to obtain information from the data through classification reduces the processing load as it enables the classification to be performed directly in the measurement domain obtained by CS. CS makes possible a lossless reconstruction with a high probability of less samples than the amount required by the Shannon sampling theorem, and by applying Preconditioning (PC) to the measurement matrix used, the amount of data required for reconstruction can be further reduced due to the number of samples required for reconstruction. The contribution of the use of the matrix derived from the measurement matrix by Singular Value Decomposition (SVD) as the measurement matrix in the CS, on the reconstruction performance has been studied only experimentally in the literature. In this study, as a first, it has been shown analytically that this approach based on SVD is a PC (SVD-PC) and will reduce the number of samples required for reconstruction in CS, meanwhile two different Monte Carlo (MC) simulations were carried out regarding to this finding. The SVD-PC performance supported by simulations is evaluated experimentally with SS applications performed on two different data sets and using three different classifiers, moreover the effect of SVD-PC on CC performance is investigated for the first time in the literature in this study.

Anahtar Kelimeler

Preconditioning, Singular value decomposition, Compressive sampling, Compressive classification, Wielandt inequality

Kaynakça

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