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Príznaky Znižovanie dimenzie: viac príznakov => viac informácie, vyššia presnosť viac príznakov => zložitejšia extrakcia viac príznakov => zložitejší tréning.

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Presentation on theme: "Príznaky Znižovanie dimenzie: viac príznakov => viac informácie, vyššia presnosť viac príznakov => zložitejšia extrakcia viac príznakov => zložitejší tréning."— Presentation transcript:

1 Príznaky Znižovanie dimenzie: viac príznakov => viac informácie, vyššia presnosť viac príznakov => zložitejšia extrakcia viac príznakov => zložitejší tréning klasifikátora The curse of dimensionality Riešenie: zníženie počtu príznakov

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3 Výber príznakov: vyberieme podmnožinu Redukcia príznakov: transformujeme pôvodnú množinu do menej-dimenzionálnej

4 Zoradenie príznakov podľa vhodnosti - ohodnotenie jednotlivých príznakov identifikácia relevantných príznakov, nevyhodnocuje sa nadbytočnosť príznakov Hľadanie vhodnej podmnožiny - ohodnotenie podmnožín príznakov identifikácia minimálnej podmnožiny príznakov, implicitne sa vyhodnocuje nadbytočnosť príznakov 2 d podmnožín d príznakov Typy algoritmov

5 Filter Separating feature selection from classifier learning Relying on general characteristics of data (information, distance, dependence, consistency) No bias toward any learning algorithm, fast Výber príznakov

6 Zoradenie príznakov podľa vhodnosti ohodnotenie jednotlivých príznakov výber najlepších Výhody Efektívnosť Ľahká implementácia Nevýhody ťažko určiť vhodný prah neuvažuje sa vzťah medzi príznakmi

7 Výber vhodných príznakov Forward1: N príznakov s najvyšším skóre Forward2: 1. vyber príznak s najvyšším skóre 2. – prerátaj skóre zvyšných príznakov – opakuj, kým nevyberieš N príznakov

8 Výber príznakov Backward1: Z množiny príznakov odstráň N príznakov s najnižším skóre Backward2: 1. Z množiny príznakov odstráň príznak s najnižším skóre 2. – prerátaj skóre zvyšných príznakov – opakuj, kým neodstrániš N príznakov

9 Hodnotiace miery Miery vhodnosti príznakov Filter: -Konzistencia -Medzitriedna vzdialenosť -Štatistická závislosť -Informačno-teoretické miery Wrapper: Prediktívna schopnosť množiny trénovacích príznakov (kvalita rozpoznávania pre testovacie dáta) krížová validácia

10 Konzistencia Podmnožina príznakov musí separovať triedy tak konzistentne ako celá množina Nekonzistencia, ak objekty s rovnakými príznakmi patria rôznym triedam

11 Štatistická závislosť Korelačný keoficient Závislosť → štatistická nadbytočnosť zdrojových dát Nekorelovanosť ≠ nezávislosť Iba ak X a Y majú normálne rozdelenie

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14 -p*log(p)-(1-p)*log(1-p) Informačno-teoretické miery

15 Entropia H(X) = 1.5 H(Y) = 1 X = College Major Y = Likes “XBOX” XY MathYes HistoryNo CSYes MathNo MathNo CSYes HistoryNo MathYes log 2

16 Špecifická podmienená entropia X = College Major Y = Likes “XBOX” XY MathYes HistoryNo CSYes MathNo MathNo CSYes HistoryNo MathYes H(Y |X=v) = entropia len týchY, X =v H(Y|X=Math) = 1 H(Y|X=History) = 0 H(Y|X=CS) = 0

17 Podmienená entropia X = College Major Y = Likes “XBOX” XY MathYes HistoryNo CSYes MathNo MathNo CSYes HistoryNo MathYes H(Y|X) = priemerná špecifická podmienená entropia Y = Σ j P(X=v j ) H(Y | X = v j ) vjvjvjvj Prob(X=v j ) H(Y | X = v j ) Math0.51 History0.250 CS0.250 H(Y|X) =.5

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19 Vzájomná informácia H(Y) = 1 H(Y|X) = 0.5 I(Y|X) = 0.5 X = College Major Y = Likes “XBOX” XY MathYes HistoryNo CSYes MathNo MathNo CSYes HistoryNo MathYes Ako sa znížia nároky (počet bitov) na prenos informácie Y, ak odosielateľ aj prijímateľ poznajú X? I(Y|X) = H(Y) - H(Y |X)

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21 Wrapper Relying on a predetermined classification algorithm Using predictive accuracy as goodness measure High accuracy, computationally expensive Výber príznakov

22 Wrapper Learning algorithm is a black box computes objective function OF(s) Účelová funkcia Exhaustive search 2 d possible subsets Greedy search is common and effective Genetic algorithms …

23 Hľadanie optimálnej podmnožiny Backward elimination tends to find better models too expensive to fit the large sets at the beginning of search Both can be too greedy. Backward elimination Initialize s={1,2,…,n} Do: remove feature from s which improves OF(s) most While OF(s) can be improved Forward selection Initialize s={} Do: Add feature to s which improves OF(s) most While OF(s) can be improved

24 Ohodnotenie podmnožiny We’re not ultimately interested in training error; we’re interested in test error (error on new data). We can estimate test error by pretending we haven’t seen some of our data. Keep some data aside as a validation set. If we don’t use it in training, then it’s a fair test of our model.

25 K-fold cross validation Rozdeľ dáta na K skupín Každú skupinu použi na validáciu Zisti priemernú chybu X1X1 Learn X2X2 X3X3 X4X4 X5X5 X6X6 X7X7 test

26 X1X1 Learn X2X2 X3X3 X4X4 X5X5 X6X6 X7X7 test K-fold cross validation Rozdeľ dáta na K skupín Každú skupinu použi na validáciu Zisti priemernú chybu

27 X1X1 … Learn X2X2 X3X3 X4X4 X5X5 X6X6 X7X7 test K-fold cross validation Rozdeľ dáta na K skupín Každú skupinu použi na validáciu Zisti priemernú chybu

28 X1X1 Learn X2X2 X3X3 X4X4 X5X5 X6X6 X7X7 K-fold cross validation Rozdeľ dáta na K skupín Každú skupinu použi na validáciu Zisti priemernú chybu OF

29 Feature Reduction Algorithms Unsupervised (minimize the information loss) Latent Semantic Indexing (LSI): truncated SVD Independent Component Analysis (ICA) Principal Component Analysis (PCA) Manifold learning algorithms (a manifold is a topological space which is locally Euclidean) - Nonlinear Supervised (maximize the class discrimination) Linear Discriminant Analysis (LDA) Canonical Correlation Analysis (CCA) Partial Least Squares (PLS)

30 Principal Component Analysis (PCA) Karhunen-Loeve or K-L method PCA finds the best “subspace” that captures as much data variance as possible Based on eigen-decomposition of data covariance matrix Very simple! Data can be represented as linear combination of features

31 PCA otočí súradnicovú sústavu tak, aby prvá os bola v smere najväčšej variability a ďalšie boli na ňu kolmé v smeroch najväčšej zvyšnej variability. nová ortonormálna báza

32 Very Nice When Initial Dimension Not Too Big What if very large dimensional data? Images e.g., (d ~10 4 ) Problem: Covariance matrix Σ is size (d x d) d=10 4 | Σ | = 10 8 Singular Value Decomposition (SVD) to the rescue!

33 SVD Singulárne číslo a singulárne vektory matice pre reálne matice

34 Vzťah medzi PCA a SVD použitie SVD namiesto PCA

35 ICA (Independent Components Analysis) Relaxes the constraint of orthogonality but keeps the linearity. Thus, could be more flexible than PCA in finding patterns.

36 PCA is not always an optimal dimensionality-reduction procedure for classification purposes. PCA is based on the sample covariance which characterizes the scatter of the entire data set, irrespective of class-membership. The projection axes chosen by PCA might not provide good discrimination power.

37 Linear Discriminant Analysis (LDA) What is the goal of LDA? Perform dimensionality reduction “while preserving as much of the class discriminatory information as possible”. Seeks to find directions along which the classes are best separated. Takes into consideration the scatter within-classes but also the scatter between-classes.

38 Fisherova lineárna disriminačná analýza riadená metóda využíva informáciu o klasifikačných triedach

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40 Variability premietnutých príznakov

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43 PCA is first applied to the data set to reduce its dimensionality. LDA is then applied to find the most discriminative directions:

44 Case Study: PCA versus LDA A. Martinez, A. Kak, "PCA versus LDA", IEEE Transactions on Pattern Analysis and Machine Intelligence, vol. 23, no. 2, pp. 228-233, 2001. Is LDA always better than PCA? There has been a tendency in the computer vision community to prefer LDA over PCA. This is mainly because LDA deals directly with discrimination between classes while PCA does not pay attention to the underlying class structure. Main results of this study: (1) When the training set is small, PCA can outperform LDA. (2) When the number of samples is large and representative for each class, LDA outperforms PCA.

45 LDA is a parametric method since it assumes unimodal Gaussian likelihoods If the distributions are significantly non-Gaussian, the LDA projections will not be able to preserve any complex structure of the data, which may be needed for classification LDA will fail when the discriminatory information is not in the mean but rather in the variance Nevýhody LDA?

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48 Deficiencies of Linear Methods Data may not be best summarized by linear combination of features

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