Shotaro Akaho scite author profile

Abstract.With the spread of data mining technologies and the accumulation of social data, such technologies and data are being used for determinations that seriously affect individuals' lives. For example, credit scoring is frequently determined based on the records of past credit data together with statistical prediction techniques. Needless to say, such determinations must be nondiscriminatory and fair in sensitive features, such as race, gender, religion, and so on. Several researchers have recently begun to attempt the development of analysis techniques that are aware of social fairness or discrimination. They have shown that simply avoiding the use of sensitive features is insufficient for eliminating biases in determinations, due to the indirect influence of sensitive information. In this paper, we first discuss three causes of unfairness in machine learning. We then propose a regularization approach that is applicable to any prediction algorithm with probabilistic discriminative models. We further apply this approach to logistic regression and empirically show its effectiveness and efficiency.

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Fairness-aware Learning through Regularization Approach

Kobayashi

2011

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Abstract-With the spread of data mining technologies and the accumulation of social data, such technologies and data are being used for determinations that seriously affect people's lives. For example, credit scoring is frequently determined based on the records of past credit data together with statistical prediction techniques. Needless to say, such determinations must be socially and legally fair from a viewpoint of social responsibility; namely, it must be unbiased and nondiscriminatory in sensitive features, such as race, gender, religion, and so on. Several researchers have recently begun to attempt the development of analysis techniques that are aware of social fairness or discrimination. They have shown that simply avoiding the use of sensitive features is insufficient for eliminating biases in determinations, due to the indirect influence of sensitive information. From a privacy-preserving viewpoint, this can be interpreted as hiding sensitive information when classification results are observed. In this paper, we first discuss three causes of unfairness in machine learning. We then propose a regularization approach that is applicable to any prediction algorithm with probabilistic discriminative models. We further apply this approach to logistic regression and empirically show its effectiveness and efficiency.

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Introduction to Canonical Correlation Analysis

Akaho

2013

The Brain & Neural Networks

112

166

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Canonical correlation analysis is a technique to extract common features from a pair of multivariate data. In complex situations, however, it does not extract useful features because of its linearity. On the other hand, kernel method used in support vector machine is an efficient approach to improve such a linear method. In this paper, we investigate the effectiveness of applying kernel method to canonical correlation analysis.

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Learning algorithms utilizing quasi-geodesic flows on the Stiefel manifold

2005

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Universal statistics of Fisher information in deep neural networks: mean field approach^*

Karakida¹,

Akaho²,

Амари³

2020

J. Stat. Mech.

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The Fisher information matrix (FIM) is a fundamental quantity to represent the characteristics of a stochastic model, including deep neural networks (DNNs). The present study reveals novel statistics of FIM that are universal among a wide class of DNNs. To this end, we use random weights and large width limits, which enables us to utilize mean field theories. We investigate the asymptotic statistics of the FIM’s eigenvalues and reveal that most of them are close to zero while the maximum eigenvalue takes a huge value. Because the landscape of the parameter space is defined by the FIM, it is locally flat in most dimensions, but strongly distorted in others. Moreover, we demonstrate the potential usage of the derived statistics in learning strategies. First, small eigenvalues that induce flatness can be connected to a norm-based capacity measure of generalization ability. Second, the maximum eigenvalue that induces the distortion enables us to quantitatively estimate an appropriately sized learning rate for gradient methods to converge.

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Shotaro Akaho

Fairness-Aware Classifier with Prejudice Remover Regularizer

Fairness-aware Learning through Regularization Approach

Introduction to Canonical Correlation Analysis

Learning algorithms utilizing quasi-geodesic flows on the Stiefel manifold

Universal statistics of Fisher information in deep neural networks: mean field approach^*

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Resources

About

Shotaro Akaho

Fairness-Aware Classifier with Prejudice Remover Regularizer

Fairness-aware Learning through Regularization Approach

Introduction to Canonical Correlation Analysis

Learning algorithms utilizing quasi-geodesic flows on the Stiefel manifold

Universal statistics of Fisher information in deep neural networks: mean field approach*

Contact Info

Product

Resources

About

Universal statistics of Fisher information in deep neural networks: mean field approach^*