Machine Learning and Portfolio Optimization

Ban, Gah‐Yi; Karoui, Noureddine El; Lim, Andrew

doi:10.1287/mnsc.2016.2644

Cited by 225 publications

(88 citation statements)

References 51 publications

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“…In recent years, Deep Learning (DL) has generated a resurgence of interest in machine learning and neural networks. DL is a technology that has provided impressive performance in such diverse application fields as robotics, visual object recognition, image classification, health, financial analysis and speech recognition [ 1 , 2 , 3 , 4 ]. In general, DL allows learning representative features of a problem hierarchically, from raw data [ 5 , 6 ].…”

Section: Introductionmentioning

confidence: 99%

Information Theoretic-Based Interpretation of a Deep Neural Network Approach in Diagnosing Psychogenic Non-Epileptic Seizures

Gasparini

Campolo

Ieracitano

et al. 2018

Entropy

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Abstract:The use of a deep neural network scheme is proposed to help clinicians solve a difficult diagnosis problem in neurology. The proposed multilayer architecture includes a feature engineering step (from time-frequency transformation), a double compressing stage trained by unsupervised learning, and a classification stage trained by supervised learning. After fine-tuning, the deep network is able to discriminate well the class of patients from controls with around 90% sensitivity and specificity. This deep model gives better classification performance than some other standard discriminative learning algorithms. As in clinical problems there is a need for explaining decisions, an effort has been carried out to qualitatively justify the classification results. The main novelty of this paper is indeed to give an entropic interpretation of how the deep scheme works and reach the final decision.

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Section: Introductionmentioning

confidence: 99%

Information Theoretic-Based Interpretation of a Deep Neural Network Approach in Diagnosing Psychogenic Non-Epileptic Seizures

Gasparini

Campolo

Ieracitano

et al. 2018

Entropy

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“…In financial contexts, Ban et al [ 45 ] discussed the effects of performance-based regularization in portfolio optimization for mean-variance and mean-conditional Value-at-Risk problems, showing evidence for its superiority towards traditional optimization and regularization methods in terms of diminishing the estimation error and shrinking the model’s overall complexity.…”

Section: Theoretical Backgroundmentioning

confidence: 99%

Between Nonlinearities, Complexity, and Noises: An Application on Portfolio Selection Using Kernel Principal Component Analysis

Peng

Albuquerque

Nascimento

et al. 2019

Entropy

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This paper discusses the effects of introducing nonlinear interactions and noise-filtering to the covariance matrix used in Markowitz’s portfolio allocation model, evaluating the technique’s performances for daily data from seven financial markets between January 2000 and August 2018. We estimated the covariance matrix by applying Kernel functions, and applied filtering following the theoretical distribution of the eigenvalues based on the Random Matrix Theory. The results were compared with the traditional linear Pearson estimator and robust estimation methods for covariance matrices. The results showed that noise-filtering yielded portfolios with significantly larger risk-adjusted profitability than its non-filtered counterpart for almost half of the tested cases. Moreover, we analyzed the improvements and setbacks of the nonlinear approaches over linear ones, discussing in which circumstances the additional complexity of nonlinear features seemed to predominantly add more noise or predictive performance.

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“…Asymptotic normality of (x n (δ), c n (δ)) follows from consistency (Proposition 4.1) and Theorem A.1. 1 We have added a scaling constant − φ (2) (1) δ in the second equation. Note that this constant does not affect the solution of the first order conditions, but does make subsequent analysis more convenient.…”

Section: Robust Optimizationmentioning

confidence: 99%

Calibration of Distributionally Robust Empirical Optimization Models

2017

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In this paper, we study the out-of-sample properties of robust empirical optimization and develop a theory for data-driven calibration of the "robustness parameter" for worst-case maximization problems with concave reward functions. Building on the intuition that robust optimization reduces the sensitivity of the expected reward to errors in the model by controlling the spread of the reward distribution, we show that the first-order benefit of "little bit of robustness" is a significant reduction in the variance of the out-of-sample reward while the corresponding impact on the mean is almost an order of magnitude smaller. One implication is that a substantial reduction in the variance of the out-of-sample reward (i.e. sensitivity of the expected reward to model misspecification) is possible at little cost if the robustness parameter is properly calibrated. To this end, we introduce the notion of a robust mean-variance frontier to select the robustness parameter and show that it can be approximated using resampling methods like the bootstrap. Our examples also show that "open loop" calibration methods (e.g. selecting a 90% confidence level regardless of the data and objective function) can lead to solutions that are very conservative out-of-sample.

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Machine Learning and Portfolio Optimization

Cited by 225 publications

References 51 publications

Information Theoretic-Based Interpretation of a Deep Neural Network Approach in Diagnosing Psychogenic Non-Epileptic Seizures

Information Theoretic-Based Interpretation of a Deep Neural Network Approach in Diagnosing Psychogenic Non-Epileptic Seizures

Between Nonlinearities, Complexity, and Noises: An Application on Portfolio Selection Using Kernel Principal Component Analysis

Calibration of Distributionally Robust Empirical Optimization Models

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