基于机器学习预测股票收益率的两步骤M-SV投资组合优化

doi:10.16381/j.cnki.issn1003-207x.2021.2308

Abstract

Abstract:

Since accurately predicting stock return sequences can improve the performance of portfolio optimization models， the results have indicated that machine learning methods have a greater capacity to confront problems with nonlinear， nonstationary charateristics than econometric models. Consequently， a novel two-stage method is proposed for well-diversified portfolio construction based on stock return prediction using machine learning， which includes two stages. To be specific， the purpose of the first stage is to select diversified stocks with high predicted returns， where the returns are predicted by machine learning methods， i.e. eXtreme Gradient Boosting（XGBoost）， support vector regression（SVR）， K-Nearest Neighbor（KNN）， and evaluate and select the model. In the second stage， considering the constraints such as transaction costs and threshold constraints， the predictive results are incorporated into the mean semi-variance （M-SV） model， mean-variance model and equally weighted model to determine optimal portfolio. Finally， using China Securities 300 Index component stocks as study sample， the empirical results demonstrate that the XGBoost+MSV model achieves better results than similar counterparts and market index in terms of return and return-risk metrics.

Key words: mean semi-variance, pivoting algorithm, machine learning, stock price prediction

CLC Number:

O159

Peng ZHANG,Shi-li DANG,Mei-yu HUANG,Jing-xin LI. Two-stage Mean Semi-variance Portfolio Optimization with Stock Return Prediction Using Machine Learning[J]. Chinese Journal of Management Science, 2023, 31(12): 96-106.

Figures/Tables 13

References 28

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模型		MAE	MSE	RMSE	H_R
XGBoost	Mean	0.0295	0.0012	0.0364	50.92%
XGBoost	Std	0.0230	0.0014	0.0241	0.1010
SVR	Mean	0.0340	0.0025	0.0440	47.85%
SVR	Std	0.0190	0.0029	0.0247	0.1126
KNN	Mean	0.0267	0.0014	0.0330	45.05%
KNN	Std	0.0182	0.0017	0.0185	0.0794

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Two-stage Mean Semi-variance Portfolio Optimization with Stock Return Prediction Using Machine Learning

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