交易频率限制下基于CVaR的多周期稀疏投资组合优化

doi:10.12005/orms.2025.0158

运筹与管理 ›› 2025, Vol. 34 ›› Issue (5): 164-169.DOI: 10.12005/orms.2025.0158

交易频率限制下基于CVaR的多周期稀疏投资组合优化

吴中明¹, 解国玉¹, 屈绍建¹, 王修来²

1.南京信息工程大学管理工程学院,江苏南京 210044;
2.南京信息工程大学管理工程学院人才大数据研究院,江苏南京 210044

收稿日期:2022-06-02 发布日期:2025-08-26
通讯作者: 屈绍建(1978-),男，山东邹城人，教授，博士生导师，研究方向:决策理论与方法，金融风险管理。
作者简介:吴中明(1991-),男,江西赣州人,副教授,硕士生导师,研究方向:运筹优化,金融风险管理。
基金资助:
教育部人文社会科学研究青年基金项目(24YJC630237);国家自然科学基金资助项目(12471291,12001286,72171123,72171149);上海市哲学社会科学基金项目(2020BGL010);国家社会科学基金重大项目(21ZDA105)

Multi-period CVaR-based Sparse Portfolio Selection Optimizationunder Constraints on Trading Frequency

WU Zhongming¹, XIE Guoyu¹, QU Shaojian¹, WANG Xiulai²

1. School of Management Science and Engineering, Nanjing University of Information Science and Technology, Nanjing 210044, China;
2. Talent Big Data Research Institute, School of Management Science and Engineering, Nanjing University of Information Science and Technology, Nanjing 210044, China

Received:2022-06-02 Published:2025-08-26

摘要/Abstract

摘要： 投资组合选择是金融领域的研究热点,本文提出交易频率限制下的多周期稀疏投资组合优化模型。该模型选用条件在险价值(CVaR)度量尾部风险,将经典的l₁范数应用于单周期资产头寸向量及相邻周期投资向量的差值,利用Fused LASSO方法得到稀疏投资组合。针对不等式约束下的非光滑优化模型,运用多块交替方向乘子法进行求解。最后通过样本内和样本外实证分析,发现模型可在预定最小期末收益条件下,降低风险并实现稀疏解目标,验证模型及算法的有效性。

关键词: 多周期, 稀疏投资组合, CVaR, 交易频率, 多块交替方向乘子法

Abstract: With the development of the economy and the increase in the income level of the population, the demand for investment and financial management has been growing. Uncertainty is an essential attribute of financial activities. Return and risk often go hand in hand, and rational investors expect to maximize returns while minimizing risk. Therefore, portfolio selection has been a hot topic of research in the field of finance, where the relationship between risk and return is represented by a quantitative model, which is solved by adding various constraints to determine the specific proportion of each risky asset to be invested. In practice, investment activity is not static and requires consideration of multi-period decision making problems that are flexible and adaptable to market conditions. Technology has improved, financial products are being innovated, the number of risk assets available in the market is vast and the frequency of trading reflects the behaviours of investors’ buying and selling or adding or subtracting positions. In order to reduce management difficulties and transaction costs, it is of great theoretical and practical importance to study the sparse optimization problem of how to select very few assets for investment in the context of high-dimensional data. At the beginning of each new period, the choice is made again in response to new changes in the market.
However, frequent trading behaviour makes it more difficult for investors to manage, and the resulting transaction costs such as commissions and stamp duty are not conducive to achieving optimal returns at the end of the period. A portfolio with a sparse number of investments during the period and a sparse number of trades during the week is more consistent with the optimization objective and the actual situation. Therefore, we add a penalty term to the weight vector in the model to constrain the number of investments and the frequency of transactions during the investment process. A multi-period sparse portfolio optimization model with trading frequency constraints is proposed. The model uses the conditional value at risk (CVaR) as a measure of tail risk, and uses the Fused LASSO method to embody the trading frequency restriction. Applying the classical paradigm to the difference between the single-period asset position vector and the adjacent-period investment vector, we can obtain the optimal solution for different degrees of sparsity by adjusting the size of the canonical parameter. The objective function is set to a minimum CVaR value, while a constraint term on the frequency of trading is added and the investment wealth correlation between the inter-periods is specified. For the non-smooth optimization model with inequality constraints, a multi-block alternating directional multiplier method is applied to solve the problem, decomposing the original problem into multiple sub-problems, which are alternately updated until convergence. The algorithm combines the separability of the dyadic method with the relaxation of the Lagrange multiplier method to reduce computation time.
To verify the validity of the model computational method, the Fama and French database, which is available for download on a public website and consists of 48 industry assets, is first used for the relevant numerical tests. In addition, to better fit the domestic securities market and determine whether the model is practically feasible, 16 representative stocks from each sector are selected from the A-share market, their closing price data are downloaded from Wind Financial Terminal, cleaned and the returns are obtained by the logarithmic method. Through in-sample and out-of-sample empirical analysis, one year is chosen as the interval period in the experiment, and the initial wealth value is set to unit 1. Three indicators reflecting performance are calculated separately: dilution, number of changes in hands and Sharpe ratio. Based on the data, the following conclusions can be drawn: the CVaR-based multi-period sparse portfolio model with trading frequency restrictions proposed in this paper performs better than the equal-weighted model with sufficient risk diversification and the minimum CVaR model. The value-at-risk can be reduced and the sparse solution objective can be achieved under the set minimum end-of-period return condition, while also providing better results in terms of Sharpe ratio. By adjusting the regularisation parameters in the model, personalized investment strategy recommendations can be obtained based on specific investor preferences. The sparse optimization approach can be further improved in subsequent research, where non-convex optimizations such as SCAD and MCP can be substituted for parametric regularization. Alternatively, the idea of robust optimization can be combined with portfolio to find the worst-case optimal solution and eliminate estimation errors.

Key words: multi-period, sparse portfolio, CVaR, trading frequency, multi-block alternating direction method of multiplier

中图分类号:

F830

吴中明, 解国玉, 屈绍建, 王修来. 交易频率限制下基于CVaR的多周期稀疏投资组合优化[J]. 运筹与管理, 2025, 34(5): 164-169.

WU Zhongming, XIE Guoyu, QU Shaojian, WANG Xiulai. Multi-period CVaR-based Sparse Portfolio Selection Optimizationunder Constraints on Trading Frequency[J]. Operations Research and Management Science, 2025, 34(5): 164-169.

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交易频率限制下基于CVaR的多周期稀疏投资组合优化

Multi-period CVaR-based Sparse Portfolio Selection Optimizationunder Constraints on Trading Frequency

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