Cited By
View all- Mukherjee ASinghal RShroff G(2024)Numin: Weighted-Majority Ensembles for Intraday TradingProceedings of the 5th ACM International Conference on AI in Finance10.1145/3677052.3698656(703-710)Online publication date: 14-Nov-2024
Conservative Predictions on Noisy Financial Data
Pages 427 - 435
Abstract
Price movements in financial markets are well known to be very noisy. As a result, even if there are, on occasion, exploitable patterns that could be picked up by machine-learning algorithms, these are obscured by feature and label noise rendering the predictions less useful, and risky in practice. Traditional rule-learning techniques developed for noisy data, such as CN2, would seek only high precision rules and refrain from making predictions where their antecedents did not apply. We apply a similar approach, where a model abstains from making a prediction on data points that it is uncertain on. During training, a cascade of such models are learned in sequence, similar to rule lists, with each model being trained only on data on which the previous model(s) were uncertain. Similar pruning of data takes place at test-time, with (higher accuracy) predictions being made albeit only on a fraction (support) of test-time data. In a financial prediction setting, such an approach allows decisions to be taken only when the ensemble model is confident, thereby reducing risk. We present results using traditional MLPs as well as differentiable decision trees, on synthetic data as well as real financial market data, to predict fixed-term returns using commonly used features. We submit that our approach is likely to result in better overall returns at a lower level of risk. In this context we introduce an utility metric to measure the average gain per trade, as well as the return adjusted for downside-risk, both of which are improved significantly by our approach.
References
[1]
Shahrokh Asadi and Jamal Shahrabi. 2016. RipMC: RIPPER for multiclass classification. Neurocomputing 191 (2016), 19–33.
[2]
Peter Clark and Tim Niblett. 1989. The CN2 induction algorithm. Machine learning 3 (1989), 261–283.
[3]
Naftali Cohen, Tucker Balch, and Manuela Veloso. 2020. Trading via image classification. In Proceedings of the First ACM International Conference on AI in Finance. 1–6.
[4]
Vasant Dhar. 2011. Prediction in financial markets: The case for small disjuncts. ACM Transactions on Intelligent Systems and Technology (TIST) 2, 3 (2011), 1–22.
[5]
Vasant Dhar, Chenshuo Sun, and Puneet Batra. 2019. Transforming finance into vision: concurrent financial time series as convolutional nets. Big Data 7, 4 (2019), 276–285.
[6]
Yan Duan, John Schulman, Xi Chen, Peter L Bartlett, Ilya Sutskever, and Pieter Abbeel. 2016. Rl 2: Fast reinforcement learning via slow reinforcement learning. arXiv preprint arXiv:1611.02779 (2016).
[7]
Chelsea Finn, Pieter Abbeel, and Sergey Levine. 2017. Model-agnostic meta-learning for fast adaptation of deep networks. In International conference on machine learning. PMLR, 1126–1135.
[8]
Chelsea Finn, Aravind Rajeswaran, Sham Kakade, and Sergey Levine. 2019. Online meta-learning. In International Conference on Machine Learning. PMLR, 1920–1930.
[9]
Nicholas Frosst and Geoffrey Hinton. 2017. Distilling a Neural Network Into a Soft Decision Tree. (11 2017).
[10]
SI Harini, Gautam Shroff, Ashwin Srinivasan, Prayushi Faldu, and Lovekesh Vig. 2023. Neuro-symbolic Meta Reinforcement Learning for Trading. arXiv preprint arXiv:2302.08996 (2023).
[11]
Bryan Lim, Stefan Zohren, and Stephen Roberts. 2019. Enhancing time-series momentum strategies using deep neural networks. The Journal of Financial Data Science 1, 4 (2019), 19–38.
[12]
Rishabh Patra, Ramya Hebbalaguppe, Tirtharaj Dash, Gautam Shroff, and Lovekesh Vig. 2023. Calibrating deep neural networks using explicit regularisation and dynamic data pruning. In Proceedings of the IEEE/CVF Winter Conference on Applications of Computer Vision. 1541–1549.
[13]
Giorgio Patrini, Alessandro Rozza, Aditya Krishna Menon, Richard Nock, and Lizhen Qu. 2017. Making deep neural networks robust to label noise: A loss correction approach. In Proceedings of the IEEE conference on computer vision and pattern recognition. 1944–1952.
[14]
Zhen Qin, Zhengwen Zhang, Yan Li, and Jun Guo. 2019. Making deep neural networks robust to label noise: cross-training with a novel loss function. IEEE access 7 (2019), 130893–130902.
[15]
Scott Reed, Honglak Lee, Dragomir Anguelov, Christian Szegedy, Dumitru Erhan, and Andrew Rabinovich. 2014. Training deep neural networks on noisy labels with bootstrapping. arXiv preprint arXiv:1412.6596 (2014).
[16]
Andrew Silva, Matthew Gombolay, Taylor Killian, Ivan Jimenez, and Sung-Hyun Son. 2020. Optimization methods for interpretable differentiable decision trees applied to reinforcement learning. In International conference on artificial intelligence and statistics. PMLR, 1855–1865.
[17]
Alberto Suarez and James Lutsko. 1999. Globally Optimal Fuzzy Decision Trees for Classification and Regression.IEEE Trans. Pattern Anal. Mach. Intell. 21 (01 1999), 1297–1311.
[18]
Kieran Wood, Sven Giegerich, Stephen Roberts, and Stefan Zohren. 2021. Trading with the Momentum Transformer: An Intelligent and Interpretable Architecture. arXiv preprint arXiv:2112.08534 (2021).
[19]
Zihao Zhang, Stefan Zohren, and Stephen Roberts. 2020. Deep reinforcement learning for trading. The Journal of Financial Data Science 2, 2 (2020), 25–40.
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November 2023
697 pages
ISBN:9798400702402
DOI:10.1145/3604237
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Published: 25 November 2023
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View all- Mukherjee ASinghal RShroff G(2024)Numin: Weighted-Majority Ensembles for Intraday TradingProceedings of the 5th ACM International Conference on AI in Finance10.1145/3677052.3698656(703-710)Online publication date: 14-Nov-2024
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