Generalized distribution prediction for asset returns
Generalized distribution prediction for asset returns
We present a novel approach for predicting the distribution of asset returns using a quantile-based method with Long Short-Term Memory (LSTM) networks. Our model is designed in two stages: the first focuses on predicting the quantiles of normalized asset returns using asset-specific features, while the second stage incorporates market data to adjust these predictions for broader economic conditions. This results in a generalized model that can be applied across various asset classes, including commodities, cryptocurrencies, as well as synthetic datasets. The predicted quantiles are then converted into full probability distributions through kernel density estimation, allowing for more precise return distribution predictions and inferencing. The LSTM model significantly outperforms a linear quantile regression baseline by 98% and a dense neural network model by over 50%, showcasing its ability to capture complex patterns in financial return distributions across both synthetic and real-world data. By using exclusively asset-class-neutral features, our model achieves robust, generalizable results.
q-fin.ST, cs.LG
Pétursson, Ísak
de802bfa-a3b0-4985-8370-767cdb8edc0e
Óskarsdóttir, María
d159ed8f-9dd3-4ff3-8b00-d43579ab71be
15 October 2024
Pétursson, Ísak
de802bfa-a3b0-4985-8370-767cdb8edc0e
Óskarsdóttir, María
d159ed8f-9dd3-4ff3-8b00-d43579ab71be
[Unknown type: UNSPECIFIED]
Abstract
We present a novel approach for predicting the distribution of asset returns using a quantile-based method with Long Short-Term Memory (LSTM) networks. Our model is designed in two stages: the first focuses on predicting the quantiles of normalized asset returns using asset-specific features, while the second stage incorporates market data to adjust these predictions for broader economic conditions. This results in a generalized model that can be applied across various asset classes, including commodities, cryptocurrencies, as well as synthetic datasets. The predicted quantiles are then converted into full probability distributions through kernel density estimation, allowing for more precise return distribution predictions and inferencing. The LSTM model significantly outperforms a linear quantile regression baseline by 98% and a dense neural network model by over 50%, showcasing its ability to capture complex patterns in financial return distributions across both synthetic and real-world data. By using exclusively asset-class-neutral features, our model achieves robust, generalizable results.
Text
2410.23296v2
- Author's Original
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Published date: 15 October 2024
Keywords:
q-fin.ST, cs.LG
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Local EPrints ID: 499138
URI: http://eprints.soton.ac.uk/id/eprint/499138
PURE UUID: 47ef1ab4-3d47-4d77-b822-235560ed8604
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Date deposited: 10 Mar 2025 18:03
Last modified: 11 Mar 2025 03:15
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Author:
Ísak Pétursson
Author:
María Óskarsdóttir
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