Option valuation under no-arbitrage constraints with neural networks

Yi Cao; Xiaoquan Liu; Jia Zhai

doi:10.1016/j.ejor.2020.12.003

Option valuation under no-arbitrage constraints with neural networks

Yi Cao, Xiaoquan Liu, Jia Zhai

Department of Finance, Accounting and Economics

Research output: Journal Publication › Article › peer-review

7 Citations (Scopus)

33 Downloads (Pure)

Abstract

In this paper, we start from the no-arbitrage constraints in option pricing and develop a novel hybrid gated neural network (hGNN) based option valuation model. We adopt a multiplicative structure of hidden layers to ensure model differentiability. We also select the slope and weights of input layers to satisfy the no-arbitrage constraints. Meanwhile, a separate neural network is constructed for predicting option-implied volatilities. Using S&P 500 options, our empirical analyses show that the hGNN model substantially outperforms well-established alternative models in the out-of-sample forecasting and hedging exercises. The superior prediction performance stems from our model's ability in describing options on the boundary, and in offering analytical expressions for option Greeks which generate better hedging results.

Original language	English
Pages (from-to)	361-374
Number of pages	14
Journal	European Journal of Operational Research
Volume	293
Issue number	1
DOIs	https://doi.org/10.1016/j.ejor.2020.12.003
Publication status	Published - 16 Aug 2021

Keywords

Artificial neural networks
Finance
Hedging
Implied volatilities
Option greeks

ASJC Scopus subject areas

General Computer Science
Modelling and Simulation
Management Science and Operations Research
Information Systems and Management

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10.1016/j.ejor.2020.12.003

3 CombineAccepted author manuscript, 3.72 MBLicence: CC BY

Cite this

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AB - In this paper, we start from the no-arbitrage constraints in option pricing and develop a novel hybrid gated neural network (hGNN) based option valuation model. We adopt a multiplicative structure of hidden layers to ensure model differentiability. We also select the slope and weights of input layers to satisfy the no-arbitrage constraints. Meanwhile, a separate neural network is constructed for predicting option-implied volatilities. Using S&P 500 options, our empirical analyses show that the hGNN model substantially outperforms well-established alternative models in the out-of-sample forecasting and hedging exercises. The superior prediction performance stems from our model's ability in describing options on the boundary, and in offering analytical expressions for option Greeks which generate better hedging results.

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KW - Hedging

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Option valuation under no-arbitrage constraints with neural networks

Abstract

Keywords

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