In this paper we propose the first calibration exercise based on quantization methods. Pricing and calibration are typically difficult tasks to accomplish: pricing should be fast and accurate, otherwise calibration cannot be performed efficiently. We apply in a local volatility context the recursive marginal quantization methodology to the pricing of vanilla and barrier options. A successful calibration of the Quadratic Normal Volatility model is performed in order to show the potentiality of the method in a concrete example, while a numerical exercise on barrier options shows that quantization overcomes Monte-Carlo methods
The two most popular equity derivatives pricing models among practitioners are the local volatility ...
We address the inverse problem of local volatility surface calibration from market given option pric...
We present a new numerical method to price vanilla options quickly in time-changed Brownian motion m...
Pricing of a derivative should be fast and accurate, otherwise it cannot be calibrated efficiently. ...
We provide the first recursive quantization-based approach for pricing options in the presence of st...
A general purpose of mathematical models is to accurately mimic some observed phenomena in the real ...
This paper presents a new algorithm to calibrate the option pricing model, i.e. the algorithm that r...
In this paper, we consider a large class of continuous semi-martingale models and propose a generic ...
This paper compares the performance of three methods for pricing vanilla options in models with know...
We document the calibration of the local volatility in terms of local and implied instantaneous vari...
This paper compares the performance of three methods for pricing vanilla options in models with know...
We review a model for computing the price, in the domestic currency, of European standard call and p...
We propose a new method to calibrate the local volatility function of an asset from observed option ...
We develop a Lagrangian based method for solving the calibration problem of identifying a local vola...
This dissertation is devoted to high performance numerical methods for option valuation and model ca...
The two most popular equity derivatives pricing models among practitioners are the local volatility ...
We address the inverse problem of local volatility surface calibration from market given option pric...
We present a new numerical method to price vanilla options quickly in time-changed Brownian motion m...
Pricing of a derivative should be fast and accurate, otherwise it cannot be calibrated efficiently. ...
We provide the first recursive quantization-based approach for pricing options in the presence of st...
A general purpose of mathematical models is to accurately mimic some observed phenomena in the real ...
This paper presents a new algorithm to calibrate the option pricing model, i.e. the algorithm that r...
In this paper, we consider a large class of continuous semi-martingale models and propose a generic ...
This paper compares the performance of three methods for pricing vanilla options in models with know...
We document the calibration of the local volatility in terms of local and implied instantaneous vari...
This paper compares the performance of three methods for pricing vanilla options in models with know...
We review a model for computing the price, in the domestic currency, of European standard call and p...
We propose a new method to calibrate the local volatility function of an asset from observed option ...
We develop a Lagrangian based method for solving the calibration problem of identifying a local vola...
This dissertation is devoted to high performance numerical methods for option valuation and model ca...
The two most popular equity derivatives pricing models among practitioners are the local volatility ...
We address the inverse problem of local volatility surface calibration from market given option pric...
We present a new numerical method to price vanilla options quickly in time-changed Brownian motion m...