Metadata-Version: 2.1
Name: stochvolmodels
Version: 1.0.20
Summary: Implementation of stochastic volatility models for option pricing
Home-page: https://github.com/ArturSepp/StochVolModels
License: LICENSE.txt
Keywords: volatility,options,Black-Scholes,Heston,Monte-Carlo
Author: Artur Sepp
Author-email: artursepp@gmail.com
Maintainer: Artur Sepp
Maintainer-email: artursepp@gmail.com
Requires-Python: >=3.8
Classifier: Development Status :: 4 - Beta
Classifier: Environment :: Console
Classifier: Intended Audience :: Financial and Insurance Industry
Classifier: Intended Audience :: Science/Research
Classifier: License :: OSI Approved :: MIT License
Classifier: License :: Other/Proprietary License
Classifier: Natural Language :: English
Classifier: Operating System :: OS Independent
Classifier: Programming Language :: Python :: 3
Classifier: Programming Language :: Python :: 3.8
Classifier: Programming Language :: Python :: 3.9
Classifier: Programming Language :: Python :: 3.10
Classifier: Programming Language :: Python :: 3.11
Classifier: Programming Language :: Python :: 3.12
Classifier: Programming Language :: Python :: 3 :: Only
Classifier: Topic :: Office/Business :: Financial :: Investment
Requires-Dist: matplotlib (>=3.5.2)
Requires-Dist: numba (>=0.55)
Requires-Dist: numpy (>=1.22.4)
Requires-Dist: pandas (>=0.19)
Requires-Dist: scipy (>=1.3)
Requires-Dist: seaborn (>=0.11.2)
Requires-Dist: statsmodels (>=0.13.0)
Project-URL: Documentation, https://github.com/ArturSepp/StochVolModels
Project-URL: Issues, https://github.com/ArturSepp/StochVolModels/issues
Project-URL: Personal website, https://artursepp.com
Project-URL: Repository, https://github.com/ArturSepp/StochVolModels
Description-Content-Type: text/markdown

# StochVolModels

Implementation of pricing analytics and Monte Carlo simulations for modeling of options and implied volatilities.

The StochVol package provides:
1) Analytics for Black-Scholes and Normal vols
2) Interfaces and implementation for stochastic volatility models,
including log-normal SV model and Heston SV model 
using analytical method with Fourier transform and Monte Carlo simulations
3) Visualization of model implied volatilities

For the analytic implementation of stochastic volatility models, the package provides interfaces for a generic volatility model with the following features.
1) Interface for analytical pricing of vanilla options 
using Fourier transform with closed-form solution for moment generating function
2) Interface for Monte-Carlo simulations of model dynamics


[Illustrations](#papers) of using package analytics for research 
work is provided in top-level package ```my_papers``` 
which contains computations and visualisations for several papers


## Installation
Install using
```python 
pip install stochvolmodels
```
Upgrade using
```python 
pip install --upgrade stochvolmodels
```
Close using
```python 
git clone https://github.com/ArturSepp/StochVolModels.git
```

# Table of contents
1. [Model Interface](#introduction)
    1. [Log-normal stochastic volatility model](#logsv)
    2. [Heston stochastic volatility model](#hestonsv)
2. [Running log-normal SV pricer](#paragraph1)
   1. [Computing model prices and vols](#subparagraph1)
   2. [Running model calibration to sample Bitcoin options data](#subparagraph2)
   3. [Comparison of model prices vs MC](#subparagraph3)
   4. [Analysis and figures for the paper](#subparagraph4)
3. [Running Heston SV pricer](#heston)
4. [Supporting Illustrations for Public Papers](#papers)


Running model calibration to sample Bitcoin options data

## Implemented Stochastic Volatility models <a name="introduction"></a>
The package provides interfaces for a generic volatility model with the following features.
1) Interface for analytical pricing of vanilla options using Fourier transform with closed-form solution for moment generating function
2) Interface for Monte-Carlo simulations of model dynamics
3) Interface for visualization of model implied volatilities

The model interface is in stochvolmodels/pricers/model_pricer.py

### Log-normal stochastic volatility model <a name="logsv"></a>

The analytics for the log-normal stochastic volatility model is based on the paper

[Log-normal Stochastic Volatility Model with Quadratic Drift](https://www.worldscientific.com/doi/10.1142/S0219024924500031) by Artur Sepp and Parviz Rakhmonov


The dynamics of the log-normal stochastic volatility model:

$$dS_{t}=r(t)S_{t}dt+\sigma_{t}S_{t}dW^{(0)}_{t}$$

$$d\sigma_{t}=\left(\kappa_{1} + \kappa_{2}\sigma_{t} \right)(\theta - \sigma_{t})dt+  \beta  \sigma_{t}dW^{(0)}_{t} +  \varepsilon \sigma_{t} dW^{(1)}_{t}$$

$$dI_{t}=\sigma^{2}_{t}dt$$

where $r(t)$ is the deterministic risk-free rate; $W^{(0)}_{t}$ and $W^{(1)}_t$  are uncorrelated Brownian motions, $\beta\in\mathbb{R}$ is the volatility beta which measures the sensitivity of the volatility to changes in the spot price, and $\varepsilon>0$ is the volatility of residual volatility. We denote by $\vartheta^{2}$, $\vartheta^{2}=\beta^{2}+\varepsilon^{2}$, the total instantaneous variance of the volatility process.


Implementation of Lognormal SV model is contained in 
```python 
stochvolmodels/pricers/logsv_pricer.py
```

### Heston stochastic volatility model <a name="hestonsv"></a>

The dynamics of Heston stochastic volatility model:

$$dS_{t}=r(t)S_{t}dt+\sqrt{V_{t}}S_{t}dW^{(S)}_{t}$$

$$dV_{t}=\kappa (\theta - V_{t})dt+  \vartheta  \sqrt{V_{t}}dW^{(V)}_{t}$$

where  $W^{(S)}$ and $W^{(V)}$ are correlated Brownian motions with correlation parameter $\rho$

Implementation of Heston SV model is contained in 
```python 
stochvolmodels/pricers/heston_pricer.py
```

## Running log-normal SV pricer <a name="paragraph1"></a>

Basic features are implemented in 
```python 
examples/run_lognormal_sv_pricer.py
```

Imports:
```python 
import stochvolmodels as sv
from stochvolmodels import LogSVPricer, LogSvParams, OptionChain
```


### Computing model prices and vols <a name="subparagraph1"></a>

```python 
# instance of pricer
logsv_pricer = LogSVPricer()

# define model params    
params = LogSvParams(sigma0=1.0, theta=1.0, kappa1=5.0, kappa2=5.0, beta=0.2, volvol=2.0)

# 1. compute ne price
model_price, vol = logsv_pricer.price_vanilla(params=params,
                                             ttm=0.25,
                                             forward=1.0,
                                             strike=1.0,
                                             optiontype='C')
print(f"price={model_price:0.4f}, implied vol={vol: 0.2%}")

# 2. prices for slices
model_prices, vols = logsv_pricer.price_slice(params=params,
                                             ttm=0.25,
                                             forward=1.0,
                                             strikes=np.array([0.9, 1.0, 1.1]),
                                             optiontypes=np.array(['P', 'C', 'C']))
print([f"{p:0.4f}, implied vol={v: 0.2%}" for p, v in zip(model_prices, vols)])

# 3. prices for option chain with uniform strikes
option_chain = OptionChain.get_uniform_chain(ttms=np.array([0.083, 0.25]),
                                            ids=np.array(['1m', '3m']),
                                            strikes=np.linspace(0.9, 1.1, 3))
model_prices, vols = logsv_pricer.compute_chain_prices_with_vols(option_chain=option_chain, params=params)
print(model_prices)
print(vols)
```


### Running model calibration to sample Bitcoin options data  <a name="subparagraph2"></a>
```python 
btc_option_chain = chains.get_btc_test_chain_data()
params0 = LogSvParams(sigma0=0.8, theta=1.0, kappa1=5.0, kappa2=None, beta=0.15, volvol=2.0)
btc_calibrated_params = logsv_pricer.calibrate_model_params_to_chain(option_chain=btc_option_chain,
                                                                    params0=params0,
                                                                    constraints_type=ConstraintsType.INVERSE_MARTINGALE)
print(btc_calibrated_params)

logsv_pricer.plot_model_ivols_vs_bid_ask(option_chain=btc_option_chain,
                               params=btc_calibrated_params)
```
![image info](docs/figures/btc_fit.PNG)



### Comparison of model prices vs MC  <a name="subparagraph3"></a>
```python 
btc_option_chain = chains.get_btc_test_chain_data()
uniform_chain_data = OptionChain.to_uniform_strikes(obj=btc_option_chain, num_strikes=31)
btc_calibrated_params = LogSvParams(sigma0=0.8327, theta=1.0139, kappa1=4.8609, kappa2=4.7940, beta=0.1988, volvol=2.3694)
logsv_pricer.plot_comp_mma_inverse_options_with_mc(option_chain=uniform_chain_data,
                                                  params=btc_calibrated_params,
                                                  nb_path=400000)
                                           
```
![image info](docs/figures/btc_mc_comp.PNG)


### Analysis and figures for the paper <a name="subparagraph4"></a>

All figures shown in the paper can be reproduced using py scripts in
```python 
examples/plots_for_paper
```


## Running Heston SV pricer <a name="heston"></a>

Examples are implemented here
```python 
examples/run_heston_sv_pricer.py
examples/run_heston.py
```

Content of run_heston.py
```python 
import numpy as np
import matplotlib.pyplot as plt
from stochvolmodels import HestonPricer, HestonParams, OptionChain

# define parameters for bootstrap
params_dict = {'rho=0.0': HestonParams(v0=0.2**2, theta=0.2**2, kappa=4.0, volvol=0.75, rho=0.0),
               'rho=-0.4': HestonParams(v0=0.2**2, theta=0.2**2, kappa=4.0, volvol=0.75, rho=-0.4),
               'rho=-0.8': HestonParams(v0=0.2**2, theta=0.2**2, kappa=4.0, volvol=0.75, rho=-0.8)}

# get uniform slice
option_chain = OptionChain.get_uniform_chain(ttms=np.array([0.25]), ids=np.array(['3m']), strikes=np.linspace(0.8, 1.15, 20))
option_slice = option_chain.get_slice(id='3m')

# run pricer
pricer = HestonPricer()
pricer.plot_model_slices_in_params(option_slice=option_slice, params_dict=params_dict)

plt.show()
```


## Supporting Illustrations for Public Papers <a name="papers"></a>

As illustrations of different analytics, this packadge includes module ```my_papers``` 
with codes for computations and visualisations featured in several papers
for 

1) "Log-normal Stochastic Volatility Model with Quadratic Drift" by Artur Sepp 
and Parviz Rakhmonov: https://www.worldscientific.com/doi/10.1142/S0219024924500031
```python 
stochvolmodels/my_papers/logsv_model_wtih_quadratic_drift
```


2) "What is a robust stochastic volatility model" by Artur Sepp and Parviz Rakhmonov, SSRN:
https://papers.ssrn.com/sol3/papers.cfm?abstract_id=4647027
```python 
stochvolmodels/my_papers/volatility_models
```


3) "Valuation and Hedging of Cryptocurrency Inverse Options" by Artur Sepp
and Vladimir Lucic, 
SSRN: https://papers.ssrn.com/sol3/papers.cfm?abstract_id=4606748 
```python 
stochvolmodels/my_papers/inverse_options
```

4) "Unified Approach for Hedging Impermanent Loss of Liquidity Provision" by 
Artur Sepp, Alexander Lipton and Vladimir Lucic, 
SSRN: https://papers.ssrn.com/sol3/papers.cfm?abstract_id=4887298 
```python 
stochvolmodels/my_papers/il_hedging
```

