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https://github.com/RomanMichaelPaolucci/Q-Fin

A Python library for mathematical finance
https://github.com/RomanMichaelPaolucci/Q-Fin
mathematical-finance option-pricing python quantitative-finance
Last synced: about 1 month ago
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A Python library for mathematical finance
Host: GitHub
URL: https://github.com/RomanMichaelPaolucci/Q-Fin
Owner: romanmichaelpaolucci
License: mit
Created: 2021-04-21T13:29:51.000Z (over 3 years ago)
Default Branch: main
Last Pushed: 2023-10-31T17:32:45.000Z (11 months ago)
Last Synced: 2024-04-17T10:58:52.020Z (5 months ago)
Topics: mathematical-finance, option-pricing, python, quantitative-finance
Language: Python
Homepage:
Size: 131 KB
Stars: 367
Watchers: 11
Forks: 51
Open Issues: 1
Metadata Files:
- Readme: README.md
- License: LICENSE
Awesome Lists containing this project

awesome-quant - Q-Fin - A Python library for mathematical finance. (Python / Financial Instruments and Pricing)
README

        # Q-Fin

A Python library for mathematical finance.

## Installation

https://pypi.org/project/QFin/

```

pip install qfin

```

# Version '0.1.20'

QFin is being reconstructed to leverage more principals of object-oriented programming.  Several modules in this version are deprecated along with the solutions to PDEs/SDEs (mainly in the options module).

QFin now contains a module called 'stochastics' which will be largely responsible for model calibration and option pricing.  A Cython/C++ equivalent to QFin is also being constructed so stay tuned! 

# Option Pricing (>= 0.1.20)

Stochastic differential equations that model underlying asset dynamics extend the 'StochasticModel' class and posses a list of model parameters and functions for pricing vanillas, calibrating to implied volatility surfaces, and Monte Carlo simulations (particularly useful after calibration for pricing path dependent options).

Below is a trivial example using ArithmeticBrownianMotion - first import the StochasticModel...

```Python

from qfin.stochastics import ArithmeticBrownianMotion

```

Next initialize the class object by parameterizing the model...

```Python

# abm parameterized by Bachelier vol = .3

abm = ArithmeticBrownianMotion([.3])

```

The abm may now be used to price a vanilla call/put option (prices default to "CALL") under the given parameter set...

```Python

# F0 = 101

# X = 100

# T = 1

abm.vanilla_pricing(101, 100, 1, "CALL")

# Call Price: 1.0000336233656906

```

Using call-put parity put prices may also be obtained...

```Python

# F0 = 99

# X = 100

# T = 1

abm.vanilla_pricing(99, 100, 1, "PUT")

# Put Price: 1.0000336233656952

```

Calibration and subsequent simulation of the process is also available - do note that some processes have a static volatility and can't be calibrated to an ivol surface.

The arithmetic Brownian motion may be simulated as follows...

```Python

# F0 = 100

# n (steps) = 10000

# dt = 1/252

# T = 1

abm.simulate(100, 10000, 1/252, 1)

```

Results of the simulation along with the simulation characteristics are stored under the tuple 'path_characteristics' : (paths, n, dt, T).  

Using the stored path characteristics we may find the price of a call just as before by averaging each discounted path payoff (assuming a stock process) with zero-rates we can avoid discounting as follows and find the option value as follows...

```Python

# list of path payoffs

payoffs = []

# option strike price

X = 99

# iteration through terminal path values to identify payoff

for path in abm.path_characteristics[0]:

    # appending CALL payoff

    payoffs.append(max((path[-1] - X), 0))

# option value today

np.average(payoffs)

# Call Price:  1.0008974837343871

```

We can see here that the simulated price is converging to the price in close-form.

# Option Pricing (deprecated <= 0.0.20) 

###  Black-Scholes Pricing

Theoretical options pricing for non-dividend paying stocks is available via the BlackScholesCall and BlackScholesPut classes.

```Python

from qfin.options import BlackScholesCall

from qfin.options import BlackScholesPut

# 100 - initial underlying asset price

# .3 - asset underlying volatility

# 100 - option strike price

# 1 - time to maturity (annum)

# .01 - risk free rate of interest

euro_call = BlackScholesCall(100, .3, 100, 1, .01)

euro_put = BlackScholesPut(100, .3, 100, 1, .01)

```

```Python

print('Call price: ', euro_call.price)

print('Put price: ', euro_put.price)

```

```

Call price:  12.361726191532611

Put price:  11.366709566449416

```

### Option Greeks

First-order and some second-order partial derivatives of the Black-Scholes pricing model are available.

#### Delta

First-order partial derivative with respect to the underlying asset price.

```Python

print('Call delta: ', euro_call.delta)

print('Put delta: ', euro_put.delta)

```

```

Call delta:  0.5596176923702425

Put delta:  -0.4403823076297575

```

#### Gamma

Second-order partial derivative with respect to the underlying asset price.

```Python

print('Call gamma: ', euro_call.gamma)

print('Put gamma: ', euro_put.gamma)

```

```

Call gamma:  0.018653923079008084

Put gamma:  0.018653923079008084

```

#### Vega

First-order partial derivative with respect to the underlying asset volatility.

```Python

print('Call vega: ', euro_call.vega)

print('Put vega: ', euro_put.vega)

```

```

Call vega:  39.447933090788894

Put vega:  39.447933090788894

```

#### Theta

First-order partial derivative with respect to the time to maturity.

```Python

print('Call theta: ', euro_call.theta)

print('Put theta: ', euro_put.theta)

```

```

Call theta:  -6.35319039407325

Put theta:  -5.363140560324083

```

# Stochastic Processes

Simulating asset paths is available using common stochastic processes.

###  Geometric Brownian Motion 

Standard model for implementing geometric Brownian motion.

```Python

from qfin.simulations import GeometricBrownianMotion

# 100 - initial underlying asset price

# 0 - underlying asset drift (mu)

# .3 - underlying asset volatility

# 1/52 - time steps (dt)

# 1 - time to maturity (annum)

gbm = GeometricBrownianMotion(100, 0, .3, 1/52, 1)

```

```Python

print(gbm.simulated_path)

```

```

[107.0025048205179, 104.82320056538235, 102.53591127422398, 100.20213816642244, 102.04283245358256, 97.75115579923988, 95.19613943526382, 96.9876745495834, 97.46055174410736, 103.93032659279226, 107.36331603194304, 108.95104494118915, 112.42823319947456, 109.06981862825943, 109.10124426285238, 114.71465058375804, 120.00234814086286, 116.91730159923688, 118.67452601825876, 117.89233466917202, 118.93541257993591, 124.36106523035058, 121.26088015675688, 120.53641952983601, 113.73881043255554, 114.91724168548876, 112.94192281337791, 113.55773877160591, 107.49491796151044, 108.0715118831013, 113.01893111071472, 110.39204535739405, 108.63917240906524, 105.8520395233433, 116.2907247951675, 114.07340779267213, 111.06821275009212, 109.65530380775077, 105.78971667172465, 97.75385009989282, 97.84501925249452, 101.90695475825825, 106.0493833583297, 105.48266575656817, 106.62375752876223, 112.39829297429974, 111.22855058562658, 109.89796974828265, 112.78068777325248, 117.80550869036715, 118.4680557054793, 114.33258212280838]

```

###  Stochastic Variance Process 

Stochastic volatility model based on Heston's paper (1993).

```Python

from qfin.simulations import StochasticVarianceModel

# 100 - initial underlying asset price

# 0 - underlying asset drift (mu)

# .01 - risk free rate of interest

# .05 - continuous dividend

# 2 - rate in which variance reverts to the implied long run variance

# .25 - implied long run variance as time tends to infinity

# -.7 - correlation of motion generated

# .3 - Variance's volatility

# 1/52 - time steps (dt)

# 1 - time to maturity (annum)

svm = StochasticVarianceModel(100, 0, .01, .05, 2, .25, -.7, .3, .09, 1/52, 1)

```

```Python

print(svm.simulated_path)

```

```

[98.21311553503577, 100.4491317019877, 89.78475515902066, 89.0169762497475, 90.70468848525869, 86.00821802256675, 80.74984494892573, 89.05033807013137, 88.51410029337134, 78.69736798230346, 81.90948751054125, 83.02502248913251, 83.46375102829755, 85.39018282900138, 78.97401642238059, 78.93505221741903, 81.33268688455111, 85.12156706038515, 79.6351983987908, 84.2375291273571, 82.80206517176038, 89.63659376223292, 89.22438477640516, 89.13899271995662, 94.60123239511816, 91.200165507022, 96.0578905115345, 87.45399399599378, 97.908745925816, 97.93068975065052, 103.32091104292813, 110.58066464778392, 105.21520242908348, 99.4655106985056, 106.74882010453683, 112.0058519886151, 110.20930861932342, 105.11835510815085, 113.59852610881678, 107.13315204738092, 108.36549026977205, 113.49809943785571, 122.67910031073885, 137.70966794451425, 146.13877267735612, 132.9973784430374, 129.75750117504984, 128.7467891695649, 127.13115959080305, 130.47967713110302, 129.84273088908265, 129.6411527208744]

```

# Simulation Pricing

###  Exotic Options 

Simulation pricing for exotic options is available under the assumptions associated with the respective stochastic processes.  Geometric Brownian motion is the base underlying stochastic process used in each Monte Carlo simulation.  However, should additional parameters be provided, the appropriate stochastic process will be used to generate each sample path.

#### Vanilla Options

```Python

from qfin.simulations import MonteCarloCall

from qfin.simulations import MonteCarloPut

# 100 - strike price

# 1000 - number of simulated price paths

# .01 - risk free rate of interest

# 100 - initial underlying asset price

# 0 - underlying asset drift (mu)

# .3 - underlying asset volatility

# 1/52 - time steps (dt)

# 1 - time to maturity (annum)

call_option = MonteCarloCall(100, 1000, .01, 100, 0, .3, 1/52, 1)

# These additional parameters will generate a Monte Carlo price based on a stochastic volatility process

# 2 - rate in which variance reverts to the implied long run variance

# .25 - implied long run variance as time tends to infinity

# -.5 - correlation of motion generated

# .02 - continuous dividend

# .3 - Variance's volatility

put_option = MonteCarloPut(100, 1000, .01, 100, 0, .3, 1/52, 1, 2, .25, -.5, .02, .3)

```

```Python

print(call_option.price)

print(put_option.price)

```

```

12.73812121792851

23.195814963576286

```

#### Binary Options

```Python

from qfin.simulations import MonteCarloBinaryCall

from qfin.simulations import MonteCarloBinaryPut

# 100 - strike price

# 50 - binary option payout

# 1000 - number of simulated price paths

# .01 - risk free rate of interest

# 100 - initial underlying asset price

# 0 - underlying asset drift (mu)

# .3 - underlying asset volatility 

# 1/52 - time steps (dt)

# 1 - time to maturity (annum)

binary_call = MonteCarloBinaryCall(100, 50, 1000, .01, 100, 0, .3, 1/52, 1)

binary_put = MonteCarloBinaryPut(100, 50, 1000, .01, 100, 0, .3, 1/52, 1)

```

```Python

print(binary_call.price)

print(binary_put.price)

```

```

22.42462873441866

27.869902820039087

```

#### Barrier Options

```Python

from qfin.simulations import MonteCarloBarrierCall

from qfin.simulations import MonteCarloBarrierPut

# 100 - strike price

# 50 - binary option payout

# 1000 - number of simulated price paths

# .01 - risk free rate of interest

# 100 - initial underlying asset price

# 0 - underlying asset drift (mu)

# .3 - underlying asset volatility

# 1/52 - time steps (dt)

# 1 - time to maturity (annum)

# True/False - Barrier is Up or Down

# True/False - Barrier is In or Out

barrier_call = MonteCarloBarrierCall(100, 1000, 150, .01, 100, 0, .3, 1/52, 1, up=True, out=True)

barrier_put = MonteCarloBarrierCall(100, 1000, 95, .01, 100, 0, .3, 1/52, 1, up=False, out=False)

```

```Python

print(binary_call.price)

print(binary_put.price)

```

```

4.895841997908933

5.565856754630819

```

#### Asian Options

```Python

from qfin.simulations import MonteCarloAsianCall

from qfin.simulations import MonteCarloAsianPut

# 100 - strike price

# 1000 - number of simulated price paths

# .01 - risk free rate of interest

# 100 - initial underlying asset price

# 0 - underlying asset drift (mu)

# .3 - underlying asset volatility

# 1/52 - time steps (dt)

# 1 - time to maturity (annum)

asian_call = MonteCarloAsianCall(100, 1000, .01, 100, 0, .3, 1/52, 1)

asian_put = MonteCarloAsianPut(100, 1000, .01, 100, 0, .3, 1/52, 1)

```

```Python

print(asian_call.price)

print(asian_put.price)

```

```

6.688201154529573

7.123274528125894

```

#### Extendible Options

```Python

from qfin.simulations import MonteCarloExtendibleCall

from qfin.simulations import MontecarloExtendiblePut

# 100 - strike price

# 1000 - number of simulated price paths

# .01 - risk free rate of interest

# 100 - initial underlying asset price

# 0 - underlying asset drift (mu)

# .3 - underlying asset volatility

# 1/52 - time steps (dt)

# 1 - time to maturity (annum)

# .5 - extension if out of the money at expiration

extendible_call = MonteCarloExtendibleCall(100, 1000, .01, 100, 0, .3, 1/52, 1, .5)

extendible_put = MonteCarloExtendiblePut(100, 1000, .01, 100, 0, .3, 1/52, 1, .5)

```

```Python

print(extendible_call.price)

print(extendible_put.price)

```

```

13.60274931789973

13.20330578685724

```