Metadata-Version: 2.4
Name: lppls
Version: 0.6.23
Summary: A Python module for fitting the LPPLS model to data.
Home-page: https://github.com/Boulder-Investment-Technologies/lppls
Author: Josh Nielsen
Author-email: josh@boulderinvestment.tech
Requires-Python: >=3.10
Description-Content-Type: text/markdown
Requires-Dist: cma>=3.3.0
Requires-Dist: matplotlib>=3.5.0
Requires-Dist: numba>=0.56.0
Requires-Dist: numpy>=1.23.0
Requires-Dist: pandas>=1.5.0
Requires-Dist: scipy>=1.9.0
Requires-Dist: tqdm>=4.64.0
Requires-Dist: xarray>=2024.1.0
Requires-Dist: scikit-learn>=1.2.0
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# Log Periodic Power Law Singularity (LPPLS) Model 
`lppls` is a Python module for fitting the LPPLS model to data.


## Overview
The LPPLS model provides a flexible framework to detect bubbles and predict regime changes of a financial asset. A bubble is defined as a faster-than-exponential increase in asset price, that reflects positive feedback loop of higher return anticipations competing with negative feedback spirals of crash expectations. It models a bubble price as a power law with a finite-time singularity decorated by oscillations with a frequency increasing with time. 

Try the demo: 

[![Open In Colab](https://colab.research.google.com/assets/colab-badge.svg)](https://colab.research.google.com/drive/1Qvbdj4DGNcC9Oop9mA6Vzdvsoec6k2I0?usp=sharing)

Here is the model:

```math
E[ln\ p(t)] = A + B(t_c-t)^{m}+C(t_c-t)^{m}\cos(\omega\ ln(t_c-t) - \phi)
```

  where:

  - $E[ln\ p(t)]$: expected log price at the date of the termination of the bubble
  - $t_c$: critical time (date of termination of the bubble and transition in a new regime) 
  - $A$: expected log price at the peak when the end of the bubble is reached at $t_c$
  - $B$: amplitude of the power law acceleration
  - $C$: amplitude of the log-periodic oscillations
  - $m$: degree of the super exponential growth
  - $\omega$: scaling ratio of the temporal hierarchy of oscillations
  - $\phi$: time scale of the oscillations
    
The model has three components representing a bubble. The first, $A+B(t_c-t)^{m}$, handles the hyperbolic power law. For $m$ < 1 when the price growth becomes unsustainable, and at $t_c$ the growth rate becomes infinite. The second term, $C(t_c-t)^{m}$, controls the amplitude of the oscillations. It drops to zero at the critical time $t_c$. The third term, $\cos(\omega\ ln(t_c-t) - \phi)$, models the frequency of the oscillations. They become infinite at $t_c$.

## Important links
 - Official source code repo: https://github.com/Boulder-Investment-Technologies/lppls
 - Download releases: https://pypi.org/project/lppls/
 - Issue tracker: https://github.com/Boulder-Investment-Technologies/lppls/issues

## Installation
Dependencies

`lppls` requires:
 - Python (>= 3.10)
 - CMA-ES (>= 3.3.0)
 - Matplotlib (>= 3.5.0)
 - Numba (>= 0.56.0)
 - NumPy (>= 1.23.0)
 - Pandas (>= 1.5.0)
 - SciPy (>= 1.9.0)
 - Scikit-learn (>= 1.2.0)
 - tqdm (>= 4.64.0)
 - Xarray (>= 2024.1.0)

User installation
```
pip install -U lppls
```

## Example Use
```python
from lppls import lppls, data_loader
import numpy as np
import pandas as pd
from datetime import datetime as dt
%matplotlib inline

# read example dataset into df 
data = data_loader.nasdaq_dotcom()

# convert time to ordinal
time = [pd.Timestamp.toordinal(dt.strptime(t1, '%Y-%m-%d')) for t1 in data['Date']]

# create list of observation data
price = np.log(data['Adj Close'].values)

# create observations array (expected format for LPPLS observations)
observations = np.array([time, price])

# set the max number for searches to perform before giving-up
# the literature suggests 25
MAX_SEARCHES = 25

# instantiate a new LPPLS model with the Nasdaq Dot-com bubble dataset
lppls_model = lppls.LPPLS(observations=observations)

# fit the model to the data and get back the params
tc, m, w, a, b, c, c1, c2, O, D = lppls_model.fit(MAX_SEARCHES)

# visualize the fit
lppls_model.plot_fit()

# should give a plot like the following...
```

![LPPLS Fit to the Nasdaq Dataset](https://raw.githubusercontent.com/Boulder-Investment-Technologies/lppls/master/img/dotcom_lppls_fit.png)

```python
# compute the confidence indicator
res = lppls_model.mp_compute_nested_fits(
    workers=8,
    window_size=120, 
    smallest_window_size=30, 
    outer_increment=1, 
    inner_increment=5, 
    max_searches=25,
    # filter_conditions_config={} # not implemented in 0.6.x
)

lppls_model.plot_confidence_indicators(res)
# should give a plot like the following...
```
![LPPLS Confidnce Indicator](https://raw.githubusercontent.com/Boulder-Investment-Technologies/lppls/master/img/dotcom_confidence_indicator.png)

If you wish to store `res` as a pd.DataFrame, use `compute_indicators`.
<details>
  <summary>Example</summary>

  ```python
  res_df = lppls_model.compute_indicators(res)
  res_df
  # gives the following...
  ```
  <img src="https://raw.githubusercontent.com/Boulder-Investment-Technologies/lppls/master/img/compute_indicator_df.png"  width="500"/>
  
</details>

## Quantile Regression
Based on the work in Zhang, Zhang & Sornette 2016, quantile regression for LPPLS uses the L1 norm (sum of absolute differences) instead of the L2 norm
and applies the q-dependent loss function during calibration. Please refer to the example usage [here](https://github.com/Boulder-Investment-Technologies/lppls/blob/master/notebooks/quantile_regression.ipynb). 

## Lagrange Regularization for Bubble Start Time Detection
The `lppls` library includes a method for determining the start time of a financial bubble using Lagrange regularization. This technique, inspired by the work of Demos & Sornette (2017), addresses the challenge of model overfitting when the bubble's inception is unknown.

By introducing a regularization term to the normalized sum of squared residuals, the method objectively identifies the optimal fitting window size. This allows for a more robust and data-driven estimation of the bubble's start time without requiring exogenous information, which is a significant improvement over previous approaches.

![Lagrange Regularization Plot](https://raw.githubusercontent.com/Boulder-Investment-Technologies/lppls/master/img/lagrange_regularization_plot.png)

This functionality is available through the `detect_bubble_start_time_via_lagrange` method. For detailed usage, please refer to the tutorial [here](https://github.com/Boulder-Investment-Technologies/lppls/blob/master/notebooks/lagrange_regularization.ipynb).

## Other Search Algorithms
Shu and Zhu (2019) proposed [CMA-ES](https://en.wikipedia.org/wiki/CMA-ES) for identifying the best estimation of the three non-linear parameters ($t_c$, $m$, $\omega$).
> The CMA-ES rates among the most successful evolutionary
algorithms for real-valued single-objective optimization and is typically applied to difficult
nonlinear non-convex black-box optimization problems in continuous domain and search space
dimensions between three and a hundred. Parallel computing is adopted to expedite the fitting
process drastically.

This approach has been implemented in a subclass and can be used as follows...
Thanks to @paulogonc for the code.
```python
from lppls import lppls_cmaes
lppls_model = lppls_cmaes.LPPLSCMAES(observations=observations)
tc, m, w, a, b, c, c1, c2, O, D = lppls_model.fit(max_iteration=2500, pop_size=4)
```
Performance Note: this works well for single fits but can take a long time for computing the confidence indicators. More work needs to be done to speed it up. 
## References
 - Filimonov, V. and Sornette, D. A Stable and Robust Calibration Scheme of the Log-Periodic Power Law Model. Physica A: Statistical Mechanics and its Applications. 2013
 - Shu, M. and Zhu, W. Real-time Prediction of Bitcoin Bubble Crashes. 2019.
 - Sornette, D. Why Stock Markets Crash: Critical Events in Complex Financial Systems. Princeton University Press. 2002.
 - Sornette, D. and Demos, G. and Zhang, Q. and Cauwels, P. and Filimonov, V. and Zhang, Q., Real-Time Prediction and Post-Mortem Analysis of the Shanghai 2015 Stock Market Bubble and Crash (August 6, 2015). Swiss Finance Institute Research Paper No. 15-31.
 - Demos, G. and Sornette, D. Lagrange regularisation approach to compare nested data sets and determine objectively financial bubbles' inceptions. 2017. arXiv:1707.07162
 - Zhang, Q., Zhang, Q., and Sornette, D. Early Warning Signals of Financial Crises with Multi-Scale Quantile Regressions of Log-Periodic Power Law Singularities. PLOS ONE. 2016. DOI:10.1371/journal.pone.0165819
