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High-Performance Kalman Filtering and Smoothing

Project description

kalmantv: High-Performance Kalman Filtering and Smoothing in Python

Mohan Wu, Martin Lysy


Description

kalmantv provides a simple Python interface to the time-varying Kalman filtering and smoothing algorithms. Various low-level backends are provided in the following modules:

  • kalmantv.cython: This module performs the underlying linear algebra using the BLAS/LAPACK routines provided by NumPy through a Cython interface. To maximize speed, no input checks are provided. All inputs must be float64 NumPy arrays in Fortran order.

  • kalmantv.eigen: This module uses the C++ Eigen library for linear algebra. The interface is also through Cython. Here again we have the same input requirements and lack of checks. Eigen is known to be faster than most BLAS/LAPACK implementations, but it needs to be compiled properly to achieve maximum performance. In particular this involves linking against an installed version of Eigen (not provided) and setting the right compiler flags for SIMD and OpenMP support. Some defaults are provided in setup.py, but tweaks may be required depending on the user's system.

  • kalmantv.numba: This module once again uses BLAS/LAPACK but the interface is through Numba. Here input checks are performed and the inputs can be in either C or Fortran order, and single or double precision (float32 and float64). However, C ordered arrays are first converted to Fortran order, so the latter is preferable for performance considerations.

Installation

git clone https://github.com/mlysy/kalmantv
cd kalmantv
pip install .

Unit Testing

The unit tests are done against the pykalman library to ensure the same results. From inside the root folder of the kalmantv source code:

pip install .[tests]
cd tests
python -m unittest discover -v

Documentation

The HTML documentation can be compiled from the kalmantv root folder:

pip install .[docs]
cd docs
make html

This will create the documentation in docs/build.

Usage

The usage of the library can be demonstrated through this simple example. Here we use the KalmanTV class from the kalmantv.cython module. The same class is defined in kalmantv.eigen and kalmantv.numba with exactly the same methods and signatures.

Suppose we start with given mean and variance of the priror, mu_state_past and var_state_past, our goal is to compute mu_state_filt and var_state_filt at the next time step. We define mu_state_pred and var_state_pred for the prediction step in the Kalman filtering algorithm. More details can be found in the documentation.

import numpy as np
from kalmantv.cython import KalmanTV
n_meas = 2 # Set the size of the measurement
n_state = 4 # Set the size of the state

# Set initial mu and var of the prior
mu_state_past = np.random.rand(n_state) 
var_state_past = np.random.rand(n_state, n_state)
var_state_past = var_state_past.dot(var_state_past.T) #Ensure positive semidefinite
var_state_past = np.asfortranarray(var_state_past) # must use Fortran order

# Parameters to the Kalman Filter
mu_state = np.random.rand(n_state)
wgt_state = np.random.rand(n_state, n_state).T # converts to Fortran order
var_state = np.random.rand(n_state, n_state)
var_state = var_state.dot(var_state.T).T
x_meas = np.random.rand(n_meas)
mu_meas = np.random.rand(n_meas)
wgt_meas = np.random.rand(n_state, n_meas).T
var_meas = np.random.rand(n_meas, n_meas)
var_meas = var_meas.dot(var_meas.T).T

# Initialize the KalmanTV class
ktv = KalmanTV(n_meas, n_state)

# Allocate memory for storing the output
mu_state_pred = np.empty(n_state)
var_state_pred = np.empty((n_state, n_state), order='F')
mu_state_filt = np.empty(n_state)
var_state_filt = np.empty((n_state, n_state), order='F')

# Run the filtering algorithm
ktv.filter(mu_state_pred, var_state_pred,
           mu_state_filt, var_state_filt,
           mu_state_past, var_state_past,
           mu_state, wgt_state, var_state,
           x_meas, mu_meas, wgt_meas, var_meas)

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