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https://github.com/nup002/pymjc

A python implementation of the Minimum Jump Cost dissimilarity measure.
https://github.com/nup002/pymjc

datascience dissimilarity dissimilarity-measures python python-3 python3 time-series timeseries

Last synced: 3 months ago
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A python implementation of the Minimum Jump Cost dissimilarity measure.

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# Minimum Jump Cost dissimilarity measure in Python



This python library implements the Minimum Jump Cost (MJC) dissimilarity measure devised by Joan Serra and Josep Lluis 

Arcos in 2012. The MJC dissimilarity measure was shown to outperform the Dynamic Time Warp (DTW) dissimilarity measure 

on several datasets. You can read their paper here: 

https://www.iiia.csic.es/sites/default/files/4584.pdf.



This library can compute the MJC for timeseries with different sampling rates, arbitrarily spaced data points, and 

non-overlapping regions.



## How to install

`pymjc` is available from PyPi. Run the following in a command line terminal:


``` pip install pymjc```



## How to use

Example: 

```

from pymjc import mjc

import numpy as np



series_1 = np.array([1,2,3,2,1])

series_2 = np.array([0,1,2,1,0])



d_xy, abandoned = mjc(series_1, series_2, show_plot=True)



print(f"The MJC dissimilarity of series 1 and series 2 is {d_xy}")

```

There are some options for reducing the computational load of this algorithm. They are detailed in the next section.



## More detailed information

The time series s1 and s2 are specified as follows:

- They may be python Lists or numpy.ndarrays

- They may be of different length.

- They may or may not have time information.

- If one of the time series has time information, the other must also have it.

- Their datatype may be floats or integers.



A time series with no time information is just a list of values. The first element of the list corresponds to

the earliest point in the time series.


Example: `s1 = [d₀, d₁, d₂, ...]`, where `dᵢ` is the i-th value of the time series.



A time series with time information must be a 2D array of shape (2, n). The data at index 0 are time

data, and the data at index 1 is amplitude data.


Example: `s1 = [[t₀, t₁, t₂, ...], [d₀, d₁, d₂, ...]]`, where `tᵢ` is the time of the i-th measurement. The time 

values may be integers or floats, and need not begin at 0.



To visualize the algorithm, you may pass the variable `show_plot=True`. This will generate a plot with the two time

series, and arrows signifying the jumps that the algorithm made when calculating the Minimum Jump Cost.



To stop the algorithm early, pass a value for `dxy_limit`. If the dissimilarity measure exceeds this value during 

computation, it is abandoned.



### Performance

The time series are cast to numpy arrays. The checking and casting lowers execution speed. Therefore, an option to

disable this checking and casting has been implemented. If you are certain that the time series `s1` and `s2`

are `numpy.ndarray`s of the format `[[time data],[amplitude data]]`, you may pass the variable `override_checks=True`.



The algorithm locates the overlapping region between the two timeseries. This step is skipped if the first and last

timestamps are equal between the two timeseries. If your data has no time data, it is skipped if there is the same

number of samples in each timeseries.



As part of the calculation of the MJC, the algorithm calculates the standard deviations of the amplitude data, and

the average sampling periods of `s1` and `s2`. This lowers execution speed, but is required.

However, if you know the standard deviations and/or the average time difference between data points of either

(or both) `s1` and `s2` a-priori, you may pass these as variables. They are named `std_s1`, `std_s2`, `tavg_s1`, and

`tavg_s2`. Any number of these may be passed. The ones which are not passed will be calculated.



mjc() input parameters:

```

s1              : numpy ndarray | List. Time series 1.

s2              : numpy ndarray | List. Time series 2.

dxy_limit       : Optional float. Early abandoning variable.

beta            : Optional float. Time jump cost. 

show_plot       : Optional bool. If True, displays a plot that visualize the algorithms jump path. Default False.

std_s1          : Optional float. Standard deviation of time series s1.

std_s2          : Optional float. Standard deviation of time series s2.

tavg_s1         : Optional float. Average sampling period of time series 1.

tavg_s2         : Optional float. Average sampling period of time series 2. 

return_args     : Optional bool. If True, returns the values for std_s1, std_s2, tavg_s1, tavg_s2, s1, and s2.

override_checks : Optional bool. Override checking and casting

```