The Gilbert-Elliot burst error model is a popular and effective tool for treating bursty (non-independent) errors in communication links.
This software accompanies the following publication: Pieper J; Voran S, Relationships between Gilbert-Elliot Burst Error Model Parameters and Error Statistics, NTIA Technical Memo TM-23-565.
It provides functions for simulating errors using the model and analyzing error arrays to estimate model parameters.
It can also make an estimate of the most likely version of the model to emit a given observation: the two-parameter
Upon installation the package provides a command line interface which allows users to determine valid model control values and simulate errors.
Navigate to the directory containing the source code and run:
pip install .
The software includes doc strings for all methods, viewable via help(method).
For example to see the help for the simulate method:
import gilbert_elliot_model as ge
print(help(ge.simulate))
Here we list the primary methods included in the package with a brief description of each:
simulate- Simulate errors using the Gilbert-Elliot burst model and a variety of controls as parameters.determine_model- Determine version of Gilbert-Elliot model with highest likelihood of emitting observation.model_error_statistics- Determine error statistics given model parameters.data_error_statistics- Measure error statsitics from error pattern.fit_hmm- Fit two-state Hidden Markov model to data in observation.valid_regions- Determine valid ranges for Gilbert-Elliot model controls and error statistics.valid_parameters- Return valid parameters either as a list of pairs or a set of all parameters.
It is worth noting that more than one set of model parameters could yield the same or very similar error patterns.
Thus, unless there is a good reason for selecting a more complicated model (such as the three- or four-parameter) models, we suggest using the two-parameter model.
More complicated models are valid and interesting provided there is good reasoning behind their use.
We provide the determine_model method as an additional tool in this process, but do not claim that it should be the primary decision maker as to which model is most appropriate in a given situation.
The functions fit_hmm and determine_model are stochastic in nature and also fairly slow, making them unsuitable for standard unit testing.
To understand the functionality of each method and ensure they are working as intended, a number of random tests were performed and their results analyzed.
These analyses are viewable at
fit hmm distribution analysis
and
determine model analysis
respectively.
Upon installation, a command line tool called gilbert-elliot is installed and added to the path.
It allows users to determine valid model control values and simulate error patterns.
To see all options for the command line tool run
gilbert-elliot --help
Here we fix the proportion of time spent in the Bad state,
gilbert-elliot --pi_B 0.7 --L1 3 --free-parameter xbar
This outputs: xbar must be in Interval.Lopen(0.466666666666667, 0.700000000000000).
Here we fix the error rate,
gilbert-elliot --xbar 0.6 --pi_B 0.7 --L1 3 --free-parameter h
This outputs: h must be in Union(Interval.Ropen(0.142857142857143, 0.269069265858405), Interval.open(0.530930734141595, 0.571428571428572)).
Building on the last example we select a value of
gilbert-elliot --xbar 0.6 --pi_B 0.7 --L1 3 --h 0.55
This outputs: Model Parameters: {'p': 0.166666666666667, 'r': 0.0714285714285714, 'h': 0.550000000000000, 'k': 0.0500000000000000}.
This further builds on the previous example by using the model controls to generate a length 10000 error pattern and save it to myerrors.csv.
gilbert-elliot --xbar 0.6 --pi_B 0.7 --L1 3 --h 0.55 --simulate --n_observations 10000 --output myerrors.csv
For questions contact Jaden Pieper, jpieper@ntia.gov