Skip to content
This repository has been archived by the owner on Dec 24, 2022. It is now read-only.

Latest commit

 

History

History
74 lines (62 loc) · 3.54 KB

README.md

File metadata and controls

74 lines (62 loc) · 3.54 KB

Elevator algorithms

In this project I am simulating elevator algorithms in Python. Animation is handled by Tkinter, and plotting is done through MatPlotLib.

Dependancies

To run this simulation engine, you need to install tkinter and matplotlib using the pip command in terminal.

Algorithms

There are three supported algorithms:

  • baseline - this is the mechanical control model from old fashion lifts
  • inefficient - this is a less efficient solution than the baseline in most cases (see heatmaps)
  • efficient - this algorithm is equal or more efficient than the baseline algorithm in all cases

The algorithms are called in the code by their string name as listed above

How to use this code base

These are a few examples of code to run in elevator.py:

Individual simulations to run

This line will run and animate a single simulation showing the efficient algorithm on a system with 10 floors where 30 people are generated at the beginning of the simulation

single_simulation(algorithm="efficient", number_of_people=30, number_of_floors=10)

Example output: Screenshot of simulation

Heatmaps to graph

This line will run simulations with the efficient algorithm on every combination of floors and people up to 100x100, and graph the results in a heatmap

heatmap("baseline", 100, 100)

Example output: Example of 100x100 heatmap

This line will run simulations with the baseline and efficient algorithm on all combinations of floors and people up to 100x100, and graph the difference in their average wait times for each combination in the form of a heatmap where green represents the efficient algorithm being more efficient than the baseline.

heatmap_comparison(max_people=47, max_floors=47)

Example output: Image of heatmap

To smooth out the heatmap, you can use this line to interpolate the data. You can also use this function to draw a graph for data saved from previous calculations using heatmap_comparison().

interpolate_heatmap(*heatmap_comparison(max_people=100, max_floors=100))

An interpolated heatmap of 100x100 comparing the baseline to my efficient algorithm

Frequency graphs

This line will draw a histogram plot of the frequency of wait times for an algorithm. This is to see the distribution of wait times, and show the average.

graph_single_algorithm_histogram("efficient", people=30, floors=10, iterations=100_000)

Example histogram

This line will draw an frequency of the wait times after a specified number of iterations of a single algorithm

graph_one_algorithm_frequency_curve("baseline", 30, 10, 10_000)

A frequency curve showing the distribution of average wait times for the baseline algorithm

This line will draw two frequency of the wait times comparing the baseline to my efficient algorithm, as well as their averages.

graph_both_algorithms_frequency_curve(30, 10, 100_000)

Example output: A frequency curve comparing the baseline to my efficient algorithm

This line will draw two box plots to show a comparison between the baseline and my efficient algorithm. This is useful to see the difference in variance and the means.

boxplot_comparison(30, 10, 1_000)

Example output: A box plot comparing the average wait times of the baseline agorithm with my efficient algorithm