Weighted Activity selection problem

From Algorithm Wiki
Revision as of 11:02, 10 October 2022 by Admin (talk | contribs) (Created page with "== Problem Description== Let's consider that you have n activities with their start and finish times, the objective is to find solution set having maximum number of non-conflicting activities that can be executed in a single time frame, assuming that only one person or machine is available for execution. It might not be possible to complete all the activities, since their timings can collapse. Two activities, say i and j, are said to be non-conflicting if si >= fj or sj...")
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Jump to navigation Jump to search

Problem Description

Let's consider that you have n activities with their start and finish times, the objective is to find solution set having maximum number of non-conflicting activities that can be executed in a single time frame, assuming that only one person or machine is available for execution.

It might not be possible to complete all the activities, since their timings can collapse. Two activities, say i and j, are said to be non-conflicting if si >= fj or sj >= fi where si and sj denote the starting time of activities i and j respectively, and fi and fj refer to the finishing time of the activities i and j respectively. Greedy approach can be used to find the solution since we want to maximize the count of activities that can be executed. This approach will greedily choose an activity with earliest finish time at every step, thus yielding an optimal solution.

Bounds Chart

File:Weighted Activity selection problemBoundsChart.png

Step Chart

File:Weighted Activity selection problemStepChart.png

Improvement Table

Complexity Classes Algorithm Paper Links Lower Bounds Paper Links
Exp/Factorial [ Brute force algorithm (1940)]
Polynomial > 3
Cubic [ Dynamic Programming (1953)]
Quadratic [ Dynamic Programming (1953)]
nlogn [ Dynamic Programming (1953)]
Linear
logn