Generally, all algorithms which are looking for a specific item in a collection of items are called search algorithms. When the collection of items is defined by a mathematical function (opposed to existing in a database), it is called a **search space**.

One of the most famous problems of this kind is the travelling salesman problem, where an algorithm is sought which will, given a list of cities and their distances, find the shortest route for visiting each city only once. For this problem, the exact solution can be found only by examining **all** possible routes (the **entire search space**), and finding the shortest one (the route which has the **minimum** distance, which is the **extreme** value in the search space). The best time complexity of such an algorithm (called an *exhaustive search*) is exponential (although it is still possible that there may be a better solution), meaning that the worst-case running time increases exponentially as the number of cities increases.

This is where genetic algorithms come into play. Similar to other heuristic algorithms, genetic algorithms try to get close to the optimal solution by improving a candidate solution iteratively, with no guarantee that an optimal solution will actually be found.

This iterative approach has the problem that the algorithm can easily get "stuck" in a local extreme (while trying to improve a solution), not knowing that there is a potentially better solution somewhere further away:

The figure shows that, in order to get to the actual, optimal solution (the **global** minimum), an algorithm currently examining the solution around the **local** minimum needs to "jump over" a large maximum in the search space. A genetic algorithm will rapidly locate such local optimums, but it will usually fail to "sacrifice" this short-term gain to get a potentially better solution.

So, a summary would be: