I am doing this question at codechef and think I have developed my algorithm but I also got a tutorial in which they have mentioned how to solve it.
Since the car is infinitely maneuverable so the shortest distance between any two points should be the maximal possible diameter. Also note that while calculating this shortest distance we need to take care of the inner and outer radius of the track.
Editorial: Their Solution
In the editorial they have nicely converted the problem to graph theory but I am unable to understand haw they make the last inference while making the following statement: "Therefore the length of the removed edge is the maximal diameter"
Basically I do not understand this logic completely and it is also possible that my algorithm is also wrong.
A number of traffic cones have been placed on a circular racetrack to form an obstacle course. You are asked to determine the largest sized car that can navigate the course. For simplicity, the cones are assumed to have zero width and the car is perfectly circular and infinitely maneuverable. The track itself is the area between 2 concentric circles. Formally, the course can be navigated by a car of radius c if there exists a closed loop around the center of the track which lies between the circles forming the track, and every point on the loop is at least c distance away from each cone and each boundary of the track.
Consider the cones and circles as vertices of a graph, where the edge between any 2 vertices has length equal to the distance between the corresponding elements of the obstacle course. Note that the longest edge in the graph is the one that connects the edges corresponding to the 2 circles. Our goal is to partition the vertices of the graph into 2 sets representing the "inside" and "outside" of the car's path, so that the distance between any two vertices from different sets is at least the diameter of the car. We do this by constructing the minimum spanning tree (MST) of the graph, then removing the longest edge on the path from the outer edge of the track to the inner edge. Because the spanning tree is minimal, no two verticies from different sets can have an edge longer than the removed edge. Because there exists a path from the outer circle to the inner circle consisting only of edges not exceeding the length of the removed edge, there cannot be a partition which is separated by a longer distance. Therefore the length of the removed edge is the maximal diameter. The MST can be easily computed in O(N2) time using Prim's algorithm, though a O(N2log N) algorithm such as Kruskal's will suffice. Both Prim's and Kruskal's can be modified to compute the length of the edge in question without actually computing the MST itself. Because the graph is mostly Euclidean, a more complicated O(N log N) solution also exists.