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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.

My Approach:

Find distance between every pair of points and then for each point in the set find the closest point to it in the same set. Let this distance be dist[i] for ith point and compare dist[i] with the max((inner_radius-dist),(outer_radius-dist)) and which ever is less is the radius of the car.

I coded this logic and I am getting wrong answer. I am not sure if my algorithm is correct. Can someone please verify or suggest a better algorithm.

[EDIT] The following is the code in c++ c

#include <stdio.h>
#include <math.h>

#define TEST_SIZE 500

/* This code is plain C so no need for this line:
using namespace std; */

int main(void) {
    int testCases, n;
    float x[TEST_SIZE], y[TEST_SIZE];//x[i], y[i] constitute pair (x,y) for ith point
    float distance, dist, min, r, R,radius;
    scanf("%d", &testCases);
    while ( testCases-- ) {
        scanf("%f%f%d", &r,&R, &n);
        //printf("r: %f, R: %f, n: %d\n", r, R, n);
        for (int i=0; i<n ; i++) {
            scanf("%f%f", &x[i], &y[i]);
        for(int i=0; i<n; ++i) {
            for(int j=0; j<n; ++j) {
                if (j!=i) {
                    dist = ((x[i]-x[j])*(x[i]-x[j])) + ((y[i]-y[j])*(y[i]-y[j]));// rhs of this equation is square of distance between 2 points
                    if(j==0 || dist>min) {
                //  printf("dist: %f\n", dist);
            radius=sqrt((x[i]*x[i]) + (y[i]*y[i]));
            if(radius-r > R-radius) {
                if(min>radius-r) {
            } else {
                if(min>R-radius) {
            if(i==0 || distance>min) { 
                distance = min;
                    distance = floorf(distance*1000 + .5)/1000;
        //printf("distance: %f\n", distance);
        printf ("%f\n", distance);
    return 0;
share|improve this question
This might get closed as it's more a maths/geometry question than software development:( – Martin James Sep 21 '12 at 11:53
Well not much of geometry is involved except Pythagoras theorem, I think it is more of algorithms question – Aman Deep Gautam Sep 21 '12 at 11:55
Also, 'dist = ((x[i]-x[j])*(x[i]-x[j])) + ((y[i]-y[j])*(y[i]-y[j]))'. Single-letter var names and over-complex one-line expressions don't help anyone much. What is 'wrong answer'? What is 'right answer? Have you thought about a debugging strategy? Have you considered splitting up those complex arithmetic expressions by adding in some usefully-named temporary vars? – Martin James Sep 21 '12 at 11:58
didn't get that far:( – Martin James Sep 21 '12 at 11:59
@AmanDeepGautam oh please, don't try to out-smart the compiler... Again, what do you do with min after you have found it? nothing! Your "optimization" has led to a blatant bug: dist should be local to the inner loop, min should be the only result from the loop. Now you're just taking the last value of dist. – mvds Sep 21 '12 at 12:38
up vote 1 down vote accepted

Your algorithm is not correct. Consider a test case with just two cones that are extremely close to each other (their distance is nearly 0). Your algorithm will wrongly compute the diameter to be the distance between these points. However the real diameter could close to the width of the circular track. You have to consider the global structure of the points to solve this problem.

EDIT: Any track taken by the car partitions the points and the circles into two sets: those appearing on the left and those appearing on the right. Note that the inner circle is always on the left side and the outer is always on the right. Let the distance between two sets is the minimum distance between any two points belonging to them. Then you have to find a partition of these points (in which the left and right circle belong to different parts) that maximizes the distance between it's two parts. Such a partition can be obtained by computing a minimum spanning tree of the points and the circles and finding the maximum edge that separates the left circle from the right circle in the tree.

share|improve this answer
thanks!. btw can you suggest something – Aman Deep Gautam Sep 21 '12 at 12:36
I have edited my comment. Hope this helps. – krjampani Sep 21 '12 at 12:52

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