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I have recently completed the following interview exercise:

'A robot can be programmed to run "a", "b", "c"... "n" kilometers and it takes ta, tb, tc... tn minutes, respectively. Once it runs to programmed kilometers, it must be turned off for "m" minutes.

After "m" minutes it can again be programmed to run for a further "a", "b", "c"... "n" kilometers.

How would you program this robot to go an exact number of kilometers in the minimum amount of time?'

I thought it was a variation of the unbounded knapsack problem, in which the size would be the number of kilometers and the value, the time needed to complete each stretch. The main difference is that we need to minimise, rather than maximise, the value. So I used the equivalent of the following solution: http://en.wikipedia.org/wiki/Knapsack_problem#Unbounded_knapsack_problem in which I select the minimum.

Finally, because we need an exact solution (if there is one), over the map constructed by the algorithm for all the different distances, I iterated through each and trough each robot's programmed distance to find the exact distance and minimum time among those.

I think the pause the robot takes between runs is a bit of a red herring and you just need to include it in your calculations, but it does not affect the approach taken.

I am probably wrong, because I failed the test. I don't have any other feedback as to the expected solution.

Edit: maybe I wasn't wrong after all and I failed for different reasons. I just wanted to validate my approach to this problem.

import static com.google.common.collect.Sets.*;
import java.util.HashMap;
import java.util.List;
import java.util.Map;
import java.util.Set;
import org.apache.log4j.Logger;
import com.google.common.base.Objects;
import com.google.common.base.Preconditions;
import com.google.common.collect.Lists;
import com.google.common.collect.Maps;

public final class Robot {

    static final Logger logger = Logger.getLogger (Robot.class);

    private Set<ProgrammedRun> programmedRuns;
    private int pause;
    private int totalDistance;

    private Robot () {
        //don't expose default constructor & prevent subclassing 

    private Robot (int[] programmedDistances, int[] timesPerDistance, int pause, int totalDistance) {

        this.programmedRuns = newHashSet ();
        for (int i = 0; i < programmedDistances.length; i++) {
            this.programmedRuns.add (new ProgrammedRun (programmedDistances [i], timesPerDistance [i] ) );
        this.pause = pause;
        this.totalDistance = totalDistance;

    public static Robot create (int[] programmedDistances, int[] timesPerDistance, int pause, int totalDistance) {
        Preconditions.checkArgument (programmedDistances.length == timesPerDistance.length);
        Preconditions.checkArgument (pause >= 0);
        Preconditions.checkArgument (totalDistance >= 0);
        return new Robot (programmedDistances, timesPerDistance, pause, totalDistance);

     * @returns null if no strategy was found. An empty map if distance is zero. A
     * map with the programmed runs as keys and number of time they need to be run
     * as value.  
    Map<ProgrammedRun, Integer> calculateOptimalStrategy () {

        //for efficiency, consider this case first
        if (this.totalDistance == 0) {
            return Maps.newHashMap ();

        //list of solutions for different distances. Element "i" of the list is the best set of runs that cover at least "i" kilometers
        List <Map<ProgrammedRun, Integer>> runsForDistances = Lists.newArrayList();

        //special case i = 0 -> empty map (no runs needed)
        runsForDistances.add (new HashMap<ProgrammedRun, Integer> () );

        for (int i = 1; i <= totalDistance; i++) {
            Map<ProgrammedRun, Integer> map = new HashMap<ProgrammedRun, Integer> ();
            int minimumTime = -1;
            for (ProgrammedRun pr : programmedRuns) {
                int distance = Math.max (0, i - pr.getDistance ());
                int time = getTotalTime (runsForDistances.get (distance) ) + pause + pr.getTime();
                if (minimumTime < 0 || time < minimumTime) {
                    minimumTime = time;
                    //new minimum found
                    map = new HashMap<ProgrammedRun, Integer> ();
                    map.putAll(runsForDistances.get (distance) );

                    //increase count
                    Integer num = map.get (pr);
                    if (num == null) num = Integer.valueOf (1);
                    else num++;

                    //update map
                    map.put (pr, num);
            runsForDistances.add (map );

        //last step: calculate the combination with exact distance

        int minimumTime2 = -1;
        int bestIndex = -1;
        for (int i = 0; i <= totalDistance; i++) {
            if (getTotalDistance (runsForDistances.get (i) ) == this.totalDistance ) {
                int time = getTotalTime (runsForDistances.get (i) );
                if (time > 0) time -= pause;
                if (minimumTime2 < 0 || time < minimumTime2 ) {
                    minimumTime2 = time;
                    bestIndex = i;

        //if solution found

        if (bestIndex != -1) {
            return runsForDistances.get (bestIndex);

        //try all combinations, since none of the existing maps run for the exact distance
        List <Map<ProgrammedRun, Integer>> exactRuns = Lists.newArrayList();

        for (int i = 0; i <= totalDistance; i++) {
            int distance = getTotalDistance (runsForDistances.get (i) );
            for (ProgrammedRun pr : programmedRuns) {
                //solution found
                if (distance + pr.getDistance() == this.totalDistance ) {
                    Map<ProgrammedRun, Integer> map = new HashMap<ProgrammedRun, Integer> ();
                    map.putAll (runsForDistances.get (i));

                    //increase count
                    Integer num = map.get (pr);
                    if (num == null) num = Integer.valueOf (1);
                    else num++;

                    //update map
                    map.put (pr, num);

                    exactRuns.add (map);

        if (exactRuns.isEmpty()) return null;

        //finally return the map with the best time
        minimumTime2 = -1;
        Map<ProgrammedRun, Integer> bestMap = null;

        for (Map<ProgrammedRun, Integer> m : exactRuns) {
            int time = getTotalTime (m);
            if (time > 0) time -= pause; //remove last pause
            if (minimumTime2 < 0 || time < minimumTime2 ) {
                minimumTime2 = time;
                bestMap = m;

        return bestMap;

    private int getTotalTime (Map<ProgrammedRun, Integer> runs) {
        int time = 0;
        for (Map.Entry<ProgrammedRun, Integer> runEntry : runs.entrySet()) {
            time += runEntry.getValue () * runEntry.getKey().getTime ();
            //add pauses
            time += this.pause * runEntry.getValue ();
        return time;

    private int getTotalDistance (Map<ProgrammedRun, Integer> runs) {
        int distance = 0;
        for (Map.Entry<ProgrammedRun, Integer> runEntry : runs.entrySet()) {
            distance += runEntry.getValue() * runEntry.getKey().getDistance ();
        return distance;

    class ProgrammedRun {
        private int distance;
        private int time;
        private transient float speed;

        ProgrammedRun (int distance, int time) {
            this.distance = distance;
            this.time = time;
            this.speed = (float) distance / time;

        @Override public String toString () {
            return "(distance =" + distance + "; time=" + time + ")";

        @Override public boolean equals (Object other) {
            return other instanceof ProgrammedRun 
                && this.distance == ((ProgrammedRun)other).distance 
                && this.time == ((ProgrammedRun)other).time;

        @Override public int hashCode () {
            return Objects.hashCode (Integer.valueOf (this.distance), Integer.valueOf (this.time));

        int getDistance() {
            return distance;

        int getTime() {
            return time;

        float getSpeed() {
            return speed;


public class Main {

    /* Input variables for the robot */

    private static int [] programmedDistances = {1, 2, 3, 5, 10}; //in kilometers
    private static int [] timesPerDistance = {10, 5, 3, 2, 1}; //in minutes

    private static int pause = 2; //in minutes

    private static int totalDistance = 41; //in kilometers

     * @param args
    public static void main(String[] args) {

        Robot r = Robot.create (programmedDistances, timesPerDistance, pause, totalDistance);

        Map<ProgrammedRun, Integer> strategy = r.calculateOptimalStrategy ();

        if (strategy == null) {
            System.out.println ("No strategy that matches the conditions was found");
        } else if (strategy.isEmpty ()) {
            System.out.println ("No need to run; distance is zero");
        } else {
            System.out.println ("Strategy found:");
            System.out.println (strategy);

share|improve this question
Your solution seems OK if robot can run only in one direction. If it can run backwards, just add "negative distances" to the knapsack problem. If it can run anywhere in 2D space, simple greedy algorithm will be the best. –  Evgeny Kluev Mar 12 '12 at 12:39
I have simplified the description but it can only go forward and on a line. I thought of a greedy approach though, it just didn't seem to have better O(n) -potentially having to traverse the whole tree to find an exact solution in the worst case-, but that was just my intuition talking with limited time constraints. I might be wrong :) –  Jubbat Mar 12 '12 at 12:52
Then, may be, the "a", "b", "c"... "n" kilometers are some sort of floating point numbers or very big relatively prime integer numbers. In this case DP is not applicable and branch-and-cut algorithm shoult be used. By the way, greedy approach (though not optimal for this task) is always O(N) (or O(N log N) to pre-sort values). –  Evgeny Kluev Mar 12 '12 at 13:00
by ta you mean \t_a not t*a yes? –  Saeed Amiri Mar 12 '12 at 13:16
Pause time "m" appears to be a constant not related to speed or distance so I don't think you can easily ignore it. Suppose "m" is large - the number of legs in the trip then becomes important. A "high speed" many leg trip could loose over a "low speed" fewer leg trip due to the accumulated "m" values. –  NealB Mar 12 '12 at 16:01

4 Answers 4

up vote 4 down vote accepted

Simplifying slightly, let ti be the time (including downtime) that it takes the robot to run distance di. Assume that t1/d1 ≤ … ≤ tn/dn. If t1/d1 is significantly smaller than t2/d2 and d1 and the total distance D to be run are large, then branch and bound likely outperforms dynamic programming. Branch and bound solves the integer programming formulation

minimize ∑i ti xi
subject to
i di xi = D
∀i xiN

by using the value of the relaxation where xi can be any nonnegative real as a guide. The latter is easily verified to be at most (t1/d1)D, by setting x1 to D/d1 and ∀i ≠ 1 xi = 0, and at least (t1/d1)D, by setting the sole variable of the dual program to t1/d1. Solving the relaxation is the bound step; every integer solution is a fractional solution, so the best integer solution requires time at least (t1/d1)D.

The branch step takes one integer program and splits it in two whose solutions, taken together, cover the entire solution space of the original. In this case, one piece could have the extra constraint x1 = 0 and the other could have the extra constraint x1 ≥ 1. It might look as though this would create subproblems with side constraints, but in fact, we can just delete the first move, or decrease D by d1 and add the constant t1 to the objective. Another option for branching is to add either the constraint xi = ⌊D/di⌋ or xi ≤ ⌊D/di⌋ - 1, which requires generalizing to upper bounds on the number of repetitions of each move.

The main loop of branch and bound selects one of a collection of subproblems, branches, computes bounds for the two subproblems, and puts them back into the collection. The efficiency over brute force comes from the fact that, when we have a solution with a particular value, every subproblem whose relaxed value is at least that much can be thrown away. Once the collection is emptied this way, we have the optimal solution.

Hybrids of branch and bound and dynamic programming are possible, for example, computing optimal solutions for small D via DP and using those values instead of branching on subproblems that have been solved.

share|improve this answer
Thanks. My knowledge of this is a bit rusty, but this seems like a suitable alternative solution to me. –  Jubbat Mar 12 '12 at 19:45

Create array of size m and for 0 to m( m is your distance) do:

a[i] = infinite;

a[0] = 0;

a[i] = min{min{a[i-j] + tj + m for all j in possible kilometers of robot. and j≠i} , ti if i is in possible moves of robot}

a[m] is lowest possible value. Also you can have array like b to save a[i]s selection. Also if a[m] == infinite means it's not possible.

Edit: we can solve it in another way by creating a digraph, again our graph is dependent to m length of path, graph has nodes labeled {0..m}, now start from node 0 connect it to all possible nodes; means if you have a kilometer i you can connect 0 and vi with weight ti, except for node 0->x, for all other nodes you should connect node i->j with weight tj-i + m for j>i and j-i is available in input kilometers. now you should find shortest path from v0 to vn. but this algorithm still is O(nm).

share|improve this answer
Yes, Saeed that's pretty much my algorithm. I see you have understood it. I think I am asking something different ie. How would you solve this, is this a good solution, etc –  Jubbat Mar 12 '12 at 16:18
If this is solution to your problem I think is good, currently I don't know how to reduce it to npc problems, but I guess your problem is npc, also I couldn't understand you have one robot or more than one? and if more than one, they can have collision or not. –  Saeed Amiri Mar 12 '12 at 17:17

Let G be the desired distance run.

Let n be the longest possible distance run without pause.

Let L = G / n (Integer arithmetic, discard fraction part)

Let R = G mod n (ie. The remainder from the above division)

Make the robot run it's longest distance (ie. n) L times, and then whichever distance (a, b, c, etc.) is greater than R by the least amount (ie the smallest available distance that is equal to or greater than R)

Either I understood the problem wrong, or you're all over thinking it

share|improve this answer
But you should minimise time. I know it doesn´t make much sense, but in this problem you could have a programmed run of 10 km in 1m and another of 1km in 10m. -- Now, if you sort by speed instead, that would be a greedy approach. I am still unsure if it has better or worse O(n) time for the average and worst case. And to be completely honest it is even hard for me to visualise why the knapsack problem is NP Complete in the first place –  Jubbat Mar 12 '12 at 17:51
This is definitely not correct. Simple example: total distance=10, available unit distances =6,5,1. You're doing 6,1,1,1,1 while optimal is clearly 5,5. And I'm not even taking time under consideration! –  Marcin Mar 12 '12 at 17:56
@Marcin Nope: 6, 5. 1 is not greater than or equal to R. I agree that the optimum solution would be 5, 5 though. –  Aaron J Lang Mar 12 '12 at 21:44
@Jubbat Sorry, I didn't realise that the time wasn't proportional to distance travelled. –  Aaron J Lang Mar 12 '12 at 21:45
@AaronJLang - perhaps I misread "How would you program this robot to go a exact number of kilometers in the minimum amount of time?" 6+5 != 10... –  Marcin Mar 12 '12 at 21:49

I am a big believer in showing instead of telling. Here is a program that may be doing what you are looking for. Let me know if it satisfies your question. Simply copy, paste, and run the program. You should of course test with your own data set.

import java.util.Arrays;

public class Speed {
 * @param distance
 * @param sprints ={{A,Ta},{B,Tb},{C,Tc}, ..., {N,Tn}}
public static int getFastestTime(int distance, int[][] sprints){
    long[] minTime = new long[distance+1];//distance from 0 to distance
    minTime[0]=0;//key=distance; value=time
    for(int[] speed: sprints)
        for(int d=1; d<minTime.length; d++)
            if(d>=speed[0] && minTime[d] > minTime[d-speed[0]]+speed[1])
    return (int)minTime[distance];

public static void main(String... args){
    //sprints ={{A,Ta},{B,Tb},{C,Tc}, ..., {N,Tn}}
    int[][] sprints={{3,2},{5,3},{7,5}};
    int distance = 21;
share|improve this answer

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