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I need some help finding a good heuristic for the following problem:

You are given an R-by-C grid and a six-sided die. Let start and end be two distinct cells on this grid. Find a path from start to end such that the sum of the faces of the die looking up, as the die is turning along the path, is minimal.

The starting orientation of the die is the following (the "2" is facing south):

enter image description here

The way I modeled this problem is by considering the value of the die's face as the cost of an edge in a graph. The graph's vertices are of the form (row, col, die) (i.e, a position in the grid and the current state/orientation of the die). The reason a vertex is not simply (row, col) is because you can end up on the same cell with multiple configurations/orientations of the die.

I used A* to find the solution to the problem; the answers given are correct, but it is not efficient enough. I've determined that the problem is the heuristic I'm using. Currently I'm using Manhattan distance, which is obviously admissible. If I multiply the heuristic with a constant, it's no longer admissible: it runs much faster but it doesn't always find the right answer.

I need some help in finding a better heuristic than Manhattan distance.

share|improve this question
I think that you shouldn't use A* but you should try to find some pattern how the shortest path looks. – usamec May 14 '13 at 19:38
"If I multiply the heuristic with a constant, it's no longer admissible" - The best I can come up with right now is (manhattenDistance/3)*6 + (manhattenDistance%3), where / is integer division and % is mod. This works because in any 3 moves with no back-tracking, all three digits will be unique, so the lowest sum we could have is 1+2+3 = 6 (The %3 simply adds any extra, non-multiple-of-three moves). I'll think about it more later, I'm sure there is something better. – BlueRaja - Danny Pflughoeft May 14 '13 at 21:43
@BlueRaja-DannyPflughoeft You can improve your heuristic very slightly with the last term. If manhattenDistance%3 == 2, the minimum value of these final two moves is 3, rather than the 2 that you are adding. – GrantS May 16 '13 at 3:01
@PaulManta Sure! Here it is: You can also use the code in my answer as you wish. – גלעד ברקן May 20 '13 at 14:35
just curious -- does anyone have an example of an A* or other algorithm finding a path with 1515 or lower sum for Paul's example? – גלעד ברקן May 24 '13 at 18:27
up vote 6 down vote accepted

Here's my algorithm applied to Paul's example of a 300x300 grid, starting from (23,25) and ending at (282, 199). It finds the minimum path and sum (1515, which is 2 points less than Paul's result of 1517) in 0.52 seconds. A version with look-up tables instead of calculating the small sections took 0.13 seconds.

Haskell code:

import Data.List (minimumBy)
import Data.Ord (comparing)
import Control.Monad (guard)

rollDie die@[left,right,top,bottom,front,back] move
  | move == "U" = [left,right,front,back,bottom,top]
  | move == "D" = [left,right,back,front,top,bottom]
  | move == "L" = [top,bottom,right,left,front,back]
  | move == "R" = [bottom,top,left,right,front,back]

dieTop die = die!!2

--dieStartingOrientation = [4,3,1,6,2,5] --left,right,top,bottom,front,back

rows = 300
columns = 300

paths (startRow,startColumn) (endRow,endColumn) dieStartingOrientation = 
  solve (dieTop dieStartingOrientation,[]) [(startRow,startColumn)] dieStartingOrientation where
    leftBorder = max 0 (min startColumn endColumn)
    rightBorder = min columns (max startColumn endColumn)
    topBorder = endRow
    bottomBorder = startRow
    solve result@(cost,moves) ((i,j):pathTail) die =
      if (i,j) == (endRow,endColumn)
         then [(result,die)]
         else do
           ((i',j'),move) <- ((i+1,j),"U"):next
           guard (i' <= topBorder && i' >= bottomBorder && j' <= rightBorder && j' >= leftBorder)
           solve (cost + dieTop (rollDie die move),move:moves) ((i',j'):(i,j):pathTail) (rollDie die move) 
        where next | null pathTail            = [((i,j+1),"R"),((i,j-1),"L")]
                   | head pathTail == (i,j-1) = [((i,j+1),"R")]
                   | head pathTail == (i,j+1) = [((i,j-1),"L")]
                   | otherwise                = [((i,j+1),"R"),((i,j-1),"L")]

--300x300 grid starting at (23, 25) and ending at (282,199)

applicationNum = 
  let (r,c) = (282-22, 199-24)
      numRowReductions = floor (r/4) - 1
      numColumnReductions = floor (c/4) - 1
      minimalR = r - 4 * fromInteger numRowReductions
      minimalC = c - 4 * fromInteger numColumnReductions
  in (fst . fst . minimumBy (comparing fst) $ paths (1,1) (minimalR,minimalC) [4,3,1,6,2,5])
     + 14*numRowReductions + 14*numColumnReductions

applicationPath = [firstLeg] ++ secondLeg ++ thirdLeg
               ++ [((0,["R"]),[])] ++ [minimumBy (comparing fst) $ paths (1,1) (2,4) die2] 
      (r,c) = (282-22, 199-24) --(260,175)
      numRowReductions = floor (r/4) - 1
      numColumnReductions = floor (c/4) - 1
      minimalR = r - 4 * fromInteger numRowReductions
      minimalC = c - 4 * fromInteger numColumnReductions
      firstLeg = minimumBy (comparing fst) $ paths (1,1) (minimalR,minimalC) [4,3,1,6,2,5]
      die0 = snd firstLeg
      secondLeg = tail . foldr mfs0 [((0,["R"]),die0)] $ [1..numColumnReductions - 1]
      die1 = snd . last $ secondLeg
      thirdLeg = tail . foldr mfs1  [((0,[]),die1)] $ [1..numRowReductions - 3 * div (numColumnReductions - 1) 4 - 1]
      die2 = rollDie (snd . last $ thirdLeg) "R"
      mfs0 a b = b ++ [((0,["R"]),[])] ++ [minimumBy (comparing fst) $ paths (1,1) (4,4) (rollDie (snd . last $ b) "R")]
      mfs1 a b = b ++ [((0,["U"]),[])] ++ [minimumBy (comparing fst) $ paths (1,1) (4,1) (rollDie (snd . last $ b) "U")]


*Main> applicationNum

*Main> applicationPath
(0.52 secs, 32093988 bytes)

List of "R" and "U":

*Main> let listRL = concatMap (\((a,b),c) -> b) applicationPath
*Main> listRL

Sum of the path using the starting die and list of "R" and "U":

*Main> let sumPath path = foldr (\move (cost,die) -> (cost + dieTop (rollDie die move), rollDie die move)) (1,[4,3,1,6,2,5]) path
*Main> sumPath listRL

Calculation of (r,c) from (1,1) using the list of "R" and "U" (since we start at (1,1,), (r,c) gets adjusted to (282-22, 199-24):

*Main> let rc path = foldr (\move (r,c) -> if move == "R" then (r,c+1) else (r+1,c)) (1,1) path
*Main> rc listRL 


Continuing the research below, it seems that the minimal face-sum path (MFS) 
can be reduced, mod 4, by either rows or columns like so:

MFS (1,1) (r,c) == MFS (1,1) (r-4,c) + 14, for r > 7
                == MFS (1,1) (r,c-4) + 14, for c > 7

This makes finding the number for the minimal path straightforward:

MFS (1,1) (r,c) = 
  let numRowReductions = floor (r/4) - 1
      numColumnReductions = floor (c/4) - 1
      minimalR = r - 4 * numRowReductions
      minimalC = c - 4 * numColumnReductions
  in MFS (1,1) (minimalR,minimalC) + 14*numRowReductions + 14*numColumnReductions

minimalR and minimalC are always less than eight, which means we can easily
pre-calculate the minimal-face-sums for these and use that table to quickly
output the overall solution.

But how do we find the path?
From my testing, it seems to work out similarly:

MFS (1,1) (1,anything) = trivial
MFS (1,1) (anything,1) = trivial
MFS (1,1) (r,c), for r,c < 5 = calculate solution in your favorite way
MFS (1,1) (r,c), for either or both r,c > 4 = 
  MFS (1,1) (minimalR,minimalC) -> roll -> 
  MFS (1,1) (min 4 r-1, min 4 c-1) -> roll -> 
  ...sections must be arranged so the last one includes 
     four rotations for one axis and at least one for the other.
     keeping one row or column the same till the end seems to work.
     (For Paul's example above, after the initial MFS box, I moved in 
     fours along the x-axis, rolling 4x4 boxes to the right, which 
     means the y-axis advanced in threes and then a section in fours 
     going up, until the last box of 2x4. I suspect, but haven't checked, 
     that the sections must divide at least one axis only in fours for 
     this to work)...
  MFS (1,1) (either (if r > 4 then 4 else min 2 r, 4) 
             or     (4, if c > 4 then 4 else min 2 c))
  => (r,c) is now reached

For example,

  MFS (1,1) (5,13) = MFS (1,1) (1,5) -> roll right -> 
                     MFS (1,1) (1,4) -> roll right -> MFS (1,1) (5,4)

  MFS (1,1) (2,13) = MFS (1,1) (1,5) -> roll right -> 
                     MFS (1,1) (1,4) -> roll right -> MFS (1,1) (2,4)

Properties of Dice Observed in Empirical Testing

For target points farther than (1,1) to (2,3), for example (1,1) to (3,4)
or (1,1) to (4,6), the minimum path top-face-sum (MFS) is equal if you 
reverse the target (r,c). In other words: 

1. MFS (1,1) (r,c) == MFS (1,1) (c,r), for r,c > 2

Not only that.

2. MFS (1,1) (r,c) == MFS (1,1) (r',c'), for r,c,r',c' > 2 and r + c == r' + c'
   e.g., MFS (1,1) (4,5) == MFS (1,1) (5,4) == MFS (1,1) (3,6) == MFS (1,1) (6,3)

But here's were it gets interesting:

The MFS for any target box (meaning from startPoint to endPoint) that
can be reduced to a symmetrical combination of (r,c) (r,c) or (r,c) (c,r), for 
r,c > 2, can be expressed as the sum of the MFS of the two smaller symmetrical 
parts, if the die-roll (the change in orientation) between the two parts is 
accounted for. In other words, if this is true, we can breakdown the calculation
into smaller parts, which is much much faster.

For example: 
 Target-box (1,1) to (7,6) can be expressed as: 
 (1,1) (4,3) -> roll right -> (1,1) (4,3) with a different starting orientation

 Check it, baby: 
 MFS  (1,1) (7,6) = MFS (1,1) (4,3) + MFS (1,1) (4,3) 
 (when accounting for the change in starting orientation, rolling right in 

 Eq. 2., implies that MFS (1,1) to (7,6) == MFS (1,1) (5,8)
 and MFS (1,1) (5,8) can be expressed as (1,1) (3,4) -> roll right -> (1,1) (3,4)

 Check it again: 
 MFS (1,1) (7,6) = MFS (1,1) (5,8) = MFS (1,1) (3,4) + MFS (1,1) (3,4)
 (when accounting for the change in starting orientation, rolling right in

Not only that.

The symmetrical parts can apparently be combined in any way:

3. MFS (1,1) (r,c) -> roll-right -> MFS (1,1) (r,c) equals
   MFS (1,1) (r,c) -> roll-right -> MFS (1,1) (c,r) equals
   MFS (1,1) (r,c) -> roll-up -> MFS (1,1) (r,c) equals
   MFS (1,1) (r,c) -> roll-up -> MFS (1,1) (c,r) equals
   MFS (1,1) (2*r-1, 2*c) equals
   MFS (1,1) (2*r, 2*c-1), for r,c > 2
share|improve this answer
+1 I also arrived at the value 14 by noting that there are only three unique sequences of four consecutive faces when going in a straight line (1-2-4-6, 1-2-5-6, and 2-3-4-5), which all add up to 14. This seemed relevant since, by looking at the paths my algorithm found, it tended to travel in lines of length at least four. The heuristic you describe here is very similar to what I ended up with. I also started thinking it should be possible to do this without using a search algorithm at all. – Paul Manta May 19 '13 at 16:58
@PaulManta I think groovy and I found something very similar, which is that you pay 14 for every 4 moves, or 3.5 on average for every move. This is essentially down to the fact that opposite sides of the die add up to 7. If you keep going in the same direction you inevitably use opposite sides of the die every other move. Even if you change directions (as explained in my post in more detail), it's still guaranteed that you use opposite sides of the die every other move counting moves only in a single direction. So I agree that a search shouldn't really be needed at all. – TooTone May 19 '13 at 17:04
@PaulManta: The fact that four moves in a straight line will always sum to 14 is trivial (since opposite sides of the die sum to 7); the issue is that it's possible to get less by moving in zigzag's (or possibly even moving away from the finish, I'm not sure on that yet). I haven't yet finished reading this answer (or TooTone's answer) to understand how they work around that issue. – BlueRaja - Danny Pflughoeft May 20 '13 at 19:15
@BlueRaja-DannyPflughoeft Just to double check, what I meant by my statement is that with face=f1, if you move the die up, say, then move the die left or right any number of times, then move the die up again, with the die ending up on f2, then f1+f2=7. E.g., with the die in the configuration in the OP, f1=1. If you move up, then the face=2. Then let's say you move right 3 times, to get face 4, then 5, then 3. Then you move up again, and f2=6, f1+f2=1+6=7. The key point in this example is that no matter how many times you move left or right, 6 is invariant. – TooTone May 20 '13 at 20:06
@flup yes you can, but you've got an up and a down movement in there and going back on yourself is going to cost you more than you gain (I did state this assumption in my post and I think it's reasonable but demonstrating the rationale for the 3.5 per move took a lot of time and I have run out of time to go into a lot more detail on this, interesting as it is!). – TooTone May 21 '13 at 23:24

Well, I'll add my comment here, since it is more optimal than the current highest-voted answer by @larsmans - but, I am convinced there must be something better (hence the bounty).

If I multiply the heuristic with a constant, it's no longer admissible

The best I can come up with is (manhattenDistance/3)*6 + (manhattenDistance%3), where / is integer division and % is mod. This works because in any 3 moves with no back-tracking, all three digits will be unique, so the lowest sum we could have is 1+2+3 = 6 (The %3 simply adds any extra, non-multiple-of-three moves).

[Edit] As @GrantS pointed out in the comments above, my heuristic can be improved very slightly by adding an additional 1 when manhattenDistance%3 == 2. This is easy to do without a conditional: (manhattenDistance/3)*6 + (manhattenDistance%3)*3/2

share|improve this answer
Thanks for offering a bounty! I'm glad you like the question. :) – Paul Manta May 16 '13 at 22:28
I upvoted even though the phrase "more optimal" makes me shudder... Would you say "more best"? "Better" is better! – j_random_hacker May 17 '13 at 21:06
It seems to me that if one were going to calculate Manhattan distance, one might as well calculate (or better yet pre-calculate) the minimal path sum for minimalR and minimalC (see my answer), in which case one needn't settle for an estimate. My answer offers a very simple calculation for an exact minimal path sum. No good? – גלעד ברקן May 23 '13 at 19:38

Main Edit 3: Proof that the optimal admissible heuristic should be based on 3.5m

The average cost of travelling along the board has to approach 3.5m over the long run where m is the Manhattan distance. Therefore the best admissible heuristic should be 3.5m plus or minus some small constant.

The reason for this is that whenever you move in a direction, x, say, from face x1, the next move in the same direction, to face x2 has to satisfy x1 + x2 = 7. This is because any moves in the perpendicular direction leave the orientation of face x2 the same. Think about rotating a die left to right -- the front and back faces stay the same no matter how many rotations you do. Conversely if you rotate a die front to back, the left and right faces stay the same.

It's easiest to see this with some examples (all starting in the configuration pictured in the question)


here you can see that we start with y1=1, and however many times we move in the x-direction afterwards, the next move in the y-direction has to be y2=6, so y1+y2=7. (Also in the x-direction, there is a simple pairing of 2+5 = 7 and 4+3 = 7).

Another example is


In this example we start with x1=1, and however many times we move in the y-direction afterwards, the next move in the x-direction has to be x2=6. (Also, we see pairings of 4+3=7 in the y-direction, 2+5=7 in the x-direction. And we know in this case the next move in the x-direction has to be 4, and the next move in the y-direction has to be 1.)

This all assumes it's never worth backtracking, but hopefully this can be taken as read.

The original post below just fills in some details of how the estimate of 3.5m should be adjusted to take account of the ability for it to be beaten over the short term.

As a side-note, as I just commented on the OP, A* search might not be required at all. It ought to make sense to simply choose a path made out of 4-long horizontal pieces and 4-long vertical pieces, say, which are optimal. And then make up the remainder with a search or a lookup table based on orientation and x-y offset. (But the question asks for an admissible heuristic so I'm going to leave my answer.)

Main Edit 2: summarize original empirical work, taking account of comments below

In the long term, as explained above, your average cost per move is 3.5. This can also can be seen empirically in the exploration of the data below.

This gives a naive estimate of 3.5m where m is the Manhattan distance. However this is an over-estimate, because in the short term it is possible to do better than the average. A good hypothesis for this is to explore how we can avoid using any faces larger than 3.

  • If we start with face 1, we can use faces 2 and 3 on our first 2 moves, going 2 moves better than 3.5m predicts.
  • If we start with face 2, we can use faces 1 and 3 on our first 2 moves, going 3 moves better than 3.5m predicts.
  • If we start with face 3, we can use faces 1 and 2 on our first 2 moves, going 4 moves better than 3.5m predicts.
  • If we start with face 4,5, or 6, we can use faces 1, 2 and 3 on our first 3 moves, going 4.5 moves better than 3.5m predicts.

This hypothesis can be confirmed empirically by simply running the script below for every starting possibility of the die, as suggested by BlueRaja - Danny Pflughoeft. So a simple admissible statistic is 3.5m - k, where k = max(f+1, 4.5), and f is the starting face. But this is a bit klunky, giving negative numbers for small values of m. It's easy to write a programmatic version that takes account of whether you have just 1 or 2 or 3 moves to go, see below

    static double Adm(int x, int y, int face /* start face */, out int m)
        double adm = 0;
        m = Math.Abs(x) + Math.Abs(y);
        if (m >= 1) {
            if (face == 1)
                adm += 2;
                adm += 1;
        if (m >= 1) {
            if (face <= 2)
                adm += 3;
                adm += 2;
        if (m >= 1 && face >=4) {
            // 4,5,6: we can still use a 3 without backtracking
            adm += 3;

        adm += 3.5 * m;

        return adm;

Running this across a search space with |x|,|y| <= 100, this function underestimates the actual cost by between 0 and 6, with a median of 0.5 or 1.5 depending on the start face.

Main Edit 1: original post

My basic thought was that it would be good to explore the data. So I had a go at Dijkstra's algorithm to see what the space of solutions looks like. What I found is supportive of what's been said already. Some factor times the Manhattan distance is appropriate, but there may be some justification for a higher factor than 1.5. This is nicely indicated by the shape of a contour plot of cost against deviation from initial x y position.

cost against deviation from initial x y position

Here's a wire frame plot -- to be honest this is just for eye candy.

enter image description here

What's interesting is that if you add another column to your data for the manhattan distance (man) and regress the cost (v) against the manhattan distance in R, you get the following

          Estimate Std. Error  t value Pr(>|t|)    
(Intercept) -0.6408087  0.0113650   -56.38   <2e-16
df$man       3.4991861  0.0001047 33421.66   <2e-16

I.e. it's telling you that for every move you make horizontally or vertically, your cost is 3.4991861, or v close to 3.5. That just happens to be the average of 1 to 6, so my intuition is that the data is telling us that on average, it's most efficient to use all the faces of the die equally over a long distance. Over short distances you can be more optimal.

I tried 3.5man - k as an estimate, with k = 2.5. This seemed to work ok. When I subtracted the actual cost from this I got -0.5 as the highest value.

> summary(df$est - df$v)
  Min. 1st Qu.  Median    Mean 3rd Qu.    Max. 
 -6.500  -2.500  -2.000  -1.777  -1.000  -0.500 

However A* search has to work for all configurations including those after the start where the die is not in the original configuration, so the constant k can't be as low as 2.5 in general. It either needs to be raised, e.g. to 4, or be dependent on the configuration of the die, as suggested in another answer.

It's quite possible that I've made some horrible mistake in all of this so I've put the code below. Like I said, I think the approach of generating the data and investigating it is sound even if my results aren't.

Here are some lines of the result file first.






C# code

class Die
    int top;
    int bottom;
    int front;
    int back;
    int left;
    int right;

    public int Top { get { return top; } }
    public int Bottom { get { return bottom; } }
    public int Front { get { return front; } }
    public int Back { get { return back; } }
    public int Left { get { return left; } }
    public int Right { get { return right; } }

    public Die(int top, int bot, int fro, int bac, int lef, int rig)
    { = top;
        bottom = bot;
        front = fro;
        back = bac;
        left = lef;
        right = rig;

    public Die RotateLeft()
        return new Die(
               top: right,
               rig: bottom,
               bot: left,
               lef: top,
               fro: front,
               bac: back

    public Die RotateRight()
        return new Die(
               rig: top,
               top: left,
               lef: bottom,
               bot: right,
               fro: front,
               bac: back

    public Die RotateUp()
        return new Die(
                top: front,
                fro: bottom,
                bot: back,
                bac: top,
                lef: left,
                rig: right

    public Die RotateDown()
        return new Die(
                fro: top,
                top: back,
                bac: bottom,
                bot: front,
                lef: left,
                rig: right

class DieXY


    public Die Die { get; set; }
    public int X { get; set; }
    public int Y { get; set; }

    public DieXY(Die die, int x, int y) { Die = die; X = x; Y = y; }

    public override int GetHashCode() { return Die.Top + Die.Bottom*6 + Die.Front*6^2 + Die.Back*6^3 + Die.Left*6^4 + Die.Right*6^5 + X*6^6 + Y*6^8; }
    public override bool Equals(object obj)
        DieXY die = (DieXY)obj;
        return die != null
            && die.Die.Top == Die.Top && die.Die.Bottom == Die.Bottom
            && die.Die.Front == Die.Front && die.Die.Back == Die.Back
            && die.Die.Left == Die.Left && die.Die.Right == Die.Right 
            && die.X == X && die.Y == Y;

class Program
    static void Main(string[] args)
        Dictionary<DieXY, int> dict = new Dictionary<DieXY, int>();
        int n = 100;
        int sofar = -1;
        DieXY root = new DieXY(new Die(1, 6, 2, 5, 4, 3), 0, 0);
        Queue<Tuple<DieXY, int>> queue = new Queue<Tuple<DieXY, int>>();
        queue.Enqueue(new Tuple<DieXY,int>(root,0));
        while (queue.Count > 0)
            Tuple<DieXY, int> curr = queue.Dequeue();
            DieXY dieXY = curr.Item1;
            Die die = dieXY.Die;
            int x = dieXY.X;
            int y = dieXY.Y;
            if (Math.Max(x,y) > sofar)
                sofar = Math.Max(x, y);
                Console.WriteLine("{0}", sofar);
            int score = curr.Item2;
            if (Math.Abs(x) <= n && Math.Abs(y) <= n)
                int existingScore = 0;
                if (!dict.TryGetValue(dieXY, out existingScore)
                    || score < existingScore)
                    dict[dieXY] = score;
                    Die newDie = null;
                    newDie = die.RotateLeft();
                    queue.Enqueue(new Tuple<DieXY, int>(new DieXY(newDie, x - 1, y), score + newDie.Top));
                    newDie = die.RotateRight();
                    queue.Enqueue(new Tuple<DieXY, int>(new DieXY(newDie, x + 1, y), score + newDie.Top));
                    newDie = die.RotateUp();
                    queue.Enqueue(new Tuple<DieXY, int>(new DieXY(newDie, x, y + 1), score + newDie.Top));
                    newDie = die.RotateDown();
                    queue.Enqueue(new Tuple<DieXY, int>(new DieXY(newDie, x, y - 1), score + newDie.Top));

        int[,] scores = new int[2*n+1,2*n+1];
        for (int aX = 0; aX < 2 * n + 1; aX++)
            for (int aY = 0; aY < 2 * n + 1; aY++)
                scores[aX, aY] = int.MaxValue;
        foreach (KeyValuePair<DieXY, int> curr in dict)
            int aX = curr.Key.X + n;
            int aY = curr.Key.Y + n;
            if (curr.Value < scores[aX, aY])
                scores[aX, aY] = curr.Value;

        using (System.IO.StreamWriter file = new System.IO.StreamWriter("out.csv"))
            for (int aX = 0; aX < 2*n+1; aX++)
                int x = aX - n;
                for (int aY = 0; aY < 2 * n + 1; aY++)
                    int y = aY - n;
                    file.WriteLine("{0},{1},{2}", x, y, scores[aX, aY]);

        Console.WriteLine("Written file");

R code below

df = read.csv("out.csv")
df=transform(df, man=abs(x)+abs(y))

v50=df[abs(df$x)<=50 & abs(df$y)<=50,]
with(v50, wireframe(v ~ x*y))
with(v50, contourplot(v ~ x*y))

summary(lm(df$v ~ df$man))

df$est = df$man * 3.5 - 2.5
summary(df$est - df$v)
share|improve this answer
3.5man - 2.5 fails for the simple case of being diagonal from the finish - the minimum possible is 1+2 = 3, but 3.5man - 2.5 gives 4.5 – BlueRaja - Danny Pflughoeft May 17 '13 at 0:30
@BlueRaja-DannyPflughoeft I might have misunderstood the problem. I thought that to start with, 1 is looking up. So the minimum you can get is roll forward (+2) and rotate left (+3)? – TooTone May 17 '13 at 0:39
The heuristic needs to apply to all spaces (and all die-configurations) on the grid in order to be used by A* – BlueRaja - Danny Pflughoeft May 17 '13 at 0:49
@BlueRaja-DannyPflughoeft Sorry, I can see what you mean now: it's not the start position that's the point; it's that this has to hold for subsequent positions. I got a bit over-excited about the analysis I did and forgot the big picture! If the rest of the analysis I presented is correct (and I have a few doubts), I believe that this would be coped with simply by subtracting a larger constant, or, perhaps as suggested in another answer, making the constant you subtract depend on the configuration. – TooTone May 17 '13 at 1:29
You could simply try running your script for every starting possibility of the die (There's only 24 - 6 possibilities for the top, and for each top, 4 possible orientations); then analyze based on the minimum number of moves over all of those. – BlueRaja - Danny Pflughoeft May 17 '13 at 3:09

If I multiply the heuristic with a constant, it's no longer admissible

It can be if you get rid of some corner cases. Let d be the Manhattan distance, and observe that the die can never have its 1 face up in two subsequent steps of the path. It follows that, if you're not already at the goal:

  • the first step has cost at least 1;
  • if 1 is face up, it's at least 2 (and the same holds for 6);
  • the rest of the path is at least as expensive as a series of 1-2 alternations, which has cost 1.5 × (d - 1).

So an admissible heuristic is

if d == 0 then
    h := 0
else if die == 1 or die == 6 then
    h := 2 + 1.5 × (d - 1)
    h := 1 + 1.5 × (d - 1)
share|improve this answer


If you have to move in a straight line, the best you can do is to end your moves with 1 and 2, for all other moves you can't do better than 3.5*distance.


With ManhattanDistance = x + y the following heuristic could be used:

Heuristic = xH + yH;


xH = calculateStraightLineHeuristic(x)
yH = calculateStraightLineHeuristic(y)

and the function calculateStraightLineHeuristic(z) is defined as follows:

    if (z = 1)
        return zH = 1
    elseif (z = 2)
        return zH = 2+1
        return zH = (z-2)*3.5+2+1
share|improve this answer

I don't think A* search will be much more effective than a simple greedy best first search or uniform cost search. Using straight line distance (Manhattan distance) is a good heuristic.

I am a little rusty on this, and I know that A* only provides the optimal solution given an admissible heuristic. It is hard to provide a better heuristic than Manhattan distance, think about it. When would a zig-zag path be better than straight distance ? Never, unless you have different path costs. If from two, your path cost to 6 is way bigger than the path cost to 4 for example, then you should factor this into your heuristic otherwise, there is nothing I can see to improve. Keep it simple.

share|improve this answer
You might also consider using pythagoras to calculate the distance to the diagonally aligned faces. But I doubt it would be much more effective. e.g (col(2,x) - col(4,x))^2 you could try adapting this a bit. – Marcel-Is-Hier May 16 '13 at 6:43
Using Euclidian distance is certainly a worse heuristic than Manhattan distance. I'm looking for a tighter lower bound on the actual path cost and Euclidean distance is smaller than, or at most equal to Manhattan distance. – Paul Manta May 16 '13 at 6:57
Point taken, and adding it to your Manhattan distance won't work since it does not warrant that your heuristic will remain admissible – Marcel-Is-Hier May 16 '13 at 7:37

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