Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

I'm programming a simple game simulation where I have some computer controlled creatures that move on a nodegraph. They want to go towards targets (think, say, wolves wanting to go towards rabbits).

I've already implemented simple pathfinding so a creature can find the fastest route directly towards a given target node, but in the case of multiple targets (lots of food on multiple nodes), I think I want to generate something like a heatmap gradient on the graph so the wolves can just query neighbor nodes and go towards the hottest neighbor.

Anybody know of an efficient way to generate a heatmap on a graph? The fastest way I can think of is to do N full graph traversals (N=number of food nodes), each time doing a BFS (or, closest/hottest-unvisited-node-first-traversal) starting at each food node, calculating heat from that food-node on each node in the graph, and then summing all the heat from each food in one collection pass. I don't like this because, well, if I have a large graph and a large number of food nodes, I may have to do many full graph traversals, each with many nodes.

I was thinking of doing a kind of BFS where I start with an open set of all the food nodes and move outwards from there, but then I'd be calculating the distance to the closest food node only; a cluster of food nodes would not generate a very hot location because I can't go back to increase heat in a previously traversed node (and if I do allow that, I'm essentially visiting every node N times like my previous example anyway). e.g. if I start with:

| | | | | | | | |

where F is food and O is an empty node, and say a food node has a heat of 5 and there's a decay of 1 per node, what I WANT my heatmap to look like is

| | | | | | | | |

but a BFS style traversal (where any node can only be visited once) will look like:

| | | | | | | | |

Anybody got a cleverer way to do this? Worst case maybe I can do my multiple N-times graph traversal, but on a schedules, so I do only one food-node traversal every X seconds...

share|improve this question

Why not simulate the flow of heat around the graph? That is, if temperature of node i at time t is Ti (t), then set:

Ti (t + 1) = α Fi (t) + (1 − β) Ti (t) + γ Σj ∈ n(i) Tj (t)

where Fi (t) is the amount of food on node i at time t, n(i) is the set of neighbours of node i, and α, β and γ are parameters of the simulation. α is the rate at which heat enters the system, β is the rate at which heat exits the system, and γ is the rate at which heat flow from a node to its neighbours. All of these should be small numbers: you will have to find good values for them by experimenting.

Using this equation, it takes O(|nodes| + |edges|) to update the temperature of every node, so you should be able to compute it regularly (ideally every frame).

The equation above is for a discrete simulation (with constant time step). If you have variable time step δt, then try:

Ti (t + δt) = δt α Fi (t) + (1 − β)δt Ti (t) + δt γ Σj ∈ n(i) Tj (t)

share|improve this answer
Wow, that is very helpful and really easy to implement. Thanks! I'll give it a shot. I already have variable timestep so I may as well implement that. Also, I can then update it on a schedule if it's too resource intensive per frame... – RibsNGibs Mar 22 '13 at 10:20
Hi, I am finally getting around to implementing this (darn day job). I was wondering if you knew what I should substitute for γ if I have edges of different lengths. That is, if γ=f(L), where L is the length of the edge, what is f(x)? My simulation doesn't have to be anywhere near "correct", but I'd like it to satisfy the property where, if I ran enough steps, 2 nodes 10 units apart would and a line of 3 units 5 units apart would converge on roughly the same heat transfer between the two end nodes. – RibsNGibs Apr 26 '13 at 0:55

Your general approach is good, but I think you are being blinded by your heatmap concept. In essence you want to compute a weighted average location of all targets, and have your hunters head for that point. I would implement this as follows:

  1. If any target closer than N, then track the closest target; else
  2. Compute weighted average location of all targets closer than Max, with weighting function = D^2 (just a guess, but quick to calculate because no square root required). Hunters head for that location on each iteration.
  3. Repeat from 1.
share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.