Using ArcGIS, QGIS, Grass, and/or GVSIG:
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There are at least two different kinds of heat maps:
Every method has advantages and problems, I'm afraid going into detail is far beyond this Q&A.
I'll try to list some methods and functions for QGIS and GRASS.
Concentration of points
If you are tracking movement of wildlife, vehicles, etc. it can be useful to assess regions with high concentration of location messages.
Tools: e.g. QGIS Heatmap plugin (available in versions > 1.7.x) or GRASS v.neighbors or v.kernel
Distributions of attribute values
Here, we're basically talking more or less about interpolation methods. Methods include:
IDW
Depending on the implementation this can be global (using all available points in the set) or local (limited by number of points or maximum distance between points and interpolated position).
Tools: QGIS interpolation plugin (global), GRASS v.surf.idw or r.surf.idw (local)
Splines
Again, huge number of possible implementations. B-Splines are popular.
Tools: GRASS v.surf.bspline
Kriging
Statistical method with various sub-types.
Tools: GRASS v.krige (thanks to om_henners for the tip) or using R.
Statistically, here is how you should go about doing a heat map:
1) Integrate point features. The idea of integration is to take points that should be considered coincident and merge them together as a single location. I like to use nearest neighbor analysis and use an appropriate value from there. (For example, when doing a crime heat map, I use the average 1st nearest neighbor for the underlying parcel dataset against which the crimes are geocoded).
2) Collect events. This creates a spatial weight for all of your integrated points. E.g. if you have 5 events at a single location, it will become one point with weight 5. This is essential for the next two steps. If you need to aggregate an attribute in the events pooled, i.e. different events have higher weight, then you can use a one-to-one spatial join. Use the 'collect event' output as the target and your original integrated events as the join features. Set the field map merge rules statistically combined the attribute on the integrated events (normally with a SUM, though you can use other statistics).
3) Determine peak spatial autocorrelation using Global Moran's I. Just like it says, run global moran's I at different intervals to determine the peak band of spatial autocorrelation in the scale appropriate to the analysis you are doing. You might want to run nearest neighbor again on your collected events to determine the start range for your moran's I tests. (e.g. use the max value for first nearest neighbor)
4) Run Getis-Ord Gi*. Use a fixed distance band based on your moran's I analysis, or use the fixed distance band as a zone of indifference. Your spatial weight from collect events is your numeric count field. This will give you z-scores for each event point in your set.
5) Run IDW against your outcomes from Getis-Ord Gi*.
This outcome is significantly different from what you get with kernel density. It will show you where high values and low values are clustered together rather than just where values are high, without regard to clustering, like in kernel density.
While I like heat maps, I realize they are often mis-used.
Typically what I've seen is a process whereby the color of each pixel is based on the result of an inverse distance weighted function applied to a collection of points. Any time a map has a lot of overlapping point markers, I think it is worth considering a heatmap.
Here's a web based api.
GeoChalkboard has a good tutorial for it.
You can use IDW in ArcGIS.
For simple heat maps and generating countour lines I've used QGis with the Grass intergration:
NB: For this to work, the datasets should be in the same projection!
I think this question has been largely answered except for a couple of points about the issues.
Heat maps can be great, but a classic flaw and issue lies with interpretation. Take the difference between a heat map of crime events compared to a map (heat or otherwise) of crime rate/proportion. While the event heat map might be useful in terms of identifying overall event density, it is blind as an estimate of risk, but would often be interpreted or misused in this way. Consider the same number of events in a region of the same size and shape, but with a different population, while crime might be concentrated in an area, that simply could be because there are more people in that space. Additionally, rates for event data, like for crimes, can be difficult to model, because to produce a heat map raster, they can require an event like model of population, but people don't tend to stand still. The average household composition may be used against a cadastral map for small regions, but this can be problematic, for example crime might not relate to presence at home, but this would be a perfectly valid way to study home invasions and domestic violence.
A second issue is that a heat map is limited to considering a single space-scale, and selecting this space-scale, ie the kernel size or rate of decay, can be complicated and depends on the goals of the study, but must be justified. If the point is to identify the centre of the strongest cluster, and the scale at which it occurs (perhaps to identify the source of a disease outbreak, and a factor in it's spread) a better option might be to consider multiple scales. With appropriate weightings proportional to the scale/area to produce a 3 dimensional raster, where local maximums in the 3D space-scale raster indicate the location of the centre of clusters and their respective sizes, and persistence between scales.