Please explain the difference between "hill climbing" and "greedy" algorithms.
It seems both are similiar, and I have a doubts that "hill climbing" is an algorithm; it seems to be an optimization. Is this correct?
Please explain the difference between "hill climbing" and "greedy" algorithms. It seems both are similiar, and I have a doubts that "hill climbing" is an algorithm; it seems to be an optimization. Is this correct? 


Hillclimbing and greedy algorithms are both heuristics that can be used for optimization problems. In an optimization problem, we generally seek some optimum combination or ordering of problem elements. A given combination or ordering is a solution. In either case, a solution can evaluated to compare it against other solutions. In a hillclimbing heuristic, you start with an initial solution. Generate one or more neighboring solutions. Pick the best and continue until there are no better neighboring solutions. This will generally yield one solution. In hillclimbing, we need to know how to evaluate a solution, and how to generate a "neighbor." In a greedy heuristic, we need to know something special about the problem at hand. A greedy algorithm uses information to produce a single solution. A good example of an optimization problem is a 01 knapsack. In this problem, there is a knapsack with a certain weight limit, and a bunch of items to put in the knapsack. Each item has a weight and a value. The object is to maximize the value of the objects in the knapsack while keeping the weight under the limit. A greedy algorithm would pick objects of highest density and put them in until the knapsack is full. For example, compared to a brick, a diamond has a high value and a small weight, so we would put the diamond in first. Here is an example of where a greedy algorithm would fail: say you have a knapsack with capacity 100. You have the following items:
The greedy algorithm would put in the diamond and then be done, giving a value of 1000. But the optimal solution would be to include the 5 gold coins, giving value 1050. The hillclimbing algorithm would generate an initial solutionjust randomly choose some items (ensure they are under the weight limit). Then evaluate the solutionthat is, determine the value. Generate a neighboring solution. For example, try exchanging one item for another (ensure you are still under the weight limit). If this has a higher value, use this selection and start over. Hill climbing is not a greedy algorithm. 


They are two totally different things. "Hill climbing" is just another name for "gradient descent" (whichever version you prefer depends on what you consider to be up or down.) The main problem that hill climbing solves is nonlinear optimization, and it does this by using local information about the function to walk toward a minimum. In this sense, it is not an algorithm but really a heuristic method (unless you are content with simply finding local extrema). Greedy algorithms on the other hand are real bona fide algorithms  they do not make any approximations and always give you exactly the right answer globally (at least in the situations where they can be applied). In a technical sense, one usually says that an algorithm is greedy if internally it makes use of an algebraic structure called a "matroid". Matroids are just a fancy way of dealing with sequences of choices, where at each step the decision you make can be considered independent of all your other choices. The classic example of a greedy problem is finding the minimum spanning tree of a graph. It turns out that the order in which you add edges to a minimum spanning tree does not matter, so long as the edges you pick don't create a cycle. Another way to say this is that if you have any two trees on a graph, and one is larger than the other, then it is always possible to take an edge from the larger tree and stick it in the smaller one such that the resulting subgraph is still a tree! This is the basis for Kruskal's algorithm, which can be considered one of the prototypes of a greedy algorithm. One can also talk about "greedy approximations" of NPhard problems. This usually proceeds by replacing the NPhard problem with a similar problem that has a greedy solution. If you do this right, one then usually hopes to show that the solution to the greedy problem always gives a reasonably good approximate solution to the original NPhard problem (typically measured in some metric sense). A classic example of this is the 2approximation of vertex cover by maximum matching. Vertex cover by itself is NPhard, but taking a maximal matching (which is a greedy problem) automatically gives an approximation of the vertex cover problem that is optimal to within a factor of 2 vertices! 


Yes you are correct. Hill climbing is a general mathematical optimization technique (see: http://en.wikipedia.org/wiki/Hill_climbing). A greedy algorithm is any algorithm that simply picks the best choice it sees at the time and takes it. An example of this is making change while minimizing the number of coins (at least with USD). You take the most of the highest denomination of coin, then the most of the next highest, until you reach the amount needed. In this way, hill climbing is a greedy algorithm. 

