I'm trying to understand exactly how these algorithms work, but I have been unable to find a simple explanation. I would greatly appreciate it if someone could provide or point me to a description of these algorithms that is easier to understand than the description in the original papers. Thanks.

of what original papers? what did you already try? what is your real problem? – Karussell Oct 14 '12 at 12:27

They solve slightly different problems: Eppstein's algorithm allows paths to have repeated vertices (loops), while Yen's doesn't, see 11011110.livejournal.com/342826.html. – Valentas Mar 24 '17 at 15:39
First of all let me provide you with the links to the papers you were talking about.
Eppstein's paper: D. Eppstein, “Finding the k shortest paths,” SIAM J. Comput., vol. 28, no. 2, pp.652–673, Feb. 1999
Here is my explanation of Yen's algorithm:
Yen's algorithm uses two lists, i.e. list A (permanent shortest paths from source to destination  chronologically ordered) and list B (tentative/candidate shortest paths). At first you have to find the 1st shortest path from the source to destination using any wellsuited shortest path algorithm (e.g. Dijkstra). Then Yen exploits the idea that the kth shortest paths may share edges and subpaths (path from source to any intermediary nodes within the route) from (k1)th shortest path. Then you have to take (k1)th shortest path and make each node in the route unreachable in turn, i.e. rub off particular edge that goes to the node within the route. Once the node is unreachable, find the shortest path from the preceding node to the destination. Then you have a new route which is created by appending the common subpath (from source to the preceding node of the unreachable node) and adds the new shortest path from preceding node to destination. This route is then added to the list B, provided that it has not appeared in list A or list B before. After repeating this for all nodes in the route, you have to find the shortest route in list B and move that to list A. You just have to repeat this process for number of Ks you have.
This algorithm has a computational complexity of O(kn^3). Please read the paper for more details.
The algorithm is as follows:
G = Adjacent Matrix of the Network
Initialize:
A_1 = shortestpath from source to destination
Glocal ← Local copy of G
for k = 2 → K do
for i = 1 → [len(A_(k−1) ) − 1] do
Current Node ← A_(k−1) [i]
Ri ← Subpath (root) from source till current node in A_(k−1)
for j = 1 → k − 1 do
Rj ← Subpath (root) from source till current node in A_j
if Ri == Rj then
Next Node ← Aj [i+1]
Glocal(Current Node, Next Node) ← infinity
Current Node ← unreachable
end if
end for
Si ← Shortestpath from current node till destination
Bi ← Ri + Si
end for
A_k ← Shortestpath amongst all paths in B
Restore original graph: Glocal ← Local copy of G
end for
Unfortunately, I have not used Eppstein's one as Yen's algorithm was optimal for my problem.
Hope this helps. Cheers.
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Edit:
Please have a look at the wikipedia entry as well. It has a nice example.
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Edit:
I have found some implementations in C. The links are as follows:
Eppstein implementation and Loading Graph for Eppstein.
If you are interested, there is a lazy version of Eppstein. The link is as follows:
Lazy Eppstein by Jimenez and Marzal
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Edit:
Just another link. This one contains several implementations (C/C++).
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Edit:
I have found a good explanation of Eppstein's algorithm.

1several links are broken; Eppstein implementation, Loading Graph for Eppstien, layze version and Jimenez and Marzal – Andreas Jul 24 '18 at 11:51