Your first thought may be trying to find the rotation that maps one object to another but this a very very complex topic... and is not actually necessary! You're not asking how to best match the two, you're just asking if they are the same or not.
Characterize your model by a list of all interpoint distances. Sort the list by that distance. Now compare the list for each object. They should be identical, since interpoint distances are not affected by translation or rotation.
1) What if the number of points is large, that's a large list of pairs (N*(N-1)/2). In this case you may elect to keep only the longest ones, or even better, keep the 1 or 2 longest ones for each vertex so that every part of your model has some contribution. Dropping information like this however changes the problem to be probabilistic and not deterministic.
2) This only uses vertices to define the shape, not edges. This may be fine (and in practice will be) but if you expect to have figures with identical vertices but different connecting edges. If so, test for the vertex-similarity first. If that passes, then assign a unique labeling to each vertex by using that sorted distance. The longest edge has two vertices. For each of THOSE vertices, find the vertex with the longest (remaining) edge. Label the first vertex 0 and the next vertex 1. Repeat for other vertices in order, and you'll have assigned tags which are shift and rotation independent. Now you can compare edge topologies exactly (check that for every edge in object 1 between two vertices, there's a corresponding edge between the same two vertices in object 2) Note: this starts getting really complex if you have multiple identical interpoint distances and therefore you need tiebreaker comparisons to make the assignments stable and unique.
3) There's a possibility that two figures have identical edge length populations but they aren't identical.. this is true when one object is the mirror image of the other. This is quite annoying to detect! One way to do it is to use four non-coplanar points (perhaps the ones labeled 0 to 3 from the previous step) and compare the "handedness" of the coordinate system they define. If the handedness doesn't match, the objects are mirror images.
Note the list-of-distances gives you easy rejection of non-identical objects. It also allows you to add "fuzzy" acceptance by allowing a certain amount of error in the orderings. Perhaps taking the root-mean-squared difference between the two lists as a "similarity measure" would work well.
Edit: Looks like your problem is a point cloud with no edges. Then the annoying problem of edge correspondence (#2) doesn't even apply and can be ignored! You still have to be careful of the mirror-image problem #3 though.