Sure. Call your two vectors A and B.
1) (Optional) Smooth your data either with a simple averaging filter (Matlab 'smooth'), or the 'filter' command. This will get rid of local changes in velocity ("gradient") that appear to be essentially noise (as in the ascending component of the red trace.
2) Differentiate both A and B. Now you are directly representing the velocity of each vector (Matlab 'diff').
3) Add the two differentiated vectors together (element-wise). Call this C.
4) Look for all points in C whose absolute value is above a certain threshold (you'll have to eyeball the data to get a good idea of what this should be). Points above this threshold indicate highly similar velocity.
5) Now look for where a high positive value in C is followed by a high negative value, or vice versa. In between these two points you will have similar curves in A and B.
Note: a) You could do the smoothing after step 3 rather than after step 1. b) Re 5), you could have a situation in which a 'hill' in your data is at the edge of the vector and so is 'cut in half', and the vectors descend to baseline before ascending in the next hill. Then 5) would misidentify the hill as coming between the initial descent and subsequent ascent. To avoid this, you could also require that the points in A and B in between the two points of velocity similarity have high absolute values.