Homography would match projections of your elements lying on a plane or lying arbitrary in 3D if the camera goes through a pure rotation or zoom and no translation. So here are the cases we are talking about with indication of what is the input to our calculations:

- planar target, pure rotation, intra-frame homography

- planar target, rotation and translation, target to frame homography

- 3D target, pure rotation, frame to frame mapping (constrained by a fundamental matrix)

In case of the planar target, a pure rotation is easy to calculate through your frame-to-frame Homography (H_{12}):
given intrinsic camera matrix A, plane to image homographies for frame H1, and H2 that can be expressed as H_{1}=A, H_{2}=A*R, H_{12} = H2*H1^{-1}=A*R*A^{-1} and thus R=A^{-1}H_{12}*A

In case of elements lying on a plane, rotation with translation of the camera (up to unknown scale) can be calculated through decomposition of target-to-frame homography. Note that the target can be just one of the views. Assuming you have your original planar target as an image (taken at some reference orientation) your task is to decompose the homography between images H_{12} which can be done through SVD. The first two columns of H represent the first two columns of the rotation martrix and be be recovered through H=ULV^{T}, [r1 r2] = UDV^{T} where D is 3x2 Identity matrix with the last row being all 0. The third column of a rotation matrix is just a vector product of the first two columns. The last column of the Homography is a translation vector times some constant.

Finally for arbitrary configuration of points in 3D and pure camera rotation, the rotation is calculated using the essential matrix decomposition rather than homography, see this