In this article, we consider a special case of Metric-Affine f (R)-gravity for f (R) = R, i.e. the Metric-Affine General Relativity (MAGR). As a companion to the first article in the series, we perform the (3+1) decomposition to the hypermomentum equation, obtained from the minimization of the MAGR action S [g, ω] with respect to the connection ω. Moreover, we show that the hypermomentum tensor H could be constructed completely from 10 hypersurfaces variables that arise from its dilation, shear, and rotational (spin) parts. The (3+1) hypermomentum equations consists of 1 scalar, 3 vector, 3 matrix, and 1 tensor equation of order -21 . Together with the (3+1) decomposition of the traceless torsion constraint, consisting of 1 scalar and 1 vector equation, we obtain 10 hypersurface equations, which are the main result in this article. Finally, we consider some special cases of MAGR, namely, the zero hypermomentum, metric, and torsionless cases. For vanishing hypermomentum, we could retrieve the metric compatibility and torsionless condition in the (3+1) framework, hence forcing the affine connection to be Levi-Civita as in the standard General Relativity.withn * ∈ T * p M is the covariant vector ton, satisfyingn * = g (n, •) = g (n) (the label p is omitted for simplicity).The Adapted Coordinate, Lapse Function, and Shift Vector Let x µ = x 0 , x i be a local coordinate on M, with x 0 and x i are, respectively, the temporal and spatial part of x µ . The corresponding coordinate vector basis on T p M is ∂ µ = {∂ 0 , ∂ i }. Any vector V ∈ T p M could be decomposed as follows: