This release presents the MMU v3.0 evidence line as a condensed spacetime simulation framework. The Methane Metauniverse MMU is formulated as an internal medium response theory with the local state w equal to w2 w3 w4. The components represent electric density like response, torsional magnetic spin like response, and volumetric gravity scale like response. The theory is translated into a frozen K M C Pi simulator, where K is local stiffness, M is internal inertia, C is neighbor and contact propagation, and Pi alpha are observable readout channels. The goal of this release is to test whether one frozen K M C Pi operator package can carry multiple route classes without route specific retuning. The tested routes include QED like Green response, condensed matter like C dispersion, GR like scale and clock response, King plot nonlinearities, time projection, eigenmode phase closure, no ether Pi light readout, and spinor like w3 branch transport. The v2.7 eigencore audit supports the route carrying and state selecting mechanism. Stable local states are treated as phase closed eigenmodes of the frozen K M C operator. Compatible source energy is captured, while non compatible excitation appears as excess and is exported through the C channel. The v2.8d no ether audit addresses the classical ether objection. The allowed Pi light readout gives a null result for observable lattice drift, while deliberately wrong directional metric and wrong Pi readout controls produce clear rejection signals. This supports the MMU route in which the internal medium has structure but the observable Pi light channel does not expose a classical absolute rest frame. The v2.9b spinor audit addresses the spin objection. The w3 route is tested as a projective branch transport structure rather than as a mechanical rotor. The audit supports a spinor like w3 phase route with a 2 pi sheet flip and 4 pi closure. The absolute 21 cm hyperfine coefficient remains a visible boundary and is not claimed as closed in this release. The consolidated status is V3 0 EVIDENCE LINE READY WITH HYPERFINE BOUNDARY. The result supports the MMU unification bridge hypothesis at the operational simulation level: the same internal medium architecture can be route carrying, state selecting, no ether compatible, and spinor phase capable, while keeping the absolute hyperfine bridge open for future SI facing closure tests.
Jurgen Wollbold (Thu,) studied this question.