My spectral chart has the electron and the Higgs point balances

The precision, the error from Shannon orthogonality, is equal, 9e-3 at both spots (more or less).  That is an outcome, from me balancing Compton frequency, and causes the group separation we see.  But for the bubbles, that is simply the boundary 'temperature' that contains the most entropy given the curvature of the vacuum. The proton is simply the kinetic energy manager of the system, it is simply packing the most bubbles in the system that curvature will support. It is limited on one side by the necessity of its external magnetic gradient to maintain curvature, and on the other side, the necessity of keeping the electron packed.

The quark machine is actually adding subtle moments of motion when you add energy to the atom.  These subtle moments, appear mathematically, as additional fraction and whole terms of the (a+1/a) polynomial. The extra terms induce separate axis of symmetry in which the electron boundary can be maintained. We model it as combinatorics of the polynomial, resolved into power functions. The vacuum sees it as sphere packing producing a moment of symmetry and bubbles regroup locally, and maintain the symmetry via phase balance. The moments of symmetry are always found relative to the electron sphere at the point of maximum congestion.

The 'frequencies' of light are simply the spectral modes released when a moment of symmetry is dropped. Gauss is simple the curve that describes a phase balanced band limited function from Higgs to the electron.  Plank are simply those spectral components organized along axis of symmetry using the prime 'trick'. For each energy change, a  moment of symmetry, and its spectral components, is either added or taken away from the Gauss spectra. But we know the prime trick from Higgs to the electron, its in the spectral chart. We know the polynomial function, so we know the spectral power series.  We can simply write the complete equations for the atom without reference to the 'force' approximation.

Its the sphere trick, Higgs the largest smallest sphere possible with the vacuum curvature, the atomic radius the smallest largest

Heisenberg's 127 and Higgs 107 define the smallest granularity. The inverse powered to the appropriate base, the largest granularity, is the wavelength IBM found when they froze gravity.