Time acceleration hypothesis

Mainstream versus Tach

Mainstream	Tach
Space between galaxies expands	Galaxies' constituents shrink
Wavelengths of light expand	Galaxies' constituents shrink
Cosmological redshift induced by expanded space	Cosmological redshift induced by shrunken observer
Cosmological time dilation induced by movement of distant objects	Cosmological time dilation induced by time accelerated observer
Galactic rotation curves are explained by cold-dark matter distribution models	Galactic rotation curves are explained by velocity-neutral radial shrinkage
Acceleration of the universe is explained by dark energy and a positive cosmological constant	Acceleration of galaxies is explained by angular momentum transfer from smaller to larger
Friedmann-Lemaître-Robertson-Walker metric	Euclidean metric
Escape from a gravitational singularity	Freedom from large gravitational wells
Variable coordinate speed of light	Constant coordinate speed of light
Big Bang	Cyclic Multiverse
Cosmological Principle	Fractal Geometry
One time	Repeatable
Global Thermodynamic Equilibrium at the largest scales	Local Thermodynamic Equilibrium at the largest scales

Parameters

Gravity ${\displaystyle G}$

Mass ${\displaystyle M}$

Radius ${\displaystyle r=\frac{1}{2}\frac{minor\ axis^2}{major\ axis}}$

Speed of light ${\displaystyle c}$

Wavelength with respect to no gravity field ${\displaystyle \lambda_0}$

Wavelength with respect to a gravity field ${\displaystyle \lambda=\lambda_0\sqrt{1-2GM/rc^2}}$

Increase of light frequency virtual due to time dilation of observer. ${\displaystyle \frac{\lambda_0}{\lambda}}$

Reduction of light wavelength virtual due to size expansion of observer. ${\displaystyle \frac{\lambda}{\lambda_0}}$

Unit proportionality

Object measurement	Units	core	middle	edge
Mass	Kilogram	=	=	=	${\displaystyle kg}$
Length	Meter	▲	=	▼	${\displaystyle m}$
Time	Second	▲	=	▼	${\displaystyle s}$
Velocity	Meter/Second	=	=	=	${\displaystyle m/s}$
Acceleration	Meter/Second^2	▼	=	▲	${\displaystyle m/s^2}$
Gravitational Constant	Meter^3/(Kilogram·Second^2)	▲	=	▼	${\displaystyle G}$
Angular velocity	Radians/Second	▼	=	▲	${\displaystyle \theta/s}$
Angular size	Radians	=	=	=	${\displaystyle \theta}$
Frequency	Radians/Second	▼	=	▲	${\displaystyle \nu}$
Luminosity	Watts	▼	=	▲	${\displaystyle W}$
Moment of inertia	Kilogram·Meter^2	▲▲	=	▼▼	${\displaystyle kg \times m^2}$
Angular momentum	Kilogram·Meter^2/Second	▲	=	▼	${\displaystyle \hbar}$
Electric Permittivity	Kilogram·Meter^3/(Second^2·Coulomb^2)	▼	=	▲	${\displaystyle \epsilon_0}$
Fine structure constant	N/A	=	=	=	${\displaystyle \alpha}$
Magnetic permeability	Kilogram·Meter/Coulomb^2	▲	=	▼	${\displaystyle \mu_0}$