The Gravitational Group
Several approaches have yielded successful descriptions of gravitation with limitations at the extremes (i.e. singularities) and an inability to correlate to the other forces. Measurement quantization has begun to bridge that gap, first by describing nature with a quantum nomenclature2(Sec. 2.2) thus eliminating singularities, and in the area of new research directly linking the phenomena of gravitation to that of electricity and magnetism. MQ goes further also providing a straight-forward description of measurement distortion with respect to targets in motion2(Sec. 3.1) and in gravitational fields,2(Sec. 3.3) demonstrating their equality not just numerically, but in physical description. MQ has succeeded in providing a new language3(Sec. 2.3) that bridges the forces of nature and each of the fundamental frames of reference2(Sec. 3.4) into a single approach.
With this new approach, the Gravitational Group returns to the core principles of relative measure1(Sec. 3.2) to dissect the role of the observer from observed2(Sec. 3.4) to redefine existing knowledge as a subset of a broader paradigm. Now with three frames of reference,2(Sec. 3.4) their differential provides for a suite of new opportunities in the exploration of gravitation.3(Sec. 2.1)
Significant fields of research are
Published Research
Quantum Inflation, Transition to Expansion, CMB Power Spectrum
An MQ Discovery Series - Pre-prints
A Series of 47 Papers Advancing Solutions to the Most Difficult Problems in Modern Theory
The Physical Constants
New Expressions for the Electric constant Using Only Planck Units
An approach to Describing Elementary Charge Using Only Planck Units
Expression for the Fine Structure Constant Using Only Planck Units
Expressions for the Gravitational Constant to 12 Significant Digits
New Expression for the Magnetic Constant Using Only Planck Units
Classical Physics
What is the Physical Difference Between Baryonic and Electromagnetic Phenomena?
Equivalence of Inertial and Gravitational Mass as a Geometric Property of Nature
Simplest Relation Between Fundamental Length, Mass, and Time
Physical Differences in Describing Phenomena Locally Versus with Respect to the Universe
Discrete Expressions Constrain our Understanding of Charge and the Ground State Orbital of an Atom
Physical Significance of Symmetry and Why Some Phenomena are Not Symmetric
Using Discrete Classical Expressions to Describe Quantum Entanglement
Physical Correlated Approach Demonstrates Singularities Are Not Predicted in Nature
Cosmology
Dark Energy – a Classical Description Using Measurement Quantization
Using Measurement Quantization to Describe Star Velocities Classically
Diameter & Age of the Universe as a Function of the CMB Temperature
Effective Mass of a Galaxy, Star Velocity and their Relation
Physical Significance of Classical and Non-Classical Gravitational Curvature
Classical Description of Mass in the Universe Without Λ and CDM