Magnitude of gravitational attraction

Magnitude of gravitational attraction between two basic 3D matter-particles (photons) is the resultant of gravitational actions on them, when their core bodies are in the same plane. When their disc-planes do not coincide, magnitude of gravitational attraction between them is minimal. For all practical purposes it may be neglected. As universal medium is unable to act on flat surfaces of a photon (its disc-faces), gravitational attraction does not develop between two photons, whose disc-planes do not coincide. Magnitude of gravitational action is proportional to extent of 2D energy fields, applying the effort. Considering two photons in space, whose disc-planes coincide, extents of 2D energy fields on their outer sides are infinite. Nature of 2D energy fields may be considered to be steady. Hence, gravitational actions on their outer sides are of highest and of constant magnitude. However, extent of 2D energy fields between the two photons depends on the distance between them. Hence, distance between peripheries of two photons becomes a factor that determines magnitude of gravitational attraction between them. As distance between two photons increases, magnitude of gravitational efforts on them, from in between the photons increase and gravitational attraction between the photons reduces. Hence, magnitude of gravitational attraction between two matter-bodies is in inverse proportion to distance between them. Gravitational actions are experienced separately by each of the basic 3D matter-particles (photons) in nature. Combinations of photons, in various groupings, form fundamental particles, atoms and all other macro bodies. Gravitational attraction (between two macro bodies), at any instant, develop only between photons in them; whose disc shaped spinning core (matter) bodies happens to be simultaneously in the same plane. Photons are disc-shaped 3D matter-bodies, spinning about their diameters. Primary 3D matter-particles are formed by binary combinations of two spinning photons moving in common circular paths, at their critical linear speeds. Therefore, frequency and regularity of a pair of (one from each macro body) photons coming in the same plane simultaneously are very small. Gravitational attraction between them takes place only when they are in the same plane. Although macro bodies are constituted by numerous photons, at any instant, very minute fractions of constituent photons from both macro bodies are under mutual gravitational attraction. Magnitude of gravitational attraction between two macro bodies is the average sum total of gravitational attractions between their constituent photons. Therefore, practically, magnitude of gravitational attraction between two macro bodies at any instant is a minute fraction of total gravitational attractions between all their constituent photons being in the same plane. Each photon is separately affected by gravitation. More number of photons in a macro body will increase gravitational attraction on it towards another macro body. Total quantity of matter-content in a macro body is roughly proportional to number of photons in a macro body. Total number of photons in a macro body may be represented by its total 3D matter-content. Therefore, magnitude of gravitational attraction due to any one body is roughly proportional to its total 3D matter-content.