Principles of Physical Complexity by Jos Koomen (Memes Ltd) - Complex Problem Solutions

 
Particle: simple quantifiers (left) & relative equation (right)

• Phenomenal monocomplex relative particle- or thing-like character (PT’) is supposed to be quantified complexly by the square root of product of phenomenal relative structure, i.e. material density (δm/∆l³) times spatial size (δl³/∆m), relative chemical variability, i.e. material conversion rate (δm/∆t³) times conservation time (δt³/∆m), and relative 3D,3d-spacetime, i.e. 3D,3d-speed (δl³/∆t³) times 3d,3D-travel time (δt³/∆l³) (see: figures above, equation below, particle//definition & ...//simple properties, and physical correlations (extract)//speed (13), travel time (16), density (20), size (23), conversion rate (41), conservation time (44) & particle (49)), or

 PT’ = √(relative structure x relative chemical variability x relative 3D,3d-spacetime time)
       = √((density x size)(conversion rate x conservation time)(3D,3d-speed x 3d,3D-travel time))
       = √(((δm/∆l³)(δl³/∆m))((δm/∆t³)(δt³/∆m))((δl³/∆t³)(δt³/∆l³)))
       = 1**

• Together, phenomenal monocomplex relative particle-like and relative process-like character are thought to underlie phenomenal bicomplex relative plastic event-like character or plastic eventuality (see also: particle//complex correlations & plastic eventuality//relative equation).

*Within entropy-less closed systems phenomenal relative particle-like character is supposed to be constant (limited maintenance of relative particle-like character).
**Ultimately, mathematical simplification by cancelling out yields '1', but, in addition, serious loss of relevant com-plex physical information as well.

Internet resources & literature references

• See: particle//definition & ...//quantifying simple properties

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