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

 
 Course: simple generalizers (left) & absolute equation 2 (right)

• Phenomenal monocomplex absolute course (CR) is supposed to be quantified complexly by the square root of phenomenal absolute energy, i.e. absolute mass times absolute temperature (mT), times the product of phenomenal absolute function, i.e. absolute temperature times 3d-time volume (Tt³), and absolute chemical variability or chemistry , i.e. absolute mass times 3d-time volume (mt³) (see: figures above, course//definition & ...//simple properties, and physical correlations (extract)//energy (11), func-tion (32), chemistry (46) & course (48)), or

            CR = √(absolute energy x (absolute function x absolute chemical variability))
                 = √((absolute mass x absolute temperature)((absolute temperature x 3d-time volume)
                       (absolute mass x 3d-time volume))) 
                 = √(mT((Tt³)(mt³)))*
                 = mTt³**

• Together, phenomenal monocomplex absolute coherence and absolute course are thought to quantify phenomenal bicomplex absolute energetic event-like character (see also: course//complex correlations & energetic eventuality//absolute equation).

*Within spaceless closed systems phenomenal absolute course is thought to be constant (maintenance of absolute course).
**Mathematical simplification by cancelling out yields 'mTt³', but, in addition, serious loss of relevant complex physical information as well.

Internet resources & literature references

• See: course//definition & & ...//simple properties

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