M P

Hi James,
your reviews take in me always a smile. Funny review.

Not diagonal system (example)
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S1 = 10 [s] = input time in MMM --> the watch
M1 = 100 [m] = input space in MMM --> the meter
K2 = 70 [Kg] = input weight in ColorWeight2 --> the balance
---
I’m running 100 meters in 10 seconds.
I write the MMM input.
It say so.
The weight associated to the space time is 100 s^2 because the space number is different to the time number (not diagonal system).
The frequency associated to the space time is 1000 m*s.
The wave length is coinciding with the space (an altitude, a length).
It write 3 color levels.
The red is 100 [m] because I’m not on the diagonal.
The green is 100 [m].
The blue is 100 [m].
It write 3 physics variables.
The velocity is 10 m/s.
The acceleration is 1 m/s^2.
The emotivity is 10 m^2/s^3.
I’ve used only the time altitude dimension, the third dimension, because I’m running on the plane.
I’m running because I’ve a physicity. With a weight.
The balance say 70 Kg.
This data is not used.
However the program has associated physics variables of 3° dimension with my weight.
The weight 100 s^2 is associated to 70 Kg.
The frequency 1000 m*s is associated to 70 Kg.
The wave length, the 100 space meters, is associated to 70 Kg.
The red is associated to 70 Kg.
The green is associated to 70 Kg.
The blue is associated to 70 Kg.
The velocity is associated to 70 Kg.
The acceleration is associated to 70 Kg.
The emotivity is associated to 70 Kg.
Because the 70 Kg are running the 100 meters in 10 seconds.
In the program at this time there is not 70 Kg information.
The obtained results has certainly an union with the 70 Kg but the output numbers are without 70 Kg dependence because I haven’t used this weight quantity.
Now is the moment to use also the weight value.
The ColorWeight2 take in input time space and weight.
Is necessary to insert a red quantity.
From MMM computation I’ve the red quantity. This number is obtained with MMM logic and it is the same logic of ColorWeight2.
Start program.
The seconds and the meters live in a range 30100 values.
They’ve a correlation with green and blue color. And I’ve this number from MMM, like the red.
I wirte the data input with this logic: to obtain the same time altitude green blue of MMM.
to select a row of time in seconds (1-30100): 10010
to select a column of space in meters (1-30100): 10100
Now the computer want the red color.
to select the red color (0-300): 100
I write the MMM red and so there is union with the weight of 70 Kg.
Are obtained output.
red profundity = 100
green profundity = 100
blue profundity = 100
[s] = 10
[m] = 100
[m/s] = 10
[m/s2] = 1
There is two programs coincidence.
There is also this.
[kg] = 1
[kg*m/s2] = 1
The 70 Kg data is not on the machine, like in MMM. And there is also now weight information. It is obtained thanks to the acceleration formula. The weight obtained is an inverse acceleration. In this way the weight force, like weight per acceleration, is always unitary.
The union with the equal symbol of the MMM weight with this weight is: 100 s^2 = 1 Kg = 1 s^2/m
The result is: altitude = 1/100 [m].
And so: 100 m = 1/100 m --> 10000 m = 1 m --> 10 Km = 1m
The 100 meters are 1/100 of meter if 1 Kg is coinciding with 100 s^2.
Is obtained the MMM-ColorWeight2 union.
The 100 meters are 1 cm because 1 Kg is coinciding with 100 s^2 if the double RGB is the same.
And the double RGB is the same because the two systems has the same quantity numbers.
To run 100 meters with a weight of 100 s^2 is equal to run 1 cm with a kilogram.
The 70 Kg aren’t used at this time.
The weight range is from 1 to 1000.
My weight could be 1 Kg or 123 Kg or 999 Kg: the same result.
The data are indipendent to the weight.
Comparison.
A man with a weight of 210 Kg is running the 100 meters in 10 seconds. At this program time the results are the same quantities: the same time and the same space. But my weight is 70 Kg and the man weight is 210 Kg. The same results with a difference in the energy production. The same numbers in the third dimension because the color output is the same but a different energy quantity because the spacetime is the same and the weight is not the same.
To run 100 meters with a weight of 100 s^2 is equal to run 1 cm with a kilogram, for me and also for the man and also for the other all weight quantities.
---
I write 70 Kg in input.
to insert a positive number of weight [Kg] with range 1-1000: 70
Is obtained this.
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN
velocity [m/s] axes: T / Y 10
gravity [m/s^2] axes: T / Y^2 1
altitude / time^2 [m/s^2] axes: T / Y^2 1
gravity / velocity [1/s] axes: 1 / T 0.1000
velocity / gravity [s] axes: Y 10
mass [s^2/m] axes: Y^2 / T 1
1 / velocity [s/m] axes: Y / T 0.1000
1 / gravity [s^2/m] axes: Y^2 / T 1
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.1429
weight / time [Kg/s] axes: XZ / Y 7
time / weight [s/Kg] axes: Y / XZ 0.1429
weight / mass [Kg*m/s^2] axes: XZT / Y^2 70
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 70
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN + 100
velocity [m/s] axes: T / Y 0.9091
gravity [m/s^2] axes: T / Y^2 0.0083
altitude / time^2 [m/s^2] axes: T / Y^2 0.0083
gravity / velocity [1/s] axes: 1 / T 0.0091
velocity / gravity [s] axes: Y 110
mass [s^2/m] axes: Y^2 / T 121
1 / velocity [s/m] axes: Y / T 1.1000
1 / gravity [s^2/m] axes: Y^2 / T 121
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0130
weight / time [Kg/s] axes: XZ / Y 0.6364
time / weight [s/Kg] axes: Y / XZ 1.5714
weight / mass [Kg*m/s^2] axes: XZT / Y^2 0.5785
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 8470
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN + 200
velocity [m/s] axes: T / Y 0.4762
gravity [m/s^2] axes: T / Y^2 0.0023
altitude / time^2 [m/s^2] axes: T / Y^2 0.0023
gravity / velocity [1/s] axes: 1 / T 0.0048
velocity / gravity [s] axes: Y 210
mass [s^2/m] axes: Y^2 / T 441
1 / velocity [s/m] axes: Y / T 2.1000
1 / gravity [s^2/m] axes: Y^2 / T 441
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0068
weight / time [Kg/s] axes: XZ / Y 0.3333
time / weight [s/Kg] axes: Y / XZ 3
weight / mass [Kg*m/s^2] axes: XZT / Y^2 0.1587
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 30870
point of half: clock verse dynamic solution without weight
time = -60
space = 30
velocity = -60
acceleration = -69
mass = -69
weight force = -69
clock verse dynamic solution = perception of the color weight
---
Now I write the 210 Kg data.
to insert a positive number of weight [Kg] with range 1-1000: 210
Is obtained this.
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN
velocity [m/s] axes: T / Y 10
gravity [m/s^2] axes: T / Y^2 1
altitude / time^2 [m/s^2] axes: T / Y^2 1
gravity / velocity [1/s] axes: 1 / T 0.1000
velocity / gravity [s] axes: Y 10
mass [s^2/m] axes: Y^2 / T 1
1 / velocity [s/m] axes: Y / T 0.1000
1 / gravity [s^2/m] axes: Y^2 / T 1
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0476
weight / time [Kg/s] axes: XZ / Y 21
time / weight [s/Kg] axes: Y / XZ 0.0476
weight / mass [Kg*m/s^2] axes: XZT / Y^2 210
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 210
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN + 100
velocity [m/s] axes: T / Y 0.9091
gravity [m/s^2] axes: T / Y^2 0.0083
altitude / time^2 [m/s^2] axes: T / Y^2 0.0083
gravity / velocity [1/s] axes: 1 / T 0.0091
velocity / gravity [s] axes: Y 110
mass [s^2/m] axes: Y^2 / T 121
1 / velocity [s/m] axes: Y / T 1.1000
1 / gravity [s^2/m] axes: Y^2 / T 121
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0043
weight / time [Kg/s] axes: XZ / Y 1.9091
time / weight [s/Kg] axes: Y / XZ 0.5238
weight / mass [Kg*m/s^2] axes: XZT / Y^2 1.7355
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 25410
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN + 200
velocity [m/s] axes: T / Y 0.4762
gravity [m/s^2] axes: T / Y^2 0.0023
altitude / time^2 [m/s^2] axes: T / Y^2 0.0023
gravity / velocity [1/s] axes: 1 / T 0.0048
velocity / gravity [s] axes: Y 210
mass [s^2/m] axes: Y^2 / T 441
1 / velocity [s/m] axes: Y / T 2.1000
1 / gravity [s^2/m] axes: Y^2 / T 441
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0023
weight / time [Kg/s] axes: XZ / Y 1
time / weight [s/Kg] axes: Y / XZ 1
weight / mass [Kg*m/s^2] axes: XZT / Y^2 0.4762
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 92610
point of half: clock verse dynamic solution without weight
time = -200
space = -110
velocity = -200
acceleration = -209
mass = -209
weight force = -209
clock verse dynamic solution = perception of the color weight
---
Comparison.
The same results.
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN
velocity [m/s] axes: T / Y 10
gravity [m/s^2] axes: T / Y^2 1
altitude / time^2 [m/s^2] axes: T / Y^2 1
gravity / velocity [1/s] axes: 1 / T 0.1000
velocity / gravity [s] axes: Y 10
mass [s^2/m] axes: Y^2 / T 1
1 / velocity [s/m] axes: Y / T 0.1000
1 / gravity [s^2/m] axes: Y^2 / T 1
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0476
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN + 100
velocity [m/s] axes: T / Y 0.9091
gravity [m/s^2] axes: T / Y^2 0.0083
altitude / time^2 [m/s^2] axes: T / Y^2 0.0083
gravity / velocity [1/s] axes: 1 / T 0.0091
velocity / gravity [s] axes: Y 110
mass [s^2/m] axes: Y^2 / T 121
1 / velocity [s/m] axes: Y / T 1.1000
1 / gravity [s^2/m] axes: Y^2 / T 121
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN + 200
velocity [m/s] axes: T / Y 0.4762
gravity [m/s^2] axes: T / Y^2 0.0023
altitude / time^2 [m/s^2] axes: T / Y^2 0.0023
gravity / velocity [1/s] axes: 1 / T 0.0048
velocity / gravity [s] axes: Y 210
mass [s^2/m] axes: Y^2 / T 441
1 / velocity [s/m] axes: Y / T 2.1000
1 / gravity [s^2/m] axes: Y^2 / T 441
---
Comparison.
Not the same results.
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN
With 70.
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.1429
weight / time [Kg/s] axes: XZ / Y 7
time / weight [s/Kg] axes: Y / XZ 0.1429
weight / mass [Kg*m/s^2] axes: XZT / Y^2 70
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 70
With 210.
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0476
weight / time [Kg/s] axes: XZ / Y 21
time / weight [s/Kg] axes: Y / XZ 0.0476
weight / mass [Kg*m/s^2] axes: XZT / Y^2 210
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 210
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN + 100
With 70.
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0130
weight / time [Kg/s] axes: XZ / Y 0.6364
time / weight [s/Kg] axes: Y / XZ 1.5714
weight / mass [Kg*m/s^2] axes: XZT / Y^2 0.5785
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 8470
With 210.
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0043
weight / time [Kg/s] axes: XZ / Y 1.9091
time / weight [s/Kg] axes: Y / XZ 0.5238
weight / mass [Kg*m/s^2] axes: XZT / Y^2 1.7355
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 25410
PHYSICS CORRELATIONS of the weight inserted in ZERO UP and ZERO DOWN + 200
With 70.
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0068
weight / time [Kg/s] axes: XZ / Y 0.3333
time / weight [s/Kg] axes: Y / XZ 3
weight / mass [Kg*m/s^2] axes: XZT / Y^2 0.1587
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 30870
With 210.
altitude / ( time * weight ) [m/(s*Kg)] axes: T / XZY 0.0023
weight / time [Kg/s] axes: XZ / Y 1
time / weight [s/Kg] axes: Y / XZ 1
weight / mass [Kg*m/s^2] axes: XZT / Y^2 0.4762
mass / weight [s^2/(Kg*m)] axes: Y^2 / XZT 92610
With 70.
point of half: clock verse dynamic solution without weight
clock verse dynamic solution = perception of the color weight
time = -60
space = 30
velocity = -60
acceleration = -69
mass = -69
weight force = -69
With 210.
point of half: clock verse dynamic solution without weight
clock verse dynamic solution = perception of the color weight
time = -200
space = -110
velocity = -200
acceleration = -209
mass = -209
weight force = -209
---
Conclusion.
The 1° triple color (R=G=B=100) system is an emotivity 10 m^2/s^3 with a weight 70 Kg: 70 Kg = 10 m^2/s^3.
The 2° triple color (R=G=B=100) system is an emotivity 10 m^2/s^3 with a weight 210 Kg: 210 Kg = 10 m^2/s^3.
The proportional unitive factor is 3.
The same emotive quantity of 3° dimension is a weight 3 times bigger in the 2° case.
The same color solution is a weight 3 times bigger in the 2° case.
Better or not better?
In the 2° case the production is 3 times the 1° case production. Like production is a better way the second. But like consume is a better way the first case. With 210 Kg the energy is a production 3 times superior but at the same time is a consume 3 times superior.
Limit case. An infinitesimal weight and an infinite weight with the same 3° dimension quantities: the same movement, a coincident dynamicity. The infinitesimal case is a minimum energy consume, the infinite case is a maximum energy consume and the proportional unitive factor is an infinite square.
With a neuro-current association the double system is only one system: the infinitesimal case (70 Kg) is right down point of current and the infinite case (210 Kg) is right up point of current and the infinite square proportional unitive factor (the 3) is left point of current, central reference like bidimensional plane. The reference plane and the choose of the right down or the reference plane and the choose of the right up. In a case is a soft emotivity (and it is fine if I not stay fine and it is not fine if I stay fine) and in the other case is a strong emotivity (and it is not fine if I not stay fine and it is fine if I stay fine).

pointless submission

I can nothing if you don’t understand my programs. Programs are programs. Also I have friends and my friends don’t think this is non-sense. Life is a strange program and this is my Matlab page.