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Tuesday, June 28, 2016

The change depends on direction of the motion: Generating Eigenvalues from special matrices


"The change depends on direction of the motion"

This means: "It is possible, we move but there will not be any change or even we maybe lose everything."
"The change depends on direction of the motion." is a philosophic quote in which mathematics (Differential Calculus) applied it to find out the definition of gradient vector field.
For example, in Economics, USD is still an independent variable where many curves such as x = f ($), y = f ($), z = ($) … are determining the direction of motion overall function of
w = f (x, y, z …).
In designing strategic plan, maybe whole a company's strategy – making hierarchy depends on only a person or a department where this independent variable will change the company to a star or overturned (collapsed). In physics, the internal energy of the gas (except an ideal gas) depends on the pressure, volume and temperature (K = f (p, v, T)).
Nowadays, we can see many matrices as transformations and operators which are affecting on vectors.
The purpose of this article is, to introduce some special matrices in which you can easily generate all eigenvalues without any calculation.
The question is: How can we apply these special matrices as operators in our real world?


Some special matrices

1. Let consider “A1” as set of Arithmetic Progression where:

d = 1,      a1 = 1   and    an = a1 + (n - 1) d, n = 1, 2, 3,…..

In this case, we have:


A1 = {a1, (a1+1), (a2 +1),……. (a1 + (n - 1) d)}


One of permutations of set A1 is to invert members of set A1 as follows:


A2 = {(a1 + (n - 1) d),….,(a2 +1), (a1+1), a1}      

We can generate many sets which are the periodicity of set A1 just like below cited:

A3 = {a1, (a1+1), (a2 +1),……. (a1 + (n - 1) d)}

A4 = {(a1 + (n - 1) d),….,(a2 +1), (a1+1), a1}

Finally, we will have set B:

B = {A1, A2, A3, A4, …….An    


Rule 1: If size members of set Aor AorAor An, is equal to size members of set B, we will have a square matrix (Mn*n) to be generated by sets A1, A2, A3,…….An in which Eigenvalue of this matrix will be calculated by using of Binomial Coefficient as follows:

Eigenvalue (Mn*n) = λ = C (k, 2)

Where:   k = n+1, nϵ N, λ > 0


Example:
A1 = {1, 2, 3, 4}
A2 = {4, 3, 2, 1}      


A3 = {1, 2, 3, 4}

A4 = {4, 3, 2, 1}  


Matrix (M 4*4) = 
   
1 2 3 4

4 3 2 1

1 2 3 4

4 3 2 1

λ = C ((4+1), 2) = 10



2. Let consider set “A” as follows:

A = {x | x ϵ R}

Rule 2: Each type square matrix which has been generated from set “A”  just like below matrix:

a1 0 0 0 0 0 0 0 0….

a1 a2 0 0 0 0 0 0…..

a1 a2 a3 0 0 0 0 0 ….

a1 a2 a3 a0 0 0 0……

It will show us the eigenvalues which are just equal members set A which have been included in this square matrix (λ = a1, a2, a3, a4, …)


Example:

A = {0.67, 2, 43, 5, -23, 9, -2.3}

Assume we have set B which is a subset of A:

B = {43, -23, -2.3, 9)

Matrix N will be:

43      0

43  -23    0

43 -23 -2.3 0

43 -23 -2.3 9

Eigenvalues of Matrix N are: λ = 43, -23, -2.3, 9

3. Consider square matrices 2*2 as follows:


a    -a

b    -b

Or 

 a      b
-a    -b
a , b ϵ R

Rule 3: Eigenvalues of above matrices are equal to: λ = 0 and
λ = a – b
4. Consider square matrices 3*3 as follows:
 a     -a      a
 b     -b      b
 c     -c       
Or
  a     b       c
 -a    -b     -c
  a      b       
a , b , c ϵ R
Rule 4: Eigenvalues of above matrices are equal to: λ = 0 and
λ = (a + c)-b
5. Consider square matrices 4*4 as follows:


a      -a      a     -a

b     -b      b     -b

c     -c           -c

d     -d      d     -d
Or
  a     b      c      d
 -a    -b    -c     -d
 a      b           d
-a    -b     -c     -d
 a, b , c , d ϵ R

Rule 5: Eigenvalues of above matrices are equal to: λ = 0 and
λ = (a + c -d)-b
6. Consider square matrix “A” as follows:

            a       0      0

A =      a       b      0

            a       b       



If we turn this matrix around first column (as axis) and then we turn it around first row (as axis), we will have matrix “B”:

          c      b     a

B =    0      b     a

               0      


a , b , c ϵ R

Rule 6: Eigenvalue of A + B is equal to λ = c
and eigenvalue of A – B or B - A is equal to zero (λ = 0)
Example:
If matrix A is:

            1.67     0        0

A =      1.67     4        0

            1.67     4       -3  


            -3     4      1.67
B =       0      4     1.67
             0      0     1.67  
                    -1.33     4        1.67
A + B =        1.67      8       1.67
                     1.67      4      -1.33  
λ =  -3
                4.67     -4       -1.67
A - B =    1.67      0       -1.67
                1.67      4       -4.67  
λ = 0




7. Here is another special matrix. Consider matrix A is a square matrix n*n just like below forms in which (a1, a3, a5, a7 a9…an) are diagonal of matrix as follows:


A =

a1   a2    0         0
   a3    a4    0     0
0    0      a5   a6    0
0    0      0     a7   a8
0    0      0      0   a9
…………………....an

Or

A =
a1        0       0
a2    a3       0    0
0     a4   a5       0
0     0    a6   a7    0
0     0    0    a8   a9
…………………....an
a1, a2, a3,….an ϵ R  

Rule 7: Eigenvalues of matrix A are all members on diagonal of matrix A. In fact, property of matrix A to generate eigenvalues is just like Diagonal Matrix.

Example:
A =
-1.56    2     0
  0     -12     3
  0        0     4  

λ = -1.56, -12 and 4

Consequently, we can find out that inverse of previous special matrix (Rule 7) will have the same eigenvalues (members of diagonal). According to Rule 7, we had below matrix M:
M =

a1 0 0 0 0 0 0 0 0….

a1 a2 0 0 0 0 0 0…..

a1 a2 a3 0 0 0 0 0 ….

a1 a2 a3 a0 0 0 0……

Therefore, eigenvalues of M^-1 are all members on diagonal of M^-1.

8. Consider "T" as set of vectors as follows:

T = {V1, V2, V3, ….Vn}

Where:

V1 = a1i

V2 = a2 i + a3 j

V3 = a4 i + a5 j + a6 k

Vn = a7 i + a8 j + a9 k + a10 t …….. amtn   and     a1, a2, a3, a4, a5, …. am are members of R (real 
numbers)

Theorem 8:

If "A" is a square matrix n*n inferred from the set of above vectors just like below cited:

A = {(a1, 0, 0, 0,…), (a2, a3, 0, 0, 0, …), (a4, a5, a6, 0, 0, 0, …..), …....Vn}

In fact, Scalar amounts of V1, V2, V3, …Vn are respectively rows of matrix A.

Then:   Eigenvalues of (A^n) = all members on diameter of matrix A^n (n member of N).

A =

4
0
0
0
0
-6.5
1
0
0
0
5
2
7
0
0
3
9
-5
12
0
-3.45
9
43
15
72

A^4 =
256
0
0
0
0
-552.5
1
0
0
0
2210
800
2401
0
0
-13147.5
13995
-18335
20736
0
-249381
4740402
17264326
6713280
26873856

Eigenvalues are = 256, 1, 2401, 20736, 26873856

Wednesday, June 1, 2016

The Particles with velocity more than the speed of light


 Around 27 months ago, I wrote an article of "Analysis and Design Open Oscillatory Systems with Forced Harmonic Motion" posted on linkhttp://www.emfps.org/2014/02/analysis-and-design-open-oscillatory.html

According to the conclusion of above article and using of Newtonian mechanics, it can be proved that there is some systems with velocity more than the speed of light.

Let me tell you another example about the kinetic theory of gases.

In the reference with below links, Physicists at CERN generated ions with temperatures of more than 1.6 trillion degrees Celsius. At the Brookhaven National Laboratory in Upton, have set a new record for the highest temperature ever measured: 4 trillion degrees Celsius.



Assume, we have a 0.500 mole sample of hydrogen gas at 1.6 - 4 trillion degrees Celsius.
By using of Maxwell–Boltzmann speed distribution function, we can calculate number of molecules with velocity between 300000 km/s to 400000 km/s at 1.6 trillion degrees Celsius which is equal 1.01326*10^21. It means that about 0.34 % of total molecules of hydrogen have velocity more than 300000 km/s. At 4 trillion degrees Celsius, number of molecules which have velocity between 300000 km/s to 700000 km/s, is equal 4.23143*10^22. It means that about 14.05% of total molecules of hydrogen have velocity more than 300000 km/s.

In record of CERN, it has been stated: "… ions together at close to the speed of light…"

The question is: Had all (100%) ions the velocity close to the speed of light?

Therefore, we have only two alternatives:

1. If the answer to above question is positive, then all reference books should apply the limited velocity of 300000 km/s for Maxwell–Boltzmann speed distribution function.

2. If the answer to above question is negative, then we can use from special theory of relativity only as a simulation model in which limited speed of light is an assumption of this model.

Of course, previous experiments showed that Newtonian mechanics is contrary to modern experimental results and is clearly a limited theory in which velocity of the particles in the Universe always remains less than the speed of light.
But, here there is a strange case and the interesting point. Because this temperature which has been generated by Physicists at CERN (1.6 trillion degrees Celsius), is approximately the boundary between using of the Maxwell-Boltzmann distribution and Maxwell–Jüttner distribution. It means that all particles (100%) in temperature less than 1.6 trillion degrees Celsius have velocity between 0 to less than 300000 km/s and we can still use from Maxwell-Boltzmann distribution instead of Maxwell–Jüttner distribution.

Thursday, January 21, 2016

Nice Quotes of Pythagoras and Immanuel Kant


Let us see some nice quotes of Pythagoras (582 B.C – 496 B.C) and Immanuel Kant (1724–1804).

Quotes of Pythagoras (582 B.C – 496 B.C)

A Greek Philosopher about Number and Control
 
 

- “All is number”

- “Number rules the Universe”

- “Number is the ruler of forms and ideas, and the cause of gods and daemons”

- “Number is the within of all thing”

- “No man is free who cannot control himself”

Quotes of Immanuel Kant (1724–1804)

A German Philosopher about Science and Universal Laws
 
 

- All human knowledge begins with intuitions, proceeds from thence to concepts, and ends with ideas.

- Give me matter, and I will construct a world out of it!

- In scientific matters ... the greatest discoverer differs from the most arduous imitator and apprentice only in degree, whereas he differs in kind from someone whom nature has endowed for fine art. But saying this does not disparage those great men to whom the human race owes so much in contrast to those whom nature has endowed for fine art. For the scientists' talent lies in continuing to increase the perfection of our cognitions and on all the dependent benefits, as well as in imparting that same knowledge to others; and in these respects they are far superior to those who merit the honor of being called geniuses. For the latter's art stops at some point, because a boundary is set for it beyond which it cannot go and which has probably long since been reached and cannot be extended further.

- The science of mathematics presents the most brilliant example of how pure reason may successfully enlarge its domain without the aid of experience

- Act only in accordance with that maxim through which you can at the same will that it become a universal law.