If necessary refer to the next essays.

----------------------------------------------------------------------------------------------------------------------------

Also refer to the next.

Energy of language   2015

Preparation for the energy of language   2015

--------------------------------------------------------------------------------------------------------------------------

1. 

Language

Language and Spacetime 

Language

Definition for the Child who Lost the World 

TANAKA Akio

Postscript

[Referential note / November 29, 2007]

For Authentication of Solidity 

[Definition added / November 3, 2008]

Definition 10, the part of is newly added.

2. 

Human sense

TANAKA Akio

24 July 2013

atbankofdam

1. Through natural language, in human being, occurred the electrical signal by eye or ear. These complex situations are beyond this paper’s limits.

2. Language is a physical object as signal and its transmission. At this circumstances, language must be recognised to be the existence that has finite time.

3. An apple on the desk gradually becomes rotten by passing the time very after the crop in the orchard. #0

4. Like an apple, language has passing physical time in oneself.

5. Language is metamorphosed  by the time progressing.  #1

6. Language includes the outer world from human being to universe. At this declaration, I recall Blaise Pascal’s Pensées. XXXIII. PROOFS OF JESUS CHRIST 308 The infinite distance between body and mind symbolizes the infinitely more infinite distance between mind and charity, for charity is supernatural.(Translated by A.J. Krailsheimer, 1966) #2

7. Language’s time goes freely from the present to the future or the present to the past. #3

8. Language symbolises the time from finiteness to infinity. #4

9. Human being recognises this vast language world perfectly. #5

References

#0 For WITTGENSTEIN Ludwig Position of Language / December 10, 2005 – August 3, 2012 / Sekinan Research Field of Language

#1 Time of Word / Complex Manifold Deformation Theory / January 1, 2009 / sekinanlogos

#2 PASCAL PENSÉES. Translated with an introduction by A.J. Krailsheimer. PENGUIN BOOKS 1966.

#3 Escalator language and Time For SHINRAN’s Idea and BOHDISATTVA / Escalator Language Theory / December 16, 2006 / Sekinan Research Field of Language

#4 From Finiteness to Infinity on Language / Topological Group Theory / February 1, 2009 / sekinanlogos

#5 Understandability of Language / Complex Manifold Deformation Theory /January 9, 2009 / sekinanlogos

Source: https://atbankofdam.wiki.zoho.com/Macro-Time-and-Micro-Time.html

To be continued.

Author. 

3. 

Signal

4. 

Nerve

5. 

Method

Manuscript of Quantum Theory for Language written in spring 2003 was roughly designed at a days I was in

hospital by pneumonia half a month in October 2002, when I always saw the river and the mountains west end of Tokyo. I was the very  reviewing life time for my research work.

My poor study was restricted in a narrow field of Chinese classical linguistics mainly developed in the late Qing dynasty the latter half of the 19th century,represented by DUAN Yucai, WANG Niansun, WANG Yingzhi, my favourite WANG Guowei and so forth.

So I determined that my approach to language was only in it and it was the most intimate for me at that time and probably herein after considering my tiny accumulation of study.

.......................................................................................

Chinese belongs to the isolated language.

In Chinese one character has one meaning and becomes a word in classical usage. Modern Chinese has many words that contain two or over two characters for one meaning, but basically almost all the characters have still classical one-character-one-meaning usage at the root of language.

Shuowenjezi Zhu written by DUAN Yucai typically shows some 2,000 year history of characters and their meanings.

Modern Chinese precisely said by Hanyu is one language of the over 50 languages officially recognized at the research, and I only know several language's grammars by the field work by linguists.

National Minority Languages in China   2004

 Xixiayu is a very interesting for me resembling the Hanyu and in the late 20th century the language was deciphered by Japanese linguist NISHIDA Tatsuo.

These language or character's situation especially of ideogram has become my study's foundation.

...................................................................

7.

Quantum group 2

In 2008 I wrote on Quantum group at studying Kac-Moody-Lie Algebra.

.....................................................................

Kac-Moody Lie Algebra

Note 2

Quantum Group

TANAKA Akio

1

Base field     K

Finite index set     I

Square matrix that has elements by integer     A = ( a_ij )_{i, j ∈ I}

Matrix that satisfies the next is called Cartan matrix.

i, j ∈ I

(1) a_ii = 2

(2) a_ij ≤ 0  ( i ≠j )

(3) a_ij = 0 ⇔ a_ji = 0

2

Cartan matrix     A = (a_ij)_i, j ∈I

Family of positive rational number    {d_i}_i∈I

Arbitrary i, j∈I    d_ia_ij = d_ja_ji

A is called symmetrizable.

3

Finite dimension vector space     h

Linearly independent subset of h     {h_i}_i∈I

Dual space of h     h*= Hom_K (h, K )

Linearly independent subset of h*     {α_i} _i∈I

Φ = {h, {h_i}_i∈I, {α_i} _i∈I }

Cartan matrix A = {α_i(h_i)} _{I, j∈I}

Φis called fundamental root data of A that is Cartan matrix.

4

Symmetrizable Cartan matrix    A = (a_ij)_i, j ∈I

Fundamental root data     {h, {h_i}_i∈I, {α_i} _i∈I }

E = α_i ⊂h*

Family of positive rational number     {d_i}_i∈I

Symmetry bilinear form over E     ( , ) : E×E → K     ( (α_i ,α_j ) = d_ia_ij )

The form is called standard form.

5

n-dimensional Euclid space    Rⁿ

Linear independent vector     v₁, …, v_n

Lattice of Rⁿ     m₁v₁+ … +m_nv_n     ( m₁, …, m_n ∈ Z )

Lattice of h     h_Z

6

From the upperv3, 4 and 5, the next three components are defined.

(Φ, ( , ), h_Z )

When the components satisfy the next, they are called integer fundamental root data.

 i ∈ I

(1)  ∈ Z

(2) α_i ( h_z ) ⊂ Z

(3) t_i :=  h_i ∈ h_z

7

Vector space over K     A

Bilinear product over K     A×A → A

When A is ring, it is called associative algebra.

8

Integer     m

t similarity of m    [m]_t

[m]_t = t^m-t^-m / t- t^-1

Integer   m, n   m≧n≧0

Binomial coefficient     (^m_n)

t similarity of m!     [m]_t! = [m]_t! [m-1]_t!...[1]_t

t similarity of (^m_n)    [^m_n]_t = [m]_t! / [n]_t! [m-n]_t!

[^m₀] = [^m_m]_t = 1

8

Integer fundamental root data that has Cartan matrix A = ( a_ij )_{i, j ∈ I}

      Ψ = ((h, {h_i}_i∈I, {α_i} _i∈I ), ( , ), h_z )

Generating set     {K^h}_h∈hz ∪{E_i, F_i}_i∈I

Associative algebra U over K (q), that is defined the next relations, is called quantum group associated with Ψ.

(1) k^hk^h’ = k^h+h’     ( h, h’∈h_Z )

(2) k⁰ = 1

(3) K^hE_iK^-h = q^αi(h)E_i    ( h∈h_Z , i∈I )

(4) K^hF_iK^-h = q^αi(h)F_i   ( h∈h_Z , i∈I )

(5) E_i F_j – F_jE_i = _ij  K_i - K_i^-1 / q_i – q_i^-1     ( i , j∈I )

(6) ^p [^1-aij_p]_qiE_i^1-aij-pE_jE_i^p = 0     ( i , j∈I , i ≠j )

(7) ^p [^1-aij_p]_qiF_i^1-aij-pF_jF_i^p = 0     ( i , j∈I , i ≠j )

[Note]

Parameter q in K is thinkable in connection with the concept of at the paper Place where Quantum of Language exists / 27 /.

Refer to the next.

Place where Quantum of Language exists / Tokyo July 18, 2004

Tokyo February 9, 2008

Sekinan Research Field of Language

www.sekinan.org

Read more: https://srfl-lab.webnode.com/news/kac-moody-lie-algebra-note-2-quantum-group/

........................................................................................

In 2004 I wrote the paper named Place where Quantum of Language exists.

11.

Symmetry 2

Symmetry seems to be related with two elements of language universals, distance and time.

Refer to the  next.

Distance Theory Algebraically Supplemented Brane Simplified Model 1 Bend 2007

...............................................................................

Distance Theory Algebraically Supplemented

Brane Simplified Model

1

Bend

TANAKA Akio

1

2

Quantum and anti-quantum have reverse direction.

3

Quantum and anti-quantum are in the shape of strings that are separated parallel longitude L apart.

4

Quantum and anti-quantum are in <AdS₅ ( 5-dimensional anti-deSitter ) space>.

5

Left side of quantum and anti-quantum is on .

6

Quantum starts from r_a in AdS₅ space and returns r_b in AdS₅ space.

r_a and r_b are equal longitude from D3 brane.

7

Quantum’s nearest point to D3 brane is r_z.

r_z’ is 1/2 of the longitude from r_a to r_b.

8

At the paper Spacetime Symmetry and Escalator Brane in Escalator Language Theory, language goes from r_a to rz and in reverse movement to r_b.

9

At the paper Actual Language and Imaginary Language, is from r_a to r_z and is from r_z to r_b.

10

We see real language that is upper side of r_z-r_z’. Imaginary language is hidden under side of r_z-r_z’ in our life.

11

At the paper Mirror Language, imaginary language is mirror language of real language.

12

Distance of language is regarded as the longitude from r_a ( or r_b ) to D3 brane in AdS₅ space. 

[Reference]

Escalator Language Theory / 2 Turning Point of Time / Tokyo December 22, 2006

Tokyo October 17, 2007

Sekinan Research Field of Language

www.sekinan.org

Read more: https://srfl-collection.webnode.com/news/distance-theory-algebraically-supplemented-brane-simplified-model-continuation-of-escalator-language-theory-1-bend-2007/

Distance is one of the most important elements of my language model of language universals. For this element algebraic approach seems to be   clearer description to the model. Refer to the next paper.

14

Symmetry 3

On symmetry I wrote Symmetry Flow Language and Symmetry Flow language 2 in 2007.

Symmetry Flow Language 2

2

Time Shift of Meaning in Moduli Space

7^th for KARCEVSKIJ Sergej

TANAKA Akio

1 Word has variation of meaning in accordance with time shift in space.

Refer to the following papers.

Language and Spacetime   Structure of Word   Tokyo April 6, 2007

Language and Spacetime   Description of Meaning   Tokyo April 16, 2007

Language and Spacetime   Shift of Time   Tokyo April 20, 2007

Symmetry Flow Language   Meaning Variation and Time Shift in Word as Homotopy   Tokyo May 17, 2007

2 Space that is deformed successively is described by parameter that is called moduli.

3 Set M consists of all of moduli.

4 Moduli space M (M) is presented for variation of word’s meaning.

5 Parameter t is presented for time shift of meaning in word.

6 Calabi-Yau manifold K has two moduli that are deformation of complex structure and Kähler manifold. Moduli have symmetry that is called Mirror symmetry.

7 K’s Ricci tensor is the following.

R_ij¯ = 0   i is regular coordinate. j¯ is non-regular coordinate.

Refer to the following paper.

Language and Spacetime   Construction of Spacetime   Especially on Transformation with Boundary for Dimensions   Tokyo April 24, 2007

8 Replaced two moduli in Calabi-Yau manifold K is called reflection Calabi-Yau manifold K~.

Refer to the following paper.

Mirror Language   Tokyo June 10, 2006

9 In K, Kähler manifold, n-dimensional toric manifold Pⁿ is presented.

Complex torus of Kähler’s form ω described by polar coordinates is the following.

ω = ∑_i dz_i ∧ dz⁻_i = ∑_i d|z_i|² ∧ dθ_i

P¹ with line bundle’s direct sum becomes resolved conifold.

10 Conifold’s toric graph has line segment that has the longitude | z₁ |²+ | z₂ |² = r. r is parameter of conifold.

11 Parameter r becomes parameter t that is described as complex.

12 Resolved conifold that has parameter t = 0 and is deformed becomes deformed conifold that has S³.

13 Parameter t of deformed conifold S³ means time of word’s meaning variation in language.

14 Deformed conifold S³ means word in language.

15 P¹× P¹ becomes square that is connected by world sheets.

16 P¹× P¹ means sentence in language.

Refer to the following paper.

Cube Theory   Structure of Cube   Tokyo March 25, 2006

Cube Theory   Cube Word   Hakuba April 1, 2006

Tokyo May 23, 2007

Sekinan Research Field of Language

Symmetry Flow Language 2 Time Shift of Meaning in Moduli Space 7th for KARCEVSKIJ Sergej

Symmetry Flow Language 2 Boundary, Deformation and Torus as Language

Symmetry Flow Language 2 Contents

Symmetry Flow Language Meaning Variation and Time Shift in Word as Homotopy For WANG Guowei and KARCEVSKIJ Sergej

Symmetry Flow Language Simplex, Simplicial Complex and Polyhedron

Symmetry Flow Language Homology on Language

Symmetry Flow Language Riemannian Metric, Flow and Entropy

Symmetry Flow Language Premise for Symmetry Flow in Language

Symmetry Flow Language Contents

Language and Spacetime Time Flow in Word For KOHARI Akihiro and His Time

Language and Spacetime Stability of Language

Language and Spacetime Construction of Spacetime Especially on Transformation with Boundary for Dimensions

Language and Spacetime Shift of Time From SAPIR Edward to KAWAMATA Yujiro

Language and Spacetime Description of Meaning 6th Time For KARCEVSKIJ Sergej

Language and Spacetime Generation of Sentence For WANG Guowei and CELAN Paul

Language and Spacetime Structure of Word From KARCEVSKIJ to MACLANE

Language and Spacetime Word Containing Time and 4 Dimensional Sphere Dedicated to MAC LANE Saunders

Language and Spacetime Language Definition for the Child who Lost the World

Language and Spacetime Contents

Relation between Language and Time
1 Language   Definition for the Child who Lost the World
2 Word Containing Time and 4 Dimensional Sphere
 
3 Structure of Word

4 Generation of Sentence
 
5 Description of Meaning
 <6th Time for KARCEVSKIJ Sergej>
6 Shift of Time
 
7 Construction of Spacetime   
   Especially on Transformation with boundary for  Dimensions
8 Stability of Language
9 Time Flow in Word
 
    

Two papers text are the next.

Language and Spacetime Word Containing Time and 4 Dimensional Sphere Dedicated to MAC LANE Saunders

Read more: https://srfl-paper.webnode.com/products/language-and-spacetime-word-containing-time-and-4-dimensional-sphere-dedicated-to-mac-lane-saunders/

Language and Spacetime Time Flow in Word For KOHARI Akihiro and His Time

Read more: https://srfl-paper.webnode.com/products/language-and-spacetime-time-flow-in-word-for-kohari-akihiro-and-his-time/

-------------------------------------------------------------------------------------------------------------------------------

What is signal? A mathematical model of nerve  Preparation 1-15

is over 

29 December 2018

-------------------------------------------------------------------------------------------------------------------------------

1.
Generation
From where language is born?

Signal generates language as the Morse code generates letters and language.

But language does not generate signal code because language has not electric energy.

It maybe that signal is the root of language.Truly or not?

What is signal?

What is generation?

I  once wrote a trial paper, Generation Theorem in 2008.

Text is the below.

.....................................................................................................

von Neumann Algebra 2

Note

Generation Theorem 

TANAKA Akio

[Main Theorem]

Commutative von Neumann Algebra N is generated by only one self-adjoint operator.

[Proof outline]

N is generated by countable {A_n}.

A_n = *A_n

Spectrum deconstruction       A_n = ∫¹_-1  λdE_λ⁽ⁿ⁾

C*algebra that is generated by set { E_λ⁽ⁿ⁾ ; λ∈Q∩[-1, 1], n∈N}     A

A’’ = N

A is commutative.

I∈A

Existence of compact Hausdorff space Ω = Sp(A  )

A   = C(Ω)

Element corresponded with f∈C(Ω)     A∈A

N is generated by A.

[Index of Terms]

|A|Ⅲ7-5

|| . ||Ⅱ2-2

||x||Ⅱ2-2

Ⅱ2-1

*algebraⅡ3-4

*homomorphismⅡ3-4

*isomorphismⅡ3-4

*subalgebraⅡ3-4

adjoint spaceⅠ12

algebraⅠ8

axiom of infinityⅠ1-8

axiom of power setⅠ1-4

axiom of regularityⅠ1-10

axiom of separationⅠ1-6

axiom of sumⅠ1-5

B ( H )Ⅱ3-3

Banach algebraⅡ2-6

Banach spaceⅡ2-3

Banach* algebraⅡ2-6

Banach-Alaoglu theoremⅡ5

basis of neighbor hoodsⅠ4

bicommutantⅡ6-2

bijectiveⅡ7-1

binary relationⅡ7-2

boundedⅡ3-3

bounded linear operatorⅡ3-3

bounded linear operator, B ( H )Ⅱ3-3

C* algebraⅡ2-8

cardinal numberⅡ7-3

cardinality, |A|Ⅱ7-5

characterⅡ3-6

character space (spectrum space), Sp( )Ⅱ3-6

closed setⅠ2-2

commutantⅡ6-2

compactⅠ3-2

complementⅠ1-3

completeⅡ2-3

countable setⅡ7-6

countable infinite setⅡ7-6

coveringⅠ3-1

commutantⅡ6-2

D ( )Ⅱ3-2

denseⅠ9

dom( )Ⅱ3-2

domain, D ( ), dom( )Ⅱ3-2

empty setⅠ1-9

equal distance operatorⅡ4-1

equipotentⅢ7-1

faithfulⅡ3-4

Gerfand representationⅡ3-7

Gerfand-Naimark theoremⅡ4

HⅡ3-1

Hausdorff spaceⅠ5

Hilbert spaceⅡ3-1

homomorphismⅡ3-4

idempotent elementⅡ9-1

identity elementⅡ9-1

identity operatorⅡ6-1

injectiveⅢ7-1

inner productⅡ2-1

inner spaceⅠ6

involution*Ⅰ10

linear functionalⅡ5-2

linear operatorⅡ3-2

linear spaceⅠ6

linear topological spaceⅠ11

locally compactⅠ3-2

locally vertexⅠ11

NⅢ3-8

N₁Ⅲ3-8

neighborhoodⅠ4

normⅡ2-2

normⅡ3-3

norm algebraⅡ5

norm spaceⅡ2-2

normalⅡ2-4

normalⅡ3-4

open coveringⅠ3-2

open setⅠ2-2

operatorⅡ3-2

ordinal numberⅡ7-3

productⅠ8

product setⅡ7-2

r( )Ⅱ2

R ( )Ⅱ3-2

ran( )Ⅱ3-2

range, R ( ), ran( )Ⅱ3-2

reflectiveⅠ12

relationⅢ7-2

representationⅡ3-5

ringⅠ7

Schwarz’s inequalityⅡ2-2

self-adjointⅡ3-4

separableⅡ7-7

setⅠ7

spectrum radius r( )Ⅱ2

Stone-Weierstrass theoremⅡ1

subalgebraⅠ8

subcoveringⅠ3-1

subringⅠ7

subsetⅠ1-3

subspaceⅠ2-3

subtopological spaceⅠ2-3

surjectiveⅢ7-1

system of neighborhoodsⅠ4

τ^s topologyⅡ7-9

τ^w topologyⅡ7-9

the second adjoint spaceⅠ12

topological spaceⅠ2-2

topologyⅠ2-1

total order in strict senseⅡ7-3

ultra-weak topologyⅢ6-4

unit sphereⅡ5-1

unitaryⅡ3-4

vertex setⅡ3-3

von Neumann algebraⅡ6-3

weak topologyⅡ5-3

weak * topologyⅡ5-3

zero elementⅡ9-1

[Explanation of indispensable theorems for main theorem]

ⅠPreparation

<0 Formula>

0-1 Quantifier

(i) Logic quantifier  ┐ ⋀  ⋁  → ∀ ∃

(ii) Equality quantifier  =

(iii) Variant term quantifier

(iiii) Bracket  [  ]

(v) Constant term quantifier

(vi) Functional quantifier

(vii) Predicate quantifier

(viii) Bracket  (   )

(viiii) Comma  ,

0-2 Term defined by induction

0-3 Formula defined by induction 

<1 Set>

1-1 Axiom of extensionality     ∀x∀y[∀z∈x↔z∈y]→x=y.

1-2 Set     a, b

1-3 a is subset of b.    ∀x[x∈a→x∈b].Notation is a⊂b. b-a = {x∈b ; x∉a} is complement of a.

1-4 Axiom of power set     ∀x∃y∀z[z∈y↔z⊂x]. Notation is P (a).

1-5 Axiom of sum     ∀x∃y∀z[z∈y↔∃w[z∈w∧w∈x]]. Notation is ∪a.

1-6 Axiom of separation     x, t= (t1, …, tn), formula φ(x, t)     ∀x∀t∃y∀z[z∈y↔z∈x∧φ(x, t)].

1-7 Proposition of intersection     {x∈a ; x∈b} = {x∈b; x∈a} is set by axiom of separation. Notation is a∩b.

1-8 Axiom of infinity     ∃x[0∈x∧∀y[y∈x→y∪{y}∈x]].

1-9 Proposition of empty set     Existence of set a is permitted by axiom of infinity. {x∈a; x≠x} is set and has not element. Notation of empty set is 0 or Ø.

1-10 Axiom of regularity     ∀x[x≠0→∃y[y∈x∧y∩x=0].

<2 Topology>

2-1

Set     X

Subset of power set P(X)     T

T that satisfies next conditions is called topology.

(i) Family of X’s subset that is not empty set     <A_i; i∈I>, A_i∈T→∪_i∈I Ai is belonged to T.       

(ii) A, B ∈T→ A∩B∈T

(iii) Ø∈T, X∈T.

2-2

Set having T, (X, T), is called topological space, abbreviated to X, being logically not confused.

Element of T is called open set.

Complement of Element of T is called closed set.

2-3

Topological space     (X, T)

Subset of X     Y

S ={A∩Y ; A∈T}

Subtopological space     (Y, S)   

Topological space is abbreviated to subspace.

<3 Compact>

3-1

Set     X

Subset of X     Y

Family of X’s subset that is not empty set     U = <U_i; i∈I>

U is covering of Y.     ∪U = ∪_i∈I ⊃Y

Subfamily of U 　　V = <U_i; i∈J > (J⊂I)

V is subcovering of U.

3-2

Topological space     X

Elements of U     Open set of X

U is called open covering of Y.

When finite subcovering is selected from arbitrary open covering of X, X is called compact.

When topological space has neighborhood that is compact at arbitrary point, it is called locally compact.

<4 Neighborhood>

Topological space     X

Point of X     a

Subset of X     A

Open set    B

a∈B⊂A

A is called neighborhood of a.

All of point a’s neighborhoods is called system of neighborhoods.

System of neighborhoods of point a     V(a)

Subset of V(a)     U

Element of U     B

Arbitrary element of V(a)     A

When B⊂A, U is called basis of neighborhoods of point a.

<5 Hausdorff space>

Topological space X that satisfies next condition is called Hausdorff space.

Distinct points of X     a, b        

Neighborhood of a     U

Neighborhood of b     V

U∩V = Ø

<6 Linear space>

Compact Hausdorff space     Ω

Linear space that is consisted of all complex valued continuous functions over Ω     C(Ω)

When Ω is locally compact, all complex valued continuous functions over Ω, that is 0 at infinite point is expressed by C₀(Ω).

<7 Ring>

Set     R

When R is module on addition and has associative law and distributive law on product, R is called ring.

When ring in which subset S is not φ satisfies next condition, S is called subring.

a, b∈S

ab∈S

<8 Algebra>

C(Ω) and C₀(Ω) satisfy the condition of algebra at product between points.

Subspace     A ⊂C(Ω) or A ⊂C₀(Ω)

When A is subring, A is called subalgebra.

<9 Dense>

Topological space     X

Subset of X     Y

Arbitrary open set that is not Ø in X     A

When A∩Y≠Ø, Y is dense in X.

<10 Involution>

Involution * over algebra A over C is map * that satisfies next condition.

Map * : A∈A ↦ A*∈A

Arbitrary A, B∈A, λ∈C

(i) (A*)* = A

(ii) (A+B)* = A*+B*

(iii) (λA)* =λ^-A*

(iiii) (AB)* = B*A*

<11 Linear topological space>

Number field     K

Linear space over K     X

When X satisfies next condition, X is called linear topological space.

(i) X is topological space

(ii) Next maps are continuous.

(x, y)∈X×X ↦ x+y∈X

(λ, x)∈K×X ↦λx∈X

Basis of neighborhoods of X’ zero element 0     V

When V⊂V is vertex set, X is called locally vertex.

<12 Adjoint space>

Norm space     X

Distance     d(x, y) = ||x-y|| (x, y∈X )

X is locally vertex linear topological space.

All of bounded linear functional over X    X*

Norm of f ∈X*      ||f||

X* is Banach space and is called adjoint space of X.

Adjoint space of X* is Banach space and is called the second adjoint space.

When X = X*, X is called reflective.

ⅡIndispensable theorems for proof

<1 Stone-Weierstrass Theorem>

Compact Hausdorff space     Ω

Subalgebra     A ⊂C(Ω)

When A ⊂C(Ω) satisfies next condition, A  is dense at C(Ω).

(i) A  separates points of Ω.

(ii) f∈A →　f^－∈A

(iii) 1∈A

Locally compact Hausdorff space        Ω

Subalgebra     A ⊂C₀(Ω)

When A ⊂C₀(Ω) satisfies next condition, A  is dense at C₀(Ω).

(i) A  separates points of Ω.

(ii) f∈A → f^－∈A

(iii) Arbitrary ω∈A ,  f∈A ,  f(ω) ≠0

<2 Norm algebra>

C* algebra     A

Arbitrary element of A     A

When A is normal, lim_n→∞||An||^1/n = ||A||

lim_n→∞||An||^1/n  is called spectrum radius of A. Notation is r(A).

[Note for norm algebra]

<2-1>

Number field     K = R or C

Linear space over K     X

Arbitrary elements of X     x, y

< x, y>∈K satisfies next 3 conditions is called inner product of x and y.

Arbitrary x, y, z∈X, λ∈K

(i) <x, x> ≧0,  <x, x> = 0 ⇔x = 0

(ii) = 

(iii) , λy+z> = λ, y> + , z>

Linear space that has inner product is called inner space.

<2-2>

||x|| = <x, x>^1/2

Schwarz’s inequality

Inner space     X

|<x, y>|≦||x|| + ||y||

Equality consists of what x and y are linearly dependent.

||・|| defines norm over X by Schwarz’s inequality.

Linear space that has norm || ・|| is called norm space.

<2-3>

Norm space that satisfies next condition is called complete.

u_n∈X (n = 1, 2,…), lim_n, m→∞||u_n – u_m|| = 0

u∈X   lim_n→∞||u_n – u|| = 0

Complete norm space is called Banach space.

<2-4>

Topological space X that is Hausdorff space satisfies next condition is called normal.

Closed set of X     F, G

Open set of X     U, V

F⊂U, G⊂V, U∩V = Ø

<2-5>

When A  satisfies next condition, A  is norm algebra.

A  is norm space.

∀A, B∈A

||AB||≦||A|| ||B||

<2-6>

When A is complete norm algebra on || ・ ||, A is Banach algebra.

<2-7>

When A is Banach algebra that has involution * and || A*|| = ||A|| (∀A∈A),  A is Banach * algebra.

<2-8>

When A is Banach * algebra and ||A*A|| = ||A||²(∀A∈A) , A is C*algebra.

<3 Commutative Banach algebra>

Commutative Banach algebra     A

Arbitrary A∈A

Character X

|X(A)|≦r(A)≦||A||

[Note for commutative Banach algebra]  (   ) is referential section on this paper.

<3-1 Hilbert space>

Hilbert space     inner space that is complete on norm ||x||      Notation is H.

<3-2 Linear operator>

Norm space     V

Subset of V     D

Element of D     x

Map T : x → Tx∈V

The map is called operator.

D is called domain of T. Notation is D ( T ) or dom T.

Set A⊂D

Set TA     {Tx : x∈A}

TD is called range of T. Notation is R (T) or ran T.

α , β∈C,   x, y∈D ( T )

T(αx+βy) = αTx+βTy

T is called linear operator.

<3-3 Bounded linear operator>

Norm space     V

Subset of V     D

sup{||x|| ; x∈D} < ∞

D is called bounded.

Linear operator from norm space V to norm space V₁      T

D ( T ) = V

||Tx||≦γ (x∈V )  γ > 0

T is called bounded linear operator.

||T || := inf {γ : ||Tx||≦γ||x|| (x∈V)} = sup{||Tx|| ; x∈V, ||x||≦1} = sup{; x∈V,  x≠0}

||T || is called norm of T.

Hilbert space     H ,K

Bounded linear operator from H  to K     B (H, K )

B ( H ) : = B ( H, H )

Subset K ⊂H

Arbitrary x, y∈K, 0≦λ≦1

λx + (1-λ)y ∈K

K  is called vertex set.

<3-4 Homomorphism>

Algebra A  that has involution*       *algebra

Element of *algebra     A∈A

When A = A*, A is called self-adjoint.

When A *A= AA*, A is called normal.

When A A*= 1, A is called unitary.

Subset of A     B

B * := B*∈B

When B = B*, B is called self-adjoint set.

Subalgebra of A     B

When B is adjoint set, B is called *subalgebra.

Algebra     A, B

Linear map : A →B  satisfies next condition, π is called homomorphism.

π(AB) = π(A)π(B) (∀A, B∈A )

*algebra    A

When π(A*) = π(A)*, π is called *homomorphism.

When ker π := {A∈A ; π(A) =0} is {0},π is called faithful.

Faithful *homomorphism is called *isomorphism.

<3-5 Representation>

*homomorphism π from *algebra to B ( H ) is called representation over Hilbert space H of A .

<3-6 Character>

Homomorphism that is not always 0, from commutative algebra A  to C, is called character.

All of characters in commutative Banach algebra A  is called character space or spectrum space. Notation is Sp( A ).

<3-7 Gerfand representation>

Commutative Banach algebra     A

Homomorphism ∧: A →C(Sp(A))

∧is called Gerfand representation of commutative Banach algebra A.

<4 Gerfand-Naimark Theorem>

When A is commutative C* algebra, A  is equal distance *isomorphism to C(Sp(A)) by Gerfand representation.

[Note for Gerfand-Naimark Theorem]

<4-1 equal distance operator>

Operator     A∈B ( H )

Equal distance operator A     ||Ax|| = ||x|| (∀x∈H)

<4-2 Equal distance *isomorphism>

C* algebra      A

Homomorphism π

π(AB) = π(A)π(B) (∀A, B∈A )

*homomorphism   π(A*) = π(A)*

*isomorphism     { π(A) =0} = {0}

<5 Banach-Alaoglu theorem>

When X is norm space, (X*)₁ is weak * topology and compact.

[Note for Banach-Alaoglu theorem]

<5-1 Unit sphere>

Unit sphere X₁ := {x∈X ; ||x||≦1}

<5-2 Linear functional>

Linear space     V

Function that is valued by K     f (x)

When f (x) satisfies next condition, f is linear functional over V.

(i) f (x+y) = f (x) +f (y)   (x, y∈V)

(ii) f (αx) = αf (x)   (α∈K, x∈V)

<5-3 weak * topology>

All of Linear functionals from linear space X to K     L(X, K)

When X is norm space, X*⊂L(X, K).

Topology over X , σ(X, X*) is called weak topology over X.

Topology over X*, σ(X*, X) is called weak * topology over X*.

<6 *subalgebra of B ( H )>

When *subalgebra N of B ( H ) is identity operator I∈N , N ”= N is equivalent with τ^uw-compact.

[Note for *subalgebra of B ( H )]

<6-1 Identity operator>

Norm space     V

Arbitrary x∈V

Ix = x

I is called identity operator.

<6-2 Commutant>

Subset of C*algebra B (H)     A

Commutant of A     A ’

A ’ := {A∈B (H) ; [A, B] := AB – BA = 0, ∀B∈A }

Bicommutant of A     A ' ’’ := (A ’)’

A ⊂A ’’

<6-3 von Neumann algebra>

*subalgebra of C*algebra B (H)     A

When A  satisfies A ’’ = A  , A  is called von Neumann algebra.

<6-4 Ultra-weak topology>

Sequence of B ( H )     {A_α}

{A_α} is convergent to A∈B ( H )

Topology     τ

When α→∞, A_α →^τ A

Hilbert space     H

Arbitrary {x_n}, {y_n}⊂H

∑_n||x_n||² < ∞

∑_n||y_n||² < ∞

|∑_n<x_n, (A_α- A)y_n>| →0

A∈B ( H )

Notation is A_α →^uτ A

[ 7 Distance theorem]

For von Neumann algebra N over separable Hilbert space, N₁ can put distance on τ^s and τ^w topology.

[Note for distance theorem]

<7-1 Equipotent>

Sets     A, B

Map     f : A → B

All of B’s elements that are expressed by f(a) (a∈A)     Image(f)

a , a’∈A

When f(a) = f(a’) →a = a’, f is injective.

When Image(f) = B, f is surjective.

When f is injective and surjective, f is bijective.

When there exists bijective f from A to B, A and B are equipotent.

<7-2 Relation>

Sets     A, B

x∈A, y∈B

All of pairs <x, y> between x and y are set that is called product set between a and b.

Subset of product set A×B     R

R is called relation.

x∈A, y∈B, <x, y>∈R     Expression is xRy. 

When A =B, relation R is called binary relation over A.     

<7-3 Ordinal number>

Set     a

∀x∀y[x∈a∧y∈x→y∈a]

a is called transitive.

x, y∈a

x∈y is binary relation.

When relation < satisfies next condition, < is called total order in strict sense.

∀x∈A∀y∈A[x<y∨x=y∨y<x]

When a satisfies next condition, a is called ordinal number.

(i) a is transitive.

(ii) Binary relation ∈ over a is total order in strict sense.

<7-4 Cardinal number>

Ordinal number    α

α that is not equipotent to arbitrary β<α is called cardinal number.

<7-5 Cardinality>

Arbitrary set A is equipotent at least one ordinal number by well-ordering theorem and order isomorphism theorem.

The smallest ordial number that is equipotent each other is cardinal number that is called cardinality over set A. Notation is |A|.

When |A| is infinite cardinal number, A is called infinite set.

<7-6 Countable set>

Set that is equipotent to N     countable infinite set

Set of which cardinarity is natural number     finite set

Addition of countable infinite set and finite set is called countable set.

<7-7 Separable>

Norm space     V

When V has dense countable set, V is called separable.

<7-8 N₁>

von Neumann algebra     N   

A∈B ( H )

N₁ := {A∈N; ||A||≦1}

<7-9 τ^s and τ^w topology>

<7-9-1τ^s topology>

Hilbert space     H

A∈B ( H )

Sequence of B ( H )  {A_α}

{A_α} is convergent to A∈B ( H )

Topology     τ

When α→∞, A_α →^τ A

|| (A_α- A)x|| →0 ∀x∈H

Notation is A_α →^s A

<7-9-2 τ^w topology>

Hilbert space     H

A∈B ( H )

Sequence of B ( H )  {A_α}

{A_α} is convergent to A∈B ( H )

Topology     τ

When α→∞, A_α →^τ A

|A_α- A)y>| →0 ∀x, y∈H

Notation is A_α →^w A

<8 Countable elements>

von Neumann algebra N over separable Hilbert space is generated by countable elements.

<9 Only one real function>

For compact Hausdorff space Ω,C(Ω) that is generated by countable idempotent elements is generated by only on real function.

<9-1>

Set that is defined arithmetic・     S

Element of S     e

e satisfies a・e = e・a = a is called identity element.  

Identity element on addition is called zero element.

Ring’s element that is not zero element and satisfies a² = a is called idempotent element.

To be continued

Tokyo April 20, 2008

Sekinan Research Field of Language

www.sekinan.org

2

Generation 2

I also wrote a overview paper on generation in 2018.

Text is the following.

..............................................................................................

Read more: https://geometrization-language.webnode.com/products/quantum-language-between-quantum-theory-for-language-2004-and-generation-of-word-2008-adding-their-days-and-after/

3

Energy

Signal needs energy for dispatching messages to the world by hand power of flag semaphore, hand power and electricity of Mores code and light and electricity of  lighthouse.