Functional Analysis Note 3 Space / May 23, 2008

Functional Analysis

Note 3

Space 

TANAKA Akio

1 Linear space (Vector space)

Complex number field or real number field     Φ

Set     X

When X satisfies next condition, X is called linear space over Φ.

It is also called vector space over Φ.

Arbitrary elements of X     x, y

Sum of x and y      x + y

(i)

Arbitrary elements of X     x, y, z

x + y = y + x

(x+y)+z = x+(y+z)

(ii)

There exists one element that is called 0 in X.

Arbitrary x∈X

x+0 = x

(iii)

Arbitrary x∈X

There exists one element that is called –x in X.

x+(-x) = 0

(iiii)

Arbitrary α∈Φ

Arbitrary x∈X

αx that is called product of α and x is uniquely defined.

Arbitrary α, β∈Φ

Arbitrary x, y∈X

1x = x

(v)

(αβ)x = α(βx)

(vi)

α(x+y) = αx+αy

(α+β)x = αx+βx

1-1 Complex linear space

When Φ is complex number field, linear space over Φ is called complex linear space.

1-2 Real linear space

When Φ is real number field, linear space over Φ is called real linear space.

2 Linear subspace

Linear space     X

Subset that is not empty in X     M

M that satisfies next condition is called linear subspace of X.

(i)

x∈M

y∈M

x+y∈M

(ii)

x∈M

Arbitrary α∈Φ

αx∈M

3 Linear subspace spanned (Linear subspace generated)

Linear space     X

Element of X     x_i∈X ( i = 1, 2, …, n)

α₁x₁+α₂x₂+…+α_nx_n (α_i∈Φ, i = 1, 2, …, n) is called linear combination of x₁, x₂, …, x_n.

Subset that is not empty in X     S

All the sets of linear combinations of arbitrary finite elements     M

M is called linear subspace spanned by S.

It is also called linear subspace generated by S.

4 Normed space

Linear space     X

Element of X    x

Real number     ||x||

||x|| that satisfies next condition is called norm of x.

X is called normed space.

(i)

||x|| ≧0

||x|| = 0 ⇌ x = 0

(ii)

Arbitrary α∈Φ

Arbitrary x, y∈X

||αx|| =|α| ||x||

(iii)

||x+y|| ≦||x||+||y||

4-1 Complex normed space

When Φ is complex number field, normed space over Φ is called complex normed space.

4-2 Real normed space

When Φ is real number field, normed space over Φ is called real normed space.

5 Distance space

Normed space     X

X’s element is also called point.

Arbitrary points of X     x, y

When d(x, y) = ||x-y|| is defined, d(x, y) satisfies next 3 conditions for distance.

X is distance space.

(i)

d(x, y) ≧0,

d(x, y) = 0 ⇌ x = y

(ii)

d(x, y) = d(y, x)

(iii)

d(x, y) ≦d(x, z) = d(z, y)

6 Linear subspace

Normed space     X

Linear subspace of X     M

M is called linear subspace of normed space X.

6-1 Closed linear subspace

When M is linear subspace of normed space X and closed set, M is called closed linear subspace.

7 Closed linear subspace spanned (Closed linear subspace generated)

Normed space     X

Subset that is not empty in X     S

Linear subspace spanned by S     M

Closure of M is called closed linear subspace spanned by S.

It is also called closed linear subspace generated by S.

8 Banach space

Sequence {x_n} of normed space X satisfied lim_{m, n →∞} = 0, {x_n} is called Cauchy sequence.

When in normed space X, arbitrary Cauchy sequence is convergent to X’s point, X is called complete.

Complete normed space is called Banach space.

8-1 Complex Banach space

When X is complex normed space, Banach space is complex Banach space

8-2 Real Banach space

When X is real normed space, Banach space is real Banach space

9 Sequence space

Set that is consisted from all of n real numbers’ group (ξ₁, ξ₂, …, ξ_n)     Vⁿ

Two elements of Vⁿ     x = (ξ₁, ξ₂, …, ξ_n)   y = (η₁, η₂, …, η_n)

x+y := (ξ₁+η1, ξ₂+η₂, …ξ_n+η_n)

Real number     α

Element of Vⁿ       x = (ξ₁, ξ₂, …, ξ_n)

αx := (αξ₁, αξ₂, …, αξ_n)

Vⁿ becomes real linear space.

10 Euclid space

Set that is consisted from all of n real numbers’ group (ξ₁, ξ₂, …, ξ_n)     Vⁿ

x = (ξ₁, ξ₂, …, ξ_n)∈Vⁿ

||x|| := 

Vⁿ becomes complete eral normed space, i.e. real Banach space.

Vⁿ is called n dimensional Euclid space. Notation is Rⁿ.

11 Unitary space

Set that is consisted from all of n complex numbers’ group (ξ₁, ξ₂, …, ξ_n)     Kⁿ

In Kⁿ, 2 points x and y, sum x+y, product αx and norm ||x|| is similarly defined as Rⁿ.

Kⁿ becomes complex Banach space.

Kⁿ is called n dimensional unitary space.

12 Functional space

Bounded closed interval     [a, b]

Real valued continuous function defined at [a, b]     x(t)

All of x(t)     C[a, b]

By norm and completeness, C[a, b] is real Banach space.

Complex valued continuous function defined at [a, b]   x(t)

All of x(t)     C[a, b]

By operation, norm and completeness, C[a, b] is complex Banach space.

13 p power Lebesgue integrable real valued function

Interval     (a, b)

Real valued measurable function at (a, b)     x(t)

x(t) satisfies next condition, x(t) is called p power Lebesgue integrable.

∫^b_a| x(t)|^pdt < ∞

All of x(t)     L^P(a, b)

By operation, norm completeness, L^P(a, b) is real Banach space.

All of complex valued measurable functions at (a, b) is complex Banach space.

14 Essentially bounded real valued function

Interval     (a, b)

Real valued measurable function at (a, b)     x(t)

Set of measure 0     N⊂(a, b)

Complement of N at (a, b)     (a, b)∖N

When x(t) is sup_{t∈(a, b)∖N} | x(t)| < ∞, x(t) is essentially bounded.

All of measurable at (a, b) and essentially bounded real valued functions      L^∞(a, b)

By operation, norm completeness, L^∞ (a, b) is real Banach space.

All of measurable at (a, b) and essentially bounded complex valued functions is complex Banach space.

15 Inner product space

Complex linear space    X

Arbitrary 2 elements pair of X    {x, y}

Complex corresponded with {x, y}     (x, y)

When (x, y) satisfied next condition, (x, y) is called inner product between x and y.

(i) (x, x)≧0 ; x=0 and only itself (x, x) = 0

(ii) (x, y) = 

(iii) (x+z, y) = (x, y) + (z, y)

(iiii) (ax, y) = a (x, y) (a; complex number)

Space defined by inner product is called inner product space.

When a at (iiii) is real number and corresponded number pair is real number (x, y), X is called real product space.

16 Hilbert space

When inner product space X is complete on norm ||x|| = , X is called Hilbert space.

When X is real inner product space, X is called real Hilbert space.

Tokyo May 23, 2008

Sekinan Research Field of Language