Let A := C ( n ) </mrow> </msup> ( [ 0 , 1 ]

tomekmusicd9

tomekmusicd9

Answered question

2022-05-25

Let A := C ( n ) ( [ 0 , 1 ] ) be the set consisting of the n-times continuously differentiable complex-valued functions. Consider A with the norm
f := max 0 t 1 k = 0 n | f ( k ) ( t ) | k ! .
I want to show that A is a commutative Banach algebra and find its maximal ideal space.
I know that the following holds:
- for all f , g A: ( f g ) ( x ) = f ( x ) g ( x ) = g ( x ) f ( x ) = ( g f ) ( x );
- for all f , g , h A:
( ( f g ) h ) ( x ) = ( f g ) ( x ) h ( x ) = g ( x ) f ( x ) h ( x ) = f ( x ) ( g h ) ( x ) = ( f ( g h ) ) ( x )
- for all f , g , h A:
( f ( g + h ) ) ( x ) = f ( x ) ( g + h ) ( x ) = f ( x ) ( g ( x ) + h ( x ) ) = f ( x ) g ( x ) + f ( x ) h ( x ) = ( f g ) ( x ) + ( f h ) ( x ) = ( f g + f h ) ( x )
- hence ( g + h ) f = g f + h f;
- for all f , g A , α R:
( α ( f g ) ) ( x ) = α ( f g ) ( x ) = α f ( x ) g ( x ) = ( α f ) ( x ) g ( x ) = ( ( α f ) g ) ( x ) = f ( x ) α g ( x ) = ( f ( α g ) ) ( x )
Now, let f , g A, then we see that
f g = max 0 t 1 k = 0 n | ( f g ) ( k ) ( t ) | k ! = max 0 t 1 k = 0 n | j = 0 k ( k j ) f ( k j ) ( t ) g ( j ) ( t ) | k ! = max 0 t 1 k = 0 n | j = 0 k k ! j ! ( k j ) ! f ( k j ) ( t ) g ( j ) ( t ) | k ! max 0 t 1 k = 0 n j = 0 k | f k j ( t ) g k ( t ) | j ! ( k j ) ! = max 0 t 1 k = 0 n j = 0 k | f k j ( t ) ( k j ) ! g k ( t ) | j ! = ?
Obviously, I want to show that f g f g , but I dont know how to do this. Any hints?

Answer & Explanation

Hailee Henderson

Hailee Henderson

Beginner2022-05-26Added 12 answers

A typo slipped in; a k became j for no reason. Fixing that, you're almost there, re showing it's a Banach algebra:
= max 0 t 1 k = 0 n j = 0 k | f ( k j ) ( t ) ( k j ) ! g ( j ) ( t ) | j ! = max 0 t 1 j = 0 n | g ( j ) ( t ) | j ! k = j n | f ( k j ) ( t ) | ( k j ) ! = max 0 t 1 j = 0 n | g ( j ) ( t ) | j ! k = 0 n j | f ( k ) ( t ) | k ! max 0 t 1 j = 0 n | g ( j ) ( t ) | j ! k = 0 n | f ( k ) ( t ) | k ! = | | g | | | | f | | .
The maximal ideal space is [ 0 , 1 ] (that is, every complex homomorphism is evaluation at some point). You need to show that if I is an ideal and for every t [ 0 , 1 ] there exists f A with f ( t ) 0 then I = A. Look up the proof of the corresponding fact for C ( [ 0 , 1 ] ); exactly the same argument works here.

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