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Assignment 3 Unsolved Problems - Abstract Algebra | MATH 731, Assignments of Linear Algebra

University of Wisconsin (UW) - MilwaukeeLinear Algebra

Material Type: Assignment; Class: Abstract Algebra; Subject: Mathematical Sciences; University: University of Wisconsin - Milwaukee; Term: Fall 2008;

Typology: Assignments

Pre 2010

Uploaded on 09/02/2009

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MATH 731, FALL 2008
HOMEWORK SET 3
Due Friday, September 26 at noon
In these problems, you may assume we are working over F=C.
A. (i) Let Vbe the vector space of continuous complex-valued functions with domain [0,1].
Show Vdoes not become an inner product space when we define hf , gi=R1
0f(x)g(x)dx
for f, g V.
(ii) Explain how to alter (in a simple way) the definition of hf, g iin (i) to obtain an inner
product.
(iii) Verify that your altered definition does in fact yield an inner product.
B. Let h,ibe an inner product on the vector space Vand define k·k :VRby kvk=
phv, vi. Prove that k·k :VRis a norm, that is, prove the following three properties
hold.
(1) kvk>0 for vV, v 6= 0;
(2) kcvk=|c|kvkfor cF, v V;
(3) kv+wk kvk+kwkfor all v, w V.
Hint: You may need to use the Cauchy-Schwartz Inequality |hv , wi| kvkkwkfor all
v, w V. You can assume this fact.
(Four bonus points for proving the Cauchy-Schwartz Inequality.)

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Download Assignment 3 Unsolved Problems - Abstract Algebra | MATH 731 and more Assignments Linear Algebra in PDF only on Docsity!

MATH 731, FALL 2008

HOMEWORK SET 3

Due Friday, September 26 at noon

In these problems, you may assume we are working over F = C.

A. (i) Let V be the vector space of continuous complex-valued functions with domain [0, 1].

Show V does not become an inner product space when we define 〈f, g〉 =

0 f^ (x)g(x)^ dx for f, g ∈ V. (ii) Explain how to alter (in a simple way) the definition of 〈f, g〉 in (i) to obtain an inner product. (iii) Verify that your altered definition does in fact yield an inner product.

B. Let√ 〈 , 〉 be an inner product on the vector space V and define ‖·‖ : V → R by ‖v‖ = 〈v, v〉. Prove that ‖·‖ : V → R is a norm, that is, prove the following three properties hold. (1) ‖v‖ > 0 for v ∈ V, v 6 = 0; (2) ‖cv‖ = |c|‖v‖ for c ∈ F, v ∈ V ; (3) ‖v + w‖ ≤ ‖v‖ + ‖w‖ for all v, w ∈ V. Hint: You may need to use the Cauchy-Schwartz Inequality |〈v, w〉| ≤ ‖v‖‖w‖ for all v, w ∈ V. You can assume this fact. (Four bonus points for proving the Cauchy-Schwartz Inequality.)