Advanced High-School Mathematics

(Tina Meador) #1

SECTION 4.2 Basics of Group Theory 239


a homomorphism of GL 2 (R) into the multiplicative group of non-
zero real numbers.


  1. (Really the same as Exercise 3) Let G be any group and fix an
    element x∈G. Prove that the mapping f : G → Gdefined by
    settingf(g) =xgx−^1 is an isomorphism ofGonto itself.

  2. LetAbe an Abeliangroup and letf :A→B be asurjective
    homomorphism, where B is also a group. Prove that B is also
    Abelian.

  3. Letf :G→H be a homomorphism of groups and setK ={g∈
    G|f(g) =eH}, whereeH is the identity ofH. Prove thatK is a
    subgroup ofG.^13

  4. LetX={ 1 , 2 , 3 , ..., n}, wherenis a positive integer. Recall that
    we have the group (2X,+), where, as usual, 2X is the power set of
    Xand + is symmetric difference (see page 194). Definef : 2X→
    {− 1 , 1 }(where{± 1 }is a group with respect to multiplication) by
    setting


f(A) =





+1 if|A|is even
− 1 if|A|is odd.

Prove thatf is a homomorphism.


  1. LetGbe a group and definef :G→Gby settingf(g) =g−^1.


(a) Show thatf is a bijection.
(b) Under what circumstances isf a homomorphism?


  1. Prove that the automorphism groups of the graphs on page 207
    (each having four vertices) are not isomorphic.

  2. Let R be the additive group of real numbers and assume that
    f:R→Ris a function which satisfiesf(x−y) =f(x)−f(y), for
    0 < x, y∈R. Prove thatf:R→Ris a homomorphism.


(^13) This subgroup ofGis usually called thekernelof the homomorphismf.

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