Math 360, Fall 2013, Assignment 3

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We admit, in geometry, not only infinite magnitudes, that is to say, magnitudes greater than any assignable magnitude, but infinite magnitudes infinitely greater, the one than the other. This astonishes our dimension of brains, which is only about six inches long, five broad, and six in depth, in the largest heads.

- Voltaire

Carefully define the following terms, then give one example and one non-example of each:

  1. Isomorphism.
  2. Isomorphic.
  3. Structural property.
  4. Identity element.
  5. Group.
  6. Inverse element.
  7. Abelian group.

Carefully state the following theorems (you need not prove them):

  1. Uniqueness of identity element.
  2. Left and right cancellation laws.

Solve the following problems:

  1. Section 3, problems 2, 3, 4, 8, 9, 10, and 17.
  2. Section 4, problems 3, 4, 5, 6, 10, 11, 12, and 13.
--------------------End of assignment--------------------

Questions:

Solutions:

  1. Isomorphism.

    Definition:

    An isomorphism from a binary structure \((A,*)\) to another binary structure \((B,\circ)\) is a function \(\varphi:A\rightarrow B\) such that \(\varphi\) is bijective, and:

    \(\forall x,y \in A: \varphi(x*y) = \varphi(x)\circ \varphi(y)\)

    Example:

    Take the binary structures (from class) of \((\mathbb{Z}_n,+_n)\) and \((U_n,\cdot)\). The function \(\varphi:\mathbb{Z}_n \rightarrow U_n\) given by \(\varphi([x]) = \omega^x\), where \(x\in\mathbb{Z}\) and \(\omega = \cos\frac{2\pi}{n} + i\sin\frac{2\pi}{n}\), is an isomorphism.

    Non-Example:

    The function \(f\)from the binary structure \((\mathbb{Q},+)\) to \((\mathbb{R},+)\) given by \(f(x) = x\) is not an isomorphism, because it is not surjective. It does meet the other two requirements for an isomorphism.

  2. Isomorphic

    Definition:

    Two binary structures are isomorphic if there is an isomorphism between them.

    Example:

    \((\mathbb{Z}_n,+_n)\) is isomorphic to \((U_n,\cdot)\).

    Non-Example:

    \((\mathbb{Q},+)<\math> is not isomorphic to <math>(\mathbb{R},+)\).

  3. Structural Property

    Definition:

    A structural property is a property that is preserved under isomorphism. So if we have two isomorphic binary structures \((A,*)\) and \((B,\circ)\), with an isomorphism \(\varphi:A\rightarrow B\), and we have a property of binary structures (i.e. a proposition) \(P\), then \(P\) is a structural property if:

    \(P(A,*) \leftrightarrow P(B,\circ)\)

    Example:

    Non-Example:

  4. Identity Element

    Definition:

    Example:

    Non-Example:

  5. Group

    Definition:

    Example:

    Non-Example:

  6. Inverse Element

    Definition:

    Example:

    Non-Example:

  7. Abelian Group

    Definition:

    Example:

    Non-Example: