Chapter 2 T/F

(a) If A∩B=∅, then either A=∅ or B=∅.

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(c) If x∈A\B ,then x∈A or x∉B.

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A function f:A→B is surjective if dom f = A.

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A function from A to B is a nonempty relation f ⊆A×B such that if (a,b)∈ f and(a,c)∈ f, then b=c.

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A nonempty set S is countable iff there exists an injection f : → S.

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A relation between A and B is an ordered subset of A × B.

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A set S is denumerable if there exists a bijection f : → S.

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Every subset of a denumerable set is denumerable.

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If R is a relation on S, then {y ∈ S: yRx} determines a partition of S.

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If a cardinal number is not finite, it is said to be infinite.

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If a set S is finite, then S is equinumerous with In for some n ∈ .

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If f:A→B and D is a nonempty subset of B, then f^-1(D) is a non-empty subset of A.

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If f:A→B, then A is the domain of f and B is the range of f.

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Iff:A→B is surjective and y∈B, then f^-1(y)∈A.

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In any relation R on a setS, we always have xRx for all x∈S.

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In proving S ⊆ T, one should avoid beginning with "Let x ∈ S," because this assumes that S is nonempty.

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Russell's paradox conflicts with the axiom of separation.

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The Banach−Tarski paradox uses the axiom of choice.

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The continuum hypothesis says that א0 is the smallest transfinite cardinal number

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The identity function maps onto {1}.

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The set of real numbers is denumerable.

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The symbol is used to denote the set of all integers.

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(a,b)=(c,d) iff a=c and b=d.

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(f) A function f : A → B is bijective if it is one-to-one and maps A onto B.

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A function f:A→B is injective if for all a and a′ in A, f(a)= f(a′) implies that a = a′.

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A relation is an equivalence relation if it is reflexive, symmetric, and transitive

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A slash (/ ) through a symbol means "not."

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A×B={{a,b}:a∈A and b∈B}.

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Every subset of a countable set is countable.

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If f is a function, then the notation y = f (x) means (x, y) ∈ f.

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If f:A→B and C is a nonempty subset of A, then f(C) is a nonempty subset of B

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If f:A→B is bijective, then f^-1 :B→A is bijective.

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If p is a partition of S and x∈S, then x∈A for some A∈p .

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If p is a partition of set S, then we can obtain a relation R on S by defining x R y iff x and y are in the same piece of the partition.

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If x∈A∪B, then x∈A or x∈B.

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IfA⊆BandA≠B,then A is called a proper subset of B.

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Let S be a nonempty set. There exists an injection f : S → iff there exists a surjection g : → S.

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The Zermelo−Fraenkel axioms are widely accepted as a foundation for set theory

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The axiom of regularity rules out the possibility that a set is a member of itself.

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The composition of two surjective functions is always surjective.

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The empty set is a subset of every set.

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The set of rational numbers is denumerable.

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Two sets S and T are equinumerous if there exists a bijection f : S → T.

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|S|≤|T| means that there exists an injection f:S→T.

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