Difference between revisions of "MAT1313"

1.1 & 1.2

Propositional Logic

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• Recognize propositional formulas built from atoms using connectives.
• Correctly interpret propositional formulas using truth tables.

2

1.3 & 1.4

• Tautologies and Deductions
• Quantifiers

• Propositional Logic

• Establish whether a propositional formula is a tautology.
• State De Morgan's Laws of logic.
• Recognize conditional tautologies as laws of deduction.
• Express conditionals in disjunctive form.
• Express the negation of a conditional in conjunctive form.
• Identify the direct and contrapositive forms of a conditional.
• Recognize the non-equivalence of a conditional and its converse.
• Recognize a biconditional as the conjunction of a conditional and its converse.
• Identify the domain of interpretation of a quantified statement.
• Correctly interpret quantified statements.
• Correctly negate quantified statements.

3

1.5 & 1.6

• Sets
• Set Operations
• Introduction to proofs of universal statements in set theory
• Disproving universal statements via counterexamples

• Tautologies and Deductions
• Quantifiers

• Recognize and interpret set equality and set inclusion.
• Recognize set operations and state their formal definitions.
• Recognize formal proofs as processes of logical deduction of conclusions from assumptions.
• Prove basic universal statements pertaining to set inclusion and set operations.
• Correctly identify false universal statements in set theory and disprove them with appropriate counterexamples.
• Correctly use propositional and quantified tautologies as deductive laws.

4

2.1

• Divisibility of integers
• The Division Algorithm.

• Proofs and Counterexamples.
• Propositional Logic.
• Quantifiers.

• Recognize the notion of integer divisibility via its formal definition, examples and counterexamples.
• Correctly state and apply the Division Algorithm of integers.
• Prove basic facts pertaining to divisibility and the division algorithm.