chapter 7 propositional and predicate logic
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Chapter 7 Propositional and Predicate Logic. Chapter 7 Contents (1). What is Logic? Logical Operators Translating between English and Logic Truth Tables Complex Truth Tables Tautology Equivalence Propositional Logic. Chapter 7 Contents (2). Deduction Predicate Calculus - PowerPoint PPT PresentationTRANSCRIPT
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Chapter 7Propositional and Predicate Logic
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Chapter 7 Contents (1)
What is Logic? Logical Operators Translating between English and Logic Truth Tables Complex Truth Tables Tautology Equivalence Propositional Logic
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Chapter 7 Contents (2)
Deduction Predicate Calculus Quantifiers and Properties of logical systems Abduction and inductive reasoning Modal logic
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What is Logic?
Reasoning about the validity of arguments. An argument is valid if its conclusions
follow logically from its premises – even if the argument doesn’t actually reflect the real world: All lemons are blue Mary is a lemon Therefore, Mary is blue.
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Logical Operators
And Λ Or V Not ¬ Implies → (if… then…) Iff ↔ (if and only if)
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What is a Logic? What is a Logic? _ A logic consists of three components:
1. Syntax: A language for stating propositions/sentences.
2. Semantics: A way of determining whether a given proposition/sentence is true or false. (Model theory) 3. Inference system: Rules for inferring/deducing theorems from other theorems.
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Translating between English and Logic
Facts and rules need to be translated into logical notation.
For example: It is Raining and it is Thursday: R Λ T R means “It is Raining”, T means “it is
Thursday”.
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Translating between English and Logic
More complex sentences need predicates. E.g.: It is raining in New York: R(N) Could also be written N(R), or even just R.
It is important to select the correct level of detail for the concepts you want to reason about.
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Truth Tables Tables that show truth values for all
possible inputs to a logical operator. For example:
A truth table shows the semantics of a logical operator.
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Complex Truth Tables We can produce
truth tables for complex logical expressions, which show the overall value of the expression for all possible combinations of variables:
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Tautology The expression A v ¬A is a tautology. This means it is always true, regardless of the value of
A. A is a tautology: this is written
╞ A A tautology is true under any interpretation. Example: A A A V ¬A An expression which is false under any interpretation is
contradictory. Example: A Λ ¬ A
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Equivalence
Two expressions are equivalent if they always have the same logical value under any interpretation: A Λ B B Λ A
Equivalences can be proven by examining truth tables.
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Some Useful Equivalences A v A A A Λ A A A Λ (B Λ C) (A Λ B) Λ C A v (B v C) (A v B) v C A Λ (B v C) (A Λ B) v (A Λ C) A Λ (A v B) A A v (A Λ B) A
A Λ true A A Λ false false A v true true A v false A
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Propositional Logic
Propositional logic is a logical system. It deals with propositions. Propositional Calculus is the language
we use to reason about propositional logic.
A sentence in propositional logic is called a well-formed formula (wff).
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Propositional Logic The following are wff’s: P, Q, R… true, false (A) ¬A A Λ B A v B A → B A ↔ B
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Deduction The process of deriving a conclusion from a set of
assumptions. Use a set of rules, such as:
A A → B BIf A is true, and A implies B is true, then we
know B is true. (Modus Ponens) If we deduce a conclusion C from a set of
assumptions, we write: {A1, A2, …, An} ├ C
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Deduction - Example
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Predicate Logic
The first of these, predicate logic, involves using standard forms of logical symbolism which have been familiar to philosophers and mathematicians for many decades.
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Most simple sentences, for example, ``Peter is generous'' or
``Jane gives a painting to Sam,'' can be represented in terms of logical
formulae in which a predicate is applied to one or more arguments
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Predicate Calculus
Predicate Calculus extends the syntax of propositional calculus with predicates and quantifiers: P(X) – P is a predicate.
First Order Predicate Calculus (FOPC) allows predicates to apply to objects or terms, but not functions or predicates.
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Quantifiers and - For all:
xP(x) is read “For all x’es, P (x) is true”. - There Exists:
x P(x) is read “there exists an x such that P(x) is true”.
Relationship between the quantifiers: xP(x) ¬(x)¬P(x) “If There exists an x for which P holds, then it is not
true that for all x P does not hold”.
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Existential Quantifier -”there exists”
There are times when, rather than claim that something is true about all things, we only want to claim that it is true about at least one thing.
For example, we might want to make the claim that "some politicians are honest," but we would probably not want to claim this universally.
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A way that mathematicians often phrase
this is "there exists a politician who is honest."
Our abbreviation for "there exists" is " ", which is called the existential quantifier because it claims the existence of something.
If we use P for the predicate "is a politician" and H for the predicate "is honest," we can write "some politicians are honest" as:
x[Px Hx].
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Properties of Logical Systems
Soundness: Is every theorem valid? Completeness: Is every tautology a
theorem? Decidability: Does an algorithm exist
that will determine if a wff is valid? Monotonicity: Can a valid logical
proof be made invalid by adding additional premises or assumptions?
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Abduction and Inductive Reasoning Abduction:
B A → B A Not logically valid, BUT can still be useful. In fact, it models the way humans reason all the
time: Every non-flying bird I’ve seen before has been a
penguin; hence that non-flying bird must be a penguin. Not valid reasoning, but likely to work in many
situations.
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Inductive Reasoning
Inductive Reasoning enable us to make predictions based on what has happened in the past.
Example: “The Sun came up yesterday and the day before, and everyday I know before that, so it will come up again tomorrow.”
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Three Kinds of Reasoning
Broadly speaking there are 3 kinds of reasoning:
deductive – Based on the use of modus ponens and other deductive rules and reasoning.
abductive – Based on common fallacy. inductive – Based on history (what has
happened in the past)
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Examples A deductive argument consists of n
premisses and a conclusion. If the argument is valid, then if the
premisses are true the conclusion must be true:
Premiss 1: If it's raining then the streets are wet Premiss 2: It's raining ----------------- Therefore the streets are wet
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All horses have brains Herman is a horse -------------- Therefore Herman has a brain
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When Conclusion Does Not Follow From the Premisses
The following are invalid: If it's raining then the streets are wet
The streets are wet --------------- Therefore it's raining
All horses have brains Herman has a brain --------------- Therefore Herman is a horse
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Examples of Invalid Arguments
The following two arguments are invalid: If it's raining then the streets are wet
The streets are wet -------------- Therefore it's raining
All horses have brains Herman has a brain -------------- Therefore Herman is a horse
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More on Deductive Reasoning
An argument can have any number of premisses:
If p then q If q then r If r then s If s then t p -------
Therefore t
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Abductive reasoning Abduction is "reasoning backwards". We
start with some facts and reason back to a hypothesis. E.g.
If someone has measles they have spots and a sore throat Jimmy has spots and a sore throat ------------------------ Therefore Jimmy has measles
This isn't formally valid, of course. In fact it is a famous fallacy, called "confirming the consequent".
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An Earlier Example
If it's raining then the streets are wet The streets are wet -------------- Therefore it's raining
Nevertheless this does seem to be how doctors work.
They use abduction to generate hypotheses, which they then test (for instance, by doing a blood test).
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Inductive reasoning
Inductive reasoning is reasoning from particular cases or facts to a general conclusion:
raven 1 is black raven 2 is black . . raven n is black ----------- Therefore all ravens are black
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More Examples horse 1 has a brain
horse 2 has a brain . . horse n has a brain ------------- Therefore all horses have brains
These go from SOME to ALL: All observed (i.e. some) Xs have property P
------------------------------- Therefore all Xs have P
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Limitations
This isn't formally valid. The conclusion does not formally follow
from the observed facts. At one time people believed that all
observed swans are white, therefore all swans are white.
This is false, of course, because there are black swans in Western Australia!
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Modal logic Modal logic is a higher order logic. Allows us to reason about certainties, and
possible worlds. If a statement A is contingent then we say that
A is possibly true, which is written:◊A
If A is non-contingent, then it is necessarily true, which is written:
A
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Reasoning in Modus Logic The following rules are examples of the
axioms that can be used to reason in modus logic:
A ◊A ¬A ¬◊A ◊A ¬A We cannot draw truth tables to prove them;
however, you can reason by your understanding of the meaning of the operators.
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Class Exercise
Draw a truth table for the following expressions:
1. ¬AΛ(AVB)Λ(BVC)
2. ¬AΛ(AVB)Λ(BVC)Λ¬D