Ideas of Shaughan Lavine, by Theme
[American, fl. 2006, Professor at the University of Arizona.]
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4. Formal Logic / F. Set Theory ST / 1. Set Theory
15945
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Second-order set theory just adds a version of Replacement that quantifies over functions
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4. Formal Logic / F. Set Theory ST / 2. Mechanics of Set Theory / b. Terminology of ST
15914
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An 'upper bound' is the greatest member of a subset; there may be several of these, so there is a 'least' one
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4. Formal Logic / F. Set Theory ST / 3. Types of Set / a. Types of set
15921
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Collections of things can't be too big, but collections by a rule seem unlimited in size
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4. Formal Logic / F. Set Theory ST / 3. Types of Set / d. Infinite Sets
15937
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Those who reject infinite collections also want to reject the Axiom of Choice
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4. Formal Logic / F. Set Theory ST / 4. Axioms for Sets / g. Axiom of Powers VI
15936
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The Power Set is just the collection of functions from one collection to another
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4. Formal Logic / F. Set Theory ST / 4. Axioms for Sets / h. Axiom of Replacement VII
15899
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Replacement was immediately accepted, despite having very few implications
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4. Formal Logic / F. Set Theory ST / 4. Axioms for Sets / i. Axiom of Foundation VIII
15930
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Foundation says descending chains are of finite length, blocking circularity, or ungrounded sets
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4. Formal Logic / F. Set Theory ST / 4. Axioms for Sets / j. Axiom of Choice IX
15898
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The controversy was not about the Axiom of Choice, but about functions as arbitrary, or given by rules
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15920
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Pure collections of things obey Choice, but collections defined by a rule may not
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4. Formal Logic / F. Set Theory ST / 5. Conceptions of Set / c. Logical sets
15919
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The 'logical' notion of class has some kind of definition or rule to characterise the class
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4. Formal Logic / F. Set Theory ST / 5. Conceptions of Set / e. Iterative sets
15900
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The iterative conception of set wasn't suggested until 1947
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15931
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The iterative conception needs the Axiom of Infinity, to show how far we can iterate
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15932
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The iterative conception doesn't unify the axioms, and has had little impact on mathematical proofs
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4. Formal Logic / F. Set Theory ST / 5. Conceptions of Set / f. Limitation of Size
15933
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Limitation of Size: if it's the same size as a set, it's a set; it uses Replacement
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4. Formal Logic / F. Set Theory ST / 6. Ordering in Sets
15913
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A collection is 'well-ordered' if there is a least element, and all of its successors can be identified
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5. Theory of Logic / A. Overview of Logic / 7. Second-Order Logic
15926
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Second-order logic presupposes a set of relations already fixed by the first-order domain
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5. Theory of Logic / D. Assumptions for Logic / 2. Excluded Middle
15934
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Mathematical proof by contradiction needs the law of excluded middle
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6. Mathematics / A. Nature of Mathematics / 1. Mathematics
15907
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Mathematics is nowadays (thanks to set theory) regarded as the study of structure, not of quantity
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6. Mathematics / A. Nature of Mathematics / 3. Nature of Numbers / b. Types of number
15942
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Every rational number, unlike every natural number, is divisible by some other number
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6. Mathematics / A. Nature of Mathematics / 3. Nature of Numbers / g. Real numbers
15922
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For the real numbers to form a set, we need the Continuum Hypothesis to be true
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6. Mathematics / A. Nature of Mathematics / 3. Nature of Numbers / h. Reals from Cauchy
18250
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Cauchy gave a necessary condition for the convergence of a sequence
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6. Mathematics / A. Nature of Mathematics / 3. Nature of Numbers / i. Reals from cuts
15904
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The two sides of the Cut are, roughly, the bounding commensurable ratios
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6. Mathematics / A. Nature of Mathematics / 4. Using Numbers / c. Counting procedure
15912
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Counting results in well-ordering, and well-ordering makes counting possible
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6. Mathematics / A. Nature of Mathematics / 5. The Infinite / a. The Infinite
15947
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The infinite is extrapolation from the experience of indefinitely large size
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15949
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The theory of infinity must rest on our inability to distinguish between very large sizes
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6. Mathematics / A. Nature of Mathematics / 5. The Infinite / c. Potential infinite
15940
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The intuitionist endorses only the potential infinite
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6. Mathematics / A. Nature of Mathematics / 5. The Infinite / f. Uncountable infinities
15909
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'Aleph-0' is cardinality of the naturals, 'aleph-1' the next cardinal, 'aleph-ω' the ω-th cardinal
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6. Mathematics / A. Nature of Mathematics / 5. The Infinite / h. Ordinal infinity
15915
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Ordinals are basic to Cantor's transfinite, to count the sets
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15917
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Paradox: the class of all ordinals is well-ordered, so must have an ordinal as type - giving a bigger ordinal
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6. Mathematics / A. Nature of Mathematics / 5. The Infinite / i. Cardinal infinity
15918
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Paradox: there is no largest cardinal, but the class of everything seems to be the largest
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6. Mathematics / B. Foundations for Mathematics / 6. Mathematics as Set Theory / a. Mathematics is set theory
15929
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Set theory will found all of mathematics - except for the notion of proof
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6. Mathematics / C. Sources of Mathematics / 1. Mathematical Platonism / b. Against mathematical platonism
15935
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Modern mathematics works up to isomorphism, and doesn't care what things 'really are'
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6. Mathematics / C. Sources of Mathematics / 10. Constructivism / b. Intuitionism
15928
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Intuitionism rejects set-theory to found mathematics
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