06-240/Classnotes For Tuesday October 10: Difference between revisions
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==A Quick Summary by {{Dror}}== |
==A Quick Summary by {{Dror}}== |
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(Intentionally terse. A sea of details appears in the book and already appeared on the blackboard. But these are useless without some '''organizing principles'''; in some sense, "understanding" is precisely being able to see those principles |
(Intentionally terse. A sea of details appears in the book and already appeared on the blackboard. But these are useless without some '''organizing principles'''; in some sense, "understanding" is precisely being able to see those principles within the sea of details. Yet don't fool yourself into thinking that the principles are enough even without the details!) |
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'''Theorem.''' A finite generating set <math>G</math> has a subset which is a basis. |
'''Theorem.''' A finite generating set <math>G</math> has a subset which is a basis. |
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'''Lemma.''' (The Replacement Lemma) If <math>G</math> generates and <math>L</math> is linearly independent, then <math>|L|\leq|G|</math> and you can replace <math>|L|</math> of the elements of <math>G</math> by the elements of <math>L</math>, and still have a generating set. |
'''Lemma.''' (The Replacement Lemma) If <math>G</math> generates and <math>L</math> is linearly independent, then <math>|L|\leq|G|</math> and you can replace <math>|L|</math> of the elements of <math>G</math> by the elements of <math>L</math>, and still have a generating set. |
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'''Proof Sketch.''' Insert the elements of <math>L</math> one by one, and for each one that comes in, take one out of <math>G</math>. Which one? One that is used in expressing the newcomer in terms of the vector currently |
'''Proof Sketch.''' Insert the elements of <math>L</math> one by one, and for each one that comes in, take one out of <math>G</math>. Which one? One that is used in expressing the newcomer in terms of the vector currently being inserted. Such one must exist or else the newcomer is a linear combination of some of the elements of <math>L</math>, but <math>L</math> is linearly independent. |
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'''Theorem.''' If a vector space <math>V</math> has a finite basis, all bases thereof are finite and have the same number of elements, the "dimension of <math>V</math>". |
'''Theorem.''' If a vector space <math>V</math> has a finite basis, all bases thereof are finite and have the same number of elements, the "dimension of <math>V</math>". |
Revision as of 08:03, 12 October 2006
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A Quick Summary by Dror
(Intentionally terse. A sea of details appears in the book and already appeared on the blackboard. But these are useless without some organizing principles; in some sense, "understanding" is precisely being able to see those principles within the sea of details. Yet don't fool yourself into thinking that the principles are enough even without the details!)
Theorem. A finite generating set has a subset which is a basis.
Proof Sketch. Grab more and more elements of so long as they are linearly independent. When you can't any more, you have a basis.
Lemma. (The Replacement Lemma) If generates and is linearly independent, then and you can replace of the elements of by the elements of , and still have a generating set.
Proof Sketch. Insert the elements of one by one, and for each one that comes in, take one out of . Which one? One that is used in expressing the newcomer in terms of the vector currently being inserted. Such one must exist or else the newcomer is a linear combination of some of the elements of , but is linearly independent.
Theorem. If a vector space has a finite basis, all bases thereof are finite and have the same number of elements, the "dimension of ".
Proof Sketch. By replacement, and .
Theorem. Assume .
- If generates, . In case of equality, is a basis.
- If is linearly independent, . In case of equality, is a basis.
Proof Sketch.
- Find a basis within ; it has elements.
- Use replacement to place the elements of within some basis.