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sav08:lattices [2009/03/31 23:44] vkuncak |
sav08:lattices [2015/04/21 17:30] (current) |
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**Definition:** A lattice is a [[:Partial order]] in which every two-element set has a least upper bound and a greatest lower bound. | **Definition:** A lattice is a [[:Partial order]] in which every two-element set has a least upper bound and a greatest lower bound. | ||
- | **Lemma:** In a lattice every non-empty set has a lub ($\sqcup$) and glb ($\sqcap$). | + | **Lemma:** In a lattice every non-empty finite set has a lub ($\sqcup$) and glb ($\sqcap$). |
- | **Proof:** is by ++| **induction!** ++ \\ | + | **Proof:** is by induction!\\ |
Case where the set S has three elements x,y and z:\\ | Case where the set S has three elements x,y and z:\\ | ||
Let $a=(x \sqcup y) \sqcup z$. \\ By definition of $\sqcup$ we have $z \sqsubseteq a$ and $ x \sqcup y \sqsubseteq a $.\\ | Let $a=(x \sqcup y) \sqcup z$. \\ By definition of $\sqcup$ we have $z \sqsubseteq a$ and $ x \sqcup y \sqsubseteq a $.\\ | ||
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Note: if you know that you have least upper bounds for all sets, it follows that you also have greatest lower bounds. | Note: if you know that you have least upper bounds for all sets, it follows that you also have greatest lower bounds. | ||
- | **Proof:** ++|by taking the least upper bound of the lower bounds. Converse also holds, dually.++ | + | **Proof:** by taking the least upper bound of the lower bounds. Converse also holds, dually. |
**Example:** Every subset of the set of real numbers has a lub. This is an axiom of real numbers, the way they are defined (or constructed from rationals). | **Example:** Every subset of the set of real numbers has a lub. This is an axiom of real numbers, the way they are defined (or constructed from rationals). | ||
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**Definition:** A lattice is //distributive// iff | **Definition:** A lattice is //distributive// iff | ||
- | \[ | + | \begin{equation*} |
\begin{array}{l} | \begin{array}{l} | ||
x \sqcap (y \sqcup z) = (x \sqcap y) \sqcup (x \sqcap z) \\ | x \sqcap (y \sqcup z) = (x \sqcap y) \sqcup (x \sqcap z) \\ | ||
x \sqcup (y \sqcap z) = (x \sqcup y) \sqcap (x \sqcup z) | x \sqcup (y \sqcap z) = (x \sqcup y) \sqcap (x \sqcup z) | ||
\end{array} | \end{array} | ||
- | \] | + | \end{equation*} |
**Example:** Lattice of all subsets of a set is distributive. Linear order is a distributive lattice. See examples of non-distributive lattices in [[wk>Distributive lattice]] and the characterization of non-distributive lattices. | **Example:** Lattice of all subsets of a set is distributive. Linear order is a distributive lattice. See examples of non-distributive lattices in [[wk>Distributive lattice]] and the characterization of non-distributive lattices. | ||
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===== References ===== | ===== References ===== | ||
- | * [[wk>Lattice (order)]] | + | * [[wp>Lattice (order)]] |
* [[http://bigcheese.math.sc.edu/~mcnulty/alglatvar/lat0.pdf|lecture notes by J.B. Nation]] or | * [[http://bigcheese.math.sc.edu/~mcnulty/alglatvar/lat0.pdf|lecture notes by J.B. Nation]] or | ||
* [[http://bigcheese.math.sc.edu/~mcnulty/alglatvar/burrissanka.pdf|Chapter I of a Course in Universal Algebra]]. | * [[http://bigcheese.math.sc.edu/~mcnulty/alglatvar/burrissanka.pdf|Chapter I of a Course in Universal Algebra]]. |