559 lines
25 KiB
Markdown
559 lines
25 KiB
Markdown
---
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title: Sequences
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TARGET DECK: Obsidian::STEM
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FILE TAGS: algebra::sequence
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tags:
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- algebra
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- sequence
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---
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## Overview
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A **sequence** is an ordered list of numbers. These are usually represented as a **closed formula** or a **recursive definition**.
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%%ANKI
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Basic
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What is a sequence?
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Back: An ordered list of values.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343193-->
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END%%
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%%ANKI
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Basic
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How does sequence $0, 1, 2, \ldots$ differ from set $\mathbb{N}$?
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Back: Order matters in the former.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343198-->
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END%%
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%%ANKI
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Basic
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How is sequence $a_1, a_2, \ldots$ more compactly denoted?
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Back: $(a_n)_{n \geq 1}$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343201-->
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END%%
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%%ANKI
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Basic
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What is the first index of $(a_n)_{n \geq 1}$?
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Back: $1$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343204-->
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END%%
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%%ANKI
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Basic
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What terms make up the expanded form of sequence $(a_n)_{n \geq 0}$?
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Back: $a_0, a_1, a_2, \ldots$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343207-->
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END%%
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%%ANKI
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Basic
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What term refers to the subscripts in sequence $a_0, a_1, a_2, \ldots$?
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Back: Indices.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343211-->
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END%%
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%%ANKI
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Basic
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How do functions and sequences relate to one another?
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Back: Every sequence is equivalent to a function mapping index to value.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343214-->
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END%%
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%%ANKI
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Basic
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How is sequence $a_0, a_1, a_2, \ldots$ interpreted as a function?
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Back: As a function that assigns $n \mapsto a_n$.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343216-->
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END%%
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%%ANKI
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Basic
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What two methods allow exact specification of a sequence?
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Back: Closed formulas and recursive definitions.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343220-->
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END%%
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%%ANKI
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Basic
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What is a closed formula for sequence e.g. $(a_n)_{n \geq 0}$?
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Back: A formula that can be computed using a fixed number of "well-known" standard operations, independent of $n$.
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Reference: Ronald L. Graham, Donald Ervin Knuth, and Oren Patashnik, *Concrete Mathematics: A Foundation for Computer Science*, 2nd ed (Reading, Mass: Addison-Wesley, 1994).
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<!--ID: 1709302343222-->
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END%%
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%%ANKI
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Cloze
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{$n!$} is a closed formula even though equivalent expression {$\Pi_{k=1}^n k$} is not.
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Reference: Ronald L. Graham, Donald Ervin Knuth, and Oren Patashnik, *Concrete Mathematics: A Foundation for Computer Science*, 2nd ed (Reading, Mass: Addison-Wesley, 1994).
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<!--ID: 1709302343225-->
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END%%
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%%ANKI
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Basic
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Why is $\Pi_{k=1}^n k$ not considered a closed formula?
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Back: The number of "well-known" standard operations (i.e. multiplications) scale with $n$.
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Reference: Ronald L. Graham, Donald Ervin Knuth, and Oren Patashnik, *Concrete Mathematics: A Foundation for Computer Science*, 2nd ed (Reading, Mass: Addison-Wesley, 1994).
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<!--ID: 1709302343228-->
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END%%
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%%ANKI
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Basic
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Why is $n!$ considered a closed formula?
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Back: Because the factorial operation is considered a "well-known" standard operation.
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Reference: Ronald L. Graham, Donald Ervin Knuth, and Oren Patashnik, *Concrete Mathematics: A Foundation for Computer Science*, 2nd ed (Reading, Mass: Addison-Wesley, 1994).
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<!--ID: 1709302343231-->
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END%%
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%%ANKI
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Basic
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What two parts make up a recursive definition of a sequence?
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Back: The recurrence relation and an initial condition.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343234-->
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END%%
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%%ANKI
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Basic
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What distinguishes a recurrence relation and a recursive definition?
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Back: A recursive definition includes a recurrence relation along with an initial condition.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343238-->
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END%%
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%%ANKI
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Basic
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How is sequence $(a_n)_{n \geq 0} = 1, 2, 4, 8, \ldots$ represented as a closed formula?
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Back: $a_n = 2^n$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343242-->
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END%%
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%%ANKI
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Basic
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How is sequence $(a_n)_{n \geq 0} = 1, 2, 4, 8, \ldots$ represented as a recursive definition?
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Back: $a_n = 2 \cdot a_{n-1}$ with $a_0 = 1$.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343245-->
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END%%
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%%ANKI
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Cloze
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It is harder to find {terms of a sequence} with a recursive definition than closed formula.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343249-->
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END%%
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%%ANKI
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Basic
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Which is considered easier to find: closed formulas or recursive definitions?
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Back: Recursive definitions.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343252-->
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END%%
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%%ANKI
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Basic
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What general strategy is typically employed when finding a closed formula for a sequence?
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Back: First find a recursive definition.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1709302343255-->
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END%%
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## Recurrence Relations
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To solve a recurrence relation means to find a closed form for the relation (with respect to initial conditions).
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%%ANKI
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Basic
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What is the recurrence relation for the Fibonacci sequence?
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Back: $F_n = F_{n-1} + F_{n-2}$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280062-->
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END%%
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%%ANKI
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Basic
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What does it mean to solve a recurrence relation?
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Back: To find a closed formula satisfying the relation and initial conditions.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280066-->
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END%%
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### Telescoping
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Telescoping refers to the property of summations in which consecutive terms cancel out. We can use telescoping to solve recurrences of form $a_n = a_{n-1} + f(n)$ by noticing that: $$\begin{align*} a_1 - a_0 & = f(1) \\ a_2 - a_1 & = f(2) \\ \vdots \\ a_n - a_{n-1} & = f(n) \\ \hline a_n - a_0 & = \sum_{k=1}^n f(n) \end{align*}$$
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%%ANKI
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Basic
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What does it mean for a sum to be telescoping?
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Back: Pairs of consecutive terms in the summation cancel each other out.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280068-->
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END%%
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%%ANKI
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Basic
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What imagery is invoked by the term "telescoping" with respect to a sum?
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Back: A collapsing telescope.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280071-->
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END%%
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%%ANKI
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Basic
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What summands typically remain after evaluating a telescoping sum?
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Back: The first and the last.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280074-->
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END%%
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%%ANKI
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Basic
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What is the result of the following after observing telescoping? $$(2 - 1) + (3 - 2) + \cdots + (100 - 99) + (101 - 100)$$
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Back: $-1 + 101$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280076-->
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END%%
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%%ANKI
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Basic
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How is the following rewritten to highlight telescoping? $$(2 - 1) + (3 - 2) + \cdots + (100 - 99) + (101 - 100)$$
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Back: $$(-1 + 2) + (-2 + 3) + \cdots + (-99 + 100) + (-100 + 101)$$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280079-->
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END%%
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%%ANKI
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Basic
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What is the result of the following? $\sum_{n=1}^N (a_n - a_{n-1})$
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Back: $a_N - a_0$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280082-->
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END%%
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%%ANKI
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Basic
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What property is used to quickly verify the following identity? $$\sum_{n=1}^N (a_n - a_{n-1}) = a_N - a_0$$
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Back: This is a telescoping sum.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280085-->
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END%%
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%%ANKI
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Basic
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Schematically show how **telescoping** can be used to solve $a_n = a_{n-1} + f(n)$.
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Back: $$\begin{align*}
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a_1 - a_0 & = f(1) \\
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& \vdots \\
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a_n - a_{n-1} & = f(n) \\
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\hline
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a_n - a_0 & = \sum_{k=1}^n f(k)
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\end{align*}$$Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280088-->
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END%%
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%%ANKI
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Basic
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What is the closed formula of recurrence $a_n = a_{n-1} + f(n)$?
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Back: $a_n = a_0 + \sum_{k=1}^n f(k)$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280091-->
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END%%
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%%ANKI
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Basic
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What summation property can be used to derive the closed formula of $a_n = a_{n-1} + f(n)$?
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Back: Telescoping.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713810280094-->
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END%%
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### Iteration
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Iteration refers to the expansion of terms, starting at the initial conditions, in the hope of discovering a pattern. It is more general than [[#Telescoping]] is. Consider $a_n = a_{n-1} + f(n)$ again. We solve with iteration like so: $$\begin{align*} a_1 & = a_0 + f(1) \\ a_2 & = (a_0 + f(1)) + f(2) \\ \vdots \\ a_n & = (\cdots(a_0 + f(1)) + f(2)) + \cdots) + f(n) \\ \hline a_n & = a_0 + \sum_{k=1}^n f(n) \end{align*}$$
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%%ANKI
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Basic
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What does it mean to solve a recurrence relation using iteration?
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Back: Repeatedly expand terms, starting at the initial conditions, to discover a pattern.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713998412589-->
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END%%
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%%ANKI
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Basic
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What is the result of "iterating" the following recursive definition twice? $$a_n = 3a_{n-1} + 2$$
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Back: $$\begin{align*}
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a_1 & = 3a_0 + 2 \\
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a_2 & = 3(3a_0 + 2) + 2
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\end{align*}$$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713998412595-->
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END%%
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%%ANKI
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Basic
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Schematically show how **iteration** can be used to solve $a_n = a_{n-1} + f(n)$.
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Back: $$\begin{align*}
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a_1 & = a_0 + f(1) \\
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& \vdots \\
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a_n & = (\cdots((a_0 + f(1)) + f(2)) + \cdots) + f(n) \\
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\hline
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a_n & = a_0 + \sum_{k=1}^n f(k)
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\end{align*}$$
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713998412597-->
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END%%
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%%ANKI
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Basic
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How fast does the number of terms grow when iterating $a_n = 3a_{n-1} + 2$?
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Back: Linearly.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713998412600-->
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END%%
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%%ANKI
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Basic
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How fast does the number of terms grow when iterating $a_n = 2a_{n-1} + 3a_{n-2}$?
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Back: Exponentially (the number of terms double each iteration).
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713998412603-->
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END%%
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%%ANKI
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Basic
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Why should you avoid using iteration to solve $a_n = 2a_{n-1} + 3a_{n-2}$?
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Back: The number of terms grows unwieldy very quickly.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713998412607-->
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END%%
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%%ANKI
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Basic
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When solving recurrences, is telescoping or iteration a more general technique?
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Back: Iteration.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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<!--ID: 1713998536738-->
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END%%
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### Characteristic Roots
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When encountering **linear homogeneous recurrence relations with constant coefficients**, we can use the characteristic root technique to solve. We demonstrate with a quadratic **characteristic polynomial**, though this technique generalizes to higher-order polynomials as well.
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Given recurrence relation $a_n + \alpha a_{n-1} + \beta a_{n-2} = 0$, the characteristic polynomial is $r^2 + \alpha r + \beta$. If $r_1$ and $r_2$ are distinct roots of the characteristic polynomial, then the solution to the recurrence relation is $$a_n = ar_1^n + br_2^n$$
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where $a$ and $b$ are determined by the initial conditions. If the characteristic polynomial only has one root $r$, the solution is instead $$a_n = ar^n + bnr^n$$
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%%ANKI
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Basic
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The characteristic root technique only works when solving what kind of recurrence relation?
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Back: Linear homogeneous recurrence relations with constant coefficients.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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Tags: algebra::polynomial
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<!--ID: 1714487050009-->
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END%%
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%%ANKI
|
|
Basic
|
|
What does "linear" refer to in "linear homogeneous recurrence relations with constant coefficients"?
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Back: The recurrence relation is a *linear* combination of previous terms.
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|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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Tags: algebra::polynomial
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<!--ID: 1714487050016-->
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END%%
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%%ANKI
|
|
Basic
|
|
What does "homogeneous" refer to in "linear homogeneous recurrence relations with constant coefficients"?
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Back: *Every* term in the relation is a multiple of previous terms.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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Tags: algebra::polynomial
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<!--ID: 1714487050019-->
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END%%
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%%ANKI
|
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Basic
|
|
Why isn't $a_n = 2a_{n-1} + 3a_{n-2}$ a linear homogeneous recurrence relation with constant coefficients?
|
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Back: N/A. It is.
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Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
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|
Tags: algebra::polynomial
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<!--ID: 1714487050023-->
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END%%
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%%ANKI
|
|
Basic
|
|
Why isn't $a_n = 2a_{n-1} \cdot 3a_{n-2}$ a linear homogeneous recurrence relation with constant coefficients?
|
|
Back: It is non-linear.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050026-->
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END%%
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%%ANKI
|
|
Basic
|
|
Why isn't $a_n = 2a_{n-1} + 3$ a linear homogeneous recurrence relation with constant coefficients?
|
|
Back: It is non-homogeneous.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050029-->
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END%%
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%%ANKI
|
|
Basic
|
|
Why isn't $a_n = 2a_{n-1} + na_{n-2}$ a linear homogeneous recurrence relation with constant coefficients?
|
|
Back: It has a nonconstant coefficient.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050032-->
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END%%
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%%ANKI
|
|
Basic
|
|
What is the most famous linear homoegeneous recurrence relation with constant coefficients?
|
|
Back: The Fibonacci sequence's recurrence relation.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050036-->
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END%%
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%%ANKI
|
|
Basic
|
|
Why might we guess the solution to e.g. $a_n = a_{n-1} + 6a_{n-2}$ is geometric?
|
|
Back: Every step of iteration multiplies a previous iteration by $6$.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050041-->
|
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END%%
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%%ANKI
|
|
Basic
|
|
How is $a_n = a_{n-1} + 6a_{n-2}$ factored to yield its characteristic polynomial?
|
|
Back: $r^{n-2}(r^2 - r - 6) = 0$
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050046-->
|
|
END%%
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|
|
%%ANKI
|
|
Basic
|
|
What is the characteristic *equation* of $a_n = a_{n-1} + 6a_{n-2}$?
|
|
Back: $r^2 - r - 6 = 0$
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050051-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the characteristic *polynomial* of $a_n = a_{n-1} + 6a_{n-2}$?
|
|
Back: $r^2 - r - 6$
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050055-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the characteristic *polynomial* of $a_n + \alpha a_{n-1} + \beta a_{n-2} = 0$?
|
|
Back: $r^2 + \alpha r + \beta$
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050059-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the characteristic *equation* of $a_n + \alpha a_{n-1} + \beta a_{n-2} = 0$?
|
|
Back: $r^2 + \alpha r + \beta = 0$
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050063-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What is the characteristic *equation* of $a_n = \alpha a_{n-1} + \beta a_{n-2}$?
|
|
Back: $r^2 - \alpha r - \beta = 0$
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050067-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Given recurrence $a_n = \alpha a_{n-1} + \beta a_{n-2}$, what guess is used to derive the concept of a characteristic polynomial?
|
|
Back: The guessing of a geometric solution, e.g. $r^n$.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050071-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
What distinguishes the characteristic polynomial from the characteristic equation of a recurrence relation?
|
|
Back: The latter sets the characteristic polynomial equal to $0$.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050075-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Using the quadratic characteristic root technique, what distinguishes the form of the closed solution?
|
|
Back: The number of distinct roots of the characteristic polynomial.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050079-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Suppose the characteristic polynomial of $a_n = \alpha a_{n-1} + \beta a_{n-2}$ has distinct roots $r_1$ and $r_2$. What is its solution?
|
|
Back: $a_n = ar_1^n + br_2^n$ where $a$ and $b$ are determined by initial conditions.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050083-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
Suppose the characteristic polynomial of $a_n = \alpha a_{n-1} + \beta a_{n-2}$ has single root $r$. What is its solution?
|
|
Back: $a_n = ar^n + bnr^n$ where $a$ and $b$ are determined by initial conditions.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050087-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
How many distinct roots does the characteristic polynomial of the following have? $$a_n = \alpha a_{n-1} + \beta a_{n-2} = ar^n + bnr^n$$
|
|
Back: One.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050090-->
|
|
END%%
|
|
|
|
%%ANKI
|
|
Basic
|
|
How many distinct roots does the characteristic polynomial of the following have? $$a_n = \alpha a_{n-1} + \beta a_{n-2} = ar_1^n + br_2^n$$
|
|
Back: Two.
|
|
Reference: Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
Tags: algebra::polynomial
|
|
<!--ID: 1714487050095-->
|
|
END%%
|
|
|
|
## Bibliography
|
|
|
|
* Oscar Levin, *Discrete Mathematics: An Open Introduction*, 3rd ed., n.d., [https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf](https://discrete.openmathbooks.org/pdfs/dmoi3-tablet.pdf).
|
|
* Ronald L. Graham, Donald Ervin Knuth, and Oren Patashnik, *Concrete Mathematics: A Foundation for Computer Science*, 2nd ed (Reading, Mass: Addison-Wesley, 1994).
|