502 lines
26 KiB
Markdown
502 lines
26 KiB
Markdown
---
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title: α-conversion
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TARGET DECK: Obsidian::STEM
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FILE TAGS: λ-calculus
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tags:
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- λ-calculus
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---
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## Overview
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Let $\lambda$-term $P$ contain an occurrence of $\lambda x. M$, and let $y \not\in FV(M)$. The act of replacing this occurrence of $\lambda x. M$ with $\lambda y. [y/x]M$ is called a **change of bound variable** or an $\alpha$-conversion in $P$.
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If $P$ can be changed to $\lambda$-term $Q$ by a finite series of changes of bound variables, we shall say **$P$ is congruent to $Q$**, or **$P$ $\alpha$-converts to $Q$**, or $P \equiv_\alpha Q$.
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%%ANKI
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Basic
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If $P \equiv Q$, does $P \equiv_\alpha Q$?
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Back: Yes.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744134-->
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END%%
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%%ANKI
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Cloze
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$P \equiv Q$ is to {equivalent} whereas $P \equiv_\alpha Q$ is to {congruent}.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1719065602220-->
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END%%
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%%ANKI
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Basic
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What two ways can we pronounce $P \equiv_\alpha Q$?
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Back: "$P$ is congruent to $Q$" and "$P$ $\alpha$-converts to $Q$".
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1718475477173-->
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END%%
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%%ANKI
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Basic
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If $P \equiv_\alpha Q$, does $P \equiv Q$?
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Back: Not necessarily.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744141-->
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END%%
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%%ANKI
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Basic
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What does an $\alpha$-conversion refer to?
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Back: The act of replacing an occurrence of $(\lambda x. M)$ with $\lambda y. [y/x]M$.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1718475424870-->
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END%%
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%%ANKI
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Basic
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What distinguishes terms "$\alpha$-conversion" and "$\alpha$-converts"?
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Back: The latter refers to 0 or more applications of the former.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1718475424871-->
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END%%
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%%ANKI
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Basic
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$\alpha$-conversion is most related to what kind of $\lambda$-term?
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Back: Abstractions.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744144-->
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END%%
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%%ANKI
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Basic
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What property must $y$ satisfy for $\lambda x. M \equiv_\alpha \lambda y. [y/x]M$?
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Back: $y \not\in FV(M)$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1718802166425-->
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END%%
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%%ANKI
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Cloze
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"$\alpha$-{conversion}" refers to exactly one change of bound variable.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1718475424873-->
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END%%
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%%ANKI
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Cloze
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"$\alpha$-{converts}" refers to zero or more change of bound variables.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1718475424874-->
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END%%
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%%ANKI
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Basic
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What *kind* of conversion is a change of bound variable?
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Back: An $\alpha$-conversion.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744150-->
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END%%
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%%ANKI
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Basic
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Given $\lambda$-terms $P$ and $Q$, what does it mean for $P$ to be congruent to $Q$?
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Back: $P \equiv_\alpha Q$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744154-->
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END%%
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%%ANKI
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Basic
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Given $\lambda$-terms $P$ and $Q$, $P \equiv_\alpha Q$ if and only if what?
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Back: $P$ can be changed to $Q$ with a finite number of changes of bound variables.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744157-->
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END%%
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%%ANKI
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Basic
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Is the following identity true? $$\lambda x y. x(xy) \equiv \lambda x. (\lambda y. x(xy))$$
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Back: Yes.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744162-->
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END%%
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%%ANKI
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Basic
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Is the following identity true? $$\lambda x y. x(xy) \equiv_\alpha \lambda x. (\lambda y. x(xy))$$
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Back: Yes.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744166-->
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END%%
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%%ANKI
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Basic
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Is the following identity true? $$\lambda x y. x(xy) \equiv \lambda u v. u(uv))$$
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Back: No.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744169-->
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END%%
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%%ANKI
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Basic
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Is the following identity true? $$\lambda x y. x(xy) \equiv_\alpha \lambda u v. u(uv))$$
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Back: Yes.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744173-->
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END%%
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%%ANKI
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Cloze
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$\alpha$-conversion is known as a change of {bound variable}.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717687744176-->
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END%%
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%%ANKI
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Basic
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What greek-prefixed term is a change of bound variable known as?
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Back: An $\alpha$-conversion.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1718475424876-->
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END%%
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%%ANKI
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Basic
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If $P \equiv_\alpha Q$, what can be said about the free variables of $P$ and $Q$?
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Back: $FV(P) = FV(Q)$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717848027572-->
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END%%
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%%ANKI
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Basic
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What does it mean for $\equiv_\alpha$ to be reflexive?
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Back: $P \equiv_\alpha P$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717848027575-->
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END%%
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%%ANKI
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Basic
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What does it mean for $\equiv_\alpha$ to be symmetric?
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Back: $P \equiv_\alpha Q \Rightarrow Q \equiv_\alpha P$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717848027579-->
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END%%
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%%ANKI
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Basic
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What does it mean for $\equiv_\alpha$ to be transitive?
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Back: $P \equiv_\alpha Q \land Q \equiv_\alpha R \Rightarrow P \equiv_\alpha R$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717848027582-->
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END%%
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%%ANKI
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Basic
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What three properties make $\equiv_\alpha$ an equivalence relation?
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Back: $\equiv_\alpha$ is reflexive, symmetric, and transitive.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717848027586-->
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END%%
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Let $x$, $y$, and $v$ be distinct variables. Then
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* $v \not\in FV(M) \Rightarrow [P/v][v/x]M \equiv_\alpha [P/x]M$
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* $v \not\in FV(M) \Rightarrow [x/v][v/x]M \equiv_\alpha M$
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* $y \not\in FV(P) \Rightarrow [P/x][Q/y]M \equiv_\alpha [([P/x]Q)/y][P/x]M$
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* $x \not\in FV(Q) \land y \not\in FV(P) \Rightarrow [P/x][Q/y]M \equiv_\alpha [Q/y][P/x]M$
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* $[P/x][Q/x]M \equiv_\alpha [([P/x]Q)/x]M$
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%%ANKI
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Basic
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$[N/x]M$ corresponds to which equivalence-transformation inference rule?
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Back: Substitution.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717449830572-->
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END%%
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%%ANKI
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Basic
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$[P/v][v/x]M \equiv [P/x]M$ corresponds to which equivalence-transformation inference rule?
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Back: Transitivity.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717449830601-->
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END%%
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%%ANKI
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Basic
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Rewrite $(E_u^x)_v^x$ using $\lambda$-calculus syntax.
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Back: $[v/x][u/x]E$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717449830608-->
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END%%
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%%ANKI
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Basic
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Rewrite $[x/v][v/x]M$ using equivalence-transformation syntax.
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Back: $(M^x_v)^v_x$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717449830614-->
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END%%
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%%ANKI
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Cloze
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{$v \not\in FV(M)$} $\Rightarrow [P/v][v/x]M \equiv_\alpha [P/x]M$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717855810777-->
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END%%
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%%ANKI
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Basic
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What happens if the antecedent is false in $v \not\in FV(M) \Rightarrow [P/v][v/x]M \equiv_\alpha [P/x]M$?
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Back: The LHS of the identity has more occurrences of $P$ than the right.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717855810781-->
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END%%
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%%ANKI
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Basic
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If $v \in FV(M)$ and $x \not\in FV(M)$, does $[P/v][v/x]M \equiv_\alpha [P/x]M$?
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Back: No.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717850495760-->
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END%%
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%%ANKI
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Basic
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If $v \not\in FV(M)$ and $x \in FV(M)$, does $[P/v][v/x]M \equiv_\alpha [P/x]M$?
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Back: Yes.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717850495763-->
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END%%
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%%ANKI
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Basic
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If $v \not\in FV(M)$, what simpler term is $[P/v][v/x]M$ congruent to?
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Back: $[P/x]M$
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717850495766-->
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END%%
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%%ANKI
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Basic
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If $v \not\in FV(M)$ and $x \in FV(M)$, does $[x/v][v/x]M \equiv_\alpha M$?
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Back: Yes.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717850495775-->
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END%%
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%%ANKI
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Basic
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If $v \not\in FV(M)$ and $x \in FV(M)$, does $[v/x][x/v]M \equiv_\alpha M$?
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Back: No.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717850495778-->
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END%%
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%%ANKI
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Basic
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If $v \in FV(M)$ and $x \not\in FV(M)$, does $[v/x][x/v]M \equiv_\alpha M$?
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Back: Yes.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717850495782-->
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END%%
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%%ANKI
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Basic
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If $v \in FV(M)$ and $x \not\in FV(M)$, does $[x/v][v/x]M \equiv_\alpha M$?
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Back: No.
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Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
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<!--ID: 1717850495785-->
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END%%
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%%ANKI
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||
Basic
|
||
If $y \not\in FV(P)$, "commuting" substitution in $[P/x][Q/y]M$ yields what congruent term?
|
||
Back: $[([P/x]Q)/y][P/x]M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1717853380814-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Cloze
|
||
{$y \not\in FV(P)$} $\Rightarrow [P/x][Q/y]M \equiv_\alpha [([P/x]Q)/y][P/x]M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1717855810784-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Cloze
|
||
{$x \not\in FV(Q) \land y \not\in FV(P)$} $\Rightarrow [P/x][Q/y]M \equiv_\alpha [Q/y][P/x]M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718422235903-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
$[P/x][Q/y]M \equiv_\alpha [Q/y][P/x]M$ is a specialization of what more general congruence?
|
||
Back: $[P/x][Q/y]M \equiv_\alpha [([P/x]Q)/y][P/x]M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718422235909-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Cloze
|
||
{$T$} $\Rightarrow [P/x][Q/x]M \equiv_\alpha [([P/x]Q)/x]M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718422235912-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
What expression containing nested substitutions is congruent to $[P/x][Q/x]M$?
|
||
Back: $[([P/x]Q)/x]M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718422235916-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
What expression containing adjacent substitutions is congruent to $[([P/x]Q)/x]M$?
|
||
Back: $[P/x][Q/x]M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718422279995-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
What happens if the antecedent of the following lemma is false? $$y \not\in FV(P) \Rightarrow [P/x][Q/y]M \equiv_\alpha [([P/x]Q)/y][P/x]M$$
|
||
Back: $y$ is subbed in $M$ on the LHS but subbed in both $P$ and $M$ on the RHS.
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1717855810787-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
Free occurrences of $x$ are substituted in which $\lambda$-terms of $[P/x][Q/y]M$?
|
||
Back: $Q$ and $M$.
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1717855810790-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
Free occurrences of $y$ are substituted in which $\lambda$-terms of $[P/x][Q/y]M$?
|
||
Back: $M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1717855810794-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
Free occurrences of $x$ are substituted in which $\lambda$-terms of $[([P/x]Q)/y][P/x]M$?
|
||
Back: $Q$ and $M$.
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1717855810798-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
Free occurrences of $y$ are substituted in which $\lambda$-terms of $[([P/x]Q)/y][P/x]M$?
|
||
Back: $P$ and $M$.
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1717855810802-->
|
||
END%%
|
||
|
||
Substitution is well-defined with respect to $\alpha$-conversion. That is, if $M \equiv_\alpha M'$ and $N \equiv N'$, then $$[N/x]M \equiv_\alpha [N'/x]M'$$
|
||
|
||
%%ANKI
|
||
Basic
|
||
The proof of which implication shows substitution is well-behaved w.r.t. $\alpha$-conversion?
|
||
Back: $M \equiv_\alpha M' \land N \equiv_\alpha N' \Rightarrow [N/x]M \equiv_\alpha [N'/x]M'$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718422973129-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
What does Hindley et al. mean by "substitution is well-behaved w.r.t. $\alpha$-conversion"?
|
||
Back: Substitution then $\alpha$-conversion is congruent to $\alpha$-conversion then substitution.
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718422973135-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Cloze
|
||
{$M \equiv_\alpha M' \land N \equiv_\alpha N'$} $\Rightarrow [N/x]M \equiv_\alpha [N'/x]M'$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718422973141-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
How does Hindley et al. describe the following implication? $$M \equiv_\alpha M' \land N \equiv_\alpha N' \Rightarrow [N/x]M \equiv_\alpha [N'/x]M'$$
|
||
Back: As "substitution is well-defined with respect to $\alpha$-conversion."
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718422981125-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
Suppose $P \equiv_\alpha Q$. How do $FV(P)$ and $FV(Q)$ relate to one another?
|
||
Back: $FV(P) = FV(Q)$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1719406791439-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
*Why* is this implication true: $P \equiv_\alpha Q \Rightarrow FV(P) = FV(Q)$
|
||
Back: $\alpha$-conversions do not modify free variables in any way.
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1719406791443-->
|
||
END%%
|
||
|
||
## Simultaneous Substitution
|
||
|
||
Substitution can be generalized in the natural way to define simultaneous substitution $$[N_1/x_1, N_2/x_2, \ldots, N_n/x_n]M$$ for $n \geq 2$. As in [[equiv-trans#Substitution|equivalence-transformation]], simultaneous substitution is different from sequential substitution.
|
||
|
||
%%ANKI
|
||
Basic
|
||
How is simultaneous substitution of $N_1$ for $x_1$ and $N_2$ for $x_2$ in $M$ denoted?
|
||
Back: $[N_1/x_1, N_2/x]M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718473252304-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
How is $[N_1/x_1, N_2/x_2]M$ denoted in the equivalence-transformation system?
|
||
Back: $M_{N_1, N_2}^{x_1, x_2}$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718473252307-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
How is $M_{N_1, N_2}^{x_1, x_2}$ denoted in $\lambda$-calculus?
|
||
Back: $[N_1/x_1, N_2/x_2]M$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718473252312-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
Suppose $M \equiv x_1x_2$. What is the result of $[u/x_1]([x_1/x_2]M)$?
|
||
Back: $uu$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718473252309-->
|
||
END%%
|
||
|
||
%%ANKI
|
||
Basic
|
||
Suppose $M \equiv x_1x_2$. What is the result of $[u/x_1, x_1/x_2]M$?
|
||
Back: $ux_1$
|
||
Reference: Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf).
|
||
<!--ID: 1718473252311-->
|
||
END%%
|
||
|
||
## Bibliography
|
||
|
||
* Hindley, J Roger, and Jonathan P Seldin. “Lambda-Calculus and Combinators, an Introduction,” n.d. [https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf](https://www.cin.ufpe.br/~djo/files/Lambda-Calculus%20and%20Combinators.pdf). |