---
layout: linguistics
title: linguistics/semantics
---

# semantics and pragmatics

>! These notes are **incomplete**! Proceed with caution, or better yet, not at all.

Semantics is the study of **meaning**.

How do we know what sentences are *true* and which are *false*?<br>
What does it *mean* for a sentence to be true?<br>
What *conditions* must hold for a sentence to be true?

<br>

<details>
<summary>table of contents</summary>

- History
- Prerequisites
- Basic Principles
  - Compositionality
  - Substitution
  - Predicate Logic & The Lambda Calculus
- Denotational Semantics
  - Entities and Functions
  - Quantification
  - Reference
  - Numbers and Plurality
  - Event Semantics
  - Situation Semantics
- Possible Worlds
  - Necessity and Possibility
  - Knowledge and Belief
  - Command, Request, and Obligation
  - Drawing Distinctions
  - Tense and Aspect
- Beyond Truth
  - Intuitionistic Logic
  - Questions
  - Utterances
- Pragmatics
  - Impliciture
  - Presupposition
  - Performative Acts
- Lexical Semantics

</details>


## History

> the dirty secret of semantics is that 2/3rds of it was created by philosophers
> and the remaining third is angelika kratzer
>
> -- partialorder

Modern approaches to semantics largely fell out of historical work in logic...
- c.i. lewis
- paul grice
- richard montague
- irene heim
- angelika kratzer
- judith butler

## Prerequisites

Formal semantics builds atop a bevy of concepts in formal logic.
Comfortability with the following concepts will be assumed:
- object languages and meta languages
- zeroth-order/propositional logic
- first-order/predicate logic
- the lambda calculus
- simple types
- logical models
- modal logic
  - possible worlds
  - accessibility relations
- second-order/higher-order logic
- intuitionistic logic

If this is not the case, there are a variety of wonderful resources for learning such topics. I am partial to *An Introduction to Non-Standard Logics* myself, and think it gives a good, syntactic motivation for possible worlds and accessibility relations. I have heard praise for *Boxes and Diamonds* (which is free and open!) but have yet to look at it myself. Wikipedia is also a wonderful reference. Best of all, however, is finding yourself a friend who is a nerd about logic! (thanks alex)

$$∧ ∨ + × ⊕ ↑ ↓ ∼ ¬ ⇁ → ⇒ ⊃ ⊐ ⥽ > ⊢ ⊨$$

## Basic Principles

### Compositionality

The *Principle of Compositionality* states that the meaning of a *constituent* is determined entirely by its *components*. This is *the* fundamental underlying principle behind formal logic and subsequently semantics. It holds for not just sentence composition (syntax), but also *word formation* (morphology), and what's of interest to us here - meaning (semantics).

### Substitution

The *Principle of Substitution* states that substituting one part of an expression with something else of the same meaning *preserves* the meaning of the expression as a whole. This might be thought of as a given, but semantics has its roots in philosophy, and philosophers care very much about enumerating their givens.

### Predicate Logic & The Lambda Calculus

Formal semantics begets a formal system for such semantics, and *first-order logic* and *the lambda calculus* are a natural fit. Semantics is the study of meaning - and what is logic but a system for expressing meaning? As discussed above, language functions by composition - and what are functions but their property of composition?

[*An Invitation to Formal Semantics*](https://eecoppock.info/bootcamp/semantics-boot-camp.pdf) covers basic logic and the lambda calculus well in its first six chapters. Otherwise, for a worse introduction, see [logic](../math/logic), and [the lambda calculus](../plt/lambda-calculus).

## Denotational Semantics

With basic logic and the lambda calculus under our belt, we may simply get straight to assigning *meaning* to language. We consider two *basic types* to start: the type of entities, $e$, and the type of truth values, $t$. Our function types we denote by ordered pairs: that is, a function from $e$ to $t$ is of type $⟨e,t⟩$. This is perhaps clunkier notation than the type-theoretic $e→t$, but it is what it is. (And does avoid issues of precedence.)

### Entities and Functions

> *I am Alice.* <br>
> *Alice is pretty.* <br>
> *The blue pigeon flew away.*

- Noun: $⟨e,t⟩ ↝ λx.Noun(x)$
- Verb (intransitive): $⟨e,t⟩ ↝ λx.Verb(x)$
- Verb (transitive): $⟨e,⟨e,t⟩⟩ ↝ λy.λx.Verb(x, y)$
- Verb (meaningless): $⟨⟨e,t⟩,⟨e,t⟩⟩ ↝ λP.λx.P(x)$
- Adj: $⟨⟨e,t⟩,⟨e,t⟩⟩ ↝ λNoun.λx.[Adj(x) ∧ Noun(x)]$

- or (clausal): $⟨t,⟨t,t⟩⟩ ↝ λq.λp.[p ∨ q]$
- and (clausal): $⟨t,⟨t,t⟩⟩ ↝ λq.λp.[p ∧ q]$
- or (verbal): $⟨⟨e,t⟩,⟨⟨e,t⟩,⟨e,t⟩⟩⟩ ↝ λQ.λP.λx.[P(x) ∨ Q(x)]$
- and (verbal): $⟨⟨e,t⟩,⟨⟨e,t⟩,⟨e,t⟩⟩⟩ ↝ λQ.λP.λx.[P(x) ∧ Q(x)]$
- or (quantifiers): $⟨⟨e,⟨e,t⟩⟩,⟨⟨e,⟨e,t⟩⟩,⟨e,⟨e,t⟩⟩⟩⟩ ↝ λQ.λP.λy.λx.[P(x,y) ∨ Q(x,y)]$
- and (quantifiers): $⟨⟨e,⟨e,t⟩⟩,⟨⟨e,⟨e,t⟩⟩,⟨e,⟨e,t⟩⟩⟩⟩ ↝ λQ.λP.λy.λx.[P(x,y) ∧ Q(x,y)]$

- not: $⟨⟨e,t⟩,⟨e,t⟩⟩ ↝ λP.λx.¬P(x)$

### Quantification

- every: $⟨⟨e,t⟩,⟨⟨e,t⟩,t⟩⟩ ↝ λQ.λP.∀x.[P(x) → Q(x)]$
  - everything: $⟨⟨e,t⟩,t⟩ ↝ λP.∀x.P(x)$
- some: $⟨⟨e,t⟩,⟨⟨e,t⟩,t⟩⟩ ↝ λQ.λP.∃x.[P(x) ∧ Q(x)]$
  - something: $⟨⟨e,t⟩,t⟩ ↝ λP.∃x.P(x)$
- no: $⟨⟨e,t⟩,⟨⟨e,t⟩,t⟩⟩ ↝ λQ.λP.∀x.[P(x) → ¬Q(x)] (or λQ.λP.¬∃x.[P(x) ∧ Q(x)])$
  - nothing: $⟨⟨e,t⟩,t⟩ ↝ λP.¬∃x.P(x)$ (or $λP.∀x.¬P(x)$)

### Reference

### Numbers and Plurality

### Event Semantics

### Tense and Aspect

## Beyond Truth

### Necessity and Possibility

### Command, Request, Obligation

> *Alice, run!* <br>
> *Alice, please run.* <br>
> *Alice should run.*

### Questions
## Resources
- ✨ [Invitation to Formal Semantics](https://eecoppock.info/bootcamp/semantics-boot-camp.pdf)