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129
documents/by-course/math-8/course-notes/main.typ
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@ -467,6 +467,135 @@ $ exists x in U, P(x) $
rational number $z$.
]<rational-between>
= Lecture #datetime(day: 27, month: 1, year: 2025).display()
== Basic properties of sets
#definition[
A set is a collection of elements.
]
#definition[
The cardinality of a set is the amount of elements in the set.
]
#example[
Prove $A subset.eq B$ iff. $A sect B = A$.
#proof[
Assume $A subset.eq B$. Let $x in A sect B$. Then $x in A$ and $x in B$. So
$x in A$ and $A sect B subset.eq A$. Now let $x in A$. Since $A subset.eq
B$, then $x in B$. Thus $x in A$ and $x in B$, so $x in A sect B$. Then $A
subset.eq A sect B$.
Now we show the other direction. Assume $A sect B = A$. Then $x in A sect
B$ implies $x in A$ and $x in B$. In particular $forall x in A, x in B$.
Thus $a subset.eq B$.
]
]
#theorem[
Let $U$ be the universe, and let $A$ and $B$ be subsets of $U$. Then
+ $(A^c)^c = A$
+ $A union A^c = U$
+ $A sect A^c = emptyset$
+ $A - B = A sect B^c$
+ $A subset.eq B <=> B^c subset.eq A^c$
+ $A sect B = emptyset <=> A subset.eq B^c$
+ $(A union B)^c = A^c sect B^c$
+ $(A sect B)^c = A^c union B^c$
]<basic-sets>
#example[part of @basic-sets][
Show that $(A sect B)^c = A^c union B^c$.
$
&x in (A sect B)^c \
&<=> x in.not A sect B \
&<=> x in A^c, x in B^c \
&<=> x in A^c union B^c
$
]
#definition[
The Cartesian product of sets $A$ and $B$:
$ A times B = {(a,b) : a in A "and" b in B} $
]
#fact[
If $A$ has cardinality $m$, $B$ has cardinality $n$, then $A times B$ has
cardinality $n dot m$.
]
#example[
Prove that $A times emptyset = emptyset$.
#proof[
Suppose that $A times emptyset != emptyset$. Then $exists (a,b), a in A, b in
emptyset$. But $b in emptyset$ is a contradiction by its definition.
]
]
== Index families of sets
#definition[A set of sets is called a family or collection of sets.]
#definition[
Let $Delta$ be a nonempty index set such that $forall alpha in Delta, exists
A_alpha$. The family of sets $cal(A) = {A_alpha : alpha in Delta}$ is an
index family of sets.
]
#example[
Let $A in {1,3}$ and consider $cal(P)(A)$.
]
#example[
Define $A_n = (n,n+2)$, the open interval from $n$ to $n+2$, for each $n in
NN$.
$cal(A) = {(n, N + 2) : n in NN} = {A_n : n in NN}$
Let $Delta = NN$ and then $alpha in Delta <=> n in NN$.
]
#definition[
The union over $cal(A)$ is the set
$ union.big_(A in cal(A)) A = {x : x in A, exists A in cal(A)} $
]
#definition[
The intersection over $cal(A)$ is the set
$ sect.big_(A in cal(A)) A = {x : x in A, forall A in cal(A)} $
]
#example[
Let $cal(A) = {{1}, {1,2},{2,3}}$. Then
$
&union.big_(A in cal(A)) A = {1,2,3} \
&sect.big_(A in cal(A)) A = emptyset
$
]
#example[
Let $A_n = [-1/n,1/n]$, the closed interval from $-1/n$ to $1/n$ for each $N in NN$. Consider the family of sets $cal(A) = {A_n : n in NN}$. Then
$
&union.big_(A in cal(A)) A = union.big_(n=1)^infinity A_n = A_1 union A_2 union A_3 union dots.c = {x : x in [-1,1]} \
&sect.big_(A in cal(A)) A = sect.big_(n=1)^infinity A_n = 0
$
]
#example[
Let $A_n = [0,n)$ for each $n in NN$ and let $cal(A) = {A_n : n in NN}$. Then
$
&union.big_(A in cal(A)) A = [0, infinity] \
&sect.big_(A in cal(A)) = [0,1)
$
]
= Solutions to selected exercises and problems
Solutions to selected problems and exercises.

30
documents/by-course/pstat-120a/hw1/main.typ
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@ -9,6 +9,19 @@
#set enum(spacing: 2em)
#let correction = content => {
set text(fill: red)
box(stroke: 1pt, inset: 5pt, content)
}
#correction[
There were 7 points off, so:
Initial score: 47/54
Corrected score: 52/52
]
+ #[
#set enum(numbering: "a)", spacing: 2em)
@ -44,7 +57,7 @@
#set enum(numbering: "a)", spacing: 2em)
+ ${15, 25, 35, 45, 51, 53, 55, 57, 59, 65, 75, 85, 95 }$
+ ${50, 52, 56, 58}$
+ ${50, 52, 54, 56, 58}$
+ $emptyset$
]
@ -64,6 +77,10 @@
represents balls numbered 1-6, and the value represents the square it
was sent to. So it's
$ {{x_1,x_2,x_3,x_4,x_5,x_6} : x_i in {1,2,3,4}}, i = 1,...6 $
#correction[
-1. We should probably write this more explicitly as ${1,2,3,4}^6$.
]
]
+ #[
When the balls are indistinguishable, we can instead represent it as
@ -100,6 +117,11 @@
+ #[
#set enum(numbering: "a)", spacing: 2em)
#correction[
-4.
These are all correct, but need to be divided by $vec(52,5)$ for the final probability. Oops...
]
+ #[
First we choose two ranks for our two pairs. Then we choose 2 suits for the
first pair and 2 suits for the second pair. Then we choose 1 card from the
@ -159,6 +181,12 @@
+ #[
First we enumerate all of the ways 4 numbers can add up to 13.
$ 2 dot 4! = 8 / 35 $
#correction[
-2. Correct way: directly find the how many outcomes sum to 13
$ {{1,2,3,7},{1,2,4,6},{1,3,4,5}} $
So the answer is simply these 3 outcomes divided by total ways to choose 4 numbers from 10:
$ 3 / vec(10,4) approx 0.0143 $
]
]
]

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documents/by-course/pstat-120a/hw2/main.typ Normal file
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@ -0,0 +1,109 @@
#import "@youwen/zen:0.1.0": *
#import "@preview/ctheorems:1.1.3": *
#import "@preview/mitex:0.2.5": *
#show: zen.with(
title: "Homework 2",
author: "Youwen Wu",
date: "Winter 2025",
)
#set enum(spacing: 2em)
#let correction = content => {
set text(fill: red)
box(stroke: 1pt, inset: 5pt, content)
}
#mitex(`
\textbf{Problem 1}
Let $P(A)$ denote the probability that a customer watches exactly one category of programs. From the problem:
\begin{itemize}
\item 70\% watch more than one category: $P(A^c) = 0.7 \Rightarrow P(A) = 0.3$.
\item 20\% watch sports: $P(S) = 0.2$.
\item Of those watching more than one category, 15\% watch sports: $P(S | A^c) = 0.15$.
\end{itemize}
We need $P(A \cap S^c)$, the probability a customer watches exactly one category and it is not sports:
\[
P(A \cap S^c) = P(A) - P(A \cap S).
\]
Since $P(A \cap S) = 0$ (sports watchers are counted under $P(A^c)$):
\[
P(A \cap S^c) = P(A) = 0.3.
\]
\textbf{Solution:} $P(A \cap S^c) = 0.3$.
\textbf{Problem 2}
We need $P(6|3,4)$, the probability the 6-sided die was chosen given rolls 3 and 4.
Using Bayes' Theorem:
\[
P(6|3,4) = \frac{P(3,4|6) P(6)}{P(3,4)}.
\]
Assuming equal probabilities of choosing any die ($P(4) = P(6) = P(12) = \frac{1}{3}$), and independent rolls:
\[
P(3,4|6) = P(3|6) P(4|6) = \frac{1}{6} \cdot \frac{1}{6} = \frac{1}{36}.
\]
\[
P(3,4) = \frac{1}{3}\left(\frac{1}{16} + \frac{1}{36} + \frac{1}{144}\right).
\]
Simplify and compute:
\[
P(6|3,4) = \frac{\frac{1}{36} \cdot \frac{1}{3}}{\frac{1}{3}\left(\frac{1}{16} + \frac{1}{36} + \frac{1}{144}\right)}.
\]
Numerical calculation gives $P(6|3,4) \approx 0.51$.
\textbf{Problem 3}
Probability a marble is blue after the second draw:
\[
P(\text{Blue on second draw}) = \frac{b}{n} \cdot \frac{b+k}{n+k} + \frac{g}{n} \cdot \frac{g+k}{n+k}.
\]
Simplify and substitute as needed.
\textbf{Problem 4}
(a) Probability of drawing two candies with the same flavor is:
\[
P(\text{same flavor}) = \sum_{pockets} P(\text{flavor from pocket})^2 \cdot P(\text{pocket})^2.
\]
(b) Bayesian calculations apply. Let heads/tails represent sequences, use Bayes' theorem.
(c) Set probabilities equal:
\[
\frac{2+x}{2+7+x} = \frac{5}{5+2}.
\]
Solve for $x$.
\textbf{Problem 5}
For independence: check $P(A \cap B) = P(A)P(B)$.
Repeat for other pairs.
\textbf{Problem 6}
Partition definition and law of total probability:
\[
P(A|B) = \sum P(A|B_i)P(B_i|B).
\]
Proof by substitution.
\textbf{Problem 7}
(a)-(c) Condition on defendant guilt and independence.
Use $P(\text{Guilty}) = 0.7$ and $P(\text{Innocent}) = 0.3$.
\textbf{Problem 8}
(a) Use total probability:
\[
P(A) = \sum P(A|word_i)P(word_i).
\]
(b) Enumerate possible word lengths.
`)

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documents/by-course/pstat-120a/hw2/package.nix Normal file
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@ -0,0 +1,37 @@
{
pkgs,
typstPackagesCache,
typixLib,
cleanTypstSource,
flakeSelf,
...
}:
let
src = cleanTypstSource ./.;
commonArgs = {
typstSource = "main.typ";
fontPaths = [
# Add paths to fonts here
# "${pkgs.roboto}/share/fonts/truetype"
];
virtualPaths = [
# Add paths that must be locally accessible to typst here
# {
# dest = "icons";
# src = "${inputs.font-awesome}/svgs/regular";
# }
];
XDG_CACHE_HOME = typstPackagesCache;
SOURCE_DATE_EPOCH = builtins.toString flakeSelf.lastModified;
};
in
typixLib.buildTypstProject (
commonArgs
// {
inherit src;
}
)