MA0301/exercise8/main.tex

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\documentclass[12pt]{article}
\usepackage{ntnu}
\usepackage{ntnu-math}
\usepackage{ntnu-code}
\author{Øystein Tveit}
\title{MA0301 Exercise 8}
\usepackage{amsthm}
\usepackage{mathabx}
\begin{document}
\ntnuTitle{}
\break{}
\begin{excs}
\exc{}
\begin{subexcs}
\subexc{}
Since there is only one president, the possibilities is the sum of candidates
\[ 5 + 8 = 13 \]
\subexc{}
For every candidate from one party there is all the candidates of the other party to be compared to. Therefore the amount of possibilities is
\[ 5 \cdot 8 = 13 \]
\end{subexcs}
\exc{}
\begin{subexcs}
\subexc{}
To end up with the amount of possibilities, we have to multiply the amounts of components together
\[ 4 \cdot 12 \cdot 3 \cdot 2 = 288 \]
\subexc{}
This reduces the amount of colors from 4 to 1. Therefore the amount of possibilities is
\[ 1 \cdot 4 \cdot 3 \cot 2 = 24 \]
\end{subexcs}
\exc{}
\begin{subexcs}
\subexc{}
Let one bakery item be either pastry or muffins.
\[ (8 + 6) \cdot (4 + 6 + 1 + 1) = 14 \cdot 12 = 168 \]
\subexc{}
\[ 14 \cdot 4 \cdot 6 \cdot 6 = 2016 \]
\subexc{}
\[ 8 \cdot 6 \cdot 6 \cdot 1 \cdot 2(14 \cdot 4) = 32256 \]
\end{subexcs}
\exc{}
\[ \nPr{8!}{8!} = \frac{8!}{(8-8)!} = 8! = 40320 \]
\exc{}
\begin{subexcs}
\subexc{}
\[ \nPr{7}{2} = \frac{7!}{(7-2)!} = \frac{7!}{5!} = 7 \cdot 6 = 42 \]
\subexc{}
\[ \nPr{8}{4} = \frac{8!}{(8-4)!} = 8 \cdot 7 \cdot 6 \cdot 5 = 1680 \]
\subexc{}
\[ \nPr{10}{7} = \frac{10!}{(10-7)!} = 10 \cdot 9 \cdot \ldots \cdot 4 = 604800 \]
\subexc{}
\[ \nPr{12}{3} = \frac{12!}{(12-3)!} = 12 \cdot 11 \cdot 10 = 1320 \]
\end{subexcs}
\exc{}
\begin{subexcs}
\subexc{}
\[ \nCr{10}{4} = \frac{10!}{4!(10-4)!} = \frac{10!}{4!6!} = \frac{10 \cdot \cancelto{3}{9} \cdot \cancelto{1}{8} \cdot 7}{1 \cdot \cancel{2} \cdot \cancel{3} \cdot \cancel{4}} = 10 \cdot 3 \cdot 7 = 210 \]
\subexc{}
\[ \nCr{12}{7} = \frac{12!}{7!5!} = \frac{\cancelto{1}{12} \cdot 11 \cdot \cancelto{1}{10} \cdot 9 \cdot 8}{1 \cdot \cancel{2} \cdot \cancel{3} \cdot \cancel{4} \cdot \cancel{5}} = 11 \cdot 9 \cdot 8 = 792 \]
\subexc{}
\[ \nCr{14}{12} = \frac{14!}{12!2!} = \frac{14 \cdot 13}{2} = 91 \]
\subexc{}
\[ \nCr{15}{10} = \frac{15!}{10!5!} = \frac{\cancelto{1}{15} \cdot \cancelto{7}{14} \cdot 13 \cdot \cancelto{3}{12} \cdot 11}{1 \cdot \cancel{2} \cdot \cancel{3} \cdot \cancel{4} \cdot \cancel{5}} = 7 \cdot 13 \cdot 3 \cdot 11 = 3003 \]
\end{subexcs}
\exc{}
\begin{subexcs}
\subexc{}
If there are no restrictions, the amount of arrangements will be the number of permutations of the books
\[ \nPr{7}{7} = 7! \]
In order for the languages to alternate, the 3 books has to be inbetween each of the 4 books
There are $\nPr{3}{3}$ permutations of the C++ books. For each of those permutations, there are $\nPr{4}{4}$ permutations of the Java books.
Hence the amount of ways to arrange the books will be
\subexc{}
\[ \nPr{3,3} \cdot \nPr{4}{4} = 3! \cdot 4! = 144 \]
Because all the C++ books has to be together, we can think of them like one "block" in the permutations of 5 blocks where four of the blocks are Java books.
For each of those blocks, there is $\nPr{3}{3}$ arrangements of the C++ books.
Hence the amount of ways to arrange the books will be
\subexc{}
\[ \nPr{3}{3} \cdot \nPr{5}{5} = 3! \cdot 5! = 720 \]
Here, there are just two blocks. Therefore there is only $\nPr{2}{2}$ permutations of the blocks
For each of those permutations, there are $\nPr{3}{3}$ ways to arrange the C++ books.
And for each way to arrange the C++ books, there are $\nPr{4}{4}$ ways to arrange the java books.
Hence the amount of ways to arrange the books will be
\subexc{}
\[ \nPr{2}{2} \cdot \nPr{3}{3} \cdot \nPr{4}{4} = 288 \]
\end{subexcs}
\exc{}
\begin{subexcs}
\subexc{}
Because we don't care if there's a different order that the people were selected, we have to use combinations.
No restrictions means every combination of 12 in 20 people.
\[ \nCr{20}{12} = 125970 \]
\subexc{}
For every combination of six women, we have every combination of six men.
\[ \nCr{10}{6} \cdot \nCr{10}{6} = 44100 \]
\subexc{}
Here we sum together all the combinations where there is an even number of women for every corresponding combination of men.
\[ \sum^5_{i=0} \nCr{10}{2i} \cdot \nCr{10}{2(6-i)} = 63090 \]
\subexc{}
In order for the selection to contain more women than men, the amount of women has to be 7 so that the amount of men is 5.
Therefore, we sum together all combination products from 7 to 10.
\[ \sum^{10}_{i=7} \nCr{10}{i} \cdot \nCr{10}{12-i} = 40935 \]
\subexc{}
Sum of all combination products from 8 to 10.
\[ \sum^{10}_{i=8} \nCr{10}{i} \cdot \nCr{10}{12-i} = 10695 \]
\end{subexcs}
\exc{}
In order to solve this task, we will sum together separate cases \\
Case i) The number only contains one distinct digit from $\{1, 3, 7, 8\}$
This would be all the permutations of the digits, that is
\[ \nPr{4}{4} \] \\
Case ii) The number contains 2 of the digit $3$ and two distinct digits from $\{1, 7, 8\}$
Here, we start with all the ways we can form a four digit number including two of the digit $3$.
Since we don't care what order the $3$s are in, we want the combinations (for example, $x{\color{red}3}{\color{ForestGreen}3}x$ and $x{\color{ForestGreen}3}{\color{red}3}x$ are the same)
Therefore the amount of ways we can write a four digit number including two of the digit $3$ would be
\[\nCr{4}{2}\]
For each of those ways to write the number, there are all the permutations of the remaining digits ways to construct a number (here order does matter since the digits are distinct)
Hence, the amount of ways we can write this number would be
\[\nCr{4}{2} \cdot \nPr{3}{3}\] \\
Case iii) The number contains 2 of the digit $7$ and two distinct digits from $\{1, 3, 8\}$
This is the same as Case ii, just with $7$s instead of $3s$ \\
Case iv) The number contains 2 of the digit $3$ and 2 of the digit $7$
In this case, the amount of combinations would be the same as the amount of the ways we can write a four digit number with two fixed numbers.
Hence, the amount of ways we can write this number would be
\[\nCr{4}{2}\]
In conclusion, the total amount of distinct four digit integers we can make with the digits $1$, $3$, $3$, $7$, $7$, $8$ would be
\[ \nPr{4}{4} + \nCr{4}{2} \cdot \nPr{3}{3} \cdot 2 + \nCr{4}{2} = 102 \]
\exc{}
Here i wrote a program to calculate a modified pascal triangle and print the coefficients of a specific row
\codeFile{scripts/pascal.py}{python}
Here are the results:
\begin{verbatim}
a.
1 x^12 y^0
12 x^11 y^1
66 x^10 y^2
220 x^9 y^3
495 x^8 y^4
792 x^7 y^5
924 x^6 y^6
792 x^5 y^7
495 x^4 y^8
220 x^3 y^9
66 x^2 y^10
12 x^1 y^11
1 x^0 y^12
b.
1 x^12 y^0
24 x^11 y^1
264 x^10 y^2
1760 x^9 y^3
7920 x^8 y^4
25344 x^7 y^5
59136 x^6 y^6
101376 x^5 y^7
126720 x^4 y^8
112640 x^3 y^9
67584 x^2 y^10
24576 x^1 y^11
4096 x^0 y^12
c.
4096 x^12 y^0
-73728 x^11 y^1
608256 x^10 y^2
-3041280 x^9 y^3
10264320 x^8 y^4
-24634368 x^7 y^5
43110144 x^6 y^6
-55427328 x^5 y^7
51963120 x^4 y^8
-34642080 x^3 y^9
15588936 x^2 y^10
-4251528 x^1 y^11
531441 x^0 y^12
\end{verbatim}
Which means that the coefficient for $x^9y^3$ for each of the subexercises would be
\begin{subexcs}
\subexc{}
\[ 220 \]
\subexc{}
\[ 17601 \]
\subexc{}
\[ -3041280 \]
\end{subexcs}
\end{excs}
\end{document}