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1

Here, we show you a step-by-step solved example of binomial theorem. This solution was automatically generated by our smart calculator:

$\left(x+3\right)^5$
2

We can expand the expression $\left(x+3\right)^5$ using Newton's binomial theorem, which is a formula that allow us to find the expanded form of a binomial raised to a positive integer $n$. The formula is as follows: $\displaystyle(a\pm b)^n=\sum_{k=0}^{n}\left(\begin{matrix}n\\k\end{matrix}\right)a^{n-k}b^k=\left(\begin{matrix}n\\0\end{matrix}\right)a^n\pm\left(\begin{matrix}n\\1\end{matrix}\right)a^{n-1}b+\left(\begin{matrix}n\\2\end{matrix}\right)a^{n-2}b^2\pm\dots\pm\left(\begin{matrix}n\\n\end{matrix}\right)b^n$. The number of terms resulting from the expansion always equals $n + 1$. The coefficients $\left(\begin{matrix}n\\k\end{matrix}\right)$ are combinatorial numbers which correspond to the nth row of the Tartaglia triangle (or Pascal's triangle). In the formula, we can observe that the exponent of $a$ decreases, from $n$ to $0$, while the exponent of $b$ increases, from $0$ to $n$. If one of the binomial terms is negative, the positive and negative signs alternate.

$\left(\begin{matrix}5\\0\end{matrix}\right)\cdot 3^{0}x^{5}+\left(\begin{matrix}5\\1\end{matrix}\right)\cdot 3^{1}x^{4}+\left(\begin{matrix}5\\2\end{matrix}\right)\cdot 3^{2}x^{3}+\left(\begin{matrix}5\\3\end{matrix}\right)\cdot 3^{3}x^{2}+\left(\begin{matrix}5\\4\end{matrix}\right)\cdot 3^{4}x^{1}+\left(\begin{matrix}5\\5\end{matrix}\right)\cdot 3^{5}x^{0}$
3

Calculate the power $3^{0}$

$1\left(\begin{matrix}5\\0\end{matrix}\right)x^{5}+\left(\begin{matrix}5\\1\end{matrix}\right)\cdot 3^{1}x^{4}+\left(\begin{matrix}5\\2\end{matrix}\right)\cdot 3^{2}x^{3}+\left(\begin{matrix}5\\3\end{matrix}\right)\cdot 3^{3}x^{2}+\left(\begin{matrix}5\\4\end{matrix}\right)\cdot 3^{4}x^{1}+\left(\begin{matrix}5\\5\end{matrix}\right)\cdot 3^{5}x^{0}$
4

Calculate the power $3^{1}$

$1\left(\begin{matrix}5\\0\end{matrix}\right)x^{5}+3\left(\begin{matrix}5\\1\end{matrix}\right)x^{4}+\left(\begin{matrix}5\\2\end{matrix}\right)\cdot 3^{2}x^{3}+\left(\begin{matrix}5\\3\end{matrix}\right)\cdot 3^{3}x^{2}+\left(\begin{matrix}5\\4\end{matrix}\right)\cdot 3^{4}x^{1}+\left(\begin{matrix}5\\5\end{matrix}\right)\cdot 3^{5}x^{0}$
5

Calculate the power $3^{2}$

$1\left(\begin{matrix}5\\0\end{matrix}\right)x^{5}+3\left(\begin{matrix}5\\1\end{matrix}\right)x^{4}+9\left(\begin{matrix}5\\2\end{matrix}\right)x^{3}+\left(\begin{matrix}5\\3\end{matrix}\right)\cdot 3^{3}x^{2}+\left(\begin{matrix}5\\4\end{matrix}\right)\cdot 3^{4}x^{1}+\left(\begin{matrix}5\\5\end{matrix}\right)\cdot 3^{5}x^{0}$
6

Calculate the power $3^{3}$

$1\left(\begin{matrix}5\\0\end{matrix}\right)x^{5}+3\left(\begin{matrix}5\\1\end{matrix}\right)x^{4}+9\left(\begin{matrix}5\\2\end{matrix}\right)x^{3}+27\left(\begin{matrix}5\\3\end{matrix}\right)x^{2}+\left(\begin{matrix}5\\4\end{matrix}\right)\cdot 3^{4}x^{1}+\left(\begin{matrix}5\\5\end{matrix}\right)\cdot 3^{5}x^{0}$
7

Calculate the power $3^{4}$

$1\left(\begin{matrix}5\\0\end{matrix}\right)x^{5}+3\left(\begin{matrix}5\\1\end{matrix}\right)x^{4}+9\left(\begin{matrix}5\\2\end{matrix}\right)x^{3}+27\left(\begin{matrix}5\\3\end{matrix}\right)x^{2}+81\left(\begin{matrix}5\\4\end{matrix}\right)x^{1}+\left(\begin{matrix}5\\5\end{matrix}\right)\cdot 3^{5}x^{0}$
8

Calculate the power $3^{5}$

$1\left(\begin{matrix}5\\0\end{matrix}\right)x^{5}+3\left(\begin{matrix}5\\1\end{matrix}\right)x^{4}+9\left(\begin{matrix}5\\2\end{matrix}\right)x^{3}+27\left(\begin{matrix}5\\3\end{matrix}\right)x^{2}+81\left(\begin{matrix}5\\4\end{matrix}\right)x^{1}+243\left(\begin{matrix}5\\5\end{matrix}\right)x^{0}$
9

Any expression to the power of $1$ is equal to that same expression

$1\left(\begin{matrix}5\\0\end{matrix}\right)x^{5}+3\left(\begin{matrix}5\\1\end{matrix}\right)x^{4}+9\left(\begin{matrix}5\\2\end{matrix}\right)x^{3}+27\left(\begin{matrix}5\\3\end{matrix}\right)x^{2}+81\left(\begin{matrix}5\\4\end{matrix}\right)x+243\left(\begin{matrix}5\\5\end{matrix}\right)x^{0}$
10

Any expression multiplied by $1$ is equal to itself

$\left(\begin{matrix}5\\0\end{matrix}\right)x^{5}+3\left(\begin{matrix}5\\1\end{matrix}\right)x^{4}+9\left(\begin{matrix}5\\2\end{matrix}\right)x^{3}+27\left(\begin{matrix}5\\3\end{matrix}\right)x^{2}+81\left(\begin{matrix}5\\4\end{matrix}\right)x+243\left(\begin{matrix}5\\5\end{matrix}\right)x^{0}$
11

Any expression (except $0$ and $\infty$) to the power of $0$ is equal to $1$

$\left(\begin{matrix}5\\0\end{matrix}\right)x^{5}+3\left(\begin{matrix}5\\1\end{matrix}\right)x^{4}+9\left(\begin{matrix}5\\2\end{matrix}\right)x^{3}+27\left(\begin{matrix}5\\3\end{matrix}\right)x^{2}+81\left(\begin{matrix}5\\4\end{matrix}\right)x+243\left(\begin{matrix}5\\5\end{matrix}\right)$
12

Calculate the binomial coefficient $\left(\begin{matrix}5\\0\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}$
13

The factorial of $0$ is $1$

$\frac{5!}{1\cdot 1}x^{5}$
14

The factorial of $5$ is $120$

$\frac{120}{1\cdot 1}x^{5}$
15

Any expression multiplied by $1$ is equal to itself

$120x^{5}$
16

Calculate the binomial coefficient $\left(\begin{matrix}5\\0\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}$
17

The factorial of $0$ is $1$

$\frac{5!}{1\cdot 1}x^{5}$
18

The factorial of $5$ is $120$

$\frac{120}{1\cdot 1}x^{5}$
19

Any expression multiplied by $1$ is equal to itself

$120x^{5}$
20

Calculate the binomial coefficient $\left(\begin{matrix}5\\1\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$3\frac{5!}{\left(1!\right)\left(5-1\right)!}x^{4}$
21

The factorial of $1$ is $1$

$3\frac{5!}{1\cdot 1}x^{4}$
22

The factorial of $5$ is $120$

$3\frac{120}{1\cdot 1}x^{4}$
23

Any expression multiplied by $1$ is equal to itself

$120\cdot 3x^{4}$
24

Calculate the binomial coefficient $\left(\begin{matrix}5\\0\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}$
25

The factorial of $0$ is $1$

$\frac{5!}{1\cdot 1}x^{5}$
26

The factorial of $5$ is $120$

$\frac{120}{1\cdot 1}x^{5}$
27

Any expression multiplied by $1$ is equal to itself

$120x^{5}$
28

Calculate the binomial coefficient $\left(\begin{matrix}5\\1\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$3\frac{5!}{\left(1!\right)\left(5-1\right)!}x^{4}$
29

The factorial of $1$ is $1$

$3\frac{5!}{1\cdot 1}x^{4}$
30

The factorial of $5$ is $120$

$3\frac{120}{1\cdot 1}x^{4}$
31

Any expression multiplied by $1$ is equal to itself

$120\cdot 3x^{4}$
32

Calculate the binomial coefficient $\left(\begin{matrix}5\\2\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$9\frac{5!}{\left(2!\right)\left(5-2\right)!}x^{3}$
33

The factorial of $2$ is $2$

$9\frac{5!}{2\cdot 1}x^{3}$
34

The factorial of $5$ is $120$

$9\frac{120}{2\cdot 1}x^{3}$
35

Any expression multiplied by $1$ is equal to itself

$9\frac{120}{2}x^{3}$
36

Calculate the binomial coefficient $\left(\begin{matrix}5\\0\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}$
37

The factorial of $0$ is $1$

$\frac{5!}{1\cdot 1}x^{5}$
38

The factorial of $5$ is $120$

$\frac{120}{1\cdot 1}x^{5}$
39

Any expression multiplied by $1$ is equal to itself

$120x^{5}$
40

Calculate the binomial coefficient $\left(\begin{matrix}5\\1\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$3\frac{5!}{\left(1!\right)\left(5-1\right)!}x^{4}$
41

The factorial of $1$ is $1$

$3\frac{5!}{1\cdot 1}x^{4}$
42

The factorial of $5$ is $120$

$3\frac{120}{1\cdot 1}x^{4}$
43

Any expression multiplied by $1$ is equal to itself

$120\cdot 3x^{4}$
44

Calculate the binomial coefficient $\left(\begin{matrix}5\\2\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$9\frac{5!}{\left(2!\right)\left(5-2\right)!}x^{3}$
45

The factorial of $2$ is $2$

$9\frac{5!}{2\cdot 1}x^{3}$
46

The factorial of $5$ is $120$

$9\frac{120}{2\cdot 1}x^{3}$
47

Any expression multiplied by $1$ is equal to itself

$9\frac{120}{2}x^{3}$
48

Calculate the binomial coefficient $\left(\begin{matrix}5\\3\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$27\frac{5!}{\left(3!\right)\left(5-3\right)!}x^{2}$
49

The factorial of $3$ is $6$

$27\frac{5!}{6\cdot 1}x^{2}$
50

The factorial of $5$ is $120$

$27\frac{120}{6\cdot 1}x^{2}$
51

Any expression multiplied by $1$ is equal to itself

$27\frac{120}{6}x^{2}$
52

Calculate the binomial coefficient $\left(\begin{matrix}5\\0\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}$
53

The factorial of $0$ is $1$

$\frac{5!}{1\cdot 1}x^{5}$
54

The factorial of $5$ is $120$

$\frac{120}{1\cdot 1}x^{5}$
55

Any expression multiplied by $1$ is equal to itself

$120x^{5}$
56

Calculate the binomial coefficient $\left(\begin{matrix}5\\1\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$3\frac{5!}{\left(1!\right)\left(5-1\right)!}x^{4}$
57

The factorial of $1$ is $1$

$3\frac{5!}{1\cdot 1}x^{4}$
58

The factorial of $5$ is $120$

$3\frac{120}{1\cdot 1}x^{4}$
59

Any expression multiplied by $1$ is equal to itself

$120\cdot 3x^{4}$
60

Calculate the binomial coefficient $\left(\begin{matrix}5\\2\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$9\frac{5!}{\left(2!\right)\left(5-2\right)!}x^{3}$
61

The factorial of $2$ is $2$

$9\frac{5!}{2\cdot 1}x^{3}$
62

The factorial of $5$ is $120$

$9\frac{120}{2\cdot 1}x^{3}$
63

Any expression multiplied by $1$ is equal to itself

$9\frac{120}{2}x^{3}$
64

Calculate the binomial coefficient $\left(\begin{matrix}5\\3\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$27\frac{5!}{\left(3!\right)\left(5-3\right)!}x^{2}$
65

The factorial of $3$ is $6$

$27\frac{5!}{6\cdot 1}x^{2}$
66

The factorial of $5$ is $120$

$27\frac{120}{6\cdot 1}x^{2}$
67

Any expression multiplied by $1$ is equal to itself

$27\frac{120}{6}x^{2}$
68

Calculate the binomial coefficient $\left(\begin{matrix}5\\4\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$81\frac{5!}{\left(4!\right)\left(5-4\right)!}x$
69

The factorial of $4$ is $24$

$81\frac{5!}{24\cdot 1}x$
70

The factorial of $5$ is $120$

$81\frac{120}{24\cdot 1}x$
71

Any expression multiplied by $1$ is equal to itself

$81\frac{120}{24}x$
72

Subtract the values $5$ and $-1$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(5-2\right)!}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(5-3\right)!}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(5-4\right)!}x+243\left(\begin{matrix}5\\5\end{matrix}\right)$
73

Subtract the values $5$ and $-2$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(5-3\right)!}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(5-4\right)!}x+243\left(\begin{matrix}5\\5\end{matrix}\right)$
74

Subtract the values $5$ and $-3$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(5-4\right)!}x+243\left(\begin{matrix}5\\5\end{matrix}\right)$
75

Subtract the values $5$ and $-4$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+243\left(\begin{matrix}5\\5\end{matrix}\right)$
76

Add the values $5$ and $0$

$\frac{5!}{\left(0!\right)\left(5!\right)}x^{5}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+243\left(\begin{matrix}5\\5\end{matrix}\right)$
77

Simplify the fraction $\frac{5!}{\left(0!\right)\left(5!\right)}$ by $5!$

$\frac{1}{0!}x^{5}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+243\left(\begin{matrix}5\\5\end{matrix}\right)$
78

Multiply the fraction by the term

$\frac{1x^{5}}{0!}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+243\left(\begin{matrix}5\\5\end{matrix}\right)$
79

Any expression multiplied by $1$ is equal to itself

$\frac{x^{5}}{0!}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+243\left(\begin{matrix}5\\5\end{matrix}\right)$
80

Calculate the binomial coefficient $\left(\begin{matrix}5\\0\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$\frac{5!}{\left(0!\right)\left(5+0\right)!}x^{5}$
81

The factorial of $0$ is $1$

$\frac{5!}{1\cdot 1}x^{5}$
82

The factorial of $5$ is $120$

$\frac{120}{1\cdot 1}x^{5}$
83

Any expression multiplied by $1$ is equal to itself

$120x^{5}$
84

Calculate the binomial coefficient $\left(\begin{matrix}5\\1\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$3\frac{5!}{\left(1!\right)\left(5-1\right)!}x^{4}$
85

The factorial of $1$ is $1$

$3\frac{5!}{1\cdot 1}x^{4}$
86

The factorial of $5$ is $120$

$3\frac{120}{1\cdot 1}x^{4}$
87

Any expression multiplied by $1$ is equal to itself

$120\cdot 3x^{4}$
88

Calculate the binomial coefficient $\left(\begin{matrix}5\\2\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$9\frac{5!}{\left(2!\right)\left(5-2\right)!}x^{3}$
89

The factorial of $2$ is $2$

$9\frac{5!}{2\cdot 1}x^{3}$
90

The factorial of $5$ is $120$

$9\frac{120}{2\cdot 1}x^{3}$
91

Any expression multiplied by $1$ is equal to itself

$9\frac{120}{2}x^{3}$
92

Calculate the binomial coefficient $\left(\begin{matrix}5\\3\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$27\frac{5!}{\left(3!\right)\left(5-3\right)!}x^{2}$
93

The factorial of $3$ is $6$

$27\frac{5!}{6\cdot 1}x^{2}$
94

The factorial of $5$ is $120$

$27\frac{120}{6\cdot 1}x^{2}$
95

Any expression multiplied by $1$ is equal to itself

$27\frac{120}{6}x^{2}$
96

Calculate the binomial coefficient $\left(\begin{matrix}5\\4\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$81\frac{5!}{\left(4!\right)\left(5-4\right)!}x$
97

The factorial of $4$ is $24$

$81\frac{5!}{24\cdot 1}x$
98

The factorial of $5$ is $120$

$81\frac{120}{24\cdot 1}x$
99

Any expression multiplied by $1$ is equal to itself

$81\frac{120}{24}x$
100

Calculate the binomial coefficient $\left(\begin{matrix}5\\5\end{matrix}\right)$ applying the formula: $\left(\begin{matrix}n\\k\end{matrix}\right)=\frac{n!}{k!(n-k)!}$

$243\left(\frac{5!}{\left(5!\right)\left(5-5\right)!}\right)$
101

Simplify the fraction $\frac{5!}{\left(5!\right)\left(5-5\right)!}$ by $5!$

$243\left(\frac{1}{\left(5-5\right)!}\right)$
102

Subtract the values $5$ and $-5$

$\frac{x^{5}}{0!}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243\left(5!\right)}{\left(5!\right)\left(0!\right)}$
103

Simplify the fraction $\frac{243\left(5!\right)}{\left(5!\right)\left(0!\right)}$ by $5!$

$\frac{x^{5}}{0!}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
104

The factorial of $0$ is $1$

$\frac{x^{5}}{1}+\frac{3\left(5!\right)}{\left(1!\right)\left(4!\right)}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
105

The factorial of $1$ is $1$

$\frac{x^{5}}{1}+\frac{3\left(5!\right)}{1\cdot 24}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
106

The factorial of $5$ is $120$

$\frac{x^{5}}{1}+\frac{3\cdot 120}{1\cdot 24}x^{4}+\frac{9\left(5!\right)}{\left(2!\right)\left(3!\right)}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
107

The factorial of $2$ is $2$

$\frac{x^{5}}{1}+\frac{3\cdot 120}{1\cdot 24}x^{4}+\frac{9\left(5!\right)}{2\cdot 6}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
108

The factorial of $5$ is $120$

$\frac{x^{5}}{1}+\frac{3\cdot 120}{1\cdot 24}x^{4}+\frac{9\cdot 120}{2\cdot 6}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
109

Multiply $1$ times $24$

$\frac{x^{5}}{1}+\frac{3\cdot 120}{24}x^{4}+\frac{9\cdot 120}{2\cdot 6}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
110

Multiply $3$ times $120$

$\frac{x^{5}}{1}+\frac{360}{24}x^{4}+\frac{9\cdot 120}{2\cdot 6}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
111

Multiply $2$ times $6$

$\frac{x^{5}}{1}+\frac{360}{24}x^{4}+\frac{9\cdot 120}{12}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
112

Multiply $9$ times $120$

$\frac{x^{5}}{1}+\frac{360}{24}x^{4}+\frac{1080}{12}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
113

Divide $360$ by $24$

$\frac{x^{5}}{1}+15x^{4}+\frac{1080}{12}x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
114

Divide $1080$ by $12$

$\frac{x^{5}}{1}+15x^{4}+90x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
115

Any expression divided by one ($1$) is equal to that same expression

$x^{5}+15x^{4}+90x^{3}+\frac{27\left(5!\right)}{\left(3!\right)\left(2!\right)}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
116

The factorial of $3$ is $6$

$x^{5}+15x^{4}+90x^{3}+\frac{27\left(5!\right)}{6\cdot 2}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
117

The factorial of $5$ is $120$

$x^{5}+15x^{4}+90x^{3}+\frac{27\cdot 120}{6\cdot 2}x^{2}+\frac{81\left(5!\right)}{\left(4!\right)\left(1!\right)}x+\frac{243}{0!}$
118

The factorial of $4$ is $24$

$x^{5}+15x^{4}+90x^{3}+\frac{27\cdot 120}{6\cdot 2}x^{2}+\frac{81\left(5!\right)}{24\cdot 1}x+\frac{243}{0!}$
119

The factorial of $5$ is $120$

$x^{5}+15x^{4}+90x^{3}+\frac{27\cdot 120}{6\cdot 2}x^{2}+\frac{81\cdot 120}{24\cdot 1}x+\frac{243}{0!}$
120

The factorial of $0$ is $1$

$x^{5}+15x^{4}+90x^{3}+\frac{27\cdot 120}{6\cdot 2}x^{2}+\frac{81\cdot 120}{24\cdot 1}x+\frac{243}{1}$
121

Multiply $6$ times $2$

$x^{5}+15x^{4}+90x^{3}+\frac{27\cdot 120}{12}x^{2}+\frac{81\cdot 120}{24\cdot 1}x+\frac{243}{1}$
122

Multiply $27$ times $120$

$x^{5}+15x^{4}+90x^{3}+\frac{3240}{12}x^{2}+\frac{81\cdot 120}{24\cdot 1}x+\frac{243}{1}$
123

Multiply $24$ times $1$

$x^{5}+15x^{4}+90x^{3}+\frac{3240}{12}x^{2}+\frac{81\cdot 120}{24}x+\frac{243}{1}$
124

Multiply $81$ times $120$

$x^{5}+15x^{4}+90x^{3}+\frac{3240}{12}x^{2}+\frac{9720}{24}x+\frac{243}{1}$
125

Divide $3240$ by $12$

$x^{5}+15x^{4}+90x^{3}+270x^{2}+\frac{9720}{24}x+\frac{243}{1}$
126

Divide $9720$ by $24$

$x^{5}+15x^{4}+90x^{3}+270x^{2}+405x+\frac{243}{1}$
127

Divide $243$ by $1$

$x^{5}+15x^{4}+90x^{3}+270x^{2}+405x+243$

Risposta finale al problema

$x^{5}+15x^{4}+90x^{3}+270x^{2}+405x+243$

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