Sum and multiplication of real numbers

Calculate the approximations of the addition, subtraction, product and division of the following pairs of numbers: a) $\dfrac{1}{3}$ and $\pi$

b) $\dfrac{1}{7}$ and $\sqrt{2}$

a) For the number $\dfrac{1}{3}$ the approximations are:

$0,3$

$0,33$

$0,333$

$0,3333$

$\ldots$

For the number $\pi$ the approximations are:

$3,1$

$3,14$

$3,141$

$3,1415$

$\ldots$

For the addition of $\dfrac{1}{3}$ and $\pi$:

$0,3+3,1=3,4$

$0,33+3,14=3,47$

$0,333+3,141=3,474$

$0,3333+3,1415=3,4748$

$\ldots$

For the subtraction of $\dfrac{1}{3}$ and $\pi$:

$0,3-3,1=-2,8$

$0,33-3,14=-2,81$

$0,333-3,141=-2,808$

$0,3333-3,1415=-2,8082$

$\ldots$

For the multiplication of $\dfrac{1}{3}$ by $\pi$:

$0,3 \cdot 3,1=0,93$

$0,33 \cdot 3,14=1,0362$

$0,333 \cdot 3,141=1,045953$

$0,3333 \cdot 3,1415=1,04706195$

$\ldots$

For the division of $\dfrac{1}{3}$ by $\pi$:

$0,3 / 3,1=0,096774$

$0,33 / 3,14=0,105095$

$0,333 / 3,141=0,106017$

$0,3333 / 3,1415=0,106095$

$\ldots$

b) For the number $\dfrac{1}{7}$ the approximations are:

$0,1$

$0,14$

$0,142$

$0,1428$

$\ldots$

For the number $\sqrt{2}$ the approximations are:

$1,4$

$1,41$

$1,414$

$1,4142$

$\ldots$

For the addition of $\dfrac{1}{7}$ and $\sqrt{2}$:

$0,1+1,4=1,5$

$0,14+1,41=1,55$

$0,142+1,414=1,556$

$0,1428+1,4142=1,5570$

$\ldots$

For the subtraction of $\dfrac{1}{7}$ and $\sqrt{2}$:

$0,1-1,4=-1,3$

$0,14-1,41=-1,27$

$0,142-1,414=-1,272$

$0,1428-1,4142=-1,2714$

$\ldots$

For the multiplication of $\dfrac{1}{7}$ by $\sqrt{2}$:

$0,1 \cdot 1,4=0,14$

$0,14 \cdot 1,41=0,1974$

$0,142 \cdot 1,414=0,20022$

$0,1428 \cdot 1,4142=0,20194776$

$\ldots$

For the quotient of $\dfrac{1}{7}$ by $\sqrt{2}$:

$0,1 / 1,4=0,0714285$

$0,14 / 1,41=0,0992907$

$0,142 / 1,414=0,1004243$

$0,1428 / 1,4142=0,1009758$

$\ldots$

a) For the addition of $\dfrac{1}{3}$ and $\pi$: $3,4748$

For the subtraction of $\dfrac{1}{3}$ and $\pi$: $-2,8082$

For the multiplication of $\dfrac{1}{3}$ by $\pi$: $1,04706195$

For the division of $\dfrac{1}{3}$ by $\pi$: $0,106095$

b) For the addition of $\dfrac{1}{7}$ and $\sqrt{2}$: $1,5570$

For the subtraction of $\dfrac{1}{7}$ and $\sqrt{2}$: $-1,2714$

For the multiplication of $\dfrac{1}{7}$ by $\sqrt{2}$: $0,20194776$

For the division of $\dfrac{1}{7}$ by $\sqrt{2}$: $0,1009758$

Describe how would you graphically draw the real numbers:

$\sqrt{2}+\sqrt{3}$
$\sqrt{2}-\sqrt{3}$
$\sqrt{3}-\sqrt{2}$
$\sqrt{2}\cdot\sqrt{3}$
$\dfrac{\sqrt{2}}{\sqrt{3}}$

We draw on the straight line the numbers $\sqrt{2}$ and $\sqrt{3}$ using the construction of rectangular triangles.

Now we move the segment $\overline{0\sqrt{3}}$ beginning from point $\sqrt{2}$. The point that we obtain corresponds to $\sqrt{2}+\sqrt{3}$.

We draw on the straight line the numbers $\sqrt{2}$ and $\sqrt{3}$. Next we move the segment $\overline{0\sqrt{3}}$ beginning from point $\sqrt{2}$, to the left (instead of to the right as we have done in the last exercice). The point that we obtain corresponds to $\sqrt{2}-\sqrt{3}$.
We draw on the straight line the numbers $\sqrt{2}$ and $\sqrt{3}$. This time we move towards the left the segment $\overline{0\sqrt{2}}$ from point $\sqrt{3}$, and the point that we obtain corresponds to $\sqrt{3}-\sqrt{2}$.
We draw on the straight line the numbers $\sqrt{2}$, $\sqrt{3}$ and the unit.

Now we move the segment $\overline{0\sqrt{3}}$ from the zero of an auxiliary straight line, finding the point $P$ .

We draw a straight line which joins the point $P$ and point $1$, and then we draw its parallel that goes through the point $\sqrt{2}$, obtaining the point $P'$ which being moved to the real straight line, gives us the point $\sqrt{2}\cdot\sqrt{3}$.

We will first try to find, on the straight line, the point $(\sqrt{3})^{-1}=\dfrac{1}{\sqrt{3}}$. So, we draw on the straight line the points $\sqrt{3}, 1$ and $0$.

Now, we draw on an auxiliary straight line a point $P$ moving the segment $\overline{01}$. We draw the straight line that joins point $P$ with point $\sqrt{3}$, and we draw a parallel to this one which crosses point $1$. In that way, we will find point $P'$ on the auxiliary straight line. Then, we only need to move the point $P'$ to the real straight line, obtaining in this way the point $(\sqrt{3})^{-1}$.

We place on the same straight line point $\sqrt{2}$ to be able to calculate the product between $\sqrt{2}$ and $(\sqrt{3})^{-1}$.

We move the segment $\overline{0(\sqrt{3})^{-1}}$ from the zero of an auxiliary straight line, finding point $P$.

We draw a straight line that joins point $P$ and point $1$, and then we draw its parallel that goes through point $\sqrt{2}$, obtaining point $P'$ that, being moved to the real straight line, gives us point $\sqrt{2}\cdot \dfrac{1}{\sqrt{3}}= \dfrac{\sqrt{2}}{\sqrt{3}}.$

1, 2 and 3. We draw on the straight line the numbers $\sqrt{2}$ and $\sqrt{3}$. Following the established procedures we draw the corresponding numbers.

We draw on the straight line the numbers $\sqrt{2}$ and $\sqrt{3}$. Using the Thales' Theorem we can obtain the result of $\sqrt{2}\cdot\sqrt{3}$.
We draw on the straight line the numbers $\sqrt{2}$ and $\sqrt{3}$. We can then solve the operation $(\sqrt{3})^{-1}$.

Using the method to multiply the number we solve the number $\sqrt{2}\cdot \dfrac{1}{\sqrt{3}}= \dfrac{\sqrt{2}}{\sqrt{3}}.$

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