Got stuck on final part of injectivity proof, finished all the rest
This commit is contained in:
Binary file not shown.
Binary file not shown.
@@ -156,7 +156,7 @@ See the assignment PDF for the full assignment specification and theorem.
|
|||||||
$\frac{2^1 * 3^1}{5^1} = \frac{6}{5}$.
|
$\frac{2^1 * 3^1}{5^1} = \frac{6}{5}$.
|
||||||
\item In order to prove that $f$ is a bijection, we have to prove that $f$ is injective and surjective.
|
\item In order to prove that $f$ is a bijection, we have to prove that $f$ is injective and surjective.
|
||||||
\begin{description}
|
\begin{description}
|
||||||
\item[Surjectivity:] We want to show that $f$ is 1-1,
|
\item[Injectivity:] We want to show that $f$ is 1-1,
|
||||||
i.e. $f(x_1)=f(x_2) \implies x_1 = x_2$.
|
i.e. $f(x_1)=f(x_2) \implies x_1 = x_2$.
|
||||||
|
|
||||||
So, let's assume that for any $x_1, x_2 \in \{ q > 0 : q \in \Q \}$, $f(x_1) = f(x_2)$.
|
So, let's assume that for any $x_1, x_2 \in \{ q > 0 : q \in \Q \}$, $f(x_1) = f(x_2)$.
|
||||||
@@ -180,7 +180,7 @@ See the assignment PDF for the full assignment specification and theorem.
|
|||||||
\end{align}
|
\end{align}
|
||||||
|
|
||||||
Because we know that each fraction constitutes a unique prime factorization, we also know that $x_1$ and
|
Because we know that each fraction constitutes a unique prime factorization, we also know that $x_1$ and
|
||||||
$x_2$ are uniquely derived. This is why the implications in the equation above holds.
|
$x_2$ are uniquely derived. This is why the implications in the equation above hold.
|
||||||
Because both $x_1$ and $x_2 > 0$, $x_1 = x_2$.
|
Because both $x_1$ and $x_2 > 0$, $x_1 = x_2$.
|
||||||
|
|
||||||
Now for the case where $x \in \Q\backslash\N$.
|
Now for the case where $x \in \Q\backslash\N$.
|
||||||
@@ -204,8 +204,34 @@ See the assignment PDF for the full assignment specification and theorem.
|
|||||||
\frac{x_1*x_1}{p_1***p_N*q_1***q_M} &= \frac{x_2*x_2}{v_1***v_n*w_1***w_m}
|
\frac{x_1*x_1}{p_1***p_N*q_1***q_M} &= \frac{x_2*x_2}{v_1***v_n*w_1***w_m}
|
||||||
\end{align}
|
\end{align}
|
||||||
|
|
||||||
\item[Injectivity:] We want to show that $f$ is onto,
|
I'm kinda stuck at this point. I see that this is definitely injective, since the way the exponents
|
||||||
i.e. $f(\{ q > 0 : q \in \Q \}) = \N$.
|
are defined, you will always know which prime factors belong to the numerator or to the denominator.
|
||||||
|
But I fail to prove this using the direct definition of $f$ like we could do for the natural numbers.
|
||||||
|
This is because the products of the denominators in the last equation are not unique.
|
||||||
|
So maybe I simplified them too much and shouldn't try and write them in terms of $x_1$ and $x_2$ like
|
||||||
|
we did earlier, and try and focus more on just the exponents, but I feel it becomes really hard
|
||||||
|
to show that $x_1 = x_2$ that way.
|
||||||
|
|
||||||
|
\item[Surjectivity:] We want to show that $f$ is onto, i.e. $f(\{ q > 0 : q \in \Q \}) = \N$.
|
||||||
|
|
||||||
|
In order to prove this, we will take an arbitrary $y \in \N$, and show that $\exists x : f(x)=y$.
|
||||||
|
We know from the \textbf{Theorem} that $y$ can be written as a product of unique prime factors,
|
||||||
|
$p_1^{r_1}***p_N^{r_N}$. From the definition of $f$ we know that if the exponents of the prime factors
|
||||||
|
$r$ are even, they belong to the numerator of $x$ and if the exponents are
|
||||||
|
odd, they belong to the denominator of $x$. If there are no prime factors with odd exponents,
|
||||||
|
$x$ will be a natural number. If $y=1$, $x=1$.
|
||||||
|
|
||||||
|
We will now only consider the case that $y$ is a prime factorization with factors with odd exponents
|
||||||
|
\footnote{The case for a prime factorization with solely even exponents can be backtracked
|
||||||
|
in a similar fashion, just without the case for odd exponents and making $x$ a fraction.}.
|
||||||
|
Then, we can find $x$ in the following way: we multiply each prime factor $p_i^{2r_i-1}$ with $p_i$
|
||||||
|
and take the square root. We know that the square root of $p_i^{2r_i}$ is defined, since the exponent
|
||||||
|
is multiplied by a factor 2, which the root negates. This will yield a prime factorization that we will
|
||||||
|
put in the denominator of a fraction. We do the same for the prime factors with even exponent, but
|
||||||
|
without multiplying with $p_i$. The prime factors we gain like that we put as a product in the
|
||||||
|
numerator of the fraction. So, we gain a fraction with both the numerator and the denominator
|
||||||
|
consisting of products of prime numbers, which are natural numbers, and so the fraction is positive
|
||||||
|
and in fact a fraction. \qed
|
||||||
\end{description}
|
\end{description}
|
||||||
\end{enumerate}
|
\end{enumerate}
|
||||||
|
|
||||||
|
|||||||
Reference in New Issue
Block a user