I'm trying to find the cardinality of the set of all polynomials with coefficients in ℝ. What's wrong with the following proof:
Let $f$ be a function: $$f: \mathbb R[x] \to P(\mathbb R)$$ $$f(a_{0}+a_{1}x^{1}+...+a_{k}x^{k}) = \left \{ a_{0}, a_{1}, ..., a_{k} \right \}$$
For example: $$f(4.3x+2.5) = \left \{ 4.3,2.5 \right \}$$
f is obviously not injective, but is onto. Meaning that $$|\mathbb R[x]]| \geq \left | P(R) \right | $$
What am I missing?
Notice that the cardinality of polynomials of degree $0$ (Only free coefficients) is $|\mathbb{R}| = \mathfrak{c}$ (We just map such polynomials to their free coefficients).
The cardinality of polynomials of degree $1$ is $|\mathbb{R} \times \mathbb{R}| = \mathfrak{c}$.
The cardinality of polynomials of degree $2$ is $|\mathbb{R} \times \mathbb{R} \times \mathbb{R}| = \mathfrak{c}$
...
The cardinality of polynomials of degree $n$ is $|\mathbb{R}^n| = \mathfrak{c}$
...
Your set is just the countable union of all these sets from above, and therefore its cardinality is also $\mathfrak{c}$. (See here: Cardinality of union of ${{\aleph }_{0}}$ disjoint sets of cardinality $\mathfrak{c}$)
Ok so look at the interval $[-n,n]$.Total number of subsets of it is $c$...now.coefficients come from one of these subsets for some $n \in N$. So it is less than $c* \aleph $...which is still $c$.The reverse inclusion is trivial.So cardinality of total polynomial is $c$.
