Same Dimensional Vector Spaces are Isomorphic

Theorem
Let $K$ be a division ring.

Let $V$, $W$ be finite dimensional $K$-vector spaces.

Suppose that $\dim_K V = \dim_K W$.

Then:


 * $V \cong W$

That is, $V$ and $W$ are isomorphic.

Proof
Let $\mathbb V$, $\mathbb W$ be bases for $V$, $W$ respectively.

We have that:
 * $\dim_K V = \dim_K W$

Thus by the definition of dimension:


 * $\mathbb V \sim \mathbb W$

Therefore we can choose a bijection $\phi: \mathbb V \leftrightarrow \mathbb W$.

Define the mapping $\lambda: V \to W$ by:


 * $\ds \map \lambda {\sum \limits_{\mathbf v \mathop \in \mathbb V} a_{\mathbf v} \mathbf v} = \sum \limits_{\mathbf v \mathop \in \mathbb V} a_\mathbf v \map \phi {\mathbf v}$

For $\mathbf v \in \mathbb V$ let $l_\mathbf v \in V^\star$ be the unique linear transformation defined on the basis $\mathbb V$ by:
 * $\forall \mathbf v' \in \mathbb V: \map {l_\mathbf v} {\mathbf v'} = \delta_{\mathbf v, \mathbf v'}$

where $\delta : V \times V \to K$ is the Kronecker delta and $V^*$ is the dual of $V$.

Now:


 * $\ds \map {l_{\mathbf v} } {\sum \limits_{\mathbf u \mathop \in \mathbb V} a_\mathbf u \mathbf u} = \map {l_\mathbf v} {\sum_{\mathbf u \mathop \in \mathbb V \mathop \setminus \set {\mathbf v} } a_\mathbf u \mathbf u + a_{\mathbf v} \mathbf v} = \sum_{\mathbf u \mathop \in \mathbb V \mathop \setminus \set {\mathbf v} } a_\mathbf u \map {l_\mathbf v} {\mathbf u} + a_{\mathbf v} \map {l_\mathbf v} {\mathbf v}$

By the definition of $l_{\mathbf v}$ and by Vector Scaled by Zero is Zero Vector, all the terms but the last vanish, and so:


 * $\ds \forall \mathbf v \in \mathbb V : \map {l_\mathbf v} {\sum \limits_{\mathbf u \mathop \in \mathbb V} a_\mathbf u \mathbf u} = a_\mathbf v$

For all $\mathbf v, \mathbf v' \in V, c \in K$:

Thus $\lambda$ is linear.

Let $\mathbf x \in \ker \lambda$ where $\ker \lambda$ denotes the kernel of $\lambda$.

Then:


 * $\ds \mathbf 0 = \map \lambda {\mathbf x} = \sum \limits_{\mathbf v \mathop \in \mathbb V} \map {l_\mathbf v} {\mathbf x} \mathbf v$

Therefore:
 * $\forall \mathbf v \in \mathbb V: \map {l_\mathbf v} {\mathbf x} = 0$

because $\mathbb V$ is linearly independent.

By Vector Scaled by Zero is Zero Vector, $\mathbf x = \mathbf 0$.

That is:


 * $\ker \lambda = \set {\mathbf 0}$

By Linear Transformation is Injective iff Kernel Contains Only Zero, it follows that $\lambda$ is injective.

Recall that $\phi$ is a bijection.

From Inverse of Bijection is Bijection, $\phi$ is invertible.

Suppose $\mathbf y \in W$.

Then:

where this last vector belongs to $\map \lambda V$.

Thus $\lambda$ is surjective.

$\lambda$ has been shown to be injective and surjective, and so is a bijection.

$\lambda$ has also been shown to be linear transformation.

Thus, by definition, $\lambda$ is an isomorphism.

Also see

 * Linear Transformation from Finite-Dimensional Vector Space is Injective iff Surjective‎