Extending fundamental form

Question

Let $V$ be a finite dimensional vector space and $\left<~,\right>$ be a symmetric bilinear form on $V$. Then I would like to extend this to a bilinear form $\left< ~,\right>$ on $V_\mathbb{C}=V\otimes_{\mathbb{R}}\mathbb{C}$ i.e., we need to define what is $\left< v\otimes \lambda ,u\otimes \mu\right>$ for $v,u\in V$ and $\lambda,\mu\in \mathbb{C}$.

It is natural to define $\left=\lambda\bar{ \mu}\left$. But this is not symmetric. I want to define some symmetric bilinear form.

I am reading Complex Geometry: An Introduction by Daniel Huybrechts.

The book defines an almost complex structure on a real vector space to be an endomorphism $I:V\rightarrow V$ such that $I^2=-id$. Then it says almost complex structure is compatible with a positive definite symmetric bilinear form $\left<~,\right>$ on $V$ if $\left=\left$ for all $u,v\in V$.

For $V_{\mathbb{C}}=V\otimes\mathbb{C}$ we have extension $I$ of $I:V\rightarrow V$ defined as $I(v\otimes \lambda)=Iv\otimes \lambda$ and it turns out that this extension is an almost complex structure on $V_{\mathbb{C}}$. I fail to extend $\left<~,\right>$ to $\mathbb{C}$. Forget about compatibility. I could not even define a symmetric bilinear form.