Linear mapping/Dual mapping/Introduction/Section

(1). For ${\displaystyle {}f\in {W}^{*}}$, we have

${\displaystyle {}{\left(\varphi \circ \psi \right)}^{*}(f)=f\circ {\left(\varphi \circ \psi \right)}={\left(f\circ \varphi \right)}\circ \psi =\varphi ^{*}(f)\circ \psi =\psi ^{*}(\varphi ^{*}(f))\,.}$

(2) follows directly from ${\displaystyle {}f\circ \operatorname {Id} _{V}=f}$.

(3). Let ${\displaystyle {}f\in {V}^{*}}$ and

${\displaystyle {}\psi ^{*}(f)=0\,.}$

Because of the surjectivity of ${\displaystyle {}\psi }$, there exist for every ${\displaystyle {}v\in V}$ a ${\displaystyle {}u\in U}$ such that ${\displaystyle {}\psi (u)=v}$. Therefore

${\displaystyle {}f(v)=f(\psi (u))=(\psi ^{*}(f))(u)=0\,,}$

and ${\displaystyle {}f}$ is itself the zero mapping. Due to fact, ${\displaystyle {}\psi ^{*}}$ injective.

(4). The condition means that we may consider ${\displaystyle {}U\subseteq V}$ as a linear subspace. Because of fact, we can write

${\displaystyle {}V=U\oplus U'\,}$

with another ${\displaystyle {}K}$-linear subspace ${\displaystyle {}U'\subseteq V}$. A linear form

${\displaystyle g\colon U\longrightarrow K}$

can always be extended to a linear form

${\displaystyle {\tilde {g}}\colon V\longrightarrow K,}$

for example, by defining ${\displaystyle {}{\tilde {g}}}$ on ${\displaystyle {}U'}$ to be the zero form. This means the surjectivity.