Linear form/Introduction/Section

A linear form on ${\displaystyle {}K^{n}}$ is of the form

${\displaystyle K^{n}\longrightarrow K,\left(x_{1},\,\ldots ,\,x_{n}\right)\longmapsto \sum _{i=1}^{n}a_{i}x_{i},}$

for a tuple ${\displaystyle {}\left(a_{1},\,\ldots ,\,a_{n}\right)}$. The projections

${\displaystyle p_{j}\colon K^{n}\longrightarrow K,\left(x_{1},\,\ldots ,\,x_{n}\right)\longmapsto x_{j},}$

are the easiest linear forms.

The zero mapping to ${\displaystyle {}K}$ is also a linear form, called the zero form.

Many important examples of linear forms on some vector spaces of infinite dimension arise in analysis. For a real interval ${\displaystyle {}[a,b]}$, the set of functions ${\displaystyle {}\operatorname {Map} \,{\left([a,b],\mathbb {R} \right)}}$, or the set of continuous functions ${\displaystyle {}C([a,b],\mathbb {R} )}$, or the set of continuously differentiable functions ${\displaystyle {}C^{1}([a,b],\mathbb {R} )}$ form real vector spaces. For a point ${\displaystyle {}P\in [a,b]}$, the evaluation ${\displaystyle {}f\mapsto f(P)}$ is a linear form (because addition and scalar multiplication is defined pointwisely on these spaces). Also, the evaluation of the derivative at ${\displaystyle {}P}$,

${\displaystyle C^{1}([a,b],\mathbb {R} )\longrightarrow \mathbb {R} ,f\longmapsto f'(P),}$

is a linear form. For ${\displaystyle {}C([a,b],\mathbb {R} )}$, the integral, that is, the mapping

${\displaystyle C([a,b],\mathbb {R} )\longrightarrow \mathbb {R} ,f\longmapsto \int _{a}^{b}f(t)dt,}$

is a linear form. This rests on the linearity of the integral.