Processo de Gram-Schmidt para $$$\left[\begin{array}{c}t\\0\end{array}\right]$$$, $$$\left[\begin{array}{c}- t\\t\end{array}\right]$$$

Ortonormalize o conjunto dos vetores $$$\mathbf{\vec{v_{1}}} = \left[\begin{array}{c}t\\0\end{array}\right]$$$, $$$\mathbf{\vec{v_{2}}} = \left[\begin{array}{c}- t\\t\end{array}\right]$$$ usando o processo de Gram-Schmidt.

De acordo com o processo de Gram-Schmidt, $$$\mathbf{\vec{u_{k}}} = \mathbf{\vec{v_{k}}} - \sum_{j=1}^{k - 1} \operatorname{proj}_{\mathbf{\vec{u_{j}}}}\left(\mathbf{\vec{v_{k}}}\right)$$$, onde $$$\operatorname{proj}_{\mathbf{\vec{u_{j}}}}\left(\mathbf{\vec{v_{k}}}\right) = \frac{\mathbf{\vec{u_{j}}}\cdot \mathbf{\vec{v_{k}}}}{\mathbf{\left\lvert\vec{u_{j}}\right\rvert}^{2}} \mathbf{\vec{u_{j}}}$$$ é uma projeção vetorial.

O vetor normalizado é $$$\mathbf{\vec{e_{k}}} = \frac{\mathbf{\vec{u_{k}}}}{\mathbf{\left\lvert\vec{u_{k}}\right\rvert}}$$$.

Passo 1

$$$\mathbf{\vec{u_{1}}} = \mathbf{\vec{v_{1}}} = \left[\begin{array}{c}t\\0\end{array}\right]$$$

$$$\mathbf{\vec{e_{1}}} = \frac{\mathbf{\vec{u_{1}}}}{\mathbf{\left\lvert\vec{u_{1}}\right\rvert}} = \left[\begin{array}{c}\frac{t}{\left|{t}\right|}\\0\end{array}\right]$$$ (para ver as etapas, consulte calculadora de vetor unitário).

Passo 2

$$$\mathbf{\vec{u_{2}}} = \mathbf{\vec{v_{2}}} - \operatorname{proj}_{\mathbf{\vec{u_{1}}}}\left(\mathbf{\vec{v_{2}}}\right) = \left[\begin{array}{c}0\\t\end{array}\right]$$$ (para ver as etapas, consulte calculadora de projeção vetorial e calculadora de subtração de vetores).

$$$\mathbf{\vec{e_{2}}} = \frac{\mathbf{\vec{u_{2}}}}{\mathbf{\left\lvert\vec{u_{2}}\right\rvert}} = \left[\begin{array}{c}0\\\frac{t}{\left|{t}\right|}\end{array}\right]$$$ (para ver as etapas, consulte calculadora de vetor unitário).

O conjunto de vetores ortonormais é $$$\left\{\left[\begin{array}{c}\frac{t}{\left|{t}\right|}\\0\end{array}\right], \left[\begin{array}{c}0\\\frac{t}{\left|{t}\right|}\end{array}\right]\right\}$$$A.