A zero vector \(\utilde{0}\) has magnitude zero and its direction cannot be determined.
The vector \(\utilde{a}\) multiplied by the scalar \(k\) is also a vector and is written as \(k\utilde{a}\) where
(i) \( \begin{vmatrix} ka \end{vmatrix}=k \begin{vmatrix} ka \end{vmatrix}\).
(ii) if \(k \gt0\), then \(k\utilde{a}\) has the same direction as \(\utilde{a}\).
(iii) if \(k \lt0\), then \(k\utilde{a}\) has the opposite direction as \(\utilde{a}\).
Vector \(\utilde{a}\) and \(\utilde{b}\) are parallel if and only if \(\utilde{a}=k\utilde{a}\) where \(k\) is a constant.
Given the vector \(\utilde{m}\).
Express the vector below in term of \(\utilde{m}\).
Based on the given diagram,
the vector has twice the magnitude of the vector \(\utilde{m}\) and also due in same direction with vector \(\utilde{m}\).
Hence, the vector in term of \(\utilde{m}\) is:
\(2\utilde{m}\).
Given a pair of vector.
Determine whether the pair of vector is parallel or not.
\(\overrightarrow{EF}=\dfrac{1}{3}\utilde{r}\)
\(\overrightarrow{FG}=9\utilde{r}\)
Vector \(\utilde{a}\) and \(\utilde{b}\) are parallel if and only if \(\utilde{a}=k\utilde{b}\) where \(k\) is a constant.
\(\overrightarrow{EF}=\dfrac{1}{3}\utilde{r}\),
Then,
\(\utilde{r}=3\overrightarrow{EF}\).
Hence,
\(\begin{aligned} \overrightarrow{FG}&=9(3\overrightarrow{EF})\\\\ &=27\overrightarrow{EF}. \end{aligned}\)
\(\therefore \overrightarrow{EF}\) and \(\overrightarrow{FG}\) are parallel.
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