Vectors (Page 6/10)

Physics - grade 10 [caps 2011]

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The parallelogram method

The parallelogram method is another graphical technique of finding the resultant of two vectors.

Method: The Parallelogram Method

Make a rough sketch of the vector diagram.
Choose a scale and a reference direction.
Choose either of the vectors to be added and draw it as an arrow of the correct length in the correct direction.
Draw the second vector as an arrow of the correct length in the correct direction from the tail of the first vector.
Complete the parallelogram formed by these two vectors.
The resultant is then the diagonal of the parallelogram. The magnitude can be determined from the length of its arrow using thescale. The direction too can be determined from the scale diagram.

A force of $F_{1} = 5 N$ is applied to a block in a horizontal direction. A second force $F_{2} = 4 N$ is applied to the object at an angle of $30^{\circ}$ above the horizontal.

Determine the resultant force acting on the block using the parallelogram method of accurate construction.

Firstly make a rough sketch of the vector diagram
Choose a suitable scale
In this problem a scale of 1 cm = 1 N would be appropriate, since then the vector diagram would take up a reasonable fraction of the page. We can now begin the accurate scale diagram.
Draw the first scaled vector
Let us draw $F_{1}$ first. According to the scale it has length 5 cm.
Draw the second scaled vector
Next we draw $F_{2}$ . According to the scale it has length 4 cm. We make use of a protractor to draw this vector at $30^{\circ}$ to the horizontal.
Determine the resultant vector
Next we complete the parallelogram and draw the diagonal.

The resultant has a measured length of 8,7 cm.
Find the direction
We use a protractor to measure the angle between the horizontal and the resultant. We get $13,3^{\circ}$ .
Apply the scale conversion
Finally we use the scale to convert the measured length into the actual magnitude. Since 1 cm = 1 N, 8,7 cm represents 8,7 N. Therefore the resultant force is 8,7 N at $13,3^{\circ}$ above the horizontal.

The parallelogram method is restricted to the addition of just two vectors. However, it is arguably the most intuitive way of adding twoforces acting on a point.

Algebraic addition and subtraction of vectors

Vectors in a straight line

Whenever you are faced with adding vectors acting in a straight line (i.e. some directed left and some right, or some acting up and others down) you can use a very simple algebraic technique:

Method: Addition/Subtraction of Vectors in a Straight Line

Choose a positive direction. As an example, for situations involving displacements in the directions west and east, youmight choose west as your positive direction. In that case, displacements east are negative.
Next simply add (or subtract) the magnitude of the vectors using the appropriate signs.
As a final step the direction of the resultant should be included in words (positive answers are in the positive direction, while negativeresultants are in the negative direction).

Let us consider a few examples.

A tennis ball is rolled towards a wall which is 10 m away from the ball. If after striking the wall the ball rolls a further 2,5 m along the ground away from the wall, calculate algebraically the ball's resultant displacement.

Draw a rough sketch of the situation
Decide which method to use to calculate the resultant
We know that the resultant displacement of the ball ( ${\vec{x}}_{R}$ ) is equal to the sum of the ball's separate displacements ( ${\vec{x}}_{1}$ and ${\vec{x}}_{2}$ ):

$\begin{matrix} {\vec{x}}_{R} & = & {\vec{x}}_{1} + {\vec{x}}_{2} \end{matrix}$

Since the motion of the ball is in a straight line (i.e. the ball moves towards and away from the wall), we can use the method of algebraic additionjust explained.
Choose a positive direction
Let's choose the positive direction to be towards the wall. This means that the negative direction is away from the wall.
Now define our vectors algebraically
With right positive:

$\begin{matrix} {\vec{x}}_{1} & = & + 10, 0 m \cdot s^{- 1} \\ {\vec{x}}_{2} & = & - 2, 5 m \cdot s^{- 1} \end{matrix}$
Add the vectors
Next we simply add the two displacements to give the resultant:

$\begin{matrix} {\vec{x}}_{R} & = & (+ 10 m \cdot s^{- 1}) + (- 2, 5 m \cdot s^{- 1}) \\ = & (+ 7, 5) m \cdot s^{- 1} \end{matrix}$
Quote the resultant
Finally, in this case towards the wall is the positive direction , so: ${\vec{x}}_{R}$ = 7,5 m towards the wall.

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Source: OpenStax, Physics - grade 10 [caps 2011]. OpenStax CNX. Jun 14, 2011 Download for free at http://cnx.org/content/col11298/1.3

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