3.3 Vector addition and subtraction: analytical methods (Page 2/5)

College physics Page 3 / 5

Step 3. To get the magnitude $R$ of the resultant, use the Pythagorean theorem:

R = \sqrt{R_{x}^{2} + R_{y}^{2}} .

Step 4. To get the direction of the resultant:

θ = {tan}^{- 1} (R_{y} / R_{x}) .

The following example illustrates this technique for adding vectors using perpendicular components.

Adding vectors using analytical methods

Add the vector $A$ to the vector $B$ shown in [link] , using perpendicular components along the x - and y -axes. The x - and y -axes are along the east–west and north–south directions, respectively. Vector $A$ represents the first leg of a walk in which a person walks $53 . 0 m$ in a direction $20.0 º$ north of east. Vector $B$ represents the second leg, a displacement of $34 . 0 m$ in a direction $63.0 º$ north of east.

Two vectors A and B are shown. The tail of the vector A is at origin. Both the vectors are in the first quadrant. Vector A is of magnitude fifty three units and is inclined at an angle of twenty degrees to the horizontal. From the head of the vector A another vector B of magnitude 34 units is drawn and is inclined at angle sixty three degrees with the horizontal. The resultant of two vectors is drawn from the tail of the vector A to the head of the vector B. — Vector $A$ has magnitude $53 . 0 m$ and direction $20.0 º$ north of the x -axis. Vector $B$ has magnitude $34 . 0 m$ and direction $63.0 º$ north of the x -axis. You can use analytical methods to determine the magnitude and direction of $R$ .

Strategy

The components of $A$ and $B$ along the x - and y -axes represent walking due east and due north to get to the same ending point. Once found, they are combined to produce the resultant.

Solution

Following the method outlined above, we first find the components of $A$ and $B$ along the x - and y -axes. Note that $A = 53.0 m$ , $θ_{A} = 20.0º$ , $B = 34.0 m$ , and $θ_{B} = 63.0º$ . We find the x -components by using $A_{x} = A cos θ$ , which gives

\begin{array}{l} A_{x} & = & A cos θ_{A} = (53. 0 m) (cos 20.0º) \\ = & (53. 0 m) (0 .940) = 49. 8 m \end{array}

and

\begin{array}{l} B_{x} & = & B cos θ_{B} = (34 . 0 m) (cos 63.0º) \\ = & (34 . 0 m) (0.454) = 15 . 4 m . \end{array}

Similarly, the y -components are found using $A_{y} = A sin θ_{A}$ :

\begin{array}{l} A_{y} & = & A sin θ_{A} = (53 . 0 m) (sin 20.0º) \\ = & (53 . 0 m) (0.342) = 18 . 1 m \end{array}

and

\begin{array}{l} B_{y} & = & B sin θ_{B} = (34 . 0 m) (sin 63 . 0 º) \\ = & (34 . 0 m) (0.891) = 30 . 3 m . \end{array}

The x - and y -components of the resultant are thus

R_{x} = A_{x} + B_{x} = 49 . 8 m + 15 . 4 m = 65 . 2 m

and

R_{y} = A_{y} + B_{y} = 18 . 1 m + 30 . 3 m = 48 . 4 m .

Now we can find the magnitude of the resultant by using the Pythagorean theorem:

R = \sqrt{R_{x}^{2} + R_{y}^{2}} = \sqrt{(65.2)^{2} + (48.4)^{2} m}

so that

R = 81.2 m.

Finally, we find the direction of the resultant:

θ = {tan}^{- 1} (R_{y} / R_{x}) =+ {tan}^{- 1} (48 . 4 / 65 . 2) .

Thus,

θ = {tan}^{- 1} (0.742) = 36 . 6 º .

The addition of two vectors A and B is shown. Vector A is of magnitude fifty three units and is inclined at an angle of twenty degrees to the horizontal. Vector B is of magnitude thirty four units and is inclined at angle sixty three degrees to the horizontal. The components of vector A are shown as dotted vectors A X is equal to forty nine point eight meter along x axis and A Y is equal to eighteen point one meter along Y axis. The components of vector B are also shown as dotted vectors B X is equal to fifteen point four meter and B Y is equal to thirty point three meter. The horizontal component of the resultant R X is equal to A X plus B X is equal to sixty five point two meter. The vertical component of the resultant R Y is equal to A Y plus B Y is equal to forty eight point four meter. The magnitude of the resultant of two vectors is eighty one point two meters. The direction of the resultant R is in thirty six point six degree from the vector A in anticlockwise direction. — Using analytical methods, we see that the magnitude of $R$ is $81 . 2 m$ and its direction is $36 . 6º$ north of east.

Discussion

This example illustrates the addition of vectors using perpendicular components. Vector subtraction using perpendicular components is very similar—it is just the addition of a negative vector.

Subtraction of vectors is accomplished by the addition of a negative vector. That is, $A - B \equiv A + (–B)$ . Thus, the method for the subtraction of vectors using perpendicular components is identical to that for addition . The components of $–B$ are the negatives of the components of $B$ . The x - and y -components of the resultant $A - B = R$ are thus

R_{x} = A_{x} + (- B_{x})

and

R_{y} = A_{y} + (- B_{y})

and the rest of the method outlined above is identical to that for addition. (See [link] .)

Analyzing vectors using perpendicular components is very useful in many areas of physics, because perpendicular quantities are often independent of one another. The next module, Projectile Motion , is one of many in which using perpendicular components helps make the picture clear and simplifies the physics.

In this figure, the subtraction of two vectors A and B is shown. A red colored vector A is inclined at an angle theta A to the positive of x axis. From the head of vector A a blue vector negative B is drawn. Vector B is in west of south direction. The resultant of the vector A and vector negative B is shown as a black vector R from the tail of vector A to the head of vector negative B. The resultant R is inclined to x axis at an angle theta below the x axis. The components of the vectors are also shown along the coordinate axes as dotted lines of their respective colors. — The subtraction of the two vectors shown in [link] . The components of $–B$ are the negatives of the components of $B$ . The method of subtraction is the same as that for addition.

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Source: OpenStax, College physics. OpenStax CNX. Jul 27, 2015 Download for free at http://legacy.cnx.org/content/col11406/1.9

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