3.3 Vector Addition and Subtraction: Analytical Methods

3.3 Vector Addition and Subtraction: Analytical Methods

The part of the graphical technique that is retained is the representation of the vectors by arrows.

Analytical methods are more precise and accurate than graphical methods, which are limited by the accuracy with which a drawing can be made.
The accuracy and precision with which physical quantities are known are the limits of analytical methods.

Analytical techniques and right triangles are related to physics because the motions of the right triangles are independent.

We often need to separate a component from a component.

The right triangle is formed by these vectors.

The analytical relationships are summarized.

The relationship between the components and the result is only for the quantities of magnitude and direction.

The magnitudes alone do not apply to the relationship.
If east, north, and north-eastern, then it is true.
The sum of the magnitudes is not equal.

The magnitude and angle of the vector are known if it is known.

The angle with trigonometric identities can be related to the magnitudes of the vector components.

The total displacement of the person walking in a city is represented by the vector.

In this example, we can use the relationships to determine the magnitude of the horizontal and vertical component vectors.

If the components are known, then they can also be found.

Once the horizontal and vertical components have been determined, the magnitude and direction can be determined.

The Pythagorean Theorem relates the legs of a right triangle to the length of the hypotenuse.

The direction is the same as before.

Both processes are crucial to analytical methods.

In Figure 3.30, you can see how to add the vectors using the components.

The resulting or total displacement of the two legs of a walk is called a vecis.

The magnitude and direction can be determined using analytical methods.

The total displacement is the number of legs of a walk.

There are many ways to arrive at the same point.

The person could have walked first in the x-direction and then in the y-direction.

When you use the analytical method, you can determine the magnitude and direction of a vector.

The x- and y-axes will be used in the problem.

Determine the horizontal and vertical components of the vectors before adding them.

Adding the components of the individual vectors along the axis will find the components of the resultant.

The magnitude of the vectors and add to give the magnitude in the horizontal direction.

The x- axis has components along the same line that can be added to one another like ordinary numbers.

The components along the y- axis are the same.
It's easier to add components that are along common axes.
The magnitude and direction can be found now that the components are known.

The following example shows how to add vectors using components.

The x- and y-axes are in the opposite directions.

A person walks north of east in the first leg of a walk.
The second leg is a displacement north of east.

The magnitude and direction are north of the x- axis.

The magnitude and direction can be determined using analytical methods.

The x- and y-axes represent the way to get to the same ending point.

They are combined to produce a result.

We first find the components of the x- and y-axes.

This example shows the addition of components.

The addition of a negative Vector is very similar to the addition of a perpendicular component.

Subtraction can be accomplished by the addition of a negative vector.

The method for addition and subtraction is the same.
The negatives of the components are the components.

The method outlined above is the same as for addition.

Punctual quantities are often independent of one another, which makes analyzing them useful in many areas of physics.

The next module, Projectile Motion, is one of many in which the components are used to make the picture clear and simplify the physics.