Lesson 2: Vectors



Lesson 2: Trigonometry andVectors I

I. Trigonometry Review

A. Definitions:

cos(() =

sin(() =

tan(() =

In physics, we are constantly using trigonometry to either determine the length of the adjacent side or the opposite side of the triangle

Adjacent side =

Opposite side =

B. Pythagorean Theorem (Right Triangles)

We primarily use the Pythagorean theorem in physics to find the length of the hypotenuse.

C. The Unit Circle and Facts To Put To Memory

The adjacent side of the triangle lies along the _____________ ______________

so we have that the __________ __________________ is given by

The opposite side of the triangle lies along the _____________ ______________

so we have that the __________ __________________ is given by

Important: These relations are only true when you measure angles with respect to the horizontal axis! We often find it convenient to measure other angles since it will make the math simpler. You must be able to apply the trigonometry definitions.

|( |cos(() |sin(() |tan(() |

|0 | | | |

|30 | | | |

|45 | | | |

|60 | | | |

|90 | | | |

II. Scalars

A. Definition -

A quantity that is completely expressed by a _________________ and ____________

EXAMPLES:

B. Scalars may be either _____________________ or ___________________

C. Symbol -

III. Vectors

A. Definition

A physical quantity that has both a _________________________ ( )

and a ______________________________ .

Examples:

Note: In advanced engineering and physics courses, we run into physical quantities that obey our definition but do not act like vectors. Thus, this definition although extremely useful is not always sufficient for advanced work. Instead, the vector like many mathematical entities is defined in terms of mathematical operations (transformations).

B. Symbol -

C. Polar Representation

1. Graphically Description:

A vector can be described by _______________________ whose _____________________ gives

the _______________________ of the vector and an ________________________ that gives the

__________________________.

2. Writing Vector in Polar Form:

3. Magnitude (length) of the vector is a ___________________ __________________.

It is the hypotenuse of our triangle!

4. Most measured data comes in this form, but it is hard to make calculations in this form!!

Example: Graph the vector [pic]

5. Unit Vectors - A unit vector is a vector with a magnitude of _________________ and has

_________ units.

Examples:

i) Cartesian Unit Vectors

ii) Cylindrical Unit Vectors

iii) Spherical Unit Vectors

D. Graphical Addition of Vectors

We wish to add two vectors [pic]and [pic].

Method:

1. Draw vector [pic]starting at the origin

2. Draw vector [pic]starting with the tail of vector[pic]at the tip of vector [pic].

3. Draw the resultant vector ( [pic] ) from the tail of [pic]to the tip of [pic].

4. Using a ruler and protractor measure the magnitude and direction of the resultant vector.

EXAMPLE 1: If [pic]and [pic]what is [pic]

Note: Our graphical method of adding vectors proves that

[pic]

E. Multiplication of a Vector by a Scalar

1.

From our knowledge of multiplying by scalars in elementary school, we know that this is the same

as adding the vector ___________ _______________ times.

2. Thus, we see from our knowledge of vector addition that the magnitude (length) of the original

vector changes by the factor ________________ .

Three Cases:

i)

ii)

iii)

3. If k > 0 then the direction of the resultant vector is the ________________ as the original vector. If

k < 0 then the direction of the resultant vector is rotated ______________ with respect to the

original vector.

Example: Given that [pic], find the following

a) [pic] b) [pic] c) [pic] d) [pic]

F. Cartesian Representation

1. The vector is broke into distances (components) along a set of unit vectors along the set of x, y, and

z axis.

Example: For [pic] do the following

i) Draw the vector B

ii) What is the x-component?

iii) What is the y-component?

Cartesian form is the easiest for doing calculations (adding and subtracting) vectors while Polar form

is usually needed for presenting your work.

2. Adding Vectors in Cartesian Form

Cx = Ax + Bx

Cy = Ay + By

Example: Given [pic] and [pic], what is [pic]?

3. Multiplying by a Scalar

Just distribute the multiplication of the scalar on to each of the vector's components.

Examples: Given the vector [pic], write the following vectors in Cartesian form

a) [pic]

b) [pic]

-----------------------

(

a

b

c

1

(

X

Y

................
................

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