Motion and its Applications VECTORS (P. 8-9). Vector scale diagrams [do not copy this portion] Motion along a straight line (i.e. one dimension) is easy.

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Presentation transcript:

Motion and its Applications VECTORS (P. 8-9)

Vector scale diagrams [do not copy this portion] Motion along a straight line (i.e. one dimension) is easy to analyze but in real life most motion does not occur in a straight line. However, there is another method you can use to solve displacement problems: Vector scale diagrams. A Vector Scale Diagram is a representation of motion using vectors drawn to a particular scale. Vector scale diagrams are very useful in measuring the total displacement of an object from its original position. [copy this] Vector Scale Diagrams - Representation of motion using vectors drawn to scale.

Vectors A Vector can be represented by a direct line segment, which is a straight line between two points with an arrowhead pointing in a specific direction. The end of the arrowhead is called the tip while the other end is called the tail. Vector - directed line segment NOTE!!! -Vectors are added tip to tail. Tip Tail

Vector Scale Diagrams For straight-line motion, vector scale diagrams are not very complex. Consider the two displacements: Δd 1 = 700m [W] & Δd 2 = 500m [W] We can determine the total displacement that results from adding these two vectors together by 1. drawing a vector scale diagram of the motion and then 2. measuring the length of the line that represents the total displacement. N Δd 1 = 700m [W] Δd 1 = 500m [W] Δd T = 1200m [W]

Vector Diagrams NOTE! In most cases we will not use a scale diagram. Instead we will sketch the vector diagram that represents the motion and then use that to help determine the displacement. When we are dealing with motion in two dimensions, we will need to use Pythagoras and trigonometry to determine the vector length and direction - HINT – remember practice questions you did last week.

Vector diagrams - Practice Fred is going to visit a friend but he needs to stop at the variety store first. He walks 200 m [N] from his home to the store and then 600m [S] to his friends House. A) Sketch a vector diagram of the situation showing ◦i) the displacement vectors and ◦ii) the total displacement vector B) What is Fred’s total displacement? C) What is Fred’s total distance?

Vector diagrams - Practice Fred is going to visit a friend but he needs to stop at the variety store first. He walks 200 m [N] from his home to the store and then 600m [S] to his friends House. A) Sketch a vector diagram of the situation showing ◦i) the displacement vectors and ◦ii) the total displacement vector Home Δd 1 = 200m [N] Δd 1 = 600m [S] Δd T =

Vector diagrams - Practice Fred is going to visit a friend but he needs to stop at the variety store first. He walks 200 m [N] from his home to the store and then 600m [S] to his friends House. B) What is Fred’s total displacement? Home Δd 1 = 200m [N] Δd 2 = 600m [S] Δd T = 400m [S] Δd T = 600m [S] -200m [N] = 400m [S]

Vector diagrams - Practice Fred is going to visit a friend but he needs to stop at the variety store first. He walks 200 m [N] from his home to the store and then 600m [S] to his friends House. C) What is Fred’s total distance? Home Δd 1 = 200m [N] Δd 1 = 600m [S] Δd T = 200m + 600m = 800m

Practice # 2 A rabbit runs 3.8 m [N] and stops to nibble on some grass. The rabbit then hops 6.3 m [N] to scratch against a small tree. A) Sketch a diagram of the motion showing the displacement vectors and the total displacement vector. B) what is the rabbits total displacement

Practice # 3 A skateboarder slides 4.2 m up a ramp, stops, and the slides 2.7 m down the ramp before jumping off. A) sketch a diagram of the motion showing the displacement vectors and the total displacement vector. What is his i)Total distance ii)Total displacement