Learning Objectives : 1.To ensure we know what scalars and vectors are 2.To be able to find the resultant for two or more vectors by scale drawing Book.

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Presentation transcript:

Learning Objectives : 1.To ensure we know what scalars and vectors are 2.To be able to find the resultant for two or more vectors by scale drawing Book Reference : Pages 90-91

Scalars and Vectors : It is often said that: “A scalar is any physical quantity that is not directional” (e.g. Mass, density, volume & energy) “A vector is any physical quantity that has direction as well as magnitude” (e.g. Force, velocity & acceleration)

Scalars and Vectors : But also think of displacement and distance: “By road there are an infinite number of routes you can take from home to school, some shorter and many longer. However, once you arrive at school your displacement will always be the same home → school. The distance travelled will vary for each potential route”

Scalars and Vectors : Now consider adding a further journey after school to a friend’s house: We now have two displacements: Home → School & School → Friend’s House Clearly the end result could be achieved by a single displacement of Home → Friend’s House

Scalars and Vectors : Home Friend’s house School Vector addition for displacements Today via scale drawing

An example: Consider an oil tanker being towed by a pair of tugs as shown: 8000 kN 20° What is the combined (resultant) effect of these two forces?

Two equivalent methods of scale drawing... The parallelogram method...

1.Choose a scale and a reference direction. 2.Choose either of the vectors to be added and draw it as an arrow of the correct length in the correct direction. 3.Draw the second vector as an arrow of the correct length in the correct direction from the tail of the first vector. 4.Complete the parallelogram formed by these two vectors. 5.The resultant is then the diagonal of the parallelogram. Its magnitude can be determined from the length of its arrow using the scale. Its direction too can be determined from the scale diagram. The parallelogram method: Rules for scale drawing...

The Tail-to-Head method... 40°

1.Choose a scale and include a reference direction. 2.Choose any of the vectors to be summed and draw it as an arrow in the correct direction and of the correct length- remember to put an arrowhead on the end to denote its direction. 3.Take the next vector and draw it as an arrow starting from the arrowhead of the first vector in the correct direction and of the correct length. 4.Continue until you have drawn each vector- each time starting from the head of the previous vector. In this way, the vectors to be added are drawn one after the other tail- to-head. 5.The resultant is then the vector drawn from the tail of the first vector to the head of the last. Its magnitude can be determined from the length of its arrow using the scale. Its direction too can be determined from the scale diagram. The Tail-to-Head method: Rules for scale drawing...