1 / 30

10.2 Vectors and Vector Value Functions

10.2 Vectors and Vector Value Functions. Quantities that we measure that have magnitude but not direction are called scalars. Quantities such as force, displacement or velocity that have direction as well as magnitude are represented by directed line segments. B. terminal point.

emerson-vinson
Download Presentation

10.2 Vectors and Vector Value Functions

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. 10.2 Vectors and Vector Value Functions

  2. Quantities that we measure that have magnitude but not direction are called scalars. Quantities such as force, displacement or velocity that have direction as well as magnitude are represented by directed line segments. B terminal point The length is A initial point

  3. B terminal point A initial point A vector is represented by a directed line segment. Vectors are equal if they have the same length and direction (same slope).

  4. y A vector is in standard position if the initial point is at the origin. x The component form of this vector is:

  5. y A vector is in standard position if the initial point is at the origin. x The component form of this vector is: The magnitude (length) of is:

  6. The component form of (-3,4) P is: (-5,2) Q v (-2,-2)

  7. Then v is a unit vector. If is the zero vector and has no direction.

  8. Vector Operations: (Add the components.) (Subtract the components.)

  9. Vector Operations: Scalar Multiplication: Negative (opposite):

  10. u v u + v is the resultant vector. u+v (Parallelogram law of addition) v u

  11. The dot product (also called inner product) is defined as: Read “u dot v” Example:

  12. The angle between two vectors is given by:

  13. The dot product (also called inner product) is defined as: This could be substituted in the formula for the angle between vectors (or solved for theta) to give:

  14. Example: Find the angle between vectors u and v:

  15. Application: Example 7 A Boeing 727 airplane, flying due east at 500mph in still air, encounters a 70-mph tail wind acting in the direction of 60o north of east. The airplane holds its compass heading due east but, because of the wind, acquires a new ground speed and direction. What are they? N E

  16. Application Example A Boeing 727 airplane, flying due east at 500mph in still air, encounters a 70-mph tail wind acting in the direction of 60o north of east. The airplane holds its compass heading due east but, because of the wind, acquires a new ground speed and direction. What are they? N E u

  17. Application: Example 7 A Boeing 727 airplane, flying due east at 500mph in still air, encounters a 70-mph tail wind acting in the direction of 60o north of east. The airplane holds its compass heading due east but, because of the wind, acquires a new ground speed and direction. What are they? N v 60o E u

  18. Application: Example 7 A Boeing 727 airplane, flying due east at 500mph in still air, encounters a 70-mph tail wind acting in the direction of 60o north of east. The airplane holds its compass heading due east but, because of the wind, acquires a new ground speed and direction. What are they? N We need to find the magnitude and direction of the resultant vectoru + v. v u+v E u

  19. N The component forms of u and v are: v 70 u+v E 500 u Therefore: and:

  20. N 538.4 6.5o E The new ground speed of the airplane is about 538.4 mph, and its new direction is about 6.5o north of east.

  21. If we separate r(t) into horizontal and vertical components, we can express r(t) as a linear combination of standard unit vectors i <1, 0> and j <0, 1>. We can describe the position of a moving particle by a vector, r(t) (position vector).

  22. In three dimensions the component form becomes:

  23. Most of the rules for the calculus of vectors are the same :

  24. The exceptions???:

  25. a.) Find the velocity and acceleration vectors. Example 7: A particle moves in an elliptical path so that its position at any time t ≥ 0 is given by <4 sin t, 2 cos t>.

  26. b.) Find the velocity, acceleration, speed, and direction of motion at t = /4 Example 7: A particle moves in an elliptical path so that its position at any time t ≥ 0 is given by <4 sin t, 2 cos t>.

  27. c.) Sketch the path of the particle and show the velocity vector at the point (4, 0). Example 7: A particle moves in an elliptical path so that its position at any time t ≥ 0 is given by <4 sin t, 2 cos t>. Graph parametrically x = 4 sin t y = 2 cos t At (4, 0): 4 = 4 sin t and 0 = 2 cos t 1 = sin t 0 = cos t v(t) = <4 cos t, -2 sin t> = <0, -2>

  28. d.) Does the particle travel clockwise or counterclockwise around the origin? Example 7: A particle moves in an elliptical path so that its position at any time t ≥ 0 is given by <4 sin t, 2 cos t>. The vector shows the particle travels clockwise around the origin.

  29. a) Write the equation of the tangent where . At : Example : slope: position: tangent:

  30. b) Find the coordinates of each point on the path where the horizontal component of the velocity is 0. The horizontal component of the velocity is . Example 6:

More Related