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T5.2 - Scalar (Dot) Product of Vectors IB Math SL1 - Santowski.

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1 T5.2 - Scalar (Dot) Product of Vectors IB Math SL1 - Santowski

2 (A) Review Operations with Vectors: (1) Add/subtract (2) multiply by scalar (3) HOW do you multiply vectors (if it even means anything in the first place????)

3 (B) Work (Mini physics lesson) The amount of work done by a force on an object (in physics) depends upon:  (1) the amount of force applied  (2) the distance through which the force is applied (displacement)  (3) the direction of the applied force relative to the displacement Now, both force and displacement are VECTOR quantities in that both have an associated direction  so what does a vector multiplication mean and how do you do it??

4 (B) Work (Mini physics lesson) Let’s keep things simple  if the force applied and the displacement are IN THE SAME direction I apply a force of 10 Newtons (forward) to move an object 2 meters forward  How much work has the force done in moving the box?? Diagram

5 (B) Work (Mini physics lesson) Let’s keep things simple  if the force applied and the displacement are IN THE SAME direction I apply a force of 10 Newtons (forward) to move an object 2 meters forward  How much work has the force done in moving the box??  20 joules of work Diagram

6 (B) Work (Mini physics lesson) Let’s make things slightly harder  if the force applied and the displacement are IN PERPENDICULAR directions I apply a force of 10 Newtons (downward) to move an object 2 meters forward  How much work does the force do in moving the box?? Diagram

7 (B) Work (Mini physics lesson) Let’s make things slightly harder  if the force applied and the displacement are IN PERPENDICULAR directions I apply a force of 10 Newtons (downward) to move an object 2 meters forward  How much work does the force do in moving the box??  0 joules of work Diagram

8 (B) Work (Mini physics lesson) Now things get difficult  if there is an angle (0°<θ<90°) between the force applied and the displacement I apply a force of 10 Newtons (at an angle of θ° to the horizontal) to move an object 2 meters forward  How much work has the force done in moving the box?? Diagram

9 (B) Work (Mini physics lesson) I apply a force of 10 Newtons (at an angle of θ to the horiaontal) to move an object 2 meters forward  How much work has the force done in moving the box?? So we need to work with the VECTOR COMPONENTS of our force vector to see HOW MUCH of the 10 N of force actually moves the box forward It turns out that only the horizontal component of 10cosθ moves the box forward Diagram 10*cosθ

10 (B) Work (Mini physics lesson) I apply a force of 10 Newtons (at an angle of θ to the horiaontal) to move an object 2 meters forward  How much work has the force done upon the box?? It turns out that only the horizontal component of 10cosθ moves the box forward So the work done by the force on the box is (10cosθ)*(2) or (10)(2)cosθ Diagram 10*cosθ

11 (B) Work (Mini physics lesson) - Summary When we deal with vector quantities that are being multiplied (i.e. force and displacement), it is only the components of the two vectors that are in the same direction that matter  Hence, the idea of the displacement vector, r, and the horizontal component of the force vector, Fcosθ So this is how we will understand the multiplication of 2 vectors Since WORK is a SCALAR quantity (no direction associated with it), we shall use the term SCALAR PRODUCT to describe this one aspect of vector multiplication

12 (C) Scalar (Dot) Product So the formula for “multiplying” vectors is Where the symbol |A| or |B| meam the magnitude of vectors A and B

13 (C) Scalar (Dot) Product - Examples (1) How much work is done by a constant force of 50 Newtons when this force is applied at an angle of 60º to pull a 12 meter sliding metal door shut. The diagram shown below illustrates this situation

14 (C) Scalar (Dot) Product - Examples (2) A force of 20 Newtons is applied to an object at an angle of -45º with the horizontal. The object is pulled 10 meters at an angle of 25º with the horizontal. How much work is done while moving the object? (HINT: Draw a diagram)

15 (C) Scalar (Dot) Product So the formula for “multiplying” vectors is But what if the vectors are given in component form? In general, if u = (u x, u y ) and v = (v x, v y ) and, the dot product is u∙v = u x v x+ u y v y The PROOF of this is left up to the STUDENT!!! HAHAHAHAH And then in 3 space, if u = (u x, u y, u z ) and v = (v x, v y, v z ) and, the dot product is u∙v = u x v x + u y v y + u z v z

16 Examples (1) Let v = (2, 5) and u = (–3, 2) be two 2 dimensional vectors. The dot product of v and u would be ? (2) Suppose that v = (2, 5) and u = (–3, 1) as shown in the diagram shown below. We wish to calculate angle, θ, between v and u. (3) What is the angle between v = (3, –7) and u = (–1, 9)?

17 (C) Scalar (Dot) Product of Perpendicular Vectors & Parallel Vectors If 2 vectors act perpendicular to each other, the dot product (ie scalar product) of the 2 vectors has value zero. For the unit vectors i (acting in the x-direction) and j (acting in the y-direction), we have the following dot (ie scalar) products (since they are perpendicular to each other): i j = j i = 0

18 Examples (4) The dot product of (2,-5,1) and (-4,-3,-2) is: (5) Given that a = 3i – j + 2k and b = 2i + j – 2k, find a b and the angle between the 2 vectors (6) http://dev.physicslab.org/PracticeProblems/Worksheets/Phy1Hon/Ve ctors/dotproduct.aspx http://dev.physicslab.org/PracticeProblems/Worksheets/Phy1Hon/Ve ctors/dotproduct.aspx (7) Find the value of t such that the vectors P = 3 i − 5 j and Q = 4 i + t j are perpendicular to each other. (8) Find the value of m such that the vectors a = 2mi + mj + 8k and b = i + 3mj – k are perpendicular

19 Examples (9) Find a vector perpendicular to a = 3i – 4j (10) find a vector perpendicular to both a = 2i + j – k and b = i + 3j + k

20 Properties of the Scalar Product (a) Closure  NO closure  the dot product of 2 vectors is NOT another vector (b) Commutative  a · b = b · a (c) Associative  NO since (a · b) · c is undefined (d) distributive  A · (B+C) = A · B + A · C

21 Properties of the Scalar Product (au + bv) · w = (au) · w + (bv) · w, where a and b are scalars u · v = 0 when u and v are orthogonal. 0 · 0 = 0 |v| 2 = v · v a (u·v) = (a u) · v

22 Internet Links http://www.youtube.com/watch?v=WNuIhXo39_k http://hyperphysics.phy-astr.gsu.edu/Hbase/vsca.html http://www.sparknotes.com/physics/vectors/vectormultiplication/s ection1.html http://www.sparknotes.com/physics/vectors/vectormultiplication/s ection1.html http://www.netcomuk.co.uk/~jenolive/vect6.html http://videolectures.net/mit801f99_lewin_lec03/ http://www.intmath.com/Vectors/5_Dot-product- vectors-2-dimensions.php http://www.intmath.com/Vectors/5_Dot-product- vectors-2-dimensions.php http://chortle.ccsu.edu/VectorLessons/vch07/vch07_1. html http://chortle.ccsu.edu/VectorLessons/vch07/vch07_1. html http://cnx.org/content/m14513/latest/

23 Homework HW : Ex 15H #1b, 2a,3a, 4ae, 5a, 6a, 8a, 10a, 12c; Ex 16G #1be, 4, 7, 9, 11d, 13; IB Packet #1, 4, 5, 7

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