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Lesson 82 – Geometric Vectors HL Math - Santowski.

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1 Lesson 82 – Geometric Vectors HL Math - Santowski

2 What is the difference between speed and velocity? => Velocity is speed combined with direction

3 What are Vectors? A scalar quantity is simply anything in life that can be described by just a number e.g. the temperature, my age etc. However, a vector is a quantity that needs a direction as well for it to make sense. => Vectors have both magnitude (size) and direction Examples -Velocity = speed + direction e.g. wind velocity is 20kmh East -Displacement = distance + direction e.g. displacement of Leeds from York is 25 miles W => Vectors are directed quantities

4  Vectors are pathways What do they look like? Vectors can be represented as: -Straight Lines (directed lines segments) Size direction - Column Vectors 3131 3 1

5 A B u AB = u = C D v CD = v = These are known as column vectors.

6 The most common notation for vectors is threefold A B AB = a = a What do they look like?

7 Position Vectors is the journey from the origin to the point A. It is known as the position vector written a. Is the position vector of the point b, written b. OA OB y x o A B a b AB = b – a where a and b are the position vectors of A and B Example If P and Q have coordinates (4,8) and 2,3), respectively, find the components of PQ. PQ = q - p

8 If vectors have the same magnitude and opposite directions then: Vectors with the same magnitude and direction are equal B A Properties AB = a then BA = -a

9 If different sized vectors have the same direction they are scalar multiples of each other e.g. m = kn m n m = 2n Properties

10 Resultant vectors can be broken down in to their component vectors e.g. y x a Rewriting resultants xyxy a =a =

11 Resultants The resultant is a single vector which is equivalent to a set of vectors e.g. the result of adding a and b a b b c = a + b

12 => vectors can be rewritten in terms of other vectors a b c Rewriting Vectors a + b = c

13 AB C DE F a b c i) BA ii) CB iii) DC iv) AC v) AD Rewrite the following vectors in terms of a, b and c

14 AB C DE F a b c i) BA ii) CB iii) DC iv) AC v) AD = - a = - b = - c = a + b = a + b + c Rewrite the following vectors in terms of a, b and c

15 AB C DE F a b c i) ED ii) FE iii) AF iv) AE v) DA vi)BF vii)EC viii)DF Rewrite the following vectors in terms of a, b and c

16 AB C DE F a b c i) ED ii) FE iii) AF iv) AE v) DA vi)BF vii)EC viii)DF = a = b = c = c + b = – c – b – c = – a + c = a – c = – a – b Rewrite the following vectors in terms of a, b and c

17 B N A O P Q a. AP = b. AB = c. OQ = d. PO = e. PQ = f. PN = g. ON = h. AN = i. BP = j. QA = b a Rewrite the following vectors in terms of a and b

18 B N A O P Q a. AP = b. AB = c. OQ = d. PO = e. PQ = f. PN = g. ON = h. AN = i. BP = j. QA = b a a b – a 2b2b - 2a 2b – 2a b – a a + b b 2a - b a – 2b Rewrite the following vectors in terms of a and b

19 Vector Geometry AB C D i) Show that YX is parallel to AC ii) What is the ratio YX:AC AB = r AD = s X Y AY:YD = 1:2 DX:XB = 1:2

20 Solutions AB C D i) Show that YX is parallel to AC ii) What is the ratio YX:AC X Y AC = r + s YX = 2/3r + 1/3(r – s) r s DB = r - s YX = 1/3(r + s) i) AC and YX are scalar multiples => parallel ii) YX : AC = 1 : 3

21 i) Express BC in terms of p and q ii) Show that XZ is parallel to BC B C A X Y Z AB = p AC = q Vector Geometry X, Y and Z are all midpoints Solutions BC = q - p XZ = ½(q – p) => Scalar multiples (same direction)

22 Exercises from Cirrito 26.3

23 Exercises from Cirrito, 26.4

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