Chapter 6

1. Chapter 6 ADDITIONAL TOPICS IN TRIGONOMETRY

2. 6.1 Law of Sines • Objectives • Use the Law of Sines to solve oblique triangles • Use the Law of Sines to solve, is possible, the triangle or triangles in the ambiguous case • Find the area of an oblique triangle using the sine function • Solve applied problems using the Law of Sines

3. Law of Sines • Previously, our relationships between sides of a triangle and the angles were unique only to RIGHT triangles • What about other triangles? Obtuse or acute ones? (oblique – not right!) • The following relationship exists (A,B,C are measures of the 3 angles; a,b,c are the lengths of sides opposite those angles):

4. Solving an oblique triangle • If given: A = 50 degrees, B = 30 degrees, b = 7 cm. Can you solve this triangle? If so, is the solution unique? • You know C = 100 degrees (Now that you know the measure of all 3 angles and the length of 1 side, how many triangles exist? Only one!) • You can find “a” & “c” by law of sines:

5. What if given: a=5”,b=7”,B=45 degrees • Law of Sines indicates sinA=.505. There are 2 angles,A, such that sin(A) = .505. A = 30 degrees, OR A = 150 degrees (WHY? Look at your unit circle!) • Are there 2 possible triangles? NO – in this case, a (5”)is smaller than b (7”), and if angle A = 150 degrees, it must be opposite the longest side of the triangle. Clearly, it is not, therefore only 1 triangle exists. (continued)

6. Example continued • If A = 30 degrees & B = 45 degrees, C=105 degrees • Use law of sines again to find c.

7. What if given: a=7”,b=5”,B=45 degrees • Law of Sines indicates sinA=.99. There are 2 angles,A, such that sin(A) = .99. A = 82 degrees, OR A = 98 degrees (WHY? Look at your unit circle!) • Are there 2 possible triangles? YES – in this case, a (7”)is larger than b (5”), and if angle A = 82 or 98 degrees, it is a larger angle than B. Clearly, there are 2 triangles that exist. (continued)

8. 2 possible triangles • Triangle 1: use law of sines to find c: • Triangle 2: use law of sines to find c:

9. Finding area of an oblique triangle • Using Law of Sines it can be found that for any triangle, height (h) = b sin A (if c is considered to be the base), therefore Area= ½ c b sinA

10. 6.2 Law of Cosines • Objectives • Use the Law of Cosines to solve oblique triangles • Solve applied problems using the Law of Cosines • Use Heron’s formula to find the area of a triangle.

11. What if know a=4”,b=6”,C=70 degrees? • Law of Sines does NOT apply • Law of Cosines was developed: • Use this to solve for c in the given triangle: • b=c, so C = B = 70 degrees, thus A = 40 degrees

12. Using Law of Cosines, you can solve a triangle with 3 given sides • If the 3 sides are given, only 1 such triangle exists

13. Heron’s Formula for Area of a Triangle • If the 3 sides of a triangle are known, the area can be found (based on Law of Cosines):

14. 6.3 Polar Coordinates • Objectives • Plot points in the polar coordinate system • Find multiple sets of polar coordinate for a given point • Convert a point from polar to rectangular coordinates • Convert a point from rectangular to polar coordinates • Convert an equation from rectangular to polar coordinates • Convert an equation from polar to rectangular coordinates

15. Defining points in the polar system • Location of a point is based on radius (distance from the origin) and theta (the angle the radius moves from standard position (positive x-axis in a cartesian system)) • Any point can be described many ways. i.e. 2 units out moving pi/2 is the same as a radius of 2 units moving -3pi/2 or a radius of 2 units moving 5pi/2

16. What is the relationship between cartesian coordinates & polar ones? • The radius = r is the hypotenuse of a rt. triangle that has base = x & height=y • Thus, • If x = horizontal leg & y = vertical leg of a right triangle, then

17. Find rectangular coordinates for

18. Convert a rectangular equation to a polar equation

19. 6.4 Graphs of Polar Equations • Objectives • Use point plotting to graph polar equations • Use symmetry to graph polar equations

20. Graphing by Point Plotting • Given a function, in polar coordinates, you can find corresponding values for “r” and “theta” that will make your equation true. • Plotting several points and connecting the points with a curve provides the a graph of the function. • Example next page

21. Example: • Put values in for theta that range from 0 to 2pi (once around the circle..after that the values begin repeating)

22. Continued example

23. “Special” curves generated by general forms

24. r=3cos(theta)

25. r=2+3sin(theta)

26. r=3cos(5theta)

28. 6.5 Complex Numbers in Polar Form: DeMoivre’s Theorem • Objectives • Plot complex numbers in the complex plane • Fine absolute value of a complex # • Write complex # in polar form • Convert a complex # from polar to rectangular form • Find products & quotients of complex numbers in polar form • Find powers of complex # in polar form • Find roots of complex # in polar form

29. Complex number = z = a + bi • a is a real number • bi is an imaginary number • Together, the sum, a+bi is a COMPLEX # • Complex plane has a real axis (horizontal) and an imaginary axis (vertical) • 2 – 5i is found in the 4th quadrant of the complex plane (horiz = 2, vert = -5) • Absolute value of 2 – 5i refers to the distance this pt. is from the origin (continued)

30. Find the absolute value • Since the horizontal component = 2 and vertical = -5, we can consider the distance to that point as the same as the length of the hypotenuse of a right triangle with those respective legs

31. Expressing complex numbers in polar form • z = a + bi

32. Express z = -5 + 3i in complex form

33. Product & Quotient of complex numbers

34. Multiplying complex numbers together leads to raising a complex number to a given power • If r is multiplied by itself n times, it creates • If the angle, theta, is added to itself n times, it creates the new angle, (n times theta) • THUS,

35. Taking a root (DeMoivre’s Theorem) • Taking the nth root can be considered as raising to the (1/n)th power • Now finding the nth root of a complex # can be expressed easily in polar form • HOWEVER, there are n nth roots for any complex number & they are spaced evenly around the circle. • Once you find the 1st root, to find the others, add 2pi/n to theta until you complete the circle

36. If you’re working with degrees add 360/n to the angle measure to complete the circle. • Example: Find the 6th roots of z= -2 + 2i • Express in polar form, find the 1st root, then add 60 degrees successively to find the other 5 roots.

37. 6.6 Vectors • Objectives • Use magnitude & direction to show vectors are equal • Visualize scalar multiplication, vector addition, & vector subtraction as geometric vectors • Represent vectors in the rectangular coordinate system • Perform operations with vectors in terms of i & j • Find the unit vector in the direction of v. • Write a vector in terms of its magnitude & direction • Solve applied problems involving vectors

38. Vectors have length and direction • Vectors can be represented on the rectangular coordinate system • Vectors have a horizontal & a vertical component • A vector starting at the origin and extending left 2 units and down 3 units is given below, along with the magnitude of the vector (distance from the origin):

39. Adding & subtracting vectorsScalar Multiplication • Add (subtract) horizontal components together & add (subtract) vertical components together • v = 3i + 7j, w = -i + 2j, v – w = 4i + 5j • Scalar Multiplication: multiply the i & j components by the constant • v = 3i + 7j, 4v = 12i + 28j (the new vector is 4 times as long as the original vector)

40. Unit Vector has the same direction as a given vector, but is 1 unit long • Unit vector = (original vector)/length of vector • Simply involves scalar multiplication once the length of the vector is determined (recall the length = length of hypotenuse if legs have lengths = a & b) • Given vector, v = -2i + 7j, find the unit vector:

41. Writing a Vector in terms of its Magnitude & Direction • v is a nonzero vector. The vector makes an angle measured from the positive x-axis to v, and we can talk about the magnitude & direction angle of this vector:

42. Velocity Vector: vector representing speed & direction of object in motion • Example: The wind is blowing 30 miles per hour in the direction N20 degrees E. Express its velocity as a vector v. • If the wind is N20 degrees E, it’s 70 degrees from the positive x-axis, so the angle=70 degrees and the magnitude is 30 mph.

43. Resultant Force • Adding 2 force vector together • Add horizontal components together, add vertical components together

44. 6.7 Dot Product • Objectives • Find dot product of 2 vectors • Find angle between 2 vectors • Use dot product to determine if 2 vectors are orthogonal • Find projection of a vector onto another vector • Express a vector as the sum of 2 orthogonal vectors • Compute work.

45. Definition of Dot Product • The dot product of 2 vectors is the sum of the products of their horizontal components and their vertical components

46. Find the dot product of v&w if v=3i+j and w= -2i - j • 7 • -5 • -7 • -4

47. Properties of Dot Product • If u,v, & w are vectors and c is scalar, then

48. Angle between vectors, v and w

49. Parallel Vectors • Parallel: the angle between the vectors is either 0 (the vectors on top of each other) or 180 (vectors are in opposite directions), in either case, cos(0)=1, cos(180) = -1, this will be true if the dot product of v & w = (plus/minus)product of their magnitudes

50. Orthogonal Vectors • Vectors that are perpendicular to each other. The angle between vectors is 90 degrees or 270 degrees. cos(90)=cos(270)=0 • Since they are orthogonal if the numerator = 0, thus the dot products of the 2 vectors = 0 if they are orthogonal