<p>Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Date: 6.1 Law of Sines Syllabus Objective: 3.5 – The student will solve application problems involving triangles (Law of Sines). Deriving the Law of Sines: Consider the two triangles. C C b a a h b h A B B c A c h h In the acute triangle, sin A = and sin B = . b a h In the obtuse triangle, sin(p -B) = sin B = . a Solve for h. h= bsin A and h= asin B sinB sin A Substitute. asin B= b sin A can be rewritten as = b a sinC sin B sin A The same type of argument can be used to show that = = . c b a Law of Sines: The ratio of the sine of an angle to the length of its opposite side is the same for all three angles of any triangle. C sinA sin B sin C a b c = =or = = b a a b csin A sin B sin C B A c</p><p>Solving a Triangle: finding all of the missing sides and angles</p><p>Note: The Law of Sines can be used to solve triangles given AAS and ASA.</p><p>Ex1: Solve the triangle DABC given that �B �15° ,= C 52 ° , and b 9 . We are given AAS, so we will use the Law of Sines. C 9 a B A c sinB sin C = Solve for c: b c Find m A using the triangle sum. m� A -180 +( 15 = 52) sinB sin A = Solve for a: b a DABC: m� A � _____, m � B = ____, m = C = ____, a ___, b ____, c _____</p><p>Page 1 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Ambiguous Case: When given SSA, there could be 2 triangles, 1 triangle, or no triangles that can be created with the given information.</p><p>Ex2: Solve the triangle DABC (if possible) when m� C=54° , a = 10, c 7 . sinC sin A Given SSA, use Law of Sines. = c a</p><p>Solve for A.</p><p>There is no possible triangle with the given information.</p><p>Ex3: Solve the triangle DABC (if possible) when m� C=31° , b = 46, c 29 . sinC sin B Given SSA, use Law of Sines. = c b Solve for B.</p><p>Note that the calculator only gives the acute angle measure for B. There does exist an obtuse angle B with the same sine. m� B -180 = 54.8 125.2° This is also an appropriate measure of an angle in a triangle, so there are 2 triangles that can be formed with the given information. Triangle 1 Triangle 2 </p><p>Page 2 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Application Problems 1. Draw a picture! 2. Use the Law of Sines to solve for what is asked in the problem.</p><p>Ex4: The angle of elevation to a mountain is 3.5° . After driving 13 miles, the angle of elevation is 9° . Approximate the height of the mountain.</p><p>(not drawn to scale)</p><p> z h</p><p>3.5° θ 9° 13</p><p>First, find θ: </p><p>You Try: Solve the triangle DABC (if possible) when m� B=98° , b = 10, c 3.</p><p>QOD: Explain why SSA is the ambiguous case when solving triangles.</p><p>Page 3 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Date: 6.2 Law of Cosines Syllabus Objective: 3.5 – The student will solve application problems involving triangles (Law of Cosines).</p><p>Law of Cosines: For any triangle, ABC</p><p> c2= a 2 + b 2 - 2 ab cos C C b2= a 2 + c 2 - 2 ac cos B b a 2 2 2 a= b + c - 2 bc cos A B A c</p><p>Note: In a right triangle, c2= a 2 + b 2 -2 ab cos90° � c 2 + a 2 - b 2 � 2 ab( 0) + c 2 a 2 b 2 (Pythagorean Theorem)</p><p>The Law of Cosines can be used to solve triangles when given SAS or SSS.</p><p>Ex1: Solve the triangle ABC when m� A=49° , b = 42, & c 15 . Note: The given information is SAS. Use a2= b 2 + c 2 - 2 bc cos A .</p><p>Now that we have a matching pair of a side and angle, we can use the Law of Sines. a b = or B =180 - 68.4 = sinA sin B Now find the two possibilities for m C using the triangle sum:</p><p>Since c is the shortest side, it must be opposite the smallest angle. So m� C .</p><p>Ex2: Solve the triangle ABC when a=31, b = 52, & c = 28 . Note: The given information is SSS. Use a2= b 2 + c 2 - 2 bc cos A . (Or any of them!)</p><p>Now that we have a matching pair of a side and angle, we can use the Law of Sines. a b = or B =180 - 56.5 = sinA sin B Now find the two possibilities for m C using the triangle sum: Since c is the shortest side, it must be opposite the smallest angle. So m� C . Application Problems</p><p>Page 4 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>1. Draw a picture! 2. Use the Law of Cosines to solve for what is asked in the problem.</p><p>Ex3: A plane takes off and travels 60 miles, then turns 15° and travels for 80 miles. How far is the plane from the airport? (not drawn to scale)</p><p>15° 80 165° 60 c Using the picture, we can find the angle in the triangle to give us SAS. Use the Law of Cosines: c2= a 2 + b 2 - 2 ab cos C</p><p>Area of a Triangle 1 h 1 Recall: A= bh sinq= � h c sin q ; \A = bcsinq 2 c 2</p><p> c h h θ b b 1 Formula for the Area of a Triangle Given SAS: A= absin C 2</p><p>Ex4: Find the area of triangle ABC shown. We will use . B 120° 1 32 A= acsin B 50 2</p><p>A C</p><p>Heron’s Area Formula a+ b + c Semi-Perimeter: s = 2 Area of a Triangle Given SSS: A= s( s - a)( s - b)( s - c)</p><p>Page 5 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Ex5: Find the area of the triangle with side lengths 5 m, 6 m, and 9 m. a+ b + c 5 + 6 + 9 Semiperimeter: s= � s � s 10 2 2 A= s( s - a)( s - b)( s - c)</p><p>You Try: Two ships leave port with a 19° angle between their planned routes. If they are traveling at 23 mph and 31 mph, how far apart are they in 3 hours?</p><p>QOD: Can there be an ambiguous case when using the Law of Cosines? Explain why or why not.</p><p>Page 6 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Date: 6.3 Vectors in the Plane Syllabus Objectives: 5.1 – The student will explore methods of vector addition and subtraction. 5.2 – The student will develop strategies for computing a vector’s direction angle and magnitude given its coordinates. 5.4 – The student will resolve vectors into unit vectors. 5.7 – The student will solve real-world application problems using vectors in two and three dimensions.</p><p>Directed Line Segment: a segment with direction and distance A: Initial Point (start); B: Terminal Point (end) B v AB</p><p>A</p><p>Coordinates of A: ( Ax, A y ) Coordinates of B: (Bx, B y )</p><p> v v 2 2 Magnitude (length) of a Directed Line Segment AB : AB=( Bx - A x) +( B y - A y ) Note: This is the distance formula!</p><p>Vector (v): the set of all directed line segments that are equivalent to a given directed line segment Note: Equivalent means same magnitude and direction.</p><p>Component Form of a Vector: Bx- A x, B y - A y</p><p>v Ex: Graph the vector AB =3, - 2 and find the magnitude. One possible graph: </p><p> y Note: could be placed anywhere on the coordinate grid. We have 6</p><p>4 2 v AB =3, - 2 -6 -4 -2 2 4 6 x -2</p><p>-4</p><p>-6 placed it in standard position, which is with the initial point at the origin. v Magnitude: AB = Note: If a vector u is written in component form, , then the magnitude of u is u = u1, u 2</p><p>2 2 0,0 u =(u1) + ( u 2 ) . This is because the initial point is the origin, ( ) .</p><p>Vector Addition: Let u = u1, u 2 and v = v1, v 2 . Then u+ v =u1 + v 1, u 2 + v 2 .</p><p>Page 7 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Scalar Multiplication: Let u = u1, u 2 and k be any constant. Then ku = ku1, ku 2 . Note: If k < 0 , then ku is in the opposite direction. Ex: Use the graph of the vectors to complete each example below.</p><p> u w</p><p> v</p><p>1. Show that u= v . Show that u= v . u = v = Show that the direction of u is the same as the direction of v. Use slope: Direction of u = ; direction of v = The direction and magnitude are the same, so u= v .</p><p>2. Find the component form and the magnitude of uand w . Component form of u: u = u = (see above) Component form of w: w = w =</p><p>3. Find the component form of 2u- 3 w . 2u- 3 w =</p><p>Unit Vector: a vector with a magnitude of 1 A unit vector in the direction of a vector v can be found by dividing v by the magnitude of v. v Unit Vector in the Direction of v: v</p><p>Standard Unit Vectors: unit vectors i and j in standard position along the positive x- and y-axes i=1,0 & j = 0,1 Any vector can be written in terms of the standard unit vectors. Ex: Write the vector v = -2,5 in terms of the standard unit vectors. v =</p><p>Ex: Find a unit vector in the direction of the given vector. Verify your answer is a unit vector and give your answer in component form and standard unit vector form. 2i- 4 j</p><p>Page 8 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Find the magnitude: 2i- 4 j = 2i- 4 j Divide the original vector by its magnitude: = 2 5</p><p>Component Form: </p><p>5 2 5 Verify magnitude of unit vector: ,- = ☺ 5 5</p><p>Recall: In the unit circle, x=cosq , y = sin q . This leads into another way of expressing a vector, in terms of its direction angle, θ.</p><p>Direction Angle: in standard position, the angle the vector makes with the positive x-axis (counterclockwise)</p><p>Resolving a Vector: in terms of its direction angle, θ, a vector can be written as u�cosq ,sin q+ u cos q i u sin q j</p><p>Ex: Find the magnitude and direction angle of v= -2 i + 6 j. Magnitude: v = Direction angle: vcosq i+ v sin q j </p><p> but since we know v= -2 i + 6 j is in Quadrant II, q =180 - 71.57 =</p><p>Page 9 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Ex: Find the component form of v given its magnitude and its direction angle. v =5,q = 30° v= vcosq i + v sin q j</p><p>Application: Resultant Force</p><p>° ° Ex: Two forces act on an object: u =3,qu = 45 and v =4,qu = - 30 . Find the direction and magnitude of the resultant force.</p><p>Write each vector in component form: u =</p><p> v= vcosqv i + v sin q v j The resultant force is the sum u+ v : </p><p>Application: Bearing</p><p>Ex: A plane flies due east at 500 km/h and there is a 60 km/h with a bearing of 45°. Find the ground speed and the actual bearing of the plane. 60 km/hr 45° θ 500 km/hr</p><p>Sketch a diagram: w v</p><p> p</p><p>Find the vectors p and w: p = w = Note: The 45° is the direction angle, not the bearing. Vector v is the sum p + w: v = The second component of vector v must equal zero, because the plane is headed due east. 60sin 45° + 500sinq = 0 Bearing of the plane: 90° + q Ground speed of the plane: v =</p><p>You Try: Find the component form of v given its magnitude and the angle it makes with the positive x- axis. v = 2 , direction: 2i+ 3 j OD: In the examples in your notes, we used sine or cosine to find the direction angle of a vector. Explain how you could use tangent to find the direction angle.</p><p>Page 10 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Date: 6.4 Vectors and Dot Product Syllabus Objective: 5.3 – The student will explore methods of vector multiplication. 5.5 – The student will determine if two vectors are parallel or perpendicular (orthogonal). 5.6 – The student will derive an equation of a line or plane by using vector operations. 5.7 – The student will solve real-world application problems using vectors in two and three dimensions.</p><p>Dot Product: Let u = u1, u 2 and v = v1, v 2 . The dot product is ug v =u1 v 1 + u 2 v 2 . Note: The dot product is a scalar.</p><p>Ex: Evaluate 5,- 2g 3,4 .</p><p>Properties of the Dot Product: 1. ug v= v g u 2 2. ug u = u 3. 0g u= 0 4. ug( v + w) = u g v+ u g w 5. (cu)g v= u g( c v) = c ( u g v)</p><p>Ex: Evaluate the following given u= -3,6 ; v = 1,0 ; w = 5, - 2 (a) wg w</p><p>(b) w</p><p>(c) (v+ w)g u</p><p>(d) vg u+ w g u</p><p> ug v-1 骣 u g v Angle Between Two Vectors: cosq= � q cos 琪 u v桫 u v Proof: Use the triangle. </p><p> v u − v θ u</p><p>Law of Cosines: v- u2 = u 2 + v 2 - 2 u v cosq 2 2 Property of Dot Product: (v - u)g( v - u) = u + v - 2 u v cosq 2 2 Expand: v� v- vg u + u g v = u g u + u - v2 u v cosq 2 2 2 2 Property of Dot Product: v-2 ug v + u = u + v - 2 u v cosq</p><p>Page 11 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p> ug v -2ug v = - 2 u v cosq� cos q Property of Equality: u v 5p Ex: Find ug v , where θ is the angle between u and v. u=6, v = 8, q = 6 u v cosq = g u v</p><p>Application Ex: Find the interior angles of the triangle with vertices (3,0) ,( 4,2) ,( 5,1) . y 4</p><p>3 B 2 1 C</p><p>-2 -1 1 2A3 4 5 6 x -1</p><p>-2 v AB = cos A =</p><p>v BA = cos B =</p><p>C</p><p>Angles: </p><p>Orthogonal Vectors: two vectors whose dot product is equal to 0</p><p>What is the angle between two non-zero orthogonal vectors? u v 0 cosq= g � cos q � � cos q 0 q 90° u v u v Note: If the angle between the vectors is 90°, we may also say they are perpendicular. The word orthogonal is used instead for vectors because the zero vector is orthogonal to any other vector, but is not perpendicular.</p><p>What is the dot product of two vectors that are parallel? The angle “between” them would have to be either 180° or 360°. ug v° u g v ug v° u g v cosq =� cos180 � = 1 ug v cosq = � cos360 � 1 ug v u v u v or u v u v</p><p>Page 12 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Parallel Vectors: two vectors whose dot product is equal to −1 or 1</p><p>Ex: Are the vectors orthogonal, parallel, or neither? v=3 i - 2 j , w = 3 i + 4 j Find vg w : The vectors are______.</p><p>骣u v proj u= 琪 g v Vector Projection: the projection of u onto v is denoted by: v 琪 2 桫v u u = u – u 2 1 </p><p> u = proj u 1 v v</p><p>Ex: Find the projection of v onto w. Then write v as the sum of two orthogonal vectors, with </p><p> one the projwv . v=1,3 ; w = 1,1</p><p>骣v w proj v= 琪 g w w 琪 2 桫w</p><p> v-projw v = v = </p><p>Application: Force Ex: Find the force required to keep a 200-lb cart from rolling down a 30° incline. Draw a diagram and label: </p><p> f 200 30°</p><p>The force due to gravity: g= -200 j (gravity acts vertically downward) 3 1 Incline vector: v=cos30° i + sin30 ° j = i + j ( ) ( ) 2 2 骣g v f=proj g = 琪 g v Force vector required to keep the cart from rolling: v 琪 2 桫v</p><p>Page 13 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>骣g v f=琪 g v = 琪 2 桫v Magnitude of Force: f =</p><p>Application: Work W = cosq ( force)( distance) Ex: A person pulls a wagon with a constant force of 15 lbs at a constant angle of 40° for 500 ft. What is the person’s work?</p><p>40°</p><p> w = cos40° ( 15 lbs)( 500 ft)</p><p>You Try: Find the projection of v onto u. Then write v as the sum of two orthogonal vectors, with one the projuv . v=2 i - 3 j ; u = i - j</p><p>QOD: If u is a unit vector, what is ug u ? Explain why.</p><p>Page 14 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Syllabus Objectives: 7.1 – The student will graph a complex number on the complex/Argand plane. 7.2 – The student will represent a complex number in trigonometric (polar) form. 7.3 – The student will simplify expressions involving complex numbers in trigonometric (polar) form. 7.4 – The student will compute the powers of complex numbers using DeMoivre’s Theorem and find the nth roots of a complex number.</p><p>Complex Number Plane (Argand Plane): horizontal axis – real axis; vertical axis – imaginary axis a+bi Plotting Points in the Complex Plane Ex: Plot the points A(3+ 4 i) , B( - 1 + 3 i) , &( 2 - i) in the complex plane. Imaginary 6 A 4 B 2</p><p>-6 -4 -2 2 4 6 Real -2 C</p><p>-4</p><p>-6</p><p>Absolute Value (Modulus) of a Complex Number: the distance a complex number is from the origin on the complex plane a+ bi = a2 + b 2 (This can be shown using the Pythagorean Theorem.)</p><p>Ex: Evaluate 3- i .</p><p>Recall: Trigonometric form of a vector: u cosq ,sin q</p><p>Trigonometric Form of a Complex Number z = a + bi: z= r(cosq + i sin q ) Note: This can also be written as . z= rcisq</p><p> b a= rcosq , b = r sin q , r = a2 + b 2 tanq = a r = modulus; θ = argument</p><p>Writing a Complex Number in Trig Form Ex: Find the trigonometric form of -2 - 2 3i . 1. Find r: r= a2 + b 2 = b 2. Find θ: tanq= � tan q a 3. Find Quadrant 4. z= r(cosq + i sin q )</p><p>Page 15 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Writing a Complex Number in Standard Form (a + bi) Ex: Write 9cisp in standard form. Expand: 9cisp= 9( cos p +i sin p ) =</p><p>Multiplying and Dividing Complex Numbers</p><p>Let z1= r 1(cosq 1 + i sin q 1 ) and z2= r 2(cosq 2 + i sin q 2 ) .</p><p>Multiplication: z1� z 2 � r 1+ r 2臌轾cos(q 1 + q 2) i sin( q 1 q 2 )</p><p> z1 r 1 Division: =臌轾cos(q1 - q 2) +i sin( q 1 - q 2 ) z2 r 2</p><p>Ex: Express the product of z1 and z2 in standard form. </p><p> nn n Powers of a Complex Number: De Moivre’s Theorem z=臌轾 r(cosq + i sin q) = r( cos n q + i sin n q ) 5 Ex: Evaluate (-2 + i 2 ) .</p><p>Rewrite in trig form: n th Roots of a Complex Number: </p><p> n n轾 骣q2 pk 骣 q 2 p k n 骣 q+ 2 p k z= r犏cos琪 + + i sin 琪 + = r cis 琪 , k=0,1, 2,...( n - 1) 臌 桫n n 桫 n n 桫 n Note: Every complex number has a total of “n” nth roots.</p><p>Ex: Find the cube roots of 8i. Write in trig form:</p><p>Evaluate the roots:</p><p>Page 16 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6 Precalculus Notes: Unit 6 – Law of Sines & Cosines, Vectors, & Complex Numbers </p><p>Roots of Unity: the nth roots of 1 Ex: Express the fifth roots of unity in standard form and graph them in the complex plane. 5th Roots of Unity: 5 1+ 0i r =1,q = 0 1cis0</p><p>5 5 骣0+ 2pk 骣 2 p k 1cis0= 1cis琪 = cis 琪 桫5 桫 5</p><p>You Try: 1. Write each complex number in trigonometric form. Then find the product and the quotient. -1 + 3i , - 2 - 2 3 i 2. Solve the equation x4 +1 = 0 . (You should have 4 solutions!)</p><p>QOD: Is the trigonometric form of a complex number unique? Explain.</p><p>Page 17 of 17 Precalculus – Graphical, Numerical, Algebraic: Larson Chapter 6</p>