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Unit-02 Plane Geometry Introduction: Learning Objectives of this UNIT 1. Classify simple plane geometrical figures. 2. Calculate perimeter and other distances of basic geometrical figures (rectangles, circles, squares, etc.), and complex figures that can be obtained by combining simple geometrical figures. 3. Calculate areas of simple geometrical figures and complex figures that can be obtained by combining simple geometrical figures. 4. Use properties of similar triangles to calculate unknown parameters of plane geometrical figures. 5. Solve real world problems involving perimeters and areas. 6. Solve real world problems using properties of the right-angle triangle (the Pythagorean Theorem) Some Concepts in Plane Geometry Angles A geometrical figure formed by two rays (straight lines) extending from a common point (the vertex) is called an angle. When these lines are perpendicular to each other the angle they subtend is called a right angle (90o). The angle is called straight (1800) when the two lines forming an angle lie along a straight line. An angle is called acute if it is less than the right angle, and obtuse if it exceeds 90o. Two adjacent angles adding to 1800 are called supplementary. When the two adjacent angles add up to a right angle the angles are termed complementary. Vertical angles are nonadjacent angles formed by two intersecting straight lines. An angle is measured in degrees ( 0 ), minutes ( ' ) and seconds( " ). 10 = 60’; 1' = 60" 1 Prof. Tyagi Angles obtained when a line intersects two parallel lines are shown in the diagram on the right. 1 2 3 4 5 The four angles, !3,!4,!5,and !6 are called alternate interior angles, where; !3 = !6 and !4 = !5 6 7 8 Figure 1 The four angles, !1,!2,!7 and !8 are called alternate exterior angles, where; !1 = !8 and !2 = !7 The angles in the following equations are called corresponding angles: !1 = !5 !2 = !6 !3 = !7 !4 = !8 Triangles. A triangle is a plane figure bounded by three line segments called sides. A triangle has three vertices (A vertex is a point common to two sides). An altitude is a perpendicular segment drawn from a vertex to the opposite side ( known as the base). The three interior angles of a triangle add up to 1800. c α b β γ a Figure 2. In Figure 2, let a, b, and c, represent the three sides of a triangle whereas, α, β and γ are the internal angles of a triangle. 1. When, a ≠ b ≠ c, the triangle is called scalene. 2. When, a = b ≠ c, the triangle is called isosceles 3. When, a = b =c, the triangle is called equilateral 2 Prof. Tyagi 4. If none of the three angles exceeds a right angle the triangle is called acute, otherwise it is termed obtuse. 5. If one of the three angles equals 900, the triangle is called a right-angle triangle. The three sides of such triangles are related through the Pythagorean theorem a2 = b2 + c2, where b and c are perpendicular to each other, and a is the hypotenuse - the side opposite to the right angle. Similarity of Triangles Two geometrical figures are called similar if they can be exactly superimposed on each other by scaling the corresponding dimensions of one of the figures by a constant factor, called the scaling factor. In the diagram shown below, ΔABC and ΔAFE are similar. Two triangles are called similar when one is just a smaller version of the other. This happens when either of the following two conditions is met. E [a] Two of the internal angles of one triangle are equal to the two internal angles of the other triangle. C In the diagram below α is common to both triangles and β = θ since BC is parallel to FE. [b] The ratios of the corresponding sides of the two triangles are equal to each other. For the example given here: AC/AE = AB/AF =BC/FE 3 A α θ β B F Figure 3. Prof. Tyagi TABLE-I Some Common Geometrical Figures Object Triangle Formulas (P = perimeter) (A = Area) P=a+b+c A = bh/2 Typical Figure a c h b Rectangle P = 2(a + b) A = ab a b Square Trapezoid Parallelogram A square can be viewed as a rectangle with a = b, therefore: P = 4a and A = a2 a a b1 A = h (b1+ b2)/2 P = sum of the four sides. No general formula can be provided h b2 A = bh P = 2*sum of the two adjacent sides h b Circle P (circumference) = 2πr A = πr2 For a sector of a circle of radius r and central angle θ P = 2r[1 +π(θ/360)] A = (θ/360) πr2 r r q Notes: 1. Perimeter is the distance measured around a plane figure. The units of measurement are inches, feet, yards, mile (in the British system of units) and centimeter (cm), meter (m), and kilometer (km) in the Metric system of units. 2. Area is measured in units of ft2, m2, etc. 4 Prof. Tyagi Plane Geometry: Solved Examples: Example 1. ΔABC is a right angle triangle, CD is perpendicular to AB. Show that ΔBCD, and ΔADC are similar. C Solution: ! # To show similarity of two triangles, you only need to show " $ that any two of the three internal angles in one triangle A D are equal to the corresponding two angles in the other triangle. In case of a right- angle triangle this requirement is reduced to showing that one of the acute angles in one triangle is equal to one of the angles in the other triangle. Therefore, the similarity can be easily proved by noting that: δ = 900 - γ and α = 900 - γ = δ. Thus, the two triangles BCD and ADC are similar. Example 2. Δ ABC is a right angle triangle and CD is perpendicular to AB. If CD = 30.0cm and DB = 20.0cm, what is the area of Δ ADC? C Solution: # ! The area of ΔADC = CD*AD/2 Using the similarity of A " $ ΔBCD and ΔADC, D B AD/CD = CD/DB = 30.0/20.0 = 1.5 Therefore, AD = 1.5CD = 45.0 cm. Hence, the area of ΔADC = CD*AD/2 = 30.0*45.0/2 = 1350 cm2 5 Prof. Tyagi B Example 3. If in Example 1 above, AB = 50.0cm, and AC = 40.0cm., determine CD using the similarity of triangles. Solution. Using the Pythagorean theorem, BC = [(50.0)2 – (40.0)2]1/2 cm = 30.0cm Next we note that ΔBCD, and ΔABC are similar, therefore, BC/AB = CD/AC therefore, CD = (BC/AB)*AC =(30.0/50.0)*40.0 = 24.0 cm ______________________________________________________________________ Problem Solving Strategy When calculating areas of complex figures, remember the following three simple steps: 1. Decompose the complex figure into its simpler parts. 2. Find the area of the component geometrical shapes. 3. Reconstruct the original figure by recombining the component parts. ______________________________________________________________________ Example 4. A 4.0-ft wide door is to be constructed out of aluminum. The door is in the shape of a semi-circle, CDE sitting atop a rectangle ABCD. If the area of the door is 47.0 square feet, determine the height, H of the door. E Solution. r The total area of the door can be expressed as the sum of two parts, i.e., a semicircle of radius, r = 2.0ft and a rectangle 4.0-ft wide and of height, (H– r). Thus, C D A B H πr2/2 + 4.0*(H-r) = 47.0 ft2 Substituting for r =2.0ft gives, [(3.14)(2.02)/2] + 4.0H – 4.0*2.0 = 47.0 ft2, or 4H = 47.0 + 8.0 – 6.28 = 48.7 ft2 H 6 = 48.7/4 = 12.2 ft. 4 ft Prof. Tyagi Example 5. What is the area of a regular hexagon of edge length b? Solution b A regular hexagon can be viewed as composed of six equilateral triangles of side b. C Therefore the area of the hexagon, AH = 6 [AB*CD/2] =6 [AD*CD] = 3b*CD b Where, o 2 2 90 A 1/2 CD = ([b – b /4] ) = (3/4)1/2 b B D Thus AH = 3b*(3/4)1/2 b =2.6b2 Example 6. A machine part ABCDA is to be fabricated from a circular piece of aluminum of radius 6.0 cm. The angle subtended by the two radii, OA and OC is 60o.Determine the area of the machine part. Solution C We can view the area to be determined as composed of two parts: a circular sector COABC of radius r = 6.0 cm and central angle of 360o – 60o = 300o and an equilateral triangle of 6.0cm on the side. The 3000-sector in turn can be viewed as a circle from which a 600-sector has been removed. Thus the machine part can be viewed as: = - o 60 r B O 60o D r A + The area of the circle = πr2 The area of the 600-sector = πr2 (60/360) The area of the equilateral triangle = OD*CD = ([r2 – r2/4]1/2)r/2 = (3/4)1/2 r2/2 Thus, the total area AT of the machine part ABCDA is: 7 Prof. Tyagi AT = πr2 - πr2 (60/360) + (3/4)1/2 r2/2 = 30π +15.59 = 109.8 cm2 = 1.1 x 10–2 m2 (Note: 1cm = 10–2 m and 1cm2 = 10–4 cm2) 8 Prof. Tyagi