EXAMPLES. 1. Construct the acute angle whose cosine is 3. What are its other trigonometric ratios? Find the number of degrees in the angle. The definition of the cosine of an angle shows that the required angle is equal to an angle in a certain right-angled triangle, namely, the triangle in hich "the side adjacent to the angle is to the hypote nuse in the ratio 2: 3." Thus the lengths of this side Now Hence, the other ratios are 3 A 2 FIG. 5. S T √5 The measure of the angle can be found in either one of two ways, viz. : (a) by measuring the angle with the protractor; (b) by finding in the table the angle whose cosine is or .6667. The latter method shows that A = 48° 11/22". [Compare the result obtained by method (a) with the value given by method (b).] 2. A right-angled triangle has an angle whose cosine is, and the length of the hypotenuse is 50 ft. Find the angles and the lengths of the two sides. 50 Ft. G By method shown in Ex. 1, construct an angle A whose cosine is 3. On one boundary line of the angle take a length AG to represent 50 ft. Draw GK perpendicular to the other boundary line. The problem may also be solved graphically as follows. Measure angles A, G, with the protractor. Measure AK, KG directly in the figure. 24 Ft. 8 Ft. 3. A ladder 24 ft. long is leaning against the side of a building, and the foot of the ladder is distant 8 ft. from the building in a horizontal direction. What angle does the ladder make with the wall? How far is the end of the ladder from the ground? Graphical method. Let AC represent the ladder, and BC the wall. Draw AC, AB, to scale, to represent 24 ft. and 8 ft. respectively. Measure angle ACB with the proMeasure BC directly in the figure. tractor. Method of computation. BC=VAC2 - AB2 = √576 – 64 = √/512 = 22.63 ft. FIG. 7. 4. Find tan 40° by construction and measurement. With the protractor lay off an angle SAT equal to 40°. From any point P in AT draw PR perpendicularly to AS. Then measure AR, RP, and substitute RP the values in the ratio, tan 40° AR T P Compare the result thus obtained with the value given for tan 40° in the tables.* Meas 5. Construct the angle whose tangent is §. Find its other ratios. ure the angle approximately, and compare the result with that given in the tables. Draw a number of right-angled, obtuse-angled, and acute-angled triangles, each of which has an angle equal to this angle. 6. Similarly for the angle whose sine is; and for the angle whose cotangent is 3. 7. Similarly for the angle whose secant is 23; and for the angle whose cosecant is 31. 8. Find by measurement of lines the approximate values of the trigonometric ratios of 30°, 40°, 45°, 50°, 55°, 60°, 70°; compare the results with the values given in the tables. *The values of the ratios are calculated by an algebraic method, and can be found to any degree of accuracy that may be required. If any of the following constructions asked for is impossible, explain why it is so. 9. Construct the acute angles in the following cases: (a) When the sines are 1, 2, 4, ; (b) when the cosines are, ‡, 3, .3; (c) when the tangents are 3, 4, 3, 1; (d) when the cotangents are 4, 2, 3, .7; (e) when the secants are 2, 3, 1, 1, 41; (f) when the cosecants are 3, 2.5, .4, 10. Find the other trigonometric ratios of the angles in Ex. 9. Find the measures of these angles, (a) with the protractor, (b) by means of the tables. 11. What are the other trigonometric ratios of the angles: (1) whose sine (2) whose cosine is (3) whose tangent is; (4) whose cotangent s; (5) whose secant is ; (6) whose cosecant is ? is α a a b 12. A ladder 32 ft. long is leaning against a house, and reaches to a point 24 ft. from the ground. Find the angle between the ladder and the wall. 13. A man whose eye is 5 ft. 8 in. from the ground is on a level with, and 120 ft. distant from, the foot of a flag pole 45 ft. 8 in. high. What angle does the direction of his gaze, when he is looking at the top of the pole, make with a horizontal line from his eye to the pole? 14. Find the ratios of 45°, 60°, 30°, 0°, 90°, before reading the next article. 15. Trigonometric ratios of 45°, 60°, 30°, 0°, 90°. The ratios of certain angles which are often met will now be found. By using the same figure it can be shown that √2 The sides of triangle AMP are proportional to 1, 1, √2. Hence, in order to produce the ratios of 45° quickly, it is merely necessary to draw Fig. 10; from this figure the ratios of 45° can A4 60 2 α D FIG. 11. 60 1 be read off at once. B. Ratios of 30° and 60°. Let ABC be an equilateral 3 triangle. From any vertex B draw a perpendicular BD to the opposite side AC. Then angle DAB = 60°, angle ABD = 30°. FIG. 12. By using the same figure it can be shown that ᎠᏴ sin DAB = DB_a√3_√3 2 In ADB the sides opposite to the angles 30°, 60°, 90°, are respectively proportional to 1, √3, 2. Hence, in order to produce the ratios of 30°, 60°, at a moment's notice, it is merely necessary to draw Fig. 12, from which these ratios can be immediately read off. C. Ratios of 0° and 90°. The algebraical note, Art. 76, may be read now. Let the hypotenuse in each of the right-angled triangles in Fig. 13 be equal to a. A M It is apparent from this figure that if the angle MAP approaches zero, then the perpendicular MP approaches zero, and the hypotenuse AP approaches to an equality with AM; so that, finally, if MAP = 0, then MP = 0, AM. Therefore, when MAP = 0, it follows that: and AP: FIG. 13. = 0, tan 0° a 1, cot 0° α cosec 0° = =∞. 0 N. B. Read the first few lines of Art. 17 before attacking the problems. 9. x cots 45° sec2 60° = 11 sin2 90°; find x. 10. x(cos 30° + 2 sin 90° + 3 cos 45° - sin2 60°) = 2 sec 0° - 5 sin 90°; find x. |