The Elements of Plane Trigonometry |
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Page 5
... proved that any two angles are proportional to the ratios by which we propose to measure them . Now , in the same circle , or equal circles , angles at the centre are proportional to their intercepted arcs . Therefore ( Fig . 6 ) , - 0 ...
... proved that any two angles are proportional to the ratios by which we propose to measure them . Now , in the same circle , or equal circles , angles at the centre are proportional to their intercepted arcs . Therefore ( Fig . 6 ) , - 0 ...
Page 39
... Prove sec 2 A. csc 2 A sec 2A + csc 2 A. = 12. Draw lines in and about a circle whose radius is unity , which represent the functions of an angle A of the 2d quadrant when cos A ; also when A is an angle of the 4th quadrant , and cos A ...
... Prove sec 2 A. csc 2 A sec 2A + csc 2 A. = 12. Draw lines in and about a circle whose radius is unity , which represent the functions of an angle A of the 2d quadrant when cos A ; also when A is an angle of the 4th quadrant , and cos A ...
Page 41
... Prove cos2 A + cos 2B + cos 2 C = 1 . 34. Given Asin , B - sin - 1 ; Prove A + B = 90 ° . 35. Prove sin1x + cos - 1x = 90 ° . 36. Find the value of tan ( tan - 1x + ctn - 1x ) . CHAPTER III . FUNCTIONS OF THE SUM AND DIFFERENCE OF THE ...
... Prove cos2 A + cos 2B + cos 2 C = 1 . 34. Given Asin , B - sin - 1 ; Prove A + B = 90 ° . 35. Prove sin1x + cos - 1x = 90 ° . 36. Find the value of tan ( tan - 1x + ctn - 1x ) . CHAPTER III . FUNCTIONS OF THE SUM AND DIFFERENCE OF THE ...
Page 44
... ( -8 ) = cos ß . Hence we have - sin ( a — ß ) = sin a cos ẞ — cos a sin ß , [ 18 , b ] cos ( α - ẞ ) = cos a cos ẞ + sin a sin ß . [ 19 , b ] The four formulas proved above can be embodied in two 44 PLANE TRIGONOMETRY .
... ( -8 ) = cos ß . Hence we have - sin ( a — ß ) = sin a cos ẞ — cos a sin ß , [ 18 , b ] cos ( α - ẞ ) = cos a cos ẞ + sin a sin ß . [ 19 , b ] The four formulas proved above can be embodied in two 44 PLANE TRIGONOMETRY .
Page 45
Henry Nathan Wheeler. The four formulas proved above can be embodied in two formulas , as follows : sin ( aß ) = sin a cosẞ + cos a sin ß , [ 18 ] cos ( α + B ) = cosa cos ẞ sin a sin ẞ . [ 19 ] where we are to use either the upper signs ...
Henry Nathan Wheeler. The four formulas proved above can be embodied in two formulas , as follows : sin ( aß ) = sin a cosẞ + cos a sin ß , [ 18 ] cos ( α + B ) = cosa cos ẞ sin a sin ẞ . [ 19 ] where we are to use either the upper signs ...
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Common terms and phrases
4th quadrant a+ß acute angle adapted to logarithmic algebraic sign angle or arc angle xOP asin centre chord circ circle whose radius circular measure colog complement cos² cosecant cosine cotangent csc q ctn q ctn ẞ decrease denote direction equal to 90 equation example figures 22 find the functions following angles formulas functions of 90 geometry given angle Hence homologous sides hypothenuse initial line log csc meas negative number of degrees numerical value numerically equal obtained OC'B OC"B opposite perp perpendicular Plane Geometry positive Prove quadrant radius is unity respectively right angle right triangle rotation secant sin a sin sin² sine sine and cosine six ratios solution ß ctn straight line Substituting subtends tang tangent terminal line tions triangle of reference trigonometric functions vertex α α ов ос
Popular passages
Page 4 - The COMPLEMENT OF AN ANGLE, or arc, is the remainder obtained by subtracting the angle or arc from 90°. Thus the complement of 45° is 45°, and the complement of 31° is 59°. When an angle, or arc, is greater than 90°, its complement is negative. Thus the complement of 127° is — 37°. Since the two acute angles of a right-angled triangle are together equal to a right angle, they are complements...
Page 73 - In any triangle, the square of the side opposite an acute angle is equal to the sum of the squares of the other two sides, minus twice the product of one of these sides and the projection of the other side upon it.
Page 76 - С = с а (s — с) [73] Since the sine of an angle and the sine of its supplement are the same (v. [8]), whenever all that is given concerning an angle is the value of its sine, the angle may have either of two supplementary values. The ambiguity thus arising in the use of [72] is, however, removed by the consideration, that, since A, B, and C, being angles of a triangle, are each less than 180°, \ A, ^B, and •£ С are each less than 90°.
Page ix - In any plane triangle, the sum of any two sides is to their difference as the tangent of half the sum of the opposite angles is to the tangent of half their difference.
Page 73 - The sum of any two sides of a triangle is to their difference, as the tangent of half the sum of the angles opposite to those sides, to the tangent of half their difference.
Page 15 - If two right triangles have an acute angle of the one equal to an acute angle of the other, the other acute angles will be equal.
Page 93 - From a window on a level with the bottom of a steeple the angle of elevation of the steeple is 40°, and from a second window 18 feet higher the angle of elevation is 37° 30'.
Page 82 - Example II. Given a = 0.3578, B = 32° 41', C = 47° 54'. Answers. C = 47° 54', 6 = 0.1959, c = 0.2691. § 85. CASE II. Given two sides and an angle opposite one of them, — a, b, and A: find c, B, and C.
Page 94 - An observer from a ship saw two headlands ; the first bearing NE by E., and the second NW After he had sailed NNW 10.25 miles, the first headland bore E. by N., and the second WNW Find the bearing and distance of the first headland from the second.
Page 69 - Having measured a distance of 200 feet, in a direct horizontal line, from the bottom of a steeple, the angle of elevation of its top, taken at that distance, was found to be 47° 30'; from hence it is required to find the height of the steeple.