A Treatise on Plane and Spherical TrigonometryH. Perkins, 1852 |
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Page 11
... radius of the circle may be ; and we obtain the same numerical expression of an angle , whether we refer it directly to the angu- lar unit , or to the corresponding unit of arc . The right angle AOA ' , Fig . 3 , and its measure , the ...
... radius of the circle may be ; and we obtain the same numerical expression of an angle , whether we refer it directly to the angu- lar unit , or to the corresponding unit of arc . The right angle AOA ' , Fig . 3 , and its measure , the ...
Page 12
... radius is unity is known to be 3.14159265 ; or , the radius being R , the semi - circumference is 3.14159265 R. Hence Arc 180 ° 3.14159265 R = When R = 1 = 3.14159265 66 1 ° = 0.017453293 R = 66 1 ' = = 0.0002908882 R 66 1 ...
... radius is unity is known to be 3.14159265 ; or , the radius being R , the semi - circumference is 3.14159265 R. Hence Arc 180 ° 3.14159265 R = When R = 1 = 3.14159265 66 1 ° = 0.017453293 R = 66 1 ' = = 0.0002908882 R 66 1 ...
Page 13
... radius , is often taken as the unit of angular measure , as this angle will be of an invariable magni- tude , whatever is the length of the radius . If x is the number of such units in a given angle , the number of degrees , & c . , in ...
... radius , is often taken as the unit of angular measure , as this angle will be of an invariable magni- tude , whatever is the length of the radius . If x is the number of such units in a given angle , the number of degrees , & c . , in ...
Page 16
... radius = 1 , all the trigonometric functions above de- fined may be represented in or about the circle by straight lines . Representing the arc AB , or angle AOB , by x , we have , when OA = 0B = 1 , Ᏼ Ꮯ Ᏼ Ꮯ sin x = = BC ов 1 AT AT ...
... radius = 1 , all the trigonometric functions above de- fined may be represented in or about the circle by straight lines . Representing the arc AB , or angle AOB , by x , we have , when OA = 0B = 1 , Ᏼ Ꮯ Ᏼ Ꮯ sin x = = BC ов 1 AT AT ...
Page 17
... radius . The properties here stated have heretofore been used by most writers upon trigonometry as definitions , but without limiting the ra- dius to unity ; and it is evidently from this mode of viewing these functions that they have ...
... radius . The properties here stated have heretofore been used by most writers upon trigonometry as definitions , but without limiting the ra- dius to unity ; and it is evidently from this mode of viewing these functions that they have ...
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Common terms and phrases
applied B+AB becomes Bowditch's Rules C+AC C₁ computation constant cos A cos cos A sin cosc cosec cosine cosm cot A cot deduce denote difference differential divided employed equal equations EXAMPLE expressed factors formulæ gives hypotenuse increments less than 180 log cot logarithms Napier's Rules negative obtain perpendicular plane triangle polar triangle positive preceding article quadrant quotient radius reduced right angle right triangles secant second member simple angle sin b cos sin b sin sin x sin² sin² ½ sine sine and cosine solution solve the triangle spherical triangle SPHERICAL TRIGONOMETRY tables tan-¹ tan² tana tangent theorem Trig trigonometric functions whence Δα
Popular passages
Page 151 - Spherical Triangle the cosine of any side is equal to the product of the cosines of the other two sides, plus the product of the sines of those sides into the cosine of their included angle ; that is, (1) cos a = cos b...
Page 58 - THE SUM OF THE OPPOSITE ANGLES', To THE TANGENT OF HALF THEIR DIFFERENCE. Thus, the sum of AB and AC, (Fig. 25.) is to their difference ; as the tangent of half the sum of the angles ACB and ABC, to the tangent of half their difference.
Page 58 - 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 15 - The sum of the two acute angles of a right triangle is equal to one right angle, or 90°.
Page 34 - I sin y \2 / \2 / = sin x cos y + cos x sin y, sin (a; — y) = sin (x + (— y)) = sin a; cos (— y) + cos a; sin (— y) = sin x cos y — cos x sin y, tan (x + y) = sin (x + y) sin x cos y + cos x...
Page 64 - As the sine of the angle opposite the given side, is to the sine of the angle opposite the required side ; so is the given side to the required side.
Page 65 - The side opposite the given angle is to the side opposite the required angle as the sine of the given angle is to the Bine of the required angle.
Page 179 - ... the sign of cos A, is the same as that of cos a, that is, A and a are in the same quadrant.
Page 150 - The law of sines states that in any spherical triangle the sines of the sides are proportional to the sines of their opposite angles: sin a _ sin b __ sin c _ sin A sin B sin C...
Page 244 - If the sides of a triangle are very small compared with the radius of the sphere and a plane triangle be formed whose sides are equal to those of the spherical triangle...