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19. Summary. In this chapter important additions have been made to the knowledge concerning angles that one gained in geometry. A process of measuring angles has been introduced. The close connection between angles and the ratios of lines has been emphasized. It has been shown that each (acute) angle has, associated with it, a definite set of six numbers, called trigonometric ratios; and it has been seen that the sets of numbers are different for different angles. It has also been shown that the seven quantities (namely, the angle and the six numbers) are so related, that, if one of the seven be given, then the remaining six can be determined.

A few applications to the measurement of lines and angles have been made in some of the preceding articles. The next two chapters are taken up with a formal treatment of such applications. It should be stated, however, that any one who understands the contents of this chapter is in possession of all the principles which will be used in the next two chapters, and can proceed directly to the solution of the problems given there. The student is recommended to attack some of the exercises in Chapters III., IV., before reading the explanations given in the text. Attention may again be given to the first part of Art. 14.

N.B. Questions and exercises suitable for practice and review on the subject-matter of Chapter II. will be found at pages 182, 183.

CHAPTER III.

SOLUTION OF RIGHT-ANGLED TRIANGLES.

Before the solution of right-angled triangles is entered upon, a few remarks will be made on the solution of triangles in general. Some of the ideas expressed in Arts. 20-24 are applicable to practical problems throughout the book.

20. Solution of a triangle. Every triangle has three sides and three angles. These six quantities are called the parts or elements of a triangle. Sometimes one or several of the parts of a triangle are known; for instance, the three sides, two angles and a side, two sides, one side, three angles, and so on. In such cases the questions arise: Can the remaining parts be found or determined? and, if so, by what method shall this be done? The process of deducing the unknown parts of a triangle from the known, is called solving the triangle, or, the solution of the triangle. This Chapter and Chapter VII. are concerned with showing, in detail, methods of solving triangles. There are two methods which can be used to find (only approximately, in general) the unknown parts of a triangle when some of its parts are given. These methods are: (a) The graphical method;

(b) The method of computation.

21. The graphical method. This method consists in drawing a triangle which has angles equal to the given angles, and sides proportional to, and thus representing the given sides, and then measuring the remaining parts directly from the drawing.

For example, a triangle has two sides whose lengths are 10 ft., 5 ft., and the included angle is 28° 30'; the third side and the other angles are required. The graphical solution is as follows: Construct a triangle QPR having two sides, PQ, PR, representing 10 ft., 5 ft., respectively, on some con

38

venient scale, and

shown in Fig. 14.

R

with their included angle, QPR, equal to 28° 30', as Measure the angles PRQ, PQR with the protractor; measure the side RQ and, by reference to the scale, find the length represented by RQ. [The results thus obtained may be compared with those obtainable by the method of computation explained in Arts. 54, 57. The latter results are R: = 128° 26' 46", Q = 23° 3' 14", RQ 6.092.]

=

P

5 Ft.

80 28 30

10 Ft. FIG. 14.

Q

The conditions necessary and sufficient for constructing a triangle, and the methods of drawing triangles that satisfy given conditions, are shown in plane geometry and in geometrical drawing. It is obvious that the graphical method can be employed only when the values of the parts given are consistent with one another, and when the parts given are sufficient in number to determine a definite triangle. For instance, suppose that one is asked to find the remaining parts of a triangle one of whose sides is 10 inches long. In this case as many unequal triangles as one please, can be constructed, all of which will satisfy the given condition. Again, a given side and a given angle are insufficient data on which to proceed to find the remaining parts of a triangle, for there is an infinite number of unequal triangles which can have parts equal to the given parts. So also the method fails if three angles be given; for an infinite number of unequal triangles can be drawn whose angles are equal to the given angles. Again, let it be required to find the angles of a triangle whose sides are 10 feet, 40 feet, 60 feet. Such a triangle is impossible, since the length of one side (60 feet) is greater than the sum of the lengths of the other two. One more instance: let two given angles be 85° and 105° and the included side be 40 inches; this triangle is impossible, since the sum of the two given angles is greater than two right angles.

22. The method of computation. This method is applicable in precisely the same cases in which the preceding method can be employed; namely, in the cases in which the parts given are consistent with one another, and afford conditions sufficient to enable one to construct a definite triangle. This will be fully apparent later, when the various cases will be treated in detail. One of

the principal purposes of this book is to show the different methods of computation applicable to various sets of given conditions. One of the principal objects of a student who is taking a first course in trigonometry should be to acquire facility and, above all, accuracy in using these methods of computation.

23. Comparison between the graphical method and the method of computation. The experience gained in some of the exercises in the preceding chapter has probably shown the student that he can attain much greater accuracy by using the method of computation than by using the graphical method. The accuracy of the results obtained by the latter method depends upon the carefulness and skill with which the figures are drawn and measured; in the other method, accuracy depends upon the care and patience employed in performing arithmetical work. While the results attainable by the graphical method, even in the case of skilled persons with excellent drawing instruments, are not as accurate as the results attainable by the other method, yet they are often accurate enough for practical purposes. When the computations required are long and complicated, the graphical method is much the more rapid of the two.

There are several reasons why it is advisable for the learner to use the graphical method, as well as the method of computation, in solving problems in this course. The first reason is that the former method will serve as a check upon the latter. With ordinary care the graphical method very quickly gives a fair approximation to the result. This result will sometimes show that there is an error in the result obtained by computation. A little error in arithmetic may yield a quantity which is ten times too great or too small; but this can be detected at once if the other method has also been used.* A second reason for using the graphical method is that this method incidentally provides training in neat, careful, and accurate drawing; this training will not only be a benefit in itself, but will be of very great advantage in other studies, and especially in the applied sciences. A third

*The results can also be tested by methods of computation, which will be shown in due course.

reason is that the pupil will gain some knowledge and experience of a method that is used in other subjects, for instance, in physics and in mechanics, and that is extensively employed by engineers in solving problems in which the computations required by the other method may be overwhelmingly cumbrous.

24. General directions for solving problems. A third method of approximating to the magnitude of lines and angles may be mentioned here, for it has often to be employed in practical life. In this method the student may suppose that he possesses neither measuring instruments, drawing materials, nor mathematical tables, and thereupon he may give an off-hand estimate concerning the magnitudes required. This method also serves as a check, by showing when great arithmetical blunders are committed. The pupil is advised to use all three methods in working each practical problem in this course, and to do so in the following order:

(1) Make an off-hand estimate as to what the magnitude required may be, and write this estimate down;

(2) Solve the problem by the graphical method;

(3) Solve the problem by the slower but more accurate and reliable method of computation. There may be some interest found in comparing the results obtained by these three methods. The exercise in judging linear and angular magnitudes afforded by the first method, the practice in neat and careful drawing necessary in the second, and the training in accurate computation given by the third, will each afford some benefit to the learner.

B

25. Solution of right-angled triangles. Let ABC be a rightangled triangle, C being the right angle. In what follows, a, b, c, denote the lengths of the sides opposite to the angles A, B, C, respectively. The sides and angles of ABC are connected by the following relations:

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α

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