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Let ABC be the proposed triangle; AD the perpendicular, let fall from the vertex A on the opposite side BC: there may be two

cases.

First. If the perpendicular falls within B the triangle ABC, the right-angled triangles ABD, ACD, will give,

R:sin B::AB: AD.

R:sin C:: AC: AD.

.A.

In these two propositions, the extremes are equal; hence, sin C: sin B::AB: AC.

Secondly. If the perpendicular falls A without the triangle ABC, the rightangled triangles ABD, ACD, will still give the proportions,

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But the angle ABD is the supplement of ABC, or B; hence sin ABD=sin B; hence we still have

sin C: sin B::AB: AC.

THEOREM IV.

In every rectilineal triangle, the cosine of either of the angles is equal to radius multiplied by the sum of the squares of the sides adjacent to the angle, minus the square of the side opposite, divided by twice the rectangle of the adjacent sides.

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First. If the perpendicular falls within
the triangle, we shall have AC2-AB2+
BC2-2BCX BD (Book IV. Prop. XII.); B
AB2+BC2-AC2

D

But in the right-angled triangle

hence BD

2BC

ABD, we have

R: cos B::AB: BD;

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hence by substituting the value of BD, we shall again have

cos B=RX

AB2+BC2-AC

2ABX BC

Scholium. Let A, B, C, be the three angles of any triangle ; a, b, c, the sides respectively opposite them: by the theorem,

we shall have cos B=RX

a2+c2_b2

2ac

And the same principle,

when applied to each of the other two angles, will, in like man

ner give cos A=R×

b2+c2—a2

2bc

a2+b2―c2

and cos C-Rx

2ab

Either of these formulas may readily be reduced to one in which the computation can be made by logarithms.

Recurring to the formula R-R cos A=2sin A (Art. XXIII.), or 2sin2A=R2—RcosA, and substituting for cosA, we shall have

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2bc

2bc

4bc

sin }A—R√((a+b—c) (a+c—b)

For the sake of brevity, put

(a+b+c)=p, or a+b+c=2p; we have a+b-c=2p—2c, a+c-b=2p-26; hence

sin }A=R √ ((P—b) (p—c)).

bc

THEOREM V.

In every rectilineal triangle, the sum of two sides is to their difference as the tangent of half the sum of the angles opposite those sides, to the tangent of half their difference.

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the property we had to demonstrate.

With the aid of these five theorems we can solve all the cases of rectilineal trigonometry.

Scholium. The required part should always be found from the given parts; so that if an error is made in any part of the work, it may not affect the correctness of that which follows.

SOLUTION OF RECTILINEAL TRIANGLES BY MEANS OF

LOGARITHMS.

It has already been remarked, that in order to abridge the calculations which are necessary to find the unknown parts of a triangle, we use the logarithms of the parts instead of the parts themselves.

Since the addition of logarithms answers to the multiplication of their corresponding numbers, and their subtraction to the division of their numbers; it follows, that the logarithm of the fourth term of a proportion will be equal to the sum of the logarithms of the second and third terms, diminished by the logarithm of the first term.

Instead, however, of subtracting the logarithm of the first term from the sum of the logarithms of the second and third terms, it is more convenient to use the arithmetical complement of the first term.

The arithmetical complement of a logarithm is the number which remains after subtracting the logarithm from 10. Thus 10-9.274687=0.725313: hence, 0.725313 is the arithmetical complement of 9.274687.

It is now to be shown that, the difference between two logarithms is truly found, by adding to the first logarithm the arithmetical complement of the logarithm to be subtracted, and diminishing their sum by 10.

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b

=

the first logarithm.

the logarithm to be subtracted. c10-b-the arithmetical complement of b.

Now, the difference between the two logarithms will be expressed by a-b. But from the equation c=10-b, we have c-10--b: hence if we substitute for b its value, we shall have

a-b=a+c-10,

which agrees with the enunciation.

When we wish the arithmetical compleinent of a logarithm, we may write it directly from the tables, by subtracting the left hand figure from 9, then proceeding to the right, subtract each figure from 9, till we reach the last significant figure, which must be taken from 10: this will be the same as taking the logarithm from 10.

Ex. From 3.274107 take 2.104729.

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jecting the 10.

We therefore have, for all the proportions of trigonometry, the following

RULE.

Add together the arithmetical complement of the logarithm of the the first term, the logarithm of the second term, and the logarithm of the third term, and their sum after rejecting 10, will be the logarithm of the fourth term. And if any expression occurs in which the arithmetical complement is twice used, 20 must be rejected from the sum.

SOLUTION OF RIGHT ANGLED TRIANGLES.

Let A be the right angle of the proposed right angled triangle, B and C the other two angles; let a be the hypothenuse, b the side opposite the angle B, c the side opposite the angle C. Here we must consider that the B

C

A

two angles C and B are complements of each other; and that consequently, according to the different cases, we are entitled to assume sin C=cos B, sin B=cos C, and likewise tang B= cot C, tang C=cot B. This being fixed, the unknown parts of a right angled triangle may be found by the first two theorems; or if two of the sides are given, by means of the property, that the square of the hypothenuse is equal to the sum of the squares of the other two sides.

EXAMPLES.

Ex. 1. In the right angled triangle BCA, there are given the hypothenuse a=250, and the side b=240; required the other parts.

or,

R

sin B: a b (Theorem I.). a b R : sin B.

When logarithms are used, it is most convenient to write the proportion thus,

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To sin B

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73° 44′ 23′′ (after rejecting 10) 9.982271

But the angle C=90°—B=90°—73° 44′ 23′′=16° 15′ 37′′. or, C might be found by the proportion,

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