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= KI, cos. IKO (R-r) cos. b.

right triangle IKO, KO

=

=

EI, cos. IEF

=

(R − r)

In the right triangle FIE, EF cos. a. Also, EH = LN = D, since each is equal to R — KL. Then EFEH+HF=EH+KO; i.e., (R-r) cos. = (R―r) cos. b + D. Hence nat. cos. a= nat. cos. b + ID (R-7)].

= 1)

Were the curve CM located, and the curve BN to be substituted for it, that is to say, were a given and b required, we should have, by transposition, nat. cos. b = nat. cos. a· [D÷ (Rr)].

Example.

28, R

A 5o compounding into a 3° curve at B, which consumes an angle of 44° 20′, and terminates at N, 28 feet too far to the left. Here D = 1,910, r = 1,146, b = 44° 20; and, by the solution, nat. cos. a = nat. cos. 44° 20′ + (28 764). The nat. cos. 44° 20'

log. 2.883093

=

=

=

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0.69883; 28÷ 764 1.447158 log. 2.564065, corresponding to the decimal 0.03665, which, being added to nat. cos. 44° 20', gives 0.73548, the nat. cos. 42° 29'. Then BKN-CEM = 44° 20' 42° 29′ 1° 51'= angle BIC, equivalent on a 5° curve to 37 feet, which therefore is the distance around the arc from B, the erroneous P.C.C., to C, the correct one.

3. From these formulas the following general rule may be drawn: Divide the distance between terminal tangents by the difference of the radii, and call the quotient Q. Find the natural cosine of the terminal arc already located, and call it C. The sum or the difference of Q and C will be the natural cosine of the terminal arc to be substituted for that already located. With radii in the order R, r, should the terminal S inside tangent located strike the proposed tangent; or,

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with radii in the order r, R, should the terminal tangent

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the proposed tangent, — take the

difference of Q and C for the required cosine.

XXXII.

HAVING LOCATED A TANGENT, A B, INTERSECTING A CURVE, CD, FROM THE CONCAVE SIDE, TO FIND THE POINT E ON SAID CURVE AT WHICH TO BEGIN A CURVE OF GIVEN RADIUS WHICH SHALL MERGE IN THE LOCATED TANGENT.

B

1. Place the transit at the intersection point B. Set points at equal distances therefrom in both directions on the curve already located, by means of which the direction of a tangent to that curve at B may be fixed, and the angle FBA measured. Call that angle a; and, as shown in the figure, suppose the located curve to be prolonged into a terminal tangent, parallel with the newly located tangent A B. Complete the diagram. Call the larger radius R; the proposed radius, r; the central angle of the proposed curve, x. Then, obviously, the R cos. a. It is also equal to (R-r) cos. x + r.

E

=

a (R − r) cos. x+r. Hence cos. x

line A G
That is to say, R cos.
= R cos. a
r ÷ (R − r); and x

-

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angle BGE, sub

tended by the are BE, from which the length of the are may

be deduced, and the point E ascertained.

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to a distance from B around the 1° curve of 1,157 feet to E,

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XXXIII.

HAVING LOCATED A TANGENT, A B, INTERSECTING A CURVE, CD, FROM THE CONVEX SIDE, TO FIND THE POINT E ON SAID CURVE AT WHICH TO BEGIN A CURVE OF GIVEN RADIUS WHICH SHALL MERGE IN THE LOCATED TANGENT.

1. This problem is analogous to the preceding one. The preparatory steps are the same in both. Having found the angle a, however, it will be manifest to the attentive reader, that, in this case, R cos. a= (R+r) cos. x + r. Hence cos. x = (R cos. a r) ÷ (R+).

Example.

B

E

2. DC, a 10 curve; angle a = 64° 32': to connect with a 4° curve. Here cos. x = · (5,730 × 0.43) — 1,433 ÷ (5,730 +1,433) = 0.1439 = =cos. 81° 43'; and x — a = 17° 11', equivalent to a distance from B around the 1° curve of 1,718 feet to E, the point at which to start the 4° curve.

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2. Another solution of the Y problem is as follows:

Draw the tangent ED inThen is BD

son that each is equal to D E. Make G F = R+r, the diameter of a semicircle. Said semicircle touches tangent B A at D, its middle point; and D E being perpendicular to G F, we have by geometry GEDE::DE: EF; i.e., GE × EF, or R × r, = DE2. Hence D E = B D = DA = √R × r = R tan. † x, and we are thus enabled to fix the points E and A.

3. In the two foregoing problems, the angle consumed by curve EA is : = 180°

x.

Example.

BE, a 210 curve located; BA, a tangent: to complete the Y with a 6° curve, E A.

By the first method, cos. x = (R 955) (2,292 + 955)

log. 3.511482

=

=

1,337

r)

(R+r) = (2,292

3,247

=

log. 3.126131

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1.614649, which corresponds to log. cos.

9.614649, or to the decimal number 0.4118, indicating in either case the angle 65° 41' =

DE=BD=DA

= x.

=

= R tan. x = 2,292 × 0.6455 = 1,479.4. DE may be found also by reference to Table XVI., where the tangent of a 1° curve for 65° 41' is seen to be 3,698.6. Dividing this number by 2, we have 1,479.4, as above.

Or, by the second method,

B

DE=√√/RX r = √2188860=1,479.4.

E

A

Having thus the means of fixing points E, D, and A, the curve E A can be laid down.

4. If BA is curved convex to the Y, construct the figure as in margin, and reason thus:

In the triangle EGF, formed by lines connecting the curve-centres, the sides are respectively equal to the sums of the contiguous radii: the angles may therefore be found as in Case III., Trigonometry.

curves will pass through the points of intersection of the tangents to those curves severally. But lines so drawn in this case bisect also the angles of a triangle, and, demonstrably by geometry, meet in one point equidistant from the three sides of the triangle. That point, therefore, must be a common P. I. for all the curves, and that equidistance the “tangent" length common to them all.

Example.

Given BA, a 3o, and B C, a 4° curve: to complete the Y with a 5° curve, CA.

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Adding half the difference to half the sum of the segments of the base EG, we shall have the greater of them; i.e., (3,343 +804) ÷ 2 = 2,073.5, which is the cos. E, EF being radius. Hence 2,073.5 ÷ 3,056

3.485153

9.831551 cos. 47° 16'

=

=

log. 3.316704

=

log.

= E. By Table XVI., the tangent of a 1o curve corresponding to this angle is 2,507.3: that of a 30 curve, therefore, is 835.8 the common tangent BD or DA. Multiplying the common tangent by 4, we shall find opposite the product in Table XVI. the central angle of the 4° curve to be 60° 32'; multiplying it by 5, we find, in like manner, the central angle of the 5° curve to be 72° 12'. Arc BA, 47° 16', is equivalent to 1,575 feet on the 3° curve; arc BC, 60° 32', is equivalent to 1,513 feet on the 4° curve. Points being thus fixed at A and C, curve CA can be laid on the ground.

=

=

5. If curve BA is concave to the Y, the radii being given, construct the figure as follows:

First draw the triangle GFE, the sides of which are obviously derived from the given radii. Prolong the sides E G and

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