Three-Arc Vertical Curve for Constrained Highway Alignments
Publication: Journal of Transportation Engineering
Volume 124, Issue 2
Abstract
Existing symmetrical and unsymmetrical (two-arc) vertical curves may not be feasible when the highway alignment is subject to physical constraints (e.g., vertical clearance) and the beginning and end of the vertical curve are fixed. This paper presents a new three-arc vertical curve that accommodates such constraints. The unsymmetrical three-arc curve connects two tangents with unequal lengths and consists of three parabolic arcs smoothly connected at the points of common curvature. Since there are generally many three-arc curves that satisfy the constraints, the optimal three-arc curve that maximizes the smoothness of the curve was found. This was achieved by minimizing the sum of the absolute differences in the rates of change of grades at the two points of common curvature using an exhaustive search. Existing traditional and equal-arc unsymmetrical curves were found to be special cases of the three-arc curve. Another interesting special case is the three-equal-arc symmetrical curve, which is directly solved in closed-form. Sight distance characteristics of the three-arc curve were analyzed and compared with those of existing curves. It is shown that the three-arc curve improves sight distance for certain conditions. Application of the new curve is illustrated using numerical examples. The proposed vertical curve should be useful in the design of constrained vertical alignments such as complex freeway interchanges.
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References
1.
Colcord, J. E.(1962). “Vertical curve theory.”Surveying and Mapping, 22(4), 589–592.
2.
Easa, S. M. (1991a). “Sight distance model for unsymmetrical crest curves.”Transp. Res. Record 1303, Transportation Research Board, Washington, D.C., 39–50.
3.
Easa, S. M. (1991b). “Sight distance models for unsymmetrical sag curves.”Transp. Res. Record 1303, Transportation Research Board, Washington, D.C., 51–62.
4.
Easa, S. M. (1994). “New and improved unsymmetrical vertical curve for highways.”Transp. Res. Record 1445, Transportation Research Board, Washington, D.C., 94–100.
5.
Easa, S. M., Abd El Halim, A. O., and Hassan, Y.(1996). “Sight distance evaluation on complex highway vertical alignments.”Can. J. Civ. Engrg., Ottawa, Canada, 23(3), 577–586.
6.
Guell, D. L. (1991). “Discussion: sight distance model for unsymmetrical crest curves.”Transp. Res. Record 1303, Transportation Research Board, Washington, D.C., 49–50.
7.
Hassan, Y., Easa, S. M., and Abd El Halim, A. O. (1995). “New development for establishing no-passing zones on two-lane highways due to vertical alignments.”Proc., 1995 Annu. Conf. of the Can. Soc. for Civ. Engrg. (CSCE), Vol. 4, Montreal, Quebec, Canada, 205–214.
8.
Hassan, Y., Easa, S. M., and Abd El Halim, A. O. (1996). “Analytical model for sight distance analysis on 3-D highway alignments.”Transp. Res. Record 1523, Transportation Research Board, Washington, D.C., 1–10.
9.
Hickerson, T. F. (1964). Route location and design. McGraw-Hill Book Co., Inc., New York, N.Y.
10.
Policy on geometric design of highways and streets. (1994). American Association of State Highway and Transportation Officials, Washington, D.C.
Information & Authors
Information
Published In
Journal of Transportation Engineering
Volume 124 • Issue 2 • March 1998
Pages: 163 - 171
Copyright
Copyright © 1998 American Society of Civil Engineers.
History
Published online: Mar 1, 1998
Published in print: Mar 1998
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