We performed numerical testing of six explicit Runge-Kutta pairs ranging in order from a (3,4) pair to a (7,8) pair. All the test problems had smooth solutions and we assumed dense output was not required. The pairs were implemented in a uniform way. In particular, the stepsize selection for all pairs was based on the locally optimal formula. We tested the efficiency of the pairs, to what extent tolerance proportionality held, the accuracy of the local error estimate and stepsize prediction, and the performance on mildly stiff problems. We also showed, for these pairs, how the performance could be altered noticeably by making simple changes to the stepsize selection strategy. As part of the work, we demonstrated new ways of presenting numerical comparisons. —From the Author's Abstract

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	DORMAND, J. R., AND PRINCE, P. J. A family of embedded Runge-Kutta formulae. J. Comput Appl. Math. 6 (1980), 19-26.
	2	J R Dormand , P J Prince, A reconsideration of some embedded Runge-Kutta formulae, Journal of Computational and Applied Mathematics, v.15 n.2, p.203-211, June 1986  [doi>10.1016/0377-0427(86)90027-0]
	3	ENRIGHT, W. H., AND HULL, T. E. Test results on initial value methods for non-stiff ordinary differential equations. SINUM 13 (1976), 944-961.
	4	W. H. Enright , K. R. Jackson , S. P. Nørsett , P. G. Thomsen, Interpolants for Runge-Kutta formulas, ACM Transactions on Mathematical Software (TOMS), v.12 n.3, p.193-218, Sept. 1986  [doi>10.1145/7921.7923]
	5	W. H. Enright , J. D. Pryce, Two FORTRAN packages for assessing initial value methods, ACM Transactions on Mathematical Software (TOMS), v.13 n.1, p.1-27, March 1987  [doi>10.1145/23002.27645]
	6	FEHLBERG, E. Classical fifth, sixth, seventh, and eighth order Runge Kutta formulas with stepsize control. Tech. Rep. TR R-287, NASA, 1968.
	7	FEHLBERa, E. Klassische Runge-Kutta-Formeln funfter und siebenter Ordnung mit Schrittweiten-Kontrolle. Computing 4 (1969), 93-106.
	8	FE~LBERG, E. Low order classical Runge-Kutta formulae with stepsize control and their application to some heat transfer problems. Tech. Rep. R-315, NASA, 1969.
	9	HIGHAM, D. J., AND HALL, G. Runge-Kutta equilibrium theory for a mixed absolute relative error measure. Tech. Rep. TR 218/89, Department of Computer Science, University of Toronto, 1989.
	10	HULL, T. E., ENRIGHT, W. H., A~D JACKSON, K.R. User's guide for DVERK--A subroutine for solving nonstiff ODE's. Tech. Rep. TR 100/76, Department of Computer Scieace, University of Toronto, Canada, 1976.
	11	PraNCE, P. J., AND DORMAND, J. R. High order embedded Runge-Kutta fi)rmulae. J. Comput. Appl. Math. 7 (1981), (;7-76.
	12	SHAMPINE, L. F., AND GORDOn, lVl. K. Computer solution of ordinary differential equations: The initial value problem. W. It. Freeman, San Francisco, 1975, pp. 186-209.
	13	VERNER, J.H. Explicit Runge-Kutta methods with estimates of the local truncation error. SINUM 15 (1978), 772-790.
	14	J. H. Verner, A contrast of some Runge-Kutta formula pairs, SIAM Journal on Numerical Analysis, v.27 n.5, p.1322-1344, Oct. 1990  [doi>10.1137/0727075]

• Data structures for quadtree approximation and compression Communications of the ACM   28, 9
  Hanan Samet
  
  
• A hierarchical single-key-lock access control using the Chinese remainder theorem Proceedings of the 1992 ACM/SIGAPP Symposium on Applied computing
  Kim S. Lee ,  Huizhu Lu ,  D. D. Fisher
  
  
• The GemStone object database management system Communications of the ACM   34, 10
  Paul Butterworth ,  Allen Otis ,  Jacob Stein
  
  
• Putting innovation to work: adoption strategies for multimedia communication systems Communications of the ACM   34, 12
  Ellen Francik ,  Susan Ehrlich Rudman ,  Donna Cooper ,  Stephen Levine
  
  
• An intelligent component database for behavioral synthesis Proceedings of the 27th ACM/IEEE Design Automation Conference on
  Gwo-Dong Chen ,  Daniel D. Gajski