TY - JOUR
T1 - A comparison of high-order explicit Runge–Kutta, extrapolation, and deferred correction methods in serial and parallel
AU - Ketcheson, David I.
AU - Waheed, Umair bin
N1 - KAUST Repository Item: Exported on 2020-10-01
PY - 2014/6/13
Y1 - 2014/6/13
N2 - We compare the three main types of high-order one-step initial value solvers:
extrapolation, spectral deferred correction, and embedded Runge–Kutta pairs.
We consider orders four through twelve, including both serial and parallel implementations.
We cast extrapolation and deferred correction methods as fixed-order
Runge–Kutta methods, providing a natural framework for the comparison. The
stability and accuracy properties of the methods are analyzed by theoretical
measures, and these are compared with the results of numerical tests. In serial,
the eighth-order pair of Prince and Dormand (DOP8) is most efficient. But
other high-order methods can be more efficient than DOP8 when implemented in
parallel. This is demonstrated by comparing a parallelized version of the wellknown
ODEX code with the (serial) DOP853 code. For an N-body problem with
N = 400, the experimental extrapolation code is as fast as the tuned Runge–Kutta
pair at loose tolerances, and is up to two times as fast at tight tolerances.
AB - We compare the three main types of high-order one-step initial value solvers:
extrapolation, spectral deferred correction, and embedded Runge–Kutta pairs.
We consider orders four through twelve, including both serial and parallel implementations.
We cast extrapolation and deferred correction methods as fixed-order
Runge–Kutta methods, providing a natural framework for the comparison. The
stability and accuracy properties of the methods are analyzed by theoretical
measures, and these are compared with the results of numerical tests. In serial,
the eighth-order pair of Prince and Dormand (DOP8) is most efficient. But
other high-order methods can be more efficient than DOP8 when implemented in
parallel. This is demonstrated by comparing a parallelized version of the wellknown
ODEX code with the (serial) DOP853 code. For an N-body problem with
N = 400, the experimental extrapolation code is as fast as the tuned Runge–Kutta
pair at loose tolerances, and is up to two times as fast at tight tolerances.
UR - http://hdl.handle.net/10754/333641
UR - http://msp.org/camcos/2014/9-2/p01.xhtml
UR - http://www.scopus.com/inward/record.url?scp=84911451795&partnerID=8YFLogxK
U2 - 10.2140/camcos.2014.9.175
DO - 10.2140/camcos.2014.9.175
M3 - Article
SN - 2157-5452
VL - 9
SP - 175
EP - 200
JO - Communications in Applied Mathematics and Computational Science
JF - Communications in Applied Mathematics and Computational Science
IS - 2
ER -