ABSTRACT
Medium-Range Forecast Errors Associated with Active Episodes of the
Madden-Julian Oscillation
Harry Hendon
Brant
Liebmann
Mathew Newman
John D. Glick
NOAA-CIRES Climate Diagnostics Center, Boulder, Colorado
Jae-Kyung E. Schemm
Climate Prediction Center, NCEP/NWS/NOAA
(Manuscript received 24 July 1998, in final form 21 December 1998)
Abstract
Systematic forecast errors associated with active episodes of the
tropical Madden-Julian oscillation (MJO) are examined using five
winters of dynamical extended range forecasts from the National Centers
for Environmental Prediction reanalysis model. Active episodes of the
MJO are identified as those periods when the amplitude of either of the
first two empirical orthogonal functions of intraseasonally filtered
outgoing longwave radiation, which efficiently capture the MJO, is
large. Forecasts initialized during active episodes of the MJO are
found not to capture the eastward propagation of the tropical
precipitation and circulation anomalies associated with the
MJO. Rather, the MJO-induced anomalies of precipitation and winds are
systematically forecast to weaken and even retrograde. By about day 7
of the forecast the convectively coupled, tropical circulation
anomalies produced by the MJO are largely gone. Systematic errors in
the extratropical 200-mb streamfunction also fully develop by day
10. The initial development of these errors is argued to result from
the collapse of the tropical divergence forcing produced by the MJO
and, thus, the lack of correct Rossby wave source. Forecast skill in
the Tropics and the Northern Hemisphere extretropics is found to be
systematically reduced during active periods of the MJO as compared to
quiescent times. This reduced skill is suggested to result because the
MJO is the dominant mode of convective variability and not because the
model is better able to forecast intraseasonal convection unrelated to
the MJO.