Abstract
Solar Cycle 24 has almost faded and the activity of Solar Cycle 25 is appearing. We have learned much about predicting solar activity in Solar Cycle 24, especially with the data provided by SDO and STEREO. Many advances have come in the short-term predictions of solar flares and coronal mass ejections, which have benefited from applying machine learning techniques to the new data. The arrival times of coronal mass ejections is a mid-range prediction whose accuracy has been improving, mostly due to a steady flow of data from SoHO, STEREO, and SDO. Longer term (greater than a year) predictions of solar activity have benefited from helioseismic studies of the plasma flows in the Sun. While these studies have complicated the dynamo models by introducing more complex internal flow patterns, the models should become more robust with the added information. But predictions made long before a sunspot cycle begins still rely on precursors. The success of some categories of the predictions of Solar Cycle 24 will be examined. The predictions in successful categories should be emphasized in future work. The SODA polar field precursor method, which has accurately predicted the last three cycles, is shown for Solar Cycle 25. Shape functions for the sunspot number and F10.7 are presented. What type of data is needed to better understand the polar regions of the Sun, the source of the most accurate precursor of long-term solar activity, will be discussed.
Highlights
Space Weather is driven by the periodic variation of the magnetic field at and above the solar surface
Once the magnetic field has erupted through the surface it can become organized into active regions
The magnetic field in and above these active regions will eventually be destroyed by either being converted into radiation and energetic particles by solar flares or by being ejected from the Sun in coronal mass ejections
Summary
Space Weather is driven by the periodic variation of the magnetic field at and above the solar surface. The predictions are needed to anticipate the space weather effects on space missions that can last two 11-year sunspot cycles These predictions test our understanding of the solar dynamo and the models used to understand the cause of flares and coronal mass ejections. Solar Cycle 24 may have had fewer sunspots than average but large events, such as the fast coronal mass ejection (CME) of 23 Jul 2012 (Russell et al, 2013) have still happened Another unusual occurrence was active region 12,192, which formed in October 2014 as the largest active region since November 1990, reaching a peak area of 3300 l-hems during its disk passage between 17 and 30 Oct 2014. What did we learn from Solar Cycle and how will that guide us into Solar Cycle
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
