The Dynamic Spectrum of Interplanetary Scintillation: First Solar Wind Observations on LOFAR

The LOw Frequency ARray (LOFAR) is a next-generation radio telescope which uses thousands of stationary dipoles to observe celestial phenomena. These dipoles are grouped in various ‘stations’ which are centred on the Netherlands with additional ‘stations’ across Europe. The telescope is designed to operate at frequencies from 10 to 240 MHz with very large fractional bandwidths (25 – 100 %). Several ‘beam-formed’ observing modes are now operational and the system is designed to output data with high time and frequency resolution, which are highly configurable. This makes LOFAR eminently suited for dynamic spectrum measurements with applications in solar and planetary physics. In this paper we describe progress in developing automated data analysis routines to compute dynamic spectra from LOFAR time–frequency data, including correction for the antenna response across the radio frequency pass-band and mitigation of terrestrial radio-frequency interference (RFI). We apply these data routines to observations of interplanetary scintillation (IPS), commonly used to infer solar wind velocity and density information, and present initial science results.

[1]  R. A. Jones,et al.  Dual‐frequency interplanetary scintillation observations of the solar wind , 2006 .

[2]  Bernard V. Jackson,et al.  Heliospheric tomography using interplanetary scintillation observations: 2. Latitude and heliocentric distance dependence of solar wind structure at 0.1–1 AU , 1998 .

[3]  Bernard V. Jackson,et al.  Heliospheric tomography using interplanetary scintillation observations , 1997 .

[4]  A. Hewish,et al.  Interplanetary Scintillation of Small Diameter Radio Sources , 1964, Nature.

[5]  J. P. Filice,et al.  Dynamic spectra of interplanetary scintillations , 1984, Nature.

[6]  A. Buffington,et al.  Inclusion of In-Situ Velocity Measurements into the UCSD Time-Dependent Tomography to Constrain and Better-Forecast Remote-Sensing Observations , 2010 .

[7]  Christine Jordan,et al.  Extremely long baseline interplanetary scintillation measurements of solar wind velocity , 2006 .

[8]  W. Coles Interplanetary scintillation , 1978 .

[9]  A. Noutsos,et al.  Observing pulsars and fast transients with LOFAR , 2011, 1104.1577.

[10]  Mario M. Bisi,et al.  Large-scale structure of the fast solar wind , 2007 .

[11]  Ronald Nijboer,et al.  The LOFAR Telescope: System Architecture and Signal Processing , 2009, Proceedings of the IEEE.

[12]  W. A. Coles,et al.  A bimodal model of the solar wind speed , 1996 .

[13]  R. Fallows,et al.  Developments in the use of EISCAT for interplanetary scintillation , 2008 .

[14]  W. A. Coles,et al.  Analysis of three-station interplanetary scintillation , 1972 .

[15]  H. R. Middleton,et al.  The Solar Eruption of 2005 May 13 and Its Effects: Long-Baseline Interplanetary Scintillation Observations of the Earth-Directed Coronal Mass Ejection , 2008 .

[16]  Spectra of interplanetary scintillation , 1980, Nature.

[17]  Louise K. Harra,et al.  Coronal Mass Ejection , 2007 .

[18]  A. Hewish,et al.  The Solar Wind outside the Plane of the Ecliptic , 1967, Nature.

[19]  B. Jackson,et al.  Heliospheric tomography using interplanetary scintillation observations. 1. Combined Nagoya and Cambridge data , 1998 .