ICEBEAR: An All‐Digital Bistatic Coded Continuous Wave Radar for Studies of the E Region of the Ionosphere
Permanent lenke
https://hdl.handle.net/10037/15643Dato
2019-04-15Type
Journal articlePeer reviewed
Forfatter
Huyghebaert, Devin; Hussey, Glenn; Vierinen, Juha; McWilliams, Kathryn; St‐Maurice, Jean-PierreSammendrag
The Ionospheric Continuous-wave E region Bistatic Experimental Auroral Radar (ICEBEAR)
is a coherent scatter ionospheric radar. It operates at a frequency of 49.5 MHz, which is ideal for observing
E region coherent echoes. The radar is located in Saskatchewan, Canada, and is operated by the University
of Saskatchewan. The ICEBEAR system uses a continuous-wave (CW) signal and requires isolation
between the receiving and transmitting arrays. This was accomplished through a bistatic setup, where the
receiver and transmitter are ≈240 km apart. Currently, the ICEBEAR system implements a pseudo random
noise phase modulation on this CW signal to obtain 3-km range resolution and 5-s integration time images
of E region ionospheric irregularities over a 600 km × 600 km field of view. The center of the field of view is
located at ≈58◦N, 106◦W. The radar design allows for future improvements to temporal and/or spatial
resolutions. Each site consists of a linear phased array with 10 equally spaced antennas. This, combined
with modern digital radio hardware, provides azimuthal angle of arrival measurements at the receiving
array and azimuthal transmission control at the transmitting array. This publication describes the radio
hardware and signal processing used by the ICEBEAR radar and emphasizes the unique capabilities of the
radar. First ICEBEAR observations from a Kp ≥ 4 event on 10 March 2018, are presented and shown to
produce simultaneously the four types of previously characterized E region coherent scatter echoes.
Beskrivelse
Published version, available after 6 months embargo.
Publisher's version available at: https://doi.org/10.1029/2018RS006747
Publisher's version available at: https://doi.org/10.1029/2018RS006747