Distributed Radar Networks Ray Greenwald JHU/APL
Importance of J, E, P, and H M-I coupling is all about the ionosphere acting as a dynamic boundary condition to magnetospheric processes Magnetospheric electric fields and pressure gradients drive FACs that close in the ionosphere in a self-consistent manner. Ionospheric conductances are variable and often highly time dependent. Seasonal variability Conjugate effects Auroral particle precipitation To understand the coupling process, we need to measure and understand the self consistency of J, E, P, and H
Importance of E E controls the circulation of magnetospheric plasma E affects auroral energization E controls the circulation of ionospheric plasma and affects the evolution of the ionosphere. Large-scale structuring Small-scale plasma instabilities E transfers momentum to the neutral atmosphere and affects global neutral wind patterns. E heats the neutral atmosphere and contributes to plasma outflow to the magnetosphere.
Measurement Techniques and Capabilities Technique Quantity Measured Derived Parameter Coverage Meas./Instr. Mags. Magnetic field Currents 100 km 1 ASI Optical emissions, 800 km Many Fabry-Perot Opt. line shift Neutral wind ???? Several Ionosonde Reflection delay Ne profile km 1 GPS Rx Propagation delay TEC 800 km ~9 HF Radar Irreg. backscatt.(F) Primarily Vd, E 3500 km Many Others
Why Radars are Good Instruments Radars provide you with both range information and angular resolution. Range information is provided by the duration of the transmitted signal. Limited by sensitivity Angular resolution provided by the characteristics of the radar antenna. Limited by cost Radars can operate under all seeing conditions. Radars, particularly obliquely-directed radars have very large fields of view. E-region radar – pie section to ~1200 km F-region radar(direct backscatter) – pie section to ~2000 km HF F-region radar(multihop) – pie section to >3500 km
Importance of Antennas The most important element of a radar system is the antenna. Antennas provide: Spatial resolution through their directivity Sensitivity through their collecting area Spatial coverage through their scanning ability Modern radar systems often use one or two-dimensional arrays of antennas that are phased electronically to steer the radar beam in one or two dimensions. SuperDARN is an example of a one-dimensional phased array that uses horizontally-polarized log-periodic dipole antennas. For optimal performance the design criteria of the individual antennas should be compatible with the design requirements of the full phased array.
An Example Schematic View of SuperDARN Radar 16 antenna main array Power Amps Switches Power Amps Switches Power Amps Switches Power Amps Switches Phasing MatrixControl Signals RF Subsystems Phasing Matrix 4 antenna interferometer array Main Processing Computer Timing Computer Communications Computer Internet ~250 m 100 m
Directive Characteristics of SuperDARN Radars Both antenna arrays are steered into 16 azimuthal beam directions using capacitive delay line phasing matrices. Phase shift between backscattered signals arriving at main and interferometer array used to determine elevation angle of returning signal. Combination of azimuth and elevation angles plus range and Doppler spectra characteristics used to specify the location of scattering region. Azimuthal beam spacing: 3.15° Two-way azimuthal beamwidth: 2.5° - 6° Accuracy of elevation angle determination: ~1°.
SuperDARN Current Northern Hemisphere Radars King Salmon Missing Prince George Missing
SuperDARN – An HF Radar Network Today and Tomorrow Northern Hemisphere Southern Hemisphere
SuperDARN web site at Johns Hopkins Applied Physics Laboratory superdarn.jhuapl.edu
Utilization of SuperDARN Data More than 380 publications have included SuperDARN data since 1993!
Utilization of SuperDARN Data
SuperDARN A Homogeneous Global Facility All SuperDARN radars have the same basic design and use the same radar control software. All radars process the data in the same manner and produce data files with identical formats. All operations are preplanned with 70% of the operations performed in a coordinated manner. Operations are continuous (24X365). Data from the radars are combined onto DVDs and distributed to the entire SuperDARN community. Data from the northern hemisphere radars are collected in near real time to specify the state of the high-latitude convection and high-latitude propagation. Products are available on the Internet. Scientific data analysis utilizes common routines to assure uniformity of the science results.
Summary SuperDARN is a unique international network of HF radars that were developed to understand the large-scale dynamics of the high-latitude ionosphere and magnetosphere. Relatively few sites are required to cover very large spatial areas SuperDARN has been developed and operated by an enthusiastic group of scientists from 10 countries. Other countries are working to become members of SuperDARN. The primary data products from SuperDARN are plasma convection and the ionospheric electric field. Other secondary data products are also important, including gravity waves, planetary waves and mesospheric winds. Since 1993, there have been more than 380 scientific publications that have used SuperDARN data. These publications cover most aspects of high-latitude ionospheric physics and magnetosphere-ionosphere coupling.