J. W. Brosnahan scite author profile

We have made measurements in the 60–100 km region using a 2.66‐MHz radar operated as an imaging Doppler interferometer. This allows us to view the entire region within 24° of zenith simultaneously, Doppler‐sorting and then echo‐locating the returns to achieve image resolution of ±3° in zenith angle and ±5 m/s in velocity. The approach is contrasted with conventional beam‐forming radar methods. We assume that the phenomena responsible for the observed weak radar scattering can be described as a distribution of discrete scattering points. Each scattering point is then characterized by its three spatial coordinates, its radial velocity, and the amplitudes and phases of its spectral components measured on a number of independent antennas. We present a series of apparent‐motion profiles from 61 to 87 km, showing the repeatability of the profiles and their evolution in time, followed by a two‐dimensional image of the scattering surface at 85 km, showing the motions of the individual scattering points and their distribution in space. Then we show images of the scattering surfaces from altitudes of 58 to 103 km, every 9 km, showing at each altitude the distribution in the horizontal plane of the locations of the scattering points, the specularity, or aspect sensitivity, of the scattering, and the derived apparent‐motion vectors. A sequence of eight 51‐s frames shows highly structured activity at 103 km.

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Interferometric directions of lightning sources at 34 MHz

Warwick¹,

Hayenga²,

Brosnahan³

1979

J. Geophys. Res.

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We present a new technique for measuring the VHF radio centroid of nearby lightning flashes at 5‐μs intervals. Its ability to provide continuous positions during long ( true>˜ 100 μs) emissions is, we believe, new and reveals new information about the discharge process. The new technique solves many of the data‐handling problems in old techniques. We have built and demonstrated this technique in one angular coordinate of the lightning flash. We present data from five flashes showing complex positional and motional patterns. The breakdown phase consists of many impulses. The average speed from impulse to impulse lies in the range of 10–100 km s−1. During individual impulses, speeds measure from one to several tens of thousands of kilometers per second. At times of strong VLF bursts there is usually a similar VHF burst. Its speed is like the speeds of individual impulses. We identify VLF‐associated VHF burst sources with the main electrical current flow in lightning flashes. We identify the motion from one impulse to another in the breakdown phase as being caused by avalanching electrons accelerating along paths soon to become the discharge paths within thunderclouds. The high speeds in impulses represent the gross current flow in breakdown channels not yet large enough to create large VLF emissions or flashes.

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Imaging Doppler interferometry and the measurement of atmospheric turbulence

Roper¹,

Brosnahan²

1997

Radio Science

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The imaging Doppler interferometer: Data analysis

Adams¹,

Edwards²,

Brosnahan³

1985

Radio Science

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J. W. Brosnahan

Multi-instrument observations of mesospheric motions over Arecibo: comparisons and interpretations

Mesospheric observations using a 2.66‐MHz radar as an imaging Doppler interferometer: Description and first results

Interferometric directions of lightning sources at 34 MHz

Imaging Doppler interferometry and the measurement of atmospheric turbulence

The imaging Doppler interferometer: Data analysis

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