Extended Radar Return from a Rocket Engine: A Thermal Model

Abstract

Cavities generate delayed radar returns. But because the standard scattering models are overwhelmed by the complexity of the problem, no predictive physical model of cavity scattering has been available to describe what is observed. The delayed return is caused by the slow disgorgement of the radar energy captured by the cavity. For some cavities, and especially for the liquid-fueled rocket engine, the length of the extended return is many times the maximum dimension of the cavity. Since this implies that the radar energy undergoes a great many internal reflections before it reemerges, it suggests treating the captured energy within the cavity as a well-mixed thermal radiation field. This suggestion leads to a simple scattering model for the well-mixed lossless thermal cavity and to a straightforward extension to accommodate the nozzle on the engine. The model gives, independently of both polarization and frequency, the formula sigma = 2AF(theta), F(theta)costheta(i), costheta(s) for the narrowband bistatic RCS of the rocket-engine's extended signature, where theta(i) and theta(s) are, respectively, the angles between the engine axis and the lines of sight to the transmitting and receiving radars, A is the area of the nozzle throat, and F(theta) is the nozzle gain factor. For a cavity with no nozzle, F(theta) = 1. The concept also produces a somewhat longer formula defining the wideband extended radar signature. It predicts, independently of incidence or scattering angles, polarization or frequency, a decay rate of 2.1 7/L dB/m. (L* is the characteristic chamber length defined in rocket engineering as the ratio of the chamber volume to the throat area.) A second component of the scattered energy, the nonextended return, is the energy reflected by the nozzle without entering the combustion chamber. Added noncoherently to the energy disgorged by the combustion chamber, it gives the total signature.

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Document Details

Document Type
Technical Report
Publication Date
Dec 18, 2008
Accession Number
ADA492443

Entities

People

  • M.l. Burrows

Organizations

  • Massachusetts Institute of Technology

Tags

Communities of Interest

  • Air Platforms
  • Energy and Power Technologies

DTIC Thesaurus Topics

  • Abstracts
  • Aspect Angle
  • Backscattering
  • Chambers
  • Combustion
  • Combustion Chambers
  • Conical Nozzles
  • Electromagnetic Scattering
  • Engineering
  • Flux Density
  • Frequency
  • Geometry
  • Radar Cross Sections
  • Radar Signatures
  • Ray Tracing
  • Rocket Engines
  • Scattering

Fields of Study

  • Physics

Readers

  • Combustion and Flow Dynamics.
  • Marine Propulsion Engineering and Naval Architecture
  • Radar Systems Engineering.