Peter Swerling
From Wikipedia, the free encyclopedia
| Peter Swerling | |
 |
|
| Born | August 15, 1942 New York City, New York |
|---|---|
| Died | August 25, 2000 (aged 71) Pacific Palisades, California |
| Residence | United States |
| Nationality | American |
| Fields | Mathematics |
| Alma mater | University of California, Los Angeles Cornell University California Institute of Technology |
| Doctoral advisor | Angus Taylor |
Peter Swerling (March 4, 1929 – August 25, 2000) was one the most influential RADAR theoretician in the second half of the 20th century. He is best known for the class of statistically "fluctuating target" scattering models he developed at the RAND Corporation in the early 1950s to characterize the performance of pulsed radar systems, referred to as Swerling Target I, II, III, and IV in the literature of RADAR. He also made significant contributions to the optimal estimation orbits and trajectories of of satellites and missiles, later refined by Rudolph Kalman as the Kalman filter.
Contents |
[edit] Biography
[edit] Education
Peter Swerling received a B.S. in Mathematics from the California Institute of Technology in 1947 and a B.A. in Economics from Cornell in 1949. He then attended the University of California, Los Angeles, where he received a M.A. in Mathematics in 1951 and a Ph.D. in Mathematics in 1955. His thesis Families of Transformations in the Function Spaces H^p was advised by Angus Taylor, and investigated families of bounded linear transformations in Banach spaces.
[edit] Entrepreneurship
In 1966, Peter Swerling founded Technology Service Corporation (TSC). TSC currently has nationwide operations with 2007 revenues approaching $63M. In 1983, he co-founded Swerling Manassee and Smith, Inc., of Canoga Park, California, and served as its president and CEO from 1986 until his retirement in 1998.
[edit] Swerling Targets
Swerling Case 0 Also known as Swerling Case V (5), is no fluctuation.
Swerling Case 1 (or i) Represent constant gain within the hit in the scan but varies from scan to scan with no correlation
Swerling Case 2 (or ii) Represent fluctuation from pulse to pulse as well as scan to scan
The PDF for Case 1 and 2 is
PDF{…} = ( 1 / RCS ) * exp( -{0…..} / RCS)
Where: RCS = mean(Sigma values)
Swerling Case 3 (or iii) Swerling Case 3 is the same as Swerling Case 1 but has “a” dominating reflective surface
Swerling Case 4 (or iv) Swerling Case 4 is the same as Swerling Case 2 but has “a” dominating reflective surface
The PDF for Case 1 and 2 is
PDF{…} = ( (4 * {0…..} ) / RCS^2 ) * exp( (-2 * {0…..}) / RCS)
Where: RCS = mean(Sigma values)
Swerling Case 5 (or v) See Swerling case 0
[edit] See also
[edit] External links
- Peter Swerling obituary and biography, SIAM
- Peter Swerling obituary and biography, American Institute of Physics
- Mathematics Genealogy Project profile
 |
This article about a United States engineer, inventor or industrial designer is a stub. You can help Wikipedia by expanding it. |
