Joint circuit and waveform optimization for next-generation radar.

Latham, Casey, 1993-

Sangam Home
→
Institutional Repositories
→
Baylor Electronically Accessible Research Documents (BEAR docs) - Baylor University
→
View Item

dc.contributor	Baylis, Charles Passant, 1979-
dc.creator	Latham, Casey, 1993-
dc.date	2018-05-30T13:08:12Z
dc.date	2018-05-30T13:08:12Z
dc.date	2018-05
dc.date	2018-04-17
dc.date	May 2018
dc.date	2018-05-30T13:08:12Z
dc.date.accessioned	2022-05-18T12:12:37Z
dc.date.available	2022-05-18T12:12:37Z
dc.identifier	http://hdl.handle.net/2104/10345
dc.identifier.uri	http://localhost:8080/xmlui/handle/CUHPOERS/29530
dc.description	Due to congested wireless radio spectrum, next-generation radar transmitters will need to be adaptive and reconfigurable in real time to share spectrum with wireless communication devices. Typical system optimization methods rely on separate optimization of the circuit and waveform, which can lead to an over-emphasis on one criteria. While the end result may be acceptable, the intermediate results may not be desirable for a real-time situation. In this thesis, a joint circuit and waveform optimization technique is demonstrated that is designed for use in a real-time reconfigurable radar transmitter. Measurement results are presented to show how joint circuit and waveform optimization allows for better intermediate results that allow real-time optimization to be utilized.
dc.format	application/pdf
dc.format	application/pdf
dc.format	application/pdf
dc.rights	Worldwide access.
dc.rights	Access changed 7/31/20.
dc.subject	Next-generation radar. Dynamic spectrum access. Joint optimization. Circuit optimization. Waveform optimization.
dc.title	Joint circuit and waveform optimization for next-generation radar.
dc.type	Thesis
dc.type	text