Title :
Shaping the Power Spectrum of Ultra-Wideband Radio-Frequency Signals
Author :
McKinney, Jason D. ; Lin, Ingrid S. ; Weiner, Andrew M.
Author_Institution :
Naval Res. Lab., Washington, DC
Abstract :
We demonstrate the ability to tailor the power spectrum of ultra-wideband (UWB) RF waveforms via a photonics-based electromagnetic pulse shaper. We describe and experimentally demonstrate a waveform design methodology that allows us to achieve desirable power spectrum properties, such as broad bandwidth and minimal spectral ripple. As one example, we generate a 115% fractional-bandwidth impulsive waveform which spans the 3-10-GHz band, with ripple below plusmn1.5 dB over a 5-GHz band. Furthermore, by treating the RF spectral phase as a design parameter, we demonstrate how to achieve increased power spectral density. We illustrate the spectral design capabilities of our technique by presenting a variety of tailored UWB waveforms (including impulses, chirped signals, and arbitrary waveforms) with bandwidths that range from ~4 to 8 GHz
Keywords :
electromagnetic pulse; pulse generators; pulse shaping; ultra wideband technology; waveform generators; 3 to 10 GHz; RF spectral phase; UWB RF waveforms; UWB waveforms; arbitrary waveforms; chirped signals; fractional-bandwidth impulsive waveform; photonics-based electromagnetic pulse shaper; power spectral density; power spectrum properties; ultra-wideband radio-frequency signals; waveform design methodology; Bandwidth; Chirp; Design methodology; EMP radiation effects; Photonics; RF signals; Radio frequency; Signal generators; Spectral shape; Ultra wideband technology; RF photonics; spectral engineering; ultra-wideband (UWB) signal generation;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2006.885573
