Title :
Generalized Coupled-Line All-Pass Phasers
Author :
Gupta, Shulabh ; Qingfeng Zhang ; Lianfeng Zou ; Li Jun Jiang ; Caloz, Christophe
Author_Institution :
Dept. of Electr. Eng., Ecole Polytech. de Montreal, Montreal, QC, Canada
Abstract :
Generalized coupled-line all-pass phasers, based on cascaded C-sections (CCSs), cascaded coupled-lines (CCLs), and hybrid-cascaded (HC) coupled transmission-line sections, are presented and demonstrated using analytical, full-wave, and experimental results. It is shown that for N commensurate coupled-line sections, CCL and HC phasers exhibit N group-delay peaks per coupled-line section harmonic frequency band, in contrast to the CCS configuration, which exhibits only one peak within this band. It is also shown that for a given maximum achievable coupling-coefficient, the HC configuration provides the largest group-delay swing. A wave-interference analysis is finally applied to the various coupled-line phasers, explaining their unique group-delay characteristics based on physical wave-propagation mechanisms.
Keywords :
coupled transmission lines; interference (signal); CCLs; CCS configuration; HC phasers; N commensurate coupled-line sections; N group-delay peaks per coupled-line section harmonic frequency band; cascaded C-sections; generalized coupled-line all-pass phasers; group-delay swing; hybrid-cascaded coupled transmission-line sections; physical wave-propagation mechanisms; wave-interference analysis; Bandwidth; Couplers; Couplings; Delays; Prototypes; Topology; Transfer functions; All-pass networks; C-sections; D-sections; dispersion engineering; group-delay engineering; phasers; radio-analog signal processing (R-ASP);
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
DOI :
10.1109/TMTT.2015.2397445
