![Sample our Engineering & Technology journals, sign in here to start your access, latest two full volumes FREE to you for 14 days]({"type":"image" , "src" : "/sda/5933/TOC-Subject-Sample-2021-Engineering-Tech.jpg"})
Abstract
A computer model (SUNRAY-3D) for the 2.5-dimensional multi-signal large-signal analysis of helix TWTs has been developed based on the approach developed earlier by the author for the one-dimensional large-signal modelling of helix and coupled-cavity TWTs. Some of the features of O'Malley's work for three-dimensional modelling of coupled-cavity TWTs were incorporated successfully for the modelling of helix TWTs. The present model is capable for the analysis of multiple input signals together with their higher order harmonics and inter-modulation products. The expressions for the circuit field and the induced current at a plane were derived from the electric field in a helical slow-wave structure instead of using the conventional equivalent circuit approach. The program analyses TWTs with arbitrary variations in the helix pitch and rf loss (including sever and tip loss) along the slow-wave structure. Induced backward voltage components and reflected voltage components due to mismatches at the terminations of the helix were included. The program has been shown to be accurate and self-consistent for drive powers from 60dB below saturation to well above saturation. The energy balance factor is satisfied to better than ±0.1% even at and above saturation. The CPU time to compute the performance of a typical TWT for a single drive power with 96 rings and 16 steps per wavelength is less than one minute on a DEC-ALPHA computer and is much less than 20 seconds on an IBM-P-IV.
Indexing terms:
Additional information
Notes on contributors
Vishnu Srivastava
Vishnu Srivastava Scientist F, received his PhD degree in Engineering in 1987 from the University of Lancaster, UK under Commonwealth fellowship plan. He is working at CEERI, Pilani as a scientist since 1976. He was a visiting fellow during 1991 and during 1997 at the University of Lancaster, UK. He was associated with the design and development of X-band 200kW coaxial magnetron and S-band 30W helix TWT. He developed both small-signal and large signal models for helix TWTs and coupled-cavity TWTs. One of the software packages developed by him was exported to UK. He has more than 70 research publications in different proceedings of the national and international conferences and journals. He received JC Bose memorial award of IETE for the best paper in engineering in 1992. Presently, he is associated with the design and development of C-band 60W space TWT, Ku-band 140 W space TWT and C-band 70 kW coupled-cavity TWT. He is chief investigator of space TWT projects and of another project on developing technology for graphite mutli-stage depressed collector under CSIR network programme.