Cross-correlation interference-free tiered polyphase codes for GNSS signal design

• Published in: Electronics letters Vol. 50; no. 3; pp. 218 - 219
• Main Authors: Kim, Jeong-been, Lee, Jewon, Park, Daesoon, Kim, Kap-jin, Song, Ki-won, Lee, Sang-Jeong, Ahn, Jae Min
• Format: Journal Article
• Language: English
• Published: Stevenage The Institution of Engineering and Technology 30.01.2014; Institution of Engineering and Technology; John Wiley & Sons, Inc
• Subjects: amplitude zero auto‐correlation polyphase secondary code; Amplitudes; Applied sciences; Autocorrelation; Coding, codes; cross‐correlation interference‐free tiered polyphase codes; Design engineering; different ranging codes; Exact sciences and technology; Global navigation satellite system; global navigation satellite systems; GNSS; GNSS signal design; Information, signal and communications theory; Interference; primary code; Radiolocalization and radionavigation; ranging signal structure; satellite navigation; Signal and communications theory; Simulation; Telecommunications; Telecommunications and information theory; Wireless communications; different ranging codes; GNSS signal design; ranging signal structure; cross-correlation interference-free tiered polyphase codes; satellite navigation; amplitude zero auto-correlation polyphase secondary code; primary code; global navigation satellite systems; Autocorrelation function; Artificial satellite; Satellite navigation; GPS system; Cross correlation; Phase coding; Autocorrelation; Pulse compression
• ISSN: 0013-5194; 1350-911X; 1350-911X
• DOI: 10.1049/el.2013.2566

A new type of tiered code for designing the ranging signal structure of global navigation satellite systems (GNSSs) is proposed. The proposed tiered code structure combines a constant amplitude zero autocorrelation polyphase secondary code with its primary code, resulting in a tiered polyphase code (TPC) that avoids cross-correlation interference between different ranging codes. The analysis and the simulation results show the performance of the proposed TPC and confirm its effectiveness as a ranging signal structure for the GNSSs.