Abnormal Group Delay and Detection Latency in the Presence of Noise for Communication Systems

Kayili, Levent

06 April 2010

Although it has been well established that abnormal group delay is a real physical phenomenon and is not in violation of Einstein causality, there has been little investigation into whether or not such abnormal behaviour can be used to reduce signal latency in practical communication systems in the presence of noise. In this thesis, we use time-varying probability of error to determine if abnormal group delay “channels” can offer reduced signal latency. Since the detection system plays a critical role in the analysis, three important detection systems are considered: the correlation, matched filter and envelope detection systems. Our analysis shows that for both spatially negligible microelectronic systems and spatially extended microwave systems, negative group delay “channels” offer reduced signal latency as compared to conventional “channels”. The results presented in the thesis can be used to design a new generation of electronic and microwave interconnects with reduced or eliminated signal latency.

electrical engineering

Einstein causality

causality

communication systems

abnormal group delay

abnormal group velocity

superluminal group delay

superluminal group velocity

time-varying error probability

signal latency

detection system

detection latency

pulse advancement

spatially extended systems

negative group delay

negative group velocity

spatially negligible systems

microwave circuits

microelectronic interconnects

channel

relativistic causality

electromagnetic

dispersion

physics

signals

0544

Abnormal Group Delay and Detection Latency in the Presence of Noise for Communication Systems

Kayili, Levent

06 April 2010

Although it has been well established that abnormal group delay is a real physical phenomenon and is not in violation of Einstein causality, there has been little investigation into whether or not such abnormal behaviour can be used to reduce signal latency in practical communication systems in the presence of noise. In this thesis, we use time-varying probability of error to determine if abnormal group delay “channels” can offer reduced signal latency. Since the detection system plays a critical role in the analysis, three important detection systems are considered: the correlation, matched filter and envelope detection systems. Our analysis shows that for both spatially negligible microelectronic systems and spatially extended microwave systems, negative group delay “channels” offer reduced signal latency as compared to conventional “channels”. The results presented in the thesis can be used to design a new generation of electronic and microwave interconnects with reduced or eliminated signal latency.

electrical engineering

Einstein causality

causality

communication systems

abnormal group delay

abnormal group velocity

superluminal group delay

superluminal group velocity

time-varying error probability

signal latency

detection system

detection latency

pulse advancement

spatially extended systems

negative group delay

negative group velocity

spatially negligible systems

microwave circuits

microelectronic interconnects

channel

relativistic causality

electromagnetic

dispersion

physics

signals

0544