An integrated Ku-band nanosecond time-stretching system using improved dispersive delay line (DDL)

Avignon-Meseldzija

et al. 2020

Circuit Theory & Apps

This article describes the design of integrated linear group delay filters for analog signal processing (ASP) applications and their implementation through constant-resistance lattice and bridged-T networks. Unlike previously published works, our design method uses a recursive procedure as the basis for the synthesis of a suitable transfer function. Thanks to this method, filters with a more linear group delay characteristic and flat magnitude response can be obtained.Two filters are designed in a 0.13-μm BiCMOS technology to demonstrate the method: a balanced lattice with a negative slope and an unbalanced bridged-T of positive slope. KEYWORDS all-pass filter, bridged-T network, lattice network, linear group delay, time-bandwidth product Int J Circ Theor Appl. 2020;48:658-673. wileyonlinelibrary.com/journal/cta

Section: Bridged-t Prototype Scaled Bridged-t Networkmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Design of integrated all‐pass filters with linear group delay for analog signal processing applications

Avignon-Meseldzija

et al. 2020

Circuit Theory & Apps

2013 IEEE MTT-S International Microwave Symposium Digest (MTT)

“…orm a proof-of-concept real on the RZ pulse streams o point out that the IDDL e-bandwidth product (TBP) estimation of the spectrum onstration. The operation of 1,12]. The proposed IDDL gher frequency with larger d the availability of high DDL has the potential of RTSA with fine resolution.…”

Section: Experimental Demonstration Omentioning

confidence: 99%

On-chip demonstration of real time spectrum analysis (RTSA) using integrated dispersive delay line (IDDL)

Xiang

Wang

Apsel

2013

Self Cite

This paper reports the first on-chip demonstration of GHz range real time spectrum analysis (RTSA) using an integrated dispersive delay line (IDDL). The IDDL is implemented in a standard 0.13 µm CMOS process and can operate from 0.4 GHz to 4 GHz with 1.2 ns dispersion. The IDDL provides a frequency-to-time mapping which can be utilized to generate a time domain representation of the frequency components. We demonstrate that the IDDL is capable of real time spectrum analysis of signals within the frequency range of 0.4 GHz to 4 GHz.

“…Apart from spectral analysis, other ASP applications that require dispersive devices are time‐stretching 7 to potentially release the constraints on digitization, or time‐reversal mirror (TRM) for ultra‐wideband communication 8 or compressive receiver 9 . All these applications need linear group delay (LGD) devices that have been designed through very different kind of technology: with optical processes, 8 surface acoustic wave (SAW) filters, 6 and microstrip C‐section structures 10 …”

Section: Introductionmentioning

confidence: 99%

A linear group delay filter with tunable positive slope for analog signal processing

Avignon-Meseldzija

Anastasov

Milić

2021

Circuit Theory & Apps

Summary This article describes the design of a tunable positive slope linear group delay filter dedicated to analog signal processing applications. The designed filter is composed of eight second‐order all‐pass cells which have been optimized to obtain a highly linear global group delay characteristic over a specified bandwidth for a specified dispersion. Each of these second‐order cells is designed with a dedicated Gm‐C topology to fit the ideal group delay characteristic with a high efficiency. Based on the sensitivity analysis of the topology, the possibility of tuning the group delay slope is highlighted. The design has been achieved with the ST CMOS 55 nm technology and has a maximum bandwidth of 2.5 GHz, a maximum reachable delay of 5.12 ns, and a group delay maximum variation of 2.5 ns. The positive slope of the group delay can be tuned in the range from 1.48 ns/GHz up to 2.03 ns/GHz. The concept of slope tunability is validated through post‐layout statistical analysis.