Abstract
This paper introduces an innovative passive topology of bandpass (BP) negative group delay (NGD) electrical circuit implemented with symmetric H-tree network. The multi-port topology of BP NGD circuit is originally represented by a resistorless H-tree constituted by lumped LC-passive network. Until now, the NGD electronic circuits available in the literature are implemented by two-port circuits which are using either resistive elements or distributed microstrip topologies. In the present investigation, the feasibility of the modelling, design, fabrication and test of unfamiliar BP NGD original H-tree circuits. The main objective of the study is to identify analytically the existence of the BP NGD function with the resistorless H-tree circuit. Because of its simplicity and the analytical equation compactness, the uncommon approach of tensorial analysis of networks (TAN) is used in the paper. After the branch and mesh analyses, the impedance matrix of the resistorless H-tree is elaborated. Hence, the resistorless H-tree equivalent S-matrix is established by means of impedance to scattering matrix transform. The BP NGD analysis in function of the inductance and capacitance parameters constituting the H-tree circuit is presented. Then, the main steps of the BP NGD investigation are described. The existence of BP NGD behavior in function of the adequate transmission parameters is identified by the consideration of the canonical form. To validate the BP NGD behavior, a proof of concept (POC) of LC-network based resistorless and symmetrical tree prototype is designed, fabricated and measured. Comparison results between well-correlated TAN calculation, simulation and experimentation are discussed.
Highlights
The group delay (GD) effect is susceptible to penalize the communication delay system in addition to the noise effect [1]
ON THE BP negative GD (NGD) VALIDATION RESULTS By using the modelled, simulated and fabricated proof of concept (POC) prototype, we studied the results of the tests
The comparative plots of simulated, measured and calculated GDs displayed in Fig. 10 confirm the observation of the BP NGD aspect
Summary
The group delay (GD) effect is susceptible to penalize the communication delay system in addition to the noise effect [1]. This particular parameter can play an important role for the enhancement of signal processing [2]. Unfamiliar function related to the GD attracted the attention of electronic circuit and system engineers when it presents a negative sign [3]–[17]. Thanks to the negative GD (NGD) function, an equalization and compensation of GD and signal delay were introduced [3]–[4]. The NGD function remains one of the most unfamiliar electronic function for the research design engineers.
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