Wireless-Coupled Oscillator Systems With an Injection-Locking Signal

Pontón, Mabel; Herrera, A.; Suárez, Almudena

doi:10.1109/tmtt.2018.2884412

Cited by 7 publications

(10 citation statements)

References 48 publications

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“…As in the single-frequency VCO of [15], two transistor devices are connected to two of the resonator ports. Our goal has been to obtain a demonstrator independent resonance modes at the incommensurate frequencies f1 = 2.4 GHz and f2 = 4.1 GHz; these values enable a comparison of the phase-noise spectral density with previous singlefrequency realizations [32]- [33] using similar components. The resonator design departs from the structure sketched in Fig.…”

Section: A Circuit Topologymentioning

confidence: 99%

Double Functionality Concurrent Dual-Band Self-Oscillating Mixer

Pontón

Herrera

Suárez

2021

IEEE Trans. Microwave Theory Techn.

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A concurrent dual-band self-oscillating mixer (SOM), based on a ring-shaped stepped-impedance resonator, is proposed and analyzed in detail. Taking advantage of the ring even and odd resonances, the circuit can operate in concurrent dual quasi-periodic mode and injection-locked mode. In the second case, it behaves as a dual-band zero-IF mixer. Initially an analytical study of the SOM behaviour in the two modes is presented. Then a variety of accurate numerical methods are used for an in-depth investigation of the main aspects of its performance, including stability, conversion gain, linearity, and phase noise. The recently proposed contour-intersection technique and the outer-tier perturbation analysis are suitably adapted to the SOM case. A method is also presented to distinguish the parameter intervals leading to heterodyne and to zero-IF operation at both the lower and upper frequency bands. In the zero-IF SOM, the possible instantaneous unlocking in the presence of modulated input signals is investigated and avoided. The methods have been applied to a dual mixer at the frequencies 2.4 GHz and 4.1 GHz.

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Section: A Circuit Topologymentioning

confidence: 99%

Double Functionality Concurrent Dual-Band Self-Oscillating Mixer

Pontón

Herrera

Suárez

2021

IEEE Trans. Microwave Theory Techn.

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“…This section presents a semi-analytical formulation of this interaction, compatible with the use of commercial HB. In this formulation [24], [25], [36], the oscillator is represented with a realistic numerical model, extracted from HB and introduced into an analytical description of the complete system. This has two advantages: it avoids the convergence problems often encountered in HB and provides insight into the dependence of the oscillator solution on the external elements and parameters.…”

Section: Semi-analytical Formulations For Oscillator-based Systemsmentioning

confidence: 99%

“…However, this operation mode often gives rise to multi-valued solutions, virtually impossible to simulate in commercial HB. To cope with this problem, semi-analytical formulations have been introduced [24], [25], [36], which make use of a realistic numerical model of the standalone oscillator, extracted from HB, that is combined with an analytical description of the selfinjection loop. Here a new procedure to determine the stability properties considering the time delay of the signal envelope is presented for the first time.…”

Section: Introductionmentioning

confidence: 99%

Stability and Oscillation Analysis at Circuit Level and Through Semi-Analytical Formulations

et al. 2021

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Harmonic balance provides steady-state solutions only and has significant shortcomings when addressing oscillatory regimes. As a result, complementary methodologies are required both to ensure the stability of the solution obtained and to design/simulate oscillator circuits. The complexity of the stability analysis increases with the number of active elements and the intricacy of the topology, so there can be uncertainties in the case of complex structures. On the other hand, as recently demonstrated oscillators enable a compact and low-cost implementation of RFID readers and radar systems, which comes at the expense of a more complex performance, very difficult/impossible to simulate with commercial HB. This work presents a review of recent advances on stability and oscillation analysis at circuit level and through semi-analytical formulations. At circuit level, a method for the stability analysis of complex microwave systems is presented, based on the calculation of the characteristic determinant, extracted from the commercial simulator through a judicious partition of the system into simpler blocks. This determinant will be used for the first time to obtain the stability boundaries through a contour-intersection method, able to provide multivalued and disconnected curves. At a semi-analytical level, a realistic numerical model of the standalone oscillator, extracted from HB simulations, is introduced in an analytical formulation that describes the oscillator interaction with other elements. Here it will be applied to a self-injection locked radar, in which the oscillator is injected by its own signal after this signal undergoes propagation and reflection effects. A procedure to determine the stability properties considering the time delay of the signal envelope is presented for the first time. Using the same self-injection concept, a new stabilization method to reduce the phase-noise of an existing oscillator with minimum impact on its original frequency is described.

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“…C OUPLED oscillator systems can be used in several applications like power combination, beam-steering in phased-arrays [1]- [7] or in sensor applications [8]- [10], where the synchronization between the oscillators provides a common time-scale between the nodes of the sensor network. In previous works [11], [12] a semi-analytical formulation (SAF) has been proposed to analyze the behavior of coupled oscillator systems.…”

Section: Introductionmentioning

confidence: 99%

“…The resulting SAF can be used to model the steady state behavior of the VCO for tuning voltage values in the neighborhood of η 0 . The SAF has been proven to be a powerful technique to model the VCO behavior when operating under free-running conditions [14], synchronized to an external source [12], [14]- [16] or as a part of an array of coupled oscillators, operating both in phased array antenna systems [11]- [13] and in wireless sensor networks [8]- [10]. In the case of coupled oscillators, the SAF is able to predict the coexisting solutions of the array, together with their bifurcation loci.…”

Section: Introductionmentioning

confidence: 99%

Piecewise Semi-Analytical Formulation for the Analysis of Coupled-Oscillator Systems

Umpierrez

Arana

Sancho

2019

IEEE Trans. Microwave Theory Techn.

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A new simulation technique to obtain the synchronized steady-state solutions existing in coupled oscillator systems is presented. The technique departs from a semianalytical formulation presented in previous works. It extends the model of the admittance function describing each individual oscillator to a piecewise linear one. This provides a global formulation of the coupled system, considering the whole characteristic of each voltage-controlled oscillator (VCO) in the array. In comparison with the previous local formulation, the new formulation significantly improves the accuracy in the prediction of the system synchronization ranges. The technique has been tested by comparison with computationally demanding circuitlevel Harmonic Balance simulations in an array of Van der Pol-type oscillators and then applied to a coupled system of FET based oscillators at 5 GHz, with very good agreement with measurements.

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Wireless-Coupled Oscillator Systems With an Injection-Locking Signal

Cited by 7 publications

References 48 publications

Double Functionality Concurrent Dual-Band Self-Oscillating Mixer

Double Functionality Concurrent Dual-Band Self-Oscillating Mixer

Stability and Oscillation Analysis at Circuit Level and Through Semi-Analytical Formulations

Piecewise Semi-Analytical Formulation for the Analysis of Coupled-Oscillator Systems

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