Transpose Return Relation Method for Designing Low Noise Oscillators

Jiménez-Martín, José Luis; González-Posadas, V.; Parra-Cerrada, Ángel; Blanco-del-Campo, A.; Segovia-Vargas, D.

doi:10.2528/pier12022305

Cited by 8 publications

(5 citation statements)

References 25 publications

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“…In our opinion, the NDF is a modern version of the return ratio (RR). Furthermore, it has successfully been used to design oscillators [13,14], showing its agreement with Bode's RR. However, the NDF criterion is difficult to apply and requires that the software be prepared for its use.…”

Section: Introductionmentioning

confidence: 69%

“…In Table 1, V D is the drain bias voltage; f lower − f upper are the lower ( f lower ) and upper ( f upper ) cutoff frequencies of the bandwidth (BW (13)), respectively; f o is the center frequency (14); ∆ f o is the percentage bandwidth (15); P out is the output power; PAE is the power-added efficiency; CW stands for continuous wave; NA stands for not applicable; and Time/Duty is the pulse width of the modulating or pulsed signal with respect to one duty cycle. BW = f upper − f lower (13) f o = f upper + f lower 2 ( 14)…”

Section: Discussionmentioning

confidence: 99%

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Stability, Mounting, and Measurement Considerations for High-Power GaN MMIC Amplifiers

González-Posadas,

Jiménez-Martín,

Parra-Cerrada

et al. 2023

Sensors

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In this paper, the precise design of a high-power amplifier (HPA) is shown, along with the problems associated with the stability of “on-wafer” measurements. Here, techniques to predict possible oscillations are discussed to ensure the stability of a monolithic microwave-integrated circuit (MMIC). In addition, a deep reflection is made on the instabilities that occur when measuring both on wafer and using a mounted chip. Stability techniques are used as tools to characterize measurement results. Both a precise design and instabilities are shown through the design of a three-stage X-band HPA in gallium nitride (GaN) from the WIN Semiconductors Corp. foundry. As a result, satisfactory performance was obtained, achieving a maximum output power equal to 42 dBm and power-added efficiency of 32% at a 20 V drain bias. In addition to identifying critical points in the design or measurement of the HPA, this research shows that the stability of the amplifier can be verified through a simple analysis and that instabilities are often linked to errors in the measurement process or in the characterization of the measurement process.

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Section: Introductionmentioning

confidence: 69%

Section: Discussionmentioning

confidence: 99%

Stability, Mounting, and Measurement Considerations for High-Power GaN MMIC Amplifiers

González-Posadas,

Jiménez-Martín,

Parra-Cerrada

et al. 2023

Sensors

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“…Other useful characteristics of the NDF are that it can predict the oscillation frequency without transistor compression (g m ) for Kurokawa's first harmonic approximation; and that it is suitable for the calculus of the Q L of the circuit because it is directly related with the RR T [8]. These characteristics make it suitable to use it as an optimization tool for low noise oscillators [12]. In the same way it is also suitable for estimating the start-up time.…”

Section: Calculus Using the Rr Tmentioning

confidence: 99%

Classic Linear Methods Provisos Verification for Oscillator Design Using NDF and Its Use as Oscillators Design Tool

Parra-Cerrada¹,

González-Posadas²,

Jiménez-Martín³

et al. 2013

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The purpose of this paper is to show the conditions that must be verified before use any of the classic linear analysis methods for oscillator design. If the required conditions are not verified, the classic methods can provide wrong solutions, and even when the conditions are verified each classic method can provide a different solution. It is necessary to use the Normalized Determinant Function (NDF) in order to perform the verification of the required conditions of the classic methods. The direct use of the NDF as a direct and stand-alone tool for linear oscillator design is proposed. The NDF method has the main advantages of not require any additional condition, be suitable for any topology and provide a unique solution for a circuit with independence of the representation and virtual ground position. The Transpose Return Relations (RR_T) can be used to calculate the NDF of any circuit and this is the approach used to calculate the NDF on this paper. Several classic topologies of microwave oscillators are used to illustrate the problems that the classic methods present when their required conditions are not verified. Finally, these oscillators are used to illustrate the use and advantages of the NDF method.

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“…Oscillator is one of the important signal sources. At present, there has been increasing demand on oscillators with low-phase noise, because it determines the overall performance of radar and communication systems [1]. Besides, other factors of oscillators such as output power, harmonic suppression, DC–RF conversion efficiency and physical dimension, also play an important role.…”

Section: Introductionmentioning

confidence: 99%

A compact low-phase noise oscillator with superior harmonic suppression characteristics based on novel nested split-ring resonator (NSRR)

Liu

Xie

Tang

et al. 2015

Int. J. Microw. Wireless Technol.

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In this paper, a novel microwave oscillator incorporating miniaturized nested split-ring resonators is proposed. The high-quality (Q) factor and wide spurious-free band of the NSRR contribute to low-phase noise and high-harmonic suppression of the proposed oscillator circuits. In addition, the NSRR is featured by compact size of 0.12λg × 0.12λg, where λg is the guided wavelength of resonance frequency. The fabricated 2.4 GHz oscillator has an output power of 11.7 dBm with 5 V DC supply and 10 mA current consumption. The second harmonic suppression is −45.49 dBc, the phase noise is −110 dBc/Hz @100 kHz, and the DC–RF conversion efficiency is measured as 30%.

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Transpose Return Relation Method for Designing Low Noise Oscillators

Cited by 8 publications

References 25 publications

Stability, Mounting, and Measurement Considerations for High-Power GaN MMIC Amplifiers

Stability, Mounting, and Measurement Considerations for High-Power GaN MMIC Amplifiers

Classic Linear Methods Provisos Verification for Oscillator Design Using NDF and Its Use as Oscillators Design Tool

A compact low-phase noise oscillator with superior harmonic suppression characteristics based on novel nested split-ring resonator (NSRR)

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