Your search keyword '"Ghonoodi, Hojat"' showing total 5 results

1. A series-coupled LC quadrature oscillator using phase/amplitude calibration.

Author

Ghonoodi, Hojat and Naimi, Hossein Miar

Subjects

*TRANSISTORS, *ELECTRIC oscillators, *PHASE shifters, *COMPLEMENTARY metal oxide semiconductors, *ENERGY consumption

Abstract

In this paper, an analytic approach for the estimation of the phase and amplitude error in series coupled LC quadrature oscillator (SC-QO) is proposed. The analysis results show that imbalances in source voltage of coupling transistor because of mismatches between LC tanks are the main source of the phase and amplitude error in this oscillator. For compensation of the phase and amplitude error, a phase and amplitude-tunable series coupled quadrature oscillator is designed in this paper. A phase shift generation circuit, designed using an added coupling transistor, can control the coupling transistor source voltage. The phase and amplitude error can simply be controlled and removed by tuning the phase shifter, while this correction does not have undesirable impact on phase noise. In fact, the proposed SC-QO generates a phase shift in the output current, which reduces the resonator phase shift (RPS) and improves phase noise. The phase and amplitude tunable SC-QO is able to correct the phase error up to ±12°, while amplitude imbalances are reduced as well. To evaluate the proposed analysis, a 4.5-GHz CMOS SC-QO is simulated using the practical 0.18-μm TSMC CMOS technology with a current consumption of 2 mA at 1.8-V supply voltage. Copyright © 2016 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2017

2. Analysis of frequency and amplitude in CMOS differential ring oscillators.

Author

Ghonoodi, Hojat, Miar-Naimi, Hossein, and Gholami, Mohammad

Subjects

*COMPLEMENTARY metal oxide semiconductors, *ELECTRIC oscillators, *WAVE analysis, *SEMICONDUCTOR manufacturing, *COMPUTER simulation

Abstract

In this paper, a new method for computing the amplitude and frequency of differential ring oscillators (ROs) is proposed. The analysis is performed in two separate parts. In the first of these, equations are derived with the assumption of a sinusoidal waveform of outputs, while in the other, the outputs are assumed to be exponential. It is shown that the derived equations for frequency and amplitude are sufficiently exact. In addition, conditions in which sinusoidal and exponential output occur are thoroughly discussed. In the instances in which the results did not satisfy the necessary conditions for sinusoidal output, the output is assumed to be exponential. Moreover, the related analytical equations are written, and the new expressions for frequency and amplitude of ROs are derived. Analytical results are confirmed by simulation results, using the Taiwan Semiconductor Manufacturing Company 0.18 µm technology model. The simulation results indicate the high level of accuracy of the proposed model. [ABSTRACT FROM AUTHOR]

Published

2016

3. Phase error analysis in CMOS injection-coupled LC quadrature oscillator (IC-QO).

Author

Ghonoodi, Hojat and Miar‐Naimi, Hossein

Subjects

*CMOS integrated circuits, *ELECTRIC oscillators, *OSCILLATIONS, *ELECTRIC potential, *FREQUENCY dividers, *TRANSISTOR circuits

Abstract

This paper presents a novel approach to study the phase error in source injection coupled quadrature oscillators (QOs). Like other LC QOs, the mismatches between LC tanks are the main source of phase error in this oscillator. The QO is analyzed where the phase error and oscillation frequency are derived in terms of circuit parameters. The proposed analysis shows that the output phase error is a function of injection current and the current of source equivalent capacitor. As a result, it is shown that increasing of tail current and LC tank quality factor decreases the phase error. Derived equations show that the phase error can be cancelled and even controlled by adjusting bias currents. To evaluate the proposed analysis and consequent designed QO, a 5.5 GHz CMOS QO is designed and simulated using the practical 0.18 µm TSMC CMOS technology. The experiments show good agreement between analytical equations and simulation results. Copyright © 2013 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2014

4. A CMOS Quadrature LC Oscillator using Automatic Phase/Amplitude Calibration.

Author

Ghonoodi, Hojat and Naimi, Hossein

Subjects

*COMPLEMENTARY metal oxide semiconductors, *ELECTRIC oscillators, *LOGIC circuits, *FEEDBACK oscillators, *NUMERICAL integration

Abstract

In this paper, a novel LC quadrature oscillator (QO) is presented that can simply and automatically cancel the phase and amplitude errors raised by mismatches in LC tanks; the major source of phase and amplitude errors. The design is based on method of using unequal coupling factors in a parallel quadrature oscillator (P-QO). This method shows how we can cancel phase and amplitude errors simultaneously by choosing appropriate inversely proportional coupling factors. To cancel the errors, the proposed circuits first sense the phase error and increase or decrease the difference between the coupling factors accordingly. When tuning tail currents, the coupling factors can be simply adjusted. The entire system has a block diagram like a PLL. The dynamics of the proposed circuit is analyzed, and it is shown how the phase and amplitude error is canceled in response to an imposed LC tank mismatch. To evaluate the circuit, a QO has been designed to oscillate at 5 GHz with 1.8 V supply and 6.2 mA current consumption. The circuit has been simulated using TSMC 0.18 CMOS practical model where all the results confirm the analytical results. [ABSTRACT FROM AUTHOR]

Published

2012

5. A Phase and Amplitude Tunable Quadrature LC Oscillator: Analysis and Design.

Author

GHonoodi, Hojat and Naimi, Hossein Miar

Subjects

*ELECTRIC oscillators, *ELECTRIC equipment, *COMPLEMENTARY metal oxide semiconductors, *DIGITAL electronics, *LOGIC circuits

Abstract

This paper presents a new analytical approach to extract closed form equations for phase and amplitude imbalances raised from mismatches between two LC-tanks in quadrature oscillators. For more generality, we considered different coupling factors for the two coupled LC oscillators. This makes our analysis so general that we could design a phase and amplitude tunable quadrature oscillator accordingly. We show that choosing appropriate inversely proportional coupling factors makes it possible to have exactly zero phase and amplitude errors. Choosing so does not have any impacts on phase noise; indeed, the trade-off between phase noise and phase error in coupled quadrature oscillators has been broken here. We show that using differential stages for tuning tail currents of oscillating stages can somehow implement the inversely proportional coupling factors. Tuning the phase and amplitude errors, the frequency does not change and power consumption remains constant too; these are the advantages of the proposed circuit. The theoretical results and proposed quadrature oscillator are evaluated and confirmed through simulations using TSMC 0.18 \mu\m model technology on a 5-GHz quadrature oscillator with current consumption of 4.2 mA at 1.8 V supply voltage. [ABSTRACT FROM PUBLISHER]

Published

2011