Silicon-based terahertz signal generation with multi-phase sub-harmonic injection locking technique

Chi, Taiyun

27 May 2016

This thesis presents a multi-phase injection locking (IL) technique and its application in the locking range extension in multi-phase injection locking oscillators (ILOs) for Terahertz (THz) signal generation. The proposed technique can significantly increase the frequency locking range of a multi-phase injection locking oscillator compared to the conventional single-phase injection locking scheme. Based on the multi-phase IL technique and sub-harmonic ILOs, an “active frequency multiplier chain” architecture and a multi-ring system layout topology are also proposed to achieve scalable THz signal generation. As proof of concept, a cascaded 3-stage 3-phase 2nd-order sub-harmonic ILO chain is implemented in the IBM 9HP SiGe BiCMOS process. The design achieves a maximum output power of -16.6dBm at 498GHz, a phase noise of -87dBc/ Hz at 1MHz offset, and a total 5.1% frequency tuning range from 485.1GHz to 510.7GHz, which is the largest frequency tuning range among all the reported silicon-based THz oscillator sources in the 0.5THz band.

Injection locking

Terahertz signal source

RF Sensing and Receiving Circuits for a Cognitive Radio

Wang, Fu-Kang

26 July 2009

In this thesis, various kinds of theory to account for injection locking and pulling in the literature are studied and compared. On this basis, this thesis derives a generalized locking equation when injection signal is modulated signal. In applications, a novel RF sensing circuit for cognitive radio system is proposed using injection locking and frequency demodulation. Detailed circuit architecture and sensing principle are also described in the thesis. In implementation, a hybrid VCO and a CMOS VCO have been separately used with the other components to establish the RF sensing circuit. The simulation relies on a discrete-time numerical method. Comparison between measurement and simulation shows very good agreement. This RF sensing circuit can simultaneously sense frequency and power with a sensing speed up to 400 MHz/ms and a sensing sensitivity as low as -80 dBm, showing that the presented prototype can fast and reliably sense frequency and power for analog and digital modulation signals.

Injection Pulling

Injection Locking

Sensor

Study of Injection Locking and Pulling in Local Oscillators.

Hsiao, Chieh-Hsun

25 July 2008

This thesis is composed of three parts. In the first part, various kinds of theory to account for injection locking and pulling in the available literature are studied and compared. In the second part, this thesis proposes an experimental setup with self-made hybrid VCO and commercially available equipments and components to measure the characteristics of injection locking and pulling. This thesis also performs simulation to verify the measured results. The simulation mainly relies on the circuit envelope technique that has been developed in our laboratory. Comparison between measurement and simulation shows good agreement in the injection-locking characteristic curves and the injection-pulling spectrum characteristics. In the third part, this thesis carries out an RFIC design for a fractional-N frequency synthesizer with special features on quantization-noise cancellation and PLL nonlinearity reduction using TSMC 0.13£gm CMOS process.

Injection Locking

Injection Pulling

Voltage Controlled Oscillator

Low-power Multi-Gb/s Wireline Communication

Hossain, Masum

31 August 2011

This thesis discusses low-power wireline receivers with particular focus on clocking circuitry and architectures. These clocking solutions can be used for a 1-D partial response channel as well as for a conventional DC coupled channel. The receiver front end for a 1-D channel requires more consideration to recover an NRZ signal from the received narrow pulses. Two possible solutions are presented. First, a full-rate detection technique is presented, where the speed is limited by the settling time of a latch circuit which has to be less than 1 UI. Second, a novel demuxing technique is introduced. It is demonstrated through theory, simulation and measurement results that the half-rate architecture can improve maximum achievable speed by a factor of 1.6. The distribution and alignment of high-frequency clocks across a wide bus of links is a signi¯cant challenge in modern computing systems. A low power clock source is demonstrated by incorporating a bu®er into a cross-coupled oscillator. Because the load is isolated from the tank, the oscillator can directly drive 50-Ohm impedances or large capacitive loads with no additional bu®ering. Using this topology, a quadrature VCO (QVCO) is implemented in 0.13 um digital CMOS. The QVCO oscillates at 20 GHz, consumes 20 mW and provides 12% tuning range. Injection locked oscillators (ILOs) are an attractive clocking tool for low-power area- e±cient wireline receivers. In this work, we explored their use as a clock deskew element, a clock recovery unit and a programmable jitter lter. A study of both LC and ring ILOs indicates signi¯cant variation in their jitter tracking bandwidth when used to provide large phase shifts. By selectively injecting di®erent phases of a quadrature-LC or ring VCO, this problem is obviated resulting in reduced phase noise. First, an ILO based half-rate clock recovery technique is presented, which can be used for AC coupled links where low frequency signal components are attenuated by the channel. The nonlinear path comprises a hysteresis latch that recovers the missing low frequency content and a linear path that boosts the high frequency component by taking advantage of the high pass channel response. By optimally combining them, the front-end recovers NRZ signals up to 13 Gb/s burning only 26 mW in 90 nm CMOS. A simple theory and simulation technique for ILO-based receivers is discussed. The clock recovery technique is veried with experimental results at 5-10 Gb/s in 90 nm CMOS consuming 70 mW and acquiring lock within 1.5 ns. Second, a clock forwarded 65nm CMOS receiver uses two ILOs to frequency- multiply, deskew, and track correlated jitter on a pulsed clock forwarded from the transmitter. Di®erent data rates and latency mismatch between the clock and data paths are ac- commodated by a jitter tracking bandwidth that is controllable up to 300MHz. Each receiver consumes 0.92 pJ/bit operating at 7.4 Gb/s and has a jitter tolerance of 1.5 UI at 200MHz.

0544

Low-power Multi-Gb/s Wireline Communication

Hossain, Masum

31 August 2011

This thesis discusses low-power wireline receivers with particular focus on clocking circuitry and architectures. These clocking solutions can be used for a 1-D partial response channel as well as for a conventional DC coupled channel. The receiver front end for a 1-D channel requires more consideration to recover an NRZ signal from the received narrow pulses. Two possible solutions are presented. First, a full-rate detection technique is presented, where the speed is limited by the settling time of a latch circuit which has to be less than 1 UI. Second, a novel demuxing technique is introduced. It is demonstrated through theory, simulation and measurement results that the half-rate architecture can improve maximum achievable speed by a factor of 1.6. The distribution and alignment of high-frequency clocks across a wide bus of links is a signi¯cant challenge in modern computing systems. A low power clock source is demonstrated by incorporating a bu®er into a cross-coupled oscillator. Because the load is isolated from the tank, the oscillator can directly drive 50-Ohm impedances or large capacitive loads with no additional bu®ering. Using this topology, a quadrature VCO (QVCO) is implemented in 0.13 um digital CMOS. The QVCO oscillates at 20 GHz, consumes 20 mW and provides 12% tuning range. Injection locked oscillators (ILOs) are an attractive clocking tool for low-power area- e±cient wireline receivers. In this work, we explored their use as a clock deskew element, a clock recovery unit and a programmable jitter lter. A study of both LC and ring ILOs indicates signi¯cant variation in their jitter tracking bandwidth when used to provide large phase shifts. By selectively injecting di®erent phases of a quadrature-LC or ring VCO, this problem is obviated resulting in reduced phase noise. First, an ILO based half-rate clock recovery technique is presented, which can be used for AC coupled links where low frequency signal components are attenuated by the channel. The nonlinear path comprises a hysteresis latch that recovers the missing low frequency content and a linear path that boosts the high frequency component by taking advantage of the high pass channel response. By optimally combining them, the front-end recovers NRZ signals up to 13 Gb/s burning only 26 mW in 90 nm CMOS. A simple theory and simulation technique for ILO-based receivers is discussed. The clock recovery technique is veried with experimental results at 5-10 Gb/s in 90 nm CMOS consuming 70 mW and acquiring lock within 1.5 ns. Second, a clock forwarded 65nm CMOS receiver uses two ILOs to frequency- multiply, deskew, and track correlated jitter on a pulsed clock forwarded from the transmitter. Di®erent data rates and latency mismatch between the clock and data paths are ac- commodated by a jitter tracking bandwidth that is controllable up to 300MHz. Each receiver consumes 0.92 pJ/bit operating at 7.4 Gb/s and has a jitter tolerance of 1.5 UI at 200MHz.

0544

Superharmonic Injection Locked Quadrature LC VCO Using Current Recycling Architecture

Kalusalingam, Shriram

2010 December 1900

Quadrature LO signal is a key element in many of the RF transceivers which tend to dominate today’s wireless communication technology. The design of a quadrature LC VCO with better phase noise and lower power consumption forms the core of this work. This thesis investigates a coupling mechanism to implement a quadrature voltage controlled oscillator using indirect injection method. The coupling network in this QVCO couples the two LC cores with their super-harmonic and it recycles its bias current back into the LC tank such that the power consumed by the coupling network is insignificant. This recycled current enables the oscillator to achieve higher amplitude of oscillation for the same power consumption compared to conventional design, hence assuring better phase noise. Mathematical analysis has been done to study the mechanism of quadrature operation and mismatch effects of devices on the quadrature phase error of the proposed QVCO. The proposed quadrature LC VCO is designed in TSMC 0.18 μm technology. It is tunable from 2.61 GHz - 2.85 GHz with sensitivity of 240 MHz/V. Its worst case phase noise is -120 dBc/Hz at 1 MHz offset. The total layout area is 1.41 mm^2 and the QVCO core totally draws 3 mA current from 1.8 V supply.

Quadrature VCO

LC VCO

Oscillator

Injection locking

QVCO

Phase noise

Σχεδιασμός και υλοποίηση ταλαντωτή με injection locking

Παπαλάμπρου, Ανδρέας

24 November 2014

Ο ταλαντωτής αποτελεί σημαντικό κομμάτι κάθε τηλεπικοινωνιακού συστήματος. Το σημαντικότερο στοιχείο της απόδοσής του είναι ο θόρυβος φάσης. Για τη βελτίωσή του χρησιμοποιείται η μέθοδος του injection locking. Με αυτή τη μέθοδο ένα σήμα αναφοράς με καλά χαρακτηριστικά θορύβου χρησιμοποιείται για να βελτιώσει την έξοδο του ταλαντωτή. Χρησιμοποιείται μια τοπολογία τροποποιημένου ταλαντωτή Colpitts, ο οποίος εξομοιώνεται και υλοποιείται. Με τις μετρήσεις που ακολουθούν επιβεβαιώνεται η καλύτερη συμπεριφορά θορύβου που επιτυγχάνει η μέθοδος του injection locking. / Oscillators form an integral part of all communication systems. Their most crucial element regarding performance is phase noise. To improve it we use the method of injection locking. With this method, a reference signal with good noise characteristics is used to improve the output of the oscillator. A modified Colpitts oscillator topology is used which is both simulated and implemented as a circuit board. Measurements confirmed that injection locking improved the characteristics of phase noise.

Ταλαντωτές

Θόρυβος φάσης

621.384 12

Oscillators

Colpitts

Injection locking

High Power Microwave Wireless Power Transmission System with Phase-Controlled Magnetrons / 位相制御マグネトロンを用いた大電力マイクロ波無線電力伝送システム

Yang, Bo

24 November 2020

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第22843号 / 工博第4783号 / 新制||工||1748(附属図書館) / 京都大学大学院工学研究科電気工学専攻 / (主査)教授 篠原 真毅, 教授 大村 善治, 准教授 後藤 康仁 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

Magnetrons

Microwave power transmission

Injection locking

Phased array

Modulation

500

1/f Additive Phase Noise Analysis for One-Port Injection Locked Oscillators

Matharoo, Rishi

27 August 2015

No description available.

Electrical Engineering

Oscillators

phase noise

injection locking

low frequency noise

Nonlinear Response of Resonant-Tunneling-Diode Terahertz Oscillator / 共鳴トンネルダイオードテラヘルツ発振器における非線形応答

Hiraoka, Tomoki

24 September 2021

京都大学 / 新制・課程博士 / 博士(理学) / 甲第23451号 / 理博第4745号 / 新制||理||1680(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 田中 耕一郎, 教授 佐々 真一, 教授 金光 義彦 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM

Resonant-tunneling-diode oscillator

Terahertz

Injection locking

Mode locking

400