Cmos Rotary Traveling Wave Oscillators (Rtwos)

Rotary Traveling Wave Oscillator (RTWO) represents a transmission line based technology for multi-gigahertz multiple phase clock generation. RTWO is known for providing low jitter and low phase noise signals but the issue of high power consumption is a major drawback in its application. Direction of wave propagation is random and is determined by the least resistance path in the absence of an external direction control circuit. The objective of this research is to address some of the problems of RTWO design, including high power consumption, uncertainty of propagation direction and optimization of design variables. Included is the modeling of RTWO for sensitivity, phase noise and power analysis. Research objectives were met through design, simulation and implementation. Different designs of RTWO in terms of ring size and number of amplifier stages were implemented and tested. Design tools employed include Agilent ADS, Cadence EDA, SONNET and Altium PCB Designer. Test chip was fabricated using IBM 0.18 μm RF CMOS technology. Performance measures of interest are tuning range, phase noise and power consumption. Agilent ADS and SONNET were used for electromagnetic modeling of transmission lines and electromagnetic field radiation. For each design, electromagnetic simulations were carried out followed by oscillation synthesis based on circuit simulation in Cadence Spectre. RTWO frequencies between 2 GHz and 12 GHz were measured based on the ring size of transmission lines. Simulated microstrip transmission line segments had a quality factor between 5.5 and 18. For the various designs, power consumption ranged from 20 mW to 120 mW. Measured phase noise ranged between -123 dBc/Hz and -87 dBc/Hz at 1 MHz offset. Development also included the design of a wide band buffer and a printed circuit board with high signal integrity for accurate measurement of oscillation frequency and other performance measures. Simulated performance, schematics and measurement results are presented

Design of a 85 GHz Rotary Traveling Wave Oscillator for Imaging Applications

This paper presents the design of a Rotary Traveling Wave Oscillator (RTWO) at 85GHz. The oscillator can be useful in imaging applications. It is implemented in 65nm commercial CMOS technology. The total area of the oscillator is 0.185x0.185 mm2. The total power consumption is 25 mA out of 1.5 V supply

Rotary travelling wave oscillator with differential nonlinear transmission lines

A methodology for the harmonic-balance analysis and design of rotary-traveling wave oscillator is presented. Two different implementations are compared. The first one is the standard configuration based on a distributed transmission lines. The second one is a new configuration based on a differential nonlinear transmission line (NLTL), which enables the generation of square waveforms with reduced number of stages, while still maintaining the capability to produce multiphase signals. The possible coexistence of oscillation modes is investigated with a detailed bifurcation analysis versus practical parameters such as the device bias voltage. The phase-noise spectrum is predicted from the variance of the common phase deviation. The parameters that determine this variance are identified with the conversion-matrix approach. The two prototypes, based on a distributed transmission line and a differential NLTL, have been manufactured and characterized experimentally, obtaining very good agreement between simulations and measurements.This work has been supported by the Spanish Ministry of Economy and Competitiveness through project TEC2011-29264-C03-01

Nonlinear microwave simulation techniques

The design of high performance circuits with short manufacturing cycles and low cost demands reliable analysis tools, capable to accurately predict the circuit behaviour prior to manufacturing. In the case of nonlinear circuits, the user must be aware of the possible coexistence of different steady-state solutions for the same element values and the fact that steady-state methods, such as harmonic balance, may converge to unstable solutions that will not be observed experimentally. In this contribution, the main numerical iterative methods for nonlinear analysis, including time-domain integrations, shooting, harmonic balance and envelope transient, are briefly presented and compared. The steady-state methods must be complemented with a stability steady-state analysis to verify the physical existence of the solution. This stability analysis can also be combined with the use of auxiliary generators to simulate the circuit self-oscillation and predict qualitative changes in the solution under the continuous variation of a parameter. The methods will be applied to timely circuit examples that are demanding from the nonlinear analysis point of view.This work has been supported by the Spanish Government under contract TEC2014-60283-C3-1-R and the Parliament of Cantabria (12.JP02.64069)

A 12GHz 30mW 130nm CMOS Rotary Travelling Wave Voltage Controlled Oscillator

This paper reports a 12GHz Rotary Travelling Wave (RTW) Voltage Controlled Oscillator designed in a 130nm CMOS technology. The phase noise and power consumption performances were compared with the literature and with telecommunication standards for broadcast satellite applications. The RTW VCO exhibits a -106dBc/Hz@1MHz and a 30mW power consumption with a sensibility of 400 MHz/V. Finally, requirements are given for a PLL implementation of the RTW VCO and simulated results are presented

Collective Pulse Dynamics: A New Timing Circuit Strategy

This work presents a novel CMOS behavior of self stabilization of ring oscillators using collective dynamics. It shows that phase error correction can occur in ring oscillators over multiple cycles without an external reference via the collective dynamics of pulses. In time domain this shows up as timing stability improvement in oscillators. Different timing stability metrics were analyzed to determine the correct methodology to analyze this stability improvement. Behavioral models were made to capture the effects of local dynamics and its collective effects. These models were shown to have a good correlation with the HSPICE circuit simulations and measured values. Multiple oscillator topologies and architectures were fabricated to test the model, behavior and subsequent analysis. Different pulse amplifier based ring oscillators show trends similar to that predicted by simulations and empirical relationships developed using behavioral simulations. Further transmission line stabilized traveling wave version of the pulse oscillators show a higher stability improvement. This work opens up a new design space in the timing circuits design where all the other conventional tricks are still applicable. It also opens up an application space due to the timing stability improvement in the order of 1000 cycles where conventional ADC’s and TDC’s work. Finally this work eases up the constraints of loop filter and source phase noise when oscillators are operated in a phase locked loop

New methodologies for the analysis and synthesis of oscillator circuits

Advances in the analysis and synthesis of oscillator circuits, using harmonic balance (HB), are presented. They rely on the use of auxiliary generators, which can be introduced into the HB software to impose mathematical conditions or to extract a realistic oscillator model. In particular, a bifurcation-detection technique, for the accurate design of dual-frequency oscillators, and a semi-analytical function, for the prediction of oscillation transients, are described. In dual-frequency oscillators, each oscillation must be the only stable solution in a certain parameter interval. This is ensured through the calculation of two distinct primary-Hopf bifurcation loci, which should give rise to disjoint parameter regions. Conditions for the physical observability of concurrent oscillations are also given. With respect to the transient prediction, both the linear and nonlinear stages are considered. The analysis is based on the derivation of outer-tier semi analytical equation, from which a growth rate function is identified, which, unlike ordinary simulations, is not constrained to particular initial values. The methods have been applied to two FET-based oscillator circuits that have been manufactured and measured, obtaining good agreement with the simulation results

Ku band rotary traveling-wave voltage controlled oscillator

Voltage-controlled oscillator (VCO) plays a key role in determination of the link budget of wireless communication, and consequently the performance of the transceiver. Lowering the noise contribution from the VCO to the entire system is always challenging and remains the active research area. Motivated by high demands for the low-phase noise, low-power consumption VCO in the application of 5G, radar-sensing system, implantable device, to name a few, this research focused on the design of a rotary travelling-wave oscillator (RTWO). A power conscious RTWO with reliable direction control of the wave propagation was investigated. The phase noise was analyzed based on the proposed RTWO. The phase noise reduction technique was introduced by using tail current source filtering technique in which a figure-8 inductors were employed. Three RTWO were implemented based on GF 130 nm standard CMOS process and TSMC 130 nm standard CMOS process. The first design was achieving 16-GHz frequency with power consumption of 5.8-mW with 190.3 dBc/Hz FoM at 1 MHz offset. The second and third design were operating at 14-GHz with a power consumption range of 13-18.4mW and 14.6-20.5mW, respectively. The one with filtering technique achieved FoM of 184.8 dBc/Hz at 1 MHz whereas the one without inudctor filtering obtained FoM of 180.8 dBc/Hz at 1 MHz offset based on simulation