New method for generating precise triangular waves and square waves

A new mathematical method for the design of electronic triangular- and square-wave generators is developed by considering the relatively simple problem of generating precise sinewaves. It is shown that the new oscillators possess a relatively large potential for performing accurately.     

Simplified method for generating precise triangular waves

Kaplan and Tatrash have given a method for the design of triangular-wave generators. The practical implementation of this circuit requires use of analogue multipliers. The aim of this letter is to propose another method which does not need multipliers.     

A simple oscillator based on conservative models for generating three phase waveforms

The reliance on conservative models is a well-known step in the development of conventional oscillators in two phases. This paper demonstrates that conservative models can also serve for the development of sinewaves and other waveform generators in three phases.     

New constant-current controlled astable multivibrator for generating sawtooth and square waves

This article presents a now constant-current controlled astable multivibrator in which only one resistor and one capacitor is used, the other elements being transistors. The circuit consists of a constant-current source and the multivibrator itself. The multivibrator is specifically designed to have a simple three-stage direct-coupled transistor amplifier, with the output of the third stage fed back to the first stage and a capacitor connected across any two collectors. The switching action takes place by means of that capacitor. Linear sawtooth and square waves are generated simultaneously at the transistor collectors. Since only one resistor and one capacitor are required, this circuit is practical with IC fabrication.     

A high-frequency electronically tunable quadrature oscillator

An architecture composed of mutually regenerative oscillators is introduced. It has been used to design a low-noise high-frequency voltage-controlled oscillator (VCO) capable of producing two output signals in quadrature with essentially identical properties. The phase relation between the quadrature outputs is frequency dependent and extremely stable. A novel way of coupling the regenerative oscillators is suggested in order to improve the frequency stability of the coupled oscillator system. Results obtained from a test chip have verified the viability of the oscillator concept. The oscillator circuit has been realized in a medium-frequency bipolar process. The tuning range extends to 500 MHz. At an oscillation frequency of 200 MHz, measured phase noise was -121 dBc/Hz at 1-MHz distance from the carrier.<>     

Self generating square/triangular wave and pulse width modulator using a single MO-CCCDTA

A self-generating square/triangular wave and pulse width modulator (PWM) using multiple output current controlled current differencing transconductance amplifier (MO-CCCDTA) is presented. To obtain all the three functions simultaneously from the same topology, the MO-CCCDTA is modified a little bit. The characterisation of the modified MO-CCCDTA structure shows that the parasitic resistances at input terminals (n and p) can be varied via bias current. The maximum useful frequency range is found to be 635 MHz, which is higher than the available literature. The waveform generator and PWM circuit use only one MO-CCCDTA, one grounded capacitor and no resistor; hence suitable for IC implementation. The duty cycle of proposed pulse width modulation can be tuned by bias current of MO-CCCDTA over a wide range. The performances of the proposed block and its applications (square/triangular/PWM) are verified by PSPICE simulation using TSMC 0.35 µm technology. The power consumption is about 1.12 mW. To verify experimentally, a prototype of MO-CCCDTA has been made using commercially available ICs (AD844AN and CA3080) on printed circuit board. The simulation and experimental results verify theoretical proposition well. Monte carlo simulation is carried out, which proves satisfactory performance of the proposed circuit against mismatches. The performance of the proposed circuit is also verified through pre-layout and post-layout simulation results. The required chip area is only 22.415 × 14.6 µm².     

A low-phase noise injection-locked quadrature voltage-controlled oscillator

This article presents a low-phase noise quadrature voltage-controlled oscillator (QVCO) in which the re-filtering technique of the side-band noise is adopted. In the proposed QVCO, besides using re-filtering technique, the passive elements replaced the noisy and lossy active coupling devices. Therefore, due to the elimination of the associate noise sources of the active coupling devices and re-filtering of side-band noise of the circuit, the proposed QVCO shows an excellent phase-noise and FOM. The proposed QVCO was implemented and simulated in TSMC 0.18 μm RF-CMOS technology. The phase noise of the proposed QVCO at 3 MHz offset frequency from the 3 GHz center frequency is ?144 dBc/Hz, for a current consumption of 11.5 mA at a power supply of 1.8-V. Simulation results show the proposed QVCO can operate with power supply as low as 0.6 V. Monte–Carlo analyses for, 3% device mismatch and process variation, result in phase error lower than 0.8°. Generalizing the proposed coupling technique to several core VCOs very low-phase noise multiphase signals can be generated.     

A 9.8-11.5-GHz quadrature ring oscillator for optical receivers

This paper describes a quadrature ring oscillator that is tunable from 9.8 to 11.5 GHz in a 30-GHz f_T BiCMOS technology. The ring oscillator can be used in advanced data clock recovery architectures in optical receivers. The circuit implementation of the oscillator uses transistors as active inductances. Isolation between the oscillator and cascaded circuits, such as buffers and flip-flops, is improved by utilizing the active inductances in a cascode configuration. Carrier to noise ratios better than 94 dBc/Hz at 2-MHz offset are measured with 75-mW dissipation and 2.7-V supply voltage. The evolution in two-stage ring oscillator topologies, leading to the realized design, is discussed in detail on the circuit level     

A 2.4 GHz high-performance CMOS differential quadrature relaxation oscillator

In this paper, the effects that limit the performance of practical implementations of RC relaxation oscillators are investigated. The insights gained are used to suggest a topology for high-frequency quadrature relaxation oscillators with closer-to-optimal performance. The proposed oscillator uses a modified latch to improve the switching speed without increasing the power consumption. Moreover, the new topology avoids static current sources, maximizes the voltage swing and has an active coupling structure without static power consumption that reduces the circuit phase-noise. Experimental results show that the oscillator operates in relaxation mode at 2.4 GHz and achieves a FoM of \(\mathrm {-162\,dBc/Hz}\), which is, as far as the authors know, the best FoM for relaxation oscillators operating in the GHz range.     

Frequency multiplier for square waves

A Circuit for multiplying the frequency of square waves is reported. It uses a linear voltage-controlled astable multi-vibrator with feedback loops for maintaining the frequency multiplication ratio and the output mark/space ratio independent of variations in component values or device parameters.     

A systematic realization of third-order quadrature oscillator with controllable amplitude

A systematic realization of third-order quadrature oscillator using a voltage-mode non-inverting lowpass filter and a voltage-mode inverting lossless feedback integrator is presented in this paper. The proposed circuit consists of two multiple-output differential voltage current conveyor transconductance amplifiers (MO-DVCCTAs), two grounded resistors and three grounded capacitors. The new circuit provides three quadrature voltage outputs, two high-impedance quadrature current outputs, and one high-impedance current output with controllable amplitude, simultaneously. When the input bias current of the first MO-DVCCTA is a modulating signal, the circuit can generate amplitude modulation or amplitude shift keying signals. The condition of oscillation and the frequency of oscillation can be controlled independently through grounded resistors. The proposed circuit only uses grounded capacitors and grounded resistors, which can be easily implemented as an integrated circuit. The experimental results and H-Spice simulation results are given to confirm the theoretical analysis.     

基于光电振荡器的光脉冲和电微波信号发生器

设计了一种基于相位调制器的用于产生光脉冲和电微波信号的光电振荡器。该方案采用直调激光器配合相位调制器产生大啁啾并由DCF压窄输出光脉冲。利用偏振分束器和合束器在不增加有源器件的基础上形成双环路结构抑制微波信号的边模。该系统可以产生9.8 GHz的重复频率,脉宽小于 12 ps的光脉冲同时输出该频率的电微波信号。测得相位噪声为-105 dBc/Hz@10 kHz,Q值大于10¹⁰。     

A low-phase-noise 900-MHz CMOS ring oscillator with quadrature output

A 900-MHz two-stage CMOS voltage controlled ring oscillator (VCRO) with quadrature output is presented. The circuit is designed in a 0.18-um CMOS technology and operated on a 1.8-V supply voltage. The VCRO have a tuning range of 730 MHz to 1.43 GHz and good tuning linearity. Between 0 V and 1.1 V of control voltage, the gain of VCRO is around −620 MHz/V. At 900 MHz, the phase noise of the VCRO is −106.1 dBc/Hz at 600-KHz frequency offset with power consumption of 65.5 mW.     

A low-power, high-frequency, all-NMOS all-current-mirror sinusoidal quadrature oscillator

A low-power, high-frequency, sinusoidal quadrature oscillator is presented through the use of only current mirrors where the small-signal paths are realized through all NMOS transistors. The technique is relatively simple based on (i) inherent time constant of current mirrors, i.e. the internal capacitances and the transconductance of a diode-connected NMOS, (ii) a negative resistance formed by a transconductance of a diode-connected NMOS load of a current mirror. No external passive components are required. As a particular example, a 2.83 GHz, 0.374 f_T, 0.38 mW sinusoidal quadrature oscillator is demonstrated. Total harmonic distortions are less than 0.8%. The oscillation frequency is current-tunable over a range of 640 MHz or 22.62%. The amplitude matching and the quadrature phase matching are better than 0.04 dB and 0.17°, respectively. A figure of merit called a normalized carrier-to-noise ratio is 158.23 dBc/Hz at the 2 MHz offset from 2.83 GHz. Comparisons to other approaches are also presented.     

A 6-GHz capacitively-coupled Colpitts CMOS quadrature voltage controlled oscillator

In this work a new low-noise low-power Colpitts quadrature voltage controlled oscillator (QVCO) made by coupling two identical current-switching differential Colpitts voltage controlled oscillators (VCO) is proposed; coupling of the VCOs is done using some capacitors in an “in-phase anti-phase” scheme. In this coupling configuration first harmonics (as well as higher harmonics) from each VCO are injected to the other VCO, as opposed to coupling schemes in which only even harmonics are injected. An analysis of the linearized circuit which confirms 90° phase difference between output signals of the proposed circuit is presented. Since no extra noise sources or power consumption are introduced to the core VCOs, the proposed QVCO achieves low phase noise performance and low power consumption. The proposed circuit is designed and simulated in a commercial 0.18 μm CMOS technology. The simulated phase noise of the proposed QVCO at 3 MHz offset frequency is ?138.3 dBc/Hz, at 6 GHz. The circuit dissipates 8.16 mW from a 1.8 V supply and its frequency can be tuned from 5.6 to 6.3 GHz.     

A 5-GHz frequency-doubling quadrature modulator with a ring-typelocal oscillator

The direct-conversion quadrature modulator described here was developed by using a frequency-doubling circuit technique so that the modulator and the local oscillator can be integrated on a single silicon chip. The local oscillation frequency in the modulator can be reduced to half the carrier frequency, and this enables the integration on a single chip. A three-level mixer with a newly designed symmetrical topology for two local oscillator inputs is used for the frequency doubling, so the image component levels of the modulated signals are low. When the modulator was implemented on a single chip by using Si-bipolar process technology with a cutoff frequency of 40 GHz, the image ratio at a carrier frequency of 5 GHz was less than -34 dBc     

A new robust capacitively coupled second harmonic quadrature LC oscillator

A study of some reported superharmonic LC quadrature voltage-controlled oscillator (LC-QVCO) is performed in which it is shown that robustness of the quadrature oscillation varies depending on the coupling configuration. Next, a new superharmonic LC-QVCO is proposed in which the common source node in either of two identical cross-connected LC-VCOs is coupled via a capacitor to the node common between the two varactors in the LC-tank of the other LC-VCO. As a result of connecting common mode nodes, the currents flowing through the two coupling capacitors are comprised of only the even harmonics. In the proposed coupling configuration there exists a closed loop through which the second harmonic signals circulate. A qualitative argument is presented to justify the robustness of the quadrature nature of the proposed QVCO by applying the Barkhausen phase criterion to the second harmonic signals in the loop. Since the coupling devices are only two capacitors, no extra noise sources and power consumption are added to the core VCOs. A Monte-Carlo simulation showed that the phase error of the proposed QVCO caused by device mismatches is no more than 1°. Also, generalizing this method to several numbers of VCOs in a loop, multiphase signals can be generated. The proposed circuits were designed using a 0.18-μm RF CMOS technology and simulation results are presented.     

基于MEMS方块谐振器的10 MHz振荡器

方块谐振器的品质因数(Q)很高,但是插入损耗也很大。为了得到低相噪的微机电系统(MEMS)振荡器,需要进一步提高方块谐振器的Q值,降低谐振器的插入损耗。通过支撑梁位置的合理设计可以达到极小的锚点损耗,从而实现非常高的品质因数。采用二阶面切变模态方块谐振器的设计方法,表现出了很多的优越性：Q值更高,动态电阻更小(在间隙为0.25 μm时达到82.1 Ω)。基于这种新型谐振器设计出的振荡器实现的相位噪声为：–156 dBc/Hz@1 kHz。