A low phase noise and low power 3–5 GHz frequency synthesizer in 0.18 µm CMOS technology

A low power frequency synthesizer for WLAN applications is proposed in this paper. The NMOS transistor-feedback voltage controlled oscillator (VCO) is designed for the purpose of decreasing phase noise. TSPC frequency divider is designed for widening the frequency range with keeping low the power consumption. The phase frequency detector (PFD) with XOR delay cell is designed to have the low blind and dead zone, also for neutralizing the charge pump (CP) output currents; the high gain operational amplifier and miller capacitors are applied to the circuit. The frequency synthesizer is simulated in 0.18 µm CMOS technology while it works at 1.8 V supply voltage. The VCO has a phase noise of −136 dBc/Hz at 1 MHz offset. It has 10.2% tuning range. With existence of a frequency divider in the frequency synthesizer loop the output frequency of the VCO can be divided into the maximum ratio of 18. It is considered that the power consumption of the frequency synthesizer is 4 mW and the chip area is 10,400 µm².     

CMOS analogue current-mode multiplier/divider circuit operating in triode-saturation with bulk-driven techniques

A CMOS analogue current-mode multiplier/divider circuit is presented. It is based on a dynamic biasing applied at the bulk terminal of MOS transistors operating in both saturation and triode. With the proposed structure, the multiplier forms a feedback loop that improves the current swing and accuracy. The multiplier has been fabricated using a standard 0.18 µm CMOS technology. The circuit consumes 144 µW using a single supply voltage of 1.8 V with a measured THD lower than 1% for an output current of 38 µA, and requires a die area of 90 µm x 45 µm.     

MISO current mode bi-quadratic filter employing high performance inverting second generation current conveyor circuit

This paper presents static and dynamic studies of a new CMOS realization for the inverting second generation current conveyor circuit (ICCII). The proposed design offers enhanced functionalities compared to ICCII circuits previously presented in the literature. It is characterized by a rail to rail dynamic range with high accuracy, a low parasitic resistor at terminal X (1.6 Ω) and low power consumption (0.31 mW) with wide current mode (3.32 GHz) and voltage mode (3.9 GHz) bandwidths.Furthermore, a new MISO current mode bi-quadratic filter based on using ICCII circuits as active elements is proposed. This filter can realize all standard filter responses without changing the circuit topology. It is characterized by active and passive sensitivities less than unity and an adjustment independently between pole frequency and quality factor. The operating frequency limit of this filter is about 0.8 GHz with 0.674 mW power consumption.The proposed current conveyor circuits and bi-quadratic filter are tested by TSPICE using CMOS 0.18 µm TSMC technology with ±0.8 V supply voltage to verify the theoretical results.     

Dual-resonance concurrent oscillator

This paper studies a new dual-band CMOS class-C voltage-controlled oscillator (VCO). The oscillator consists of a dual-resonance LC resonator in shunt with two pairs of capacitive cross-coupled nMOSFETs. The proposed oscillator has been implemented with the TSMC 0.18 μm CMOS technology, and it shows a frequency tuning range with two frequency bands and a small tuning hysteresis is measured. The oscillator can generate differential signals at 2.4 GHz and 6.9 GHz and it also can generate concurrent frequency oscillation while the circuit is biased around the bias with frequency tuning hysteresis. With the supply voltage of V_DD = 1.1 V, the VCO-core current and power consumption of the oscillator are 2.90 mA and 3.19 mW, respectively. The die area of the class-C oscillator is 0.9 × 0.97 mm². Overvoltage stress is applied to the oscillator, measurement indicates the concurrent oscillation is sensitive to overvoltage stress.     

A low-power rail-to-rail input-range linear delay element circuit

Delay elements are one of the key components in many time-domain circuits such as time-based analog-to-digital converters. In this paper, a new rail-to-rail current-starved delay element is proposed which not only presents good linearity for the voltage-delay curve over the input range of ground to supply voltage, but also it consumes a dynamic power only during the transition times without consuming any static power. The proposed delay element is designed and simulated in a 0.13-µm CMOS technology with a supply voltage of 1.2 V. Post-layout simulation results demonstrate that the proposed circuit has a linear voltage-delay transfer function with a voltage-to-time gain of −1.33 ps/mV. Moreover, when samples of a full-scale sin-wave input signal are applied to the proposed circuit with a clock frequency of 100 MHz, the power consumption is 30 µW, and signal-to-noise-and-distortion ratio (SNDR) of the output delay times is 30.4 dB, making it suitable for use in a time-based analog-to-digital converter with up to 5-bit resolution.     

A new CMOS differential current-mode AGC on the division operation based

A new CMOS differential current-mode AGC on the division operation based is presented. The operation principle consists in detection of both positive and negative envelopes of the differential input signal cycles, respectively. The output signal with constant magnitude is obtained by dividing the differential input signal to the difference between the positive and negative detected envelopes. The new current-mode architecture of the proposed AGC (composed only by an envelope detector and a divider stage) diminishes significantly the settling time, the circuit complexity and the power consumption. The circuit yields an input dynamic range of 15 dB and provides a constant magnitude output signal in the frequency range from 10 MHz to 70 MHz. The current consumption is 5 mA from a single 3.3 V supply voltage. The simulations performed in 0.13 µm CMOS process confirm the theoretically obtained results.     

Sub-1 V,pico-watt subthreshold CMOS voltage reference circuit with dual temperature compensation

A pico-watt CMOS voltage reference is developed using an SK Hynix 0.18 µm CMOS process. The proposed architecture is resistorless and consists of MOSFET circuits operated in the subthreshold region. A dual temperature compensation technique is utilized to produce a near-zero temperature coefficient reference output voltage. Experimental results demonstrate an average reference voltage of 250.7 mV, with a temperature coefficient as low as 3.2 ppm/°C for 0 to 125 °C range, while the power consumption is 545 pW under a 420 mV power supply at 27 °C. The power supply rejection ratio and output noise without any filtering capacitor at 100 Hz are −54.5 dB and 2.88 µV/Hz^1/2, respectively. The active area of the fabricated chip is 0.00332 mm².     

Injection locking phase rotator for Outphasing transmitter

This paper presents a novel technique of implementing the amplitude information into out-phase mapping, which is a necessary block of the high-efficiency Outphasing transmitter architecture. The proposed technique is based on using injection locking ring oscillator and switching-based control circuit to implement phase rotator. The technique is compatible with digital implementation using DSP. Since, Outphasing transmitters use switching power amplifiers, this implementation is suitable for an all-digital and adjustable transmitter implementation. The modulator system is designed using UMC130 nm CMOS technology; and is simulated at 1.8 GHz operation frequency, as it is commonly used in multiple mobile applications requiring high power levels. Simulation shows an out-phasing error of 0.41° rms, across the whole input amplitude sweep of 45 dB. The power consumption of the single phase rotator is 1.5 mW from 1.2 V supply.     

A 1.58 nW power consumption and 34.45 ppm/°C temperature coefficient bandgap reference (BGR) for subblocks of RFID tag

In this paper a bandgap reference (BGR) circuit irrespective of the temperature and the supply voltage variation with very low power consumption is proposed. The proportional to absolute temperature (PTAT) and complementary to absolute temperature (CTAT) generators of the proposed BGR, which has four cores cascaded with each other, are used in order to increase not only the output voltage, but also the output control ability for the temperature and the voltage insensitivity. To combine produced voltage from PTAT and CTAT generator, a weight combination circuit, which uses internal capacitors of transistors, is applied. Due to the fact that all of the transistors in such a topology are worked in sub-threshold region, the power consumption is significantly diminished to 1.58 nW. Also the variation of the temperature from −25 °C to 150 °C, leads to the temperature coefficient about 34.45 ppm/°C. The design simulation is done at 960 MHz frequency in TSMC 0.18 µm CMOS technology with the help of Cadence software. Also the post layout simulation result and the layout of the proposed circuit are presented. The output and the chip area of this BGR are 141.5 mV and 1387 µm² respectively.     

Floating active inductor based Class-C VCO with 8 digitally tuned sub-bands

A fully integrated floating active inductor based voltage-controlled oscillator (VCO) is presented. The active inductor employs voltage differencing transconductance amplifier (VDTA) as a building block. The designed VCO achieves frequency tuning by varying the bias current through the VDTA and utilizes a Class-C topology for improving the phase noise performance. The inductor-less VCO is designed and implemented in a 45-nm CMOS process and its performance is estimated using Virtuoso ADE of Cadence. Operating at a supply voltage of ±1 V, the proposed VCO consumes 0.44–1.1 mW corresponding to the oscillation frequency of 1.1–1.8 GHz thereby exhibiting a tuning range of 48.27%. The phase noise of the VCO lies in the range of −94.12 to −98.37 dBc/Hz at 1 MHz offset resulting in a FOM of −172.14 to −176.69 dBc/Hz.     

A low voltage and low power parallel electronically tunable resistor with linear and nonlinear characteristics

In this paper a bilateral resistive circuit is designed and presented with is work as a positive and negative electronically tunable resistor and has zero DC offset. The proposed topology is designed by paralleling two electronically tunable resistors to obtain lower resistive values and decreasing nonlinearity percent. The proposed topology is low voltage and low power and with proper transcurrent circuit, its current–voltage characteristics can be linear, expansive (square) and compressive (square root). Its supply voltages are ±1 V and its dynamic range is ±1 V too. The designed circuit is simulated in an industrial 65 nm CMOS process. The linear version is tunable over the wide resistance range of 7 kΩ–37 GΩ.     

Low-voltage low-power FGMOS based VDIBA and its application as universal filter

This paper presents Floating gate MOS (FGMOS) based low-voltage low-power variant of recently proposed active element namely Voltage Differencing Inverting Buffered Amplifier (VDIBA). The proposed configuration operates at lower supply voltage ±0.75 V with the total quiescent power consumption of 1.5 mW at the biasing current of 100 µA. Further the operating frequency of the proposed VDIBA is improved by using the resistive compensation method of bandwidth extension in Operational Transconductance Amplifier (OTA) stage of the block. By using resistive compensation method of bandwidth extension, the bandwidth of OTA stage increases from 92.47 MHz to 220.67 MHz. As an application, proposed FGMOS based VDIBA has been used to realize a novel resistorless voltage mode (VM) universal filter. The proposed universal filter configuration is capable of realizing all the standard filter functions in both inverting and non-inverting forms simultaneously without any matching constraint. Other important features include independently tunable filter parameters, cascadibility and low sensitivity figure. The proposed filter is tunable over the frequency range of 4.1 MHz to 12.9 MHz and is capable of compensating for process, voltage and temperature (PVT) variation. The simulations are performed using SPICE and TSMC 0.18 µm CMOS technology parameters with±0.75 V supply voltage to validate the effectiveness of the proposed circuit.     

A high dynamic range analog-front-end IC for electrochemical amperometric and voltammetric sensors

A wide input range, compliant with electrochemical amperometric and voltammetric sensors analog-front-end (AFE) integrated circuit (IC) is proposed. The AFE employs current integrator (CI) and trans-impedance amplifier (TIA) to deal with the input current in the order of nA and μA separately, achieving the advantage of high dynamic range and high resolution. Input voltage is converted to current through a series of precise resistances, and detected by CI or TIA, which making the input voltage range is not limited by the power supply. An incremental sigma-delta ADC is employed to digitize the transferring signal, reducing the complexity and power dissipation. Compared to other alternatives, the AFE could handle current and voltage signals simultaneously, and input voltage range is not limited by power supply, showing high dynamic range and resolution. The AFE IC is fabricated in 0.18 μm 1P5M mixed-signal CMOS process, occupies an area of 3.2 mm×2 mm, the readout circuit has a dynamic range of 120 dB, consumes 4.2 mA.     

0.4-V bulk-driven differential-difference amplifier

A new solution for an ultra-low-voltage, low-power, bulk-driven fully differential-difference amplifier (FDDA) is presented in the paper. Simulated performance of the overall FDDA for a 50 nm CMOS process and supply voltage of 0.4 V, shows dissipation power of 31.8 μW, the open loop voltage gain of 58.6 dB and the gain-bandwidth product (GBW) of 2.3 MHz for a 20 pF load capacitance. Despite the very low supply voltage, the FDDA exhibits rail-to-rail input/output swing. The circuit performance has also been tested in two applications; the differential voltage follower and the second-order band-pass filter, showing satisfactory accuracy and dynamic range.     

Improving linearity in MOS varactor based VCOs by means of the output quiescent bias point

This paper presents a CMOS based LC tank VCO topology improving the tuning range linearity. The VCO tuning range is linearized with PMOS varactors which remain in the inversion region for an extended range of the control voltage. This is achieved with the design of the quiescent operating point in the VCO's output nodes with a value close to the voltage rails, letting the varactors to behave quasi linearly in the achievable VCO tuning range. The experimental results of a VCO in a CMOS 0.35 µm process show a linear tuning range improvement of 75% of the control voltage in the (1.43–1.55) GHz range, with a minimum VCO gain variation compared to similar architectures. The results show a phase noise improvement from −94 dBc/Hz to −124 dBc/Hz @600 kHz offset from the carrier with an overall reduced amplitude noise for the VCO.     

A new ultra low-power,universal OTA-C filter in subthreshold region using bulk-drive technique

In this paper, a new ultra low-power universal OTA-C filter which can properly operate in all modes of operation (voltage, current, trans-resistance and trans-conductance) is presented. However, in order to reduce the power consumption effectively, the proposed circuit uses subthreshold transistors which are biased at I_a = 50 nA, I_b = 150 nA. Furthermore, using the bulk-drive technique leads to a reduced power consumption as well as the supply voltage of ±0.3 V. Moreover, the grounded capacitors are used to effectively reduce the parasitic effects. However, the result of sensitivity analysis shows that the proposed circuit has a very low sensitivity to the values of active and passive circuit elements such as: trans-conductance (g_m) and capacitance (C) values. Furthermore, the proposed circuit uses the minimum number of active elements to effectively reduce the power consumption as well as the chip area. Finally, the proposed filter is designed and simulated in HSPICE using 0.18µm CMOS technology parameters, while HSPICE simulation results have very close agreement with theoretical results obtained from MATLAB, which justifies the design accuracy and low-power performance of the proposed universal filter.     

A monolithic buck DC–DC converter with on-chip PWM circuit

A monolithic CMOS voltage-mode, buck DC–DC converter with integrated power switches and new on-chip pulse-width modulation (PWM) technique of switching control is presented in this paper. The PWM scheme is constructed by a CMOS ring oscillator, which duty is compensated by a pseudo hyperbola curve current generator to achieve almost constant frequency operation. The minimum operating voltage of this voltage-mode buck DC–DC converter is 1.2 V. The proposed buck DC–DC converter with a chip area of 0.82 mm² is fabricated with a standard 0.35-μm CMOS process. The experimental results show that the converter is well regulated over an output range from 0.3 to 1.2 V, with an input voltage of 1.5 V. The maximum efficiency of the converter is 88%, and its efficiency is kept above 80% over an output power ranging from 30 to 300 mW.     

RF to DC micro-converter in standard CMOS process for on-chip power harvesting applications

In this paper a radio frequency (RF) to direct current (DC) voltage converter with multi-stage rectifiers is reported for micro power conversion in RF power harvesting systems. The purpose of this paper is to select an appropriate structure for the micro power-converters, operating in high frequencies. The main idea is to convert RF range sinusoidal signals to a DC voltage to produce power for the rest of the electrical circuit or a system. The reported rectifier demonstrated an efficiency of 10% at large span of frequency for input signal of 350 mV. In the presented work, an analytical and numerical study of the micro power-converters is reported for various applications. Different design parameters have been investigated for an efficient structure design including, number of MOSs, DC current of a known load, size of MOSFETs capacitors, and frequency of the operation. Consequently, optimized parameters have been reported in order to improve the RF to DC conversion efficiency. Reported circuits were designed and simulated in 180 nm twin-well CMOS process with low threshold metal-oxide semiconductor field-effect transistors (MOSFETS); this multistage rectifier occupied an area of 0.23 mm × 0.146 mm and it produced an output voltage of 2 V at its output. This output voltage can provide the supply voltage required to operate the RFID processing circuitry. Post layout simulations demonstrated that for thirteen stages of the rectifiers, the efficiency of 10% for a capacitive load of 10 pF has been achieved.     

0.8 V PLL-based automatic frequency tuning system for current-mode filters

A wide-range automatic frequency tuning system for current-mode filters is proposed in this paper. The cutoff frequency of the tunable filter is controlled by an external reference signal and is locked in the desired frequency through a current-mode based phase locked loop (PLL) circuit. Although the PLL operates in a relatively narrow band, the total tuning range of the topology is extended by interpolating an automatic frequency detector after the reference input and before the PLL. The use of current controlled oscillator, based on same blocks with those in the filter, offers accuracy and feasible design in the control path. The topology has been simulated using MOS transistor models for a 130 nm CMOS technology in 0.8 V supply voltage. The achieved overall automatic tuning range was from 2.3 MHz to 660 MHz.     

An improved 860–960 MHz fully integrated CMOS power amplifier designation for UHF RFID transmitter

An improved design of 860–960 MHz fully integrated CMOS power amplifier (PA) for UHF RFID transmitter is presented in this paper. It utilizes three stage differential structure, including common-source structure applying RC feedback circuit to improve linearity, cascade structure adopting self-biased cascode technique and self-forward-body-bias (SFBB) technique to overcome shortcomings of low breakdown voltage and to reduce supply voltage respectively in order to obtain high output power, high efficiency and low supply voltage. By integrating these techniques organically, simulation results demonstrate that the circuit provides 21 dBm output power and 35% power-added efficiency (PAE) with 3 V supply. A comparison with other PAs operating in similar frequencies shows the proposed LNA has advantages of higher output power, higher PAE, higher linearity and lower supply voltage.