Showing papers on "Precision rectifier published in 2006"

A 950-MHz rectifier circuit for sensor network tags with 10-m distance

Abstract: This paper presents a 950-MHz wireless power transmission system and a high-sensitivity rectifier circuit for ubiquitous sensor network tags. The wireless power transmission offers a battery-life-free sensor tag by recharging the output power of a base station into a secondary battery implemented with the tag. For realizing the system, a high-sensitivity rectifier with dynamic gate-drain biasing has been developed in a 0.3-/spl mu/m CMOS process. The measurement results show that the proposed rectifier can recharge a 1.2-V secondary battery over -14-dBm input RF power at a power conversion efficiency of 1.2%. In the proposed wireless system, this sensitivity corresponds to 10-m distance communication at 4-W output power from a base station.

Piezoelectric micro-power generation interface circuits

Abstract: New power conversion circuits to interface to a piezoelectric micro-power generator have been fabricated and tested. Circuit designs and measurement results are presented for a half-wave synchronous rectifier with voltage doubler, a full-wave synchronous rectifier and a passive full-wave rectifier circuit connected to the piezoelectric micro-power generator. The measured power efficiency of the synchronous rectifier and voltage doubler circuit fabricated in a 0.35-/spl mu/m CMOS process is 88% and the output power exceeds 2.5 /spl mu/W with a 100-k/spl Omega/, 100-nF load. The two full-wave rectifiers (passive and synchronous) were fabricated in a 0.25-/spl mu/m CMOS process. The measured peak power efficiency for the passive full-wave rectifier circuit is 66% with a 220-k/spl Omega/ load and supplies a peak output power of 16 /spl mu/W with a 68-k/spl Omega/ load. Although the active full-wave synchronous rectifier requires quiescent current for operation, it has a higher peak efficiency of 86% with an 82-k/spl Omega/ load, and also exhibits a higher peak power of 22 /spl mu/W with a 68-k/spl Omega/ load which is 37% higher than the passive full-wave rectifier.

Hybrid rectenna and monolithic integrated zero-bias microwave rectifier

Abstract: In this study, we have developed a hybrid sensitive rectenna (rectifier + antenna) system at 2.45 GHz. To achieve this system, we have first optimized and validated a zero-bias microwave sensitive rectifier using commercial Schottky diodes. We have then optimized and achieved a 2times2 patch antenna array, which is associated to the microwave rectifier in order to validate the rectenna system, where an RF-dc conversion efficiency of 56% has been observed experimentally. In order to minimize the rectenna dimensions, we have conducted a study using the OMMIC ED02AH 0.20-mum GaAs pseudomorphic high electron-mobility transistor process to develop and achieve a monolithic rectifier at 2.45 GHz with RF-dc conversion efficiency of 65%

Differential Mode Input Filter Design for a Three-Phase Buck-Type PWM Rectifier Based on Modeling of the EMC Test Receiver

Abstract: For a three-phase buck-type pulsewidth modulation rectifier input stage of a high-power telecommunications power supply module, a differential-mode (DM) electromagnetic compatibility (EMC) filter is designed for compliance to CISPR 22 Class B in the frequency range of 150 kHz-30 MHz. The design is based on a harmonic analysis of the rectifier input current and a mathematical model of the measurement procedure including the line impedance stabilization network (LISN) and the test receiver. Guidelines for a successful filter design are given, and components for a 5-kW rectifier prototype are selected. Furthermore, formulas for the estimation of the quasi-peak detector output based on the LISN output voltage spectrum are provided. The damping of filter resonances is optimized for a given attenuation in order to facilitate a higher stability margin for system control. Furthermore, the dependence of the filter input and output impedances and the attenuation characteristic on the inner mains impedance are discussed. As experimentally verified by using a three-phase common-/Differential-Mode separator, this procedure allows accurate prediction of the converter DM conducted emission levels and therefore could be employed in the design process of the rectifier system to ensure compliance to relevant EMC standards

Switch mode power supply controllers

Abstract: This invention relates to SMPS controllers employing primary side sensing. We describe a system for identifying a knee point in a sensing waveform, at which the output voltage of the SMPS may be sampled accurately on the primary side. The system identifies the knee point by fitting a tangent to a portion of a power transformer voltage waveform, and samples the voltage waveform at the knee point to determine the SMPS output voltage. In preferred embodiments this technique is implemented using a decaying peak detector, providing a timing signal indicating detection of the knee point. Sample/hold and error amplifier circuits may be employed to achieve output voltage regulation.

A Novel Variable Hysteresis Band Current Control of Three-Phase Three-Level Unity PF Rectifier With Constant Switching Frequency

Abstract: A Simple and novel variable hysteresis band current control technique for three-phase three-level unity power factor (PF) rectifier is proposed in this paper. The hysteresis band is controlled as variations of the rectifier input voltage and output dc link voltage to achieve constant switching frequency at any operating conditions, i.e., at rated and below and above the rated conditions. The rectifier has the characteristic of easy implementation, and draws a nearly sinusoidal current at unity input PF. Theoretical and predicted results of its analysis are verified initially through digital simulation, and confirmed by using an experimental prototype

Full-wave rectifier realization using only two CCII+s and NMOS transistors

Abstract: In this paper, a voltage-mode full-wave rectifier employing plus-type second-generation current conveyors (CCII+s) and enhancement-mode n-channel metal-oxide semiconductor field-effect transistors (MOSFETs) is proposed. The presented circuit requires no passive components, and is suitable for high frequency applications. The proposed full-wave rectifier circuit is simulated using HSPICE to verify the theoretical analysis.

Transformer-isolated flyback converters and methods for regulating output current thereof

Abstract: A system and method for delivering regulated power and current to an output load has a flyback transformer having a primary winding and a secondary winding. The secondary winding delivers stored energy to the output load. An oscillator circuit is provided for generating a periodical signal. A switching circuit is coupled to the flyback transformer and the oscillator circuit for energizing the primary winding to a reference current level each cycle of the oscillator circuit. The oscillator circuit has an integrator for deriving a time integral of a voltage at the primary winding. The oscillator circuit has a peak detector coupled to the integrator for holding a peak value of the time integral. The oscillator circuit further has a ramp generator for producing a ramp signal. A comparator is provided for comparing the peak value with the ramp signal and generating the periodical signal whenever the ramp signal exceeds the peak value.

Solid state led bridge rectifier light engine

Abstract: A solid-state light engine comprised of light emitting diodes (LEDs) configured into a bridge rectifier with a current limiting module coupled to the LED bridge rectifier. The light engine may be packaged for high temperature operation. Optionally, the LEDs comprise wavelength-converting phosphors with a persistence that is a multiple of the peak to peak current period, to smooth and mask ripple frequency pulsation of emitted light.

Bipolar Microwave RMS Power Detectors

Abstract: A peak/RMS power detector with ges40 dB dynamic range is presented. The simulated frequency response is flat to 60GHz and the measured response is flat to 20 GHz. Analysis shows that the Meyer detector, originally developed as a peak detector, can be used for RMS detection with an error less than 0.5dB over an approximately 20 dB range, comparable to the popular RF/microwave diode detector. The range for RMS detection is extended by cascading several stages of attenuators and detectors, leading to a circuit suitable for applications such as embedded RFIC test. The power detector is only 700times550 mum2 including all AC and DC bond pads

Switching-mode power supply having a synchronous rectifier

Abstract: A DC-to-DC converter incorporates a transformer having a primary winding connected to a pair of DC input terminals via an active switch, which turns on and off under the control of a feedback circuit, and a secondary winding connected to a pair of DC output terminals via a synchronous rectifier and a smoothing capacitor. The synchronous rectifier is a parallel connection of a synchronous rectifier switch and a diode. A synchronous rectifier control circuit is connected to the synchronous rectifier switch for causing conduction therethrough while the active switch is off. The synchronous rectifier control circuit comprises a capacitor for determination of the conducting periods of the synchronous rectifier switch, and a logic network for on/off control of the synchronous rectifier switch according to whether the active switch is on or off and whether the capacitor voltage is higher than a predefined threshold or not.

A new single-phase ZCS-PWM boost rectifier with high power factor and low conduction losses

Abstract: This paper proposes a new single-phase high-power-factor rectifier, which features regulation by conventional pulsewidth modulation (PWM), soft commutation, and instantaneous average line current control. A new zero-current switching PWM (ZCS-PWM) auxiliary circuit is configured in the presented ZCS-PWM rectifier to perform ZCS in the active switches and zero-voltage switching (ZVS) in the passive switches. Furthermore, soft commutation of the main switch is achieved without additional current stress by the presented ZCS-PWM auxiliary circuit. A significant reduction in the conduction losses is achieved because of the following reasons: 1) the circulating current for the soft switching flows only through the auxiliary circuit; 2) a minimum number of switching devices are involved in the circulating current path; and 3) the proposed rectifier uses a single converter instead of the conventional configuration composed of a four-diode front-end rectifier followed by a boost converter. Seven transition states for describing the behavior of the ZCS-PWM rectifier in one switching period are described. The PWM-switch model is used to predict the system performance. A prototype rated at 1 kW, operating at 60 kHz, with an input alternating current voltage of 220 V/sub rms/ and an output voltage of 400 V/sub dc/, has been implemented in laboratory. An efficiency of 98.3% and a power factor over 0.99 have been measured. Analysis, design, and the control circuitry are also presented in this paper.

Zero voltage zero current switching converter

Abstract: A power converter circuit includes an input switching circuit, an isolation circuit, a rectifier circuit that includes a least a pair of rectifiers, and an output circuit. The input switching circuit receives a first voltage and generates an AC voltage. The isolation circuit has a primary side configured to receive the AC voltage from the input switching circuit and a secondary side. The secondary side communicates with the rectifier circuit and the output circuit. The output circuit includes a secondary inductor and a diode. The secondary inductor communicates with a primary inductor and either the rectifier circuit or the secondary side. The diode communicates with the primary inductor, the secondary inductor, and the rectifier circuit. The secondary inductor inhibits current flow through the rectifier circuit and forces current flow through the diode when no voltage is applied to the primary side of the isolation circuit.

DC-DC flyback converter having a synchronous rectification self-driven circuit

Abstract: A DC-DC flyback converter, includes a three-winding transformer; a primary power circuit having a first MOSFET connected to a first winding of the transformer; a secondary power circuit connected to a second winding of the transformer terminals; and a self-driven circuit connected to a third winding of the transformer. The secondary power circuit includes a synchronous rectifier in the form of a second MOSFET and the self-driven circuit further includes a delay drive circuit, an isolation differential circuit, a negative removal circuit having a third MOSFET and a synchronous rectifier trigger switch-off circuit for switching the synchronous rectifier to an off condition.

Bipolar microwave RMS power detectors

Abstract: A peak/RMS power detector with > 40 dB dynamic range is presented. The simulated frequency response is flat to 60 GHz and the measured response is flat to 20 GHz. Analysis shows that the Meyer detector, originally developed as a peak detector, can be used for RMS detection with an error less than 0.5 dB over an approximately 20 dB range, comparable to the popular RF/microwave diode detector. The range for RMS detection is extended by cascading several stages of attenuators and detectors, leading to a circuit suitable for applications such as embedded RFIC test. The power detector is only 700 x 550 μm 2 including all AC and DC bond pads.

Programmable PFC based hybrid multipulse power rectifier for ultra clean power application

Abstract: A novel hybrid three-phase rectifier is proposed. It is capable to achieve high input power factor (PF) and low total harmonic input currents distortion (THD/sub I/). The proposed hybrid high power rectifier is composed by a standard three-phase six-pulse diode rectifier (Graetz bridge) with a parallel connection of single-phase Sepic rectifiers in each three-phase rectifier leg. Such topology results in a structure capable of programming the input current waveform and providing conditions for obtaining high input power factor and low harmonic current distortion. In order to validate the proposed hybrid rectifier, this work describes its principles, with detailed operation, simulation, experimental results, and discussions on power rating of the required Sepic converters as related to the desired total harmonic current distortion. It is demonstrated that only a fraction of the output power is processed through the Sepic converters, making the proposed solution economically viable for very high power installations, with fast investment payback. Moreover, retrofitting to existing installations is also feasible since the parallel path can be easily controlled by integration with the existing dc-link. A prototype has been implemented in the laboratory and it was fully demonstrated to both operate with excellent performance and be feasibly implemented in higher power applications.

Single-stage electronic ballast with class-E rectifier as power-factor corrector

Abstract: A single-stage high-power-factor electronic ballast with a Class-E rectifier as a power-factor corrector is proposed. A Class-E rectifier is inserted between the front-end bridge rectifier and the bulk filter capacitor to increase the conduction angle of the bridge-rectifier diode current for obtaining low line-current harmonics. The Class-E rectifier is driven by a high-frequency sinusoidal current source, which is obtained from the square-wave output voltage of the Class-D inverter through an LC series resonant circuit. A high-frequency transformer is used for impedance matching. The experimental results for a 32-W prototype ballast are given. The switching frequency was 61.3 kHz. At full power, the power factor was 0.992 and the total ballast efficiency was 88.3%. The lamp-current crest factor was about 1.36. The simulated and experimental results were in very good agreement.

Space Vector Modulation Control of an AC–DC–AC Converter With a Front-End Diode Rectifier and Reduced DC-link Capacitor

Abstract: In this paper, the control of an ac-dc-ac converter with a front-end diode rectifier and reduced dc-link capacitor based on the space vector modulation strategy is investigated. The modulation index is time-varying and determined by the instantaneous value of the dc voltage measured by a voltage sensor. Using a small bipolar capacitor, instead of a large electrolytic capacitor on the dc-link, increases the lifetime of the converter and reduces its size. The input current quality of this converter has been shown to be superior to that of the conventional ac-dc-ac converter with front-end diode rectifier. The perfectly sinusoidal local average output voltage can still be achieved under unbalanced input voltage condition by implementing a time-varying modulation index. The rule for determining the dc capacitance has also been studied in this paper. The simulation results obtained from PSIM simulation software and experimental results obtained from the lab prototype are used to verify the theoretical expectations

A Simple, Passive 24-Pulse AC–DC Converter With Inherent Load Balancing

Abstract: A new converter topology for a three-phase multipulse rectifier circuit is described. This converter draws almost sinusoidal currents from the ac system with very low harmonic content and typically less than 3% total harmonic distortion. The topology uses only passive components and has a lower component count than other rectifier circuits with similar performance. Two six-pulse rectifier bridges are connected in series, fed by a series connection of transformers, to form a 12-pulse system. An additional low power harmonic injection circuit enhances the performance of the circuit to obtain low harmonic current pollution levels that are comparable with those achieved from a 24-pulse rectifier. The circuit operation is explained and experimental results are presented.

Comparison of current doubler rectifier and center tapped rectifier for low voltage applications

Abstract: It is well known that the current doubler rectifier is very suitable for low voltage (1V-2V) and very high current (50A-100A) dc-dc converters. However, at lower current applications (30A, 20A, 10A), it is not clear which is the more appropriate rectifier the current doubler or the center tapped. The goal of this paper is to identify the application area of these rectifiers. The output current together the output current ripple/output current ratio (/spl Delta/I/I/sub O/) are important parameters to select the more suitable rectifier.

Direct Power Control System of Three Phase Boost Type PWM Rectifiers

Abstract: This paper establishs the power control mathematical model of rectifier based on the mathematical model of three phase boost type PWM rectifier in synchronous dq coordinates. According to the power control mathematical model, the paper proposes a new design method of filter inductance in AC side , voltage and capacitance in DC side of main circuit for three phase boost type PWM rectifier by combining with the features of direct power control(DPC) system. Based on the models of rectifier, the control structure of rectifier DPC system and the design method of controller is obtained. Meanwhile, the paper discusses the influence of bridge loss and equivalent series resistance(ESR) of capacitor on rectifier. The design method is proved feasible by simulation and experiment and is available for reference in engineering.

High frequency and high precision CMOS full-wave rectifier

Abstract: This paper describes a high frequency and high precision full-wave rectifier using a fully differential input and output operational transconductance amplifier (FDIO-OTA), which is very suitable for CMOS technology implementation. The system comprises a voltage to current converter, precision full-wave rectifier and a current-to-voltage converter. An input voltage signal is converted into two symmetrical current signals by using a FDIO-OTA. Two current signals will be rectified by using MOS diodes and convert into output voltage by using grounded MOS resistor. The circuit exhibits a very precise rectifier and very high operating frequency. The simulation results demonstrate the performance of the proposed circuit.

A CMOS-Control Rectifier for DiscontinuousConduction Mode Switching DC-DC Converters

Abstract: A sub-1V boost converter with a CMOS-control rectifier enables adaptive dead-time control and mV-range forward-voltage drop. This converter can operate with <0.9V input and deliver 2.5V and 250mW output with 85% efficiency and is intended for single-cell battery-powered mobile systems

A 3.125 Gb/s limit amplifier in CMOS with 42 dB gain and 1 /spl mu/s offset compensation

Abstract: A fast offset compensation method for high-gain amplifiers is presented that leverages a novel peak detector design and a dynamic, multi-tap feedback system to achieve roughly three orders of magnitude improvement in settling time over traditional compensation methods. Design tradeoffs between gain, bandwidth, power dissipation, and noise performance of the limit amplifier are discussed. Measured results of a custom 3.125 Gb/s limit amplifier in 0.18 /spl mu/m CMOS employing the proposed compensation technique demonstrate a sub-1-ms settling time while still achieving less than 4 ps rms output jitter with a 2.5 mV peak-to-peak input at 2.5 Gb/s.

Half-bridge LLC resonant converter with a synchronous rectification function

Abstract: The invention discloses a half-bridge LLC resonant converter with a synchronous rectification function that includes a first switch; a second switch; a first transformer; a first synchronous rectifier; a second synchronous rectifier; a controller; and a second transformer. The controller of the half-bridge LLC resonant converter with a synchronous rectification function can control the first synchronous rectifier and the second synchronous rectifier directly and the connected second transformer also can control the first switch and the second switch directly. The first synchronous rectifier and second synchronous rectifier having a low conducting resistance substitute the rectifier and greatly lower the power consumption. The controller outputs a control signal to drive a transformer to output a signal to the primary winding, and its signal delay is formed by a delay of an electronic circuit and a power MOS switch of the first switch and second switch.

Dc/dc converter and controller thereof

Abstract: A DC/DC converter for driving a load is provided. The DC/DC converter includes an inductor, a switch, a capacitor and a rectifier element. The switch and the inductor are coupled in series between a first common level and a second common level. The capacitor and the rectifier element are coupled in series between the first and second terminal of the switch or the inductor. The load is coupled between a coupling point of the capacitor and rectifier element and the second common level, wherein the coupling point of the capacitor and rectifier element outputs an output voltage to drive the load. A control terminal of the switch is switched between open circuit state and short circuit state according to a control signal.

An analog signal processing ASIC for a small animal LSO–APD PET tomograph

Abstract: MADPET-II is a small animal PET scanner currently under development that provides individual readout for each one of its 1152 LSO–APD electronic channels. In order to process such a large number of channels individually, the analog signal processing electronics are fully integrated into monolithic chips. Each chip contains four independent differential receivers, shaping amplifiers, peak hold detectors and non-delay line constant-fraction discriminators (CFDs). The CFDs use a high-pass CR circuit rather than the conventional delay line to generate a bipolar pulse. The performance of the chip has been tested for walk, jitter and pulse height linearity by studying the peak detector and the CFD signals, and has been optimized by adjusting the corresponding bias currents so as to maximize the signal-to-noise ratio and to minimize the walk of the CFD output (trigger). The response of the peak detector to different input signal amplitudes is linear ( R 2 = 0.99945 ± 0.00002 ) . The walk performance of the CFD can be adjusted by changing the offset of the CR high-pass filter output signal, and can be minimized to approximately 2 ns over a 5:1 input amplitude dynamic range.

Minimizing Current Distortion of a Three-Phase Bridge Rectifier Based on Line Injection Technique

Abstract: This paper demonstrates a new concept and a novel passive resonant construction, which is connected between the ac and dc sides of the three-phase bridge rectifier, for reducing line current harmonics. This resonant net connection, in combination with the conduction intervals of each diode, generates a circulating third harmonic current between the ac and dc sides of the diode rectifier. This will cause a significant reduction in line current harmonics. As a result of this, the shape of line current becomes nearly sinusoidal. Results of analytical, simulation, and experimental verification on a typical example are presented. The total harmonic distortion (THD) of the line current can be reduced from 32% to 5%. Therefore, based on this concept a very cheap, lossless, and passive rectifier with low THD and almost unity power factor has been developed

RFID system and RFID chip equipped with sensor function

Abstract: An integrated circuit chip includes a rectifier circuit configured to convert an alternating voltage supplied from an antenna into a direct-current voltage, a nonvolatile memory coupled to the rectifier circuit to operate by use of the direct-current voltage, a sensor circuit coupled to the rectifier circuit to operate by use of the direct-current voltage to collect measurement data, and a logic circuit configured to control the nonvolatile memory and the sensor circuit such that an access operation of the nonvolatile memory and a data collecting operation of the sensor circuit are not performed concurrently.

Energy Harvesting Using Frequency Rectification

Abstract: An energy harvesting apparatus (1) includes an energy frequency rectification structure (5) to receive mechanical energy and a first frequency, and a solid-state electromechanical transducer (3) coupled to the inverse frequency rectifier (5) to receive a force provided the inverse frequency rectifier (5) The force, when provided by the inverse frequency rectifier (5), causes the solid-state transducer (3) to be subjected to a second frequency that is higher than the first frequency to thereby generate electromechanical power.