A wide-band feedforward amplifier

The design of a wide-band feedforward amplifier in the frequency range 30-300 MHz is described. Expressions are derived for feedforward amplifier sensitivity, and the effect of imperfect loop cancellation is described. The effect of circuit imbalance on gain and terminal impedances is investigated. The circuit is realized in thin-film hybrid form, and measurements show 20 dB of distortion improvement at 300 MHz. Practical aspects of circuit adjustment and operation are considered.     

前馈系统中辅助放大器非线性分析

前馈系统中由于信号对消环路失配,导致在辅助功放输入端载波信号无法完全对消,辅助放大器的再次非线性失真会影响整个系统的失真。本文研究了残余载波信号再次产生的互调失真对整个系统线性化指标的影响,并给出了系统性能与电路参数和幅度、相位失配的关系式,通过这个关系式可以计算出要达到特定载波互调比时所需器件的最低指标要求。     

CDMA射频线性功率放大器

该文对前馈线性校正射频功率放大器进行了分析,给出了分析结果。并用该结果指导设计了CDMAIS-95基站射频线性功率放大器,放大器增益47dB,连续波输出功率60W,在通频带内三阶交调改善了23dB。     

Gain/phase imbalance cancellation technique in LINC transmitters

A new technique for correcting the gain/phase imbalance in LINC transmitters is presented. The technique employs a feedback signal to generate an error signal, consisting mainly of intermodulation distortion. A direct search method is used to optimise the gain/phase imbalance for correction. An out-of-band radiation suppression of 10 dB was achieved using a signal processing workstation simulation package     

A Wide-Band Phase-Feedback Inverse-Sine Phase Modulator with Application Toward a LINC Amplifier

A wide-band inverse-sine phase modulator is demonstrated. The modulator has application in a LINC amplifier for linear amplification at microwave frequencies using commonly available saturating amplifiers or injection-locked oscillators. A bandwidth greater than 10 MHz at a carrier frequency of 96 MHz with distortion products 40 dB or greater below desired components has been shown. The distortion behavior as a second-order effect of the loop delay as predicted by analysis has been verified. The output of the inverse-sine phase modulator and its conjugate, generated by a second phase modulator, were subtracted as in a LINC amplifier, to provide at least 40-dB suppression of the zeroth order and even-order components.     

Linear distortion correction using a feedforward system

The application of the feedforward amplifier linearization technique to the removal of both harmonic and intermodulation distortions is well understood and has been discussed in the literature. An additional benefit of the feedforward technique, which has received relatively little attention, is that of so-called linear distortion removal. Linear distortion is a term used to describe the nonideal gain and phase response (e.g., frequency response ripple) present in all practical amplifiers, and it is possible to significantly improve these parameters, in a practical application, using the feedforward technique. This paper discusses the improvements in this area, which may be achieved by utilizing the feedforward technique, demonstrates mathematically how they arise, and presents both simulation and practical results to demonstrate the effect for various types of gain and phase response nonlinearity     

Predistorted LINC transmitter

A LINC transmitter exhibits memoryless amplitude dependent distortion characteristics when gain/phase imbalances are present between the two amplifier branches. Simulation results show that using a complex gain predistorter can correct for the gain/phase imbalances and significantly reduce interference in adjacent channels     

Cascomp feedforward error correction in high speed amplifier design

The authors discuss practical implications of cascomp feedforward error correction in high-performance transconductance amplifier design and a method of extending cascomp's thermal distortion cancellation to include overdriven or common-mode inputs. The authors also briefly describe a new low-power highly integrated vertical deflection system IC using the improved cascomp that approaches the gain accuracy and thermal distortion of highly degenerated feedback designs while retaining the good overdrive recovery and speed of simple cascode differential pairs.     

On the performance of Cartesian feedback and feedforward linearization structures operating at 28 GHz

Some performance results of the Cartesian feedback and feedforward linearization techniques applied to a class-A power amplifier operating at 28 GHz are presented. The performance of the combination of HMMC-5040 (driver) and HMMC-5033 (power amplifier) is used as benchmark for simulation analysis. This analysis is addressed to show the key aspects on spectral regrowth due to phase margin and loop gain for Cartesian feedback, and time delay, phase and gain mismatch for feedforward. A 16 QAM digital signal at 10 Mbits/s filtered with a squared raised cosine filter with /spl alpha/=0, 25 is used as test signal.     

Useful Characteristics for Controlling the Cancellation Performance and Center Frequency of a Linearization Loop

The cancellation performance of a linearization loop is limited by the degree of an amplitude imbalance and a phase imbalance. A delay mismatch causes a phase variation as a function of frequency. Therefore, the cancellation performance and linearization bandwidth are limited by a delay mismatch. The expression for the effects of an amplitude imbalance, a phase imbalance, and a delay mismatch on the characteristics of a linearization loop is derived and analyzed. The simulation results are compared with the results obtained by means of using a commercial simulation tool and the exact agreement is reported. The derived equation could be used in designing a linearization loop and predicting the cancellation performance of the linearization loop usefully. Some useful characteristics, known from the simulation results obtained by using the derived equation, of a linearization loop for designing and implementing feedforward amplifiers are described in detail.     

掺铒非线性光纤环镜中增益带宽对超短光孤子放大的影响

根据宽带脉冲的特点,建立了描述宽带脉冲放大的理论模型,并同时用数值方法研究了超短孤子在掺铒非线性光纤环镜中的放大.计算结果表明,当输入脉冲的频谱宽度和增益带宽相接近时,超短光孤子的波形和频谱产生畸变,放大效率降低,使得输出脉冲不再具有孤子特性.而这种影响可以通过优化不同增益带宽的ED-NALM中环的长度来消除.     

Impact of second harmonic injection on the linearity and linear gain of RF/microwave amplifiers

This article reviews the development and applications of harmonic injection technique. It discusses the impact of second harmonic injection on the linearity and linear gain of amplifiers. It reveals that amplifier characteristics and input drive level determine whether second harmonic injection enhances or reduces the linear gain of an amplifier. Furthermore, a method has been developed to predict this behaviour which can be used to identify amplifiers that are best suited to harmonic injection or build amplifiers that may particularly be used with harmonic injection. For experimental investigation, a second harmonic injected amplifier was used that employs a frequency-doubler. In laboratory experiments, third-order intermodulation distortion was suppressed by 18?dB at the expense of 0.7?dB linear gain whereas theoretical analysis has predicted that second harmonic injection could compromise the linear gain of the amplifier by up to 1.3?dB for 20?dB distortion suppression.     

基于最小电流选择的运算放大器设计

设计了一种工作电压为3V恒跨导满幅CMOS运算放大器,针对轨对轨输入级中存在的跨导不恒定和简单AB类输出级性能偏差这2个问题,提出了利用最小电流选择电路来稳定输入级的总跨导;浮动电流源控制的无截止前馈AB类输出级实现了运放的满幅输出,同时减小了交越失真。该电路通过HSpice进行仿真验证,在0～3V输入共模范围内,输入级跨导的变化小于3.3%,开环增益为93dB,单位增益带宽为8MHz,相位裕量为66°。     

A 5-GHz 20-dBm Power Amplifier With Digitally Assisted AM-PM Correction in a 90-nm CMOS Process

This paper presents an integrated CMOS power amplifier and a technique for correcting AM-PM distortion in power amplifiers. The linearization technique uses a varactor as part of a tuned circuit to introduce a phase shift that counteracts the AM-PM distortion of the power amplifier. The varactor is controlled by the amplitude of the IQ baseband data in a feedforward fashion. The technique has been demonstrated in a 5-GHz class-AB CMOS power amplifier designed for WLAN applications and implemented in a 90-nm CMOS process. The power amplifier delivers 16 dBm of average power while transmitting at 54 Mb/s (64 QAM). The proposed linearization technique is shown to improve the efficiency of the power amplifier by a factor of 2.8.     

An analytic approach for CDMA output of feedforward power amplifier

In this paper, a novel method is introduced to predict the Code-Division Multiple-Access (CDMA) output spectrum of an RF power amplifier linearized with feedforward technique based on transfer function. In this method, an RF power amplifier is modeled mathematically by nonlinear complex envelope transfer function based on AM-AM and AM-PM distortion diagrams. Using this model, analytic expressions of CDMA output spectrum of power amplifier is calculated. Having mathematical model of RF power amplifier leads to derive analytic expressions for InterModulation (IM) products in feedforward amplifier. Based on these expressions, IM products are related to nonlinear complex envelope transfer function of feedforward amplifier. Then, CDMA output spectrum of feedforward linearization technique is predicted. The loops imbalances in feedforward technique are considered in analysis. Finally, the results of derived expressions in MATLAB software are compared with ADS simulations results and good agreements were achieved. Employing this method gives insight for feedforward analysis and loops imbalances effects in feedforward amplifier for CDMA applications.     

An adaptive digital method of imbalances cancellation in LINC transmitters

The linear amplification using nonlinear components (LINC) technique is a well-known power amplifier linearization method to reduce adjacent channel interference in a nonconstant envelope modulation system. Its major drawback is the inherent sensitivity to gain and phase imbalances between the two amplifier branches. In this paper, a novel full-digital base band method is described which corrects any gain and phase imbalances in LINC transmitters mainly due to the unmatching of the two amplifier paths. Amplifiers are characterized by a level-dependent complex gain using a memoryless model. The method uses adaptive signal processing techniques to obtain the optimal complex coefficient to adjust gain and phase imbalances. Its main advantage is the ability to track the input signal variations and adapt to the changes of amplifier nonlinear characteristics. Other effects are included in the analysis such as quadrature modulator and demodulator imbalances and loop delay. A computer simulation has been carried out to verify the method functionality.     

A robust feedforward compensation scheme for multistage operational transconductance amplifiers with no Miller capacitors

A multistage operational transconductance amplifier with a feedforward compensation scheme which does not use Miller capacitors is introduced. The compensation scheme uses the positive phase shift of left-half-plane (LHP) zeroes caused by the feedforward path to cancel the negative phase shift of poles to achieve a good phase margin. A two-stage path increases further the low frequency gain while a feedforward single-stage amplifier makes the circuit faster. The amplifier bandwidth is not compromised by the absence of the traditional pole-splitting effect of Miller compensation, resulting in a high-gain wideband amplifier. The capacitors of a capacitive amplifier using the proposed techniques can be varied more than a decade without significant settling time degradation. Experimental results for a prototype fabricated in an AMI 0.5-/spl mu/m CMOS process show DC gain of around 90 dB and a 1% settling time of 15 ns for a load capacitor of 12 pF. The power supply used is /spl plusmn/1.25 V.     

Second-order distortion generated by amplification ofintensity-modulated signals with chirping in erbium-doped fiber

A rate equation analysis for second-order distortion generated in an erbium-doped fiber amplifier is reported. It is shown that the relevant mechanism of distortion is the interaction between the frequency chirping of input light and the local gain tilt in the erbium-doped fiber. It is found that the output light distortion is highly affected by the phase difference between the input light distortion and the chirping-induced distortion. This indicates that second-order distortion is not always degraded by erbium-doped fiber amplifiers     

A wide-band ultralinear amplifier from 3 to 300 MHz

The design of a low-distortion, wide-band amplifier with 75-/spl Omega/ input and output impedances is described. Simultaneous shunt and series feedback is used and design equations are derived for terminal impedances, forward gain, loop gain, and noise figure. The advantages of a Darlington connection for low distortion are described. For 0-dBm signal levels, the amplifier achieves third-order intermodulation products of -88 dB relative to the carrier at 300 MHz and 12 channel cross-modulation (CM) of -77 dB at channel 13.