A 1.2-V RF front-end with on-chip VCO for PCS 1900 direct conversion receiver in 0.13-/spl mu/m CMOS

In this paper, a 1.2-V RF front-end realized for the personal communications services (PCS) direct conversion receiver is presented. The RF front-end comprises a low-noise amplifier (LNA), quadrature mixers, and active RC low-pass filters with gain control. Quadrature local oscillator (LO) signals are generated on chip by a double-frequency voltage-controlled oscillator (VCO) and frequency divider. A current-mode interface between the downconversion mixer output and analog baseband input together with a dynamic matching technique simultaneously improves the mixer linearity, allows the reduction of flicker noise due to the mixer switches, and minimizes the noise contribution of the analog baseband. The dynamic matching technique is employed to suppress the flicker noise of the common-mode feedback (CMFB) circuit utilized at the mixer output, which otherwise would dominate the low-frequency noise of the mixer. Various low-voltage circuit techniques are employed to enhance both the mixer second- and third-order linearity, and to lower the flicker noise. The RF front-end is fabricated in a 0.13-/spl mu/m CMOS process utilizing only standard process options. The RF front-end achieves a voltage gain of 50 dB, noise figure of 3.9 dB when integrated from 100 Hz to 135 kHz, IIP3 of -9 dBm, and at least IIP2 of +30dBm without calibration. The 4-GHz VCO meets the PCS 1900 phase noise specifications and has a phase noise of -132dBc/Hz at 3-MHz offset.     

A low noise CMOS RF front-end for UWB 6-9 GHz applications

An integrated fully differential ultra-wideband CMOS RF front-end for 6-9 GHz is presented.A resistive feedback low noise amplifier and a gain controllable IQ merged folded quadrature mixer are integrated as the RF front-end. The ESD protected chip is fabricated in a TSMC 0.13μm RF CMOS process and achieves a maximum voltage gain of 23-26 dB and a minimum voltage gain of 16-19 dB,an averaged total noise figure of 3.3-4.6 dB while operating in the high gain mode and an in-band IIP3 of-12.6 dBm while in th...     

A high IIP2 downconversion mixer using dynamic matching

This paper presents an RF downconversion mixer with improved rejection to second-order intermodulation for RF application within a direct-conversion receiver requiring high input blocking performance. The mixer, implemented in a 2.7-V 0.35-μm BiCMOS process, achieves a second-order input intercept point of at least +72 dBm for a BiCMOS design and at least +66 dBm for an all-CMOS design. The design utilizes dynamic matching to enhance the balance of a fully differential mixer through mitigation of both component and device mismatches. In addition, dynamic matching is shown to improve the mixer's 1/f noise performance. For an all-CMOS mixer design, a 30-dB improvement in the mixer's noise floor at 1 kHz has been observed compared to conventional fully differential CMOS Gilbert-cell mixer. Additionally, background is given on second-order intermodulation and on system IIP2 requirements for a direct-conversion receiver     

A 0.13 /spl mu/m CMOS front-end, for DCS1800/UMTS/802.11b-g with multiband positive feedback low-noise amplifier

This paper presents a fully integrated CMOS receiver front-end based on a direct conversion architecture for UMTS/802.11b-g and a low-IF architecture at 100 kHz for DCS1800. The two key building blocks are a multiband low-noise amplifier (LNA) that uses positive feedback to improve its gain and a highly linear mixer. The front-end, integrated in a 0.13 /spl mu/m CMOS process, exhibits a minimum noise figure of 5.2 dB, a programmable gain that can be varied from 13.5 to 28.5 dB, an IIP3 of more than -7.5 dBm and an IIP2 better than 50 dBm. The total current consumption is 20mA from a 1.2V supply.     

应用于软件无线电接收机中的无源下变频混频器

设计了一个应用于软件无线电接收机中的宽带无源下变频混频器,采用SMIC 0.13μm RF工艺实现,芯片面积0.42 mm<'2>.测试结果表明:在1.2 V电源电压下消耗了9 mA电流,工作频段0.9～2.2 GHz,电压转换增益17 dB,HP3 6～7 dBm,IIP2 40～42 dBm,DSB NF 17.5...     

A low power direct conversion receiver RF front-end with high in-band IIP2/IIP3 and low 1/f noise

A low power direct-conversion receiver RF front-end with high in-band IIP2/IIP3 and low 1/f noise is presented. The front-end includes the differential low noise amplifier, the down-conversion mixer, the LO buffer, the IF buffer and the bandgap reference. A modified common source topology is used as the input stages of the down-conversion mixer (and the LNA) to improve IIP2 of the receiver RF front-end while maintaining high IIP3. A shunt LC network is inserted into the common-source node of the switching pairs in the down-conversion mixer to absorb the parasitic capacitance and thus improve IIP2 and lower down the 1/f noise of the down-conversion mixer. The direct-conversion receiver RF front-end has been implemented in 0.18 μm CMOS process. The measured results show that the 2 GHz receiver RF front-end achieves +33 dBm in-band IIP2, 21 dB power gain, 6.2 dB NF and −2.3 dBm in-band IIP3 while only drawing 6.7 mA current from a 1.8 V power supply.     

A low voltage CMOS RF front-end for IEEE 802.11b WLAN transceiver

A low voltage CMOS RF front-end for IEEE 802.11b WLAN transceiver is presented. The problems to implement the low voltage design and the on-chip input/output impedance matching are considered, and some improved circuits are presented to overcome the problems. Especially, a single-end input, differential output double balanced mixer with an on-chip bias loop is analyzed in detail to show its advantages over other mixers. The transceiver RF front-end has been implemented in 0.18 um CMOS process, the measured results show that the Rx front-end achieves 5.23 dB noise figure, 12.7 dB power gain (50 ohm load), −18 dBm input 1 dB compression point (ICP) and −7 dBm IIP3, and the Tx front-end could output +2.1 dBm power into 50 ohm load with 23.8 dB power gain. The transceiver RF front-end draws 13.6 mA current from a supply voltage of 1.8 V in receive mode and 27.6 mA current in transmit mode. The transceiver RF front-end could satisfy the performance requirements of IEEE802.11b WLAN standard. Supported by the National Natural Science Foundation of China, No. 90407006 and No. 60475018.     

RF front-end of direct conversion receiver RFIC for cdma-2000

We report on the front-end of a highly integrated dual-band direct-conversion receiver IC for cdma-2000 mobile handset applications. The RF front-end included a CELL-band low-noise amplifier (LNA), dual-band direct-conversion quadrature I/Q down-converters, and a local-oscillator (LO) signal generation circuit. At 2.7 V, the LNA had a noise figure of 1.2 dB and input third-order intermodulation product (IIP3) of 9 dBm. I/Q down-converters had a noise figure of 4-5 dB and IIP3 of 4-5 dBm and IIP2 of 55 dBm. An on-chip phase-locked loop and external voltage-controlled oscillator generated the LO signal. The receiver RFIC was implemented in a 0.35-/spl mu/m SiGe BiCMOS process and meets or exceeds all cdma-2000 requirements when tested individually or on a handset.     

A 72-mW CMOS 802.11a direct conversion front-end with 3.5-dB NF and 200-kHz 1/f noise corner

A direct conversion 802.11a receiver front-end including a synthesizer with quadrature VCO has been integrated in a 0.13-/spl mu/m CMOS process. The chip has an active area of 1.8 mm/sup 2/ with the entire RF portion operated from 1.2 V and the low frequency portion operated from 2.5 V. Its key features are a current driven passive mixer with a low impedance load that achieves a low 1/f noise corner and an high I-Q accuracy quadrature VCO. Measured noise figure is 3.5 dB with an 1/f noise corner of 200 kHz, and an IIP3 of -2 dBm. The synthesizer DSB phase noise integrated over a 10 MHz band is less than -36 dBc while its I-Q phase unbalance is below 1 degree.     

A highly linear receiver front-end employing modified derivative superposition method with tuned inductors for 5.25 GHz

We design a highly linear CMOS RF receiver front-end operating in the 5 GHz band using the modified derivative superposition (DS) method with one- or two-tuned inductors in the low noise amplifier (LNA) and mixer. This method can be used to adjust the magnitude and phase of the third-order currents at output, and thus ensure that they cancel each other out. We characterize the two front-ends by the third-order input intercept point (IIP3), voltage conversion gain, and a noise figure based on the TSMC 0.18 μm RF CMOS process. Our simulation results suggest that the front-end with one-tuned inductor in the mixer supports linearization with the DS method, which only sacrifices 1.9 dB of IIP3 while the other performance parameters are improved. Furthermore, the front-end with two-tuned inductors requires a precise optimum design point, because it has to adjust two inductances simultaneously for optimization. If the inductances have deviated from the optimum design point, the front-end with two-tuned inductors has worse IIP3 characteristic than the front-end with one-tuned inductor. With two-tuned inductors, the front-end has an IIP3 of 5.3 dBm with a noise figure (NF) of 4.7 dB and a voltage conversion gain of 23.1 dB. The front-end with one-tuned inductor has an IIP3 of 3.4 dBm with an NF of 4.4 dB and a voltage conversion gain of 24.5 dB. There is a power consumption of 9.2 mA from a 1.5 V supply.     

Design techniques for mitigation of intermodulation distortion components in CMOS RF receiver front-end circuits with subthreshold operation

This paper provides an overview of target applications and design aspects for emerging radio frequency front-end circuits with subthreshold biasing to reduce power consumption. Design methods are described to linearize a subthreshold pseudo-differential common-source cascode low-noise amplifier (LNA) and a subthreshold active mixer. The linearization techniques can improve the third-order intermodulation intercept point (IIP3) through the use of passive components, which implies that they do not require auxiliary amplifiers to suppress third-order distortion components, and therefore do not incur any extra power consumption. A 1.95 GHz receiver front-end chip with a narrowband LNA and down-conversion mixer was designed and fabricated in 110 nm CMOS technology. Measurement results show that the linearized low-power front-end has a 20.6 dB voltage gain, a 9.5 dB double sideband noise figure, and a ? 10.8 dBm IIP3 with a power consumption of 0.9 mW.     

A 2.7-V 900-MHz CMOS LNA and mixer

A CMOS low-noise amplifier (LNA) and a mixer for RF front-end applications are described. A current reuse technique is described that increases amplifier transconductance for the LNA and mixer without increasing power dissipation, compared to standard topologies. At 900 MHz, the LNA minimum noise figure (NF) is 1.9 dB, input third-order intercept point (IIP3) is -3.2 dBm and forward gain is 15.6 dB. With a 1-GHz local oscillator (LO) and a 900-MHz RF input, the mixer minimum double sideband noise figure (DSB NF) is 5.8 dB, IIP3 is -4.1 dBm, and power conversion gain is 8.8 dB. The LNA and mixer, respectively, consume 20 mW and 7 mW from a 2.7 V power supply. The active areas of the LNA and mixer are 0.7 mm×0.4 mm and 0.7 mm×0.2 mm, respectively. The prototypes were fabricated in a 0.5-μm CMOS process     

A CMOS passive mixer with low flicker noise for low-power direct-conversion receiver

A CMOS passive mixer is designed to mitigate the critical flicker noise problem that is frequently encountered in constituting direct-conversion receivers. With a unique single-balanced passive mixer design, the resulted direct-conversion receiver achieves an ultralow flicker-noise corner of 45 kHz, with 6 dB more gain and much lower power and area consumption than the double-balanced counterpart. CMOS switches with a unique bias-shifting network to track the LO DC offset are devised to reduce the second-order intermodulation. Consequently, the mixer's IIP2 has been greatly enhanced by almost 21 dB from a traditional single-balanced passive mixer. An insertion compensation method is also implemented for effective dc offset cancellation. Fabricated in 0.18 /spl mu/m CMOS and measured at 5 GHz, this passive mixer obtains 3 dB conversion gain, 39 dBm IIP2, and 5 dBm IIP3 with LO driving at 0 dBm. When the proposed mixer is integrated in a direct-conversion receiver, the receiver achieves 29 dB overall gain and 5.3 dB noise figure.     

用于IEEE802．11b／g WLAN直接下变频接收机的射频前端设计

介绍了一种应用于IEEE802．11b／g无线局域网接收机射频前端的设计。基于直接下变频的系统架构。接收机集成了低噪声放大器、I／Q下变频器、去直流偏移滤波器、基带放大器和信道选择滤波器。电路采用TSMC0．18μm CMOS工艺设计,工作在2．4GHz ISM（工业、科学和医疗）频段,实现的低噪声放大器噪声系数为0．84dB,增益为16dB,S11低于-15dB,功耗为13mW;I／Q下变频器电压增益为2dB,输入1dB压缩点为-1 dBm,噪声系数为13dB,功耗低于10mw。整个接收机射频前端仿真得到的噪声系数为3．5dB,IIP3为-8dBm,IP2大于30dBm,电压增益为31dB,功耗为32mW。     

一个双频带可重构的直接变频接收机射频前端

A dual-band reconfigurable wireless receiver RF front-end is presented, which is based on the directconversion principle and consists of a low noise amplifer （LNA） and a down-converter. By utilizing a compact switchable on-chip symmetrical inductor, the RF front-end could be switched between two operation frequency bands without extra die area cost. This RF front-end has been implemented in the 180 nm CMOS process and the measured results show that the front-end could provide a gain of 25 dB and IIP3 of 6 dBm at 2.2 GHz, and a gain of 18.8 dB and IIP3 of 7.3 dBm at 4.5 GHz. The whole front-end consumes 12 mA current at 1.2 V voltage supply for the LNA and 2.1 mA current at 1.8 V for the mixer, with a die area of 1.2 × 1 mm^2.     

A low power 3-5 GHz CMOS UWB receiver front-end

A novel low power RF receiver front-end for 3-5 GHz UWB is presented. Designed in the 0.13μm CMOS process, the direct conversion receiver features a wideband balun-coupled noise cancelling transconductance input stage, followed by quadrature passive mixers and transimpedance loading amplifiers. Measurement results show that the receiver achieves an input return loss below-8.5 dB across the 3.1-4.7 GHz frequency range, max-imum voltage conversion gain of 27 dB, minimum noise figure of 4 dB, IIP3 of-11.5 dBm, and IIP2 of 33 dBm. Working under 1.2 V supply voltage, the receiver consumes total current of 18 mA including 10 mA by on-chip quadrature LO signal generation and buffer circuits. The chip area with pads is 1.1 × 1.5 mm2.     

A 0.18μm CMOS GAIN-SWITCHED LNA AND MIXER WITH LARGE DYNAMIC RANGE

A 2.4GHz 0.18μm CMOS gain-switched single-end Low Noise Amplifier(LNA) and a passive mixer with no external balun for near-zero-IF(Intermediate Frequency)/RF(Radio Frequency) applications are described.The LNA,fabricated in the 0.18μm 1P6M CMOS technology,adopts a gain-switched technique to increase the linearity and enlarge the dynamic range.The mixer is an IQ-based passive topology.Measurements of the CMOS chip are performed on the FR-4 PCB and the input is matched to 50Ω.Combining LNA and mixer,the front...     

A 0.18μm CMOS gain-switched LNA and mixer with large dynamic range

A 2.4GHz 0.18μm CMOS gain-switched single-end Low Noise Amplifier （LNA） and a passive mixer with no external balun for near-zero-IF （Intermediate Frequency）/RF （Radio Frequency） applications are described. The LNA, fabricated in the 0.18μm 1P6M CMOS technology, adopts a gain-switched technique to increase the linearity and enlarge the dynamic range. The mixer is an IQ-based passive topology. Measurements of the CMOS chip are performed on the FR-4 PCB and the input is matched to 50Ω. Combining LNA and mixer, the front-end measured performances in high gain state are： -15dB of Sll, 18.5dB of voltage gain, 4.6dB of noise figure, 15dBm of IIP3, 85dBm to -10dBm dynamic range. The full circuit drains 6mA from a 1.8V supply.     

A 0.18 μm CMOS direct down-converter for highly integrated 3G receivers

This paper presents the design of a high dynamic range direct down-converter for 3G cell-phone applications. The mechanisms responsible for second-order intermodulation distortion are discussed in details, leading to the following design strategy: the transconductor is degenerated by means of an RC filter, an LC network resonating at RF frequency loads the switching pair and carefully matched resistors are used in the output load. Prototypes realized in 0.18 μm CMOS show: +78 dBm IIP2 minimum among 40 samples, +10 dBm IIP3, 4 nV/√Hz input-referred noise density while burning only 4 mA from 1.8 V.     

A direct conversion receiver with an IP2 calibrator for CDMA/PCS/GPS/AMPS applications

A second-order intercept point (IP2) calibration technique is developed using common-mode feedback (CMFB) circuitry in a direct-conversion receiver for wireless CDMA/PCS/GPS/AMPS applications. The IP2 calibrator is capable of providing different CMFB gain to tune its common-mode output impedance for each of the positive and negative mixer outputs. The CDMA mixer applying this method achieved a second-order input intercept point (IIP2) of 64 dBm, a third-order input intercept point (IIP3) of 4 dBm, a noise figure of 6.5 dB and a voltage gain of 42.2 dB. This result shows a 20 dB improvement from an uncalibrated IIP2 of 44 dBm. The receiver RFIC is implemented in a 0.5-/spl mu/m SiGe BiCMOS process, and it operates from a 2.7 to 3.1 V single power supply.