An ultra-broadband distributed passive gate-pumped mixer in 0.18μm CMOS

A broadband distributed passive gate-pumped mixer(DPGM) using standard 0.18μm CMOS technology is presented.By employing distributed topology,the mixer can operate at a wide frequency range.In addition,a fourth-order low pass filter is applied to improve the port-to-port isolation.This paper also analyzes the impedance match and conversion loss of the mixer,which consumes zero dc power and exhibits a measured conversion loss of 9.4—17 dB from 3 to 40 GHz with a compact size of 0.78 mm~2.The input referred 1 dB compression point is higher than 4 dBm at a fixed IF frequency of 500 MHz and RF frequency of 23 GHz,and the measured RF-to-LO, RF-to-IF and LO-to-IF isolations are better than 21,38 and 45 dB,respectively.The mixer is suitable for WLAN, UWB,Wi-Max,automotive radar systems and other millimeter-wave radio applications.     

A reconfigurable passive mixer for multimode multistandard receivers in 0.18 μm CMOS

This paper presents a reconfigurable quadrature passive mixer for multimode multistandard receivers. By using controllable transconductor and transimpedance-amplifier stages, the voltage conversion gain of the mixer is reconfigured according to the requirement of the selected communication standard Other characteristics such as noises figure, linearity and power consumption are also reconfigured consequently. The design concept is verified by implementing a quadrature passive mixer in 0.18 μm CMOS technology. On wafer measurement results show that, with the input radio frequency ranges from 700 MHz to 2.3 GHz, the mixer achieves a controllable voltage conversion gain from 4 to 22 dB with a step size of 6 dB. The measured maximum ⅡP3 is 8.5 dBm and the minimum noise figure is 8.0 dB. The consumed current for a single branch (I or Q) ranges from 3.1 to 5.6 mA from a 1.8 V supply voltage. The chip occupies an area of 0.71 mm² including pads.     

A 0.7-7 GHz wideband reconfigurable receiver RF front-end in CMOS

In this paper,a 0.7-7 GHz wideband RF receiver front-end SoC is designed using the CMOS process.The front-end is composed of two main blocks:a single-ended wideband low noise amplifier (LNA) and an inphase/quadrature (I/Q) voltage-driven passive mixer with IF amplifiers.Based on a self-biased resistive negative feedback topology,the LNA adopts shunt-peaking inductors and a gate inductor to boost the bandwidth.The passive down-conversion mixer includes two parts:passive switches and IF amplifiers.The measurement results show that the front-end works well at different LO frequencies,and this chip is reconfigurable among 0.7 to 7 GHz by tuning the LO frequency.The measured results under 2.5-GHz LO frequency show that the front-end SoC achieves a maximum conversion gain of 26 dB,a minimum noise figure (NF) of 3.2 dB,with an IF bandwidth of greater than 500 MHz.The chip area is 1.67 × 1.08 mm2.     

A RF receiver frontend for SC-UWB in a 0.18-μm CMOS process

正A radio frequency(RF) receiver frontend for single-carrier ultra-wideband(SC-UWB) is presented. The front end employs direct-conversion architecture,and consists of a differential low noise amplifier(LNA),a quadrature mixer,and two intermediate frequency(IF) amplifiers.The proposed LNA employs source inductively degenerated topology.First,the expression of input impedance matching bandwidth in terms of gate-source capacitance, resonant frequency and target S_(11) is given.Then,a noise figure optimization strategy under gain and power constraints is proposed,with consideration of the integrated gate inductor,the bond-wire inductance,and its variation.The LNA utilizes two stages with different resonant frequencies to acquire flat gain over the 7.1-8.1 GHz frequency band,and has two gain modes to obtain a higher receiver dynamic range.The mixer uses a double balanced Gilbert structure.The front end is fabricated in a TSMC 0.18-/im RF CMOS process and occupies an area of 1.43 mm~2.In high and low gain modes,the measured maximum conversion gain are 42 dB and 22 dB,input 1 dB compression points are -40 dBm and -20 dBm,and S_(11) is better than -18 dB and -14.5 dB.The 3 dB IF bandwidth is more than 500 MHz.The double sideband noise figure is 4.7 dB in high gain mode.The total power consumption is 65 mW from a 1.8 V supply.     

Low power high gain gain-controlled LNA and mixer for GNSS receivers Wei Binbin(魏斌斌)1, Jiang Jinguang(江金光)1,2,3*

A low power high gain gain-controlled LNA ＋ mixer for GNSS receivers is reported. The high gain LNA is realized with a current source load. Its gain-controlled ability is achieved using a programmable bias circuit. Taking advantage of the high gain LNA, a high noise figure passive mixer is adopted. With the passive mixer, low power consumption and high voltage gain of the LNA ＋ mixer are achieved. To fully investigate the performance of this circuit, comparisons between a conventional LNA ＋ mixer, a previous low power LNA ＋ mixer, and the proposed LNA ＋ mixer are presented. The circuit is implemented in 0.18 #m mixed-signal CMOS technology. A 3.8 dB noise figure, an overall 45 dB converge gain and a 10 dB controlled gain range of the two stages are measured. The chip occupies 0.24 mm2 and consumes 2 mA current under 1.8 V supply.     

A low power high gain gain-controlled LNAC＋mixer for GNSS receivers

A low power high gain gain-controlled LNAC+mixer for GNSS receivers is reported. The high gain LNA is realized with a current source load.Its gain-controlled ability is achieved using a programmable bias circuit. Taking advantage of the high gain LNA, a high noise figure passive mixer is adopted. With the passive mixer, low power consumption and high voltage gain of the LNACmixer are achieved. To fully investigate the performance of this circuit, comparisons between a conventional LNAC+mixer, a previous low power LNAC+mixer, and the proposed LNAC+mixer are presented. The circuit is implemented in 0.18 m mixed-signal CMOS technology. A 3.8 dB noise figure, an overall 45 dB converge gain and a 10 dB controlled gain range of the two stages are measured. The chip occupies 0.24 mm2and consumes 2 mA current under 1.8 V supply.     

A transformer-loaded receiver front end for 2.4 GHz WLAN in 0.13μm CMOS technology

A 2.4 GHz radio frequency receiver front end with an on-chip transformer compliant with IEEE 802.11b/g standards is presented.Based on zero-IF receiver architecture,the front end comprises a variable gain common-source low noise amplifier with an on-chip transformer as its load and a high linear quadrature folded Gilbert mixer.As the load of the LNA,the on-chip transformer is optimized for lowest resistive loss and highest power gain.The whole front end draws 21 mA from 1.2 V supply,and the measured results show a double side band noise figure of 3.75 dB,-31 dBm IIP3 with 44 dB conversion gain at maximum gain setting.Implemented in 0.13μm CMOS technology,it occupies a 0.612 mm~2 die size.     

A multi-mode multi-band RF receiver front-end for a TD-SCDMA/LTE/LTE-advanced in 0.18-μm CMOS process

正A fully integrated multi-mode multi-band directed-conversion radio frequency(RF) receiver front-end for a TD-SCDMA/LTE/LTE-advanced is presented.The front-end employs direct-conversion design,and consists of two differential tunable low noise amplifiers(LNA),a quadrature mixer,and two intermediate frequency(IF) amplifiers.The two independent tunable LNAs are used to cover all the four frequency bands,achieving sufficient low noise and high gain performance with low power consumption.Switched capacitor arrays perform a resonant frequency point calibration for the LNAs.The two LNAs are combined at the driver stage of the mixer,which employs a folded double balanced Gilbert structure,and utilizes PMOS transistors as local oscillator(LO) switches to reduce flicker noise.The front-end has three gain modes to obtain a higher dynamic range.Frequency band selection and mode of configuration is realized by an on-chip serial peripheral interface(SPI) module.The frontend is fabricated in a TSMC 0.18-μm RF CMOS process and occupies an area of 1.3 mm~2.The measured doublesideband (DSB) noise figure is below 3.5 dB and the conversion gain is over 43 dB at all of the frequency bands. The total current consumption is 31 mA from a 1.8-V supply.     

一种片上变压器为负载的用于0.13 μm CMOS工艺2.4GHz WLAN的接收机射频前端电路

A 2.4 GHz radio frequency receiver front end with an on-chip transformer compliant with IEEE 802.11b/g standards is presented. Based on zero-IF receiver architecture, the front end comprises a variable gain common-source low noise amplifier with an on-chip transformer as its load and a high linear quadrature folded Gilbert mixer. As the load of the LNA, the on-chip transformer is optimized for lowest resistive loss and highest power gain. The whole front end draws 21 mA from 1.2 V supply, and the measured results show a double side band noise figure of 3.75 dB, -31 dBm IIP3 with 44 dB conversion gain at maximum gain setting. Implemented in 0.13 μ m CMOS technology, it occupies a 0.612 mm² die size.     

应用于DRM/DAB系统的高转换增益及线性度优化的新结构混频器

This paper focuses on a new design of a down-conversion mixer for a low-IF wideband receiver.Based on the folded structure and differential multiple gated transistor(DMGTR) technique,a novel quadrature mixer with a high conversion gain,a moderate linearity,and a moderate NF is proposed.The mixer is designed and implemented in a 0.18-m CMOS process,and can operate in a frequency range from 150 kHz to 1.5 GHz.The circuit performance is confirmed by both simulation and measurement results.The measurement results exhibit a peak conversion gain of 13.35 dB,a high third order input referred intercept point of 14.85 dBm,and a moderate single side band noise figure of 10.67 dB.Moreover,the whole quadrature mixer core occupies a compact die area of 0.122 mm2.It consumes a current of 3.96 mA(excluding the output buffers) under a single supply voltage of 1.8 V.     

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.     

用于U波段移动数字电视的宽带大动态范围高线性度射频前端

A wideband large dynamic range and high linearity U-band RF front-end for mobile DTV is introduced,and includes a noise-cancelling low-noise amplifier(LNA),an RF programmable gain amplifier(RFPGA) and a current communicating passive mixer.The noise/distortion cancelling structure and RC post-distortion compensation are employed to improve the linearity of the LNA.An RFPGA with five stages provides large dynamic range and fine gain resolution.A simple resistor voltage network in the passive mixer decreases the gate bias voltage of the mixing transistor,and optimum linearity and symmetrical mixing is obtained at the same time.The RF front-end is implemented in a 0.25 μm CMOS process.Tests show that it achieves an ⅡP3(third-order intercept point) of –17 dBm,a conversion gain of 39 dB,and a noise figure of 5.8 dB.The RFPGA achieves a dynamic range of –36.2 to 23.5 dB with a resolution of 0.32 dB.     

Ka波段对极鳍线混频器和检波器设计

This paper mainly discusses the analysis and design of a finline single-ended mixer and detector. In the circuit, for the purpose of eliminating high-order resonant modes and improving transition loss, metallic via holes are implemented along the mounting edge of the substrate embedded in the split-block of the WG-finline-microstrip transition. Meanwhile, a Ka band slow-wave and bandstop filter, which represents a reactive termination, is designed for the utilization of idle frequencies and operation frequencies energy. Full-wave analysis is carded out to optimize the input matching network of the mixer and the detector circuit using lumped elements to model the nonlinear diode. The exported S-matrix of the optimized circuit is used for conversion loss and voltage sensitivity analysis. The lowest measured conversion loss is 3.52 dB at 32.2 GHz; the conversion loss is flat and less than 5.68 dB in the frequency band of 29-34 GHz. The highest measured zero-bias voltage sensitivity is 1450 mV/mW at 38.6 GHz, and the sensitivity is better than 1000 mV/mW in the frequency band of 38-40 GHz.     

A 0.35μm CMOS Mixer for 2.45-GHz RFID Application

A RF mixer with both low noise and high linearity is designed,operating at 2.45-GHz ISM band for RFID application.The designed mixer uses an optimal input matching network and the carefully chosen sizes of transistors,also with the appropriate bias point,to improve the noise figure(NF).Also,with a resonant LC loop as the current source and a parallel PMOS-resistor as the load,the mixer has a high linearity.The post simulation results show that the single side- band noise figure of 8.57 dB,conversion gain of 10.02 dB,input 1-dB compression point(P-1dB)of-8.33 dBm,and input third-order intercept point(IIP3)of 5.35 dBm.     

Design and optimization of a 2.4 GHz RF front-end with an on-chip balun

A 2.4 GHz low-power,low-noise and highly linear receiver front-end with a low noise amplifier(LNA) and balun optimization is presented.Direct conversion architecture is employed for this front-end.The on-chip balun is designed for single-to-differential conversion between the LNA and the down-conversion mixer,and is optimized for the best noise performance of the front-end.The circuit is implemented with 0.35μm SiGe BiCMOS technology.The front-end has three gain steps for maximization of the input dynamic range.The overall maximum gain is about 36 dB.The double-sideband noise figure is 3.8 dB in high gain mode and the input referred third-order intercept point is 12.5 dBm in low gain mode.The down-conversion mixer has a tunable parallel R-C load at the output and an emitter follower is used as the output stage for testing purposes.The total front-end dissipation is 33 mW under a 2.85 V supply and occupies a 0.66 mm~2 die size.     

A 0.18μm CMOS Gilbert low noise mixer with noise cancellation

正This paper presents a broadband Gilbert low noise mixer implemented with noise cancellation technique operating between 10 MHz and 0.9 GHz.The Gilbert mixer is known for its perfect port isolation and bad noise performance.The noise cancellation technique of LNA can be applied here to have a better NF.The chip is implemented in SMIC 0.18μm CMOS technology.Measurement shows that the proposed low noise mixer has a 13.7-19.5 dB voltage gain from 10 MHz to 0.9 GHz,an average noise figure of 5 dB and a minimum value of 4.3 dB.The core area is 0.6 x 0.45 mm~2.     

利用简单电阻偏置网络实现的高线性度电流驱动型无源混频器

A high linearity current communicating passive mixer including the mixing cell and transimpedance amplifier(TIA) is introduced.It employs the resistor in the TIA to reduce the source voltage and the gate voltage of the mixing cell.The optimum linearity and the maximum symmetric switching operation are obtained at the same time.The mixer is implemented in a 0.25μm CMOS process.The test shows that it achieves an input third-order intercept point of 13.32 dBm,conversion gain of 5.52 dB,and a single sideband noise figure of 20 dB.     

A 5 GHz 7.2 dB NF low power direct conversion receiver front-end with balun LNA

A 5GHz low power direct conversion receiver radio frequency front-end with balun LNA is presented. A hybrid common gate and common source structure balun LNA is adopted,and the capacitive cross-coupling technique is used to reduce the noise contribution of the common source transistor.To obtain low l/f noise and high linearity,a current mode passive mixer is preferred and realized.A current mode switching scheme can switch between high and low gain modes,and meanwhile it can not only perform good linearity but save power consumption at low gain mode.The front-end chip is manufactured on a 0.13-μm CMOS process and occupies an active chip area of 1.2 mm~2.It achieves 35 dB conversion gain across 4.9-5.1 GHz,a noise figure of 7.2 dB and an IIP3 of -16.8 dBm,while consuming 28.4 mA from a 1.2 V power supply at high gain mode.Its conversion gain is 13 dB with an IIP3 of 5.2 dBm and consumes 21.5 mA at low gain mode.     

一种新型指数增益控制60dB可变增益放大器

A CMOS variable gain amplifier（VGA） that adopts a novel exponential gain approximation is presented.No additional exponential gain control circuit is required in the proposed VGA used in a direct conversion receiver.A wide gain control voltage from 0.4 to 1.8 V and a high linearity performance are achieved.The three-stage VGA with automatic gain control（AGC） and DC offset cancellation（DCOC） is fabricated in a 0.18-μm CMOS technology and shows a linear gain range of more than 58-dB with a linearity error less than ±1 dB.The 3-dB bandwidth is over 8 MHz at all gain settings.The measured input-referred third intercept point（IIP3） of the proposed VGA varies from-18.1 to 13.5 dBm,and the measured noise figure varies from 27 to 65 dB at a frequency of 1 MHz.The dynamic range of the closed-loop AGC exceeds 56 dB,where the output signal-to-noise-and-distortion ratio（SNDR） reaches 20 dB.The whole circuit,occupying 0.3 mm^2 of chip area,dissipates less than 3.7 mA from a 1.8-V supply.     

53-GHz平衡式考毕兹振荡器的设计与测试

A 53 GHz Colpitts oscillator implemented in a SiGe：C BiCMOS technology is presented. Limited by a 26.5 GHz frequency analyzer, the oscillator was measured indirectly through an on-chip mixer. The mixer downconverted the oscillating frequency to an intermediate frequency （IF） below 26.5 GHz. By adjusting the local oscillating （LO） frequency and recording the changes of IF frequency, the oscillator＇s output frequency （RF） was determined. Additionally, using phase noise theory of mixers, the oscillator＇s phase noise was estimated as -58 dBc/Hz at 1 MHz offset and the output power was about -21 dBm. The chip is 270 ×480μm in size.