0.18 /spl mu/m 3-6 GHz CMOS broadband LNA for UWB radio

A 3-6 GHz CMOS broadband low noise amplifier (LNA) for ultra-wideband (UWB) radio is presented. The LNA is fabricated with the 0.18 /spl mu/m 1P6M standard CMOS process. Measurement of the CMOS LNA is performed using an FR-4 PCB test fixture. From 3 to 6 GHz, the broadband LNA exhibits a noise figure of 4.7-6.7 dB, a gain of 13-16 dB, and an input/output return loss higher than 12/10 dB, respectively. The input P/sub 1 dB/ and input IP3 (IIP3) at 4.5 GHz are about -14 and -5 dBm, respectively. The DC supply is 1.8 V.     

A fully monolithic 260-/spl mu/W, 1-GHz subthreshold low noise amplifier

A micro-power complementary metal oxide semiconductor (CMOS) low-noise amplifier (LNA) is presented based on subthreshold MOS operation in the GHz range. The LNA is fabricated in an 0.18-/spl mu/m CMOS process and has a gain of 13.6 dB at 1 GHz while drawing 260 /spl mu/A from a 1-V supply. An unrestrained bias technique, that automatically increases bias currents at high input power levels, is used to raise the input P1dB to -0.2 dBm. The LNA has a measured noise figure of 4.6 dB and an IIP3 of 7.2 dBm.     

K-band low-noise amplifiers using 0.18 /spl mu/m CMOS technology

Two K-Band low-noise amplifiers (LNAs) are designed and implemented in a standard 0.18 /spl mu/m CMOS technology. The 24 GHz LNA has demonstrated a 12.86 dB gain and a 5.6 dB noise figure (NF) at 23.5 GHz. The 26 GHz LNA achieves an 8.9 dB gain at the peak gain frequency of 25.7 GHz and a 6.93 dB NF at 25 GHz. The input referred third-order intercept point (IIP3) is >+2 dBm for both LNAs with a current consumption of 30 mA from a 1.8 V power supply. To our knowledge, the LNAs show the highest operation frequencies ever reported for LNAs in a standard CMOS process.     

5.7 GHz low-power variable-gain LNA in 0.18 /spl mu/m CMOS

A variable-gain low-noise amplifier (LNA) suitable for low-voltage and low-power operation is designed and implemented in a standard 0.18 /spl mu/m CMOS technology. With a current-reused topology, the common-source gain stages are stacked for minimum power dissipation while achieving high small-signal gain. The fully integrated 5.7 GHz LNA exhibits 16.4 dB gain, 3.5 dB noise figure and 8 dB gain tuning range with good input and output return losses. The LNA consumes 3.2 mW DC power from a supply voltage of 1 V. A gain/power quotient of 5.12 dB/mW is achieved in this work.     

Highly linear 0.18-/spl mu/m CMOS power amplifier with deep n-Well structure

The linearity of a 0.18-/spl mu/m CMOS power amplifier (PA) is improved by adopting a deep n-well (DNW). To find the reason for the improvement, bias dependent nonlinear parameters of the test devices are extracted from a small-signal model and a Volterra series analysis for an optimized nMOS PA with a proper matching circuit is carried out. From the analysis, it is revealed that the DNW of the nMOS lowers the harmonic distortion generated from the intrinsic gate-source capacitance (C/sub gs/), which is the dominant nonlinear source, and partially from drain junction capacitance (C/sub jd/). Single-ended and differential PAs for 2.45-GHz WLAN are designed and fabricated using a 0.18-/spl mu/m standard CMOS process. The single-ended PA with the DNW improves IMD3 and IMD5 about 5 dB with identical power performances, i.e., 20 dBm of P/sub out/, 18.7 dB of power gain and 31% of power-added efficiency (PAE) at P/sub 1dB/. The IMD3 and IMD5 are below -40 dBc and -47dBc, respectively. The differential PA with the DNW also shows about 7 dB improvements of IMD3 and IMD5 with 20.2 dBm of P/sub out/, 18.9 dB of power gain and 35% of PAE at P/sub 1dB/. The IMD3 and IMD5 are below -45 dB and -57 dBc, respectively. These performances of the linear PAs are state-of-the-art results.     

Packaged single-ended CMOS low noise amplifier with 2.3 dB noise figure and 64 dBm IIP/sub 2/

A single-ended low noise amplifier (LNA) implemented in a foundry 0.18 /spl mu/m CMOS process is tested on a PC board using the chip-on-board technique. The measured S/sub 11/ and S/sub 22/ are less than -10 dB over 5.15-5.35 GHz, which is the lower subband of UNII and HIPERLAN/2 band. The measured noise figure is 2.0 dB and power gain is 15.5 dB at 5.15 GHz, while drawing 5.8 mA of current from a 1.8 V supply. The measured IIP/sub 2/ is greater than 64 dBm. This extremely high IP/sub 2/ is due to the tuned response of the LNA. The LNA is suitable for WLAN applications in the lower UNII and HIPERLAN/2 subband.     

A 1-V transformer-feedback low-noise amplifier for 5-GHz wireless LAN in 0.18-/spl mu/m CMOS

A low-noise amplifier (LNA) uses low-loss monolithic transformer feedback to neutralize the gate-drain overlap capacitance of a field-effect transistor (FET). A differential implementation in 0.18-/spl mu/m CMOS technology, designed for 5-GHz wireless local-area networks (LANs), achieves a measured power gain of 14.2 dB, noise figure (NF, 50 /spl Omega/) of 0.9 dB, and third-order input intercept point (IIP3) of +0.9 dBm at 5.75 GHz, while consuming 16 mW from a 1-V supply. The feedback design is benchmarked to a 5.75-GHz cascode LNA fabricated in the same technology that realizes 14.1-dB gain, 1.8-dB NF, and IIP3 of +4.2 dBm, while dissipating 21.6 mW at 1.8 V.     

Low-power programmable gain CMOS distributed LNA

A design methodology for low power MOS distributed amplifiers (DAs) is presented. The bias point of the MOS devices is optimized so that the DA can be used as a low-noise amplifier (LNA) in broadband applications. A prototype 9-mW LNA with programmable gain was implemented in a 0.18-/spl mu/m CMOS process. The LNA provides a flat gain, S/sub 21/, of 8 /spl plusmn/ 0.6dB from DC to 6.2 GHz, with an input impedance match, S/sub 11/, of -16 dB and an output impedance match, S/sub 22/, of -10 dB over the entire band. The 3-dB bandwidth of the distributed amplifier is 7GHz, the IIP3 is +3 dBm, and the noise figure ranges from 4.2 to 6.2 dB. The gain is programmable from -10 dB to +8 dB while gain flatness and matching are maintained.     

A low-voltage folded-switching mixer in 0.18-/spl mu/m CMOS

Scaling of CMOS technologies has a great impact on analog design. The most severe consequence is the reduction of the voltage supply. In this paper, a low voltage, low power, AC-coupled folded-switching mixer with current-reuse is presented. The main advantages of the introduced mixer topology are: high voltage gain, moderate noise figure, moderate linearity, and operation at low supply voltages. Insight into the mixer operation is given by analyzing voltage gain, noise figure (NF), linearity (IIP3), and DC stability. The mixer is designed and implemented in 0.18-/spl mu/m CMOS technology with metal-insulator-metal (MIM) capacitors as an option. The active chip area is 160 /spl mu/m/spl times/200 /spl mu/m. At 2.4 GHz a single side band (SSB) noise figure of 13.9 dB, a voltage gain of 11.9 dB and an IIP3 of -3 dBm are measured at a supply voltage of 1 V and with a power consumption of only 3.2 mW. At a supply voltage of 1.8 V, an SSB noise figure of 12.9 dB, a voltage gain of 16 dB and an IIP3 of 1 dBm are measured at a power consumption of 8.1 mW.     

A 24-GHz 3.9-dB NF low-noise amplifier using 0.18 /spl mu/m CMOS technology

A 24-GHz low-noise amplifier (LNA) was designed and fabricated in a standard 0.18-/spl mu/m CMOS technology. The LNA chip achieves a peak gain of 13.1 dB at 24 GHz and a minimum noise figure of 3.9 dB at 24.3 GHz. The supply voltage and supply current are 1 V and 14 mA, respectively. To the author's knowledge, this LNA demonstrates the lowest noise figure among the reported LNAs in standard CMOS processes above 20 GHz.     

5.8-GHz CMOS T/R switches with high and low substrate resistances in a 0.18-/spl mu/m CMOS process

Two single-pole, double-throw transmit/receive switches were designed and fabricated with different substrate resistances using a 0.18-/spl mu/m p/sup $/substrate CMOS process. The switch with low substrate resistances exhibits 0.8-dB insertion loss and 17-dBm P/sub 1dB/ at 5.825 GHz, whereas the switch with high substrate resistances has 1-dB insertion loss and 18-dBm P/sub 1dB/. These results suggest that the optimal insertion loss can be achieved with low substrate resistances and 5.8-GHz T/R switches with excellent insertion loss and reasonable power handling capability can be implemented in a 0.18-/spl mu/m CMOS process.     

10-13.6 Gbit/s 0.18 /spl mu/m CMOS modulator drivers with 8 V/sub PP/ differential output swing

A novel intrinsic drain-gate capacitance (C/sub DG/) feedback network is incorporated into the conventional cascode circuit configuration to implement a 10-13.6 Gbit/s modulator driver. The driver fabricated in 0.18 /spl mu/m CMOS process could generate an 8 V/sub PP/ differential output swing. The power consumption is as low as 0.6 W. The present work shows that the driving capability is greater than the currently reported CMOS drivers.     

A 24-GHz CMOS front-end

This paper reports the first 24-GHz CMOS front-end in a 0.18-/spl mu/m process. It consists of a low-noise amplifier (LNA) and a mixer and downconverts an RF input at 24 GHz to an IF of 5 GHz. It has a power gain of 27.5 dB and an overall noise figure of 7.7 dB with an input return loss, S/sub 11/ of -21 dB consuming 20 mA from a 1.5-V supply. The LNA achieves a power gain of 15 dB and a noise figure of 6 dB on 16 mA of dc current. The LNA's input stage utilizes a common-gate with resistive feedthrough topology. The performance analysis of this topology predicts the experimental results with good accuracy.     

A power efficient differential 20-GHz low noise amplifier with 5.3-GHz 3-dB bandwidth

A 20-GHz differential two-stage low-noise amplifier (LNA) is demonstrated in a foundry digital 130-nm CMOS technology with 8-metal layers. This LNA has 20-dB voltage gain and /spl sim/5.5-dB noise figure at 20GHz with 24-mW power consumption. The measured IP/sub 1 dB/ and IIP/sub 3/ are -11 dBm and -4dBm. Compared to the previously published bulk CMOS LNAs operating above 20GHz, this LNA has exceptionally low power and current consumption especially considering its differential topology and wide bandwidth.     

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.     

Single-pole double-throw CMOS switches for 900-MHz and 2.4-GHz applications on p/sup -/silicon substrates

A 900-MHz single-pole double-throw (SPDT) switch with an insertion loss of 0.5 dB and a 2.4-GHz SPDT switch with an insertion loss of 0.8 dB were implemented using 3.3-V 0.35-/spl mu/m NMOS transistors in a 0.18-/spl mu/m bulk CMOS process utilizing 20-/spl Omega//spl middot/cm p/sup -/ substrates. Impedance transformation was used to reduce the source and load impedances seen by the switch to increase the power handling capability. SPDT switches with 30-/spl Omega/ impedance transformation networks exhibit 0.97-dB insertion loss and 24.3-dBm output P/sub 1dB/ when tuned for 900-MHz operation, and 1.10-dB insertion loss and 20.6-dBm output P/sub 1dB/ when tuned for 2.4-GHz operation. The 2.4-GHz switch is the first bulk CMOS switch which can be used for 802.11b wireless local area network applications.     

24 GHz low-noise amplifier in 0.18 /spl mu/m CMOS technology

A 24 GHz monolithic low-noise amplifier (LNA) is implemented in a standard 0.18 /spl mu/m CMOS technology. Measurements show a gain of 12.86 dB and a noise figure of 5.6 dB at 23.5 GHz. The input and output return losses are better than 11 dB and 22 dB across the 22-29 GHz span, respectively. The operation frequency of 24 GHz is believed to be the highest reported for LNA in a standard CMOS technology.     

Low-voltage high-gain differential OTA for SC circuits

A new differential operational transconductance amplifier (OTA) for SC circuits that operates with a supply voltage of less than two transistor threshold voltages is presented. Its simplicity relies on the use of a low-voltage regulated cascode circuit, which achieves very high output impedance under low-voltage restrictions. The OTA has been designed to operate with a supply voltage of V/sub DD/=1.5 V, using a 0.6 /spl mu/m CMOS technology with transistor threshold voltages of V/sub TN/=0.75 V and V/sub TP/=-0.85 V. Post-layout simulation results for a load capacitance (C/sub L/) of 2 pF show a 75 MHz gain-bandwidth product and 100 dB DC gain with a quiescent power consumption of 750 /spl mu/W.     

An ultra-wideband CMOS low noise amplifier for 3-5-GHz UWB system

An ultra-wideband (UWB) CMOS low noise amplifier (LNA) topology that combines a narrowband LNA with a resistive shunt-feedback is proposed. The resistive shunt-feedback provides wideband input matching with small noise figure (NF) degradation by reducing the Q-factor of the narrowband LNA input and flattens the passband gain. The proposed UWB amplifier is implemented in 0.18-/spl mu/m CMOS technology for a 3.1-5-GHz UWB system. Measurements show a -3-dB gain bandwidth of 2-4.6GHz, a minimum NF of 2.3 dB, a power gain of 9.8 dB, better than -9 dB of input matching, and an input IP3 of -7dBm, while consuming only 12.6 mW of power.     

A CMOS ultra-wideband impulse radio transceiver for 1-mb/s data communications and /spl plusmn/2.5-cm range finding

A CMOS ultra-wideband impulse radio (UWB-IR) transceiver was developed in 0.18-/spl mu/m CMOS technology. It can be used for 1-Mb/s data communications as well as for precise range finding within an error of /spl plusmn/2.5 cm. The power consumptions of the transmitter and receiver for data communication are 0.7 and 4.0 mW, respectively. When an LNA operates intermittently through bias switching, the power consumption of the transceiver is only 1 mW. The range for data communication is 1 m with BER of 10/sup -3/. For ranging applications, the transmitter can reduce the power to 0.7 /spl mu/W for 1k pulses per second, and the receiver consumes little power. The transceiver design, all-digital transmitter, and intermittent circuit operation at the receiver reduce the power consumption dramatically, which makes the transceiver well suited for applications like sensor networks. The electronic field intensity is lower than 35 /spl mu/V/m, and thus the UWB system can be operated even under the current Japan radio regulations.