A 2.4-GHz CMOS transceiver for Bluetooth

A fully integrated CMOS transceiver tuned to 2.4 GHz consumes 46 mA in receive mode and 47 mA in transmit mode from a 2.7-V supply. It includes all the receive and transmit building blocks, such as frequency synthesizer, voltage-controlled oscillator (VCO), power amplifier, and demodulator. The receiver uses a low-IF architecture for higher level of integration and lower power consumption. It achieves a sensitivity of -82 dBm at 0.1% BER, and a third-order input intercept point (IIP3) of -7 dBm. The direct-conversion transmitter delivers a GFSK modulated spectrum at a nominal output power of 4 dBm. The on-chip voltage controlled oscillator has a close-in phase-noise of -120 dBc/Hz at 3-MHz offset     

CMOS highly linear direct-conversion transmitter for WCDMA with fine gain accuracy

A highly linear,high output power,0.13μm CMOS direct conversion transmitter for wideband code division multiple access(WCDMA) is described.The transmitter delivers 6.8 dBm output power with 38 mA current consumption.With careful design on the resistor bank in the IQ-modulator,the gain step accuracy is within 0.1 dB,hence the image rejection ratio can be kept below—47 dBc for the entire output range.The adjacent channel leakage ratio and the LO leakage at 6.8 dBm output power are -44 dBc @ 5 MHz and -37 dBc,respectively,and the corresponding EVM is 3.6%.The overall gain can be programmed in 6 dB steps in a 66-dB range.     

用于WCDMA的高线性，高增益精度的直接变频发射机

本文描述了一个高线性,高输出功率的直接变频发射机。该发射机针对宽频码分多工存取标准设计,在0.13微米CMOS工艺下实现。本系统最大输出功率为6.8dBm,消耗的电流为38mA。在最大输出功率下,邻道功率泄漏（ACLR）和载波泄漏分别为-44dBc@5MHz和-37dBc,相应的误差矢量振幅（EVM）为3.6%。整个系统可以以6dB为步长实现66dB的增益控制范围,通过电阻阵列的微调功能,增益控制精度可以达到0.1dB以内。系统的镜像抑制比可以在整个输出范围内保持在-47dBc以下。     

5-GHz SiGe HBT monolithic radio transceiver with tunable filtering

A wide-band CDMA-compliant fully integrated 5-GHz radio transceiver was realized in SiGe heterojunction-bipolar-transistor technology with on-chip tunable voltage controlled oscillator (VCO) tracking filters. It allows for wide-band modulation schemes with bandwidth up to 20 MHz. The receiver has a single-ended single-sideband noise figure of 5.9 dB, more than 40 dB on-chip image rejection, an input compression point of -22 dBm, and larger than 70 dB local-oscillator-RF isolation. The phase noise of the on-chip VCO is -100 and -128 dBc/Hz at 100 kHz and 5 MHz offset from the carrier, respectively. The transmitter output compression point is +10 dBm. An image rejection better than 40 dB throughout the VCO tracking range has been demonstrated in the transmitter with all spurious signals 40 dB below the carrier. The differential transceiver draws 125 mA in transmit mode and 45 mA in receive mode from a 3.5-V supply     

适于视频应用的高数据传输率集成CMOS收发机

这篇文章给出了一个5GHz CMOS射频收发机的设计方案。此设计采用0.18微米射频CMOS加工工艺,集合了最新IEEE802.11n的特性例如多输入多输出技术的专利协议以及其他无线技术,可提供应用在家庭环境中的实时高清电视数据的无线高速传输。设计频率涵盖了从4.9GHz到5.9GHz的ISM频带,每个射频信道的频宽为20MHz。收发机采用了直接上变频发射器和低中频接收器的结构。在没有片上校准的情况下,设计采用双正交直接上变频混频器,得到了超过35dB的镜像抑制。测试结果得到6dB接收机噪声系数以及在-3dBm输出功率时得到发射机EVM结果优于33dB。     

A low-power CMOS Bluetooth RF transceiver with a digital offset canceling DLL-based GFSK demodulator

This paper presents a fully integrated 0.18-/spl mu/m CMOS Bluetooth transceiver. The chip consumes 33 mA in receive mode and 25 mA in transmit mode from a 3-V system supply. The receiver uses a low-IF (3-MHz) architecture, and the transmitter uses a direct modulation with ROM-based Gaussian low-pass filter and I/Q direct digital frequency synthesizer for high level of integration and low power consumption. A new frequency shift keying demodulator based on a delay-locked loop with a digital frequency offset canceller is proposed. The demodulator operates without harmonic distortion, handles up to /spl plusmn/160-kHz frequency offset, and consumes only 2 mA from a 1.8-V supply. The receiver dynamic range is from -78 dBm to -16 dBm at 0.1% bit-error rate, and the transmitter delivers a maximum of 0 dBm with 20-dB digital power control capability.     

A 0.25-μm CMOS 1.9-GHz PHS RF Transceiver With a 150-kHz Low-IF Architecture

We present a 1.9-GHz Personal Handy-phone System (PHS) transceiver, fully integrated and fabricated in 0.25-mum CMOS technology. The receiver is based on a 150-kHz low-IF architecture and meets the fast channel switching and DC-offset cancellation requirements of PHS. It includes a low-noise amplifier (LNA), a downconversion mixer, a complex filter, and a programmable gain amplifier. A fractional-N frequency synthesizer achieves seamless handover with a 25 mus channel switching time and a phase noise of -121 dBc/Hz at a 600-kHz offset frequency, with compliant ACS performance. The receiver provides -105 dBm sensitivity and 55 dBc ACS at a 600-kHz frequency offset. The transmitter is based on the direct modulation architecture and consists of an upconversion mixer and a pre-driver stage. The gain of the pre-driver is digitally controllable to suit any type of commercial power amplifier. The transmitter shows a 3% EVM and a 65 dBc ACPR at a 600-kHz offset frequency. The whole transceiver occupies 15.2 mm² and dissipates 70 mA in RX and 44 mA in TX, with a 2.8-V supply     

A 1.9-GHz Single-Chip CMOS PHS Cellphone

A single-chip CMOS PHS cellphone, integrated in a 0.18-mum CMOS technology, implements all handset functions including radio, voice, audio, MODEM, TDMA controller, CPU, and digital interfaces. Both the receiver and transmitter are based on a direct conversion architecture. The RF transceiver achieves -106 dBm receive sensitivity and +4 dBm EVM-compliant transmit power. The local oscillator, based on a sigma-delta fractional-N synthesizer, has a phase noise of -118 dBc/Hz at 600kHz offset and settling time of 15 mus. The current consumption for the receiver, transmitter and synthesizer are 32 mA, 29 mA, and 25 mA, respectively, from a 3.0 V supply     

A Bluetooth radio in 0.18-/spl mu/m CMOS

This paper describes the results of an implementation of a Bluetooth radio in a 0.18-/spl mu/m CMOS process. A low-IF image-reject conversion architecture is used for the receiver. The transmitter uses direct IQ-upconversion. The VCO runs at 4.8-5.0 GHz, thus facilitating the generation of 0/spl deg/ and 90/spl deg/ signals for both the receiver and transmitter. By using an inductor-less LNA and the extensive use of mismatch simulations, the smallest silicon area for a Bluetooth radio implementation so far can be reached: 5.5 mm/sup 2/. The transceiver consumes 30 mA in receive mode and 35 mA in transmit mode from a 2.5 to 3.0-V power supply. As the radio operates on the same die as baseband and SW, the crosstalk-on-silicon is an important issue. This crosstalk problem was taken into consideration from the start of the project. Sensitivity was measured at -82 dBm.     

A Fully Integrated 2.4-GHz IEEE 802.15.4-Compliant Transceiver for ZigBee™ Applications

A single-chip 2.4-GHz CMOS radio transceiver with integrated baseband processing according to the IEEE 802.15.4 standard is presented. The transceiver consumes 14.7 mA in receive mode and 15.7 mA in transmit mode. The receiver uses a low-IF topology for high sensitivity and low power consumption, and achieves -101 dBm sensitivity for 1% packet error rate. The transmitter topology is based on a PLL direct-modulation scheme. Optimizations of architecture and circuit design level in order to reduce the transceiver power consumption are described. Special attention is paid to the RF front-end design which consumes 2.4mA in receive mode and features bidirectional RF pins. The 5.77 mm² chip is implemented in a standard 0.18-mum CMOS technology. The transmitter delivers +3 dBm into the 100-Omega differential antenna port     

A dual-mode 802.11b/bluetooth radio in 0.35-/spl mu/m CMOS

A fully integrated dual-mode CMOS transceiver tuned to 2.4 GHz consumes 65 mA in receive mode and 78 mA in transmit mode from a 3-V supply. The radio includes all the receive and transmit building blocks, such as frequency synthesizer, voltage-controlled oscillator (VCO), and power amplifier, and is intended for use in 802.11b and Bluetooth applications. The Bluetooth receiver uses a low-IF architecture for higher level of integration and lower power consumption, while the 802.11b receiver is direct conversion. The receiver achieves a typical sensitivity of -88 dBm at 11 Mb/s for 802.11b, and -83 dBm for Bluetooth mode. The receiver minimum IIP3 is -8 dBm. Both transmitters use a direct-conversion architecture, and deliver a nominal output power of 0 dBm, with a power range of 20 dB in 2-dB steps.     

A 3.1 GHz–8.0 GHz Single-Chip Transceiver for MB-OFDM UWB in 0.18-$mu$ m CMOS Process

This paper presents the design and integration of a fully-integrated dual-conversion zero-IF2 CMOS transceiver for 9-band MB-OFDM UWB systems from 3.1 GHz to 8.0 GHz. The transceiver integrates all building blocks including a variable-gain wideband LNA, a single combined mixer for both RF down-conversion in RX and up-conversion in TX, a fast-settling frequency synthesizer, and IQ ADCs and DACs. Fabricated in a standard 0.18- mum CMOS process, the receiver measures maximum S11 of - 13 dB, maximum NF of 8.25 dB, in-band IIP3 of better than -13.7 dBm, and variable gain from 25.3 to 84.0 dB. IQ path gain and phase mismatches of the receiver chain are measured to be 0.8 dB and 4 ^deg, respectively. The transmitter achieves a minimum output P-1 dB of -8.2 dBm, sideband rejection of better than -42.2 dBc, and LO leakage of smaller than - 46.5 dBc.     

A 5.25-GHz image rejection RF front-End Receiver With Polyphase filters

A 5.25-GHz image rejection (IR) radio frequency (RF) front-end receiver is proposed, which is implemented in 0.18-/spl mu/m CMOS technology. The proposed receiver adopts both a high-intermediate frequency (IF) and the double quadrature architecture to achieve high IR at 5-GHz frequency. The measured results show a power gain of 14 dB, a minimum noise figure of 7.9dB, and IIP3 of -8dBm. The measured maximum image rejection ratio is 45dBc. The receiver consumes a total of 32mA from a 1.8-V supply.     

A 5-GHz radio front-end with automatically Q-tuned notch filter and VCO

A low-voltage receiver front-end for 5-GHz radio applications is presented. The receiver consists of a low-noise amplifier (LNA) with notch filter, a voltage-controlled oscillator (VCO), and a mixer. The LNA/notch filter has an automatic Q-tuning circuit integrated with it to provide good image rejection. On-chip transformers are used extensively in the receiver to improve performance and facilitate low-voltage operation. The receiver has a gain of 19.8 dB, noise figure of 4.5 dB, a third-order input intercept point (IIP3) of -11.5 dBm, and an image rejection of 59 dB, and the VCO had a phase noise of -116 dBc/Hz at 1-MHz offset.     

A 5.4 mW/0.07 mm$^{2}$ 2.4 GHz Front-End Receiver in 90 nm CMOS for IEEE 802.15.4 WPAN Standard

An integrated 2.4 GHz CMOS receiver front-end according to the IEEE 802.15.4 standard is presented in this paper. It integrates the overall RF part, from the balun up to the first stage of the channel filter, as well as the cells for the LO signal conditioning. The proposed architecture is based on a 6 MHz low-IF topology, which uses an inductorless LNA and a new clocking scheme for driving a passive mixer. When integrated in a 90 nm CMOS technology, the receiver front-end exhibits an area of only 0.07 mm², or 0.23 mm² when including an input integrated balun. The overall chip consumes 4 mA from a single 1.35 V supply voltage and it achieves a 35 dB conversion gain from input power in dBm to output voltage in dBvpk, a 7.5 dB NF value, -10 dBm of IIP3 and more than 32 dB of image rejection.     

A monolithic 3.1-4.8 GHz MB-OFDM UWB transceiver in 0.18-μm CMOS

A monolithic RF transceiver for an MB-OFDM UWB system in 3.1-4.8 GHz is presented.The transceiver adopts direct-conversion architecture and integrates all building blocks including a gain controllable wideband LNA,a I/Q merged quadrature mixer,a fifth-order Gm-C bi-quad Chebyshev LPF/VGA,a fast-settling frequency synthesizer with a poly-phase filter,a linear broadband up-conversion quadrature modulator,an active D2S converter and a variablegain power amplifier.The ESD protected transceiver is fabricated in Jazz Semiconductor's 0.18-μm RF CMOS with an area of 6.1 mm2 and draws a total current of 221 mA from 1.8-V supply.The receiver achieves a maximum voltage gain of 68 dB with a control range of 42 dB in 6 dB/Step,noise figures of 5.5-8.8 dB for three sub-bands,and an inband/out-band IIP3 better than-4 dBm/+9 dBm.The transmitter achieves an output power ranging from-10.7 to-3dBm with gain control,an output P1dB better than-7.7 dBm,a sideband rejection about 32.4 dBc,and LO suppression of 31.1 dBc.The hopping time among sub-bands is less than 2.05 ns.     

A 3.1-4.8 GHz transmitter with a high frequency divider in 0.18 μm CMOS for OFDM-UWB

A fully integrated low power RF transmitter for a WiMedia 3.1-4.8 GHz multiband orthogonal frequency division multiplexing ultra-wideband system is presented. With a separate transconductance stage, the quadrature up-conversion modulator achieves high linearity with low supply voltage. The co-design of different resonant frequencies of the modulator and the differential to single (D2S) converter ensures in-band gain flatness. By means of a series inductor peaking technique, the D2S converter obtains 9 dB more gain without extra power consumption. A divided-by-2 divider is used for carrier signal generation. The measurement results show an output power between -10.7 and -3.1 dBm with 7.6 dB control range, an OIP3 up to 12 dBm, a sideband rejection of 35 dBc and a carrier rejection of 30 dBc. The ESD protected chip is fabricated in the Jazz 0.18/zm RF CMOS process with an area of 1.74 mm~2 and only consumes 32 mA current (at 1.8 V) including the test associated parts.     

An 863-870 MHz spread-spectrum FSK transceiver design for wireless sensor

Simulation results of a 863-870 MHz frequency-hopped spread-spectrum (FHSS) transceiver with binary frequency shift keying (BFSK) modulation at 20 kb/s for wireless sensor applications is presented.The transmit/receive RF front end contains a BFSK modulator, an upconversion mixer, a power amplifier (PA), and an 863-870 MHz band pass filter (BPF) at the transmitter side and a low-noise amplifier with down conversion mixer to zero-IF, a low-pass channel-select filter, a limiter and a BFSK demodulator at the receiver side. The various block parameters of the transmit/receive RF front end like noise figure (NF), gain, 1 dB compression point (P-1 dB), and IIP3 are simulated and optimized to meet low power and low cost transceiver specifications.The transmitter simulations show an output ACPR (adjacent channel power ratio) of −22 dBc, 3.3 dBm P-1 dB of PA, and transmitted power of 0 dBm. The receiver simulations show 51.1 dB conversion gain, −7 dBm IIP3, −15 dB return loss (S11), and 10 dB NF. Low power arctangent-differentiated BFSK demodulator has been chosen and the BER performance has been co simulated with the analog receiver. The complete receiver achieves a BER of 10⁻³ at 10.5 dB of EbtoNo. The transceiver simulations show an RMS frequency error of 1.45 kHz.     

A fully integrated 900-MHz CMOS wireless receiver with on-chip RF and IF filters and 79-dB image rejection

A monolithic 900-MHz CMOS wireless receiver with on-chip RF and IF filters and a fully integrated fractional-N synthesizer is presented. Implemented in a standard 0.5-/spl mu/m CMOS process and without any off-chip component, the complete receiver has a measured image rejection of 79 dB, a sensitivity of -90 dBm, an IIP3 of -24 dBm, and a noise figure of 22 dB with a power of 227 mW and a chip area of 5.7 mm/sup 2/. The synthesizer achieves a phase noise of -118 dBc/Hz at 600 kHz offset and a settling time of less than 150 /spl mu/s.     

Low-power transceiver analog front-end circuits for bidirectional high data rate wireless telemetry in medical endoscopy applications

State-of-the-art endoscopy systems require electronics allowing for real-time, bidirectional data transfer. Proposed are 2.4-GHz low-power transceiver analog front-end circuits for bidirectional high data rate wireless telemetry in medical endoscopy applications. The prototype integrates a low-IF receiver analog front-end [low noise amplifier (LNA), double balanced down-converter, bandpass-filtered automatic gain controlled (AGC) loop and amplitude-shift keying (ASK) demodulator], and a direct up-conversion transmitter analog front-end [20-MHz IF phase-locked loop (PLL) with well-defined amplitude control circuit, ASK modulator, up-converter, and power amplifier] on a single chip together with an internal radio frequency oscillator and local oscillating (LO) buffers. Design tradeoffs have been made over the boundaries of the different building blocks to optimize the overall system performance. All building blocks feature circuit topologies that enable comfortable operation at low power consumption. The circuits have been implemented in a 0.25-microm CMOS process. The measured sensitivity of the receiver analog front-end is -70 dBm with a data rate of 256 kbps, and the measured output power of the transmitter analog front-end could achieve -23 dBm with a data rate of 1 Mbps. The integrated circuit consumes a current of 6 mA in receiver mode and 5.6 mA in transmitter mode with a power supply of 2.5 V. This paper shows the feasibility of achieving the analog performance required by the wireless endoscopy capsule system in 0.25 microm CMOS.