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 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     

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 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 multimode 0.3-200-kb/s transceiver for the 433/868/915-MHz bands in 0.25-/spl mu/m CMOS

A fully integrated transceiver suitable for low-data-rate wireless telemetry and sensor networks operating in the license-free ISM frequency bands at 433, 868, or 915 MHz implemented in 0.25-/spl mu/m CMOS is presented. G/FSK, ASK, and OOK modulation formats are supported at data rates from 0.3 to 200 kb/s. The transceiver's analog building blocks include a low-noise amplifier, mixer, channel filter, received signal-strength indication, frequency synthesizer, voltage-controlled oscillator, and power amplifier. FSK demodulation is implemented using a novel digital complex-frequency correlator that operates over a wide modulation-index range and approximates matched filter detection performance. Automatic gain control, automatic frequency control, and symbol timing recovery loops are included on chip. Operating in the 915-MHz band in FSK mode at 9.6 kb/s, the receiver consumes 19.7 mA from a 3-V supply and achieves a sensitivity of -112.8dBm at 0.1% BER. The transmitter consumes 28.5 mA for an output power of 10 dBm and delivers up to 14 dBm.     

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 WiMedia/MBOA-Compliant CMOS RF Transceiver for UWB

A WiMedia/MBOA compliant RF transceiver for ultra-wideband data communication in the 3-5-GHz band is presented. The transceiver includes receiver, transmitter and synthesizer is completely integrated in 0.13-mum standard CMOS technology. The receiver uses a feedback-based low-noise amplifier (LNA) to obtain an RF gain of 4 to 37 dB and an overall measured noise figure of 3.6 to 4.1 dB over the 3-5-GHz band of interest. The transmitter supports an error vector magnitude (EVM) of -28 dB up to -4 dBm output power and meets the FCC and WiMedia mask specifications. The power consumption from a single supply voltage of 1.5 V is 237 mW for the receiver and 284 mW for the transmitter, both including the synthesizer     

A Single-Chip CMOS Transceiver for UHF Mobile RFID Reader

This paper describes a single-antenna low-power single-chip radio frequency identification (RFID) reader for mobile phone applications. The reader integrates an RF transceiver, data converters, a digital baseband modem, an MPU, memory, and host interfaces. The direct conversion RF receiver architecture with the highly linear RF front-end circuit and DC offset cancellation circuit is used to give good immunity to the large transmitter leakage. It is suitable for a mobile phone reader with single-antenna architecture and low-power reader solution. The transmitter is implemented in the direct I/Q up-conversion architecture. The frequency synthesizer based on a fractional-N phase-locked-loop topology offering 900 MHz quadrature LO signals is also integrated with the RF transceiver. The reader is fabricated in a 0.18 mum CMOS technology, and its die size is 4.5 mm times 5.3 mm including electrostatic discharge I/O pads. The reader consumes a total current of 89 mA apart from the external power amplifier with 1.8 V supply voltage. It achieves an 8 dBm P1dB, an 18.5 dBm IIP3, and a maximum transmitter output power of 4 dBm.     

应用于IEEE 802.11b无线局域网系统的2.4GHzCMOS单片收发机射频前端

实现了一个应用于IEEE 802.11b无线局域网系统的2.4GHz CMOS单片收发机射频前端,它的接收机和发射机都采用了性能优良的超外差结构.该射频前端由五个模块组成:低噪声放大器、下变频器、上变频器、末前级和LO缓冲器.除了下变频器的输出采用了开漏级输出外,各模块的输入、输出端都在片匹配到50Ω.该射频前端已经采用0.18μm CMOS工艺实现.当低噪声放大器和下变频器直接级联时,测量到的噪声系数约为5.2dB,功率增益为12.5dB,输入1dB压缩点约为-18dBm,输入三阶交调点约为-7dBm.当上变频器和末前级直接级联时,测量到的噪声系数约为12.4dB,功率增益约为23.8dB,输出1dB压缩点约为1.5dBm,输出三阶交调点约为16dBm.接收机射频前端和发射机射频前端都采用1.8V电源,消耗的电流分别为13.6和27.6mA.     

Low-power-consumption direct-conversion CMOS transceiver for multi-standard 5-GHz wireless LAN systems with channel bandwidths of 5-20 MHz

This paper describes a low-power-consumption direct-conversion CMOS transceiver for WLAN systems operating at 4.9-5.95 GHz. Its power consumption is reduced by using a resonator-switching wide-dynamic-range LNA. The broad tuning range needed for multiple-channel-bandwidth systems is provided by a single widely tunable low-pass filter based on negative-source-degeneration-resistor transconductors, and its automatic frequency-band-selection PLL supports multiple standard 5-GHz WLAN systems. The system noise figure is 4.4 dB at a maximum gain of 74 dB, and the receiver IIP3 is +5 dBm and -21dBm for the minimum and maximum gain modes, respectively. The error vector magnitude (EVM) of the transmitted signal is 2.6%. The current consumption is extremely low, 65 mA in the transmitter path and 60 mA in the receiver path.     

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 2.4-GHz Low-Power Low-IF Receiver and Direct-Conversion Transmitter in 0.18-μm CMOS for IEEE 802.15.4 WPAN Applications

In this paper, a low-power low-IF receiver and a direct-conversion transmitter (DCT) suitable for the IEEE standard 802.15.4 radio system at the 2.4-GHz band are presented in 0.18-mum deep n-well CMOS technology. By using vertical NPN (V-NPN) bipolar junction transistors in the baseband analog circuits of the low-IF receiver, the image rejection performance is improved and the power consumption is reduced. In addition, by applying the V-NPN current mirrored technique in a DCT, the carrier leakage is reduced and the linearity performance is improved. The receiver has 10 dB of noise figure, -15 dBm of third-order input intercept point, and 35 dBc of image rejection. The transmitter has more than -2 dBm of transmit output power, -35 dBc of local oscillator leakage, and -46 dBc of the transmit third harmonic component. The receiver and transmitter dissipate 6 and 9 mA from a 1.8-V supply, respectively     

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 single-chip dual-band direct-conversion IEEE 802.11a/b/g WLAN transceiver in 0.18-/spl mu/m CMOS

This paper presents a single-chip dual-band CMOS direct-conversion transceiver fully compliant with the IEEE 802.11a/b/g standards. Operating in the frequency ranges of 2.412-2.484 GHz and 4.92-5.805 GHz (including the Japanese band), the fractional-N PLL based frequency synthesizer achieves an integrated (10 kHz-10 MHz) phase noise of 0.54/spl deg//1.1/spl deg/ for 2/5-GHz band. The transmitter error vector magnitude (EVM) is -36/-33 dB with an output power level higher than -3/-5dBm and the receiver sensitivity is -75/-74 dBm for 2/5-GHz band for 64QAM at 54 Mb/s.     

A 900-MHz dual-conversion low-IF GSM receiver in 0.35-μm CMOS

A low-power fully integrated GSM receiver is developed in 0.35-μm CMOS. This receiver uses dual conversion with a low IF of 140 kHz. This arrangement lessens the impact of the flicker noise. The first IF of 190 MHz best tolerates blocking signals. The receiver includes all of the circuits for analog channel selection, image rejection, and more than 100-dB controllable gain. The receiver alone consumes 22 mA from a 2.5-V supply, to give a noise figure of 5 dB, and input IP3 of -16 dBm. A single frequency synthesizer generates both LO frequencies. The integrated VCO with on-chip resonator and buffers consume another 8 mA, and meets GSM phase-noise specifications     

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.     

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.     

An interference-robust receiver for ultra-wideband radio in SiGe BiCMOS technology

A 3.1-4.8 GHz ultra-wideband (UWB) receiver front-end for high data rate, short-range communication is presented. The receiver, based on the Multi Band OFDM Alliance (MBOA) standard proposal, consists of a zero-IF receive chain and an ultra-fast frequency-hopping synthesizer. The combination of high-linearity RF circuits, aggressive baseband filtering and low local oscillator spurs from the synthesizer results in an interference-robust receiver, having the ability to co-exist with systems operating in the 2.4-GHz and 5-GHz ISM bands. The packaged device shows an overall noise figure of 4.5 dB and has a measured input IP3 of -6 dBm and input IP2 of +25 dBm. Spurious tones generated by the synthesizer are below -45 dBc and -50 dBc in the 2.4-GHz and 5-GHz ISM bands, respectively. The hopping speed is well below the required 9.5 ns. The complete receive chain has been realized in a 0.25 /spl mu/m BiCMOS technology and draws 78mA from a 2.5-V supply.     

A low-power monolithic CMOS transceiver for 802.11b wireless LANs

A single-chip low-power transceiver IC operating in the 2.4 GHz ISM band is presented. Designed in 0.18 μm CMOS, the transceiver system employs direct-conversion architecture for both the receiver and transmitter to realize a fully integrated wireless LAN product. A sigma-delta (∑△) fractional-N frequency synthesizer provides on-chip quadrature local oscillator frequency. Measurement results show that the receiver achieves a maximum gain of 81 dB and a noise figure of 8.2 dB, the transmitter has maximum output power of-3.4 dBm and RMS EVM of 6.8%. Power dissipation of the transceiver is 74 mW in the receiving mode and 81 mW in the transmitting mode under a supply voltage of 1.8 V, including 30 mW consumed by the frequency synthesizer. The total chip area with pads is 2.7×4.2 mm2.     

All-digital PLL and transmitter for mobile phones

We present the first all-digital PLL and polar transmitter for mobile phones. They are part of a single-chip GSM/EDGE transceiver SoC fabricated in a 90 nm digital CMOS process. The circuits are architectured from the ground up to be compatible with digital deep-submicron CMOS processes and be readily integrateable with a digital baseband and application processor. To achieve this, we exploit the new paradigm of a deep-submicron CMOS process environment by leveraging on the fast switching times of MOS transistors, the fine lithography and the precise device matching, while avoiding problems related to the limited voltage headroom. The transmitter architecture is fully digital and utilizes the wideband direct frequency modulation capability of the all-digital PLL. The amplitude modulation is realized digitally by regulating the number of active NMOS transistor switches in accordance with the instantaneous amplitude. The conventional RF frequency synthesizer architecture, based on a voltage-controlled oscillator and phase/frequency detector and charge-pump combination, has been replaced with a digitally controlled oscillator and a time-to-digital converter. The transmitter performs GMSK modulation with less than 0.5/spl deg/ rms phase error, -165 dBc/Hz phase noise at 20 MHz offset, and 10 /spl mu/s settling time. The 8-PSK EDGE spectral mask is met with 1.2% EVM. The transmitter occupies 1.5 mm/sup 2/ and consumes 42 mA at 1.2 V supply while producing 6 dBm RF output power.