A direct-conversion CMOS transceiver for the 802.11a/b/g WLAN standard utilizing a Cartesian feedback transmitter

A fully integrated dual-band transceiver is implemented in 0.18-/spl mu/m CMOS and is compliant with the IEEE 802.11a/b/g standards. The direct-conversion transceiver occupies 12 mm/sup 2/ in a QFN-40 package. A fractional-N synthesizer operates at twice the channel frequency, covering continuously bands from 4.9 to 5.9 GHz, as well as the 2.4-GHz band. The 5- and 2.4-GHz receivers achieve a sensitivity level below -73 dBm in the 54-Mb/s mode and below -93 dBm in the 6-Mb/s mode, while consuming 230 mW. A fast RSSI-channel power-detection system allows to power-down signal processing in the listen mode. The 5- and 2.4-GHz transmitters implement a wideband Cartesian feedback loop for enhanced EVM performances and improved spectrum masks compliance. The transmitters deliver -2-dBm average power with an EVM of 3% in the 54-Mb/s mode while consuming 300 mW.     

A 52?pJ/bit 433-MHz low power OOK transmitter

An OOK transmitter in 433-MHz ISM band employing a speed-up circuit is described. The proposed speed-up circuit accelerates the start-up of the oscillator and buffer by briefly increasing the bias currents during transmission of bit “1”. This leads to a data rate increase from 3 to 10-Mb/s without any penalty on power consumption. The data rate can also be made adaptable by varying the duration in which the bias current is increased. The proposed OOK transmitter is implemented in 0.35-μm CMOS technology. The measured results show that the transmitter achieves a maximum data rate of 10-Mb/s with a dc power consumption of 518 μW from a 1-V power supply, yielding an energy efficiency of 52 pJ/bit or 0.97 nJ/bit/mW when normalized to the output power. This paper also derives a closed form equation which describes the transient behavior of Colpitts oscillator during start up.     

A 1.8-V 2.4/5.15-GHz dual-band LCVCO in 0.18-/spl mu/m CMOS technology

A dual band, fully integrated, low phase-noise and low-power LC voltage-controlled oscillator (VCO) operating at the 2.4-GHz industrial scientific and medical band and 5.15-GHz unlicensed national information infrastructure band has been demonstrated in an 0.18-/spl mu/m CMOS process. At 1.8-V power supply voltage, the power dissipation is only 5.4mW for a 2.4-GHz band and 8mW for a 5.15-GHz band. The proposed VCO features phase-noise of -135dBc/Hz at 3-MHz offset frequency away from the carrier frequency of 2.74GHz and -126dBc/Hz at 3-MHz offset frequency away from 5.49GHz. The oscillator is tuned from 2.2 to 2.85GHz in the low band (2.4-GHz band) and from 4.4 to 5.7GHz in the high band (5.15-GHz band).     

A 20-Gb/s 1 : 2 Demultiplexer With Capacitive-Splitting Current-Mode-Logic Latches

This paper presents a high-speed 1:2 demultiplexer (DEMUX) implemented in a 0.18-mum CMOS process. By employing a capacitive-splitting architecture for the current-mode-logic latches, a significant speed improvement is achieved in the proposed DEMUX. Provided a 2²³ - 1 pseudorandom bit sequence from the pattern generator, the fabricated circuit operates at an input data rate up to 20 Gb/s. The fully integrated DEMUX consumes a dc power of 150 mW from a 2-V supply voltage.     

A 2.5-10-GHz clock multiplier unit with 0.22-ps RMS jitter in standard 0.18-/spl mu/m CMOS

This paper demonstrates a low-jitter clock multiplier unit that generates a 10-GHz output clock from a 2.5-GHz reference clock. An integrated 10-GHz LC oscillator is locked to the input clock, using a simple and fast phase detector circuit that overcomes the speed limitation of a conventional tri-state phase frequency detector due to the lack of an internal feedback loop. A frequency detector guarantees PLL locking without degenerating jitter performance. The clock multiplier is implemented in a standard 0.18-/spl mu/m CMOS process and achieves a jitter generation of 0.22 ps while consuming 100 mW power from a 1.8-V supply.     

A 10-bit 1-GSample/s Nyquist current-steering CMOS D/A converter

In this paper, a 10-bit 1-GSample/s current-steering CMOS digital-to-analog (D/A) converter is presented. The measured integral nonlinearity is better than ±0.2 LSB and the measured differential nonlinearity lies between -0.08 and 0.14 LSB proving the 10-bit accuracy. The 1-GSample/s conversion rate has been obtained by an, at transistor level, fully custom-designed thermometer decoder and synchronization circuit. The layout has been carefully optimized. The parasitic interconnect loads have been estimated and have been iterated in the circuit design. A spurious-free dynamic range (SFDR) of more than 61 dB has been measured in the interval from dc to Nyquist. The power consumption equals 110 mW for a near-Nyquist sinusoidal output signal at a 1-GHz clock. The chip has been processed in a standard 0.35-μm CMOS technology and has an active area of only 0.35 mm²     

A 2.125-Gb/s BiCMOS fiber channel transmitter for serial datacommunications

A 2.125-Gb/s transmitter meeting the specifications of the emerging ANSI Fiber Channel standard has been developed using BiCMOS technology. This transmitter features (1) a fully bipolar 10:1 multiplexer (MUX) and a 2.125-GHz retimer for high-accuracy transmission of data, (2) an emitter-coupled logic (ECL) CMOS analog phase-locked loop, (3) pure ECL-level output for direct connection to the currently available optical modules, and (4) BiCMOS process technology that includes 0.25-μm CMOS devices and 20-GHz bipolar devices. The LSI serializes 32-bit-wide, 53.125-Mb/s data into 2.125-Gb/s data through a CMOS 8B10B encoder. The chip area is 3×2 mm², and the power dissipation is 860 mW     

A 20-Gb/s 0.13-/spl mu/m CMOS serial link transmitter using an LC-PLL to directly drive the output multiplexer

A 20-Gb/s transmitter is implemented in 0.13-/spl mu/m CMOS technology. An on-die 10-GHz LC oscillator phase-locked loop (PLL) creates two sinusoidal 10-GHz complementary clock phases as well as eight 2.5-GHz interleaved feedback divider clock phases. After a 2/sup 20/-1 pseudorandom bit sequence generator (PRBS) creates eight 2.5-Gb/s data streams, the eight 2.5-GHz interleaved clocks 4:1 multiplex the eight 2.5-Gb/s data streams to two 10-Gb/s data streams. 10-GHz analog sample-and-hold circuits retime the two 10-Gb/s data streams to be in phase with the 10-GHz complementary clocks. Two-tap equalization of the 10-Gb/s data streams compensate for bandwidth rolloff of the 10-Gb/s data outputs at the 10-GHz analog latches. A final 20-Gb/s 2:1 output multiplexer, clocked by the complementary 10-GHz clock phases, creates 20-Gb/s data from the two retimed 10-Gb/s data streams. The LC-VCO is integrated with the output multiplexer and analog latches, resonating the load and eliminating the need for clock buffers, reducing power supply induced jitter and static phase mismatch. Power, active die area, and jitter (rms/pk-pk) are 165 mW, 650 /spl mu/m/spl times/350 /spl mu/m, and 2.37 ps/15 ps, respectively.     

A 6.5-GHz energy-efficient BFSK modulator for wireless sensor applications

A 6.5-GHz FSK modulator suitable for low power wireless sensor network is presented. The energy efficient modulator employs closed-loop direct VCO modulation to achieve high data rate, multistage variable loop bandwidth technique for fast startup time and /spl Sigma/-/spl Delta/ for reduced power consumption in the synthesizer with fine resolution in frequency channel selection. The modulator, implemented using 0.25-/spl mu/m CMOS, achieves 20-/spl mu/s startup time with an effective data rate of 2.5 Mb/s while consuming 22 mW.     

An ultralow power CMOS/SIMOX programmable counter LSI

We designed and fabricated an extremely low-power CMOS/SIMOX programmable counter large scale integrated circuits (LSI) for high-speed phase-locked loop (PLL) frequency synthesizer applications. This was to verify the potential usefulness of ultrathin-film 0.24-μm-gate CMOS/SIMOX process technology for creating an extremely low-power LSI containing high-speed circuits operating at frequencies of at least 1 GHz and at low supply voltages. While operating at up to 2.2 GHz and consuming only 4.5 mW at 1.5 V, it is capable of 4-GHz performance with power consumption of 19 mW at 2.5 V. Even at a low supply voltage of 1.5 V, high input-sensitivity was also achieved in the 1- to 2-GHz frequency range. These low-power and high input-sensitivity characteristics outperform those of state-of-the-art BiCMOS PLL LSIs     

A Low-Power 114-GHz Push–Push CMOS VCO Using LC Source Degeneration

An LC source-degeneration negative-resistance cell of an LC VCO is investigated, which is capable of operating at millimeter-wave (MMW) range with low dc power consumption. Several negative-resistance cells in LC oscillators are also compared. The LC source-degenerated topology is demonstrated through a 114-GHz push-push fully integrated LC VCO implemented in TSMC 0.13-mum CMOS process. With core power consumption of 8.4 mW, the tuning range at the fundamental port is 56.4-57.6 GHz and at the push-push port is 112.8-115.2 GHz. The measured phase noise at the fundamental port is -13.6 dBc/Hz at 10-MHz offset. This VCO is believed to have the best figure of merit among MMW VCOs using bulk CMOS processes.     

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.     

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.     

A 15/30-GHz Dual-Band Multiphase Voltage-Controlled Oscillator in 0.18- μm CMOS

A multiphase oscillator suitable for 15/30-GHz dual-band applications is presented. In the circuit implementation, the 15-GHz half-quadrature voltage-controlled oscillator (VCO) is realized by a rotary traveling-wave oscillator, while frequency doublers are adopted to generate the quadrature output signals at the 30-GHz frequency band. The proposed circuit is fabricated in a standard 0.18-mum CMOS process with a chip area of 1.1times1.0 mm². Operated at a 2-V supply voltage, the VCO core consumes a dc power of 52 mW. With a frequency tuning range of 250 MHz, the 15-GHz half-quadrature VCO exhibits an output power of -8 dBm and a phase noise of -112 dBc/Hz at 1-MHz offset frequency. The measured power level and phase noise of the 30-GHz quadrature outputs are -16 dBm and -104 dBc/Hz, respectively     

Analysis and Design of Two Low-Power Ultra-Wideband CMOS Low-Noise Amplifiers With Out-Band Rejection

Two 3–5-GHz low-power ultra-wideband (UWB) low-noise amplifiers (LNAs) with out-band rejection function using 0.18- $mu{hbox{m}}$ CMOS technology are presented. Due to the Federal Communications Commission's stringent power-emission limitation at the transmitter, the received signal power in the UWB system is smaller than those of the close narrowband interferers such as the IEEE 802.11 a/b/g wireless local area network, and the 1.8-GHz digital cellular service/global system for mobile communications. Therefore, we proposed a wideband input network with out-band rejection capability to suppress the out-band properties for our first UWB LNA. Moreover, a feedback structure and dual-band notch filter with low-power active inductors will further attenuate the out-band interferers without deteriorating the input matching bandwidth in the second UWB LNA. The 55/48/45 dB maximum rejections at 1.8/2.4/5.2 GHz, a power gain of 15 dB, and 3.5-dB minimum noise figure can be measured while consuming a dc power of only 5 mW.      

A 20-Gb/s Burst-Mode Clock and Data Recovery Circuit Using Injection-Locking Technique

A 20-Gb/s clock and data recovery circuit incorporates injection-locking technique to achieve high-speed operation with low power dissipation. The circuit creates spectral line at the frequency of data rate and injection-locks two cascaded LC oscillators. A frequency-monitoring mechanism is employed to ensure a close matching between the VCO natural frequency and data rate. Fabricated in 90-nm CMOS technology, this circuit achieves a bit error rate of less than 10^-9 in both continuous (PRBS of 2³¹-1) and burst modes while consuming 175 mW from a 1.5-V supply.     

A high-speed 64K CMOS RAM with bipolar sense amplifiers

A TTL-compatible 64K static RAM with CMOS-bipolar circuitry has been developed using a 1.2-/spl mu/m MoSi gate n-well CMOS-bipolar technology. Address access time is typically 28 ns, with 225 mW active power and 100 nW standby power. A CMOS six-transistor memory cell is used. The cell size is 18/spl times/20 /spl mu/m, and the chip size is 5.95/spl times/6.84 mm. The n-p-n transistors are used in the sense amplifiers, voltage regulators, and level clamping circuits. The bipolar sense amplifiers reduce the detectable bit line swing, thus improving the worst-case bit line delay time and the sensing delay time. In order to reduce the word line delay, the MoSi layer, which has 5 /spl Omega//sheet resistivity, was used for the gate material. The n-well CMOS process is based on a scaled CMOS process, and collector-isolated n-p-n transistors and CMOS are integrated simultaneously without adding any extra process steps and without causing any degradation of CMOS characteristics. The n-p-n transistor has a 2-GHz cutoff frequency at 1 mA collector current.     

A low-power 2.4-GHz transmitter/receiver CMOS IC

A 2.4-GHz CMOS receiver/transmitter incorporates circuit stacking and noninvasive baseband filtering to achieve a high sensitivity with low power dissipation. Using a single 1.6-GHz local oscillator, the transceiver employs two upconversion and downconversion stages while providing on-chip image rejection filtering. Realized in a 0.25-/spl mu/m digital CMOS technology, the receiver exhibits a noise figure of 6 dB and consumes 17.5 mW from a 2.5-V supply, and the transmitter delivers an output power of 0 dBm with a power consumption of 16 mW.     

A 0.35-/spl mu/m CMOS analog turbo decoder for the 40-bit rate 1/3 UMTS channel code

This work presents the design and the test results of an analog decoder for the 40-bit block length, rate 1/3, Turbo Code defined in the UMTS standard. The prototype is fully integrated in a three-metal double-poly 0.35-/spl mu/m CMOS technology, and includes an I/O interface that maximizes the decoder throughput. After the successful implementation of proof-of-concept analog iterative decoders by different research groups in both bipolar and CMOS technologies, this is the first reported prototype of an analog decoder for a realistic error-correcting code. The decoder was successfully tested at the maximum data rate defined in the standard (2 Mb/s), with an overall power consumption of 10.3 mW at 3.3 V, going down to 7.6 mW with the decoder core operated at 2 V, and an extremely low energy per decoded bit and trellis state (0.85 nJ for the decoder core alone).     

A high-speed 850-nm optical receiver front-end in 0.18-/spl mu/m CMOS

A high-speed optical interface circuit for 850-nm optical communication is presented. Photodetector, transimpedance amplifier (TIA), and post-amplifier are integrated in a standard 0.18-/spl mu/m 1.8-V CMOS technology. To eliminate the slow substrate carriers, a differential n-well diode topology is used. Device simulations clarify the speed advantage of the proposed diode topology compared to other topologies, but also demonstrate the speed-responsivity tradeoff. Due to the lower responsivity, a very sensitive transimpedance amplifier is needed. At 500 Mb/s, an input power of -8 dBm is sufficient to have a bit error rate of 3/spl middot/10/sup -10/. Next, the design of a broadband post-amplifier is discussed. The small-signal frequency dependent gain of the traditional and modified Cherry-Hooper stage is analyzed. To achieve broadband operation in the output buffer, so-called "f/sub T/ doublers" are used. For a differential 10 mV/sub pp/ 2/sup 31/-1 pseudo random bit sequence, a bit error rate of 5/spl middot/10/sup -12/ at 3.5 Gb/s has been measured. At lower bit-rates, the bit error rate is even lower: a 1-Gb/s 10-mV/sub pp/ input signal results in a bit error rate of 7/spl middot/10/sup -14/. The TIA consumes 17mW, while the post-amplifier circuit consumes 34 mW.