A 0.18-/spl mu/m SiGe BiCMOS receiver and transmitter chipset for SONET OC-768 transmission systems

A 43-Gb/s receiver (Rx) and transmitter (Tx) chip set for SONET OC-768 transmission systems is reported. Both ICs are implemented in a 0.18-/spl mu/m SiGe BiCMOS technology featuring 120-GHz f/sub T/ and 100 GHz f/sub max/. The Rx includes a limiting amplifier, a half-rate clock and data recovery unit, a 1:4 demultiplexer, a frequency acquisition aid, and a frequency lock detector. Input sensitivity for a bit-error rate less than 10/sup -9/ is 40 mV and jitter generation better than 230 fs rms. The IC dissipates 2.4 W from a -3.6-V supply voltage. The Tx integrates a half-rate clock multiplier unit with a 4:1 multiplexer. Measured clock jitter generation is better than 170 fs rms. The IC consumes 2.3 W from a -3.6-V supply voltage.     

A 10-Gb/s CMU/CDR chip-set in SiGe BiCMOS commercial technology with multistandard capability

A 10-Gb/s CMU/CDR chip-set presenting multistandard compliance with SDH/SONET and 10-GbE specifications has been fabricated in a commercial SiGe BiCMOS technology. The clock multiplier unit (CMU) features dual reference clock frequency, and the phase tracking loop uses a charge pump with low common-mode current to minimize frequency ripple; the output jitter is below 80 mUIpp. The clock and data recovery (CDR) features a 20-mV-sensitivity limiting amplifier, a 2-DFF-based decision circuit to maximize clock phase margin (CPM) and a dual-loop phase-locked loop (PLL) architecture with external reference clock. A novel phase detector topology featuring a transition density factor compensation loop has been exploited to minimize jitter. Power consumption is 480 mW and 780 mW, respectively, for the two ICs, from 3.3-V and 2.5-V power supplies     

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 low-power small-area /spl plusmn/7.28-ps-jitter 1-GHz DLL-based clock generator

In this paper, a delay-locked loop (DLL)-based clock generator is presented. Although a DLL-based clock generator requires a clean reference signal, it has several inherent advantages over conventional phase-locked-loop-based clock generators, i.e., no jitter accumulation, fast locking, stable loop operation, and easy integration of the loop filter. We propose a phase detector with a reset circuitry and a new frequency multiplier to overcome the limited locking range and frequency multiplication problems of the conventional DLL-based system. Fabricated in a 0.35-/spl mu/m CMOS process, our DLL-based clock generator occupies 0.07 mm/sup 2/ of area and consumes 42.9 mW of power. It operates in the frequency range of 120 MHz-1.1 GHz and has a measured cycle-to-cycle jitter of /spl plusmn/7.28 ps at 1 GHz. The die area, peak-to-peak, and r.m.s. jitter are the smallest compared to those of reported high-frequency clock multipliers.     

A CMOS 10-gb/s SONET transceiver

This paper presents a single-chip SONET OC-192 transceiver (transmitter and receiver) fabricated in a 90-nm mixed-signal CMOS process. The transmitter consists of a 10-GHz clock multiplier unit (CMU), 16:1 multiplexer, and 10-Gb/s output buffer. The receiver consists of a 10-Gb/s limiting input amplifier, clock and data recovery circuit (CDR), 1:16 demultiplexer, and drivers for low-voltage differential signal (LVDS) outputs. Both transmit and receive phase-locked loops employ a 10-GHz on-chip LC voltage-controlled oscillator (VCO). This transceiver exceeds all SONET OC-192 specifications with ample margin. Jitter generation at 10.66-Gb/s data rate is 18 mUI/sub pp/ (unit interval, peak-to-peak) and jitter tolerance is 0.6 UI/sub pp/ at 4-MHz jitter frequency. This transceiver requires 1.2V for the core logic and 1.8 V for input/output LVDS buffers. Multiple power supply domains are implemented here to mitigate crosstalk between receiver and transmitter. The overall power dissipation of this chip is 1.65 W.     

A 43-Gb/s full-rate clock transmitter in 0.18-/spl mu/m SiGe BiCMOS technology

A 43-Gb/s full-rate clock transmitter chip for SONET OC-768 transmission systems is reported. The IC is implemented in a 0.18-/spl mu/m SiGe BiCMOS technology featuring 120 GHz f/sub T/ and 100 GHz f/sub max/ HBTs. It consists of a 4:1 multiplexer, a clock multiplier unit, and a frequency lock detector. The IC features clock jitter generation of 260 fs rms and dissipates 2.3 W from a -3.6-V supply voltage. Measurement results are compared to a previously reported half-rate clock transmitter designed using the same technology.     

A 10-Gb/s CMOS CDR and DEMUX IC With a Quarter-Rate Linear Phase Detector

This paper presents a 10-Gb/s clock and data recovery (CDR) and demultiplexer IC in a 0.13-mum CMOS process. The CDR uses a new quarter-rate linear phase detector, a new data recovery circuit, and a four-phase 2.5-GHz LC quadrature voltage-controlled oscillator for both wide phase error pulses and low power consumption. The chip consumes 100 mA from a 1.2-V core supply and 205 mA from a 2.5-V I/O supply including 18 preamplifiers and low voltage differential signal (LVDS) drivers. When 9.95328-Gb/s 2³¹-1 pseudorandom binary sequence is used, the measured bit-error rate is better than 10^-15 and the jitter tolerance is 0.5UIpp, which exceeds the SONET OC-192 standard. The jitter of the recovered clock is 2.1 psrms at a 155.52MHz monitoring clock pin. Multiple bit rates are supported from 9.4 Gb/s to 11.3 Gb/s     

A 10-Gb/s 16:1 multiplexer and 10-GHz clock synthesizer in0.25-μm SiGe BiCMOS

A 10-Gb/s 16:1 multiplexer, 10-GHz clock generator phase-locked loop (PLL), and 6 × 16 b input data buffer are integrated in a 0.25-μm SiGe BiCMOS technology. The chip multiplexes 16 parallel input data streams each at 622 Mb/s into a 9.953-Gb/s serial output stream. The device also produces a 9.953-GHz output clock from a 622- or 155-MHz reference frequency. The on-board 10-GHz voltage-controlled oscillator (VCO) has a 10% tuning range allowing the chip to accommodate both the SONET/SDH data rate of 9.953 Gb/s and a forward error correction coding rate of 10.664 Gb/s. The 6 × 16 b input data buffer accommodates ±2.4 ns of parallel input data phase drift at 622 Mb/s. A delay-locked loop (DLL) in the input data buffer allows the support of multiple input clocking modes. Using a clock generator PLL bandwidth of 6 MHz, the 9.953-GHz output clock exhibits a generated jitter of less than 0.05 UI_P-P over a 50-kHz to 80-MHz bandwidth and jitter peaking of less than 0.05 dB     

Low-power fully integrated 10-Gb/s SONET/SDH transceiver in 0.13-/spl mu/m CMOS

Here, we present a low-power fully integrated 10-Gb/s transceiver in 0.13-/spl mu/m CMOS. This transceiver comprises full transmit and receive functions, including 1:16 multiplex and demultiplex functions, high-sensitivity limiting amplifier, on-chip 10-GHz clock synthesizer, clock-data recovery, 10-GHz data and clock drivers, and an SFI-4 compliant 16-bit LVDS interface. The transceiver exceeds all SONET/SDH (OC-192/STM-64) jitter requirements with significant margin: receiver high-frequency jitter tolerance exceeds 0.3 UI/sub pp/ and transmitter jitter generation is 30 mUI/sub pp/. All functionality and specifications (core and I/O) are achieved with power dissipation of less than 1 W.     

OC-192 transmitter and receiver in standard 0.18-/spl mu/m CMOS

This paper presents the first fully integrated SONET OC-192 transmitter and receiver fabricated in a standard 0.18-/spl mu/m CMOS process. The transmitter consists of an input data register, 16-b-wide first-in-first-out (FIFO) circuit, clock multiplier unit (CMU), and 16:1 multiplexer to give a 10-Gb/s serial output. The receiver integrates an input amplifier for 10-Gb/s data, clock and data recovery circuit (CDR), 1:16 demultiplexer, and drivers for low-voltage differential signal (LVDS) outputs. An on-chip LC-type voltage-controlled oscillator (VCO) is employed by both the transmitter and receiver. The chipset operates at multiple data rates (9.95-10.71 Gb/s) with functionality compatible with the multisource agreement (MSA) for 10-Gb transponders. Both chips demonstrate SONET-compliant jitter characteristics. The transmitter 10.66-GHz output clock jitter is 0.065 UI/sub pp/ (unit interval, peak-to-peak) over a 50-kHz-80-MHz bandwidth. The receiver jitter tolerance is more than 0.4 UI/sub pp/ at high frequencies (4-80 MHz). A high level of integration and low-power consumption is achieved by using a standard CMOS process. The transmitter and receiver dissipate a total power of 1.32 W at 1.8 V and are packaged in a plastic ball grid array with a footprint of 11/spl times/11 mm/sup 2/.     

A 2.5-10-Gb/s CMOS transceiver with alternating edge-sampling phase detection for loop characteristic stabilization

This paper describes a technique for stabilizing the binary phase detector (PD) gain under various jitter conditions. A dead zone in the phase detector estimates the magnitude of high-frequency data jitter, and the resulting jitter information is used to control the charge-pump current. An alternating edge-sampling (AES) PD reduces hardware overhead by removing possible redundancies in previous dead-zone implementations. A series sense amplifier driven by a single-phase clock helps high-speed data sampling with increased data evaluation time. A dual path voltage-controlled oscillator incorporating dual-loop architecture enables wide-range operation of clock/data recovery circuits with low jitter. Fabricated in a 0.18-/spl mu/m CMOS process, a test transceiver operates from 2.5 to 11.5 Gb/s with a bit-error rate of less than 10/sup -12/ while consuming 540 mW from a 1.8-V supply.     

2.5Gb/s 0.18μm CMOS时钟数据恢复电路

采用TSMC公司标准的0.18μm CMOS工艺,设计并实现了一个全集成的2.5Gb/s时钟数据恢复电路.时钟恢复由一个锁相环实现.通过使用一个动态的鉴频鉴相器,优化了相位噪声性能.恢复出2.5GHz时钟信号的均方抖动为2.4ps,单边带相位噪声在10kHz频偏处为-111dBc/Hz.恢复出2.5Gb/s数据的均方抖动为3.3ps.芯片的功耗仅为120mW.     

A Si bipolar phase and frequency detector IC for clock extractionup to 8 Gb/s

A phase and frequency detector IC is presented that operates up to an NRZ bit rate of 8 Gb/s. The IC comprises a phase detector (PD), a quadrature phase detector (QPD), and frequency detector (FD). In the PD and QPD the VCO signal and the quadrature VCO signal are sampled by the NRZ input signal. The two beat notes provided by this operation are subsequently processed in the FD. The superposition of the FD output and the PD output signals are then fed into a passive loop filter (lag/lead filter). The loop filter and the VCO are external components. The measured pull-in range is >±100 MHz at 8 Gb/s. The measured r.m.s. time jitter of the extracted clock is less than 1.9 ps for a pseudorandom bit sequence (PRBS) length of 2²³-1. A 0.9-μm 12-GHz f_T silicon bipolar process was used to fabricate the chip with a total power consumption of 1.4 W     

A 12.5-Gb/s Parallel Phase Detection Clock and Data Recovery Circuit in 0.13-$muhbox m$CMOS

A clock and data recovery (CDR) architecture featuring a parallel phase detector is proposed for speeding up linear-type CDRs. A cause of speed limit in conventional CDRs is very short UP pulses in its phase detector circuit. The parallel phase detector expands UP pulsewidth by adding fixed-width using a half-rate clock. The parallel phase detector is used in the CDR with a couple of unbalanced charge-pump. The bandwidth of decision latches of the PD is extended by 1.7 times by using both shunt-peaking and capacitance coupling. The monolithic CDR implemented in 0.13-$muhbox m$CMOS shows 1.7 times wider phase linear response region of 0.56UI than that of a conventional CDR. It operates at 12.5-Gb/s with PRBS$2 ^31 -1$input data. Measurements show large jitter tolerance of over 0.5 UIpp for 4-8 MHz jitter frequency as well as jitter transfer characteristics independent on input-jitter amplitudes of 0.1, 0.3, and 0.5 UIpp.     

A 40-Gb/s clock and data recovery circuit in 0.18-/spl mu/m CMOS technology

A phase-locked clock and data recovery circuit incorporates a multiphase LC oscillator and a quarter-rate bang-bang phase detector. The oscillator is based on differential excitation of a closed-loop transmission line at evenly spaced points, providing half-quadrature phases. The phase detector employs eight flip-flops to sample the input every 12.5 ps, detecting data transitions while retiming and demultiplexing the data into four 10-Gb/s outputs. Fabricated in 0.18-/spl mu/m CMOS technology, the circuit produces a clock jitter of 0.9 ps/sub rms/ and 9.67 ps/sub pp/ with a PRBS of 2/sup 31/-1 while consuming 144 mW from a 2-V supply.     

A DLL-Based Programmable Clock Multiplier in 0.18-μ m CMOS With −70 dBc Reference Spur

This paper describes a 150-400 MHz programmable clock multiplier which uses a recirculating DLL. The clock multiplier uses a sampling phase detector and employs chopping, autozeroing and various other circuit techniques to reduce static phase offset and crosstalk between the reference and the output clock. The DLL is implemented in 0.18-mum CMOS, consumes 16 mW of power, and achieves 1-5 ps RMS jitter and -70 dBc reference spur level.     

PLL design technique by a loop-trajectory analysis taking decision-circuit phase margin into account for over-10-Gb/s clock and data recovery circuits

A design technique for an over-10-Gb/s clock and data recovery (CDR) IC provides good jitter tolerance and low jitter. To design the CDR using a PLL that includes a decision circuit with a certain phase margin affecting the pull-in performance, we derived a simple expression for the pull-in range of the PLL, which we call the "limited pull-in range," and used it for the pull-in performance evaluation. The method allows us to quickly and easily compare the pull-in performance of a conventional PLL with a full-rate clock and a PLL with a half-rate clock, and we verified that the half-rate PLL is advantageous because of its wider frequency range. For verification of the method, we fabricated a half-rate CDR with a 1:16 DEMUX IC using commercially available Si bipolar technology with f/sub T/=43 GHz. The half-rate clock technique with a linear phase detector, which is adopted to avoid using the binary phase detector often used for half-rate CDR ICs, achieves good jitter characteristics. The CDR IC operates reliably up to over 15 Gb/s and achieves jitter tolerance with wide margins that surpasses the ITU-T specifications. Furthermore, the measured jitter generation is less than 0.4 ps rms, which is much lower than the ITU-T specification. In addition, the CDR IC can extract a precise clock signal under harsh conditions, such as when the bit error rate of input data is around 2/spl times/10/sup -2/ due to a low-power optical input of -24 dBm.     

A 10-Gb/s CMOS clock and data recovery circuit with a half-ratelinear phase detector

A 10-Gb/s phase-locked clock and data recovery circuit incorporates an interpolating voltage-controlled oscillator and a half-rate phase detector. The phase detector provides a linear characteristic while retiming and demultiplexing the data with no systematic phase offset. Fabricated in a 0.18-μm CMOS technology in an area of 1.1×0.9 mm², the circuit exhibits an RMS jitter of 1 ps, a peak-to-peak jitter of 14.5 ps in the recovered clock, and a bit-error rate of 1.28×10^-6, with random data input of length 2²³-1. The power dissipation is 72 mW from a 2.5-V supply     

A 1.2-V 37–38.5-GHz Eight-Phase Clock Generator in 0.13- μm CMOS Technology

A 37-38.5-GHz clock generator is presented in this paper. An eight-phase LC voltage-controlled oscillator (VCO) is presented to generate the multiphase outputs. The high-pass characteristic CL ladder topology sustains the high-frequency signals. The split-load divider is presented to extend the input frequency range. The proposed PD improves the static phase error and enhances the gain. To verify the function of each block and modify the operation frequency, two additional testing components-an eight-phase VCO and a split-load frequency divider-are fabricated using 0.13-mum CMOS technology. The measured quadrature-phase outputs of VCO and input sensitivity of the divider are presented. This clock generator has been fabricated with 0.13-mum CMOS technology. The measured rms clock jitter is 0.24 ps at 38 GHz while consuming 51.6 mW without buffers from a 1.2-V supply. The measured phase noise is -97.55 dBc/Hz at 1-MHz offset frequency     

A DC-20-GHz InP HBT balanced analog multiplier for high-data-ratedirect-digital modulation and fiber-optic receiver applications

This paper reports on a dc-20-GHz InP heterojunction bipolar transistor (HBT) active mixer, which obtains the highest gain-bandwidth product (GBP) thus far reported for a direct-coupled analog mixer integrated circuit (IC). The InP HBT active mixer is based on the Gilbert transconductance multiplier cell and integrates RF, local oscillator, and IF amplifiers, High-speed 70-GHz f_T and 160-GHz f_max InP HBT devices along with microwave matching accounts for its record performance. Operated as a down-converter mixer, the monolithic microwave integrated circuit achieves an RF bandwidth (BW) from dc-20 GHz with 15.3-dB gain and benchmarks a factor of two improvement in GBP over state-of-the-art analog mixer ICs. Operated as an up-converter, direct-digital modulation of a 2.4-Gb/s 2³¹ -1 pseudorandom bit sequence (PRBS) onto a 20-GHz carrier frequency resulted in a carrier rejection of a 28 dB, clock suppression of 35 dBc, and less than a 50-ps demodulated eye phase jitter. The analog multiplier was also operated as a variable gain amplifier, which obtained 20-dB gain with a BW from dc-18 GHz, an third-order intercept of 12 dBm, and over 25 dB of dynamic range. A single-ended peak-to-peak output voltage of 600 mV was obtained with a ±35-mV 15 Gb/s 2⁵-1 PRES input demonstrating feasibility for OC-192 fiber-telecommunication data rates. The InP-based analog multiplier IC is an attractive building block for several wideband communications such as those employed in satellites, local multipoint distribution systems, high-speed local area networks, and fiber-optic links