High-gain SiGe transimpedance amplifier array for a 12/spl times/10 Gb/s parallel optical-fiber link

A transimpedance amplifier array for 12 parallel optical-fiber channels each operating at 10 Gb/s is presented, which is used in the receiver of short-distance links. It stands out for the following features: high gain (transimpedance 25 k/spl Omega/ in the limiting mode), high input sensitivity and wide input dynamic range (input current swing from 20 to 240 /spl mu/A/sub p-p/), constant output voltage swing (differential 0.5 V/sub p-p/ at 50 /spl Omega/ load), and low power consumption (1.4 W) at a single supply voltage (5 V). Each channel has its own offset-current control circuit. To the best of the authors' knowledge, the total throughput of 12/spl times/10 Gb/s=120 Gb/s is the highest value reported for a single-chip amplifier array. The target specifications have been achieved with the first technological run without needing any redesign. This fact demonstrates that the inherent severe crosstalk problems of such high-gain amplifier arrays can reliably be solved by applying adequate decoupling measures and simulation tools.     

40-GHz transimpedance amplifier with differential outputs using InP-InGaAs heterojunction bipolar transistors

High-gain and high-bandwidth transimpedance amplifiers (TIAs) are required for fiber-optic receiver modules. This paper reports on the design, fabrication, and characterization of a 40-Gb/s TIA for SONET/SDH STS-768/STM-256 applications based on an InP-InGaAs single heterojunction bipolar transistor (SHBT) process developed at Vitesse Semiconductor Corporation (Vitesse Indium Phosphide Release 1 or VIP-1). This amplifier consists of a single-ended input transimpedance pre-amplifier and a differential output post-amplifier. The measured differential transimpedance is 1800 /spl Omega/ with -3-dB bandwidth greater than 40 GHz. The high gain of this circuit eliminates the need for a standalone limiting amplifier between the conventional transimpedance pre-amplifier and the demultiplexer in short-reach applications.     

1-Gb/s 80-dB/spl Omega/ fully differential CMOS transimpedance amplifier in multichip on oxide technology for optical interconnects

A 1-Gb/s differential transimpedance amplifier (TIA) is realized in a 0.25-/spl mu/m standard CMOS technology, incorporating the regulated cascode input configuration. The TIA chip is then integrated with a p-i-n photodiode on an oxidized phosphorous-silicon (OPS) substrate by employing the multichip-on-oxide (MCO) technology. The MCO TIA demonstrates 80-dB/spl Omega/ transimpedance gain, 670-MHz bandwidth for 1-pF photodiode capacitance, 0.54-/spl mu/A average input noise current, -17-dBm sensitivity for 10/sup -12/ bit-error rate (BER), and 27-mW power dissipation from a single 2.5-V supply. It also shows negligible switching noise effect from an embedded VCO on the OPS substrate. Furthermore, a four-channel MCO TIA array is implemented for optical interconnects, resulting in less than -40-dB crosstalk between adjacent channels.     

10-Gb/s limiting amplifier and laser/modulator driver in 0.18-/spl mu/m CMOS technology

A limiting amplifier incorporates active feedback, inductive peaking, and negative Miller capacitance to achieve a voltage gain of 50 dB, a bandwidth of 9.4 GHz, and a sensitivity of 4.6 mV/sub pp/ for a bit-error rate of 10/sup -12/ while consuming 150 mW. A driver employs T-coil peaking and negative impedance conversion to achieve operation at 10 Gb/s while delivering a current of 100 mA to 25-/spl Omega/ lasers or a voltage swing of 2 V/sub pp/ to 50-/spl Omega/ modulators with a power dissipation of 675 mW. Fabricated in 0.18-/spl mu/m CMOS technology, both prototypes operate with a 1.8-V supply.     

High-gain differential CMOS transimpedance amplifier with on-chip buried double junction photodiode

An integrated fully differential CMOS transimpedance amplifier (TIA) with buried double junction photodiode input is described. The TIA features a variable high transimpedance gain (250 k/spl Omega/ to 2.5 M/spl Omega/), large DC photocurrent rejection capability (>55 dB) and low input referred noise density at 100 kHz (2pA//spl radic/Hz).     

Optical receiver IC for CD/DVD/blue-laser application

In this paper, an optoelectronic receiver IC for CD, DVD, and Blue-Laser optical data storage applications is presented. The IC was developed in a 0.5-/spl mu/m BiCMOS technology with integrated PIN photodiodes. It includes a new architecture of high-speed and low-noise variable gain transimpedance amplifiers witch current preamplifier input. The amplifier transimpedance gain is programmable over a gain range of 130 /spl Omega/ to 270 k/spl Omega/ by a serial interface. The amplifier small-signal bandwidth is 260 MHz for the highest gain, which gives a gain-bandwidth product of 70 THz/spl Omega/ and a sensitivity improvement by a factor of 2 compared to published OEICs. The amplifiers support a special write/clip mode which realizes a nonlinear gain reduction for high input signals. The output voltage buffers are 130-/spl Omega/ impedance matched for optimized data transmission over a flex cable. The impedance is generated by active-impedance synthesis to increase the output dynamic range.     

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.     

Low-power InP/GaAsSb/InP DHBT cascode transimpedance amplifier with GBP/P/sub dc/ of 7.2 GHz/mW

A low-power high gain-bandwidth monolithic cascode transimpedance amplifier using novel InP/GaAsSb/InP DHBT technology was investigated. The amplifier exhibited state-of-the-art performance of 17.3 dB gain, 12 GHz bandwidth, 55 dB/spl Omega/ transimpedance, and a corresponding gain-bandwidth of 6.7 THz/spl Omega/ while consuming only 12.2 mW DC power. It also achieved good gain-bandwidth-product per DC power figure-of-merit (GBP/P/sub dc/) of 7.2 GHz/mW     

A 1.8-V 10-Gb/s fully integrated CMOS optical receiver analog front-end

A fully integrated 10-Gb/s optical receiver analog front-end (AFE) design that includes a transimpedance amplifier (TIA) and a limiting amplifier (LA) is demonstrated to require less chip area and is suitable for both low-cost and low-voltage applications. The AFE is fabricated using a 0.18-/spl mu/m CMOS technology. The tiny photo current received by the receiver AFE is amplified to a differential voltage swing of 400 mV/sub (pp)/. In order to avoid off-chip noise interference, the TIA and LA are dc-coupled on the chip instead of ac-coupled though a large external capacitor. The receiver front-end provides a conversion gain of up to 87 dB/spl Omega/ and -3dB bandwidth of 7.6 GHz. The measured sensitivity of the optical receiver is -12dBm at a bit-error rate of 10/sup -12/ with a 2/sup 31/-1 pseudorandom test pattern. Three-dimensional symmetric transformers are utilized in the AFE design for bandwidth enhancement. Operating under a 1.8-V supply, the power dissipation is 210 mW, and the chip size is 1028 /spl mu/m/spl times/1796 /spl mu/m.     

A Common-Base Transistor Differential Amplifier

A differential amplifier with the input transistor pair operating in the common-base mode was designed for a dc to 100-MHz current preamplifier application. It features 0.6-ohm input impedance and 1.0-k /spl Omega/ transimpedance gain.     

Substrate coupling in a high-gain 30-Gb/s SiGe amplifier-modeling, suppression, and measurement

For demonstrating substrate coupling in high-gain broadband amplifiers, a limiting differential transimpedance amplifier has been developed and fabricated in a SiGe bipolar technology. It operates up to 30 Gb/s and stands out for a maximum (nonlinear) transimpedance in the limiting mode of 25 k/spl Omega/, resulting in a gain /spl times/ speed product as high as 750 k/spl Omega//spl middot/Gb/s. This record value could be achieved by applying several techniques for suppression of noise coupling simultaneously. The effectiveness of each technique was verified experimentally by measuring the output eye diagrams of different mounted amplifier versions. The high accuracy potential of the substrate modeling tools applied for optimizing the amplifier design has been demonstrated separately by measurements on special (mounted) test structures up to 40 GHz. These investigations also showed the strong degradation of shielding measures by bond inductances with increasing frequency.     

1.25-Gb/s regulated cascode CMOS transimpedance amplifier for Gigabit Ethernet applications

A transimpedance amplifier (TIA) has been realized in a 0.6-/spl mu/m digital CMOS technology for Gigabit Ethernet applications. The amplifier exploits the regulated cascode (RGC) configuration as the input stage, thus achieving as large effective input transconductance as that of Si Bipolar or GaAs MESFET. The RGC input configuration isolates the input parasitic capacitance including photodiode capacitance from the bandwidth determination better than common-gate TIA. Test chips were electrically measured on a FR-4 PC board, demonstrating transimpedance gain of 58 dB/spl Omega/ and -3-dB bandwidth of 950 MHz for 0.5-pF photodiode capacitance. Even with 1-pF photodiode capacitance, the measured bandwidth exhibits only 90-MHz difference, confirming the mechanism of the RGC configuration. In addition, the noise measurements show average noise current spectral density of 6.3 pA//spl radic/(Hz) and sensitivity of -20-dBm for a bit-error rate of 10/sup -12/. The chip core dissipates 85 mW from a single 5-V supply.     

A wide-band low-noise monolithic transimpedance amplifier

A transimpedance amplifier with nominal 200-MHz bandwidth, 6.6-k/spl Omega/ gain, and 33-nA RMS-equivalent input noise current is described. The circuit is realized in silicon-bipolar-monolithic technology and functions with source capacitances ranging from zero to several picofarads.     

GaAs-based high-gain direct-coupled distributed preamplifier using active feedback topology

A single-chip ultra-high gain distributed amplifier (DA) was developed using commercial GaAs PHEMT foundry for 40-Gb/s base band applications. Two seven-section DAs are directly coupled using a lumped dc level-shift circuit. The dc bias level of the second-stage DA can be tuned using the level-shift circuit for optimum gain. The gain of each DA stage has been optimized using a novel active feedback cascode topology, which allows the gain bandwidth product to be maximized while avoiding instability problems. The fabricated single-chip DA with a size of 2.1 mm /spl times/ 2.3 mm showed a high gain of 28 dB, and an average noise figure of 4.6 dB with a 41 GHz bandwidth. The corresponding transimpedance gain was 62 dB/spl Omega/ and the input noise current density was 14.5 pA//spl radic/Hz. The gain bandwidth product (GBWP) is 1030 GHz, which corresponds to the highest performance using GaAs technology for 40 Gb/s applications.     

37-GHz bandwidth monolithically integrated InP HBT/evanescently coupled photodiode

In this letter, we demonstrate a monolithically integrated optoelectronic integrated circuit (OEIC) for 1.55-/spl mu/m wavelength application. The presented OEIC consists of an evanescently coupled photodiode (ECPD) and a single-stage common-base InP-InGaAs heterojunction bipolar transistor (HBT) amplifier. The guide structure was grown first by metal-organic chemical vapor deposition and pin/HBT was then regrown by molecular beam epitaxy. The ECPD exhibits a responsivity of 0.3 A/W and a -3-dB electrical bandwidth of 30 GHz. The photoreceiver demonstrates a -3-dB electrical bandwidth of 37 GHz with a transimpedance gain of 32 dB/spl middot//spl Omega/. This is, to our knowledge, the first ECPD/HBT ever reported for a monolithically integrated OEIC.     

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.     

On the performance analysis and design of an integrated front-end PIN/HBT photoreceiver

A detailed study on the performance analysis and optimum design of an integrated front-end PIN/HBT photoreceiver for fiber-optic communication is presented. Receiver circuits with two different transimpedance amplifiers-a single-stage common emitter (CE) amplifier and a three-stage amplifier comprising a CE amplifier and two emitter followers (EFs), are analyzed assuming a standard load of 50 /spl Omega/. A technique to include the transit-time effect of a PIN photodetector on the overall receiver circuit analysis is introduced and discussed. Gain-bandwidth product (GB) and gain-bandwidth-sensitivity measure product (GBS) are obtained as functions of feedback resistance (R/sub F/) and various device parameters. Hence, some optimum designs are suggested using a photodetector of area 100 /spl mu/m/sup 2/ and with a feedback resistance of 500 /spl Omega/. The bandwidth plays a major role in determining the optimum designs for maximum GB and maximum GBS. A bandwidth >8 GHz has been obtained for the photoreceiver even with a single-stage CE amplifier. The optimum design for a receiver with a three-stage amplifier shows a bandwidth of 35 GHz which is suitable for receivers operating well beyond 40 Gb/s; however, in this case, the gain is reduced. The performance of different fixed square-emitter structures are investigated to choose the optimum designs corresponding to different gains. Very low power dissipation has been estimated for the optimized devices. The noise performance of the devices with optimum designs was calculated in terms of the minimum detectable optical power for a fixed bit-error rate of 10/sup -9/. The present design indicates that GB and noise performance can be improved by using an optimum device design.     

A new integrated front-end for a noninvasive brain imaging system based on near-infrared spectroreflectometry

In this paper, we present a fully integrated front-end of a portable spectroreflectometry-based brain imaging system dedicated for acquisition of modulated optical signals at a frequency of 1 Hz to 25 kHz. The proposed front-end preamplifier is composed of a photodetector, a transimpedance preamplifier, a two-stage voltage amplifier and a mixer. Strict constraints regarding noise thus have to be considered. The preamplifier consists of a transimpedance block featuring a 95-dB/spl Omega/ gain and an average input current noise density at the frequency of interest of approximately 3 pA//spl radic/Hz. Each of the two subsequent voltage amplifiers allows the user to obtain an additional 25-dB gain. Considering the tuning capabilities and the losses due to the filters and the nonideal buffers, the proposed front-end allows us to obtain a total gain up to 145 dB. The back-end of the amplification chain is composed of a mixer which is used to produce a continuous voltage proportional to the amplitude of the input optical signals. All those features were integrated using CMOS 0.18-/spl mu/m technology and the experimental results are in agreement with the initial design requirements.     

A 3-V fully differential distributed limiting driver for 40-Gb/s optical transmission systems

A fully differential 40-Gb/s electro-absorption modulator driver is presented. Based on a distributed limiting architecture, the circuit can supply up to 3.0-V/sub pp/ (peak-to-peak) per side in a 50-/spl Omega/ load at data rates as high as 44 Gb/s. Both the input and the output are internally matched to 50 /spl Omega/ and exhibit return loss of better than 10 dB up to 50 GHz. Additional features of the driver include the use of a single -5.2-V supply, output swing control (1.7-3.0-V/sub pp/ per side), dc output offset control (-0.15 V to -1.1 V), and pulsewidth control (30% to 66%). The driver architecture was optimized based on a comprehensive analytical derivation of the frequency response of cascaded source-coupled field-effect transistor logic blocks using both single and double source-follower topologies.     

An InGaAs-InP HBT differential transimpedance amplifier with 47-GHz bandwidth

Return-to-zero differential phase-shift keying applications require a differential amplifier with high bandwidth, high gain, low noise, and good input impedance match. In this paper, we describe an InGaAs-InP heterostructure bipolar transistor differential transimpedance amplifier with high bandwidth of 47 GHz and high gain of 56 dB-/spl Omega/. The input-referred current noise is less than 35 pA//spl radic/Hz over the measurement range up to 40 GHz.