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.     

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.     

High-speed monolithically integrated silicon photoreceivers fabricated in 130-nm CMOS technology

A complementary metal-oxide-semiconductor (CMOS) monolithically integrated photoreceiver is presented. The circuit was fabricated in a 130-nm unmodified CMOS process flow on 2-/spl mu/m-thick silicon-on-insulator substrates. The receiver operated at 8 Gb/s with 2-dBm average input optical power and a bit error rate of less than 10/sup -9/. The integrated lateral p-i-n photodetector was simultaneously realized with the amplifier and had a responsivity of 0.07 A/W at 850 nm. The measured receiver sensitivities at 5, 3.125, 2, and 1 Gb/s, were -10.9, -15.4, -16.5, and -19 dBm, respectively. A 3-V single-supply operation was possible at bit rates up to 3.125 Gb/s. The transimpedance gain of the receivers was in the range 53.4-31 dB/spl Omega/. The circuit dissipated total power between 10 mW and 35 mW, depending on the design.     

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.     

Two-stage quasi-class-E power amplifier in GaN HEMT technology

This letter presents a two-stage quasi-class-E monolithic microwave integrated circuit power amplifier at 2.0GHz, which is based on field-plated GaN high electron mobility transistor technology. It consists of a driver stage and a power stage. The circuit schematic is described. The amplifier achieves an output power of 37.5dBm into a 50-/spl Omega/ load, a power added efficiency (PAE) of 50%, and a gain of 18.2dB. A power density of 5.6W/mm is achieved.     

A 4-terminal wide-band monolithic amplifier

A bipolar monolithic amplifier is described which achieves 18 dB gain, 725 MHz-3 dB bandwidth and 4.4 dB noise figure. The circuit is housed in a 4-lead TO-46 package, consumes 180 mW of DC power and requires no external components. Input and output impedances are matched to 50 /spl Omega/ with VSWR less than 1.5 across the band. A high-power version of the circuit consumes 1 W of DC power and gives 152 mW output power at 200 MHz.     

40 Gb/s differential traveling wave modulator driver

In this letter a MMIC differential traveling wave driver for 40 Gb/s electro-absorption modulation driver is presented. The driver delivers 2.7 Vp-p or 2.4 V eye amplitude at each output into 50 /spl Omega/ load. The driver has high gain (>20 dB), a 3 dB bandwidth of 45 GHz, and rise/fall times of only 10/9 ps, respectively. The circuit uses a single -5.0 V power supply and consumes 1.8 W of dc power. The driver also features cross-point control and output amplitude control functions.     

100-Gb/s multiplexing and demultiplexing IC operations in InP HEMT technology

This paper describes the 100-Gb/s multiplexing operation of a selector IC and demultiplexing operation of a D-type flip-flop (D-FF) using production-level 0.1-/spl mu/m-gate-length InP HEMT IC technology. To boost the operating speed of the selector IC, a selector core circuit directly drives an external 50-/spl Omega/ load, and is included in the output stage. In addition, a test chip containing the selector and a D-FF to confirm error-free operation of these circuits was designed. The fabricated selector IC exhibited clear eye openings at 100 Gb/s, and its error-free operation was confirmed by using the test chip.     

6-k/spl Omega/ 43-Gb/s differential transimpedance-limiting amplifier with auto-zero feedback and high dynamic range

A high-gain, 43-Gb/s InP HBT transimpedance-limiting amplifier (TIALA) with 100-/spl mu/A/sub pp/ sensitivity and 6 mA/sub pp/ input overload current is presented. The circuit also operates as a limiting amplifier with 40-dB differential gain, better than 15-dB input return loss, and a record-breaking sensitivity of 8 mV/sub pp/ at 43 Gb/s. It features a differential TIA stage with inductive noise suppression in the feedback network and consumes less than 450mW from a single 3.3-V supply. The TIALA has 6-k/spl Omega/ (76dB/spl Omega/) differential transimpedance gain and 35-GHz bandwidth and comprises the transimpedance and limiting gain functions, an auto-zero dc feedback circuit, signal level monitor, and slicing level adjust functions. Other important features include 45-dB isolation and 800-mV/sub pp/ differential output.     

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.     

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.     

5-Gbit/s Si integrated regenerative demultiplexer and decision circuit

A silicon bipolar circuit is presented which may be used as either a 1:2 demultiplexer or a decision circuit up to the bit rate of 5 Gb/s. The circuit was fabricated with a standard bipolar technology with oxide-wall isolation, 2-/spl mu/m emitter stripe widths, and a transit frequency of about 9 GHz at V/SUB CE/=1 V. The high-speed performance of the circuit was achieved by applying a double sampling scheme. Clock phase margin (CPM) and decision ambiguity are 120/spl deg/ and 150 mV at 4 Gb/s, respectively. CPM at 5 Gbit/s is about 90%. Decision feedback equalization may be included in the circuit scheme for optional use.     

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.     

40-Gb/s circuits built from a 120-GHz f/sub T/ SiGe technology

Product designs for 40-Gb/s applications fabricated from SiGe BiCMOS technologies are now becoming available. In this paper we first briefly discuss heterojunction bipolar transistor (HBT) device operation at high speed, demonstrating that perceived concerns regarding lower BV/sub CEO/ and higher current densities required to operate silicon HBTs at such high speeds do not in actuality limit design or performance. The high-speed portions of the 40-Gb/s system are then addressed individually. We demonstrate the digital capability through a 4: 1 multiplexer and a 1 : 4 demultiplexer running over 50 Gb/s error free at a -3.3-V power supply. We also demonstrate a range of analog elements, including a lumped limiting amplifier which operates with a 35-GHz bandwidth, a transimpedance amplifier with 220-/spl Omega/ gain and 49.1-GHz bandwidth, a 21.5-GHz voltage-controlled oscillator with over -100-dBc/Hz phase noise at 1-MHz offset, and a modulator driver which runs a voltage swing twice the BV/sub CEO/ of the high-speed SiGe HBT. These parts demonstrate substantial results toward product offerings, on each of the critical high-speed elements of the 40-Gb/s system.     

High-dynamic-range VGA with temperature compensation and linear-in-dB gain control

This paper presents the design and measured performance of a novel intermediate-frequency variable-gain amplifier for Wideband Code-Division Multiple Access (WCDMA) transmitters. A compensation technique for parasitic coupling is proposed which allows a high dynamic range of 77 dB to be attained at 400 MHz while using a single variable-gain stage. Temperature compensation and decibel-linear characteristic are achieved by means of a control circuit which provides a lower than /spl plusmn/1.5 dB gain error over full temperature and gain ranges. The device is fabricated in a 0.8-/spl mu/m 46 GHz f/sub T/ silicon bipolar technology and drains up to 6 mA from a 2.7-V power supply.     

High Gain Equalizing Amplifier Integrated Circuits for a Gigabit Optical Repeater

Equalizing amplifier circuits for a gigabit optical-fiber transmission system are integrated on two monolithic chips implementing an advanced silicon bipolar process. Several new circuit techniques such as a broad-band 50-/spl Omega/ matching amplifier and an electrically controlled and adjusted peaking technique are employed. It is clarified that the main degradation factors of circuit stability are parasitic capacitance between the input and output terminals, and the crosstalk occuring through the wire bonding inductance. The maximum gain and 3-dB down bandwidth of the equalizing amplifier IC's are 64 dB and 1.2 GHz, respectively. The noise figure obtained is 4.5 dB within the dc to 2-GHz range.     

SiGe differential transimpedance amplifier with 50-GHz bandwidth

InP and SiGe technologies are both attractive for design of circuits operating at 40 GB/s and beyond. In this paper, we describe a fully differential SiGe transimpedance amplifier (TIA) suitable for differential phase-shift keying applications. The TIA exhibits 49 dB-/spl Omega/ transimpedance, greater than 50-GHz bandwidth, and input-referred current noise less than 30 pA//spl radic/Hz. For comparison, we have also developed a similar TIA in an InP double-heterostructure bipolar transistor technology. The InP TIA had 48 dB-/spl Omega/ transimpedance and 49-GHz bandwidth.     

A 30-gb/s 70-mW one-stage 4:1 multiplexer in 0.13-/spl mu/m CMOS

A completely integrated 4:1 multiplexer for high-speed operation and low power consumption is presented. The circuit uses a new architecture where four data streams are multiplexed in one stage. Pulses with a duty cycle of 25% switch the inputs to the multiplexer (MUX) output. The pulses are generated from the clock signal and the divided clock signal. Measurement results show the performance of the IQ divider. Current-mode logic is used because of the higher speed compared to static CMOS and the robustness against common-mode disturbances. The multiplexer uses no output buffer and directly drives the 50-/spl Omega/ environment. The lower number of gates compared to the conventional tree topology enables low-power design. Relaxed timing conditions are additional benefits of the one-stage MUX topology. The IC is fabricated in a 0.13-/spl mu/m standard bulk CMOS technology and uses 1.5-V supply voltage. The MUX works up to 30 Gb/s and consumes 70 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 24-GHz, +14.5-dBm fully integrated power amplifier in 0.18-/spl mu/m CMOS

A 24-GHz +14.5-dBm fully integrated power amplifier with on-chip 50-/spl Omega/ input and output matching is demonstrated in 0.18-/spl mu/m CMOS. The use of substrate-shielded coplanar waveguide structures for matching networks results in low passive loss and small die size. Simple circuit techniques based on stability criteria derived result in an unconditionally stable amplifier. The power amplifier achieves a power gain of 7 dB and a maximum single-ended output power of +14.5-dBm with a 3-dB bandwidth of 3.1 GHz, while drawing 100 mA from a 2.8-V supply. The chip area is 1.26 mm/sup 2/.