Design of a low-power 3.5-GHz broad-band CMOS transimpedance amplifier for optical transceivers

This paper describes a novel low-power low-noise CMOS voltage-current feedback transimpedance amplifier design using a low-cost Agilent 0.5-/spl mu/m 3M1P CMOS process technology. Theoretical foundations for this transimpedance amplifier by way of gain, bandwidth and noise analysis are developed. The bandwidth of the amplifier was extended using the inductive peaking technique, and, simulation results indicated a -3-dB bandwidth of 3.5 GHz with a transimpedance gain of /spl ap/60 dBohms. The dynamic range of the amplifier was wide enough to enable an output peak-to-peak voltage swing of around 400 mV for a test input current swing of 100 /spl mu/A. The output noise voltage spectral density was 12 nV//spl radic/Hz (with a peak of /spl ap/25 nV//spl radic/Hz), while the input-referred noise current spectral density was below 20 pA//spl radic/Hz within the amplifier frequency band. The amplifier consumes only around 5 mA from a 3.3-V power supply. A test chip implementing the transimpedance amplifier was also fabricated using the low-cost CMOS process.     

一种用于生物信号采集的CMOS全差分前置跨阻放大器设计

针对生物信号微弱、变化范围大等特点设计了一种用于检测微弱电流的全差分跨阻放大器(TIA)电路结构。不同于传统电路的单端输入,该结构采用高增益的全差分两级放大器实现小信号输入及轨到轨输出。基于CSMC 0.18μm CMOS工艺,采用1.8V电源电压对设计的电路进行了仿真,仿真结果表明:TIA输入电流动态范围为100nA^10μA,最大跨阻增益达到104.38dBΩ,-3dB带宽为4MHz,等效输入噪声电流为1.26pA/Hz。对电路进行跨阻动态特性仿真表明,在输入电流为100nA时,输出电压的动态摆幅达到3.24mV,功耗仅为250μW,总谐波失真(THD)为-49.93dB。所设计的高增益、低功耗、宽输入动态范围TIA适用于生物医疗中极微小生物信号的采集,可作为模块电路集成在便携设备中。     

1-Gb/s zero-pole cancellation CMOS transimpedance amplifier for Gigabit Ethernet applications

A zero-pole cancellation transimpedance amplifier (TIA) has been realized in 0.35 μm RF CMOS tech nology for Gigabit Ethernet applications. The TIA exploits a zero-pole cancellation configuration to isolate the input parasitic capacitance including photodiode capacitance from bandwidth deterioration. Simulation results show that the proposed TIA has a bandwidth of 1.9 GHz and a transimpedance gain of 65 dB·Ω for 1.5 pF photodiode capaci tance, with a gain-bandwidth product of 3.4 THz·Ω. Even with 2 pF photodiode capacitance, the bandwidth exhibits a decline of only 300 MHz, confirming the mechanism of the zero-pole cancellation configuration. The input resis tance is 50 Ω, and the average input noise current spectral density is 9.7 pA/(Hz)~(1/2). Testing results shows that the eye diagram at 1 Gb/s is wide open. The chip dissipates 17 mW under a single 3.3 V supply.     

A Single-Chip 2.5-Gb/s CMOS Burst-Mode Optical Receiver

This paper describes the design of a 2.5-Gb/s burst-mode optical receiver in a 0.18-mum CMOS process. A dual-gain-mode transimpedance amplifier (TIA) with constant damping factor control is proposed to tolerate a wide dynamic range input signal. By incorporating an automatic threshold tracking circuit (ATC), the TIA and limiting amplifier (LA) are dc coupled with feedforward offset cancellation. Dual-band filters are adopted in the ATC for a rapid response time while keeping the tracking error small. By integrating both a TIA and a post-LA in a single chip, the burst-mode receiver provides a conversion gain of 106 dBmiddotOmega in the high gain mode, 97 dBmiddotOmega in the low gain mode, and a -3-dB bandwidth of 1.85 GHz. The measured input sensitivity, overload level, and dynamic range of the optical receiver are -19 dBm, -2 dBm, and 17 dB, respectively. The response time is less than 50 ns. Operating under a single 1.8-V supply, this chip dissipates only 122 mW.     

一种宽输入动态范围跨阻放大器的设计

利用对数放大的增益可变性特点,设计出基于对数放大的跨阻放大器,克服了采用传统AGC调整跨阻的复杂性和低可靠性;同时,避免了采用肖特基二极管箝位方法的工艺局限性,有效扩展了跨阻放大器的输入动态范围。在详细分析跨阻动态特性及温度特性的基础上,分析了电路噪声性能,并进行了仿真验证。试验样片的测试结果进一步证明所提出的方法是有效的。     

一种跨阻放大器的设计

文章提出了一种基于调节型共源共栅电路结构（RGC）的跨阻放大器,采用0.5μm的标准互补型金属氧化物半导体（CMOS）工艺进行设计,仿真。测试结果表明,该电路具有69.93dB的跨阻增益,830MHz的-3dB带宽。在输入电流为1μA时,其输出电压的动态摆幅达到4.5mV,在5V电源电压下功耗仅为63.16mW。     

20 mW 1.25 Gbit/s CMOS transimpedance amplifier with 30 dB dynamic range

A 1.25 Gbit/s transimpedance amplifier using a novel photodiode capacitance cancellation technique has been demonstrated in 0.35 mum CMOS technology. The transimpedance amplifier achieved a transimpedance gain of 17.1 kOmega as well as a wide dynamic range from +1 to -29 dBm while consuming only 20 mW from a 3 V supply     

应用于10Gb/s光接收机的全差分CMOS跨阻前置电路设计

设计了一种的低成本、低功耗的10 Gb/s光接收机全差跨阻前置放大电路。该电路由跨阻放大器、限幅放大器和输出缓冲电路组成,其可将微弱的光电流信号转换为摆幅为400 mVpp的差分电压信号。该全差分前置放大电路采用0.18 m CMOS工艺进行设计,当光电二极管电容为250 fF时,该光接收机前置放大电路的跨阻增益为92 dB,-3 dB带宽为7.9 GHz,平均等效输入噪声电流谱密度约为23 pA/(0~8 GHz)。该电路采用电源电压为1.8 V时,跨阻放大器功耗为28 mW,限幅放大器功耗为80 mW,输出缓冲器功耗为40 mW,其芯片面积为800 m1 700 m。     

An in-probe receiver amplifier with 3 dB noise figure and 50 dB dynamic range for medical ultrasound imaging using CMUTs

This paper presents the design and measurements of an in-probe receiver amplifier for ultrasound imaging applications using a capacitive micromachined ultrasonic transducer (CMUT). In such applications, the noise and the dynamic range play very important roles, as the former dictates the minimum input signal level and the latter defines the maximum input signal level that can be applied to a system. This work concentrates on both of these specifications. The amplifier consists of a transimpedance amplifier followed by a voltage gain stage implemented using a current feedback amplifier. It is designed and fabricated using a 180 nm CMOS process. A noise figure of 3 dB is measured for a CMUT model with 10–30 MHz frequency range. The amplifier shows a dynamic range of 50 dB with 0.8 % total harmonic distortion for the full scale input current of 7 µA peak-to-peak.     

A 40-Gb/s Transimpedance Amplifier in 0.18-$mu$m CMOS Technology

A 40-Gb/s transimpedance amplifier (TIA) is realized in 0.18-mum CMOS technology. From the measured S-parameters, a transimpedance gain of 51 dBOmega and a 3-dB bandwidth up to 30.5 GHz were observed. A bandwidth enhancement technique, pi-type inductor peaking (PIP), is proposed to achieve a bandwidth enhancement ratio (BWER) of 3.31. In addition, the PIP topology used at the input stage decreases the noise current as the operation frequency increases. Under a 1.8 V supply voltage, the TIA consumes 60.1 mW with a chip area of 1.17 X 0.46 mm2. The proposed CMOS TIA presents a gain-bandwidth product per DC power figure of merit (GBP/P_de) of 180.1 GHzOmega/mW.     

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.     

High-gain transimpedance amplifier in InP-based HBT technology forthe receiver in 40-Gb/s optical-fiber TDM links

A monolithic integrated transimpedance amplifier for the receiver in a 40-Gb/s optical-fiber TDM system has been fabricated in an InP-based HBT technology. Despite its high gain (transimpedance of 2 kΩ in the limiting mode, 10 kΩ in the linear mode) the complete amplifier was realized on a single chip. Clear output eye diagrams were measured up to 43 Gb/s under realistic driving conditions. The voltage swing of 0.6 V_pp at the differential 50 Ω output does not change within the demanded input dynamic range of 6 dB. At the upper input current level even 48 Gb/s were achieved. The power consumption is approximately 600 mW at a single supply voltage of -5.5 V     

A linear and wide dynamic range transimpedance amplifier with adaptive gain control technique

A linear and wide dynamic range transimpedance amplifier (TIA) for the pulsed time-of-flight imaging LADAR application has been designed and simulated in a 0.18 μm 3.3 V CMOS technology. Specific design techniques, including adaptive gain control technique to widen linear dynamic range, pseudo-differential structure of the front end to decrease the common-mode noise and noise minimization to improve SNR, have been proposed to achieve challenging designs goals with linear dynamic range of 5000:1, high transimpedance gain of 89 dB Ω, bandwidth up to 150 MHz, equivalent input-referred noise current less than 8 \({\text{pA}}/\sqrt {\text{Hz}}\), in 2 pF photodiode parasitic capacitance. The proposed TIA consumes 165 mW with 3.3 V power supply.     

10Gb/s光接收机跨阻前置放大器芯片设计研究

采用0.18 μm BiCMOS工艺设计并实现了一种高增益、低噪声、宽带宽以及大输入动态范围的光接收机跨阻前置放大器.在寄生电容为250 fF的情况下,采用全集成的四级放大电路,合理实现了上述各项参数指标间的折中.测试结果表明:放大器单端跨阻增益为73 dB,-3 dB带宽为7.6 GHz,灵敏度低至-20.44 dBm,功耗为74 mW,最大差分输出电压为200 mV,最大输入饱和光电流峰-峰值为1 mA,等效输入噪声为17.1 pA/√Hz,芯片面积为800 μ.m×950μm.     

8 Gbits/s inductorless transimpedance amplifier in 90 nm CMOS technology

This work presents the design and the measured performance of a 8 Gb/s transimpedance amplifier (TIA) fabricated in a 90 nm CMOS technology. The introduced TIA uses an inverter input stage followed by two common-source stages with a 1.5 kΩ feedback resistor. The TIA is followed by a single-ended to differential converter stage, a differential amplifier and a 50 Ω differential output driver to provide an interface to the measurement setup. The optical receiver shows a measured optical sensitivity of ?18.3 dBm for a bit error rate = 10^?9. A gain control circuitry is integrated with the TIA to increase its input photo-current dynamic range (DR) to 32 dB. The TIA has an input photo-current range from 12 to 500 μA without overloading. The stability is guaranteed over the whole DR. The optical receiver achieves a transimpedance gain of 72 dBΩ and 6 GHz bandwidth with 0.3 pF total input capacitance for the photodiode and input PAD. The TIA occupies 0.0036 mm² whereas the complete optical receiver occupies a chip area of 0.46 mm². The power consumption of the TIA is only 12 mW from a 1.2 V single supply voltage. The complete chip dissipates 60 mW where a 1.6 V supply is used for the output stages.     

155Mb/s光通信用CMOS自动增益控制跨阻前置放大器

采用华润上华的0.6μm标准CMOS工艺设计了一种应用于光纤通信系统STM-1速率级别的自动增益控制(AGC)跨阻前置放大器.为了扩展输入动态范围,采用自动增益控制技术监控输入电流中与电流幅度成正比的直流分量的变化.当输入信号过大时,降低电路的跨阻增益,从而避免输出波形出现严重失真.通过分析电路中几个主要元件对等效输入噪声电流的贡献,给出了噪声性能优化的方法.测试结果表明,在5V电源电压下,小信号时电路差分跨阻增益达到91.7dBΩ(38.5kΩ),-3dB带宽125MHz,最大输入光功率0dBm,平均等效输入噪声电流谱密度为4.8pA.功耗为180mW.芯片面积为0.7×0.4mm².     

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.     

Design of an L1 band low noise single-chip GPS receiver in 0.18 μm CMOS technology

This article presents an L1 band low noise integrated global positioning system(GPS)receiver chip using 0.18 μm CMOS technology.Dual-conversion with a low-IF architecture was used for this GPS receiver.The receiver is composed of low noise amplifier(LNA),down-conversion mixers,band pass filter,received signal strength indicator,variable gain amplifier,programmable gain amplifier,ADC,PLL frequency synthesizer and other key blocks.The receiver achieves a maximum gain of 105 dB and noise figure less than 6 dB.The variable gain amplifier(VGA)and programmable gain amplifier(PGA)provide gain control dynamic range over 50 dB.The receiver consumes less than 160 mW from a 1.8 V supply while occupying a 2.9 mm2chip area including the ESD I/O pads.     

6 GHz transimpedance amplifier for optical sensing system in low-cost 0.35 /spl mu/m CMOS

A high-speed transimpedance amplifier (TIA) has been designed and implemented in a low cost 0.35 mum CMOS technology. Combining the techniques of regulated cascode input stage, current shunt feedback and inductive-series peaking, the TIA achieves a transimpedance gain of 51 dBOmega and 3 dB bandwidth of 6 GHz, in the presence of a photodiode capacitance of 0.6 pF. This is believed to be the fastest TIA ever reported in 0.35 mum CMOS technology     

一种高线性度电压电流转换电路的设计与实现

介绍了利用CSMC 0.6μm CMOS工艺实现的、应用于电流模逻辑电路中的高线性度电压电流转换(VTC)电路。该电路采用了高增益两级运算放大器,以及工作在弱反型区的MOS管电压电流呈指数律关系实现的PTAT基准电流源。详细分析了电阻与运算放大器的非线性影响因素。测试结果表明,输出的总谐波失真为0.0002%,输入动态范围为0～2.6V,输出电流为50～426μA,PTAT基准电流源对电源变化的灵敏度为0.0217。芯片采用5V供电,功耗约为1.3mW,芯片面积为0.112mm2。