Low Noise Amplifier using Darlington Pair At 90nm Technology

The demand of low noise amplifier (LNA) has been rising in today’s communication system. LNA is the basic building circuit of the receiver section satellite. The design concept demonstrates the design trade off with NF, gain, power consumption. This paper reports on with analysis of wideband LNA. This paper shows the schematic of LNA by using Darlington pair amplifier. This LNA has been fabricated on 90nm CMOS process. This paper is focused on to make comparison of three stage and single stage LNA. Here, the phase mismatch between these patameters is quantitavely analyzed to study the effect on gain and noise figure (NF). In this paper, single stage LNA has shown the 23 dB measured gain, while the three stages LNA has demonstrated 29 dB measured gain. Here, LNA designed using darlington pair shows low NF of 3.3-4.8 dB, which comparable to other reported single stage LNA designs and appreciably low compared to the three stages LNA. Hence, findings from this paper suggest the use of single stage LNA designed using Darlington pair in transceiver satellite applications

A 1.2 V low noise amplifier with double feedback for high gain and low noise figure

Dissertação para obtenção do Grau de Mestre em Engenharia Eletrotécnica e de ComputadoresIn this thesis we present a balun low noise amplifier (LNA) in which the gain is boosted using a double feedback structure. The circuit is based in a Balun LNA with noise and distortion cancellation. The LNA is based in two basic stages: common-gate (CG) and common-source (CS). We propose to replace the resistors by active loads, which have two inputs that will be used to provide the feedback (in the CG and CS stages). This proposed methodology will boost the gain and reduce the NF (Noise Figure). Simulation results, with a 130 nm CMOS technology, show that the gain is 19.65 dB and the NF is less than 2.17 dB. The total power dissipation is only 5 mW (since no extra blocks are required), leading to an FOM (Figure of Merit) of 3.13 mW-1 from a nominal 1.2 supply

Design of broadband inductor-less RF front-ends with high dynamic range for G.hn

System-on-Chip (SoC) was adopted in recent years as one of the solutions to reduce the cost of integrated systems. When the SoC solution started to be used, the final product was actually more expensive due to lower yield. The developments in integrated technology through the years allowed the integration of more components in lesser area with a better yield. Thus, SoCs became a widely used solution to reduced the cost of the final product, integrating into a single-chip the main parts of a system: analog, digital and memory. As integrated technology kept scaling down to allow a higher density of transistors and thus providing more functionality with the same die area, the analog RF parts of the SoC became a bottleneck to cost reduction as inductors occupy a large die area and do not scale down with technology. Hence, the trend moves toward the research and design of inductor-less SoCs that further reduce the cost of the final solution. Also, as the demand for home networking high-data-rates communication systems has increased over the last decade, several standards have been developed to satisfy the requirements of each application, the most popular being wireless local area networks (WLANs) based on the IEEE 802.11 standard. However, poor signal propagation across walls make WLANs unsuitable for high-speed applications such as high-definition in-home video streaming, leading to the development of wired technologies using the existing in-home infrastructure. The ITU-T G.hn recommendation (G.9960 and G.9961) unifies the most widely used wired infrastructures at home (coaxial cables, phone lines and power lines) into a single standard for high-speed data transmission of up to 1 Gb/s. The G.hn recommendation defines a unified networking over power lines, phone lines and coaxial cables with different plans for baseband and RF. The RF-coax bandplan, where this thesis is focused, uses 50 MHz and 100 MHz bandwidth channels with 256 and 512 carriers respectively. The center frequency can range from 350 MHz to 2450 MHz. The recommendation specifies a transmission power limit of 5 dBm for the 50 MHz bandplan and 8~dBm for the 100 MHz bandplan, therefore the maximum transmitted power in each carrier is the same for both bandplans. Due to the nature of an in-home wired environment, receivers that can handle both very large and very small amplitude signals are required; when transmitter and receiver are connected on the same electric outlet there is no channel attenuation and the signal-to-noise-plus-distortion ratio (SNDR) is dominated by the receiver linearity, whereas when transmitter and receiver are several rooms apart channel attenuation is high and the SNDR is dominated by the receiver noise figure. The high dynamic range specifications for these receivers require the use of configurable-gain topologies that can provide both high-linearity and low-noise for different configurations. Thus, this thesis has been aimed at researching high dynamic range broadband inductor-less topologies to be used as the RF front-end for a G.hn receiver complying with the provided specifications. A large part of the thesis has been focused on the design of the input amplifier of the front-end, which is the most critical stage as the noise figure and linearity of the input amplifier define the achievable overall specifications of the whole front-end. Three prototypes has been manufactured using a 65 nm CMOS process: two input RFPGAs and one front-end using the second RFPGA prototype.El "sistema en un chip" (SoC) fue adoptado recientemente como una de las soluciones para reducir el coste de sistemas integrados. Cuando se empezó a utilizar la solución SoC, el producto final era más caro debido al bajo rendimiento de producción. Los avances en tecnología integrada a lo largo de los años han permitido la integración de más componentes en menos área con mejoras en rendimiento. Por lo tanto, SoCs pasó a ser una solución ampliamente utilizada para reducir el coste del producto final, integrando en un único chip las principales partes de un sistema: analógica, digital y memoria. A medida que las tecnologías integradas se reducían en tamaño para permitir una mayor densisdad de transistores y proveer mayor funcionalidad con la misma área, las partes RF analógicas del SoC pasaron a ser la limitación en la reducción de costes ya que los inductores ocupan mucha área y no escalan con la tecnología. Por lo tanto, las tendencias en investigación se mueven hacia el diseño de SoCs sin inductores que todavía reducen más el coste final del producto. También, a medida que la demanda en sistemas de comunicación domésticos de alta velocidad ha crecido a lo largo de la última década, se han desarrollado varios estándares para satisfacer los requisitos de cada aplicación, siendo las redes sin hilos (WLANs) basadas en el estándar IEEE 802.11 las más populares. Sin embargo, una pobre propagación de señal a través de las paredes hacen que las WLANs sean inadecuadas para aplicaciones de alta-velocidad como transmisión de vídeo de alta definición en tiempo real, resultando en el desarrollo de tecnologías con hilos utilizando la infraestructura existente en los domicilios. La recomendación ITU-T G.hn (G.9960 and G.9961) unifica las principales infraestructuras con hilos domésticas (cables coaxiales, línias de teléfono y línias de electricidad) en un sólo estándar para la transmisión de datos hasta 1 Gb/s. La recomendación G.hn define una red unificada sobre línias de electricidad, de teléfono y coaxiales con diferentes esquemas para banda base y RF. El esquema RF-coax en el cual se basa esta tesis, usa canales con un ancho de banda de 50 MHz y 100 MHz con 256 y 512 portadoras respectivamente. La frecuencia centra puede variar desde 350 MHz hasta 2450 MHz. La recomendación especifica un límite en la potencia de transmisión de 5 dBm para el esquema de 50 MHz y 8 dBm para el esquema de 100 MHz, de tal forma que la potencia máxima por portadora es la misma en ambos esquemas. Debido a la estructura de un entorno doméstico con hilos, los receptores deben ser capaces de procesar señales con amplitud muy grande o muy pequeña; cuando transmisor y receptor están conectados en la misma toma eléctrica no hay atenuación de canal y el ratio de señal a rudio más distorsión (SNDR) está dominado por la linealidad del receptor, mientras que cuando transmisor y receptor están separados por varias habitaciones la atenuación es elevada y el SNDR está dominado por la figura de ruido del receptor. Los elevados requisitos de rango dinámico para este tipo de receptores requieren el uso de topologías de ganancia configurable que pueden proporcionar tanto alta linealidad como bajo ruido para diferentes configuraciones. Por lo tanto, esta tesis está encarada a la investigación de topologías sin inductores de banda ancha y elevado rango dinámico para ser usadas a la entrada de un receptor G.hn cumpliendo con las especificaciones proporcionadas. Una gran parte de la tesis se ha centrado en el diseño del amplificador de entrada al ser la etapa más crítica, ya que la figura de ruido y linealidad del amplificador de entrada definen lás máximas especificaciones que el sistema puede conseguir. Se han fabricado 3 prototipos con un proceso CMOS de 65 nm: 2 amplificadores y un sistema completo con amplificador y mezclador.Postprint (published version

Linearity vs. Power Consumption of CMOS LNAs in LTE Systems

This paper presents a study of linearity in wideband CMOS low noise amplifiers (LNA) and its relationship to power consumption in context of Long Term Evolution (LTE) system. Using proposed figure of merit to compare 35 state-of-the-art LNA circuits published in recent years, the paper shows a proportional but relatively weak dependence between amplifier performance (that is combined linearity, noise figure and gain) with power consumption. As a result, the predicted increase of LNA performance, necessary to satisfy stringent linearity specifications of LTE standard, may require a significant increase in power, a critical budget planning aspect for both handheld devices and base stations operating in small cells

Low-power CMOS front-ends for wireless personal area networks

The potential of implementing subthreshold radio frequency circuits in deep sub-micron CMOS technology was investigated for developing low-power front-ends for wireless personal area network (WPAN) applications. It was found that the higher transconductance to bias current ratio in weak inversion could be exploited in developing low-power wireless front-ends, if circuit techniques are employed to mitigate the higher device noise in subthreshold region. The first fully integrated subthreshold low noise amplifier was demonstrated in the GHz frequency range requiring only 260 μW of power consumption. Novel subthreshold variable gain stages and down-conversion mixers were developed. A 2.4 GHz receiver, consuming 540 μW of power, was implemented using a new subthreshold mixer by replacing the conventional active low noise amplifier by a series-resonant passive network that provides both input matching and voltage amplification. The first fully monolithic subthreshold CMOS receiver was also implemented with integrated subthreshold quadrature LO (Local Oscillator) chain for 2.4 GHz WPAN applications. Subthreshold operation, passive voltage amplification, and various low-power circuit techniques such as current reuse, stacking, and differential cross coupling were combined to lower the total power consumption to 2.6 mW. Extremely compact resistive feedback CMOS low noise amplifiers were presented as a cost-effective alternative to narrow band LNAs using high-Q inductors. Techniques to improve linearity and reduce power consumption were presented. The combination of high linearity, low noise figure, high broadband gain, extremely small die area and low power consumption made the proposed LNA architecture a compelling choice for many wireless applications.Ph.D.Committee Chair: Laskar, Joy; Committee Member: Chakraborty, Sudipto; Committee Member: Chang, Jae Joon; Committee Member: Divan, Deepakraj; Committee Member: Kornegay, Kevin; Committee Member: Tentzeris, Emmanoui

A 5-Gb/s 66 dB CMOS variable-gain amplifier with reconfigurable DC-offset cancellation for multi-standard applications

This paper proposes a variable gain amplifier (VGA) with reconfigurable DC-offset cancellation (DCOC) for multi-standard applications. In this design, a cell-based design method and some bandwidth extension technologies are adopted to achieve a high data rate and a wide gain control range simultaneously. In addition, the DCOC having a tunable lower-cutoff frequency can make an optimum compromise between BER and SNR according to the specified baseband standard. The measurements show that the VGA achieves a gain control range from −6 dB to 60 dB, a bandwidth beyond 3 GHz, and a tunable lower-cutoff frequency from 0 to 300 kHz. When entering a 2 23 −1 pseudo-random bit sequence signal at 5 Gb/s, the VGA consumes 17 mW from a 1.2-V supply and the output data peak-to-peak jitter is less than 40 ps. The VGA is fabricated in a 90-nm CMOS process with a chip size (including all pads) of 0.52×0.5 mm 2

Feedback methods for inductorless bandwidth extension and linearisation of post-amplifiers in optical receiver frontends

Optical communication is increasingly important in today's telecommunications. It is not only a key component in long-haul infrastructure, but is also being brought into new applications within the datacentre, at the circuit board and integrated circuit level, and in next generation mobile networks. This thesis proposes feedback tuning approaches in order to address two challenges within optical receiver analog frontend circuits: a) the dynamic response of a prior bandwidth extension technique; and b) linearity optimisation. To address dynamic response, we begin with an inductorless method of bandwidth extension using positive feedback loops. In a multi-stage post-amplifier with local positive feedback loops, we propose an approach which tunes each positive feedback gain separately, and demonstrate that this achieves better dynamic response and eye opening than the prior equal-feedback-gain approach. We additionally propose root-locus analysis as a means of characterising dynamic response, and suggest some design guidelines based on this analysis. To address linearity optimisation, we propose the use of an interleaving negative-feedback post-amplifier topology, previously proposed only for bandwidth extension. We investigate the relationship between the feedback gains and linearity and develop a design approach for linearity optimisation. We then designed and fabricated two 70 dB 6 GHz optical receiver circuits, making use of two different post-amplifiers, in order to compare different design approaches. We achieved a linearity of 0.08 dBVrms OIP3 (quasi-static) and a THD of 0.195\% at 1 GHz

Receiver Front-Ends in CMOS with Ultra-Low Power Consumption

Historically, research on radio communication has focused on improving range and data rate. In the last decade, however, there has been an increasing demand for low power and low cost radios that can provide connectivity with small devices around us. They should be able to offer basic connectivity with a power consumption low enough to function extended periods of time on a single battery charge, or even energy scavenged from the surroundings. This work is focused on the design of ultra-low power receiver front-ends intended for a receiver operating in the 2.4GHz ISM band, having an active power consumption of 1mW and chip area of 1mm². Low power consumption and small size make it hard to achieve good sensitivity and tolerance to interference. This thesis starts with an introduction to the overall receiver specifications, low power radio and radio standards, front-end and LO generation architectures and building blocks, followed by the four included papers. Paper I demonstrates an inductorless front-end operating at 915MHz, including a frequency divider for quadrature LO generation. An LO generator operating at 2.4GHz is shown in Paper II, enabling a front-end operating above 2GHz. Papers III and IV contain circuits with combined front-end and LO generator operating at or above the full 2.45GHz target frequency. They use VCO and frequency divider topologies that offer efficient operation and low quadrature error. An efficient passive-mixer design with improved suppression of interference, enables an LNA-less design in Paper IV capable of operating without a SAW-filter

Wideband CMOS low noise amplifiers

Modern fully integrated receiver architectures, require inductorless circuits to achieve their potential low area, low cost, and low power. The low noise amplifier (LNA), which is a key block in such receivers, is investigated in this thesis. LNAs can be either narrowband or wideband. Narrowband LNAs use inductors and have very low noise figure, but they occupy a large area and require a technology with RF options to obtain inductors with high Q. Recently, wideband LNAs with noise and distortion cancelling, with passive loads have been proposed, which can have low NF, but have high power consumption. In this thesis the main goal is to obtain a very low area, low power, and low-cost wideband LNA. First, it is investigated a balun LNA with noise and distortion cancelling with active loads to boost the gain and reduce the noise figure (NF). The circuit is based on a conventional balun LNA with noise and distortion cancellation, using the combination of a common-gate (CG) stage and common-source (CS) stage. Simulation and measurements results, with a 130 nm CMOS technology, show that the gain is enhanced by about 3 dB and the NF is reduced by at least 0.5 dB, with a negligible impact on the circuit linearity (IIP3 is about 0 dBm). The total power dissipation is only 4.8 mW, and the active area is less than 50 x 50 m2 . It is also investigated a balun LNA in which the gain is boosted by using a double feedback structure.We propose to replace the load resistors by active loads, which can be used to implement local feedback loops (in the CG and CS stages). This will boost the gain and reduce the noise figure (NF). Simulation results, with the same 130 nm CMOS technology as above, show that the gain is 24 dB and NF is less than 2.7 dB. The total power dissipation is only 5.4 mW (since no extra blocks are required), leading to a figure-of-merit (FoM) of 3.8 mW1, using 1.2 V supply. The two LNA approaches proposed in this thesis are validated by simulation and by measurement results, and are included in a receiver front-end for biomedical applications (ISM and WMTS), as an example; however, they have a wider range of applications