509 research outputs found

    A 1.2 V and 69 mW 60 GHz Multi-channel Tunable CMOS Receiver Design

    Get PDF
    A multi-channel receiver operating between 56 GHz and 70 GHz for coverage of different 60 GHz bands worldwide is implemented with a 90 nm Complementary Metal-Oxide Semiconductor (CMOS) process. The receiver containing an LNA, a frequency down-conversion mixer and a variable gain amplifier incorporating a band-pass filter is designed and implemented. This integrated receiver is tested at four channels of centre frequencies 58.3 GHz, 60.5 GHz, 62.6 GHz and 64.8 GHz, employing a frequency plan of an 8 GHz-intermediate frequency (IF). The achieved conversion gain by coarse gain control is between 4.8 dB–54.9 dB. The millimeter-wave receiver circuit is biased with a 1.2V supply voltage. The measured power consumption is 69 mW

    Current reuse topology in UWB CMOS LNA

    Get PDF
    Non

    Trends and Challenges in CMOS Design for Emerging 60 GHz WPAN Applications

    Get PDF
    International audienceThe extensive growth of wireless communications industry is creating a big market opportunity. Wireless operators are currently searching for new solutions which would be implemented into the existing wireless communication networks to provide the broader bandwidth, the better quality and new value-added services. In the last decade, most commercial efforts were focused on the 1-10 GHz spectrum for voice and data applications for mobile phones and portable computers (Niknejad & Hashemi, 2008). Nowadays, the interest is growing in applications that use high rate wireless communications. Multigigabit- per-second communication requires a very large bandwidth. The Ultra-Wide Band (UWB) technology was basically used for this issue. However, this technology has some shortcomings including problems with interference and a limited data rate. Furthermore, the 3-5 GHz spectrum is relatively crowded with many interferers appearing in the WiFi bands (Niknejad & Hashemi, 2008). The use of millimeter wave frequency band is considered the most promising technology for broadband wireless. In 2001, the Federal Communications Commission (FCC) released a set of rules governing the use of spectrum between 57 and 66 GHz (Baldwin, 2007). Hence, a large bandwidth coupled with high allowable transmit power equals high possible data rates. Traditionally the implementation of 60 GHz radio technology required expensive technologies based on III-V compound semiconductors such as InP and GaAs (Smulders et al., 2007). The rapid progress of CMOS technology has enabled its application in millimeter wave applications. Currently, the transistors became small enough, consequently fast enough. As a result, the CMOS technology has become one of the most attractive choices in implementing 60 GHz radio due to its low cost and high level of integration (Doan et al., 2005). Despite the advantages of CMOS technology, the design of 60 GHz CMOS transceiver exhibits several challenges and difficulties that the designers must overcome. This chapter aims to explore the potential of the 60 GHz band in the use for emergent generation multi-gigabit wireless applications. The chapter presents a quick overview of the state-of-the-art of 60 GHz radio technology and its potentials to provide for high data rate and short range wireless communications. The chapter is organized as follows. Section 2 presents an overview about 60 GHz band. The advantages are presented to highlight the performance characteristics of this band. The opportunities of the physical layer of the IEEE 802.15.3c standard for emerging WPAN applications are discussed in section 3. The tremendous opportunities available with CMOS technology in the design of 60 GHz radio is discussed in section 4. Section 5 shows an example of 60 GHz radio system link. Some challenges and trade-offs on the design issues of circuits and systems for 60 GHz band are reported in section 6. Finally, section 7 presents the conclusion and some perspectives on future directions

    Ultra-Wideband CMOS Transceiver Front-End for Bio-Medical Radar Sensing

    Get PDF
    Since the Federal Communication Commission released the unlicensed 3.1-10.6 GHz frequency band for commercial use in early 2002, the ultra wideband (UWB) has developed from an emerging technology into a mainstream research area. The UWB technology, which utilizes wide spectrum, opens a new era of possibility for practical applications in radar sensing, one of which is the human vital sign monitoring. The aim of this thesis is to study and research the possibility of a new generation humanrespiration monitoring sensor using UWB radar technology and to develop a new prototype of UWB radar sensor for system-on-chip solutions in CMOS technology. In this thesis, a lowpower Gaussian impulse UWB mono-static radar transceiver architecture is presented. The UWB Gaussian pulse transmitter and receiver are implemented and fabricated using 90nm CMOS technology. Since the energy of low order Gaussian pulse is mostly condensed at lower frequency, in order to transmit the pulse in a very efficient way, higher order Gaussian derivative pulses are desired as the baseband signal. This motivates the advancement of the design into UWB high-order pulse transmitter. Both the Gaussian impulse UWB transmitter and Gaussian higher-order impulse UWB transmitter take the low-power and high-speed advantage of digital circuit to generate different waveforms. The measurement results are analyzed and discussed. This thesis also presents a low-power UWB mono-static radar transceiver architecture exploiting the full benefit of UWB bandwidth in radar sensing applications. The transceiver includes a full UWB band transmitter, an UWB receiver front-end, and an on-chip diplexer. The non-coherent UWB transmitter generates pulse modulated baseband signals at different carrier frequencies within the designated 3-10 GHz band using a digitally controlled pulse generator. The test shows the proposed radar transceiver can detect the human respiration pattern within 50 cm distance. The applications of this UWB radar sensing solution in commercialized standard CMOS technology include constant breathing pattern monitoring for gated radiation therapy, realtime monitoring of patients, and any other breathing monitoring. The research paves the way to wireless technology integration with health care and bio-sensor network

    Design and Analysis of SiGe Millimeter-Wave Radio Front-End MMICs For 5G Communication

    Get PDF
    This thesis focuses on design and realization of millimeter-wave radio frontend circuits for fifth generation(5G) wireless communication in 0.13um silicongermanium(SiGe) BiCMOS process. Radio front-end includes single-pole doublethrough (SPDT) switch, low noise amplifier (LNA) and buffer amplifier(BA) as a part of radio frequency(RF) transceiver system for E-band. The SPDT switch utilizes the reveres saturated SiGe heterojunction bipolar transistor(HBT). The resulting reverse saturated switch shows an insertion loss of 1 dB , isolation of 26 dB, reflection coefficient better than 25 dB at 75 GHz and provides a bandwidth of 40 GHz. A single to differential ended low noise amplifier(LNA)is designed using transformer balun. Simultaneous noise and impedance matching is used in order to realize both low noise and low reflection at the same time. The post layout simulation of E-band low noise amplifier exhibits a gain and noise figure(NF) of 26 dB and 5.5 dB respectively with a power consumption of 33.5 mW. The buffer amplifier shows a gain of 5.5 dB at 75 GHz. Finally, the receiver achieved a gain of 19.6 dB, noise figure(NF) of 6.9 dB and impedance matching better than 13.5 dB at 75 GHz. A 3 dB bandwidth of more than 12 GHz is achieved from the receiver. Extensive simulation results showing the performance of each circuit of receiver are presented

    Feasibility Study and Design of a Wearable System-on-a-Chip Pulse Radar for Contactless Cardiopulmonary Monitoring

    Get PDF
    A new system-on-a-chip radar sensor for next-generation wearable wireless interface applied to the human health care and safeguard is presented. The system overview is provided and the feasibility study of the radar sensor is presented. In detail, the overall system consists of a radar sensor for detecting the heart and breath rates and a low-power IEEE 802.15.4 ZigBee radio interface, which provides a wireless data link with remote data acquisition and control units. In particular, the pulse radar exploits 3.1–10.6 GHz ultra-wideband signals which allow a significant reduction of the transceiver complexity and then of its power consumption. The operating principle of the radar for the cardiopulmonary monitoring is highlighted and the results of the system analysis are reported. Moreover, the results obtained from the building-blocks design, the channel measurement, and the ultra-wideband antenna realization are reported

    Quadrature Phase-Domain ADPLL with Integrated On-line Amplitude Locked Loop Calibration for 5G Multi-band Applications

    Get PDF
    5th generation wireless systems (5G) have expanded frequency band coverage with the low-band 5G and mid-band 5G frequencies spanning 600 MHz to 4 GHz spectrum. This dissertation focuses on a microelectronic implementation of CMOS 65 nm design of an All-Digital Phase Lock Loop (ADPLL), which is a critical component for advanced 5G wireless transceivers. The ADPLL is designed to operate in the frequency bands of 600MHz-930MHz, 2.4GHz-2.8GHz and 3.4GHz-4.2GHz. Unique ADPLL sub-components include: 1) Digital Phase Frequency Detector, 2) Digital Loop Filter, 3) Channel Bank Select Circuit, and 4) Digital Control Oscillator. Integrated with the ADPLL is a 90-degree active RC-CR phase shifter with on-line amplitude locked loop (ALL) calibration to facilitate enhanced image rejection while mitigating the effects of fabrication process variations and component mismatch. A unique high-sensitivity high-speed dynamic voltage comparator is included as a key component of the active phase shifter/ALL calibration subsystem. 65nm CMOS technology circuit designs are included for the ADPLL and active phase shifter with simulation performance assessments. Phase noise results for 1 MHz offset with carrier frequencies of 600MHz, 2.4GHz, and 3.8GHz are -130, -122, and -116 dBc/Hz, respectively. Monte Carlo simulations to account for process variations/component mismatch show that the active phase shifter with ALL calibration maintains accurate quadrature phase outputs when operating within the frequency bands 600MHz-930MHz, 2.4GHz-2.8GHz and 3.4GHz-4.2GHz

    Configurable circuits and their impact on multi-standard RF front-end architectures

    Get PDF
    This thesis studies configurable circuits and their impact on multi-standard RF front-end architectures. In particular, low-voltage low-power linear LNA and mixer topologies suitable for implementation in multi-standard front-ends are subject of the investigation. With respect to frequency and bandwidth, multi-standard front-ends can be implemented using either tunable or wideband LNA and mixer topologies. Based on the type of the LNA and mixer(s), multi-standard receiver RF front-ends can be divided into three groups. They can be (tunable) narrow-band, wide-band or combined. The advantages and disadvantages of the different multi-standard receiver RF front-ends have been discussed in detail. The partitioning between off-chip selectivity, on-chip selectivity provided by the LNA and mixer, linearity, power consumption and occupied chip area in each multi-standard RF front-end group are thoroughly investigated. A Figure of Merit (FOM) for the multi-standard receiver RF front-end has been introduced. Based on this FOM the most suitable multi-standard RF front-end group in terms of cost-effectiveness can be selected. In order to determine which multi-standard RF front-end group is the most cost-effective for a practical application, a GSM850/E-GSM/DCS/PCS/Bluetooth/WLANa/b/g multi-standard receiver RF front-end is chosen as a demonstrator. These standards are the most frequently used standards in wireless communication, and this combination of standards allows to users almost "anytime-anywhere" voice and data transfer. In order to verify these results, three demonstrators have been defined, designed and implemented, two wideband RF front-end circuits in 90nm CMOS and 65nm CMOS, and one combined multi-standard RF front-end circuit in 65nm CMOS. The proposed multi-standard demonstrators have been compared with the state-of the art narrow-band, wide-band and combined multi-standard RF front-ends. On the proposed multi-standard RF front-ends and the state-of the art multi-standard RF front-ends the proposed FOM have been applied. The comparison shows that the combined multi-standard RF front-end group is the most cost effective multi-standard group for this application

    An Energy-Efficient Reconfigurable Mobile Memory Interface for Computing Systems

    Get PDF
    The critical need for higher power efficiency and bandwidth transceiver design has significantly increased as mobile devices, such as smart phones, laptops, tablets, and ultra-portable personal digital assistants continue to be constructed using heterogeneous intellectual properties such as central processing units (CPUs), graphics processing units (GPUs), digital signal processors, dynamic random-access memories (DRAMs), sensors, and graphics/image processing units and to have enhanced graphic computing and video processing capabilities. However, the current mobile interface technologies which support CPU to memory communication (e.g. baseband-only signaling) have critical limitations, particularly super-linear energy consumption, limited bandwidth, and non-reconfigurable data access. As a consequence, there is a critical need to improve both energy efficiency and bandwidth for future mobile devices.;The primary goal of this study is to design an energy-efficient reconfigurable mobile memory interface for mobile computing systems in order to dramatically enhance the circuit and system bandwidth and power efficiency. The proposed energy efficient mobile memory interface which utilizes an advanced base-band (BB) signaling and a RF-band signaling is capable of simultaneous bi-directional communication and reconfigurable data access. It also increases power efficiency and bandwidth between mobile CPUs and memory subsystems on a single-ended shared transmission line. Moreover, due to multiple data communication on a single-ended shared transmission line, the number of transmission lines between mobile CPU and memories is considerably reduced, resulting in significant technological innovations, (e.g. more compact devices and low cost packaging to mobile communication interface) and establishing the principles and feasibility of technologies for future mobile system applications. The operation and performance of the proposed transceiver are analyzed and its circuit implementation is discussed in details. A chip prototype of the transceiver was implemented in a 65nm CMOS process technology. In the measurement, the transceiver exhibits higher aggregate data throughput and better energy efficiency compared to prior works
    • 

    corecore