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| Author | : Raghavasimhan Thirunarayanan |
| Publisher | : |
| Total Pages | : 149 |
| Release | : 2016 |
| Genre | : |
| ISBN | : |
Mots-clés de l'auteur: LP ; IoT ; WMNs ; Duty cycling ; Quantization Noise ; MEMS ; FBAR ; fast start up ; frequency agility ; Loop-free Synthesizers ; Phase Domain DDS.
| Author | : Chung-Chih Hung |
| Publisher | : Springer Nature |
| Total Pages | : 231 |
| Release | : 2021-12-07 |
| Genre | : Technology & Engineering |
| ISBN | : 3030888452 |
This book introduces the origin of biomedical signals and the operating principles behind them and introduces the characteristics of common biomedical signals for subsequent signal measurement and judgment. Since biomedical signals are captured by wearable devices, sensor devices, or implanted devices, these devices are all battery-powered to maintain long working time. We hope to reduce their power consumption to extend service life, especially for implantable devices, because battery replacement can only be done through surgery. Therefore, we must understand how to design low-power integrated circuits. Both implantable and in-vitro medical signal detectors require two basic components to collect and transmit biomedical signals: an analog-to-digital converter and a frequency synthesizer because these measured biomedical signals are wirelessly transmitted to the relevant receiving unit. The core unit of wireless transmission is the frequency synthesizer, which provides a wide frequency range and stable frequency to demonstrate the quality and performance of the wireless transmitter. Therefore, the basic operating principle and model of the frequency synthesizer are introduced. We also show design examples and measurement results of a low-power low-voltage integer-N frequency synthesizer for biomedical applications. The detection of biomedical signals needs to be converted into digital signals by an analog-to-digital converter to facilitate subsequent signal processing and recognition. Therefore, the operating principle of the analog-to-digital converter is introduced. We also show implementation examples and measurement results of low-power low-voltage analog-to-digital converters for biomedical applications.
| Author | : David Gaidioz |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 2021 |
| Genre | : |
| ISBN | : |
More than twenty billion of connected devices are predicted in the coming years, the Internet-of-Things (IoT) is a common reality of our day-to-day lives. Concerning a connected object, two critical parameters have to be taken into account: the power consumption has to be minimized to increase the battery-operate lifetime, and the cost of the object has to be as low as possible to ensure a successful mass deployment.The frequency synthesis design is ruled by the same IoT challenges. Although today solutions provide a power consumption around ten mW, Ultra Lower Power (ULP) solutions are more and more targeted. Realized in the frame of the common laboratory between STMicroelectronics and IMS Laboratory, this CIFRE thesis Propose a new frequency synthesis circuit implemented in 28nm FD-SOI technology. The specifications of this alternative solution are drawn to reach optimum compromise in terms of power consumption, RF performances and silicon area.
| Author | : Jouko Vankka |
| Publisher | : Springer Science & Business Media |
| Total Pages | : 374 |
| Release | : 2005-10-25 |
| Genre | : Technology & Engineering |
| ISBN | : 1402031955 |
The approach adopted in Digital Synthesizers and Transmitters for Software Radio will provide an understanding of key areas in the field of digital synthesizers and transmitters. It is easy to include different digital techniques in the digital synthesizers and transmitters by using digital signal processing methods, because the signal is in digital form. By programming the digital synthesizers and transmitters, adaptive channel bandwidths, modulation formats, frequency hopping and data rates are easily achieved. Techniques such as digital predistortion for power amplifier linearization, digital compensation methods for analog I/Q modulator nonlinearities and digital power control and ramping are presented in this book. The flexibility of the digital synthesizers and transmitters makes them ideal as signal generators for software radio. Software radios represent a major change in the design paradigm for radios in which a large portion of the functionality is implemented through programmable signal processing devices, giving the radio the ability to change its operating parameters to accommodate new features and capabilities. A software radio approach reduces the content of radio frequency (RF) and other analog components of traditional radios and emphasizes digital signal processing to enhance overall transmitter flexibility. Software radios are emerging in commercial and military infrastructure.
| Author | : Vladimir Kopta |
| Publisher | : CRC Press |
| Total Pages | : 224 |
| Release | : 2022-09-01 |
| Genre | : Technology & Engineering |
| ISBN | : 1000794490 |
Over the past two decades we have witnessed the increasing popularity of the internet of things. The vision of billions of connected objects, able to interact with their environment, is the key driver directing the development of future communication devices. Today, power consumption as well as the cost and size of radios remain some of the key obstacles towards fulfilling this vision. Ultra-Low Power FM-UWB Transceivers for IoT presents the latest developments in the field of low power wireless communication. It promotes the FM-UWB modulation scheme as a candidate for short range communication in different IoT scenarios. The FM-UWB has the potential to provide exactly what is missing today. This spread spectrum technique enables significant reduction in transceiver complexity, making it smaller, cheaper and more energy efficient than most alternative options. The book provides an overview of both circuit-level and architectural techniques used in low power radio design, with a comprehensive study of state-of-the-art examples. It summarizes key theoretical aspects of FM-UWB with a glimpse at potential future research directions. Finally, it gives an insight into a full FM-UWB transceiver design, from system level specifications down to transistor level design, demonstrating the modern power reduction circuit techniques. Ultra-Low Power FM-UWB Transceivers for IoT is a perfect text and reference for engineers working in RF IC design and wireless communication, as well as academic staff and graduate students engaged in low power communication systems research.
| Author | : David James Betowski |
| Publisher | : |
| Total Pages | : |
| Release | : 2004 |
| Genre | : Frequency synthesizers |
| ISBN | : |
| Author | : Adem Aktas |
| Publisher | : |
| Total Pages | : |
| Release | : 2004 |
| Genre | : Frequency synthesizers |
| ISBN | : |
Abstract: PLL (Phase-Locked Loop) frequency synthesizers are used in wireless transceivers for frequency conversion. Recent directions in PLL frequency synthesizer research and development are to fully integrate PLL synthesizers in CMOS technology, to improve phase noise performance, and to operate wide range of frequency bands and channel bandwidths. Fully integration of synthesizers in CMOS technology is desired for low cost, low power consumption and small size in mobile wireless terminals. Low phase noise is required by digital modulation techniques which have been used in new mobile standards for the efficient use of the frequency spectrum. Operation over a wide range of frequency bands and channel bandwidths are required to support migration and backward compatibility in the wireless standard evolution. This work investigates the PLL frequency synthesizer design and implementation in CMOS technology with focus on integration of wideband VCOs (Voltage-Controlled Oscillators). Phase noise of a PLL synthesizer is a major design parameter. A PLL noise model is developed for noise optimization purposes. Wideband RF VCO design with sub-bands is investigated. Frequency planning, synthesizer architecture and technology considerations are also explored for wideband VCO design. Band switching techniques VCO tuning range presented. Active VCO circuit topologies and resonator design are also presented. The PLL frequency synthesizers are designed and implemented for a multi-band/standard(IEEE 802.11a/b/g) WLAN radio in 0.18um CMOS. Phase noise trade-offs for PLL design are explored in this application. Development and design of a wideband VCO for this application is also presented. An auto calibration circuit is developed for VCO tuning band selection. Another application of the wideband PLL frequency synthesizer is designed and implemented for a fully integrated dual-mode frequency synthesizer for GSM and WCDMA standards in 0.5um CMOS. A hybrid integer-N/fractional-N architecture is developed to meet the multi-standard requirements. Design and implementation of high performance RF VCO depends on the RF models of the devices. RF CMOS characterization and modeling techniques are explored. Microwave wafer measurement and calibration techniques are also investigated for CMOS technology.
| Author | : 黃鈺絜 |
| Publisher | : |
| Total Pages | : 98 |
| Release | : 2020 |
| Genre | : |
| ISBN | : |
| Author | : Kasra Ardalan |
| Publisher | : |
| Total Pages | : 0 |
| Release | : 1998 |
| Genre | : |
| ISBN | : |
Frequency synthesizers find wide applications in different communication systems. The demand for higher performance and speed from one side, and lower power consumption and cost from another side, makes the synthesizer's design a challenging task. In this thesis, a very low power integrated circuit fractional-N frequency synthesizer was designed which employs a $\Delta\Sigma$ modulator in its architecture to digitally control the output frequency and also to shape the noise of the dual modulus divider. The target application for this design is clock recovery in digital communication receivers in which the timing information is obtained in digital domain (such as baud-rate timing recovery method). This information has to be applied to a digitally-controlled frequency synthesizer which generates pulses to sample the incoming data for extracting the information. The center frequency of VCO is around 315 MHz which makes the system suitable for high speed applications (622Mb/s in case of 4-PAM modulation scheme). The chip is fabricated in a CMOS 0.35$\mu$ process and consumes only 8.5 mW power using a single 3.3 V power supply.
| Author | : Massimo Alioto |
| Publisher | : Springer |
| Total Pages | : 527 |
| Release | : 2017-01-23 |
| Genre | : Technology & Engineering |
| ISBN | : 3319514822 |
This book offers the first comprehensive view on integrated circuit and system design for the Internet of Things (IoT), and in particular for the tiny nodes at its edge. The authors provide a fresh perspective on how the IoT will evolve based on recent and foreseeable trends in the semiconductor industry, highlighting the key challenges, as well as the opportunities for circuit and system innovation to address them. This book describes what the IoT really means from the design point of view, and how the constraints imposed by applications translate into integrated circuit requirements and design guidelines. Chapter contributions equally come from industry and academia. After providing a system perspective on IoT nodes, this book focuses on state-of-the-art design techniques for IoT applications, encompassing the fundamental sub-systems encountered in Systems on Chip for IoT: ultra-low power digital architectures and circuits low- and zero-leakage memories (including emerging technologies) circuits for hardware security and authentication System on Chip design methodologies on-chip power management and energy harvesting ultra-low power analog interfaces and analog-digital conversion short-range radios miniaturized battery technologies packaging and assembly of IoT integrated systems (on silicon and non-silicon substrates). As a common thread, all chapters conclude with a prospective view on the foreseeable evolution of the related technologies for IoT. The concepts developed throughout the book are exemplified by two IoT node system demonstrations from industry. The unique balance between breadth and depth of this book: enables expert readers quickly to develop an understanding of the specific challenges and state-of-the-art solutions for IoT, as well as their evolution in the foreseeable future provides non-experts with a comprehensive introduction to integrated circuit design for IoT, and serves as an excellent starting point for further learning, thanks to the broad coverage of topics and selected references makes it very well suited for practicing engineers and scientists working in the hardware and chip design for IoT, and as textbook for senior undergraduate, graduate and postgraduate students ( familiar with analog and digital circuits).
