Global ETD Search

51	Design of a Low Power Fractional-N PLL Frequency Synthesizer in 65nm CMOS Chaille, Jack Ryan 23 May 2022 (has links) No description available. Electrical Engineering PLL frequency synthesizer fractional-N low power low-power delta sigma phase locked loop phase-locked loop DSM delta-sigma
52	Design of an Ultra-Low Phase Noise and Wide-Band Digital Phase Locked Loop for AWS and PCS Band Applications and CppSim Evaluation Tiagaraj, Sathya Narasimman 27 September 2016 (has links) No description available. Engineering Electrical Engineering
53	Frequency Synthesis for Cognitive Radio Receivers and Other Wideband Applications Zahir, Zaira January 2017 (has links) (PDF) The radio frequency (RF) spectrum as a natural resource is severely under-utilized over time and space due to an inefficient licensing framework. As a result, in-creasing cellular and wireless network usage is placing significant demands on the licensed spectrum. This has led to the development of cognitive radios, software defined radios and mm-wave radios. Cognitive radios (CRs) enable more efficient spectrum usage over a wide range of frequencies and hence have emerged as an effective solution to handle huge network demands. They promise versatility, flex-ability and cognition which can revolutionize communications systems. However, they present greater challenges to the design of radio frequency (RF) front-ends. Instead of a narrow-band front-end optimized and tuned to the carrier frequency of interest, cognitive radios demand front-ends which are versatile, configurable, tun-able and capable of transmitting and receiving signals with different bandwidths and modulation schemes. The primary purpose of this thesis is to design a re-configurable, wide-band and low phase-noise fast settling frequency synthesizer for cognitive radio applications. Along with frequency generation, an area efficient multi-band low noise amplifier (LNA) with integrated built-in-self-test (BIST) and a strong immunity to interferers has also been proposed and implemented for these radios. This designed LNA relaxes the specification of harmonic content in the synthesizer output. Finally some preliminary work has also been done for mm-wave (V-band) frequency synthesis. The Key Contributions of this thesis are: A frequency synthesizer, based on a type-2, third-order Phase Locked Loop (PLL), covering a frequency range of 0.1-5.4 GHz, is implemented using a 0.13 µm CMOS technology. The PLL uses three voltage controlled oscillators (VCOs) to cover the whole range. It is capable of switching between any two frequencies in less than 3 µs and has phase noise values, compatible with most communication standards. The settling of the PLL in the desired state is achieved in dynamic multiple steps rather than traditional single step settling. This along with other circuit techniques like a DAC-based discriminator aided charge pump, fast acquisition pulse-clocked based PFD and timing synchro-negation is used to obtain a significantly reduced settling time A single voltage controlled LC-oscillator (LC-VCO) has been designed to cover a wide range of frequencies (2.0-4.1 GHz) using an area efficient and switch-able multi-tap inductor and a capacitor bank. The switching of the multi-tap inductor is done in the most optimal manner so as to get good phase-noise at the output. The multi-tap inductor provides a significant area advantage, and in spite of a degraded Q, provides an acceptable phase noise of -123 dBc/Hz and -113 dBc/Hz at an offset of 1 MHz at carrier frequencies of 2 and 4 GHz, respectively. Implemented in a 0.13 µm CMOS technology, the oscillator with ≈ 69 % tuning range, occupies an active area of only 0.095 mm2. An active inductor based noise-filter has been proposed to improve the phase-noise performance of the oscillator without much increase in the area. A variable gain multi-band low noise amplifier (LNA) is designed to operate over a wide range of frequencies (0.8 GHz to 2.4 GHz) using an area efficient switchable-π network. The LNA can be tuned to different gain and linearity combinations for different band settings. Depending upon the location of the interferers, a specific band can be selected to provide optimum gain and the best signal-to-intermodulation ratio. This is accomplished by the use of an on-chip Built-in-Self-Test (BIST) circuit. The maximum power gain of the amplifier is 19 dB with a return loss better than 10 dB for 7 mW of power consumption. The noise figure is 3.2 dB at 1 GHz and its third-order intercept point (I I P3) ranges from -15 dBm to 0 dBm. Implemented in a 0.13 µm CMOS technology, the LNA occupies an active area of about 0.29 mm2. Three different types of VCOs (stand-alone LC VCO, push-push VCO and a ring oscillator based VCO) for generating mm-wave frequencies have been implemented using 65-nm CMOS technology and their measured results have been analyzed Cognitive Radio Cognitive Radio - Wide-Band Receivers Wideband Applications Millimeter Wave Communication Systems Frequency Synthesizers Radio Transceiver Architectures Frequency Synthesizer Specifications Wideband LC-Oscillators Multi-Band Low Noise Amplifier Wide-band LC-VCO Electrical Communication Engineering
54	Frequency Synthesis in Wireless and Wireline Systems Turker, Didem 1981- 14 March 2013 (has links) First, a frequency synthesizer for IEEE 802.15.4 / ZigBee transceiver applications that employs dynamic True Single Phase Clocking (TSPC) circuits in its frequency dividers is presented and through the analysis and measurement results of this synthesizer, the need for low power circuit techniques in frequency dividers is discussed. Next, Differential Cascode Voltage-Switch-Logic (DCVSL) based delay cells are explored for implementing radio-frequency (RF) frequency dividers of low power frequency synthesizers. DCVSL ip- ops offer small input and clock capacitance which makes the power consumption of these circuits and their driving stages, very low. We perform a delay analysis of DCVSL circuits and propose a closed-form delay model that predicts the speed of DCVSL circuits with 8 percent worst case accuracy. The proposed delay model also demonstrates that DCVSL circuits suffer from a large low-to-high propagation delay ( PLH) which limits their speed and results in asymmetrical output waveforms. Our proposed enhanced DCVSL, which we call DCVSL-R, solves this delay bottleneck, reducing PLH and achieving faster operation. We implement two ring-oscillator-based voltage controlled oscillators (VCOs) in 0.13 mu m technology with DCVSL and DCVSL-R delay cells. In measurements, for the same oscillation frequency (2.4GHz) and same phase noise (-113dBc/Hz at 10MHz), DCVSL-R VCO consumes 30 percent less power than the DCVSL VCO. We also use the proposed DCVSL-R circuit to implement the 2.4GHz dual-modulus prescaler of a low power frequency synthesizer in 0.18 mu m technology. In measurements, the synthesizer exhibits -135dBc/Hz phase noise at 10MHz offset and 58 mu m settling time with 8.3mW power consumption, only 1.07mWof which is consumed by the dual modulus prescaler and the buffer that drives it. When compared to other dual modulus prescalers with similar division ratios and operating frequencies in literature, DCVSL-R dual modulus prescaler demonstrates the lowest power consumption. An all digital phase locked loop (ADPLL) that operates for a wide range of frequencies to serve as a multi-protocol compatible PLL for microprocessor and serial link applications, is presented. The proposed ADPLL is truly digital and is implemented in a standard complementary metal-oxide-semiconductor (CMOS) technology without any analog/RF or non-scalable components. It addresses the challenges that come along with continuous wide range of operation such as stability and phase frequency detection for a large frequency error range. A proposed multi-bit bidirectional smart shifter serves as the digitally controlled oscillator (DCO) control and tunes the DCO frequency by turning on/off inverter units in a large row/column matrix that constitute the ring oscillator. The smart shifter block is completely digital, consisting of standard cell logic gates, and is capable of tracking the row/column unit availability of the DCO and shifting multiple bits per single update cycle. This enables fast frequency acquisition times without necessitating dual loop fi lter or gear shifting mechanisms. The proposed ADPLL loop architecture does not employ costly, cumbersome DACs or binary to thermometer converters and minimizes loop filter and DCO control complexity. The wide range ADPLL is implemented in 90nm digital CMOS technology and has a 9-bit TDC, the output of which is processed by a 10-bit digital loop filter and a 5-bit smart shifter. In measurements, the synthesizer achieves 2.5GHz-7.3GHz operation while consuming 10mW/GHz power, with an active area of 0.23 mm2. wireline systems wireless systems TDC DCO DPLL ADPLL digital PLL all digital PLL delay model DCVSL VCO ring oscillator prescaler dual modulus prescaler frequency divider PLL frequency synthesizer Frequency Synthesis
55	High performance continuous-time filters for information transfer systems Mohieldin, Ahmed Nader 30 September 2004 (has links) Vast attention has been paid to active continuous-time filters over the years. Thus as the cheap, readily available integrated circuit OpAmps replaced their discrete circuit versions, it became feasible to consider active-RC filter circuits using large numbers of OpAmps. Similarly the development of integrated operational transconductance amplifier (OTA) led to new filter configurations. This gave rise to OTA-C filters, using only active devices and capacitors, making it more suitable for integration. The demands on filter circuits have become ever more stringent as the world of electronics and communications has advanced. In addition, the continuing increase in the operating frequencies of modern circuits and systems increases the need for active filters that can perform at these higher frequencies; an area where the LC active filter emerges. What mainly limits the performance of an analog circuit are the non-idealities of the used building blocks and the circuit architecture. This research concentrates on the design issues of high frequency continuous-time integrated filters. Several novel circuit building blocks are introduced. A novel pseudo-differential fully balanced fully symmetric CMOS OTA architecture with inherent common-mode detection is proposed. Through judicious arrangement, the common-mode feedback circuit can be economically implemented. On the level of system architectures, a novel filter low-voltage 4th order RF bandpass filter structure based on emulation of two magnetically coupled resonators is presented. A unique feature of the proposed architecture is using electric coupling to emulate the effect of the coupled-inductors, thus providing bandwidth tuning with small passband ripple. As part of a direct conversion dual-mode 802.11b/Bluetooth receiver, a BiCMOS 5th order low-pass channel selection filter is designed. The filter operated from a single 2.5V supply and achieves a 76dB of out-of-band SFDR. A digital automatic tuning system is also implemented to account for process and temperature variations. As part of a Bluetooth transmitter, a low-power quadrature direct digital frequency synthesizer (DDFS) is presented. Piecewise linear approximation is used to avoid using a ROM look-up table to store the sine values in a conventional DDFS. Significant saving in power consumption, due to the elimination of the ROM, renders the design more suitable for portable wireless communication applications. Continuous-time filter OTA-C filter Common-mode feedback Common-mode feedforward Fully differential Pseudo differential Wireless communication LC bandpass filter Direct digital frequency synthesizer frequency tuning Low voltage Low power
56	Spectrum Sensing Receivers for Cognitive Radio Khatri, Vishal January 2016 (has links) (PDF) Cognitive radios require spectral occupancy information in a given location, to avoid any interference with the existing licensed users. This is achieved by spectrum sensing. Existing narrowband, serial spectrum sensors are spectrally inefficient and power hungry. Wideband spectrum sensing increases the number of probable fre-quency candidates for cognitive radio. Wideband RF systems cannot use analog to digital converters (ADCs) for spectrum sensing without increasing the sampling rate and power consumption. The use of ADCs is limited because of the dynamic range of the signals that need to be sampled and the frequency of operation. In this work, we have presented a CMOS based area efficient, dedicated and scalable wideband parallel/serial spectrum sensor for cognitive radio. The key contributions of the thesis are: 1. An injection locked oscillator cascade (ILOC) for parallel LO synthesis. An area-efficient, wideband RF frequency synthesizer, which simultaneously gen-erates multiple local oscillator (LO) signals, is designed. It is suitable for parallel wideband RF spectrum sensing in cognitive radios. The frequency synthesizer consists of an injection locked oscillator cascade where all the LO signals are derived from a single reference oscillator. The ILOC is implemented in a 130-nm technology with an active area of 0.017 mm2. It generates 4 uni-formly spaced LO carrier frequencies from 500 MHz to 2 GHz. 2. A wideband, parallel RF spectrum sensor for cognitive radios has been de-signed. This spectrum sensor is designed to detect RF occupancy from 250 MHz to 5.25 GHz by using an array of CMOS receivers with envelope detec-tors. A parallel LO synthesizer is implemented as an ILOC. The simulated sensitivity is around -25 dBm for 250 MHz wide bandwidth. 3. A mitigation technique for harmonic downconversion in wideband spectrum sensors. The downconversion of radio frequency (RF) components around the harmonics of the local oscillator (LO), and its impact on the accuracy of white space detection using integrated spectrum sensors, is (are) studied. We propose an algorithm to mitigate the impact of harmonic Down conversion by utilizing multiple parallel downconverters in the system architecture. The proposed algorithm is validated on a test-board using commercially avail-able integrated circuits (IC) and a test-chip implemented in a 130-nm CMOS technology. The measured data shows that the impact of the harmonic down-conversion is closely related to the LO characteristics, and that much of it can be mitigated by the proposed technique. 4. A wideband spectrum sensor for narrowband energy detection. A wideband spectrum sensing system for cognitive radio is designed and implemented in a 130-nm RF mixed-mode CMOS technology. The system employs an I-Q downconverter, a pair of complex filters and a pair of envelope detectors for energy detection. The spectrum sensor works from 250 MHz to 3.25 GHz. The design makes use of the band pass nature of the complex filter to achieve two objectives : i) Separation of upper sideband (USB) and lower sideband (LSB) around the local oscillator (LO) signal and ii) Resolution of smaller bands within a large detection bandwidth. The measured sensitivity is close to -45 dBm for a single tone test over a bandwidth of 40 MHz. The measured Image reject ratio (IRR) is close to 30 dB. The overall sensing bandwidth is 3.5 GHz and the overall wideband detection bandwidth is 250 MHz which is partitioned into 40 MHz narrowband chunks with 8 such overlapping chunks. Cognitive Radio Spectrum Sensing Spectrum Sensor Cognitive Radios (CR) Securing Military Networks Emergency Network Deployment Wireless Technologies Spectrum Sensing Receivers Harmonic Downconversion Hilbert Transform Spectrum Sensors Radio Frequency Synthesizer Spectrum Sensing Receiver Specification Communication Engineering
57	Low Power And Low Spur Frequency Synthesizer Circuit Techniques For Energy Efficient Wireless Transmitters Manikandan, R R 09 1900 (has links) (PDF) There has been a huge rise in interest in the design of energy efficient wireless sensor networks (WSN) and body area networks (BAN) with the advent of many new applications over the last few decades. The number of sensor nodes in these applications has also increased tremendously in the order of few hundreds in recent years. A typical sensor node in a WSN consists of circuits like RF transceivers, micro-controllers or DSP, ADCs, sensors, and power supply circuits. The RF transmitter and receiver circuits mainly the frequency synthesizers(synthesis of RF carrier and local oscillator signals in transceivers) consume a significant percentage of its total power due to its high frequency of operation. A charge-pump phase locked loop (CP-PLL) is the most commonly used frequency synthesizer architecture in these applications. The growing demands of WSN applications, such as low power consumption larger number of sensor nodes, single chip solution, and longer duration operation presents several design challenges for these transmitter and frequency synthesizer circuits in these applications and a few are listed below, Low power frequency synthesizer and transmitter designs with better spectral performance is essential for an energy efficient operation of these applications. The spurious tones in the frequency synthesizer output will mix the interference signals from nearby sensor nodes and from other interference sources present nearby ,to degrade the wireless transmitter and receiver performance[1]. With the increased density of sensor nodes (more number of in-band interference sources) and degraded performance of analog circuits in the nano-meter CMOS process technologies, the spur reduction techniques are essential to improve the performance of frequency synthesizers in these applications. A single chip solution of sensor nodes with its analog and digital circuits integrated on the same die is preferred for its low power, low cost, and reduced size implementation. However, the parasitic interactions between these analog and digital sub-systems integrated on a common substrate, degrade the spectral performance of frequency synthesizers in these implementations[2]. Therefore, techniques to improve the mixed signal integration performance of these circuits are in great demand. In this thesis, we present a custom designed energy efficient 2.4 GHz BFSK/ASK transmitter architecture using a low power frequency synthesizer design technique taking advantage of the CMOS technology scaling benefits. Furthermore, a few design guidelinesandsolutionstoimprovethespectralperformanceoffrequency synthesizer circuits and in-turn the performance of transmitters are also presented. The target application being short distance, low power, and battery operated wireless communication applications. The contributions in this thesis are, Spectral performance improvement techniques The CP mismatch current is a dominant source of reference spurs in the nano-meter CMOS PLL implementations due to its worsened channel length modulation effect [3]. In this work, we present a CP mismatch current calibration technique using an adaptive body bias tuning of its PMOS transistors. Chip prototype of 2.4 GHzCP-PLLwith the proposed CP calibration technique was fabricated in UMC 0.13 µm CMOS process. Measurements show a CP mismatch current of less than 0.3 µA(0.55 %) using the proposed calibration technique over the VCO control voltage range 0.3 to 1 V. The closed loop PLL measurements using the proposed technique exhibited a 9dB reduction in the reference spur levels across the PLL output frequency range 2.4 -2.5 GHz. The parasitic interactions between analog and digital circuits through the common substrate severely affects the performance of CP-PLLs. In this work, we experimentally demonstrate the effect of periodic switching noise generated from the digital buffers on the performance of charge-pump PLLs. The sensitivity of PLL performance metrics such as output spur level, phase noise, and output jitter are monitored against the variations in the properties of a noise injector digital signal. Measurements from a 500 MHz CP-PLL shows that the pulsed noise injection with the duty cycle of noise injector signal reduced from 50% to 20%, resulted in a 12.53 dB reduction in its output spur level and a 107 ps reduction in its Pk-Pk deterministic period jitter performance. Low power circuit techniques A low power frequency synthesizer design using a digital frequency multiplication technique is presented. The proposed frequency multiply by 3 digital edge combiner design having a very few logic gates, demonstrated a significant reduction in the power consumption of frequency synthesizer circuits, with an acceptable spectral performance suitable for these relaxed performance applications. A few design guidelines and techniques to further improve its spectral performance are also discussed and validated through simulations. Chip prototypes of 2.4 GHz CP-PLLs with and without digital frequency multiplier circuits are fabricated in UMC 0.13 µm CMOS process. The 2.4 GHz CP-PLL using the proposed digital frequency multiplication technique (10.7 mW) consumed a much reduced power compared to a conventional implementation(20.3 mW). A custom designed, energy efficient 2.4 GHz BFSK/ASK transmitter architecture using the proposed low power frequency synthesizer design technique is presented. The transmitter uses a class-D power amplifier to drive the 50Ω antenna load. Spur reduction techniques in frequency synthesizers are also used to improve the spectral performance of the transmitter. A chip prototype of the proposed transmitter architecture was implemented in UMC0.13 µm CMOS process. The transmitter consume14 mA current from a 1.3V supply voltage and achieve improved energy efficiencies of 0.91 nJ/bit and 6.1 nJ/bit for ASK and BFSK modulations with data rates 20Mb/s & 3Mb/s respectively. Transmitter Architecture Energy Efficient Wireless Transmitters Wireless Sensor Networks Phase-Locked Loop (PLL) Frequency Synthesizer Circuits Wireless Communication Charge Pump Phase-Locked Loop (CP-PLL) Analog Integrated Circuits Charge Pump Circuits Electronic Circuits Spur Suppression Technique Energy Efficient Transmitters Communication Engineering
58	Frekvenční syntezátor pro mikrovlnné komunikační systémy / Frequency synthesizer for microwave communication systems Klapil, Filip January 2020 (has links) The main aim of the thesis is to develop a solution of a frequency synthesizer for a microwave communication systems. Specifically, it suggests a design for frequency synthesizer with phase-locked loop. At beginning of the thesis the principle and basic properties of this method of signal generation are explained. Then it is followed by a brief discussion of the parameters of synthesizers and their influence on design. Another part of the work is the analysis of circuit the frequency synthesizer with the phase-locked loop MAX2871, which is followed by a proposal for the design of the frequency synthesizer module hardware. The last part of the work deals with practical implementation, verification of function and measurement of achieved parameters and their evaluation.

Search results