A fully integrated multiband frequency synthesizer for WLAN and WiMAX applications

This paper presents a fractional N frequency synthesizer which covers WLAN and WiMAX frequencies on a single chip. The synthesizer is fully integrated in 0.35μm BiCMOS AMS technology except crystal oscillator. The synthesizer operates at four frequency bands (3.101-3.352GHz, 3.379-3.727GHz, 3.7-4.2GHz, 4.5-5.321GHz) to provide the specifications of 802.16 and 802.11 a/b/g/y. A single on-chip LC - Gm based VCO is implemented as the core of this synthesizer. Different frequency bands are selected via capacitance switching and fine tuning is done using varactor for each of these bands. A bandgap reference circuit is implemented inside of this charge pump block to generate temperature and power supply independent reference currents. Simulated settling time is around 10μsec. Total power consumption is measured to be 118.6mW without pad driving output buffers from a 3.3V supply. The phase noise of the oscillator is lower than -116.4dbc/Hz for all bands. The circuit occupies 2.784 mm2 on Si substrate, including DC, Digital and RF pads

Design of a 3 GHz fine resolution LC DCO

In this thesis, the design of a fine resolution LC digitally controlled oscillator (DCO) is introduced. Two NMOS varactor banks are used to achieve 12 bits medium and fine frequency tuning. Both delta-sigma modulator and capacitive divider circuit are implemented to achieve a finer resolution and a larger dynamic range. The LC-oscillator has a coarse tuning range from 3.05 GHz to 3.85 GHz and a fine tuning range of 50MHz. It features a phase noise level of -115dBc/Hz at 1MHz frequency offset and consumes 5.4mW. Efficient simulation methodology is explored. Finally, this DCO is simulated in an All-Digital Phase Locked Loop (ADPLL) with other ideal behavior blocks implemented using Verilog-A, and the performance of the DCO is evaluated.Electrical and Computer Engineerin

A CCO-based Sigma-Delta ADC

Analog-to-digital converter (ADC) is one of the most important blocks in nowadays systems. Most of the data processing is done in the digital domain however, the physical world is analog. ADCs make the bridge between analog and digital domain. The constant and unstoppable evolution of the technology makes the dimensions of the transistors smaller and smaller, and the classical solutions of Sigma-Delta converters (ΣΔ) are becoming more challenging to design because they normally require high active gain blocks difficult to achieve in modern technologies. In recent years, the use of voltage-controlled oscillators (VCO) in ΣΔ converters has been widely explored, since they are used as quantizers and their implementations are mostly made with digital blocks, which is preferable with new technologies. In this work a second-order ΣΔ modulator based on two current-controlled oscillators (CCO) with a single output phase and an independent phase generator for each CCO that generates any desired number of phases using the oscillation of its CCO as reference has been proposed. This ΣΔ modulator was studied through a MATLAB/Simulink® model, obtaining promising results with the SNDR in the order of 75 dB, at a sampling frequency of 1 GHz, and a bandwidth of 5 MHz, corresponding to an ENOB of, approximately, 12 bits

Process and Temperature Compensated Wideband Injection Locked Frequency Dividers and their Application to Low-Power 2.4-GHz Frequency Synthesizers

There has been a dramatic increase in wireless awareness among the user community in the past five years. The 2.4-GHz Industrial, Scientific and Medical (ISM) band is being used for a diverse range of applications due to the following reasons. It is the only unlicensed band approved worldwide and it offers more bandwidth and supports higher data rates compared to the 915-MHz ISM band. The power consumption of devices utilizing the 2.4-GHz band is much lower compared to the 5.2-GHz ISM band. Protocols like Bluetooth and Zigbee that utilize the 2.4-GHz ISM band are becoming extremely popular. Bluetooth is an economic wireless solution for short range connectivity between PC, cell phones, PDAs, Laptops etc. The Zigbee protocol is a wireless technology that was developed as an open global standard to address the unique needs of low-cost, lowpower, wireless sensor networks. Wireless sensor networks are becoming ubiquitous, especially after the recent terrorist activities. Sensors are employed in strategic locations for real-time environmental monitoring, where they collect and transmit data frequently to a nearby terminal. The devices operating in this band are usually compact and battery powered. To enhance battery life and avoid the cumbersome task of battery replacement, the devices used should consume extremely low power. Also, to meet the growing demands cost and sized has to be kept low which mandates fully monolithic implementation using low cost process. CMOS process is extremely attractive for such applications because of its low cost and the possibility to integrate baseband and high frequency circuits on the same chip. A fully integrated solution is attractive for low power consumption as it avoids the need for power hungry drivers for driving off-chip components. The transceiver is often the most power hungry block in a wireless communication system. The frequency divider (prescaler) and the voltage controlled oscillator in the transmitter’s frequency synthesizer are among the major sources of power consumption. There have been a number of publications in the past few decades on low-power high-performance VCOs. Therefore this work focuses on prescalers. A class of analog frequency dividers called as Injection-Locked Frequency Dividers (ILFD) was introduced in the recent past as low power frequency division. ILFDs can consume an order of magnitude lower power when compared to conventional flip-flop based dividers. However the range of operation frequency also knows as the locking range is limited. ILFDs can be classified as LC based and Ring based. Though LC based are insensitive to process and temperature variation, they cannot be used for the 2.4-GHz ISM band because of the large size of on-chip inductors at these frequencies. This causes a lot of valuable chip area to be wasted. Ring based ILFDs are compact and provide a low power solution but are extremely sensitive to process and temperature variations. Process and temperature variation can cause ring based ILFD to loose lock in the desired operating band. The goal of this work is to make the ring based ILFDs useful for practical applications. Techniques to extend the locking range of the ILFDs are discussed. A novel and simple compensation technique is devised to compensate the ILFD and keep the locking range tight with process and temperature variations. The proposed ILFD is used in a 2.4-GHz frequency synthesizer that is optimized for fractional-N synthesis. Measurement results supporting the theory are provided

An Energy-Efficient Reconfigurable Mobile Memory Interface for Computing Systems

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

Digital controlled oscillator (DCO) for all digital phase-locked loop (ADPLL) – a review

Digital controlled oscillator (DCO) is becoming an attractive replacement over the voltage control oscillator (VCO) with the advances of digital intensive research on all-digital phase locked-loop (ADPLL) in complementary metal-oxide semiconductor (CMOS) process technology. This paper presents a review of various CMOS DCO schemes implemented in ADPLL and relationship between the DCO parameters with ADPLL performance. The DCO architecture evaluated through its power consumption, speed, chip area, frequency range, supply voltage, portability and resolution. It can be concluded that even though there are various schemes of DCO that have been implemented for ADPLL, the selection of the DCO is frequently based on the ADPLL applications and the complexity of the scheme. The demand for the low power dissipation and high resolution DCO in CMOS technology shall remain a challenging and active area of research for years to come. Thus, this review shall work as a guideline for the researchers who wish to work on all digital PLL

A Noise-Shifting Differential Colpitts VCO

A novel noise-shifting differential Colpitts VCO is presented. It uses current switching to lower phase noise by cyclostationary noise alignment and improve the start-up condition. A design strategy is also devised to enhance the phase noise performance of quadrature coupled oscillators. Two integrated VCOs are presented as design examples

12???14.5 GHZ DIGITALLY CONTROLLED OSCILLATOR USING A HIGH-RESOLUTION DELTA-SIGMA DIGITAL-TO-ANALOG CONVERTER

Department of Electrical EngineeringThis thesis focuses on the design of digitally-controlled oscillators (DCO) for ultra-low-jitter digital phase-locked-loops (PLL), which requires very fine frequency resolution and low phase noise performance. Before going details of the design, fundamentals of the digital-to-analog converter (DAC), delta-sigma modulator (DSM), LC voltage-controlled oscillator (VCO) are discussed in Chapters 2, 3, and 4 respectively. Detailly, Chapter 2 begins with the basic operations of the digital-toanalog converters. Plus, several types of DACs and their properties are discussed. For instance, resistorbased DAC or current source-based DAC. In Chapter 3, the backgrounds of DSMs are presented. The reason why DSMs are indispensable components in fractional number generation is presented. The meaning of the randomization and noise shaping in DSMs is discussed then high-order noise shaping DSMs are explained as well. Chapter 4, starts with the LC tanks. Integrated passive components are introduced such as spiral inductors, metal-insulator-metal (MIM) capacitors, and metal-oxide-metal (MOM) capacitors. The start-up of the oscillators also explained by using two approaches, the Barkhausen criterion and the negative resistance theory. Then the pros and cons of the CMOS and NMOS type topologies are stated. Finally, the phase noise in oscillators is analyzed by using the Leeson???s equation and the impulse-sensitivity function theory. In chapter 5, the detailed designs of the prototype DCO are presented. The designed DCO consists of 2nd order DSM, string resistor-based DAC, and CMOS-type LC VCO. The frequency resolutions of the proportional and integral path are different but the structures are identical. For the high-performance oscillator, iterative design is required. In the measurements, the designed DCO achieved 17 and 18 bit of frequency resolution in the proportional and integral path respectively, 12-14.5GHz of the frequency tuning range, 50 and 500MHz/V of KVCO for the main and auxiliary loop respectively, and -184.5 dB of figure of merit (FOM). The power consumption is 5.5mW and the prototype was fabricated in TSMC 65nm CMOS process.clos