High Tolerance of Charge Pump Leakage Current in Integer-N PLL Frequency Synthesizer for 5G Networks

One of the most promising solutions for the future fifth generation communication systems is to utilize millimeter wave (mm-W) radio frequencies. There is, however, little works about Phase Locked Loop (PLL) frequency synthesizer designed for mm-W band frequency for 5G applications. This article discusses integer PLL architecture for frequency synthesis; it targets the highest range of 5G mmW [81-86] GHz using ultra-wide channel spacing of 1GHz. This work investigates the design of a third passive loop filter for frequency synthesizer using a Phase Frequency Detector and a current switch Charge Pump such as analog devices ADF4155. The critical performance for the Charge Pump depends on the leakage current produced by the technology of its transistors. This undesirable current can have a high impact on the loop stability. However, by optimizing PLL filter parameters, the synthesizer was able to tolerate up to 117 nA. With such a high leakage current, a high performance of the system was achieved. As a result, less than −71 dBc reference spur level at 50 MHz offset frequency was ensured and 3.23 µs settling time for a hopping frequency of 5 GHz was achieved

Energy-efficient modulation and physical layer design for low terahertz band communication channel in 5G femtocell Internet of Things

© 2018 Elsevier B.V. High throughput capability of the terahertz band (0.3–10 THz) wireless communications is expected to be utilized by the fifth generation of mobile telecommunication systems and enable a plethora of new applications. Supporting devices will transfer large amounts of data in both directions, causing high energy consumption by the electronic circuitries of the equipment in use. Therefore, physical layer for these systems must be designed carefully in order to reduce energy consumption per bit. In this paper, the best performing modulation scheme and hardware parameters that minimize the energy consumption without affecting the system throughput are determined. THz band device technologies are outlined and a complete survey of the state-of-the-art low-THz band circuit blocks which are suitable for mass market production is given. It is shown that for short-range communications, M-ary quadrature amplitude modulation is the most energy-efficient technique that can lead up to 90% reduction in consumed energy. Moreover, optimal transceiver parameters which can be used to further minimize the energy consumption of the THz band system are examined

Recent Trends in Communication Networks

In recent years there has been many developments in communication technology. This has greatly enhanced the computing power of small handheld resource-constrained mobile devices. Different generations of communication technology have evolved. This had led to new research for communication of large volumes of data in different transmission media and the design of different communication protocols. Another direction of research concerns the secure and error-free communication between the sender and receiver despite the risk of the presence of an eavesdropper. For the communication requirement of a huge amount of multimedia streaming data, a lot of research has been carried out in the design of proper overlay networks. The book addresses new research techniques that have evolved to handle these challenges

8-12 GHz pHEMT MMIC Low-Noise Amplifier for 5G and Fiber-Integrated Satellite Applications

The fifth-generation (5G) radio access technology promises to revolutionise integrated earth-space communications applications for ubiquitous, seamless and broadband services. The assigned sub-6 GHz and millimetre-wave 5G frequencies require the sensitivity of the receiver front-end subsystem(s) to detect and amplify the desired signal at a noise floor of less than -90 dBm for a cost-effective infrastructure deployment. This paper presents a broadband monolithic microwave integrated circuit (MMIC) low-noise amplifier (LNA) design based on a 0.15 µm gate length Indium Gallium Arsenide (InGaAs) pseudomorphic high electron mobility transistor (pHEMT) technology for 5G and fiber-integrated satellite communications applications. The designed three-stage 8-12 GHz LNA implements a common-source topology. The MMIC LNA subsystem performance demonstrates an industry-leading in-band gain response of 40 dB; a noise figure of 1.0 dB; and a power dissipation of 43 mW. For a constant bandwidth receiver, the sensitivity changes by approximately 1.5 dB over the operating satellite signal frequency. Similarly, for a variable bandwidth receiver, the sensitivity changes by approximately 1.5 dB over the channel bandwidth. Moreover, the sensitivity margin of the designed LNA is 40 dB and this holds a great promise for real-time radio access component-level reconfiguration applications

Digitally Controlled Oscillator for mm-Wave Frequencies

In the fifth generation of mobile communication, 5G, frequencies above 30 GHz, so-called millimeter-wave (mm-wave) frequencies are expected to play a prominent role. For the synthesis of these frequencies, the all-digital phase locked loop (ADPLL) has recently gained much attention. A core component of the ADPLL is the digitally controlled oscillator (DCO), an oscillator that tunes the frequency discretely. For good performance, the frequency steps must be made very small, while the total tuning range must be large. This thesis covers several coarse- and fine-tuning techniques for DCOs operating at mm-wave frequencies. Three previously not published fine-tuning schemes are presented: The first one tunes the second harmonic, which will, due to the Groszkowski effect, tune the fundamental tone. The second one is a current-modulation scheme, which utilizes the weak current-dependence of the capacitance of a transistor to tune the frequency. In the third one, a digital-to-analog converter (DAC) is connected to the bulk of the differential pair and tunes the frequency by setting the bulk voltage. The advantages and disadvantages of the presented tuning schemes are discussed and compared with previously reported fine-tuning schemes. Two oscillators were implemented at 86 GHz. Both oscillator use the same oscillator core and hence have the same power consumption and tuning range, 14.1 mW and 13.9%. A phase noise of -89.7 dBc/Hz and -111.4 dBc/Hz at 1 MHz and 10 MHz offset, respectively, were achieved, corresponding to a Figure-of-Merit of -178.5 dBc/Hz. The first oscillator is fine-tuned using a combination of a transformer-based fine-tuning and the current modulation scheme presented here. The achieved frequency resolution is 55 kHz, but can easily be made finer. The second oscillator utilizes the bulk bias technique to achieve its fine tuning. The fine-tuning resolution is here dependent on the resolution of the DAC; a 100μV resolution corresponds to a resolution of 50 kHz.n 2011, the global monthly mobile data usage was 0.5 exabytes, or 500 million gigabytes. In 2016, this number had increased to 7 exabytes, an increase by a factor 14 in just five years, and there are no signs of this trend slowing down. To meet the demands of the ever increasing data usage, engineers have begun to investigate the possibility to use significantly higher frequencies, 30 GHz or higher, for mobile communication than what is used today, which is 3 GHz or below. To be able to transmit and receive data at these high frequency, an oscillator capable of operating at these frequencies are required. An oscillator is an electrical circuit that generates an alternating current (a current that first goes one way, and then the other) at a specific frequency. Below is an example to illustrate to function and importance of the oscillator: Imagine driving a car and listening to the radio. Suddenly, a horrendous song starts playing from the radio, so you instantly tune to another station and find some great, smooth jazz. Satisfied, you lean back and drive on. But what exactly happened when you "tuned to another station"? What you really did was changing the frequency of the oscillator, which can be found in the radio receiver of the car. The radio receiver filters out all frequencies, except for the frequency of the local oscillator. So by setting the frequency of the local oscillator to the frequency of the desired radio channel, only this radio channel will reach the speakers of the car. Thus, the oscillator must be able to vary its frequency to any frequency that a radio station can transmit on. While an old car radio may seem like a simple example, the very same principle is used in mobile communication, even at frequencies above 30 GHz. The oscillator is also used in the same way when transmitting signals, so that the signals are transmitted on the correct frequency. The design of the local oscillator is a hot topic among radio engineers. A poorly designed oscillator will ruin the performance of the whole receiver or transmitter. This thesis covers the design of a special type of oscillators, called digital controlled oscillators or DCO, operating at 30 GHz or higher. The frequency of these oscillators are determined by a digital word (ones and zeros), instead of using an analog voltage, which is traditionally used. Digital control results in greater flexibility and higher noise-resilience, but it also means that the frequency can’t be changed continuously, but rather in discrete steps. This discrete behavior will cause noise in the receiver. To minimize this noise, the frequency steps should be minimized. In this thesis, we have proposed a DCO design, operating at 85.5 GHz, which can be tuned almost 7 % in either direction. To our knowledge, no other DCO operates at such high frequencies. In the proposed oscillators the frequency steps are only 55 kHz apart, which is so small that its effect on the radio receiver can, with a good conscience, be ignored. This is achieved with a novel technique that makes tiny, tiny changes in the current that passes through the oscillator

Advanced CMOS Integrated Circuit Design and Application

The recent development of various application systems and platforms, such as 5G, B5G, 6G, and IoT, is based on the advancement of CMOS integrated circuit (IC) technology that enables them to implement high-performance chipsets. In addition to development in the traditional fields of analog and digital integrated circuits, the development of CMOS IC design and application in high-power and high-frequency operations, which was previously thought to be possible only with compound semiconductor technology, is a core technology that drives rapid industrial development. This book aims to highlight advances in all aspects of CMOS integrated circuit design and applications without discriminating between different operating frequencies, output powers, and the analog/digital domains. Specific topics in the book include: Next-generation CMOS circuit design and application; CMOS RF/microwave/millimeter-wave/terahertz-wave integrated circuits and systems; CMOS integrated circuits specially used for wireless or wired systems and applications such as converters, sensors, interfaces, frequency synthesizers/generators/rectifiers, and so on; Algorithm and signal-processing methods to improve the performance of CMOS circuits and systems

A low power, low noise, 1.8 GHz voltage-controlled oscillator

Thesis (M.S.)--Massachusetts Institute of Technology, Dept. of Electrical Engineering and Computer Science, 1997.Includes bibliographical references (leaf 97).by Donald A. Hitko.M.S

Integrated RF oscillators and LO signal generation circuits

This thesis deals with fully integrated LC oscillators and local oscillator (LO) signal generation circuits. In communication systems a good-quality LO signal for up- and down-conversion in transmitters is needed. The LO signal needs to span the required frequency range and have good frequency stability and low phase noise. Furthermore, most modern systems require accurate quadrature (IQ) LO signals. This thesis tackles these challenges by presenting a detailed study of LC oscillators, monolithic elements for good-quality LC resonators, and circuits for IQ-signal generation and for frequency conversion, as well as many experimental circuits. Monolithic coils and variable capacitors are essential, and this thesis deals with good structures of these devices and their proper modeling. As experimental test devices, over forty monolithic inductors and thirty varactors have been implemented, measured and modeled. Actively synthesized reactive elements were studied as replacements for these passive devices. At first glance these circuits show promising characteristics, but closer noise and nonlinearity analysis reveals that these circuits suffer from high noise levels and a small dynamic range. Nine circuit implementations with various actively synthesized variable capacitors were done. Quadrature signal generation can be performed with three different methods, and these are analyzed in the thesis. Frequency conversion circuits are used for alleviating coupling problems or to expand the number of frequency bands covered. The thesis includes an analysis of single-sideband mixing, frequency dividers, and frequency multipliers, which are used to perform the four basic arithmetical operations for the frequency tone. Two design cases are presented. The first one is a single-sideband mixing method for the generation of WiMedia UWB LO-signals, and the second one is a frequency conversion unit for a digital period synthesizer. The last part of the thesis presents five research projects. In the first one a temperature-compensated GaAs MESFET VCO was developed. The second one deals with circuit and device development for an experimental-level BiCMOS process. A cable-modem RF tuner IC using a SiGe process was developed in the third project, and a CMOS flip-chip VCO module in the fourth one. Finally, two frequency synthesizers for UWB radios are presented