Caracteriza??o de circuitos planares de micro-ondas pelo m?todo iterativo das ondas

Silva Neto, Valdemir Praxedes da

26 July 2013

Made available in DSpace on 2014-12-17T14:56:15Z (GMT). No. of bitstreams: 1 ValdemirPSN_DISSERT.pdf: 1834625 bytes, checksum: 95e248e92979a128a6b21a87f73fdd48 (MD5) Previous issue date: 2013-07-26 / The planar circuits are structures that increasingly attracting the attention of researchers, due the good performance and capacity to integrate with other devices, in the prototyping of systems for transmitting and receiving signals in the microwave range. In this context, the study and development of new techniques for analysis of these devices have significantly contributed in the design of structures with excellent performance and high reliability. In this work, the full-wave method based on the concept of electromagnetic waves and the principle of reflection and transmission of waves at an interface, Wave Concept Iterative Procedure (WCIP), or iterative method of waves is described as a tool with high precision study microwave planar circuits. The proposed method is applied to the characterization of planar filters, microstrip antennas and frequency selective surfaces. Prototype devices were built and the experimental results confirmed the proposed mathematical model. The results were also compared with simulated results by Ansoft HFSS, observing a good agreement between them. / Os circuitos planares s?o estruturas que atraem cada vez mais a aten??o dos pesquisadores, pelo bom desempenho e pela capacidade de integra??o com outros dispositivos, na prototipagem de sistemas de transmiss?o e recep??o de sinais na faixa de micro-ondas. Neste contexto, o estudo e o desenvolvimento de novas t?cnicas de an?lise desses dispositivos t?m contribu?do de forma significativa na concep??o de estruturas com desempenhos excelentes e alto grau de confiabilidade. Neste trabalho, o m?todo de onda completa baseado no conceito de ondas eletromagn?ticas e no princ?pio da reflex?o e transmiss?o de ondas em uma interface, Wave Concept Iterative Procedure (WCIP), ou m?todo iterativo das ondas ? descrito como uma ferramenta com alto grau de precis?o no estudo de circuitos planares de micro-ondas. O m?todo proposto ? aplicado na caracteriza??o de filtros planares, antenas de microfita e superf?cies seletivas de frequ?ncia. Prot?tipos dos dispositivos foram constru?dos e os resultados experimentais comprovaram o modelo matem?tico proposto. Os resultados obtidos tamb?m foram comparados com os resultados simulados pelo Ansoft HFSS, tendo sido observada uma boa concord?ncia entre eles

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA

Design and Analysis of a Discrete, PCB-Level Low-Power, Microwave Cross-Coupled Differential Lc Voltage-Controlled Oscillator

Virdee, Pavin Singh

01 September 2022

Radio Frequency (RF) and Microwave devices are typically implemented in Integrated Circuit (IC) form to minimize parasitics, increase precision and tolerances, and minimize size. Although IC fabrication for students and independent engineers is cost-prohibitive, an abundance of low-cost, easily accessible printed circuit board (PCB) and electronic component manufacturers allows affordable PCB fabrication. While nearly all microwave voltage-controlled oscillator (VCO) designs are IC-based, this study presents a discrete PCB-level cross-coupled, differential LC VCO to demonstrate this more affordable and accessible approach. This thesis presents a 65 mW, discrete component VCO PCB with industry-comparable RF performance. A phase noise of -103.7 dBc/Hz is simulated at a 100 kHz offset from a 4.05 GHz carrier. This VCO achieves a 532 MHz (13.25%) tuning bandwidth. A figure of merit, FOMP, [1] value of -177.7 dB (includes phase noise and power consumption) is calculated at 4.05 GHz. This surpasses the performance of an industry standard VCO (HMC430LPx, Analog Devices), -176.5 dB, and four other commercially available VCOs. Furthermore, this study presents novel discrete design implementations to minimize both power consumption and capacitive loading effects, while optimizing phase noise. Finally, this project serves as a reference for analyzing and implementing low-level, complex RF and Microwave circuits on a PCB accessible to all students and independent engineers.

RF and Microwave Circuits

Voltage-Controlled Oscillator

Printed Circuit Board

Phase Noise

Low-Power

Differential Pair

Electrical and Computer Engineering

Electrical and Electronics

Electromagnetics and Photonics

Programmable and Tunable Circuits for Flexible RF Front Ends

Ahsan, Naveed

January 2008

Most of today’s microwave circuits are designed for specific function and specialneed. There is a growing trend to have flexible and reconfigurable circuits. Circuitsthat can be digitally programmed to achieve various functions based on specific needs. Realization of high frequency circuit blocks that can be dynamically reconfigured toachieve the desired performance seems to be challenging. However, with recentadvances in many areas of technology these demands can now be met. Two concepts have been investigated in this thesis. The initial part presents thefeasibility of a flexible and programmable circuit (PROMFA) that can be utilized formultifunctional systems operating at microwave frequencies. Design details andPROMFA implementation is presented. This concept is based on an array of genericcells, which consists of a matrix of analog building blocks that can be dynamicallyreconfigured. Either each matrix element can be programmed independently or severalelements can be programmed collectively to achieve a specific function. The PROMFA circuit can therefore realize more complex functions, such as filters oroscillators. Realization of a flexible RF circuit based on generic cells is a new concept.In order to validate the idea, a test chip has been fabricated in a 0.2μm GaAs process, ED02AH from OMMICTM. Simulated and measured results are presented along withsome key applications like implementation of a widely tunable band pass filter and anactive corporate feed network. The later part of the thesis covers the design and implementation of tunable andwideband highly linear LNAs that can be very useful for multistandard terminals suchas software defined radio (SDR). One of the key components in the design of a flexibleradio is low noise amplifier (LNA). Considering a multimode and multiband radiofront end, the LNA must provide adequate performance within a large frequency band.Optimization of LNA performance for a single frequency band is not suitable for thisapplication. There are two possible solutions for multiband and multimode radio frontends (a) Narrowband tunable LNAs (b) Wideband highly linear LNAs. A dual bandtunable LNA MMIC has been fabricated in 0.2μm GaAs process. A self tuningtechnique has also been proposed for the optimization of this LNA. This thesis alsopresents the design of a novel highly linear current mode LNA that can be used forwideband RF front ends for multistandard applications. Technology process for thiscircuit is 90nm CMOS.

Microwave circuits

phase shifters

programmable circuits

active corporate feed network

four-port circuit

generic cells

phase shift capability

programmable microwave function array

tunable recursive filter

Engineering and Technology

Teknik och teknologier

Abnormal Group Delay and Detection Latency in the Presence of Noise for Communication Systems

Kayili, Levent

06 April 2010

Although it has been well established that abnormal group delay is a real physical phenomenon and is not in violation of Einstein causality, there has been little investigation into whether or not such abnormal behaviour can be used to reduce signal latency in practical communication systems in the presence of noise. In this thesis, we use time-varying probability of error to determine if abnormal group delay “channels” can offer reduced signal latency. Since the detection system plays a critical role in the analysis, three important detection systems are considered: the correlation, matched filter and envelope detection systems. Our analysis shows that for both spatially negligible microelectronic systems and spatially extended microwave systems, negative group delay “channels” offer reduced signal latency as compared to conventional “channels”. The results presented in the thesis can be used to design a new generation of electronic and microwave interconnects with reduced or eliminated signal latency.

electrical engineering

Einstein causality

causality

communication systems

abnormal group delay

abnormal group velocity

superluminal group delay

superluminal group velocity

time-varying error probability

signal latency

detection system

detection latency

pulse advancement

spatially extended systems

negative group delay

negative group velocity

spatially negligible systems

microwave circuits

microelectronic interconnects

channel

relativistic causality

electromagnetic

dispersion

physics

signals

0544

Abnormal Group Delay and Detection Latency in the Presence of Noise for Communication Systems

Kayili, Levent

06 April 2010

Although it has been well established that abnormal group delay is a real physical phenomenon and is not in violation of Einstein causality, there has been little investigation into whether or not such abnormal behaviour can be used to reduce signal latency in practical communication systems in the presence of noise. In this thesis, we use time-varying probability of error to determine if abnormal group delay “channels” can offer reduced signal latency. Since the detection system plays a critical role in the analysis, three important detection systems are considered: the correlation, matched filter and envelope detection systems. Our analysis shows that for both spatially negligible microelectronic systems and spatially extended microwave systems, negative group delay “channels” offer reduced signal latency as compared to conventional “channels”. The results presented in the thesis can be used to design a new generation of electronic and microwave interconnects with reduced or eliminated signal latency.

electrical engineering

Einstein causality

causality

communication systems

abnormal group delay

abnormal group velocity

superluminal group delay

superluminal group velocity

time-varying error probability

signal latency

detection system

detection latency

pulse advancement

spatially extended systems

negative group delay

negative group velocity

spatially negligible systems

microwave circuits

microelectronic interconnects

channel

relativistic causality

electromagnetic

dispersion

physics

signals

0544