Técnicas de igualização adaptativas com estimativas imperfeitas do canal para os futuros sistemas 5G

Wireless communication networks have been continuously experiencing an exponential growth since their inception. The overwhelming demand for high data rates, support of a large number of users while mitigating disruptive interference are the constant research focus and it has led to the creation of new technologies and efficient techniques. Orthogonal frequency division multiplexing (OFDM) is the most common example of a technology that has come to the fore in this past decade as it provided a simple and generally ideal platform for wireless data transmission. It’s drawback of a rather high peak-to-average power ratio (PAPR) and sensitivity to phase noise, which in turn led to the adoption of alternative techniques, such as the single carrier systems with frequency domain equalization (SC-FDE) or the multi carrier systems with code division multiple access (MC-CDMA), but the nonlinear Frequency Domain Equalizers (FDE) have been of special note due to their improved performance. From these, the Iterative Block Decision Feedback Equalizer (IB-DFE) has proven itself especially promising due to its compatibility with space diversity, MIMO systems and CDMA schemes. However, the IB-DFE requires the system to have constant knowledge of the communication channel properties, that is, to have constantly perfect Channel State Information (CSI), which is both unrealistic and impractical to implement. In this dissertation we shall design an altered IB-DFE receiver that is able to properly detect signals from SC-FDMA based transmitters, even with constantly erroneous channel states. The results shall demonstrate that the proposed equalization scheme is robust to imperfect CSI (I-CSI) situations, since its performance is constantly close to the perfect CSI case, within just a few iterations.Redes sem fios têm crescido de maneira contínua e exponencial desde a sua incepção. A tremenda exigência para altas taxas de dados e o suporte para um elevado número de utilizadores sem aumentar a interferência disruptiva originada por estes são alguns dos focos que levaram ao desenvolvimento de técnicas de compensação e novas tecnologias. “Orthogonal frequency division multiplexing” (OFDM) é um dos exemplos de tecnologias que se destacaram nesta última década, visto ter fornecido uma plataforma para transmissão de dados sem-fio eficaz e simples. O seu maior problema é a alta “peak-to-average power ratio” (PAPR) e a sua sensibilidade a ruído de fase que deram motivo à adoção de técnicas alternativas, tais como os sistemas “single carrier” com “frequency domain equalization” (SC-FDE) ou os sistemas “multi-carrier” com “code division multiple access” (MC-CDMA), mas equalizadores não lineares no domínio de frequência têm sido alvo de especial atenção devido ao seu melhor desempenho. Destes, o “iterative block decision feedback equalizer” (IB-DFE) tem-se provado especialmente promissor devido à sua compatibilidade com técnicas de diversidade no espaço, sistemas MIMO e esquemas CDMA. No entanto, IB-DFE requer que o sistema tenha constante conhecimento das propriedades dos canais usados, ou seja, necessita de ter perfeito “channel state information” (CSI) constantemente, o que é tanto irrealista como impossível de implementar. Nesta dissertação iremos projetar um recetor IB-DFE alterado de forma a conseguir detetar sinais dum transmissor baseado em tecnologia SC-FDMA, mesmo com a informação de estado de canal errada. Os resultados irão então demonstrar que o novo esquema de equalização proposto é robusto para situações de CSI imperfeito (I-CSI), visto que o seu desempenho se mantém próximo dos valores esperados para CSI perfeito, em apenas algumas iterações.Mestrado em Engenharia Eletrónica e Telecomunicaçõe

Adaptive Feedforward Amplifier Design

Tez (Yüksek Lisans) -- İstanbul Teknik Üniversitesi, Fen Bilimleri Enstitüsü, 2005Thesis (M.Sc.) -- İstanbul Technical University, Institute of Science and Technology, 2005Bu çalışmada, özünde doğrusal olmayan bir güç kuvvetlendiricisi uyarlanır ileri besleme yöntemi kullanılarak doğrusal hale getirilmiştir. Temel ileri beslemeli bir kuvvetlendirici iki adet döngüye sahiptir ve iki adet kuvvetlendirici kullanır. Birinci döngünün çıkışında güç kuvvetlendiricisinin (asıl kuvvetlendirici) neden olduğu hata işareti (iç-modülasyon bozulması) elde edilir. İkinci döngüde ise elde edilen bu hata işareti kullanılarak kuvvetlendirici çıkışında oluşan bozulma işareti yok edilir ve böylece kuvvetlendirici doğrusallaştırılmış olur. İleri besleme duyarlılığı çok yüksek olan bir yöntemdir. Bu nedenle her iki döngüde de birer uyarlanır denetim devresi kullanmak gereklidir. Bu denetim devresi her iki döngüdeki alt ve üst yollar arasındaki genlik ve faz dengesini kontrol altında tutmak ve her zaman için dengede kalmasını sağlamak için kullanılır. Sayısal işaret işleme (DSP) tabanlı kontrol devresi en küçük karesel ortalama (LMS) algoritmasını kullanarak uyarlama katsayılarını hesaplamaktadır. Her iki döngüdeki genlik ve faz ayarı vektör modülatörleri kullanarak yapılmıştır. Sonuç olarak, 5.8GHz uyarlanır ileri beslemeli kuvvetlendiricinin benzetimi yapılmıştır ve benzetim sonucunda kuvvetlendiricinin iç-modülasyon performansının 25dB iyileştirildiği gözlenmiştir.In this study, an inherently nonlinear power amplifier is linearized by using feedforward technique. A fundamental feedforward amplifier has two loops and uses two amplifiers. Error signal (intermodulation distortion) caused by power amplifier (main amplifier) is obtained at the output of the first loop. In the second loop, distortion signal at the output of the amplifier is cancelled by using this obtained error signal and thus amplifier is linearized. Feedforward is a method, which has a very high sensitivity. Hence, it is necessary to use adaptive control circuit in each loop. This control circuit is used to check on amplitude and phase balances between upper and lower branches of both loops and to guarantee that these balances is always provided. Digital Signal Processing (DSP) based control circuit calculates adaptation coefficients by using Least Mean Square (LMS) algorithm. Gain and phase adjustment is done by using vector modulators in both loops. Consequently, a 5.8GHz adaptive feedforward amplifier is simulated and as a result of simulation, it is observed that intermodulation performance of amplifier is improved by 25dB.Yüksek LisansM.Sc

High Efficiency Power Supplies for Multi-mode RF Power Amplifiers in Cellular Handset Applications

Cellular handset evolution requires the front end transmitter to support multiple 3G/4G bands for global roaming, and also to be backward compatible with the existing 2G (quad-band GSM/EDGE) network. The cost and size would be prohibitive if one power amplifier (PA) only supports one band or if multiple supplies are required for multiple PAs. Solutions of interest are based on multi-standard multi-band PAs (e.g. 2 multi-mode PAs instead of 8+ mode-specific PAs), and an efficient power supply that supports these multi-mode PAs. The thesis starts with a study of PA supply architectures and DC-DC converters. A series architecture consisting of a boost converter followed by a buck converter has advantages of low-noise buck converter output, together with the ability to deliver full power at low battery voltages to extend the battery life. The buck converter presents a constant power load for the boost converter, which raises stability concerns. Small-signal control-to-output transfer functions are derived for peak or valley current mode controlled boost converter with a downstream regulated converter modeled as constant power load. It is shown how current mode control provides active damping to ensure stability and well-behaved dynamic response. Furthermore, it is shown how load current feedforward presents an effective way to improve power load transient response. Modeling and design approaches are validated by test circuit simulations, demonstrating stable operations using current mode control under constant power loads, and improved power step load transient response based on load current feedforward. A buck/boost and LDO series architecture is proposed as the solution to address efficiency, linearity, noise and time mask requirements for the supplies supporting multi-standard, multi-band PAs. A monolithic integrated circuit (IC) has been designed and implemented in a standard 0.5 5V CMOS process for supplying the multi-mode PAs. The buck/boost converter with wide output range delivers the peak efficiency of 92%. The power LDO has 1-4 MHz bandwidth, to support the GSM/EDGE/WCDMA time mask requirements and the polar EDGE operation. The test chip consumes the quiescent current 1.1 mA, and it delivers maximum 5 W output

Integrated Filters and Couplers for Next Generation Wireless Tranceivers

The main focus of this thesis is to investigate the critical nonlinear distortion issues affecting RF/Microwave components such as power amplifiers (PA) and develop new and improved solutions that will improve efficiency and linearity of next generation RF/Microwave mobile wireless communication systems. This research involves evaluating the nonlinear distortions in PA for different analog and digital signals which have been a major concern. The second harmonic injection technique is explored and used to effectively suppress nonlinear distortions. This method consists of simultaneously feeding back the second harmonics at the output of the power amplifier (PA) into the input of the PA. Simulated and measured results show improved linearity results. However, for increasing frequency bandwidth, the suppression abilities reduced which is a limitation for 4G LTE and 5G networks that require larger bandwidth (above 5 MHz). This thesis explores creative ways to deal with this major drawback. The injection technique was modified with the aid of a well-designed band-stop filter. The compact narrowband notch filter designed was able to suppress nonlinear distortions very effectively when used before the PA. The notch filter is also integrated in the injection technique for LTE carrier aggregation (CA) with multiple carriers and significant improvement in nonlinear distortion performance was observed. This thesis also considers maximizing efficiency alongside with improved linearity performance. To improve on the efficiency performance of the PA, the balanced PA configuration was investigated. However, another major challenge was that the couplers used in this configuration are very large in size at the desired operating frequency. In this thesis, this problem was solved by designing a compact branch line coupler. The novel coupler was simulated, fabricated and measured with performance comparable to its conventional equivalent and the coupler achieved substantial size reduction over others. The coupler is implemented in the balanced PA configuration giving improved input and output matching abilities. The proposed balanced PA is also implemented in 4G LTE and 5G wireless transmitters. This thesis provides simulation and measured results for all balanced PA cases with substantial efficiency and linearity improvements observed even for higher bandwidths (above 5 MHz). Additionally, the coupler is successfully integrated with rectifiers for improved energy harvesting performance and gave improved RF-dc conversion efficienc

Linealización de amplificadores por prealimentación para UMTS

This paper presents the most important concepts in a UMTS feedforward linearization system. The developed system meets the down link UMTS specifications, achieving a ACLRc<-45 dBc, a ACLRLL<-57 dBc, a EVM of 48% and a PCDE of –44 dB. The output power is +27.7 dBm for this application. An efficiency of nearly the 4.5 % has been obtained, being the total consumption of 13.3 W. The most problematic elements, as the error loop amplifier which must have a 1dB compression point 10 dB over the level of the generated signal, have been analyzed. This specification is due to the special characteristics of the UMTS signals as its variable envelope. Moreover, it can be seen that an imperfect cancellation is advisable to improve both output power and ACLR

Optical free space feedforward non-linearity correction system

Recent years have seen unprecedented growth in the popularity and deployment of mobile phones. As this continues, so the strain on existing mobile cellular radio network has also increased, leading to the need to investigate new technologies to relieve this pressure. The problem is being further exacerbated by the introduction of the 3rd generation of mobile communications, otherwise known as UMTS (Universal Mobile Telecommunications System), with the aim of offering multimedia services on pocket sized portable receivers. A major cost of the mobile radio network, in terms of both financial and social/environmental aspects, is the need apparent need for more base transceiver stations (BTS), due to the increased number of services, and the density of them. Therefore, judicious use of fewer, but more "intelligent" base stations, thereby reducing the overall system costs, and extra flexibility in the design of mobile cells would be desirable. This can be achieved by having the BTS antennas remotely positioned from the BTS by transmitting the radio signals down an optical fibre or, as in this project, over free space. The main application for this is in densely urban heavy use areas, where there is extensive reuse of both cell and cell cluster. This, along with building shadowing, would require a BTS on every corner, and where extra cell design flexibility would be desirable. Also, in remote rural areas, where various natural features, such as rivers or mountains can cause similar cell design problems, there is a need for this flexibility. The problem with this requirement is that the electrical to optical conversion process, involving a laser diode driver unit, is inherently non-linear, and, unless this is resolved, the desired signal will become unusable due to distortion. To overcome these nonlinearities, a novel correction may be used, based on an optical feedforward correction technique. The prototype system employs off-the-shelf components, and has one Fabry Perot laser diode (FP-LD) providing two signals (via a beam splitter), for a main path and one for the error path loop. The error path signal is detected by a receiver circuit, then mixed with a reference signal to produce a 'pure' error signal, which then modulates the second FP-LD. In contrast with previous fibre feedforward systems, where the two LD outputs are then combined in the optical fibre pre-reception, this system has to combine the signals post-reception. After the main signal and error signal are received and recombined, the non-linearities of the main path are predominantly cancelled by those present in the error path signal, leaving only the desired signal, free of non-linearities

Performance of an Echo Canceller and Channel Estimator for On-Channel Repeaters in DVB-T/H Networks

This paper investigates the design and performance of an FIR echo canceller for on-channel repeaters in DVB-T/H network within the framework of the PLUTO project. The possible approaches for echo cancellation are briefly reviewed and the main guidelines for the design of such systems are presented. The main system parameters are discussed. The performance of an FIR echo canceller based on an open loop feedforward approach for channel estimation is tested for different radio channel conditions and for different number of taps of the FIR filter. It is shown that a minimum number of taps is recommended to achieve a certain mean rejection ratio or isolation depending on the type of channel. The expected degradation in performance due to the use of fixed point rather than floating point arithmetic in hardware implementation is presented for different number of bits. Channel estimation based on training sequences is investigated. The performance of Maximum Length Sequences and Constant Amplitude Zero Autocorrelation (CAZAC) Sequences is compared for different channels. Recommendations are given for training sequence type, length and level for DVB-T/H on-channel repeater deployment