Space Time Processing for Third Generation CDMA Systems

Alam, Fakhrul

25 November 2002

The capacity of a cellular system is limited by two different phenomena, namely multipath fading and multiple access interference (MAI). A Two Dimensional (2-D) receiver combats both of these by processing the signal both in the spatial and temporal domain. An ideal 2-D receiver would perform joint space-time processing, but at the price of high computational complexity. In this dissertation we investigate computationally simpler technique termed as a Beamformer-Rake. In a Beamformer-Rake, the output of a beamformer is fed into a succeeding temporal processor to take advantage of both the beamformer and Rake receiver. Wireless service providers throughout the world are working to introduce the third generation (3G) cellular service that will provide higher data rates and better spectral efficiency. Wideband CDMA (WCDMA) has been widely accepted as one of the air interfaces for 3G. A Beamformer-Rake receiver can be an effective solution to provide the receivers enhanced capabilities needed to achieve the required performance of a WCDMA system. This dissertation investigates different Beamformer-Rake receiver structures suitable for the WCDMA system and compares their performance under different operating conditions. This work develops Beamformer-Rake receivers for WCDMA uplink that employ Eigen-Beamforming techniques based on the Maximum Signal to Noise Ratio (MSNR) and Maximum Signal to Interference and Noise Ratio (MSINR) criteria. Both the structures employ Maximal Ratio Combining (MRC) to exploit temporal diversity. MSNR based Eigen-Beamforming leads to a Simple Eigenvalue problem (SE). This work investigates several algorithms that can be employed to solve the SE and compare the algorithms in terms of their computational complexity and their performance. MSINR based Eigen-Beamforming results in a Generalized Eigenvalue problem (GE). The dissertation describes several techniques to form the GE and algorithms to solve it. We propose a new low-complexity algorithm, termed as the Adaptive Matrix Inversion (AMI), to solve the GE. We compare the performance of the AMI to other existing algorithms. Comparison between different techniques to form the GE is also compared. The MSINR based beamforming is demonstrated to be superior to the MSNR based beamforming in the presence of strong interference. There are Pilot Symbol Assisted (PSA) beamforming techniques that exploit the Minimum Mean Squared Error (MMSE) criterion. We compare the MSINR based Beamformer-Rake with the same that utilizes Direct Matrix Inversion (DMI) to perform MMSE based beamforming in terms of Bit Error Rate (BER). In a wireless system where the number of co-channel interferers is larger than the number of elements of a practical antenna array, we can not perform explicit null-steering. As a result the advantage of beamforming is partially lost. In this scenario it is better to attain diversity gain at the cost of spatial aliasing. We demonstrate this with the aid of simulation. Orthogonal Frequency Division Multiplexing (OFDM) is a multi-carrier technique that has recently received considerable attention for high speed wireless communication. OFDM has been accepted as the standard for Digital Audio Broadcast (DAB) and Digital Video Broadcast (DVB) in Europe. It has also been established as one of the modulation formats for the IEEE 802.11a wireless LAN standard. OFDM has emerged as one of the primary candidates for the Fourth Generation (4G) wireless communication systems and high speed ad hoc wireless networks. We propose a simple pilot symbol assisted frequency domain beamforming technique for OFDM receiver and demonstrate the concept of sub-band beamforming. Vector channel models measured with the MPRG Viper test-bed is also employed to investigate the performance of the beamforming scheme. / Ph. D.

Smart Antenna

Beamformer-Rake

Adaptive Antenna

Array Algorithm

OFDM

Space Time Processing

Beamforming

WCDMA

Combined Space-Time Diversity and Interference Cancellation for MIMO Wireless Systems

Tsai, Jiann-An

03 May 2002

There is increasing interest in the exploitation of multiple-input and multiple-output (MIMO) channels to enhance the capacity of wireless systems. In this study, we develop and evaluate a channel model, evaluate the corresponding channel capacity, and design and analyze a simple orthogonal transmit waveform for MIMO channels in mobile radio environments. We also evaluate the system performance of various interference cancellation techniques when employing multiple-receive antenna in interference-limited systems. The first part of this dissertation presents two major contributions to MIMO systems. The analytical expression for space-time MIMO channel correlation is derived for a Rayleigh fading channel. The information-theoretic channel capacity based on this correlation is also evaluated for a wide variety of mobile radio channels. The second part of this dissertation presents two major contributions to the area of orthogonal waveform design. We analyze the bit-error-rate (BER) performance of a proposed space-time orthogonal waveform for MIMO mobile radio communications. The application of the proposed space-time orthogonal waveform to a conventional cellular system is also evaluated and briefly discussed. Finally, this dissertation investigates a number of interference cancellation techniques for multiple-receive antenna systems. Both adaptive beamforming and multiuser detection are evaluated for various signal waveforms over a variety of mobile radio channels. / Ph. D.

Space-Time Diversity

Adaptive Antenna Arrays

Interference Cancellation

Wireless Communications

MIMO

Multi-layered Space Frequency Time Codes

Al-Ghadhban, Samir Naser

01 December 2005

This dissertation focuses on three major advances on multiple-input multiple-output (MIMO) systems. The first studies and compares decoding algorithms for multi-layered space time coded (MLSTC) systems. These are single user systems that combine spatial multiplexing and transmit diversity. Each layer consists of a space time code. The detection algorithms are based on multi-user detection theory. We consider joint, interference nulling and cancellation, and spatial sequence estimation algorithms. As part of joint detection algorithms, the sphere decoder is studied and its complexity is evaluated over MIMO channels. The second part contributes to the field of space frequency time (SFT) coding for MIMO-OFDM systems. It proposes a full spatial and frequency diversity codes at much lower number of trellis states. The third part proposes and compares uplink scheduling algorithms for multiuser systems with spatial multiplexing. Several scheduling criteria are examined and compared. The capacity and error rate study of MLSTBC reveals the performance of the detection algorithms and their advantage over other open loop MIMO schemes. The results show that the nulling and cancellation operations limit the diversity of the system to the first detected layer in serial algorithms. For parallel algorithms, the diversity of the system is dominated by the performance after parallel nulling. Theoretically, parallel cancellation should provide full receive diversity per layer but error propagations as a result of cancellation prevent the system from reaching this goal. However, parallel cancellation provides some gains but it doesn't increase the diversity. On the other hand, joint detection provides full receive diversity per layer. It could be practically implemented with sphere decoding which has a cubic complexity at high SNR. The results of the SFT coding show the superiority of the IQ-SFT codes over other codes at the same number of sates. The IQ-SFT codes achieve full spatial and frequency diversity at much lower number of trellis states compared to conventional codes. For V-BLAST scheduling, we propose V-BLAST capacity maximizing scheduler and we show that scheduling based on optimal MIMO capacity doesn't work well for V-BLAST. The results also show that maximum minimum singularvalue (MaxMinSV) scheduling performs very close to the V-BLAST capacity maximizing scheduler since it takes into account both the channel power and the orthogonality of the channel. / Ph. D.

Space frequency time codes

multi-layered space time codes

Uplink MIMO scheduling

MIMO Wireless Systems

Constructing Vision: László Moholy-Nagy's Partiturskizze zu einer mechanischen Exzentrik, Experiments in Higher Spatial Dimensions

La Coe, Jodi Lynn

01 May 2019

In 1936, while an expatriate in London, László Moholy-Nagy signed the Manifeste dimensioniste, crafted by Hungarian poet Charles Sirató, declaring his allegiance to the pursuit of creating artistic works in higher dimensions. In his artworks and writings, Moholy-Nagy was deeply invested in emerging technologies of the early twentieth century in the service of seeing the world differently, augmenting and training the sensory organs to visualize higher dimensions of space, essentially to see what does not appear, what is apparently invisible. Through his work with light and movement, which took many forms, painting, photography, film, kinetic sculpture, and theater, he worked through traditional and avant garde notions of space and time as related to psychophysical experience. Moholy-Nagy held that higher dimensions could be experienced through a re-education of human senses and began to lay out his claim for the education of the senses in order to see the world differently as early as 1922 in "Produktion–Reproduktion" (De Stijl). In Malerei, Fotografie, Film (Painting, Photography, Film, 1925), Moholy-Nagy asserted that through the visual objectivity produced photographs, especially in oblique photographs, "[w]e may say that we see the world with entirely different eyes." In this dissertation, I examine the influence of contemporary psychophysical, space-time theories on a stage/ performance design created by Moholy-Nagy, in particular, the two versions of his design for a synaesthetic theatrical performance entitled, Partiturskizze zu einer mechanischen Exzentrik (Score-Sketch for a Mechanical Eccentric): one a hybrid, mixed media drawing (c. 1923) and the other a revised version printed in Die Bühne im Bauhaus (The Stage of the Bauhaus, 1925). Following the structure of the hybrid drawing, each chapter is an interpretation of a single panel of the drawing, corresponding to the prelude and the five acts of the performance. This interpretation was made through a close reading of the drawing itself, examining the references made in the images and notations, comparing the two versions, and uncovering similar themes in his lectures, writings, and artistic works, and, in turn, pursuing references to physics, psychology, mathematics, and literature, whose profound influence was acknowledged by Moholy-Nagy in those texts. These influences include the writings of Albert Einstein, Hermann Minkowski, János Bolyai, Hermann von Helmholtz, Rudolf Carnap, Sigmund Freud, Wilhelm Wundt, E. T. A. Hoffmann, James Joyce, and many others. Through this analysis, I reveal the ambitious intention at the heart of the Exzentrik, to immerse the audience in a synaesthetic experience that expands their psychophysical consciousness using electromagnetic vibrations in the form of visible and invisible light and sound, as well as shocking and comedic forms and movements, and that, thereby, opens the audience to the construction of a new vision that endows them with the capacity to envision higher dimensions of space. / Doctor of Philosophy / In 1936, while living in London, László Moholy-Nagy signed the Dimensionist Manifesto, written by Hungarian poet Charles Sirató, declaring his allegiance to the pursuit of creating artistic works in higher dimensions, such as three-dimensional paintings or four-dimensional space-time constructions. In his artworks and writings, Moholy-Nagy was deeply invested in the emerging and advancing technologies of the early twentieth century in the service of seeing the world differently, augmenting and training the sensory organs to visualize higher dimensions of space, essentially to see what does not appear to the naked eye, for instance x-ray images reveal what is apparently invisible. Through his work with light and movement, which took many forms, painting, photography, film, moving sculptures, and theater, he explored how a person experiences space and time both physically and intellectually and Moholy-Nagy began to lay out his claim for the education of the senses in order to see the world differently. In Malerei, Fotografie, Film (Painting, Photography, Film, 1925), Moholy-Nagy asserted that through the visual objectivity produced photographs, especially in oblique photographs, “[w]e may say that we see the world with entirely different eyes.” In this dissertation, I have examined the influence of contemporary space-time theories on two versions of Moholy-Nagy’s design for a theatrical performance called the Score-Sketch for a Mechanical Eccentric, one a hand-drawn and painted collage (c. 1923) and the other a revised version printed in The Stage of the Bauhaus (1925). Following the structure of the former, each chapter is an interpretation of a single panel of the drawing/collage, corresponding to the prelude and the five acts of the performance. This interpretation was made through a close reading of the drawing itself, examining the references made in the images and notations, comparing the two versions, and uncovering similar themes in his lectures, writings, and artistic works, and, in turn, pursuing references to physics, psychology, mathematics, and literature, whose profound influence was acknowledged by Moholy-Nagy in those texts. These influences include the writings of Albert Einstein, Hermann Minkowski, János Bolyai, Hermann von Helmholtz, Rudolf Carnap, Sigmund Freud, Wilhelm Wundt, E. T. A. Hoffmann, James Joyce, and many others. Through this analysis, I will reveal the ambitious intention at the heart of the performance, to immerse the audience in a multi-sensory experience that will expand their consciousness, thereby, to expand their sensory perception, using shocking and comedic displays to psychologically open the audience to the possibility of perceiving higher dimensions of space.

apperception

dimensionism

perception

space-time

theater

Bauhaus

László Moholy-Nagy

eccentric

Analysis of Static and Dynamic Deformations of Laminated Composite Structures by the Least-Squares Method

Burns, Devin James

27 October 2021

Composite structures, such as laminated beams, plates and shells, are widely used in the automotive, aerospace and marine industries due to their superior specific strength and tailor-able mechanical properties. Because of their use in a wide range of applications, and their commonplace in the engineering design community, the need to accurately predict their behavior to external stimuli is crucial. We consider in this thesis the application of the least-squares finite element method (LSFEM) to problems of static deformations of laminated and sandwich plates and transient plane stress deformations of sandwich beams. Models are derived to express the governing equations of linear elasticity in terms of layer-wise continuous variables for composite plates and beams, which allow inter-laminar continuity conditions at layer interfaces to be satisfied. When Legendre-Gauss-Lobatto (LGL) basis functions with the LGL nodes taken as integration points are used to approximate the unknown field variables, the methodology yields a system of discrete equations with a symmetric positive definite coefficient matrix. The main goal of this research is to determine the efficacy of the LSFEM in accurately predicting stresses in laminated composites when subjected to both quasi-static and transient surface tractions. Convergence of the numerical algorithms with respect to the LGL basis functions in space and time (when applicable) is also considered and explored. In the transient analysis of sandwich beams, we study the sensitivity of the first failure load to the beam's aspect ratio (AR), facesheet-core thickness ratio (FCTR) and facesheet-core stiffness ratio (FCSR). We then explore how failure of sandwich beams is affected by considering facesheet and core materials with different in-plane and transverse stiffness ratios. Computed results are compared to available analytical solutions, published results and those found by using the commercial FE software ABAQUS where appropriate / Master of Science / Composite materials are formed by combining two or more materials on a macroscopic scale such that they have better engineering properties than either material individually. They are usually in the form of a laminate comprised of numerous plies with each ply having unidirectional fibers. Laminates are used in all sorts of engineering applications, ranging from boat hulls, racing car bodies and storage tanks. Unlike their homogeneous material counterparts, such as metals, laminated composites present structural designers and analysts a number of computational challenges. Chief among these challenges is the satisfaction of the so-called continuity conditions, which require certain quantities to be continuous at the interfaces of the composite's layers. In this thesis, we use a mathematical model, called a state-space model, that allows us to simultaneously solve for these quantities in the composite structure's domain and satisfy the continuity conditions at layer interfaces. To solve the governing equations that are derived from this model, we use a numerical technique called the least-squares method which seeks to minimize the squares of the governing equations and the associated side condition residuals over the computational domain. With this mathematical model and numerical method, we investigate static and dynamic deformations of laminated composites structures. The goal of this thesis is to determine the efficacy of the proposed methodology in predicting stresses in laminated composite structures when subjected to static and transient mechanical loading.

Composites

least-squares finite element method

linear elasticity

space-time coupled

Application of Machine Learning to Multi Antenna Transmission and Machine Type Resource Allocation

Emenonye, Don-Roberts Ugochukwu

11 September 2020

Wireless communication systems is a well-researched area in electrical engineering that has continually evolved over the past decades. This constant evolution and development have led to well-formulated theoretical baselines in terms of reliability and efficiency. However, most communication baselines are derived by splitting the baseband communications into a series of modular blocks like modulation, coding, channel estimation, and orthogonal frequency modulation. Subsequently, these blocks are independently optimized. Although this has led to a very efficient and reliable process, a theoretical verification of the optimality of this design process is not feasible due to the complexities of each individual block. In this work, we propose two modifications to these conventional wireless systems. First, with the goal of designing better space-time block codes for improved reliability, we propose to redesign the transmit and receive blocks of the physical layer. We replace a portion of the transmit chain - from modulation to antenna mapping with a neural network. Similarly, the receiver/decoder is also replaced with a neural network. In other words, the first part of this work focuses on jointly optimizing the transmit and receive blocks to produce a set of space-time codes that are resilient to Rayleigh fading channels. We compare our results to the conventional orthogonal space-time block codes for multiple antenna configurations. The second part of this work investigates the possibility of designing a distributed multiagent reinforcement learning-based multi-access algorithm for machine type communication. This work recognizes that cellular networks are being proposed as a solution for the connectivity of machine type devices (MTDs) and one of the most crucial aspects of scheduling in cellular connectivity is the random access procedure. The random access process is used by conventional cellular users to receive an allocation for the uplink transmissions. This process usually requires six resource blocks. It is efficient for cellular users to perform this process because transmission of cellular data usually requires more than six resource blocks. Hence, it is relatively efficient to perform the random access process in order to establish a connection. Moreover, as long as cellular users maintain synchronization, they do not have to undertake the random access process every time they have data to transmit. They can maintain a connection with the base station through discontinuous reception. On the other hand, the random access process is unsuitable for MTDs because MTDs usually have small-sized packets. Hence, performing the random access process to transmit such small-sized packets is highly inefficient. Also, most MTDs are power constrained, thus they turn off when they have no data to transmit. This means that they lose their connection and can't maintain any form of discontinuous reception. Hence, they perform the random process each time they have data to transmit. Due to these observations, explicit scheduling is undesirable for MTC. To overcome these challenges, we propose bypassing the entire scheduling process by using a grant free resource allocation scheme. In this scheme, MTDs pseudo-randomly transmit their data in random access slots. Note that this results in the possibility of a large number of collisions during the random access slots. To alleviate the resulting congestion, we exploit a heterogeneous network and investigate the optimal MTD-BS association which minimizes the long term congestion experienced in the overall cellular network. Our results show that we can derive the optimal MTD-BS association when the number of MTDs is less than the total number of random access slots. / Master of Science / Wireless communication systems is a well researched area of engineering that has continually evolved over the past decades. This constant evolution and development has led to well formulated theoretical baselines in terms of reliability and efficiency. This two part thesis investigates the possibility of improving these wireless systems with machine learning. First, with the goal of designing more resilient codes for transmission, we propose to redesign the transmit and receive blocks of the physical layer. We focus on jointly optimizing the transmit and receive blocks to produce a set of transmit codes that are resilient to channel impairments. We compare our results to the current conventional codes for various transmit and receive antenna configuration. The second part of this work investigates the possibility of designing a distributed multi-access scheme for machine type devices. In this scheme, MTDs pseudo-randomly transmit their data by randomly selecting time slots. This results in the possibility of a large number of collisions occurring in the duration of these slots. To alleviate the resulting congestion, we employ a heterogeneous network and investigate the optimal MTD-BS association which minimizes the long term congestion experienced in the overall network. Our results show that we can derive the optimal MTD-BS algorithm when the number of MTDs is less than the total number of slots.

Machine Type Communication

Space Time Block Coding

Deep learning (Machine learning)

Reinforcement Learning

VT-STAR design and implementation of a test bed for differential space-time block coding and MIMO channel measurements

Chembil Palat, Ramesh

18 November 2002

Next generation wireless communications require transmission of reliable high data rate services. Second generation wireless communications systems use single-input multiple-output (SIMO) channel in the reverse link, meaning one transmit antenna at the user terminal and multiple receive antennas at the base station. Recently, information theoretic research has shown an enormous potential growth in the capacity of wireless systems by using multiple antenna arrays at both ends of the link. Space-time coding exploits the spatial-temporal diversity provided by the multiple input multiple output (MIMO) channels, significantly increasing both system capacity and the reliability of the wireless link. The Virginia Tech Space-Time Advanced Radio (VT-STAR) system presents a test bed to demonstrate the capabilities of space-time coding techniques in real-time. Core algorithms are implemented on Texas Instruments TMS320C67 Evaluation Modules (EVM). The radio frequency subsystem is composed of multi-channel transmitter and receiver chains implemented in hardware for over the air transmission. The capabilities of the MIMO channel are demonstrated in a non-line of sight (NLOS) indoor environment. Also to characterize the capacity gains in an indoor environment this test bed was modified to take channel measurements. This thesis reports the system design of VT-STAR and the channel capacity gains observed in an indoor environment for MIMO channels. / Master of Science

MIMO (Multiple input multiple output )

Efficient continuous synthesis of high purity deep eutectic solvents by twin screw extrusion

Crawford, Deborah E., Wright, L.A., James, S.L., Abbott, A.P.

13 February 2020

No / Mechanochemical synthesis has been applied to the rapid synthesis of Deep Eutectic Solvents (DESs), including Reline 200 (choline chloride : urea, 1 : 2), in a continuous flow methodology by Twin Screw Extrusion (TSE). This gave products in higher purity and with Space Time Yields (STYs), four orders of magnitude greater than for batch methods

Mechanochemical synthesis

Deep Eutectic Solvents (DESs)

Twin Screw Extrusion (TSE)

Space Time Yields (STYs)

Simulation performance of multiple-input multiple-output systems employing single-carrier modulation and orthogonal frequency division multiplexing

Saglam, Halil Derya

12 1900

Approved for public release, distribution is unlimited / This thesis investigates the simulation performance of multiple-input multiple-output (MIMO) systems utilizing Alamoutibased space-time block coding (STBC) technique. The MIMO communication systems using STBC technique employing both single- carrier modulation and orthogonal frequency division multiplexing (OFDM) are simulated in Matlab. The physical layer part of the IEEE 802.16a standard is used in constructing the simulated OFDM schemes. Stanford University Interim (SUI) channel models are selected for the wireless channel in the simulation process. The performance results of the simulated MIMO systems are compared to those of conventional single antenna systems. / Lieutenant Junior Grade, Turkish Navy

MIMO systems

Space time codes

Multiplexing

Multiple-input Multiple-output (MIMO)

Space-time block coding (STBC)

Stanford University Interim (SUI) models

Spatially correlated MIMO channels

Spatial diversity

Alamouti scheme

Maximal ratio combining

A Filterbank Precoding Framework For MIMO Frequency Selective Channels

Vijaya, Krishna, A

08 1900

Wireless systems with multiple antennas at both the transmitter and receiver (MIMO systems) have been the focus of research in the recent past due to their ability to provide higher data rates and better reliability than their single antenna counterparts. Designing a communication system for MIMO frequency selective channels provides many signal processing challenges. Popular methods like MIMOOFDM and space-time precoding linearly process blocks of data at both the transmitter and the receiver. Independence between the blocks is ensured by introducing sufficient redundancy between successive blocks. This approach has many pitfalls, including the limit on achievable data rate due to redundancy requirements and the need for additional coding/processing. In this thesis, we provide a filterbank precoding framework (FBP) for communication over MIMO frequency selective channels. By viewing the channel as a polynomial matrix, we derive the minimum redundancy required for achieving FIR equalization of the precoded channel. It is shown that, for most practical channels, a nominal redundancy is enough. The results are general, and hold for channels of any dimension and order. We derive the zero-forcing and MMSE equalizers for the precoded channel. The role of equalizer delay in system performance is analyzed. We extend the minimum redundancy result to the case of space-time filterbank precoding (STFP). Introducing the time dimension allows the channel to be represented by a block pseudocirculant matrix. By using the Smith form of block pseudocirculant matrices, we show that very high data rates can be achieved with STFP. When channel information is available at the transmitter, we derive an iterative algorithm for obtaining the MMSE optimal precoder-equalizer pair. We then provide a comparison of FBP with the block processing methods. It is shown that FBP provides better BER performance than the block processing methods at a lower computational cost. The reasons for the better performance of FBP are discussed.

Telecommunication Channels

MIMO Frequency Channels

Filterbank Precoding

Space-time Filterbank Precoding (STFP)

MMSE Precoding

FIR Equalization

Filterbank Precoder

Optimal Space-time Precoding (STP-OP)

Communication Engineering