261 research outputs found
Hardware implementation of multiple-input multiple-output transceiver for wireless communication
This dissertation proposes an efficient hardware implementation scheme for iterative multi-input multi-output orthogonal frequency-division multiplexing (MIMO-OFDM) transceiver. The transmitter incorporates linear precoder designed with instantaneous channel state information (CSI). The receiver implements MMSE-IC (minimum mean square error interference cancelation) detector, channel estimator, low-density parity-check (LDPC) decoder and other supporting modules. The proposed implementation uses QR decomposition (QRD) of complex-valued matrices with four co-ordinate rotation digital computer (CORDIC) cores and back substitution to achieve the best tradeoff between resource and throughput. The MIMO system is used in field test and the results indicate that the instantaneous CSI varies very fast in practices and the performance of linear precoder designed with instantaneous CSI is limited. Instead, statistic CSI had to be used.
This dissertation also proposes a higher-rank principle Kronecker model (PKM). That exploits the statistic CSI to simulate the fading channels. The PKM is constructed by decomposing the channel correlation matrices with the higher-order singular value decomposition (HOSVD) method. The proposed PKM-HOSVD model is validated by extensive field experiments conducted for 4-by-4 MIMO systems in both indoor and outdoor environments. The results confirm that the statistic CSI varies slowly and the PKM-HOSVD will be helpful in the design of linear precoders. --Abstract, page iv
Large-Scale MIMO Detection for 3GPP LTE: Algorithms and FPGA Implementations
Large-scale (or massive) multiple-input multiple-output (MIMO) is expected to
be one of the key technologies in next-generation multi-user cellular systems,
based on the upcoming 3GPP LTE Release 12 standard, for example. In this work,
we propose - to the best of our knowledge - the first VLSI design enabling
high-throughput data detection in single-carrier frequency-division multiple
access (SC-FDMA)-based large-scale MIMO systems. We propose a new approximate
matrix inversion algorithm relying on a Neumann series expansion, which
substantially reduces the complexity of linear data detection. We analyze the
associated error, and we compare its performance and complexity to those of an
exact linear detector. We present corresponding VLSI architectures, which
perform exact and approximate soft-output detection for large-scale MIMO
systems with various antenna/user configurations. Reference implementation
results for a Xilinx Virtex-7 XC7VX980T FPGA show that our designs are able to
achieve more than 600 Mb/s for a 128 antenna, 8 user 3GPP LTE-based large-scale
MIMO system. We finally provide a performance/complexity trade-off comparison
using the presented FPGA designs, which reveals that the detector circuit of
choice is determined by the ratio between BS antennas and users, as well as the
desired error-rate performance.Comment: To appear in the IEEE Journal of Selected Topics in Signal Processin
Hardware co-processor to enable MIMO in next generation wireless networks
One prevailing technology in wireless communication is Multiple Input, Multiple Output (MIMO) communication. MIMO communication simultaneously transmits several data streams, each from their own antenna within the same frequency channel. This technique can increase data bandwidth by up to a factor of the number of transmitting antennas, but comes with the cost of a much higher computational complexity for the wireless receiver. MIMO communication exploits differing channel effects caused by physical distances between antennas to differentiate between transmitting antennas, an intrinsically two dimensional operation. Current Digital Signal Processors (DSPs), on the other hand, are designed to perform computations on one dimensional vectors of incoming data. To compensate for the lack of native support of these higher dimensional operations, current base stations are forced to add multiple new processing elements while many mobile devices cannot support MIMO communication. In order to allow wireless clients and stations to have native support of the two dimensional operations required by MIMO communication, a hardware co-processor was designed to allow the DSP to offload these operations onto another processor to reduce computation time
An adaptive detector implementation for MIMO-OFDM downlink
Cognitive radio (CR) systems require flexible and adaptive implementations of signal processing algorithms. An adaptive symbol detector is needed in the baseband receiver chain to achieve the desired flexibility of a CR system. This paper presents a novel design of an adaptive detector as an application-specific instruction-set processor (ASIP). The ASIP template is based on transport triggered architecture (TTA). The processor architecture is designed in such a manner that it can be programmed to support different suboptimal multiple-input multiple-output (MIMO) detection algorithms in a single TTA processor. The linear minimum mean-square error (LMMSE) and three variants of the selective spanning for fast enumeration (SSFE) detection algorithms are considered. The detection algorithm can be switched between the LMMSE and SSFE according to the bit error rate (BER) performance requirement in the TTA processor. The design can be scaled for different antenna configurations and different modulations. Some of the algorithm architecture co-optimization techniques used here are also presented. Unlike most other detector ASIPs, high level language is used to program the processor to meet the time-to-market requirements. The adaptive detector delivers 4.88 - 49.48 Mbps throughput at a clock frequency of 200 MHz on 90 nm technology
FPGA Prototyping of A High Data Rate LTE Uplink Baseband Receiver
The Third Generation Partnership Project (3GPP) Long Term Evolution (LTE) standard is becoming the appropriate choice to pave the way for the next generation wireless and cellular standards. While the popular OFDM technique
has been adopted and implemented in previous standards and also in the LTE downlink, it suffers from high peak-to-average-power ratio (PAPR). High PAPR requires more sophisticated power amplifiers (PAs) in the handsets and would result in lower efficiency PAs. In order to combat such effects, the LTE uplink
choice of transmission is the novel Single Carrier Frequency Division Multiple Access (SC-FDMA) scheme which has lower PAPR due to its inherent signal structure. While reducing the PAPR, the SC-FDMA requires a more complicated detector structure in the base station for multi-antenna and multi-user
scenarios. Since the multi-antenna and multi-user scenarios are critical parts of the LTE standard to deliver high performance and data rate, it is important to design novel architectures to ensure high reliability and data rate in the receiver. In this paper, we propose a flexible architecture of a high data rate LTE uplink receiver with multiple receive antennas and implemented a single
FPGA prototype of this architecture. The architecture is verified
on the WARPLab (a software defined radio platform based on Rice Wireless Open-access Research Platform) and tested in the real over-the-air indoor channel.NokiaNokia Siemens Networks (NSN)XilinxAzimuth SystemsNational Science Foundatio
Complexity Analysis of MMSE Detector Architectures for MIMO OFDM Systems
In this paper, a field programmable gate array (FPGA) implementation of a linear minimum mean square error (LMMSE) detector is considered for MIMO-OFDM systems. Two square root free algorithms based on QR decomposition (QRD) are introduced for the implementation of LMMSE detector. Both algorithms are based on QRD via Givens rotations, namely coordinate rotation digital computer (CORDIC) and squared
Givens rotation (SGR) algorithms. Linear and triangular shaped array architectures are considered to exploit the parallelism in the computations. An FPGA hardware implementation is presented and computational complexity of each implementation is evaluated and compared.ElekrobitNokiaTexas InstrumentsNational Technology Agency of FinlandTeke
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