458 research outputs found
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Enhancing MB-OFDM throughput with dual circular 32-QAM
Quadrature Phase Shift Keying (QPSK) and Dual Carrier Modulation (DCM) are currently used as the modulation schemes for Multiband Orthogonal Frequency Division Multiplexing (MB-OFDM) in the ECMA-368 defined Ultra-Wideband (UWB) radio platform. ECMA-368 has been chosen as the physical radio platform for many systems including Wireless USB (W-USB), Bluetooth 3.0 and Wireless HDMI; hence ECMA-368 is an important issue to consumer electronics and the users experience of these products.
To enable the transport of high-rate USB, ECMA-368 offers up to 480 Mb/s instantaneous bit rate to the Medium Access Control (MAC) layer, but depending on radio channel conditions dropped packets unfortunately result in a lower throughput. This paper presents an alternative high data rate modulation scheme that fits within the configuration of the current standard increasing system throughput by achieving 600 Mb/s (reliable to 3.1 meters) thus maintaining the high rate USB throughput even with a moderate level of dropped packets. The modulation system is termed Dual Circular 32-QAM (DC 32-QAM). The system performance for DC 32-QAM modulation is presented and compared with 16-QAM and DCM1
Adaptive multi-carrier spread-spectrum with dynamic time-frequency codes for UWB applications
International audienceIn this paper, we propose a spread spectrum multi-carrier multiple-access (SS-MC-MA) waveform for high data rate UWB applications, taking into consideration the European UWB context. This new UWB scheme respects the parameters of the multiband orthogonal frequency division multiplexing (MB-OFDM) technique which is one of the candidates for wireless personal area networks (WPAN) standardization. We optimize the spreading code length and the number of codes in our proposed scheme in order to maximize the system range for a given target throughput. Furthermore, we dynamically distribute the time-frequency codes that provide frequency hopping between users in order to improve our system range. We show that our adaptive system transmits information at much higher attenuation levels and with larger throughput than the ones of the MB-OFDM proposal. Hence, we conclude that our proposed system can be advantageously exploited for UWB applications
Adaptive multi-carrier spread-spectrum with dynamic time-frequency codes for UWB applications
International audienceIn this paper, we propose a spread spectrum multi-carrier multiple-access (SS-MC-MA) waveform for high data rate UWB applications, taking into consideration the European UWB context. This new UWB scheme respects the parameters of the multiband orthogonal frequency division multiplexing (MB-OFDM) technique which is one of the candidates for wireless personal area networks (WPAN) standardization. We optimize the spreading code length and the number of codes in our proposed scheme in order to maximize the system range for a given target throughput. Furthermore, we dynamically distribute the time-frequency codes that provide frequency hopping between users in order to improve our system range. We show that our adaptive system transmits information at much higher attenuation levels and with larger throughput than the ones of the MB-OFDM proposal. Hence, we conclude that our proposed system can be advantageously exploited for UWB applications
Resource allocation for multicarrier CDMA systems in ultra-wideband communications
International audienceUltra-wideband (UWB) is a fast emerging technology that has attracted considerable interest in short range, high data rate wireless personal area networks (WPAN) applications. One of the main candidates for WPAN standardization is the multiband orthogonal frequency division multiplexing (MB-OFDM), supported by the Multiband OFDM Alliance (MBOA). In this paper, we propose a new low-complexity resource allocation algorithm applied to a spread spectrum multicarrier multiple-access (SS-MC-MA) waveform, which is new for high data rate UWB applications. The proposed scheme aims at maximizing the system's throughput while taking into consideration the WPAN environment and respecting the OFDM parameters of the MBOA solution. The adaptive allocation algorithm applied to OFDM and SS-MC-MA leads to roughly double the throughput compared to the MBOA solution at low attenuation levels. Furthermore, at high attenuation levels, SS-MC-MA outperforms the adaptive OFDM. Hence, we conclude that the proposed adaptive SS-MC-MA can especially be advantageously exploited for high attenuation UWB applications
Cross-layer Resource Allocation Scheme for Multi-band High Rate UWB Systems
In this paper, we investigate the use of a cross-layer allocation mechanism
for the high-rate ultra-wideband (UWB) systems. The aim of this paper is
twofold. First, through the cross-layer approach that provides a new service
differentiation approach to the fully distributed UWB systems, we support
traffic with quality of service (QoS) guarantee in a multi-user context.
Second, we exploit the effective SINR method that represents the
characteristics of multiple sub-carrier SINRs in the multi-band WiMedia
solution proposed for UWB systems, in order to provide the channel state
information needed for the multi-user sub-band allocation. This new approach
improves the system performance and optimizes the spectrum utilization with a
low cost data exchange between the different users while guaranteeing the
required QoS. In addition, this new approach solves the problem of the
cohabitation of more than three users in the same WiMedia channel
A Review of UWB MAC Protocols
In this paper, we review several ultra-wideband
(UWB) medium access control (MAC) protocols that have been
proposed to date. This review then considers the possibility of
developing an optimal MAC layer for high data rate UWB
transmission systems that transmit very little power especially
in application to mobile devices. MAC in UWB wireless
networks is necessary to coordinate channel access among
competing devices. Unique UWB characteristics offer great
challenges and opportunities in effective UWB MAC design.
We first present the background of UWB and the concept of MAC protocols for UWB. Secondly, we summarize four UWB MAC protocols that have been proposed by other researchers
and finally, a conclusion with a view to the planned future
work. The main contribution of this paper is that it presents a summarised version of several MAC protocols applicable to UWB systems. This will hopefully initiate further research and developments in UWB MAC protocol design
Spectrum control and iterative coding for high capacity multiband OFDM
The emergence of Multiband Orthogonal Frequency Division Modulation (MB-OFDM) as an ultra-wideband (UWB) technology injected new optimism in the market through realistic commercial implementation, while keeping promise of high data rates intact. However, it has also brought with it host of issues, some of which are addressed in this thesis.
The thesis primarily focuses on the two issues of spectrum control and user capacity for the system currently proposed by the Multiband OFDM Alliance (MBOA). By showing that line spectra are still an issue for new modulation scheme (MB-OFDM), it proposes a mechanism of scrambling the data with an increased length linear feedback shift register (compared to the current proposal), a new set of seeds, and random phase reversion for the removal of line spectra. Following this, the thesis considers a technique for increasing the user capacity of the current MB-OFDM system to meet the needs of future wireless systems, through an adaptive multiuser synchronous coded transmission scheme. This involves real time iterative generation of user codes, which are generated over time and frequency leading to increased capacity. With the assumption of complete channel state information (CSI) at the receiver, an iterative MMSE algorithm is used which involves replacement of each users s signature with its normalized MMSE filter function allowing the overall Total Squared Correlation (TSC) of the system to decrease until the algorithm converges to a fixed set of signature vectors. This allows the system to be overloaded and user\u27s codes to be quasi-orthogonal. Simulation results show that for code of length nine (spread over three frequency bands and three time slots), ten users can be accommodated for a given QoS and with addition of single frequency sub-band which allows the code length to increase from nine to twelve (four frequency sub-bands and three time slots), fourteen users with nearly same QoS can be accommodated in the system. This communication is overlooked by a central controller with necessary functionalities to facilitate the process. The thesis essentially considers the uplink from transmitting devices to this central controller. Furthermore, analysis of this coded transmission in presence of interference is carried to display the robustness of this scheme through its adaptation by incorporating knowledge of existing Narrowband (NB) Interference for computing the codes. This allows operation of sub-band coexisting with NB interference without substantial degradation given reasonable interference energy (SIR=-l0dB and -5dB considered). Finally, the thesis looks at design implementation and convergence issues related to code vector generation whereby, use of Lanczos algorithm is considered for simpler design and faster convergence. The algorithm can be either used to simplify design implementation by providing simplified solution to Weiner Hopf equation (without requiring inverse of correlation matrix) over Krylov subspace or can be used to expedite convergence by updating the signature sequence with eigenvector corresponding to the least eigenvalue of the signature correlation matrix through reduced rank eigen subspace search
Spectrum Sharing for Massive Access in Ultra-Narrowband IoT Systems
Ultra-narrowband (UNB) communications has become a signature feature for many
emerging low-power wide-area (LPWA) networks. Specifically, using extremely
narrowband signals helps the network connect more Internet-of-things (IoT)
devices within a given band. It also improves robustness to interference,
extending the coverage of the network. In this paper, we study the coexistence
capability of UNB networks and their scalability to enable massive access. To
this end, we develop a stochastic geometry framework to analyze and model UNB
networks on a large scale. The framework captures the unique characteristics of
UNB communications, including the asynchronous time-frequency access, signal
repetition, and the absence of base station (BS) association. Closed-form
expressions of the transmission success probability and network connection
density are presented for several UNB protocols. We further discuss multiband
access for UNB networks, proposing a low-complexity protocol. Our analysis
reveals several insights on the geographical diversity achieved when devices do
not connect to a single BS, the optimal number of signal repetitions, and how
to utilize multiple bands without increasing the complexity of BSs. Simulation
results are provided to validate the analysis, and they show that UNB
communications enables a single BS to connect thousands of devices even when
the spectrum is shared with other networks.Comment: This paper is accepted for publication in the IEEE Journal on
Selected Areas in Communications. arXiv admin note: text overlap with
arXiv:1811.1109
Finding the Optimal MAC Protocol for Low-Power High Data Rate Ultra-Wideband (UWB) Networks
In this paper, we explore the possibility of designing an optimal medium access control (MAC) layer for high data rate ultra-wideband (UWB) transmission systems that transmit very little power especially in mobile devices. MAC in UWB wireless networks is necessary to coordinate channel access among competing devices. The unique UWB characteristics offer great challenges and opportunities in effective UWB MAC design. We first study the background of UWB and available MAC protocols that have been used in UWB. Secondly, we analyse the power consumption for UWB in mobile devices based on competing short-range wireless technologies such as Bluetooth and Wi-Fi as references. Finally we present the key issue that will be considered in the design of an optimal MAC layer that will fully exploit UWB potential as a low-power, high data rate, short range wireless transmission system
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