用于MB-OFDM UWB系统的FFT/IFFT处理器的设计与实现

设计了一种应用于超宽带(UWB)无线通信系统中的FFT/IFFT处理器。该处理器采用基24算法进行FFT运算,利用8路并入并出的流水线结构实现该算法,提高了处理器的数据吞吐率,降低了芯片功耗。提出了一种新颖的数据处理方式,在保证信噪比的情况下节约了逻辑资源。在乘法器的设计环节,针对UWB系统的具体特点,在结构上对乘法器进行了改进和优化,提高了乘法器的性能。最后,设计的FFT/IFFT处理器采用TSMC 0.18μm CMOS标准工艺库综合,芯片的内核面积为0.762mm2(不含测试电路)。在1.8V,25℃条件下,最大工作时钟317.199MHz,在UWB典型的工作频率下,内核功耗为33.5304mW。     

一个符合IEEE 802.11a标准的新颖FFT/IFFT处理器设计

本文提出了一种新颖的FFT/IFFT处理器结构,并用可编程逻辑器件(CPLD)实现了该结构.这种新型结构有效地结合了传统流水线结构和循环结构的优点,并恰当地满足了802.11a 协议要求的速率,达到了实现面积远小于其它结构的目的.在本文中,用CPLD分别实现了这种新型结构和传统流水线结构,仿真结果证明所提出的新型结构在占用面积上具有较大的优越性.     

An Area Efficient FFT/IFFT Processor for MIMO-OFDM WLAN 802.11n

A pipelined Fast Fourier Transform and its inverse (FFT/IFFT) processor, which utilizes hardware resources efficiently, is proposed for MIMO-OFDM WLAN 802.11n. Compared with a conventional MIMO-OFDM implementation, (in which as many FFT/IFFT processors as the number of transmit/receive antennas is used), the proposed architecture (using hardware sharing among multiple data sequences) reduces hardware complexity without sacrificing system throughput. Further, the proposed architecture can support 1–4 input data sequences with sequence lengths of 64 or 128, as needed. The FFT/IFFT processor is synthesized using TSMC 0.18 um CMOS technology and saves 25% area compared to a conventional implementation approach using radix-2³ algorithm. The proposed FFT/IFFT processor can be configured to improve power efficiency according to the number of input data sequences and the sequence length. The processor consumes 38 mW at 75 MHz for one input sequence with 64-point length; it consumes 87 mW at 75 MHz for four input sequences with length 128-point and can be efficiently used for IEEE 802.11n WLAN standard.

65nm CMOS工艺单收单发IEEE802.11AC芯片的MAC控制器的设计实现

本文提出一种兼容IEEE80211AC SISO的无线局域网SOC芯片,芯片集成模拟前端、数字基带处理、媒体访问控制处理器模块,采用SMIC 65nm 1P6M CMOS工艺实现,测试结果表明,在正常工作条件下能提供较高的吞吐率、灵活的速率选择以及良好的兼容性,在标准IEEE802.11AC SISO模式下,测试所得UDP吞吐率为267M b/s。     

基于IEEE 802.11ac的多用户MIMO传输方案的优化设计及其性能分析

在IEEE 802.11ac Draft 2.0标准草案的基础上,针对其新引入的多用户MIMO传输机制进行了深入研究,提出了几点改进的优化设计方案,并完成了相应的性能分析。最后对IEEE 802.11ac的多用户MIMO传输方案进行了系统的性能分析,仿真结果表明,改进的传输方案在误比特率(BER)和吞吐量方面获得了明显的性能增益,且与针对性能的理论分析与仿真结果相吻合。     

基于802.11a的FFT/IFFT处理器设计

设计了一种应用于802.11a的64点FFT/IFFT处理器.采用单蝶形4路并行结构,提出了4路并行无冲突地址产生方法,有效地提高了吞吐率,完成64点FFT/IFFT运算只需63个时钟周期.提出的RAM双乒乓结构实现了对输入和输出均为连续数据流的缓存处理.不仅能实现64点FFT和IFFT,而且位宽可以根据系统任意配置.为了提高数据运算的精度,设计采用了块浮点算法,实现了精度与资源的折中.16位位宽时,在HJTC 0.18μmCMOS工艺下综合,内核面积为:0.626 7 mm2,芯片面积为:1.35 mm×1.27 mm,最高工作频率可达300 MHz,功耗为126.17 mW.     

基于802.11a的OFDM系统基带处理器的FPGA实现

探讨基于802．11a的OFDM系统的硬件构架，给出了适应于OFDM系统的并行存储的高速FFT处理器电路结构，以及实现导频插入、循环前缀的硬件结构。经FPCA验证，在系统时钟频率为20MHz时，64点FFT计算时间为2．55us。     

Enhanced high‐performance distributed coordination function for IEEE 802.11 multi‐rate LANs

To compensate for the effects of fading in wireless channels, IEEE 802.11 systems utilize a rate‐adaptation mechanism to accomplish a multi‐rate capability. However, the IEEE 802.11 distributed coordination function results in a fundamental performance anomaly in multi‐rate networks; namely, when stations with different transmission rates collide, the throughput performance of the high‐rate station is significantly degraded by the relatively longer channel occupancy time of the low‐rate station. This study resolves this problem through the use of an enhanced high‐performance distributed coordination function (EHDCF) protocol. While most existing solutions to the multi‐rate performance anomaly problem have the form of simple contention‐based protocols, EHDCF has two modes, namely a contending mode and an active mode. In the proposed protocol, new stations joining the network are assigned a contending mode, but switch to an active node (and are therefore permitted to transmit data packets) as soon as they have gained access to the channel. Having transmitted a data packet, the active node then selects the next transmission station in accordance with a probability‐based rule designed such that the high‐rate stations within the network receive a greater number of transmission opportunities than the low‐rate stations. The simulation results show that the EHDCF protocol not only yields a significant improvement in the network throughput but also guarantees the temporal fairness of all the stations. Copyright © 2009 John Wiley & Sons, Ltd.     

下一代WLAN技术标准802.11ac/ad

基于IEEE802.11n标准的WLAN能够支持高达600 Mbit/s的传输速率,但在支持无线高清视频传输等高吞吐量无线数据业务时仍然会遇到瓶颈。面对这一挑战I,EEE已启动下一代WLAN技术标准802.11ac和802.11ad的制定工作,数据吞吐量将达到几个Gbit/s,能够更好地满足快速增长的市场需求。     

应用于超宽带系统中的低功耗、高速FFT/IFFT处理器设计

设计了一种应用于超宽带(UWB)无线通信系统中的FFT/IFFT处理器.采用8×8×2混合基算法进行FFT运算,实现了2路64点或者1路128点FFT功能,并为该算法提出了一种新型的8路并行反馈结构.该结构提高了处理器的数据吞吐率,降低了芯片功耗.为了减少处理器中的乘法数目,提高时序性能,提出了改进型移位加算法.设计的FFT/IFFT处理器采用SMIC 0.13μm CMOS工艺制造,芯片的核心面积为1.44mm2.测试结果表明,该芯片最高数据吞吐率到达1Gsample/s,在典型的工作频率500Msample/s下,芯片功耗为39.6mW.与现有同类型FFT芯片相比,该芯片面积缩小了40%,功耗减少了45%.     

Saturation throughput analysis of multi‐rate IEEE 802.11 wireless networks

IEEE 802.11 protocol supports adaptive rate mechanism, which selects the transmission rate according to the condition of the wireless channel, to enhance the system performance. Thus, research of multi‐rate IEEE 802.11 medium access control (MAC) performance has become one of the hot research topics. In this paper, we study the performance of multi‐rate IEEE 802.11 MAC over a Gaussian channel. An accurate analytical model is presented to compute the system saturation throughput. We validate our model in both single‐rate and multi‐rate networks through various simulations. The results show that our model is accurate and channel error has a significant impact on system performance. In addition, our numerical results show that the performance of single‐rate IEEE 802.11 DCF with basic access method is better than that with RTS/CTS mechanism in a high‐rate and high‐load network and vice versa. In a multi‐rate network, the performance of IEEE 802.11 DCF with RTS/CTS mechanism is better than that with basic access method in a congested and error‐prone wireless environment. Copyright © 2008 John Wiley & Sons, Ltd.     

Enhanced uplink multi‐users scheduling for future 802.11ax networks: wait‐to‐pick‐as‐available enhanced

One of the key enablers of the upcoming IEEE 802.11ax standard is the inclusion of uplink multi‐users (UL MU) transmission model, which is performed using multiple‐input multiple‐output (MIMO) and beamforming techniques. So far, UL MU‐MIMO has not been standardized in any of IEEE 802.11 amendments, because of technical issues facing its definition. One of these significant issues is the scheduling of UL MU‐MIMO transmissions, which refers to selection rules and resource allocation procedures performed before simultaneous data transmissions. Indeed, simultaneous transmitters and receiver should exchange some information to correctly transmit the parallel data frames. However, this information exchange adds overheads, leading to reduce network performance. In this regard, we have proposed, in a previous work, a novel 802.11ax medium access control protocol aiming at reducing elapsed time in managing the establishment of an UL ‐MU communication called Wait‐to‐Pick‐As‐Available (W2PAA). Our contribution in this paper is twofold. First, we introduce an analytical model based on semi‐Markov Chains to evaluate the performance of W2PAA; taking into a detailed behavior of the backoff counter (i.e. freezing period). Second, we propose an enhanced version of W2PAA aiming at improving both system and user‐oriented performances. Aiming at validating the analytical model and comparing the performance of both versions of W2PAA, we used computer simulation. Obtained results, validate the analytical model in one hand, and clearly indicated the gain of both W2PAA versions by report to the basic UL‐Single User on the other hand. Copyright © 2016 John Wiley & Sons, Ltd.     

A novel self‐adaptive transmission scheme over an IEEE 802.11 WLAN for supporting multi‐service

The IEEE 802.11 wireless local area network (WLAN) media access control (MAC) specification is a hybrid protocol of random access and polling when both distributed coordination function (DCF) and point coordination function (PCF) are used. Data traffic is transmitted with the DCF, while voice transmission is carried out with the PCF. Based on the performance analysis of the MAC protocol for integrated data and voice transmission by simulation, this paper puts forward a self‐adaptive transmission scheme to support multi‐service over the IEEE 802.11 WLAN. The simulation results show that, on the premise of satisfying the maximum allowable delay of packet voice, the self‐adaptive transmission scheme can improve the data traffic performance and increase the WLAN capacity through dynamic and appropriate adjustment of the protocol parameters. Especially, voice traffic is sensitive to delay jitter, and the self‐adaptive scheme can effectively decrease it. Finally, it is worth noting that the adaptive scheme is easy to be realized, whereas no change in the MAC protocol is needed. Copyright © 2006 John Wiley & Sons, Ltd.     

The design and implementation of the IEEE 802.11 MAC based on soft-core processor and RTOS

The implementation method of the IEEE 802.11 Medium Access Control （MAC） protocol is mainly based on DSP （Digital Signal Processor）/ARM （Advanced Reduced instruction set computer Machine） processor or DSP/ARM IP （Intellectual Property） core. This paper presents a method based on Nios II soft-core processor embedded in Altera＇s Cyclone FPGA （Field Programmable Gate Array） and MicroC/OS-II RTOS （Real-Time Operation System）. The benefits and drawbacks of above methods are compared, and then the method presented in this paper is described. The hardware and software partitioning are discussed; the hardware architecture is also illustrated and the MAC software programming is described in detail. The presented method has some advantages, such as low cost, easy-implementation and very suitable for the implementation of IEEE 802.11 MAC in research stage.     

A compact microstrip fed dual polarised multiband antenna for IEEE 802.11 a/b/g/n/ac/ax applications

A compact microstrip fed dual polarised multiband monopole antenna for IEEE 802.11 a/b/g/n/ac/ax communication based applications is presented. The antenna is circularly polarised in IEEE 802.11 b/g bands while linearly polarised in IEEE 802.11 a/n/ac/ax bands. The asymmetric U-shaped slot in the ground plane of proposed antenna is used to introduce the necessary 90° phase shift between two orthogonal electric field vectors necessary for circular polarisation. The Ω-shaped slot on patch is used to introduce a band elimination notch between the usable frequency bands. The radiation characteristics of the proposed antenna (at 2.4 GHz) can be changed from left hand circular polarisation (LHCP) to right hand circular polarisation (RHCP) by replacing asymmetric U-shaped slot with its mirror image on the opposite side of ground plane. The proposed antenna has a wide impedance bandwidth of 110.8% and can also be used in various applications including worldwide interoperability for microwave access (WiMAX) and IEEE 802.11p standard based V2V (Vehicle to Vehicle) communication.     

Goodput and throughput comparison of single‐hop and multi‐hop routing for IEEE 802.11 DCF‐based wireless networks under hidden terminal existence

We investigate how multi‐hop routing affects the goodput and throughput performances of IEEE 802.11 distributed coordination function‐based wireless networks compared with direct transmission (single hopping), when medium access control dynamics such as carrier sensing, collisions, retransmissions, and exponential backoff are taken into account under hidden terminal presence. We propose a semi‐Markov chain‐based goodput and throughput model for IEEE 802.11‐based wireless networks, which works accurately with both multi‐hopping and single hopping for different network topologies and over a large range of traffic loads. Results show that, under light traffic, there is little benefit of parallel transmissions and both single‐hop and multi‐hop routing achieve the same end‐to‐end goodput. Under moderate traffic, concurrent transmissions are favorable as multi‐hopping improves the goodput up to 730% with respect to single hopping for dense networks. At heavy traffic, multi‐hopping becomes unstable because of increased packet collisions and network congestion, and single‐hopping achieves higher network layer goodput compared with multi‐hop routing. As for the link layer throughput is concerned, multi‐hopping increases throughput 75 times for large networks, whereas single hopping may become advantageous for small networks. The results point out that the end‐to‐end goodput can be improved by adaptively switching between single hopping and multi‐hopping according to the traffic load and topology. Copyright © 2015 John Wiley & Sons, Ltd.     

Analytical modeling of bidirectional multi‐channel IEEE 802.11 MAC protocols

This paper presents an analytical approach to model the bi‐directional multi‐channel IEEE 802.11 MAC protocols (Bi‐MCMAC) for ad hoc networks. Extensive simulation work has been done for the performance evaluation of IEEE 802.11 MAC protocols. Since simulation has several limitations, this work is primarily based on the analytical approach. The objective of this paper is to show analytically the performance advantages of Bi‐MCMAC protocol over the classical IEEE 802.11 MAC protocol. The distributed coordination function (DCF) mode of medium access control (MAC) is considered in the modeling. Two different channel scheduling strategies, namely, random channel selection and fastest channel first selection strategy are also presented in the presence of multiple channels with different transmission rates. M/G/1 queue is used to model the protocols, and stochastic reward nets (SRNs) are employed as a modeling technique as it readily captures the synchronization between events in the DCF mode of access. The average system throughput, mean delay, and server utilization of each MAC protocol are evaluated using the SRN formalism. We also validate our analytical model by comparison with simulation results. The results obtained through the analytical modeling approach illustrate the performance advantages of Bi‐MCMAC protocols with the fastest channel first scheduling strategy over the classical IEEE 802.11 protocol for TCP traffic in wireless ad hoc networks. Copyright © 2010 John Wiley & Sons, Ltd.     

IEEE 802.11n MIMO-OFDM无线局域网系统的定时与频率同步

本文提出了一种针对基于IEEE 802.11n标准的MIMO-OFDM无线局域网系统的定时与频率同步方案。本文提出的同步算法基于训练序列。该算法充分利用多天线分集,使同步算法的MSE性能得到显著的改进。仿真表明本文提出的同步方案在低信噪比条件下仍具有良好的性能,并且能够有效地对抗瑞利衰落信道的影响。     

E‐MAC: an elastic MAC layer for IEEE 802.11 networks

We present a system for real‐time traffic support in infrastructure and ad hoc IEEE 802.11 networks. The proposed elastic MAC (E‐MAC) protocol provides a distributed transmission schedule for stations with real‐time traffic requirements, while allowing a seamless coexistence with standard IEEE 802.11 clients, protecting best‐effort 802.11 traffic from starvation by means of admission control policies. Our scheduling decisions are based on an ‘elastic’ transmission opportunity (TXOP) assignment which allows for efficient wireless resource usage: whenever a real‐time station does not use the assigned TXOP, the other real‐time stations can take over the unused access opportunity, thus preventing the well‐known inefficiencies of static time division multiple access (TDMA) schemes. Unlike other TDMA‐based solutions for 802.11, E‐MAC does not require a tight synchronization among the participating clients, thus allowing its implementation on commodity WLAN hardware via minor software changes at the client side, and no changes at the access points (APs). We studied the performance of our mechanism via ns‐2 simulations and a mathematical model, showing that it outperforms IEEE 802.11e in terms of throughput, delay, and jitter. We finally provide a proof of concept through the results obtained in a real testbed where we implemented the E‐MAC protocol. Copyright © 2011 John Wiley & Sons, Ltd.     

A smart exponential‐threshold‐linear backoff mechanism for IEEE 802.11 WLANs

Based on the standardized IEEE 802.11 Distributed Coordination Function (DCF) protocol, this paper proposes a new backoff mechanism, called Smart Exponential‐Threshold‐Linear (SETL) Backoff Mechanism, to enhance the system performance of contention‐based wireless networks. In the IEEE 802.11 DCF scheme, the smaller contention window (CW) will increase the collision probability, but the larger CW will delay the transmission. Hence, in the proposed SETL scheme, a threshold is set to determine the behavior of CW after each transmission. When the CW is smaller than the threshold, the CW of a competing station is exponentially adjusted to lower collision probability. Conversely, if the CW is larger than the threshold, the CW size is tuned linearly to prevent large transmission delay. Through extensive simulations, the results show that the proposed SETL scheme provides a better system throughput and lower collision rate in both light and heavy network loads than the related backoff algorithm schemes, including Binary Exponential Backoff (BEB), Exponential Increase Exponential Decrease (EIED) and Linear Increase Linear Decrease (LILD). Copyright © 2011 John Wiley & Sons, Ltd.