一种AOWL-FSLE的UWB均衡接收机

针对UWB(Ultra Wideband)系统在不同室内环境下信道不同对ISI抑制带来的影响,提出了一种可调观察窗口长度分数间隔线性均衡的(AOWL-FSLE)均衡接收机.该接收机能够根据室内信道不同,自适应地调整观察窗口长度.研究结果表明,当信道变化时,与固定观察窗口长度分数间隔线性均衡的(FOWL-FSLE)均衡接收机相比,该接收机能够更有效地抑制ISI影响,提高系统的BER性能.

正交频分复用时域自适应均衡接收机实现及性能分析

本文提出了一种新型的OFDM系统时域自适应均衡接收机,接收端在数据作FFT解调之前先进行时域信号的均衡处理。均衡器采用了最小递归二乘系数更新算法和类似判决反馈均衡的结构,并由此基于现有的802,11a标准构建了完整的OFDM仿真系统。通过仿真分析可得出,这种接收机能可靠消除WLAN中存在的严重多径时延的影响,相比传统OFDM系统而言性能得到明显改善.同时表明无需在接收机的频域部分作进一步的均衡信号处理。

DC-10 Mbit/s突发模式非均衡码光接收机

设计了一种直接数字输出的DC-10 Mbit/s非均衡码突发信号光接收机,并采用0.5μmCMOS工艺成功实现.该接收机根据突发非均衡码的特点,以峰值检测为基础,采用全直流耦合,设计了新型开关自动增益控制电路和复位控制逻辑电路,实现了灵敏度和动态范围的优化.整个系统具有高响应速度,可消除突发导致的比特丢失.测试结果表明,当速率为10Mbit/s和600bit/s时,该接收机可分别获得优于-30dBm和-36dBm的灵敏度及宽于30dB的动态范围.对于连续"0"信号和无信号状态,该接收机提供可编程时间的报警指示功能.整个接收机采用5V单电源供电,功耗仅为30mW.

适用于HSDPA的码片均衡干扰加权抵消联合接收机

随着因特网与多媒体业务的需求,WCDMA引入了高速下行链路分组接入(HSDPA)技术将其下行链路数据传输速率提高到10Mbps。为了提高HSDPA传输的性能,该文提出了一种新的码片均衡干扰加权抵消联合接收机(LMMSE-IWC)。理论分析与计算机模拟结果表明LMMSE-IWC性能优于传统的Rake接收机和LMMSE码片均衡器。

是德科技最新款64 GBaud BERT扩展解决方案助力400G接收机测试化繁为简,轻松提速

新闻要点：新款比特误码率测试仪（BERT）功能更全面,并配有全新的可调均衡器,是PAM-4和NRZ测试的理想之选高度整合的码型发生器可以显著优化接收机测试设置内置均衡器可以重新打开闭合眼图,获得可重复的结果支持扩展和升级,轻松满足未来需求是德科技公司（NYSE：KEYS）近日宣布为M8040A高性能比特误码率测试仪（BERT）解决方案推出功能更强大的创新选件。

Acoustic MIMO Communications in a Very Shallow Water Channel

Underwater acoustic channels pose a great difficulty for the development of high speed communication due to highly limited band-width as well as hostile multipath interference. Enlightened by rapid progress of multiple-input multiple-output （MIMO） technologies in wireless communication scenarios, MIMO systems offer a potential solution by enabling multiple spatially parallel communication channels to improve communication performance as well as capacity. For MIMO acoustic communications, deep sea channels offer substantial spatial diversity among multiple channels that can be exploited to address simultaneous multipath and co-channel interference. At the same time, there are increasing requirements for high speed underwater communication in very shallow water area （for example, a depth less than 10 m）. In this paper, a space-time multichannel adaptive receiver consisting of multiple decision feedback equalizers （DFE） is adopted as the receiver for a very shallow water MIMO acoustic communication system. The performance of multichannel DFE receivers with relatively small number of receiving elements are analyzed and compared with that of the multichannel time reversal receiver to evaluate the impact of limited spatial diversity on multi-channel equalization and time reversal processing. The results of sea trials in a very shallow water channel are presented to demonstrate the feasibility of very shallow water MIMO acoustic communication.