Felix Wunsch, S. Koslowski, Sebastian Müller, Nicolas Cuervo, F. Jondral
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引用次数: 3
摘要
在本提案中,我们详细介绍了我们设计认知覆盖系统的方法,该系统在异构软件定义无线电(SDR)平台上实现,该平台由一台现成的消费者笔记本电脑和一台USRP X310组成。为了保证高灵活性、频谱效率和低带外辐射,我们选择了滤波器组多载波(Filter Bank multiccarrier, FBMC)作为物理层波形。在认知方面,我们提出了一种基于主用户(PU)传输参数和行为模式学习以及连续、低延迟信道监测的混合解决方案。为了实现低延迟和提高性能,我们在FPGA上实现了关键的信号处理组件。根据PU错误率的反馈信息,优化检测阈值。
In this proposal, we provide details on our approach for the design of a cognitive overlay system which is implemented on a heterogeneous Software Defined Radio (SDR) platform consisting of an off-the-shelf consumer laptop and a USRP X310. To ensure high flexibility, spectral efficiency and low out-of-band radiation, we chose Filter Bank Multicarrier (FBMC) as physical layer waveform. For the cognitive aspect we propose a hybrid solution based on learning of Primary User (PU) transmission parameters and behavioral patterns as well as continuous, low-delay channel monitoring. To achieve a low delay and to improve performance, we implement critical signal processing components on an FPGA. Detection thresholds are optimized by using feedback information on the PU error rate.
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