We propose a neural network (NN)-based algorithm for device detection and time of arrival (ToA) and carrier frequency offset (CFO) estimation for the narrowband physical random-access channel (NPRACH) of narrowband internet of things (NB-IoT). The introduced NN architecture leverages residual convolutional networks as well as knowledge of the preamble structure of the 5G New Radio (5G NR) specifications. Benchmarking on a 3rd Generation Partnership Project (3GPP) urban microcell (UMi) channel model with random drops of users against a state-of-the-art baseline shows that the proposed method enables up to 8 dB gains in false negative rate (FNR) as well as significant gains in false positive rate (FPR) and ToA and CFO estimation accuracy. Moreover, our simulations indicate that the proposed algorithm enables gains over a wide range of channel conditions, CFOs, and transmission probabilities. The introduced synchronization method operates at the base station (BS) and, therefore, introduces no additional complexity on the user devices. It could lead to an extension of battery lifetime by reducing the preamble length or the transmit power. Our code is available at: https://github.com/NVlabs/nprach_synch/.
翻译:我们提议对窄带物质互联网(NB-IoT)的窄带物理随机访问频道(NPRACH)进行基于神经网络(NN)的仪器探测和到达时间(ToA)和载荷频率(CFO)估算算法,引入NN结构利用剩余革命网络,并了解5G新电台(5GNR)规格的序言结构;对第三代伙伴关系项目(3GPP)城市微电池(UMI)频道模型进行基准测量,用户随机下降,以达到最先进的基线,显示拟议方法使假负率(FNR)和假正率(FPR)及TOA和CFO的收益高达8 dB,以及假正率(FPR)和托A和CFO的显著收益。此外,我们的模拟表明,拟议的算法使广泛的频道条件、CFOs和传输概率获得收益。引入的同步方法在基站运作,因此用户装置不具有额外的复杂性。通过缩短序言长度或传输能力,可以导致电池寿命延长。