ZTE Communications最新文献

英文中文

Next Generation Mobile Video Networking 下一代移动视频网络

ZTE Communications

Pub Date : 2020-03-18 DOI: 10.19729/J.CNKI.1673-5188.2018.03.001

Hwang Jenq-neng, Wen Yonggang

引用次数: 2

A Quantum Key Re-Transmission Mechanism for QKD-Based Optical Networks 基于QKD的光网络的量子密钥重传机制

ZTE Communications

Pub Date : 2020-03-18 DOI: 10.19729/J.CNKI.1673-5188.2018.03.009

Wang Hua, Zhao Yongli, Wang Dajiang, Wang Jiayu, Wang Zhenyu

引用次数: 2

Mechanism of Fast Data Retransmission in CU-DU Split Architecture of 5G NR 5G NR CU-DU分离架构下的快速数据重传机制

ZTE Communications

Pub Date : 2020-03-18 DOI: 10.19729/J.CNKI.1673-5188.2018.03.007

Huang-Chuan He, Liu Yang, Liu Zhuang, Han Jiren, Gao Yin

引用次数: 1

Behavior Targeting Based on Hierarchical Taxonomy Aggregation for Heterogeneous Online Shopping Applications 基于层次分类聚合的异构网上购物应用行为定向

ZTE Communications

Pub Date : 2020-03-16 DOI: 10.3969/J.ISSN.1673-5188.2018.01.009

Z. Lifeng, Zhang Chunhong, Hu Zheng, Tang Xiaosheng

引用次数: 0

Secure Beamforming Design for SWIPT in MISO Full-Duplex Systems MISO全双工系统中SWIPT的安全波束形成设计

ZTE Communications

Pub Date : 2020-03-16 DOI: 10.3969/J.ISSN.1673-5188.2018.01.006

A. Okandeji, Muhammad R. A. Khandaker, Wong Kai-Kit, Zhang Yangyang, Zheng Zhong-bin

引用次数: 0

Ultra-Low Power High-Efficiency UHF-Band Wireless Energy Harvesting Circuit Design and Experiment 超低功耗高效超高频无线能量采集电路设计与实验

ZTE Communications

Pub Date : 2020-03-16 DOI: 10.3969/J.ISSN.1673-5188.2018.01.002

Li Zhenbing, Li Jian, Zhou Jie, Zhao Fading, Wen Guang-jun

引用次数: 0

Exploiting Correlations of Energy and Information: A New Paradigm of Energy Harvesting Communications 利用能量与信息的相关性:能量收集通信的新范式

ZTE Communications

Pub Date : 2020-03-16 DOI: 10.3969/J.ISSN.1673-5188.2018.01.004

Gong Jie, Zhou Sheng

引用次数: 0

Design of Wireless Energy-Harvested UHF WSN Tag for Cellular IoT 面向蜂窝物联网的无线能量采集UHF WSN标签设计

ZTE Communications

Pub Date : 2020-03-16 DOI: 10.3969/J.ISSN.1673-5188.2018.01.003

Li Gang, Xu Rui, Li Zhenbing, Zhou Jie, Li Jian, Wen Guang-jun

In this paper, a wireless energy⁃harvested ultra⁃high frequency (UHF) wireless sensor network (WSN) tag is designed and imple⁃ mented for cellular IoT applications. The WSN tag is made up of a wireless energy harvesting circuit, a temperature sensing cir⁃ cuit, and a radio frequency identification (RFID) tag. The developed WSN tag is compatible with the ISO/IEC18000⁃6C protocol. The WSN tag can receive the GSM RF energy operating in China GSM900 and GSM1800 bands in the surrounding environment and the solar energy, then converts the RF energy to direct current (DC) by schottky diode⁃based rectifying circuit, and finally stores the DC energy in a supercapacitor through a DC⁃DC booster circuit. The DC⁃DC booster circuit drives the front⁃end circuit, TI MSP430 microcontroller, temperature sensing circuit, and other active circuits in the tag. The MSP430 works in low⁃power mode when it is powered up, and it can also reduce power consumption more by reducing main clock (MCLK) frequency accord⁃ ing to different forward link rates. The implemented WSN tag demonstrated that the RF⁃to⁃DC conversion efficiency is higher than 39% when the receiving 900 MHz RF signal power is from ⁃14 dBm to 0 dBm and could make the tag work normally. The signal receiving sensitivity of the WSN tag is up to ⁃32 dBm at the rate of 40 kbit/s from the Reader to the WSN tag. The WSN tag sup⁃ ports Miller coding and extended Miller coding. This wireless energy harvested UHF WSN tag, compared with conventional UHF passive tags and battery⁃powered active UHF RFID Tags, has many advantages, such as far communication distance, long service life, and sensing functionality. It will have wide applications in the Internet of Things (IoT). DC⁃DC booster circuit; MSP430; RF energy harvest; WSN tag

本文设计并实现了一种用于蜂窝物联网应用的无线能量采集超高频(UHF)无线传感器网络(WSN)标签。该WSN标签由无线能量采集电路、温度传感电路和射频识别(RFID)标签组成。所开发的WSN标签兼容ISO/IEC18000⁃6C协议。该WSN标签可以接收周围环境中工作在中国GSM900和GSM1800频段的GSM射频能量以及太阳能，然后通过基于肖特基二极管的整流电路将射频能量转换为直流(DC)，最后通过DC⁃DC升压电路将直流能量存储在超级电容器中。DC⁃DC升压电路驱动前端电路、TI MSP430微控制器、温度传感电路和标签中的其他有源电路。MSP430在上电时工作在低功耗模式下，并根据不同的转发链路速率降低主时钟(MCLK)频率，从而进一步降低功耗。所实现的WSN标签在接收到的900 MHz RF信号功率为⁃14 dBm ~ 0 dBm时，其RF⁃to⁃DC转换效率高于39%，并能使标签正常工作。以40kbit /s的速率从阅读器到WSN标签的信号接收灵敏度高达⁃32dbm。WSN标签支持米勒编码和扩展米勒编码。与传统的超高频无源标签和电池供电的有源超高频RFID标签相比，这种无线能量采集的超高频WSN标签具有通信距离远、使用寿命长、传感功能强等优点。它将在物联网(IoT)中有广泛的应用。DC⁃DC升压电路;MSP430的;射频能量收集;摘要:标签

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引用次数: 1

Recent Advances of Simultaneous Wireless Information and Power Transfer in Cellular Networks 蜂窝网络中同时无线信息和功率传输的最新进展

ZTE Communications

Pub Date : 2020-03-16 DOI: 10.3969/J.ISSN.1673-5188.2018.01.005

Liu Binghong, P. Mugen, Zhou Zheng

引用次数: 2

Overview of Co-Design Approach to RF Filter and Antenna 射频滤波器与天线协同设计方法综述

ZTE Communications

Pub Date : 2020-03-16 DOI: 10.3969/J.ISSN.1673-5188.2018.01.007

Zhang Wenmei, C. Xinwei

引用次数: 2

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