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Understanding 5G Spectrum Frequency Bands

2022-09-09
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What Frequency Spectrum Do 5G Networks Use?

5G, or “fifth generation” cellular technology, represents a massive leap forward for wireless mobile communications. In terms of data rates, security and latency, 5G far surpasses previous generations of communication platforms:  

  • 4G (LTE, LTE-Advanced, LTE-Advanced Pro, WiMax)  
  • 3G (UMTS, WCDMA, CDMA, 1xEV-DO) 
  • 2G (GSM, GPRS, CDMA, 1xRTT) 

5G technology promises a cost- and energy-efficient solution with close-to-universal device reach. 

Mass quantities of new radio spectrum have been specified to support these capabilities in the 5G standard. This spectrum consists of 5G New Radio (NR) and, notably, millimeter wave (mmWave) bands, known technically as frequency range 2 (FR2). In 2016, the Federal Communications Commission (FCC) opened vast bandwidth amounts in high-band spectrum for 5G, as have regulators across many countries. 

As a result, the Spectrum Frontiers Proposal (SFP) doubled the amount of mmWave unlicensed spectrum to 14 GHz. This increase created four times the flexible, mobile-use spectrum the FCC had licensed to date. 

In March 2018, the European Union (EU) agreed to open the 3.6 and 26 GHz bands by 2020. 

Low-, Mid- and High-Band 5G Spectrum Frequencies and Their Allocations

5G will operate on three different spectrum bands. This structure may not seem important for the average consumer, but it will have varying effects on everyday use.

Low-Band Spectrum

Low-band spectrum is “sub” 1 GHz spectrum. U.S carriers primarily use low-band spectrum for 3G and LTE. It provides consumers with a broad coverage area and good building penetration, but data speeds peak around 100 Mbps. 

Operators will reclaim this spectrum for 5G in the coming years with concluded 3G sunsets. 

According to Digital Trends, T-Mobile is the leading player in the low-band spectrum space. The operator bought a large block of 600 MHz (i.e., Band n71 in 5G) spectrum during FCC auctions in 2017. 

Since that purchase, the company has been building its nationwide 5G network on the spectrum block. With the Sprint merger, T-Mobile leveraged the block with other mid- and high-band spectrum to create the most 5G coverage in the U.S. 

Mid-Band Spectrum

This spectrum between 1 and 6 GHz provides faster throughput and lower latency than the low-band spectrum. As Digital Trends notes, mid-band transmissions are less suitable for building penetration.  

However, peak speeds can reach as high as 1 Gbps and provide more capacity to the network. 4G and 5G standards use this spectrum. Mid-band spectrum is the foremost 5G coverage and capacity contributor. 

To do this, mobile operators apply multiple-input, multiple-output (MIMO) technology to the 5G deployment. MIMO groups several antennas at one cell tower, creating multiple radio links to each mobile device. 

High-Band Spectrum

Most people think of high-band spectrum (i.e., mmWave or FR2) when they think of 5G. High-band spectrum enables speeds in the tens of Gbps range at even lower latency. However, the high-band coverage area is limited and has poor building and rain penetration. It’s considered as line-of-sight for practical purposes. 

For mmWave mobile devices to work, the cell and the mobile device must use new antenna technology that can dynamically steer and form the radio beam to and from the cell tower. Steering and forming are done through power modulation and interferometry to and from tightly packed antenna module arrays. These modules are small because the signal is in the millimeter wavelength spectrum. 

mmWave is fundamental to achieving 5G speed and latency targets. Therefore, major telecommunication companies are developing the technology to address these propagation challenges. 

As 5G starts rolling out in high-band spectrum, carriers will piggyback off 5G FR1 and LTE while overlaying the infrastructure to support 5G FR2. 

Upgrades will include indoor and urban small cells. Small cells are low-power base stations positioned in high density so that each covers a small area at high speeds. Building many of these small cell clusters will expand coverage, particularly that of mmWave, but this will take time. 

Preparing for a 5G Future

Commercial 5G networks are achieving viable coverage for commercial IoT deployments. Innovative solution providers can start building future-proof mobile broadband and IoT-based designs for this next-generation technology while meeting today’s consumer demands.  

Telit helps you design future-ready solutions to solve today’s challenges. Experience the difference Telit can make. 

Our developer kits allow you to test Telit’s hardware, connectivity services and device management portal for your IoT solutions.  Speak with our 5G experts to request a 5G sample kit. 


Editor’s Note: This blog was originally published on 9 May 2019 and has since been updated.

参考译文
了解5G频段
5G,即“第五代”蜂窝技术,代表着无线移动通信的巨大飞跃。在数据速率、安全性和延迟方面,5G远远超过了前几代的通信平台:5G技术承诺成本为 ,并提供近乎通用的设备覆盖的节能解决方案。大量新的无线电频谱已被指定,以支持5G标准中的这些功能。这个频谱包括5G新无线电(NR),特别是毫米波(mmWave)频段,技术上称为频率范围2 (FR2)。2016年, 联邦通信委员会(FCC) 与许多国家的监管机构一样,为5G开放了大量的高频段频谱带宽。因此, Spectrum Frontiers Proposal (SFP) 将mmWave的未授权频谱数量增加了一倍,达到14 GHz。这一增长创造了四倍的灵活的,移动使用频谱FCC已经许可到目前为止。2018年3月, 欧盟(EU)同意在2020年之前开放3.6和26 GHz频段。5G将在三个不同的频段运行。这种结构可能对普通消费者来说并不重要,但它会对日常使用产生不同的影响。低频段频段是“sub”1 GHz频段。美国运营商主要在3G和LTE中使用低频段频段。它为消费者提供了广泛的覆盖区域和良好的建筑渗透率,但数据速度峰值在100 Mbps左右。未来几年,随着3G时代的结束,运营商将为5G收回这一频段。据 Digital Trends报道,T-Mobile在低频段频段领域处于领先地位。该运营商在2017年FCC拍卖期间购买了一大块600 MHz(即5G中的n71频段)频谱。自那次收购以来,该公司一直在该频段上建设全国范围的5G网络。通过与Sprint的合并,T-Mobile利用其他中高频段频段的区块,在美国创建了最大的5G覆盖范围。与低频段频段相比,1 - 6 GHz频段提供了更快的吞吐量和更低的延迟。正如Digital Trends所指出的,中波段传输不太适合建筑渗透。然而,峰值速度可以达到1gbps,并为网络提供更大的容量。4G和5G标准使用这个频谱。中频段是5G覆盖和容量的首要贡献者。为此,移动运营商在5G部署中应用了多输入多输出(MIMO)技术。MIMO将一个基站上的多个天线组合在一起,为每个移动设备创建多个无线链路。当提到5G时,大多数人想到的是高频段频谱(即毫米波或FR2)。高频带频谱可以在更低的延迟下实现数十Gbps范围的速度。然而,高频带覆盖范围有限,建筑和雨水渗透较差。它被认为是实用的视距。为了毫米波移动设备的工作,蜂窝和移动设备必须使用新的天线技术,可以动态地控制和形成无线波束进出蜂窝塔。转向和成形是通过功率调制和干涉测量来完成的,从密集的天线模块阵列。这些模块很小,因为信号是毫米波长的频谱。mmWave是实现5G速度和延迟目标的基础。因此,主要的电信公司正在开发技术来解决这些传播挑战。随着5G开始在高频段频谱中铺开,运营商将搭载5G FR1和LTE,同时覆盖基础设施以支持5G FR2。升级将包括室内和城市小单元。小型基站是低功率的高密度基站,每个基站以高速覆盖一小块区域。建立许多这样的小型小区集群将扩大覆盖范围,尤其是mmWave的覆盖范围,但这需要时间。 商用5G网络正在为商用物联网部署实现可行的覆盖。创新的解决方案提供商可以开始为下一代技术构建面向未来的移动宽带和基于物联网的设计,同时满足当今的消费者需求。Telit帮助您设计面向未来的解决方案,以解决当今的挑战。体验Telit带来的不同。我们的开发工具包允许您测试Telit的硬件,连接服务和设备管理门户为您的物联网解决方案。 与我们的5G专家沟通,请求5G样品包。编者注:本博客最初于2019年5月9日发布,并已进行更新。
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