5G进程将扰乱测试过程
Moor Insights & Strategy总裁兼首席分析师帕特里克•穆尔黑德(Patrick Moorhead)表示:“十年后,我们回首往事时会说,5G是有史以来最重要的技术之一。”
Moor Insights & Strategy总裁兼首席分析师帕特里克•穆尔黑德(Patrick Moorhead)表示:“十年后,我们回首往事时会说,5G是有史以来最重要的技术之一。”
\u201cTen years from now, we\u2019re going to look back and say that 5G was one of the most important pieces of technology ever,\u201d says Patrick Moorhead, president and principal analyst at Moor Insights & Strategy. \u201cIt enables everything we see today that\u2019s emerging, whether it\u2019s self-driving cars that talk to each other or just having the most amazing video experience.\u201d<\/p>
The Road to 5G<\/em><\/strong><\/p> The 3GPP standardization body is furiously marching toward defining 5G, but the real work is just beginning. Companies specializing in semiconductor, network infrastructure, cloud, software, manufacturing, and test technologies must now design, develop, test, and deliver solutions that take advantage of these new wireless capabilities. This is no easy task.<\/p> 5G features new technologies such as Massive MIMO and mmWave. Both technologies use multiple antennas and beamforming, which is a huge departure from current and previous wireless architectures. 5G also includes new wireless control mechanisms that split the control and data to facilitate the concept of network slicing, which scales the level of service to an individual user device.<\/p> In addition, the standards proposed for 5G are far more complex than 3G and 4G standards. 5G will transform our networks, so the industry must transform the way these systems are designed, developed, and tested. For algorithm design, simply modeling systems without any real-world validation has not been enough for an idea to advance from concept to production. For test, traditional methods that focus on an individual component will not be able to account for the overall impact to the system.<\/p> A Platform-Based Approach<\/em><\/strong><\/p> Wireless researchers across the world quickly discovered that the only path to success is via a platform-based approach to 5G with software at the core. Nokia introduced the first mmWave 5G prototype at 73 GHz and broke the record for mobile access data rates using mmWave spectrum. Lund University developed the first Massive MIMO prototype, and researchers at the University of Bristol and Facebook extended their Massive MIMO prototypes to achieve unprecedented spectrum efficiency milestones.<\/p> These system prototypes have already played an important part in the 5G technology evolution. The platform-based design approach used in these examples takes full advantage of software defined radios (SDRs) to tackle system challenges and reduce time to results. SDRs for design and prototyping will continue to evolve as the software changes. We can even envision more capable SDRs with software extending beyond the physical layer to leverage the vast ecosystem of open source software. This will enable researchers to address both the upper layers and the network to further decrease time to adoption and shatter the siloed approach to design.<\/p> 5G Innovation Doesn\u2019t Stop at Design<\/em><\/strong><\/p> Test and measurement solutions will be key in the commercialization cycle. Test systems must expand beyond the physical layer to quickly and cost-efficiently test these new multiantenna technologies with controllable\/steerable beams. Additionally, these systems must address the new mmWave-capable devices with extremely wide bandwidths. These test solutions must not only be able to test the important parameters of a device but also be cost-effective for 5G to reach its potential and achieve widespread adoption.<\/p> With these characteristics, 5G requires a different approach to test for wireless devices and systems. For example, system-level over-the-air (OTA) test must become standard in the 5G ecosystem. OTA test presents several challenges but perhaps the most daunting pertains to the environment in which the test equipment and the device under test must coexist. Air is an unpredictable medium, and the channel itself varies over time and environmental conditions. Wireless test engineers must isolate the channel in the OTA scenario and control the device on a per beam basis to effectively \u201ctest\u201d the device.<\/p> In addition, companies like Intel have introduced early phased array antenna modules featuring an antenna attached directly to the RF front end to minimize system losses. Because access to the device is limited, the test equipment must step up in frequency to the mmWave bands and characterize key performance metrics beam by beam.<\/p> Finally, whereas bandwidth is a familiar test challenge, the tested bandwidth of 5G is expected to increase by 50X over a standard LTE channel. At these bandwidths, test systems must not only generate and acquire wider bandwidth waveforms but also process all that data in real time.<\/p> What\u2019s Next<\/em><\/strong><\/p> Wireless researchers have embraced a platform design approach using SDRs to expedite the early research phase of 5G, and they have delivered. Now, test solution providers must do the same. 5G presents a paradigm shift the likes of which we\u2019ve never seen before, and a platform-based approach that is flexible and software configurable will be essential to the development of this ecosystem.<\/p> <\/p>","blog_img":"","posted_date":"2017-11-11 10:36:55","modified_date":"2019-09-10 13:14:44","featured":"0","status":"Y","seo_title":"5G progress set to disrupt test processes","seo_url":"5g-progress-set-to-disrupt-test-processes","url":"\/\/www.iser-br.com\/tele-talk\/5g-progress-set-to-disrupt-test-processes\/2696","url_seo":"5g-progress-set-to-disrupt-test-processes"}">
5克这标志着将深刻影响全球企业和消费者的一代人的转变。它承诺革命性的无束缚体验,更快的数据,更短的网络响应时间(更低的延迟),随时随地的即时访问,以及数十亿设备的容量。我们谈论的不仅仅是能够更快地将视频下载到你的手机。与3G和4G不同,5G有望远远超越我们的移动设备,进入触及我们生活方方面面的应用程序。从实现工业物联网到确保自动驾驶汽车的安全,5G将以难以想象的方式改变我们的生活。 Moor Insights & Strategy总裁兼首席分析师帕特里克•穆尔黑德(Patrick Moorhead)表示:“十年后,我们回首往事时会说,5G是有史以来最重要的技术之一。”“它使我们今天看到的所有新兴事物都成为可能,无论是自动驾驶汽车,还是拥有最令人惊叹的视频体验。” 5G之路 3GPP标准化机构正朝着定义5G的方向疯狂前进,但真正的工作才刚刚开始。专注于半导体、网络基础设施、云、软件、制造和测试技术的公司现在必须设计、开发、测试和交付利用这些新的无线功能的解决方案。这不是一项简单的任务。 5G采用了Massive等新技术米姆和mmWave。这两种技术都使用多天线和波束形成,这与当前和以前的无线架构有很大的不同。5G还包括新的无线控制机制,将控制和数据分开,以促进网络切片的概念,将服务水平扩展到单个用户设备。 此外,针对5G提出的标准要比3G和4G标准复杂得多。5G将改变我们的网络,因此行业必须改变这些系统的设计、开发和测试方式。对于算法设计来说,仅仅对系统进行建模而不进行任何真实世界的验证是不足以让一个想法从概念发展到生产的。对于测试,专注于单个组件的传统方法将无法解释对系统的整体影响。 基于平台的方法 世界各地的无线研究人员很快发现,成功的唯一途径是通过以软件为核心的基于平台的方法实现5G。诺基亚推出了第一个73 GHz的毫米波5G原型机,并打破了使用毫米波频谱的移动访问数据速率记录。隆德大学开发了第一个Massive MIMO原型,布里斯托尔大学和Facebook的研究人员扩展了他们的Massive MIMO原型,以实现前所未有的频谱效率里程碑。 这些系统原型已经在5G技术发展中发挥了重要作用。这些示例中使用的基于平台的设计方法充分利用了软件定义无线电(sdr)来解决系统挑战,并减少获得结果的时间。用于设计和原型的sdr将随着软件的变化而继续发展。我们甚至可以设想功能更强大的sdr,其软件扩展到物理层以外,以利用开源软件的巨大生态系统。这将使研究人员能够同时解决上层和网络问题,从而进一步减少采用的时间,并打破孤立的设计方法。 5G创新不止步于设计 测试和测量解决方案将是商业化周期的关键。测试系统必须扩展到物理层之外,以快速和经济有效地测试这些新的多天线技术与可控/可操纵波束。此外,这些系统必须处理具有极宽带宽的新型毫米波设备。这些测试解决方案不仅必须能够测试设备的重要参数,而且必须具有成本效益,以实现5G的潜力并实现广泛采用。 由于这些特点,5G需要一种不同的方法来测试无线设备和系统。例如,系统级空中(OTA)测试必须成为5G生态系统的标准。OTA测试提出了几个挑战,但最令人生畏的可能是测试设备和被测设备必须共存的环境。空气是一种不可预测的介质,通道本身随着时间和环境条件的变化而变化。无线测试工程师必须在OTA场景中隔离通道,并在每个波束的基础上控制设备,以有效地“测试”设备。 此外,像英特尔这样的公司已经推出了早期相控阵天线模块,其特点是将天线直接连接到射频前端,以最大限度地减少系统损耗。由于对设备的访问受到限制,测试设备必须将频率提高到毫米波波段,并逐波束表征关键性能指标。 最后,虽然带宽是一个常见的测试挑战,但5G的测试带宽预计将比标准LTE信道增加50倍。在这些带宽下,测试系统不仅必须生成和获取更宽的带宽波形,而且还必须实时处理所有数据。 接下来是什么 无线研究人员采用了一种使用sdr来加速5G早期研究阶段的平台设计方法,并且已经交付使用。现在,测试解决方案提供者也必须这样做。5G带来了一种我们从未见过的范式转变,一种灵活的、基于平台的、软件可配置的方法对这一生态系统的发展至关重要。 免责声明:所表达的观点仅代表作者,ETTelecom.com并不一定订阅它。乐动体育1002乐动体育乐动娱乐招聘乐动娱乐招聘乐动体育1002乐动体育etelecom.com不对直接或间接对任何人/组织造成的任何损害负责。
\u201cTen years from now, we\u2019re going to look back and say that 5G was one of the most important pieces of technology ever,\u201d says Patrick Moorhead, president and principal analyst at Moor Insights & Strategy. \u201cIt enables everything we see today that\u2019s emerging, whether it\u2019s self-driving cars that talk to each other or just having the most amazing video experience.\u201d<\/p>
The Road to 5G<\/em><\/strong><\/p> The 3GPP standardization body is furiously marching toward defining 5G, but the real work is just beginning. Companies specializing in semiconductor, network infrastructure, cloud, software, manufacturing, and test technologies must now design, develop, test, and deliver solutions that take advantage of these new wireless capabilities. This is no easy task.<\/p> 5G features new technologies such as Massive MIMO and mmWave. Both technologies use multiple antennas and beamforming, which is a huge departure from current and previous wireless architectures. 5G also includes new wireless control mechanisms that split the control and data to facilitate the concept of network slicing, which scales the level of service to an individual user device.<\/p> In addition, the standards proposed for 5G are far more complex than 3G and 4G standards. 5G will transform our networks, so the industry must transform the way these systems are designed, developed, and tested. For algorithm design, simply modeling systems without any real-world validation has not been enough for an idea to advance from concept to production. For test, traditional methods that focus on an individual component will not be able to account for the overall impact to the system.<\/p> A Platform-Based Approach<\/em><\/strong><\/p> Wireless researchers across the world quickly discovered that the only path to success is via a platform-based approach to 5G with software at the core. Nokia introduced the first mmWave 5G prototype at 73 GHz and broke the record for mobile access data rates using mmWave spectrum. Lund University developed the first Massive MIMO prototype, and researchers at the University of Bristol and Facebook extended their Massive MIMO prototypes to achieve unprecedented spectrum efficiency milestones.<\/p> These system prototypes have already played an important part in the 5G technology evolution. The platform-based design approach used in these examples takes full advantage of software defined radios (SDRs) to tackle system challenges and reduce time to results. SDRs for design and prototyping will continue to evolve as the software changes. We can even envision more capable SDRs with software extending beyond the physical layer to leverage the vast ecosystem of open source software. This will enable researchers to address both the upper layers and the network to further decrease time to adoption and shatter the siloed approach to design.<\/p> 5G Innovation Doesn\u2019t Stop at Design<\/em><\/strong><\/p> Test and measurement solutions will be key in the commercialization cycle. Test systems must expand beyond the physical layer to quickly and cost-efficiently test these new multiantenna technologies with controllable\/steerable beams. Additionally, these systems must address the new mmWave-capable devices with extremely wide bandwidths. These test solutions must not only be able to test the important parameters of a device but also be cost-effective for 5G to reach its potential and achieve widespread adoption.<\/p> With these characteristics, 5G requires a different approach to test for wireless devices and systems. For example, system-level over-the-air (OTA) test must become standard in the 5G ecosystem. OTA test presents several challenges but perhaps the most daunting pertains to the environment in which the test equipment and the device under test must coexist. Air is an unpredictable medium, and the channel itself varies over time and environmental conditions. Wireless test engineers must isolate the channel in the OTA scenario and control the device on a per beam basis to effectively \u201ctest\u201d the device.<\/p> In addition, companies like Intel have introduced early phased array antenna modules featuring an antenna attached directly to the RF front end to minimize system losses. Because access to the device is limited, the test equipment must step up in frequency to the mmWave bands and characterize key performance metrics beam by beam.<\/p> Finally, whereas bandwidth is a familiar test challenge, the tested bandwidth of 5G is expected to increase by 50X over a standard LTE channel. At these bandwidths, test systems must not only generate and acquire wider bandwidth waveforms but also process all that data in real time.<\/p> What\u2019s Next<\/em><\/strong><\/p> Wireless researchers have embraced a platform design approach using SDRs to expedite the early research phase of 5G, and they have delivered. Now, test solution providers must do the same. 5G presents a paradigm shift the likes of which we\u2019ve never seen before, and a platform-based approach that is flexible and software configurable will be essential to the development of this ecosystem.<\/p> <\/p>","blog_img":"","posted_date":"2017-11-11 10:36:55","modified_date":"2019-09-10 13:14:44","featured":"0","status":"Y","seo_title":"5G progress set to disrupt test processes","seo_url":"5g-progress-set-to-disrupt-test-processes","url":"\/\/www.iser-br.com\/tele-talk\/5g-progress-set-to-disrupt-test-processes\/2696","url_seo":"5g-progress-set-to-disrupt-test-processes"},img_object:["","retail_files/author_1510817608_temp.jpg"],fromNewsletter:"",newsletterDate:"",ajaxParams:{action:"get_more_blogs"},pageTrackingKey:"Blog",author_list:"James Kimery",complete_cat_name:"Blogs"});" data-jsinvoker_init="_override_history_url = "//www.iser-br.com/tele-talk/5g-progress-set-to-disrupt-test-processes/2696";">