科技先锋系列报告65-RingCentral(RNG.N)：统一通信服务巨头-2020.03

版权申明本白皮书版权属于宽带集群（B-TrunC）产业联盟，并受法律保护。

转载、摘编或利用其它方式使用本白皮书文字或者观点的，应注明“来源：宽带集群（B-TrunC）产业联盟”。

违反上述声明者，联盟将追究其相关法律责任。

前言集群通信正广泛应用于公共安全、交通运输、能源等领域，在保障社会治安、安全生产和提高经济建设效率等方面发挥着重要作用。

随着通信技术的发展，行业用户的需求随之增加，除了传统的语音业务外，对图像、视频等宽带数据业务的需求不断涌现。

传统窄带集群通信由于传输带宽较窄，仅能提供语音和低速数据业务，无法支持视频类的宽带数据传输，难以满足复杂场景下的可视调度指挥需求，发展宽带集群通信成为当务之急。

当前，LTE技术已在公众移动通信网络大规模应用，这为宽带集群通信发展奠定了坚实的技术和产业基础，因此，基于LTE技术的宽带集群通信(B-TrunC)系统也应运而生。

本白皮书主要介绍了宽带集群通信市场发展、产业发展、重点行业的发展进展及前景、实际应用案例等内容，可以帮助读者准确把握宽带集群通信行业的市场现状和发展趋势。

目录1 宽带集群通信市场发展 (1)1.1宽带集群通信的市场需求 (1)1.2 宽带集群通信发展的关键因素分析 (3)1.3 宽带集群通信市场发展迅速 (4)2 宽带集群通信产业发展 (6)2.1 B-TrunC对宽带集群通信产业发展意义重大 (6)2.1.1 有效支撑国家战略落地 (6)2.1.2 统一技术体制和标准 (8)2.1.3 推动国际化发展 (9)2.2 宽带集群通信具备频率基础 (9)2.3 宽带集群通信产业链发展迅速 (10)2.3.1 系统设备 (10)2.3.2 芯片和终端 (11)2.3.3 调度台 (12)2.3.4 一体化系统 (12)2.4 宽带集群通信产品测试认证 (13)3 宽带集群通信在重点行业的发展进展及前景 (16)3.1 无线政务 (16)3.1.1 城市管理与公共服务 (17)3.1.2 政府移动办公 (19)3.1.3 重大赛事、活动、展览等保障应用 (20)3.1.4 政府公共安全和应急 (21)3.2 公共安全 (23)3.2.1 日常警务指挥 (24)3.2.2 重大活动保障 (25)3.2.3 应急处置 (26)3.2.4 融合平台 (28)3.4 机场 (31)3.5 电力 (33)3.6 铁路站场 (36)3.7 港口 (38)3.8 石油石化 (40)3.8.1 石油企业 (40)3.8.2 炼化企业 (41)3.9其它行业 (42)4 附录：宽带集群通信应用案例 (43)4.1 无线政务网 (43)4.1.1 南京无线政务网 (43)4.1.2 天津无线政务网 (43)4.1.3 北京政务物联数据专网 (43)4.1.4 北京政企行业专网 (44)4.1.5 海南政企行业专网 (44)4.1.6 湖北政企行业专网 (44)4.1.7 深圳无线政务网 (45)4.1.8 武汉无线政务网 (45)4.2 公共安全 (45)4.2.1 西安公安 (45)4.2.2 西双版纳公安 (46)4.2.3 燕城监狱 (46)4.2.4 漓江公安 (46)4.2.5 呼和浩特公安 (46)4.2.6 吴江公安 (47)4.2.7 喀什公安 (47)4.2.8 贵阳公安 (48)4.2.9 宜春公安 (48)4.2.11 重大事件保障 (49)4.3 轨道交通 (49)4.3.1 北京地铁燕房线 (49)4.3.2 郑州地铁1号线、2号线 (49)4.3.3 石家庄地铁1号线、3号线 (50)4.3.4 杭州地铁4号线 (50)4.3.5 温州市域铁路S1线 (50)4.3.6 乌鲁木齐地铁1号线 (51)4.3.7 三亚有轨电车 (51)4.3.8 广州地铁14、21、知识城支线 (51)4.3.9 南京地铁宁高线 (51)4.3.10 重庆轨道交通十号线 (52)4.3.11 青岛地铁2号线 (52)4.4 机场 (52)4.4.1 上海浦东和虹桥机场 (52)4.4.2 三亚凤凰国际机场 (52)4.4.3 郑州新郑国际机场 (53)4.4.4 南宁吴圩机场 (53)4.5 港口 (53)4.5.1 青岛港 (53)4.5.2 日照港 (54)4.5.3 唐山港 (54)4.5.4 上海港 (54)4.6 铁路站场 (55)4.6.1 哈尔滨铁路局站场 (55)4.6.2 南宁铁路局站场 (55)4.6.3 西安铁路局站场 (55)4.7 电力 (56)4.7.2 深圳电力 (56)4.7.3 东莞电力 (56)4.7.4 新疆电力 (57)4.7.5 珠海电力 (57)4.7.6 同煤电力 (57)4.7.7 柳州电力 (58)4.7.8 电力应急 (58)4.8石油石化 (58)4.8.1 塔里木油田 (58)4.8.2 九江石化 (59)4.8.3 青海油田 (59)4.8.4 独山子炼化 (59)4.8.5 鲁西化工 (60)4.9 矿山 (60)4.9.1 魏家峁露天煤矿 (60)4.9.2 同煤塔山煤矿 (60)4.9.3 西湾露天矿 (60)4.10 其他 (61)4.10.1 阿尔山国家森林公园 (61)4.10.2 天津津南区水环境管理 (61)4.10.3 山东泰安山洪灾害防治 (61)4.10.4 山东日照山洪灾害防治 (62)4.10.5 国家防汛抗旱应急指挥 (62)4.10.6 北京马驹桥智慧城市 (62)4.10.7 国家海域动态监视监测管理 (63)图表目录图表1：B-TrunC产品认证的技术体系 (14)图表2：B-TrunC无线政务-重大活动保障 (23)图表3：B-TrunC公共安全-日常警务指挥 (25)图表4：B-TrunC港口解决方案 (39)图表5：B-TrunC港口-青岛港 (40)1 宽带集群通信市场发展1.1宽带集群通信的市场需求伴随移动互联网的飞速发展以及全球无线城市的大规模建设，宽带化已成为无线通信系统的总体发展趋势，集群通信系统也向着系统IP化、业务多样化、数据宽带化、终端多模化的方向发展。

●【业界新技术】下一代网络（NGN）标准简介（2003-07-17 通信世界）一、概念与定义NGN是Next Generation Network的缩写，字面意思是下一代网络。

当前所谓的下一代网络是一个很松散的概念。

因为不同的领域对下一代网络有不同的看法，所以尚没有公认的明确的定义。

此外，所谓下一代网络应当是在“这一代”网络基础上有突破性或者革命性进步才能称为“下一代”网络。

在计算机网络看来，这一代网络是以IPv4为基础的互联网，下一代网络是以高带宽以及IPv6为基础的NGI（下一代互联网）。

在传输网络看来，这一代网络是以TDM为基础，SDH以及WDM为代表的传输网络，下一代网络是ASON（自动交换光网络）以及GFP（通用帧协议）为基础。

在移动通信网络看来，这一代网络是以GSM为代表的网络，下一代网络是3G（第三代移动通信），以WCDMA以及CDMA2000为代表。

在电话网看来，这一代网络是以TDM时隙交换为基础的程控交换机组成的电话网络，下一代网络是指以分组交换和软交换为基础的电话网络。

在电信网络层以下所采用的核心技术来看，这一代网络是以TDM电路交换为基础的网络，下一代网络在网络层以下将以分组交换为基础构建。

总体来说，我们认为广义上的下一代网络是指以软交换为代表能够为公众大规模灵活提供视讯话音数据等多种通信业务，以分组交换为业务统一承载平台，传输层适应数据业务特征及带宽需求，与通信运营商相关，可运营、维护、管理的通信网络。

二、NGN分层由于通信网络庞大而复杂，网络通常分层描述。

如图1所示NGN可以分成业务层、业务承载层以及传输层。

*其中传输层主要提供点到点专线连接。

可以采用ASON等技术。

*业务承载层采用分组形式，提供寻址、复用以及路由交换功能。

*业务层基于业务承载层提供的分组服务，为用户提供实际的服务例如电话、视频会议、流媒体点播等，主要采用软交换方式提供。

三、NGN特征NGN主要特点是能够为公众大规模灵活提供以视讯业务为代表，包含话音业务互联网业务等。

1g到5g的发展历程英语作文The first generation of mobile communication, known as 1G, was a revolutionary step in the late 1980s. It laid the foundation for wireless communication, primarily offeringvoice calls and basic data services. The technology was rudimentary, with limited coverage and often poor reception.As we moved into the 1990s, 2G emerged, bringing with it the ability to send text messages and access the internet ata snail's pace. This era was marked by the first steps into mobile data, albeit with a user experience that was far from the smooth connectivity we enjoy today.The turn of the millennium saw the advent of 3G, a significant leap forward in mobile technology. It enabled faster internet speeds and the birth of mobile browsing and video calling. This generation was pivotal in the rise of smartphones, setting the stage for the mobile internet revolution.4G, introduced in the early 2010s, transformed the mobile landscape with its lightning-fast speeds and high-qualityvideo streaming capabilities. It was the catalyst for the widespread adoption of mobile applications and services, reshaping the way we communicate, work, and entertain ourselves.Now, as we stand on the brink of the 5G era, the promiseof near-instantaneous data transfer and ultra-reliable connectivity is upon us. 5G is expected to revolutionize industries, from healthcare to autonomous vehicles, by providing the backbone for the Internet of Things and smart cities.Each generation has built upon the last, with improvements in speed, capacity, and reliability. The progression from 1G to 5G is not just a story of technological advancement but also a narrative of human ingenuity and the relentless pursuit of a more connected world.Looking back, it's fascinating to see how mobile communication has evolved from a luxury to an indispensable part of our daily lives. The journey from 1G to 5G is a testament to the power of innovation and the potential for technology to transform society.As we embrace the possibilities of 5G, it's important to reflect on the past and consider the future. The next chapter in mobile communication is being written, and it's one that promises to be as exciting as the journey that has led us here.。

2023年统一通信（UC）行业市场环境分析随着人们对数字化的需求增加，统一通信（UC）在商业和企业市场中的需求也在迅速增长。

UC作为一种集成了多种通信方式并提供协同工作功能的解决方案，正在改变如何进行业务和企业交流的方式。

现在，让我们来看一下UC行业市场环境分析。

一.市场概览统一通信市场因其广泛的应用和快速增长的趋势而成为该行业中最具吸引力的市场之一。

据统计，截至2020年，全球UC市场收入达到484亿美元，预计到2026年将增长至1041亿美元，年复合增长率（CAGR）为12.6％。

该市场的推动力是数字化转型和云计算服务的广泛采用。

二.市场驱动因素1.云计算的普及：云端通信和记录在云端的信息可以让用户轻松访问和共享文件，从而为商业和企业提供了更高效和实时的协同工作体验。

2.移动设备的广泛使用：越来越多的员工使用移动设备从事工作，这促使企业采用综合通信解决方案以支持移动办公。

3.数字化转型的加速：统一通信作为数字化转型的重要组成部分，可以为企业提供智能的通信解决方案并推进数字化转型。

4.全球采用情况的增加：UC市场在全球的采用情况持续增长，特别是在发展中国家。

这为提供更多的解决方案和服务提供了重要的机会。

三.市场挑战1.安全问题：使用UC平台可能会引起隐私和数据安全问题。

2.不透明的成本结构：通常需要采用多种技术和服务来构建一个完整的UC解决方案，这使得成本结构不够透明，使企业难以预测实际成本。

3.互操作性难题：企业需要考虑如何将其现有的通信系统与新的UC系统集成起来，以确保信息流畅传输。

四.市场前景统一通信市场的未来前景看起来非常光明，特别是随着数字化转型和云计算服务的日益普及。

在未来几年内，UC解决方案将在企业和商业市场上得到广泛应用，并且可能成为通信发展的主导趋势。

此外，随着大量企业和组织的数字化转型趋势加快，市场需求将不断增加，从而推动UC市场的发展。

手机发展史1g~5g的英语作文The Evolution of Mobile Technology: From 1G to 5GThe world of mobile technology has undergone a remarkable transformation over the past few decades. Starting from the humble beginnings of 1G networks, the industry has evolved rapidly, introducing increasingly advanced generations of wireless communication systems. Each generation has brought about significant advancements, revolutionizing the way we connect, communicate, and access information. In this essay, we will explore the journey of mobile technology from 1G to 5G, highlighting the key features and developments that have shaped the industry.1G: The Dawn of Cellular CommunicationThe first generation of mobile networks, commonly known as 1G, was introduced in the early 1980s. This analog-based system provided basic voice communication capabilities, allowing users to make and receive calls on their mobile devices. 1G networks utilized advanced mobile phone systems (AMPS) and were primarily used for voice transmission. The technology was limited in its coverage and suffered from poor call quality, with frequent dropped calls and static interference. However, it laid the foundation for the futuredevelopment of mobile communication.2G: The Digital RevolutionThe 1990s ushered in the second generation of mobile networks, or 2G. This digital-based system marked a significant leap forward, introducing features such as text messaging, picture messaging, and basic internet connectivity. 2G networks, including Global System for Mobile (GSM) and Code Division Multiple Access (CDMA), offered improved call quality, better coverage, and increased security compared to their 1G predecessors. The introduction of digital encoding also allowed for more efficient use of the available spectrum, enabling the support of more users within a given geographical area.3G: The Smartphone EraThe early 2000s saw the emergence of the third generation of mobile networks, or 3G. This technology revolutionized the mobile landscape, paving the way for the widespread adoption of smartphones. 3G networks, such as Universal Mobile Telecommunications System (UMTS) and CDMA2000, provided significantly faster data speeds, enabling users to access the internet, stream multimedia content, and engage in video calling. The increased bandwidth and improved network performance transformed the way we interacted with our mobile devices, ushering in a new era of mobile computing and connectivity.4G: The Age of Broadband MobileThe fourth generation of mobile networks, or 4G, was introduced in the late 2000s and early 2010s. 4G networks, including Long-Term Evolution (LTE) and Worldwide Interoperability for Microwave Access (WiMAX), offered even faster data speeds, lower latency, and more reliable connections. This enabled users to enjoy seamless streaming, real-time video conferencing, and high-quality mobile gaming. The increased bandwidth and improved network performance also facilitated the growth of mobile-based applications and services, further enhancing the user experience.5G: The Future of Wireless CommunicationThe latest generation of mobile networks, 5G, has been hailed as the most transformative and disruptive technology in the history of mobile communication. Launched in the early 2010s, 5G networks offer unprecedented speeds, low latency, and increased capacity, revolutionizing the way we interact with our devices and the world around us. 5G technology utilizes advanced techniques such as millimeter-wave spectrum, massive MIMO (Multiple-Input, Multiple-Output), and beamforming to deliver lightning-fast data speeds, seamless connectivity, and enhanced reliability.The impact of 5G extends far beyond personal mobile devices. It has the potential to revolutionize various industries, including healthcare,transportation, manufacturing, and smart city infrastructure. The low latency and high bandwidth of 5G networks enable real-time data processing, remote control, and the implementation of sophisticated IoT (Internet of Things) applications. This paves the way for advancements in telemedicine, autonomous vehicles, industrial automation, and smart city initiatives, transforming the way we live, work, and interact with our environment.Moreover, 5G technology is poised to support the growth of emerging technologies such as virtual reality (VR), augmented reality (AR), and cloud gaming. The high-speed and low-latency characteristics of 5G networks can provide an immersive and seamless experience for users, unlocking new possibilities in entertainment, education, and various other domains.In conclusion, the evolution of mobile technology from 1G to 5G has been a remarkable journey, marked by significant advancements in connectivity, speed, and functionality. Each generation has built upon the successes and lessons of its predecessors, ultimately shaping the way we communicate, access information, and interact with the world around us. As we continue to witness the rapid progress of mobile technology, it is clear that the future holds even more exciting and transformative possibilities, revolutionizing the way we live, work, and experience the world.。

网络1g到5g的发展英语作文The Evolution of Wireless Network Technology: From 1G to 5GThe world of communication has undergone a remarkable transformation over the past few decades, driven by the rapid advancements in wireless network technology. From the humble beginnings of the first-generation (1G) cellular networks to the cutting-edge fifth-generation (5G) systems, the evolution of wireless networks has revolutionized the way we connect, communicate, and access information. This essay will explore the journey of wireless network technology, its progression from 1G to 5G, and the profound impact it has had on our lives.The First Generation (1G) of wireless networks, introduced in the 1980s, marked the initial step towards the modern era of mobile communication. These analog systems, primarily designed for voice communication, were limited in their capabilities and offered low-quality connections. The 1G networks, such as the Advanced Mobile Phone System (AMPS) in the United States, were primarily focused on providing basic voice services and had a limited capacity to handle the growing demand for mobile communication.The Second Generation (2G) of wireless networks, which emerged in the early 1990s, brought about a significant leap in technology. These digital systems, including the Global System for Mobile Communications (GSM) and Code Division Multiple Access (CDMA), not only improved voice quality but also introduced the capability for text messaging, commonly known as SMS (Short Message Service). The 2G networks laid the foundation for the integration of data services, paving the way for the emergence of more advanced applications and the proliferation of mobile devices.The Third Generation (3G) of wireless networks, introduced in the early 2000s, represented a major advancement in mobile technology. These networks, such as the Universal Mobile Telecommunications System (UMTS) and CDMA2000, offered significantly higher data transfer rates, enabling the widespread adoption of multimedia applications, mobile internet, and video calling. The 3G era witnessed the rise of smartphones, which revolutionized the way we interacted with our mobile devices, allowing for seamless access to a vast array of online services and content.The Fourth Generation (4G) of wireless networks, which emerged in the late 2000s, further elevated the capabilities of mobile communication. 4G technologies, such as Long-Term Evolution (LTE) and WiMAX, provided even faster data speeds, improved network reliability, and enhanced support for multimedia applications. The 4Gnetworks paved the way for the widespread adoption of streaming services, real-time video communication, and the proliferation of mobile applications that transformed various aspects of our lives, from entertainment to productivity.The Fifth Generation (5G) of wireless networks, the latest and most advanced iteration, is now being rolled out globally. 5G promises to deliver unprecedented levels of speed, low latency, and increased capacity, revolutionizing the way we interact with the digital world. This new generation of networks is designed to support a wide range of applications, from high-definition video streaming and cloud gaming to the Internet of Things (IoT) and autonomous vehicles. The ultra-fast data speeds and low latency of 5G networks enable the development of innovative technologies that were previously unimaginable, such as remote healthcare, smart cities, and industrial automation.The evolution of wireless network technology has had a profound impact on our lives. From the simple voice calls of the 1G era to the seamless, data-rich experiences of 5G, the progression of wireless networks has transformed the way we communicate, access information, and interact with the digital world. The increased connectivity and data capabilities have enabled the rise of various industries, such as e-commerce, social media, and cloud computing, significantly shaping the way we live, work, and entertain ourselves.Moreover, the advancements in wireless network technology have played a crucial role in the development of emerging technologies, such as the Internet of Things, artificial intelligence, andvirtual/augmented reality. These innovative applications, enabled by the enhanced capabilities of 5G and beyond, have the potential to revolutionize various sectors, including healthcare, transportation, and smart city infrastructure.In conclusion, the evolution of wireless network technology from 1G to 5G has been a remarkable journey, marked by continuous advancements and the transformation of the way we connect and communicate. Each generation of wireless networks has brought about significant improvements in speed, capacity, and functionality, paving the way for new and innovative applications that have profoundly impacted our personal and professional lives. As we look to the future, the ongoing development of wireless network technology promises to continue shaping the digital landscape and ushering in a new era of unprecedented connectivity and technological progress.。

全球5G进展简报--内部参考2020年2月14日一、NSA/SA标准情况1.RAN标准进展1.13GPP R15标准已完成标准制定3GPP R15协议的功能部分于2019年6月份冻结，2019年9月和12月全会完成RAN4性能规范，R15协议已经完全冻结。

⏹功能协议（Core Part）−NSA和SA协议功能；−2019年6月ASN.1完成。

⏹性能协议（Performance Part）−制定基站解调性能，终端RRM和解调性能的协议；−2019年12月制定完成基站和终端性能要求。

图13GPP R15三个阶段协议制定周期1.23GPP R16标准进展图23GPP R16标准制定周期3GPP R16标准与R15标准并行制定，R16重点制定垂直行业应用技术和eMBB性能提升技术。

⏹R16功能协议将于2020年3月份全会冻结，2020年6月份冻结ASN.1−R16阶段重点项目5G V2X，工业IoT和URLLC增强，非授权频谱技术；−R16阶段性能增强，支持定位功能，MIMO增强，功耗优化等技术；−由于R16研究周期较短，大部分立项课题都无法完成原定研究内容，2019年9月和12月两次全会激烈讨论，R16课题研究内容进行删减，部分研究内容将在R17阶段继续完成。

⏹R16性能协议将于2020年9月份全会完成−2020年3月至9月，3GPP主要制定R16性能相关协议，制定基站、终端的解调能力，RRM性能等相关的规范；R16规范新增功能特性：⏹URLLC物理层增强项目：改进控制信道和控制信令设计，增强上行数据信道传输可靠性，设计上行数据信道多用户复用机制，支持减少传输时延的免授权调度机制等。

由于R16规范制定周期较短，部分研究工作将在R17继续完善。

⏹工业互联网技术项目：该项目基于NR空口技术，支持自动化工厂、运输、电力等行业应用。

该研究课题从PDCP、Qos调度等协议优化提供高可靠性传输，对于时延敏感业务增强技术。

行业周报高通财报发布，十四五强化国家战略科技力量电子2020年11月08日强于大市（维持）行情走势图相关研究报告《行业周报*电子*苹果财报发布，持续关注面板上行周期》 2020-11-01 《行业周报*电子*华为Mate40系列发布，海力士收购英特尔存储业务》 2020-10-25《行业周报*电子*台积电三季报发布，苹果新机上市》 2020-10-19 《行业点评*电子*苹果新品发布会：iPhone 12系列发布，5G 起航》 2020-10-14《行业周报*电子*中芯国际回应限制升级，关注电视面板涨价》 2020-10-11证券分析师刘舜逢 投资咨询资格编号 S1060514060002 **************************************.CN徐勇 投资咨询资格编号 S1060519090004 *********************************.CN研究小程序⏹ 行业动态：1）高通财报发布：高通发布2020财年第四季度（对应中国会计期间2020第三季度）业绩报告，第四季度营收83.46亿美元，同比增长73%，净利润29.6亿美元，同比增长485%。

分业务来看，手机基带芯片业务（QCT ）和技术许可业务（QTL ）仍然是营收的主力军。

高通第四财季手机基带业务实现营收49.67亿美元，同比增长38%；高通技术许可业务（QTL ）营收15.07亿美元，同比增长30%。

1）智能手机是基带出货量的主要驱动力，2014-2019年随着华为和三星自研Soc 的占比增加，苹果转用英特尔基带芯片，高通、MTK 的份额出现下降；2）2020年随着苹果和高通和解，苹果iPhone 12的推出带动了高通基带芯片的销售。

2）十四五强化国家战略科技力量：11月3日，《中共中央关于制定国民经济和社会发展第十四个五年规划和二〇三五年远景目标的建议》全文公布。

《建议》中明确提出，强化国家战略科技力量。

第1篇摘要：高通公司作为全球领先的无线通信技术供应商，其在中国市场的表现一直备受关注。

本文将对高通中国区的财务报告进行深入分析，旨在揭示其在中国市场的财务状况、盈利能力、市场表现以及未来发展趋势。

一、财务报告概述高通中国区的财务报告主要包括收入、利润、现金流等关键财务指标。

以下是对高通中国区财务报告的概述：1. 收入：高通中国区的收入主要来自手机芯片、网络基础设施、软件和服务等多个领域。

近年来，随着5G技术的推广和应用，高通中国区的收入持续增长。

2. 利润：高通中国区的利润主要来自手机芯片的销售，尤其是在高端手机市场。

然而，受到市场竞争和成本上升等因素的影响，利润率有所下降。

3. 现金流：高通中国区的现金流状况良好，主要得益于稳定的收入和有效的成本控制。

二、收入分析1. 手机芯片收入：高通中国区的手机芯片收入是公司收入的主要来源。

近年来，随着智能手机市场的持续增长，手机芯片收入保持了稳定增长。

2. 网络基础设施收入：高通中国区的网络基础设施收入主要来自4G和5G网络设备。

随着5G技术的推广，网络基础设施收入有望实现快速增长。

3. 软件和服务收入：高通中国区的软件和服务收入主要包括授权费和咨询费等。

随着5G技术的应用，软件和服务收入有望实现快速增长。

三、利润分析1. 手机芯片利润：高通中国区的手机芯片利润主要来自高端手机市场。

然而，受到市场竞争和成本上升等因素的影响，手机芯片利润率有所下降。

2. 网络基础设施利润：高通中国区的网络基础设施利润主要来自4G和5G网络设备。

随着5G技术的推广，网络基础设施利润有望实现快速增长。

3. 软件和服务利润：高通中国区的软件和服务利润主要来自授权费和咨询费等。

随着5G技术的应用，软件和服务利润有望实现快速增长。

四、市场表现分析1. 市场份额：高通中国区在手机芯片市场拥有较高的市场份额，尤其在高端手机市场。

然而，随着中国本土芯片厂商的崛起，高通的市场份额面临挑战。