荷马先生
11-25
Google说还没有下单,急什么急,没出息
一文读懂“谷歌链”:AI全栈式创新,TPU+OCS共塑下一代智算网络
免责声明:上述内容仅代表发帖人个人观点,不构成本平台的任何投资建议。
分享至
微信
复制链接
精彩评论
我们需要你的真知灼见来填补这片空白
打开APP,发表看法
APP内打开
发表看法
{"i18n":{"language":"zh_CN"},"detailType":1,"isChannel":false,"data":{"magic":2,"id":504032959164752,"tweetId":"504032959164752","gmtCreate":1764064550001,"gmtModify":1764064552380,"author":{"id":3570605047103152,"idStr":"3570605047103152","authorId":3570605047103152,"authorIdStr":"3570605047103152","name":"荷马先生","avatar":"https://static.tigerbbs.com/1d69283377af06639e7c3544aa273e68","vip":1,"userType":1,"introduction":"","boolIsFan":false,"boolIsHead":false,"crmLevel":1,"crmLevelSwitch":1,"individualDisplayBadges":[],"fanSize":12,"starInvestorFlag":false},"themes":[],"images":[],"coverImages":[],"title":"","html":"<html><head></head><body><p>Google说还没有下单,急什么急,没出息</p></body></html>","htmlText":"<html><head></head><body><p>Google说还没有下单,急什么急,没出息</p></body></html>","text":"Google说还没有下单,急什么急,没出息","highlighted":1,"essential":1,"paper":1,"likeSize":0,"commentSize":0,"repostSize":0,"favoriteSize":0,"link":"https://laohu8.com/post/504032959164752","repostId":2586879428,"repostType":4,"repost":{"id":"2586879428","kind":"highlight","weMediaInfo":{"introduction":"追踪全球财经热点,精选影响您财富的资讯,投资理财必备神器!","home_visible":1,"media_name":"华尔街见闻","id":"1084101182","head_image":"https://static.tigerbbs.com/66809d1f5c2e43e2bdf15820c6d6897e"},"pubTimestamp":1764059977,"share":"https://www.laohu8.com/m/news/2586879428?lang=zh_CN&edition=full","pubTime":"2025-11-25 16:39","market":"sh","language":"zh","title":"一文读懂“谷歌链”:AI全栈式创新,TPU+OCS共塑下一代智算网络","url":"https://stock-news.laohu8.com/highlight/detail?id=2586879428","media":"华尔街见闻","summary":"中泰证券认为,本轮“谷歌链”爆发的关键技术变量在于OCS光交换技术的全面引入。本质上是用物理光路直接传输数据,彻底抛弃了“光—电—光”的信号转换过程。通过深度整合自研TPU芯片与OCS(光电路交换机)技术,谷歌不仅突破了传统数据中心的能效与扩展瓶颈,更为下一代智算网络确立了新的架构标准。谷歌已围绕芯片(TPU)—网络(OCS)—模型(Gemini)—应用(云计算/搜索/广告等)全栈优势构筑AI护城河。","content":"<html><head></head><body><p>在AI军备竞赛日益白热化的背景下,<a href=\"https://laohu8.com/S/GOOG\">谷歌</a>正凭借其从芯片到网络的“全栈式”创新构筑独特的算力护城河。</p><p>在<a href=\"https://laohu8.com/S/600918\">中泰证券</a>看来,这一轮“谷歌链”爆发的关键技术变量在于OCS光交换技术的全面引入。通过深度整合自研TPU芯片与OCS(光电路交换机)技术,谷歌不仅突破了传统数据中心的能效与扩展瓶颈,更为下一代智算网络确立了新的架构标准。</p><p>TPU与OCS的深度耦合,不仅支撑了Gemini等大模型的高效迭代,也直接带动了上游光模块(特别是1.6T)、MEMS芯片、光器件等产业链环节的增量需求。AI数据中心正从静态架构向动态光子互联演进。</p><p class=\"t-img-caption\"><img src=\"https://community-static.tradeup.com/news/22dd80a7200875634ac7e26a556be416\" tg-width=\"1318\" tg-height=\"263\"/></p><h2 id=\"id_645066037\">TPU v7“Ironwood”放量:ASIC市场的主导力量</h2><p>中泰证券认为,<a href=\"https://laohu8.com/S/GOOGL\">谷歌A</a>I已围绕芯片(TPU)—网络(OCS)—模型(Gemini)—应用(云计算/搜索/广告等)全栈优势构筑护城河。</p><p>从2011年谷歌成立谷歌大脑 (Google Brain)实验室开始涉足AI开始,一系列具有影响力的AI研究相继问世,包括2017年发布Transformer架构到2023年推出多模态大模型Gemini,目前已形成从芯片到集群架构到大模型再到应用端的布局,谷歌将AI逐步整合到多元业务流程中,这些业务为谷歌获取了<a href=\"https://laohu8.com/S/603138\">海量数据</a>,用于训练完善AI。</p><p>分析师强调,<strong>谷歌自研芯片的跨越式发展是其算力战略的核心。</strong></p><p>即将全面上市的TPU v7(Ironwood)在性能上实现了质的飞跃,单芯片计算能力较上一代TPU v5p提升超过十倍,峰值带宽达7.4 TB/s。</p><p>在集群架构上,Ironwood继续沿用且优化了3D Torus(三维环面)拓扑结构。该架构允许将多个“4×4×4”的立方体构建块动态组合,单集群规模可扩展至9216颗芯片。为<strong>了匹配这一极高的算力密度,TPU v7开始配置1.6T光模块,这也带动了市场对高速光模块需求的预期上修。</strong></p><p class=\"t-img-caption\"><img src=\"https://community-static.tradeup.com/news/8d66ead2b02cb9ca1f149b4ca41a9e71\" tg-width=\"1573\" tg-height=\"588\"/></p><p><strong>供应链调研指出,2026年谷歌TPU将成为全球自研ASIC市场的主力,预计出货量远高于AWS Trainium或Microsoft Maia等竞品。随着<a href=\"https://laohu8.com/S/NVDA\">英伟达</a>GB200与谷歌TPU v7的双重拉动,2026年行业1.6T光模块需求有望上修至2000万只以上。</strong></p><p class=\"t-img-caption\"><img src=\"https://community-static.tradeup.com/news/c77cb83d19af7d01f492810c883f623c\" tg-width=\"1024\" tg-height=\"350\"/></p><h2 id=\"id_3408044160\">OCS:打破传统电交换瓶颈的关键技术</h2><p>中泰证券表示,<strong>谷歌在AI数据中心大规模引入OCS(光电路交换机)的核心逻辑在于解决大规模扩展(Scale-Out)带来的功耗与效率难题。</strong></p><p>传统数据中心架构正在失效。在传统Clos架构中,随着算力集群规模指数级扩张,基于电信号的分组交换机(EPS)面临着严重的功耗散热问题和昂贵的布线成本。<strong>据Cisco测算,数据中心交换系统的总功耗在过去十余年间提升了22倍。</strong></p><p><strong>谷歌引入OCS,本质上是用物理光路直接传输数据,彻底抛弃了“光—电—光”的信号转换过程。</strong></p><p>这其中,OCS是实现服务器解耦(Server Disaggregation)的关键,它允许计算资源跨机架动态编排,像搭积木一样组合算力,从而突破了静态机架的资源浪费瓶颈。在Ironwood集群中,48台OCS交换机连接了9216个TPU芯片,构建了一个低延迟、高带宽的动态光子网络。</p><p class=\"t-img-caption\"><img src=\"https://community-static.tradeup.com/news/6b3e33d0d1457a0c2d0be835df9c4d8f\" tg-width=\"740\" tg-height=\"354\"/></p><p>数据证明了这一技术路线的优越性:<strong>引入OCS定制化网络后,谷歌网络的吞吐量提升了30%,功耗降低了40%,网络宕机时间减少了50倍,最关键的是,它让资本开支减少了30%。</strong></p><p class=\"t-img-caption\"><img src=\"https://community-static.tradeup.com/news/ded48346a0435ddce8a6f92992fa25e0\" tg-width=\"1024\" tg-height=\"408\"/></p><h2 id=\"id_3899894281\">解构谷歌OCS:独特的MEMS技术与定制光器件价值</h2><p>中泰证券表示,理解“谷歌链”的投资价值,必须理解OCS的物理构成。</p><p>目前谷歌主流的Palomar OCS基于MEMS(微机电系统)方案,拥有136个光路通道(实际使用128路)。其核心工作原理是通过2D MEMS微镜阵列反射光信号,实现毫秒级的光路切换,无需光收发器进行电信号转换。</p><p class=\"t-img-caption\"><img src=\"https://community-static.tradeup.com/news/323818e7cb4e9ba64d2f47146605ddad\" tg-width=\"1024\" tg-height=\"429\"/></p><p>这套系统带来了一系列独特的硬件需求。</p><p>首先是定制光模块,谷歌在光模块中内置了环形器(Circulator),实现了单根光纤的双向传输,这使得所需的端口和光缆数量不仅比传统胖树架构减少了40%,还创造了环形器这一增量市场。</p><p>其次是核心光学元件,包括MEMS阵列、准直器、2D透镜阵列等,这些精密光学元器件的单机价值量极高。此外,虽然谷歌目前主推MEMS方案,但也正在探索液晶、压电陶瓷和硅光波导等新技术路径,为供应链上的技术创新者提供了潜在的入局机会。</p><p class=\"t-img-caption\"><img src=\"https://community-static.tradeup.com/news/5c9e1253661a8d67a5a0f55ae29ab37c\" tg-width=\"1024\" tg-height=\"339\"/></p><p>OCS技术的崛起为光通信产业链带来了全新的增量环节。随着<a href=\"https://laohu8.com/S/MSFT\">微软</a>、<a href=\"https://laohu8.com/S/META\">Meta</a>等其他云服务商也开始探索OCS应用,Lightcounting预测2024-2029年OCS市场将以28%的复合增速增长,行业正迎来技术与需求的双重爆发期。</p><p class=\"t-img-caption\"><img src=\"https://community-static.tradeup.com/news/37c5c90bcd64f66787a9b18a2bfa699e\" tg-width=\"1024\" tg-height=\"306\"/></p></body></html>","collect":0,"html":"<!DOCTYPE html>\n<html>\n<head>\n<meta http-equiv=\"Content-Type\" content=\"text/html; charset=utf-8\" />\n<meta name=\"viewport\" content=\"width=device-width,initial-scale=1.0,minimum-scale=1.0,maximum-scale=1.0,user-scalable=no\"/>\n<meta name=\"format-detection\" content=\"telephone=no,email=no,address=no\" />\n<title>一文读懂“谷歌链”:AI全栈式创新,TPU+OCS共塑下一代智算网络</title>\n<style type=\"text/css\">\na,abbr,acronym,address,applet,article,aside,audio,b,big,blockquote,body,canvas,caption,center,cite,code,dd,del,details,dfn,div,dl,dt,\nem,embed,fieldset,figcaption,figure,footer,form,h1,h2,h3,h4,h5,h6,header,hgroup,html,i,iframe,img,ins,kbd,label,legend,li,mark,menu,nav,\nobject,ol,output,p,pre,q,ruby,s,samp,section,small,span,strike,strong,sub,summary,sup,table,tbody,td,tfoot,th,thead,time,tr,tt,u,ul,var,video{ font:inherit;margin:0;padding:0;vertical-align:baseline;border:0 }\nbody{ font-size:16px; line-height:1.5; color:#999; background:transparent; }\n.wrapper{ overflow:hidden;word-break:break-all;padding:10px; }\nh1,h2{ font-weight:normal; line-height:1.35; margin-bottom:.6em; }\nh3,h4,h5,h6{ line-height:1.35; margin-bottom:1em; }\nh1{ font-size:24px; }\nh2{ font-size:20px; }\nh3{ font-size:18px; }\nh4{ font-size:16px; }\nh5{ font-size:14px; }\nh6{ font-size:12px; }\np,ul,ol,blockquote,dl,table{ margin:1.2em 0; }\nul,ol{ margin-left:2em; }\nul{ list-style:disc; }\nol{ list-style:decimal; }\nli,li p{ margin:10px 0;}\nimg{ max-width:100%;display:block;margin:0 auto 1em; }\nblockquote{ color:#B5B2B1; border-left:3px solid #aaa; padding:1em; }\nstrong,b{font-weight:bold;}\nem,i{font-style:italic;}\ntable{ width:100%;border-collapse:collapse;border-spacing:1px;margin:1em 0;font-size:.9em; }\nth,td{ padding:5px;text-align:left;border:1px solid #aaa; }\nth{ font-weight:bold;background:#5d5d5d; }\n.symbol-link{font-weight:bold;}\n/* header{ border-bottom:1px solid #494756; } */\n.title{ margin:0 0 8px;line-height:1.3;color:#ddd; }\n.meta {color:#5e5c6d;font-size:13px;margin:0 0 .5em; }\na{text-decoration:none; color:#2a4b87;}\n.meta .head { display: inline-block; overflow: hidden}\n.head .h-thumb { width: 30px; height: 30px; margin: 0; padding: 0; border-radius: 50%; float: left;}\n.head .h-content { margin: 0; padding: 0 0 0 9px; float: left;}\n.head .h-name {font-size: 13px; color: #eee; margin: 0;}\n.head .h-time {font-size: 11px; color: #7E829C; margin: 0;line-height: 11px;}\n.small {font-size: 12.5px; display: inline-block; transform: scale(0.9); -webkit-transform: scale(0.9); transform-origin: left; -webkit-transform-origin: left;}\n.smaller {font-size: 12.5px; display: inline-block; transform: scale(0.8); -webkit-transform: scale(0.8); transform-origin: left; -webkit-transform-origin: left;}\n.bt-text {font-size: 12px;margin: 1.5em 0 0 0}\n.bt-text p {margin: 0}\n</style>\n</head>\n<body>\n<div class=\"wrapper\">\n<header>\n<h2 class=\"title\">\n一文读懂“谷歌链”:AI全栈式创新,TPU+OCS共塑下一代智算网络\n</h2>\n\n<h4 class=\"meta\">\n\n\n2025-11-25 16:39 北京时间 <a href=https://wallstreetcn.com/articles/3760084><strong>华尔街见闻</strong></a>\n\n\n</h4>\n\n</header>\n<article>\n<div>\n<p>在AI军备竞赛日益白热化的背景下,谷歌正凭借其从芯片到网络的“全栈式”创新构筑独特的算力护城河。在中泰证券看来,这一轮“谷歌链”爆发的关键技术变量在于OCS光交换技术的全面引入。通过深度整合自研TPU芯片与OCS(光电路交换机)技术,谷歌不仅突破了传统数据中心的能效与扩展瓶颈,更为下一代智算网络确立了新的架构标准。TPU与OCS的深度耦合,不仅支撑了Gemini等大模型的高效迭代,也直接带动了上游...</p>\n\n<a href=\"https://wallstreetcn.com/articles/3760084\">网页链接</a>\n\n</div>\n\n\n</article>\n</div>\n</body>\n</html>\n","type":0,"thumbnail":"https://static.tigerbbs.com/69bda624dad1064625bad9c30f3beafa","relate_stocks":{"LU0353189763.USD":"ALLSPRING US ALL CAP GROWTH FUND \"I\" (USD) ACC","LU2242650005.HKD":"FIDELITY FUNDS GLOBAL MULTI ASSET DYNAMIC \"A\" (HKD) ACC","LU0149725797.USD":"汇丰美国股市经济规模基金","LU2471134952.CNY":"INVESCO GLOBAL EQUITY INCOME ADVANTAGE \"A\" (CNYHDG) INC","IE00BHPRN162.USD":"BNY MELLON BLOCKCHAIN INNOVATION \"B\" (USD) ACC","IE00BK4W5L77.USD":"HSBC GLOBAL FUNDS ICAV US EQUITY INDEX \"HC\" (USD) ACC","LU1235294995.USD":"FIDELITY GLOBAL TECHNOLOGY \"A\" (USDHDG) ACC","GOOGL":"谷歌A","GB00B4QBRK32.GBP":"FUNDSMITH EQUITY \"R\" (GBP) INC","LU2471134879.HKD":"INVESCO GLOBAL EQUITY INCOME ADVANTAGE \"A\" (HKD) INC","LU0965509101.SGD":"AB LOW VOLATILITY EQUITY PORTFOLIO \"A\" (SGDHDG) ACC","IE00BFMHRM44.USD":"NEUBERGER BERMAN GLOBAL EQUITY MEGATRENDS \"A\" (USD) ACC","LU0130517989.USD":"HARRIS ASSOCIATES US VALUE EQUITY \"R\" INC","IE00B19Z3B42.SGD":"Legg Mason ClearBridge - Value A Acc SGD","IE00B19Z8X17.USD":"FTGF CLEARBRIDGE US LARGE CAP GROWTH \"AG\" (USD) ACC","LU2168564065.EUR":"AZ ALLOCATION - TREND \"AAZ\" (EUR) ACC","GOOG":"谷歌","LU1280957306.USD":"THREADNEEDLE (LUX) US CONTRARIAN CORE EQUITIES \"AUP\" (USD) INC","IE00BQXX3C00.GBP":"GUINNESS GLOBAL INNOVATORS \"C\" (GBP) ACC","LU0096364046.USD":"CT (LUX) I AMERICAN \"DU\" (USD) ACC","LU1221951046.USD":"NORDEA 1 STABLE RETURN \"HM\" (USDHDG) INC","IE0002270589.USD":"LEGG MASON CLEARBRIDGE VALUE \"A\" (USD) INC","LU0868494617.USD":"UBS (LUX) EQUITY SICAV - US TOTAL YIELD SUSTAINABLE \"P\" (USD) ACC","LU0957808578.USD":"THREADNEEDLE (LUX) GLOBAL TECHNOLOGY \"ZU\" (USD) ACC","IE00BYQQ9H92.USD":"BNY MELLON GLOBAL LEADERS \"A\" (USD) ACC","LU2271345857.HKD":"ALLIANZ GLOBAL SUSTAINABILITY \"AT\" (HKD) ACC","LU1778281490.HKD":"HSBC GIF GLOBAL LOWER CARBON EQUITY \"AD\" (HKD) INC","LU2125154935.USD":"ALLSPRING (LUX) WF GLOBAL EQUITY ENHANCED INCOME \"I\" (USD) INC","LU1221951129.SGD":"NORDEA 1 STABLE RETURN \"HM\" (SGDHDG) INC","LU2750360997.AUD":"INVESCO GLOBAL EQUITY INCOME ADVANTAGE \"A\" (AUDHDG) INC","LU1894683264.USD":"AMUNDI FUNDS US EQUITY RESEARCH VALUE \"A2\" (USD) ACC","BK4612":"AI芯片","LU2191332357.HKD":"SCHRODER ISF SUSTAINABLE MULTI-ASSET INCOME \"A\" (HKDHDG) INC","LU0203345920.USD":"SCHRODER ISF QEP GLB ACT. VL \"A\" (USD) ACC","LU0354030438.USD":"富国美国大盘成长基金Cl A Acc","LU0345768153.USD":"NINETY ONE GSF GLOBAL STRATEGIC MANAGED \"A\" (USD) ACC","IE00BWXC8680.SGD":"PINEBRIDGE US LARGE CAP RESEARCH ENHANCED \"A5\" (SGD) ACC","LU1585245621.USD":"EASTSPRING INV GLOBAL LOW VOLATILITY EQUITY FUND \"A\" (USD) ACC B","LU1153585028.USD":"BGF GLOBAL LONG-HORIZON EQUITY \"A4\" (USD) INC","LU1803068979.SGD":"FTIF - Franklin Technology A (acc) SGD-H1","LU2236285917.USD":"ALLIANZ GLOBAL INCOME \"AMG\" (USD) INC","SG9999014898.SGD":"United Global Quality Growth Fund Dis SGD","LU2023250843.SGD":"Allianz Thematica Cl AT Acc H2-SGD","IE0004086264.USD":"BNY MELLON GLOBAL OPPORTUNITIES \"A\" (USD) ACC","LU1059921491.USD":"NORDEA 1 GLOBAL STABLE EQUITY \"HB\" (USDHDG) ACC","LU0672654240.SGD":"FTIF - Franklin US Opportunities A Acc SGD-H1","BK4573":"虚拟现实","SG9999015952.SGD":"LIONGLOBAL DISRUPTIVE INNOVATION \"I\" (SGD) ACC"},"source_url":"https://wallstreetcn.com/articles/3760084","is_english":false,"share_image_url":"https://static.laohu8.com/e9f99090a1c2ed51c021029395664489","article_id":"2586879428","content_text":"在AI军备竞赛日益白热化的背景下,谷歌正凭借其从芯片到网络的“全栈式”创新构筑独特的算力护城河。在中泰证券看来,这一轮“谷歌链”爆发的关键技术变量在于OCS光交换技术的全面引入。通过深度整合自研TPU芯片与OCS(光电路交换机)技术,谷歌不仅突破了传统数据中心的能效与扩展瓶颈,更为下一代智算网络确立了新的架构标准。TPU与OCS的深度耦合,不仅支撑了Gemini等大模型的高效迭代,也直接带动了上游光模块(特别是1.6T)、MEMS芯片、光器件等产业链环节的增量需求。AI数据中心正从静态架构向动态光子互联演进。TPU v7“Ironwood”放量:ASIC市场的主导力量中泰证券认为,谷歌AI已围绕芯片(TPU)—网络(OCS)—模型(Gemini)—应用(云计算/搜索/广告等)全栈优势构筑护城河。从2011年谷歌成立谷歌大脑 (Google Brain)实验室开始涉足AI开始,一系列具有影响力的AI研究相继问世,包括2017年发布Transformer架构到2023年推出多模态大模型Gemini,目前已形成从芯片到集群架构到大模型再到应用端的布局,谷歌将AI逐步整合到多元业务流程中,这些业务为谷歌获取了海量数据,用于训练完善AI。分析师强调,谷歌自研芯片的跨越式发展是其算力战略的核心。即将全面上市的TPU v7(Ironwood)在性能上实现了质的飞跃,单芯片计算能力较上一代TPU v5p提升超过十倍,峰值带宽达7.4 TB/s。在集群架构上,Ironwood继续沿用且优化了3D Torus(三维环面)拓扑结构。该架构允许将多个“4×4×4”的立方体构建块动态组合,单集群规模可扩展至9216颗芯片。为了匹配这一极高的算力密度,TPU v7开始配置1.6T光模块,这也带动了市场对高速光模块需求的预期上修。供应链调研指出,2026年谷歌TPU将成为全球自研ASIC市场的主力,预计出货量远高于AWS Trainium或Microsoft Maia等竞品。随着英伟达GB200与谷歌TPU v7的双重拉动,2026年行业1.6T光模块需求有望上修至2000万只以上。OCS:打破传统电交换瓶颈的关键技术中泰证券表示,谷歌在AI数据中心大规模引入OCS(光电路交换机)的核心逻辑在于解决大规模扩展(Scale-Out)带来的功耗与效率难题。传统数据中心架构正在失效。在传统Clos架构中,随着算力集群规模指数级扩张,基于电信号的分组交换机(EPS)面临着严重的功耗散热问题和昂贵的布线成本。据Cisco测算,数据中心交换系统的总功耗在过去十余年间提升了22倍。谷歌引入OCS,本质上是用物理光路直接传输数据,彻底抛弃了“光—电—光”的信号转换过程。这其中,OCS是实现服务器解耦(Server Disaggregation)的关键,它允许计算资源跨机架动态编排,像搭积木一样组合算力,从而突破了静态机架的资源浪费瓶颈。在Ironwood集群中,48台OCS交换机连接了9216个TPU芯片,构建了一个低延迟、高带宽的动态光子网络。数据证明了这一技术路线的优越性:引入OCS定制化网络后,谷歌网络的吞吐量提升了30%,功耗降低了40%,网络宕机时间减少了50倍,最关键的是,它让资本开支减少了30%。解构谷歌OCS:独特的MEMS技术与定制光器件价值中泰证券表示,理解“谷歌链”的投资价值,必须理解OCS的物理构成。目前谷歌主流的Palomar OCS基于MEMS(微机电系统)方案,拥有136个光路通道(实际使用128路)。其核心工作原理是通过2D MEMS微镜阵列反射光信号,实现毫秒级的光路切换,无需光收发器进行电信号转换。这套系统带来了一系列独特的硬件需求。首先是定制光模块,谷歌在光模块中内置了环形器(Circulator),实现了单根光纤的双向传输,这使得所需的端口和光缆数量不仅比传统胖树架构减少了40%,还创造了环形器这一增量市场。其次是核心光学元件,包括MEMS阵列、准直器、2D透镜阵列等,这些精密光学元器件的单机价值量极高。此外,虽然谷歌目前主推MEMS方案,但也正在探索液晶、压电陶瓷和硅光波导等新技术路径,为供应链上的技术创新者提供了潜在的入局机会。OCS技术的崛起为光通信产业链带来了全新的增量环节。随着微软、Meta等其他云服务商也开始探索OCS应用,Lightcounting预测2024-2029年OCS市场将以28%的复合增速增长,行业正迎来技术与需求的双重爆发期。","news_type":1,"symbols_score_info":{"GOOGL":1.5,"GOOG":1.5}},"isVote":1,"tweetType":1,"viewCount":321,"commentLimit":10,"likeStatus":false,"favoriteStatus":false,"reportStatus":false,"symbols":[],"verified":2,"subType":0,"readableState":1,"langContent":"CN","currentLanguage":"CN","warmUpFlag":false,"orderFlag":false,"shareable":true,"causeOfNotShareable":"","featuresForAnalytics":[],"commentAndTweetFlag":false,"andRepostAutoSelectedFlag":false,"upFlag":false,"length":34,"optionInvolvedFlag":false,"xxTargetLangEnum":"ZH_CN"},"commentList":[],"isCommentEnd":true,"isTiger":false,"isWeiXinMini":false,"url":"/m/post/504032959164752"}
精彩评论