谷歌測試通過壓電陶瓷（DLBS）OCS 技術，突破 AI 集羣光交換性能瓶頸

IT之家

09/19

近日，谷歌在光路交換機（OCS）技術領域取得新進展，正積極測試基於壓電陶瓷（DLBS）的 OCS 方案，以優化其 AI 超算集羣的網絡性能。壓電陶瓷技術憑藉光路直接傳輸無反射損耗、切換時延低至毫秒級等優勢，成爲繼 MEMS 和數字液晶（DLC）後的重要技術路線。

據行業分析，壓電陶瓷 OCS 的系統損耗最低、切換速度最快，尤其適合高穩定性的 AI 集羣互聯場景。且其兼具正逆壓電效應，能高效實現光電信號轉換，擁有低能耗、無電磁噪音、壽命長，適配嚴苛工作環境等優勢。谷歌 TPUv4 / v7 集羣已採用 OCS 構建 3D 環面網絡，若壓電陶瓷方案成熟，有望進一步降低功耗並提升萬卡級組網效率。此次測試或加速壓電陶瓷在超大規模 GPU 互聯中的應用，推動數據中心效能升級。

谷歌此前 OCS 採用 MEMS 微鏡，因良率問題需屏蔽部分通道，而壓電陶瓷或突破這一限制。根據報道，谷歌 2025 年 OCS 採購量預計翻倍至 2 萬臺，壓電陶瓷方案有望支撐更大規模 GPU / TPU 互聯，動態調整集羣拓撲，爲百億億次算力集羣提供高效光互聯支撐。隨着 OCP 聯盟成立，OCS 技術標準化進程加速，壓電陶瓷或成爲下一代數據中心光交換的關鍵選項。

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技術標準化進程加速，壓電陶瓷或成爲下一代數據中心光交換的關鍵選項。</p></article></body></html>","source":"tencent","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>谷歌測試通過壓電陶瓷（DLBS）OCS 技術，突破 AI 集羣光交換性能瓶頸</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; 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技術，突破 AI 集羣光交換性能瓶頸\n</h2>\n<h4 class=\"meta\">\n<p class=\"head\">\n<strong class=\"h-name small\">IT之家</strong><span class=\"h-time small\">2025-09-19 18:38</span>\n</p>\n</h4>\n</header>\n<article>\n<html><body><article><p>近日，<a href=\"https://laohu8.com/S/GOOG\">谷歌</a>在光路交換機（OCS）技術領域取得新進展，正積極測試基於壓電陶瓷（DLBS）的 OCS 方案，以優化其 AI 超算集羣的網絡性能。壓電陶瓷技術憑藉光路直接傳輸無反射損耗、切換時延低至毫秒級等優勢，成爲繼 MEMS 和數字液晶（DLC）後的重要技術路線。</p><img src=\"https://e.thsi.cn/img/478f1b5d829f5151\"/><p>據行業分析，壓電陶瓷 OCS 的系統損耗最低、切換速度最快，尤其適合高穩定性的 AI 集羣互聯場景。且其兼具正逆壓電效應，能高效實現<a href=\"https://laohu8.com/S/600184\">光電</a>信號轉換，擁有低能耗、無電磁噪音、壽命長，適配嚴苛工作環境等優勢。<a href=\"https://laohu8.com/S/GOOGL\">谷歌</a> TPUv4 / v7 集羣已採用 OCS 構建 3D 環面網絡，若壓電陶瓷方案成熟，有望進一步降低功耗並提升萬卡級組網效率。此次測試或加速壓電陶瓷在超大規模 GPU 互聯中的應用，推動數據中心效能升級。</p><p>谷歌此前 OCS 採用 MEMS 微鏡，因良率問題需屏蔽部分通道，而壓電陶瓷或突破這一限制。根據報道，谷歌 2025 年 OCS 採購量預計翻倍至 2 萬臺，壓電陶瓷方案有望支撐更大規模 GPU / TPU 互聯，動態調整集羣拓撲，爲百億億次算力集羣提供高效光互聯支撐。隨着 OCP 聯盟成立，OCS 技術標準化進程加速，壓電陶瓷或成爲下一代數據中心光交換的關鍵選項。</p></article></body></html>\n<div 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