谷歌测试通过压电陶瓷（DLBS）OCS 技术，突破 AI 集群光交换性能瓶颈

IT之家

09/19

近日，谷歌在光路交换机（OCS）技术领域取得新进展，正积极测试基于压电陶瓷（DLBS）的 OCS 方案，以优化其 AI 超算集群的网络性能。压电陶瓷技术凭借光路直接传输无反射损耗、切换时延低至毫秒级等优势，成为继 MEMS 和数字液晶（DLC）后的重要技术路线。据行业分析，压电陶瓷 OCS 的系统损耗最低、切换速度最快，尤其适合高稳定性的 AI 集群互联场景。且其兼具正逆压电效应，能高效实现光电...

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集群互联场景。且其兼具正逆压电效应，能高效实现光电...</p>\n\n<a href=\"http://gu.qq.com/resources/shy/news/detail-v2/index.html#/?id=nesSN2025091918455495387ce0&s=b\">网页链接</a>\n\n</div>\n\n\n</article>\n</div>\n</body>\n</html>\n","isBrief":false,"type":0,"news_type":1,"symbol":"LU1935042991.SGD","symbol_name":"MANULIFE GF GLOBAL MULTI-ASSET DIVERSIFIED INCOME  \"AA\" (SGDHDG) INC","start_time":0,"source_url":"http://gu.qq.com/resources/shy/news/detail-v2/index.html#/?id=nesSN2025091918455495387ce0&s=b","article_id":"2568252748","we_media_id":null,"thumbnails":[],"rights":{"source":"tencent","url":"http://gu.qq.com/resources/shy/news/detail-v2/index.html#/?id=nesSN2025091918455495387ce0&s=b","rn_cache_url":null,"customStyle":"body{padding-top:10px;}#news_title{font-weight:bold;#titleStyle#;}#news_description span{font-size:12px;#descriptionStyle#;}.footer-note{#statement#}","selectors":".mod-LoadTzbdNews, body","filters":".relate-stock, .hot-list, .recom-box, 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和数字液晶（DLC）后的重要技术路线。据行业分析，压电陶瓷 OCS 的系统损耗最低、切换速度最快，尤其适合高稳定性的 AI 集群互联场景。且其兼具正逆压电效应，能高效实现光电信号转换，拥有低能耗、无电磁噪音、寿命长，适配严苛工作环境等优势。谷歌 TPUv4 / v7 集群已采用 OCS 构建 3D 环面网络，若压电陶瓷方案成熟，有望进一步降低功耗并提升万卡级组网效率。此次测试或加速压电陶瓷在超大规模 GPU 互联中的应用，推动数据中心效能升级。谷歌此前 OCS 采用 MEMS 微镜，因良率问题需屏蔽部分通道，而压电陶瓷或突破这一限制。根据报道，谷歌 2025 年 OCS 采购量预计翻倍至 2 万台，压电陶瓷方案有望支撑更大规模 GPU / TPU 互联，动态调整集群拓扑，为百亿亿次算力集群提供高效光互联支撑。随着 OCP 联盟成立，OCS 技术标准化进程加速，压电陶瓷或成为下一代数据中心光交换的关键选项。","kind":"news","is_publish_news":true,"is_publish_highlight":false,"is_publish_live":false,"is_publish_wemedia":null,"editions":null,"column":"","sentiment":"0","news_tag":"","news_rank":0,"symbols":[],"gpt_button":0,"need_auth":false,"code":"91000000","status":"200"}}}