公开(公告)号：US10045098B2

公开(公告)日：2018-08-07

申请号：US15395203

申请日：2016-12-30

Applicant: Intel Corporation

Inventor： Matthew Adiletta ,  Aaron Gorius ,  Myles Wilde ,  Michael Crocker

IPC: H04J14/00 ,  H04Q11/00

Abstract: Technologies for switching network traffic include a network switch. The network switch includes one or more processors and communication circuitry coupled to the one or more processors. The communication circuity is capable of switching network traffic of multiple link layer protocols. Additionally, the network switch includes one or more memory devices storing instructions that, when executed, cause the network switch to receive, with the communication circuitry through an optical connection, network traffic to be forwarded, and determine a link layer protocol of the received network traffic. The instructions additionally cause the network switch to forward the network traffic as a function of the determined link layer protocol. Other embodiments are also described and claimed.

公开(公告)号：US10034407B2

公开(公告)日：2018-07-24

申请号：US15394392

申请日：2016-12-29

Applicant: INTEL CORPORATION

Inventor： Steven C. Miller ,  Michael Crocker ,  Aaron Gorius ,  Paul Dormitzer

IPC: H05K7/14 ,  G06F13/40 ,  H05K5/02

Abstract: Examples may include a sled for a rack of a data center including physical storage resources. The sled comprises mounting flanges to enable robotic insertion and removal from a rack and storage device mounting slots to enable robotic insertion and removal of storage devices into the sled. The storage devices are coupled to an optical fabric through storage resource controllers and a dual-mode optical network interface.

公开(公告)号：US09961018B2

公开(公告)日：2018-05-01

申请号：US15262276

申请日：2016-09-12

Applicant: Intel Corporation

Inventor： Matthew J. Adiletta ,  Aaron Gorius ,  Myles Wilde ,  Hugh Wilkinson ,  Amit Y. Kumar

IPC: H04L12/933 ,  H04B1/40 ,  H04L12/931 ,  H04L29/08 ,  H05K7/14

CPC classification number: H04L49/10 ,  H04B1/40 ,  H04L49/35 ,  H04L67/10 ,  H05K7/1492

Abstract: Apparatus and methods for cableless connection of components within chassis and between separate chassis. Pairs of Extremely High Frequency (EHF) transceiver chips supporting very short length millimeter-wave wireless communication links are configured to pass radio frequency signals through holes in one or more metal layers in separate chassis and/or frames, enabling components in the separate chassis to communicate without requiring cables between the chassis. Various configurations are disclosed, including multiple configurations for server chassis, storage chassis and arrays, and network/switch chassis. The EHF-based wireless links support link bandwidths of up to 6 gigabits per second, and may be aggregated to facilitate multi-lane links.

公开(公告)号：US09936613B2

公开(公告)日：2018-04-03

申请号：US15396647

申请日：2016-12-31

Applicant: Intel Corporation

Inventor： Matthew J. Adiletta ,  Aaron Gorius ,  Michael T. Crocker ,  Myles Wilde

IPC: H05K7/14 ,  H05K7/20 ,  G02B6/38 ,  G02B6/44

CPC classification number: H04Q11/0005 ,  B25J15/0014 ,  B65G1/0492 ,  G02B6/3882 ,  G02B6/3893 ,  G02B6/3897 ,  G02B6/4292 ,  G02B6/4452 ,  G05D23/1921 ,  G05D23/2039 ,  G06F1/183 ,  G06F3/061 ,  G06F3/0611 ,  G06F3/0616 ,  G06F3/0619 ,  G06F3/0625 ,  G06F3/0631 ,  G06F3/0638 ,  G06F3/064 ,  G06F3/0647 ,  G06F3/0653 ,  G06F3/0658 ,  G06F3/0659 ,  G06F3/0664 ,  G06F3/0665 ,  G06F3/067 ,  G06F3/0673 ,  G06F3/0679 ,  G06F3/0683 ,  G06F3/0688 ,  G06F3/0689 ,  G06F8/65 ,  G06F9/4401 ,  G06F9/5016 ,  G06F9/5044 ,  G06F9/505 ,  G06F9/5072 ,  G06F9/5077 ,  G06F11/141 ,  G06F11/3414 ,  G06F12/0862 ,  G06F12/0893 ,  G06F12/10 ,  G06F12/109 ,  G06F12/1408 ,  G06F13/161 ,  G06F13/1668 ,  G06F13/1694 ,  G06F13/4022 ,  G06F13/4068 ,  G06F13/409 ,  G06F13/42 ,  G06F13/4282 ,  G06F15/8061 ,  G06F17/30949 ,  G06F2209/5019 ,  G06F2209/5022 ,  G06F2212/1008 ,  G06F2212/1024 ,  G06F2212/1041 ,  G06F2212/1044 ,  G06F2212/152 ,  G06F2212/202 ,  G06F2212/401 ,  G06F2212/402 ,  G06F2212/7207 ,  G06Q10/06 ,  G06Q10/06314 ,  G06Q10/087 ,  G06Q10/20 ,  G06Q50/04 ,  G07C5/008 ,  G08C17/02 ,  G08C2200/00 ,  G11C5/02 ,  G11C5/06 ,  G11C7/1072 ,  G11C11/56 ,  G11C14/0009 ,  H03M7/30 ,  H03M7/3084 ,  H03M7/3086 ,  H03M7/40 ,  H03M7/4031 ,  H03M7/4056 ,  H03M7/4081 ,  H03M7/6005 ,  H03M7/6023 ,  H04B10/25 ,  H04B10/2504 ,  H04L9/0643 ,  H04L9/14 ,  H04L9/3247 ,  H04L9/3263 ,  H04L12/2809 ,  H04L29/12009 ,  H04L41/024 ,  H04L41/046 ,  H04L41/0813 ,  H04L41/082 ,  H04L41/0896 ,  H04L41/12 ,  H04L41/145 ,  H04L41/147 ,  H04L41/5019 ,  H04L43/065 ,  H04L43/08 ,  H04L43/0817 ,  H04L43/0876 ,  H04L43/0894 ,  H04L43/16 ,  H04L45/02 ,  H04L45/52 ,  H04L47/24 ,  H04L47/765 ,  H04L47/782 ,  H04L47/805 ,  H04L47/82 ,  H04L47/823 ,  H04L49/15 ,  H04L49/25 ,  H04L49/357 ,  H04L49/45 ,  H04L49/555 ,  H04L67/02 ,  H04L67/10 ,  H04L67/1004 ,  H04L67/1008 ,  H04L67/1012 ,  H04L67/1014 ,  H04L67/1029 ,  H04L67/1034 ,  H04L67/1097 ,  H04L67/12 ,  H04L67/16 ,  H04L67/306 ,  H04L67/34 ,  H04L69/04 ,  H04L69/329 ,  H04Q1/04 ,  H04Q11/00 ,  H04Q11/0003 ,  H04Q11/0062 ,  H04Q11/0071 ,  H04Q2011/0037 ,  H04Q2011/0041 ,  H04Q2011/0052 ,  H04Q2011/0073 ,  H04Q2011/0079 ,  H04Q2011/0086 ,  H04Q2213/13523 ,  H04Q2213/13527 ,  H04W4/023 ,  H04W4/80 ,  H05K1/0203 ,  H05K1/181 ,  H05K5/0204 ,  H05K7/1418 ,  H05K7/1421 ,  H05K7/1422 ,  H05K7/1447 ,  H05K7/1461 ,  H05K7/1485 ,  H05K7/1487 ,  H05K7/1489 ,  H05K7/1491 ,  H05K7/1492 ,  H05K7/1498 ,  H05K7/2039 ,  H05K7/20709 ,  H05K7/20727 ,  H05K7/20736 ,  H05K7/20745 ,  H05K7/20836 ,  H05K13/0486 ,  H05K2201/066 ,  H05K2201/10121 ,  H05K2201/10159 ,  H05K2201/10189 ,  Y10S901/01

Abstract: A rack for supporting a sleds includes a pair of elongated support posts and pairs of elongated support arms that extend from the elongated support posts. Each pair of the elongated support arms defines a sled slot to receive a corresponding sled. To do so, each elongated support arm includes a circuit board guide to receive a chassis-less circuit board substrate of the corresponding sled. The rack may include a cross-member arm associated with each sled slot and an optical connector mounted to each cross-member arm. Additional elongated support posts may be used to provide additional sled slots.

公开(公告)号：US20180027687A1

公开(公告)日：2018-01-25

申请号：US15396646

申请日：2016-12-31

Applicant: Intel Corporation

Inventor： Matthew J. Adiletta ,  Aaron Gorius ,  Myles Wilde ,  Michael T. Crocker

IPC: H05K7/14 ,  H05K7/20 ,  H05K1/18

CPC classification number: H04Q11/0005 ,  B25J15/0014 ,  B65G1/0492 ,  G02B6/3882 ,  G02B6/3893 ,  G02B6/3897 ,  G02B6/4292 ,  G02B6/4452 ,  G05D23/1921 ,  G05D23/2039 ,  G06F1/183 ,  G06F3/061 ,  G06F3/0611 ,  G06F3/0616 ,  G06F3/0619 ,  G06F3/0625 ,  G06F3/0631 ,  G06F3/0638 ,  G06F3/064 ,  G06F3/0647 ,  G06F3/0653 ,  G06F3/0658 ,  G06F3/0659 ,  G06F3/0664 ,  G06F3/0665 ,  G06F3/067 ,  G06F3/0673 ,  G06F3/0679 ,  G06F3/0683 ,  G06F3/0688 ,  G06F3/0689 ,  G06F8/65 ,  G06F9/4401 ,  G06F9/5016 ,  G06F9/5044 ,  G06F9/505 ,  G06F9/5072 ,  G06F9/5077 ,  G06F11/141 ,  G06F11/3414 ,  G06F12/0862 ,  G06F12/0893 ,  G06F12/10 ,  G06F12/109 ,  G06F12/1408 ,  G06F13/161 ,  G06F13/1668 ,  G06F13/1694 ,  G06F13/4022 ,  G06F13/4068 ,  G06F13/409 ,  G06F13/42 ,  G06F13/4282 ,  G06F15/8061 ,  G06F17/30949 ,  G06F2209/5019 ,  G06F2209/5022 ,  G06F2212/1008 ,  G06F2212/1024 ,  G06F2212/1041 ,  G06F2212/1044 ,  G06F2212/152 ,  G06F2212/202 ,  G06F2212/401 ,  G06F2212/402 ,  G06F2212/7207 ,  G06Q10/06 ,  G06Q10/06314 ,  G06Q10/087 ,  G06Q10/20 ,  G06Q50/04 ,  G07C5/008 ,  G08C17/02 ,  G08C2200/00 ,  G11C5/02 ,  G11C5/06 ,  G11C7/1072 ,  G11C11/56 ,  G11C14/0009 ,  H03M7/30 ,  H03M7/3084 ,  H03M7/3086 ,  H03M7/40 ,  H03M7/4031 ,  H03M7/4056 ,  H03M7/4081 ,  H03M7/6005 ,  H03M7/6023 ,  H04B10/25 ,  H04B10/2504 ,  H04L9/0643 ,  H04L9/14 ,  H04L9/3247 ,  H04L9/3263 ,  H04L12/2809 ,  H04L29/12009 ,  H04L41/024 ,  H04L41/046 ,  H04L41/0813 ,  H04L41/082 ,  H04L41/0896 ,  H04L41/12 ,  H04L41/145 ,  H04L41/147 ,  H04L41/5019 ,  H04L43/065 ,  H04L43/08 ,  H04L43/0817 ,  H04L43/0876 ,  H04L43/0894 ,  H04L43/16 ,  H04L45/02 ,  H04L45/52 ,  H04L47/24 ,  H04L47/765 ,  H04L47/782 ,  H04L47/805 ,  H04L47/82 ,  H04L47/823 ,  H04L49/15 ,  H04L49/25 ,  H04L49/357 ,  H04L49/45 ,  H04L49/555 ,  H04L67/02 ,  H04L67/10 ,  H04L67/1004 ,  H04L67/1008 ,  H04L67/1012 ,  H04L67/1014 ,  H04L67/1029 ,  H04L67/1034 ,  H04L67/1097 ,  H04L67/12 ,  H04L67/16 ,  H04L67/306 ,  H04L67/34 ,  H04L69/04 ,  H04L69/329 ,  H04Q1/04 ,  H04Q11/00 ,  H04Q11/0003 ,  H04Q11/0062 ,  H04Q11/0071 ,  H04Q2011/0037 ,  H04Q2011/0041 ,  H04Q2011/0052 ,  H04Q2011/0073 ,  H04Q2011/0079 ,  H04Q2011/0086 ,  H04Q2213/13523 ,  H04Q2213/13527 ,  H04W4/023 ,  H04W4/80 ,  H05K1/0203 ,  H05K1/181 ,  H05K5/0204 ,  H05K7/1418 ,  H05K7/1421 ,  H05K7/1422 ,  H05K7/1447 ,  H05K7/1461 ,  H05K7/1485 ,  H05K7/1487 ,  H05K7/1489 ,  H05K7/1491 ,  H05K7/1492 ,  H05K7/1498 ,  H05K7/2039 ,  H05K7/20709 ,  H05K7/20727 ,  H05K7/20736 ,  H05K7/20745 ,  H05K7/20836 ,  H05K13/0486 ,  H05K2201/066 ,  H05K2201/10121 ,  H05K2201/10159 ,  H05K2201/10189 ,  Y10S901/01

Abstract: A sled for operation in a corresponding rack of a data center includes a chassis-less circuit board substrate having one or more physical resources coupled to a top side of the chassis-less circuit board and one or more memory devices coupled to a bottom side of the chassis-less circuit board. The sled does not include a housing or chassis and is opened to the local environment. In the illustrative embodiments, the sled may be embodied as a compute sled, an accelerator sled, or a storage sled.

公开(公告)号：US09450635B2

公开(公告)日：2016-09-20

申请号：US14244475

申请日：2014-04-03

Applicant: Intel Corporation

Inventor： Matthew J. Adiletta ,  Aaron Gorius ,  Myles Wilde ,  Hugh Wilkinson ,  Amit Y. Kumar

IPC: H04B1/38 ,  H04B1/40 ,  H04L12/933 ,  H04L12/931 ,  H04L29/08

CPC classification number: H04L49/10 ,  H04B1/40 ,  H04L49/35 ,  H04L67/10 ,  H05K7/1492

Abstract: Apparatus and methods for cableless connection of components within chassis and between separate chassis. Pairs of Extremely High Frequency (EHF) transceiver chips supporting very short length millimeter-wave wireless communication links are configured to pass radio frequency signals through holes in one or more metal layers in separate chassis and/or frames, enabling components in the separate chassis to communicate without requiring cables between the chassis. Various configurations are disclosed, including multiple configurations for server chassis, storage chassis and arrays, and network/switch chassis. The EHF-based wireless links support link bandwidths of up to 6 gigabits per second, and may be aggregated to facilitate multi-lane links.

Abstract translation: 用于无线连接机箱内部和分离机箱之间的部件的装置和方法。 支持非常短长度的毫米波无线通信链路的极高频（EHF）收发器芯片配置成通过单独的机箱和/或框架中的一个或多个金属层中的孔传递射频信号，使单独机架中的组件能够 通信而不需要机箱之间的电缆。 公开了各种配置，包括服务器机箱，存储机箱和阵列以及网络/交换机机箱的多种配置。 基于EHF的无线链路支持高达每秒6吉比特的链路带宽，并且可以聚合以便于多车道链路。