Abstract: Described are examples of optical blind-mate connector adaptors, optical blind-mate connectors to blind-mate to the adaptors, and optical blind-mate systems. In various implementations, an optical blind-mate connector adapter may include a sleeve housing and a shutter mounted at an opening of the sleeve housing. The shutter may include a shutter flap to cover the opening in a closed position and a shutter tab to receive a force to move the shutter flap from the closed position to an open position extending away from the sleeve housing.

Abstract: Described are examples of optical blind-mate connector adaptors, optical blind-mate connectors to blind-mate to the adaptors, and optical blind-mate systems.

Abstract: A blade computer system comprises side-by-side computer blades (44, 144), a connectivity module (50, 150, 350) extending across and connected to each of the plurality of side-by-side computer blades (44, 144) along the ends of the computer blades (44, 144) and at least one first power supply-fan unit (46, 146) extending perpendicular to the first axis and directly connected to each of the first plurality of side-by-side computer blades (44, 144) along ends of the plurality of side-by-side computer blades (44, 144) such that the at least one power supply-fan unit (46, 146) draws air across the first plurality of side-by-side computer blades (44, 144) and into the first connectivity module (50, 150, 350).

Abstract: Heat is conducted from a primary component to a thermal dissipation structure. An airflow removes from the thermal dissipation structure. An air channel associated with the thermal dissipation structure diverts a portion of the airflow to a secondary component, thereby providing cooling to the secondary component.

Abstract: A blade computer system comprises side-by-side computer blades (44, 144), a connectivity module (50, 150, 350) extending across and connected to each of the plurality of side-by-side computer blades (44, 144) along the ends of the computer blades (44, 144) and at least one first power supply-fan unit (46, 146) extending perpendicular to the first axis and directly connected to each of the first plurality of side-by-side computer blades (44, 144) along ends of the plurality of side-by-side computer blades (44, 144) such that the at least one power supply-fan unit (46, 146) draws air across the first plurality of side-by-side computer blades (44, 144) and into the first connectivity module (50, 150, 350).

Abstract: One example relates to an optical engine comprising an optical waveguide. The optical waveguide can comprise a total internal reflection (TIR) edge to change direction of an optical light beam to an angle parallel to a top surface and a bottom surface of the optical waveguide. The optical waveguide can also comprise a plurality of aligning holes extending from the top surface to the bottom surface of the optical waveguide. The optical engine can comprise a substantially transparent slab underlying the optical waveguide. The slab can also comprise a micro lens to collimate the optical light beam. The slab can further comprise a plurality of aligning pins extending perpendicular from a top surface and bottom surface of the slab. Each of the plurality of aligning pins can extend through a respective one of the plurality of aligning holes.

Abstract: A system includes a chassis and a slot in the chassis. The slot has a depth dimension along which a removable module may be moved to insert the module in the slot and remove the module from the slot. The system includes waveguides, which have couplers that are arranged at different depths of the slot to couple the waveguides to the module in response to the module being inserted into the slot.

Abstract: A first module including a first port to connect to a second module including a second port. The first port including an attraction field to attract a second port if the second port was within the attraction field. A flexible member can be connected to the first port and a first edge can apply a force to the first port.

Abstract: In an embodiment a first module can include a first side and a first edge. An optical transmitter connector can be a first distance from the first side at a first position along the first edge. An optical receiver connector can be a second distance from the first side wherein the first and the second distances are different and wherein the optical receiver connector is at a second position along the first edges. In an embodiment a chassis includes a first slot and a second slot with a first waveguide and a second waveguide.

Abstract: One example relates to an optical engine comprising an optical waveguide. The optical waveguide can comprise a total internal reflection (TIR) edge to change direction of an optical light beam to an angle parallel to a top surface and a bottom surface of the optical waveguide. The optical waveguide can also comprise a plurality of aligning holes extending from the top surface to the bottom surface of the optical waveguide. The optical engine can comprise a substantially transparent slab underlying the optical waveguide. The slab can also comprise a micro lens to collimate the optical light beam. The slab can further comprise a plurality of aligning pins extending perpendicular from a top surface and bottom surface of the slab. Each of the plurality of aligning pins can extend through a respective one of the plurality of aligning holes.

Abstract: Waveguide apparatuses and methods are provided. A waveguide method (700) can include stacking (710) a plurality of layers (110) to form a plurality of waveguides (120). Each of the plurality of layers can include at least one waveguide surface (140). The method can further include aligning (720) the plurality of layers using at least one alignment device (160). The method can also include trapping (730) the aligned, stacked plurality of layers between a first member (170) and second member (180).

Abstract: An embodiment of a system and method disaggregate I/O resources from a server's compute resources, such as CPU and memory, by moving the server's local I/O devices to a remote location apart from the server's compute resources. An embodiment uses optical technology to accomplish the fast communication speeds needed between the compute resources and the remotely located I/O resources. Specifically, an embodiment uses fiber-optic cables and electrical-to-optical conversion to facilitate communication between the compute resources and the I/O resources. The compute resources and the remotely located I/O resources can be designed differently to allow conductive liquid cooling for the compute resources and air cooling for the I/O resources.

Abstract: A module includes a housing. The housing can include a port. The port can extend though an opening in the housing if the module is inserted in the chassis.

Abstract: A bade computer system comprises side-by-side computer blades (44, 144), a connectivity module (50, 150, 350) extending across and connected to each of the plurality of side-by-side computer blades (44, 144) along the ends of the computer blades (44, 144) and at least one first power supply-fan unit (46, 146) extending perpendicular to the first axis and directly connected to each of the first plurality of side-by-side computer blades (44, 144) along ends of the plurality of side-by-side computer blades (44, 144) such that the at least one power supply-fan unit (46, 146) draws air across the first plurality of side-by-side computer blades (44, 144) and into the first connectivity module (50, 150, 350).

Abstract: In an embodiment a first module can include a first side and a first edge. An optical transmitter connector can be a first distance from the first side at a first position along the first edge. An optical receiver connector can be a second distance from the first side wherein the first and the second distances are different and wherein the optical receiver connector is at a second position along the first edges. In an embodiment a chassis includes a first slot and a second slot with a first waveguide and a second waveguide.

Abstract: A module includes a housing.

Abstract: A first module including a first port to connect to a second module including a second port. The first port including an attraction field to attract a second port if the second port was within the attraction field. A flexible member can be connected to the first port and a first edge can apply a force to the first port.

Abstract: Waveguide apparatuses and methods are provided. A waveguide method (700) can include stacking (710) a plurality of layers (110) to form a plurality of waveguides (120). Each of the plurality of layers can include at least one waveguide surface (140). The method can further include aligning (720) the plurality of layers using at least one alignment device (160). The method can also include trapping (730) the aligned, stacked plurality of layers between a first member (170) and second member (180).

Abstract: An embodiment of a system and method disaggregate I/O resources from a server's compute resources, such as CPU and memory, by moving the server's local I/O devices to a remote location apart from the server's compute resources. An embodiment uses optical technology to accomplish the fast communication speeds needed between the compute resources and the remotely located I/O resources. Specifically, an embodiment uses fiber-optic cables and electrical-to-optical conversion to facilitate communication between the compute resources and the I/O resources. The compute resources and the remotely located I/O resources can be designed differently to allow conductive liquid cooling for the compute resources and air cooling for the I/O resources.

Abstract: A blade assembly is disclosed. The blade assembly comprises a printed circuit (PC) board, and a disk drive drawer. The disk drive drawer is configured to move from a closed position into an open position, wherein the disk drive drawer is adjacent to the PC board when in the closed position and is positioned away from the PC board when in the open position. The blade assembly also comprises at least one stack of internal drives attached to the disk drive drawer. Each stack of internal drives comprise: a base bracket attached to the disk drive drawer, at least one drive cage pivotally mounted to the base bracket and configured to rotate between an open position and a closed position. In the closed position the drive cage is parallel with the disk drive drawer and in the open position the drive cage makes an angle a with the disk drive drawer. The drive cage is configured to hold a disk drive.