Abstract: A transceiver lock insert may include a housing, a first connector housed at least partially within the housing and configured to communicatively and mechanically couple to a transceiver module, a second connector housed at least partially within the housing and configured to communicatively and mechanically couple to a cable, transmission media communicatively coupled between the first connector and the second connector and configured to communicatively couple the transceiver module to the cable, and a lock housed within the housing and configured to, when the transceiver lock insert is inserted into the transceiver module, secure the transceiver lock insert to the transceiver module to prevent access by a person to a release mechanism of the transceiver module.

Abstract: A silicon photonics (SiP) chip includes MAC and PHY blocks interconnected by optical waveguides (560) to provide network interface for a computer system. The SiP chip may be formed in a package mounted to the computer's motherboard. In an example, the computer system is a blade server module mounted in a datacenter chassis.

Abstract: Embodiments of the present disclosure include systems and methods for controlling the direction of cooling air flow across components of an electronic devices. In one or more embodiments, a device or information handling system includes an air flow generator that is able to generate air flow in different directions by activation of a button, a controller, or both. In one or more embodiments, a sensor measures air temperatures of air when the air flows in different directions, and an air flow direction is selected using the air temperature measurements.

Abstract: An active device module may include an active device, a housing configured to house the active device, a slide release latch mechanically coupled to the housing via a spring having a spring force that biases the slide release latch in a first position relative to the housing, and connectivity flaps mechanically coupled to the slide release latch via activation levers, wherein when the slide release latch is in the first position and a cable is inserted into the active device module, the connectivity flaps apply a compressive force to either side of the cable to mechanically maintain the cable within the active device module.

Abstract: An active device module may include an active device, a housing configured to house the active device, a slide release latch mechanically coupled to the housing via a spring having a spring force that biases the slide release latch in a first position relative to the housing, and connectivity flaps mechanically coupled to the slide release latch via activation levers, wherein when the slide release latch is in the first position and a cable is inserted into the active device module, the connectivity flaps apply a compressive force to either side of the cable to mechanically maintain the cable within the active device module.

Abstract: A transceiver lock insert may include a housing, a first connector housed at least partially within the housing and configured to communicatively and mechanically couple to a transceiver module, a second connector housed at least partially within the housing and configured to communicatively and mechanically couple to a cable, transmission media communicatively coupled between the first connector and the second connector and configured to communicatively couple the transceiver module to the cable, and a lock housed within the housing and configured to, when the transceiver lock insert is inserted into the transceiver module, secure the transceiver lock insert to the transceiver module to prevent access by a person to a release mechanism of the transceiver module.

Abstract: A silicon photonics (SiP) chip includes MAC and PHY blocks interconnected by optical waveguides (560) to provide network interface for a computer system. The SiP chip may be formed in a package mounted to the computer's motherboard. In an example, the computer system is a blade server module mounted in a datacenter chassis.

Abstract: A single cable optical data and power transmission system includes a powering device that transmits electrical signal data and power via its powering device port to a first transceiver. The first transceiver then transmits the power via an electrical wire in a cable connected to the first transceiver, while converting the electrical signal data to optical signal data and transmitting the optical signal data via an optical wire in the cable connected to the first transceiver. A second transceiver coupled to the cable receives the optical signal data transmitted over the optical wire in the cable, receives the power transmitted over the electrical wire in the cable, converts the optical signal data to electrical signal data, and transmits the electrical signal data and the power via a powered device port to a powered device.

Abstract: A silicon photonics (SiP) chip includes MAC and PHY blocks interconnected by optical waveguides (560) to provide network interface for a computer system. The SiP chip may be formed in a package mounted to the computer's motherboard. In an example, the computer system is a blade server module mounted in a datacenter chassis.

Abstract: Embodiments of the present disclosure include systems and methods for controlling the direction of cooling air flow across components of an electronic devices. In one or more embodiments, a device or information handling system includes an air flow generator that is able to generate air flow in different directions by activation of a button, a controller, or both. In one or more embodiments, a sensor measures air temperatures of air when the air flows in different directions, and an air flow direction is selected using the air temperature measurements.

Abstract: Embodiments of the present disclosure include systems and methods for controlling the direction of cooling air flow across components of an electronic devices. An air-cooled electronic device includes: an air flow generator that is able to generate air flow in either first or second direction across the device; a sensor that measures first and second temperatures of air in the device when the air flows in the first and second directions, respectively; and a controller coupled to the mechanism and the sensor. The controller compares the first temperature to the second temperature and controls the air flow generator to generate the air flow in one of the first and second directions based on comparison of the first temperature to the second temperature.

Abstract: A networking device includes a chassis, a port located on the chassis, a port configuration display located on the chassis, and a plurality of port configuration buttons located on the chassis. A port configuration engine is included in the chassis and is coupled to each of the port, the port configuration display, and the plurality of port configuration buttons. The port configuration engine is configured to provide a current Virtual Local Area Network (VLAN) assignment for the port for display on the port configuration display. When the port configuration engine determines that a first port configuration button of the plurality of port configuration buttons has been actuated at least once, the port configuration engine modifies the current VLAN assignment for the port to provide a modified VLAN assignment for the port, and provides the modified VLAN assignment for the port for display on the port configuration display.

Abstract: A power distribution system includes a chassis with a plurality of ports that include a first port configured to communicate with powering devices and a second port configured to communicate with powered devices. A power distribution engine in the chassis is coupled to each of the plurality of ports. The power distribution engine determines that power available to the power distribution engine is insufficient to power a first powered device that is coupled to the first port, requests power from a first powering device that is coupled to the second port, and provides power that is received through the second port from the first powering device to the first powered device through the first port. In an embodiment, the first powered device and the second powered device are switch IHSs, the first port is configured as a trunk port, and the second port is configured as an access port.

Abstract: A networking device includes a chassis, a port located on the chassis, a port configuration display located on the chassis, and a plurality of port configuration buttons located on the chassis. A port configuration engine is included in the chassis and is coupled to each of the port, the port configuration display, and the plurality of port configuration buttons. The port configuration engine is configured to provide a current Virtual Local Area Network (VLAN) assignment for the port for display on the port configuration display. When the port configuration engine determines that a first port configuration button of the plurality of port configuration buttons has been actuated at least once, the port configuration engine modifies the current VLAN assignment for the port to provide a modified VLAN assignment for the port, and provides the modified VLAN assignment for the port for display on the port configuration display.

Abstract: A microburst monitoring system includes a port and a memory system with an egress queue and a shadow queue that are associated with the port. A networking engine is coupled to the port and the memory system and configured to receive and process packets to provide egress frames for forwarding through the port. The networking engine then stores the egress frames in the egress queue, and stores information about each of the egress frames in the shadow queue. When the networking device determines that the storage of the egress frames has caused the egress queue to reach a threshold, the networking device causes the information about each of the egress frames in the egress queue to be captured, and that captured information may be analyzed to determine a source device that is generating at least some of the packets to be throttled.

Abstract: A networking device testing system includes a testing device that is connected to a load generator device and a networking device. The testing device includes a testing device chassis. First testing device connectors are included on the testing device chassis and are each connected to a respective networking device connectors on the networking device. Pairs of the first testing device connectors are coupled together such that traffic received through one of the first testing device connectors in each pair is directed to the other of the first testing device connectors in each pair. Second testing device connectors are included on the testing device chassis. At least one of the second testing device connectors is connected to the load generator device. Each of the second testing device connectors is coupled to a respective one of the first testing device connectors.

Abstract: The electronic device includes a housing that surrounds one or more components of the device and has front, back, top and bottom sides. At least one port is located on at least one of the front and back sides of the housing and configured to receive an end plug of a network cable and communicatively coupled to the one or more components. The housing includes at least one opening formed on at least one of the front and back sides, where the opening is configured to allow the network cable to pass therethrough. At least one side of the housing defines a space so as to allow the network cable to travel between the front side to the back side through the opening and the space.

Abstract: The electronic device includes a housing that surrounds one or more components of the device and has front, back, top and bottom sides. At least one port is located on at least one of the front and back sides of the housing and configured to receive an end plug of a network cable and communicatively coupled to the one or more components. The housing includes at least one opening formed on at least one of the front and back sides, where the opening is configured to allow the network cable to pass therethrough. At least one side of the housing defines a space so as to allow the network cable to travel between the front side to the back side through the opening and the space.

Abstract: Embodiments of the present disclosure include systems and methods for controlling the direction of cooling air flow across components of an electronic devices. An air-cooled electronic device includes: an air flow generator that is able to generate air flow in either first or second direction across the device; a sensor that measures first and second temperatures of air in the device when the air flows in the first and second directions, respectively; and a controller coupled to the mechanism and the sensor. The controller compares the first temperature to the second temperature and controls the air flow generator to generate the air flow in one of the first and second directions based on comparison of the first temperature to the second temperature.

Abstract: A power distribution system includes a chassis with a plurality of ports that include a first port configured to communicate with powering devices and a second port configured to communicate with powered devices. A power distribution engine in the chassis is coupled to each of the plurality of ports. The power distribution engine determines that power available to the power distribution engine is insufficient to power a first powered device that is coupled to the first port, requests power from a first powering device that is coupled to the second port, and provides power that is received through the second port from the first powering device to the first powered device through the first port. In an embodiment, the first powered device and the second powered device are switch IHSs, the first port is configured as a trunk port, and the second port is configured as an access port.