Abstract: A metal ionic antimicrobial surface configured for external use on a surface location in an indoor environment. A surface structure includes a pair of opposed major surfaces, one surface forming an exposed layer having a pattern of conductive strips and corresponding insulative spacings with a power pod structure secured to the surface structure. The power pod structure houses a battery and a power control circuit electrically connected to the conductive strips. In embodiments, the battery has an amp-hour capacity of 150-1500 mAh, an average width of each conductive strip of copper and silver metallic ions and each insulative spacing is between 0.1 to 0.5 millimeters, and the power control circuit includes a voltage booster circuit that maintains a constant low voltage of 2.5V-4.5V.

Abstract: A bracket for an optical network terminal is described. The bracket includes cable management features to store a fiber optic cable that connects to the optical network terminal. The bracket includes a holding region configured to receive and hold an optical network terminal. A rear of bracket includes a fiber cable spool configured to position a fiber cable. A port passes through the bracket for the fiber cable to pass form the fiber cable spool to the optical network terminal.

Abstract: A wall-mountable outlet comprising an enclosure and a faceplate mechanically coupled to the enclosure. An optical network terminal (ONT) is provided in the enclosure. In one example embodiment, the ONT comprises an optical-electrical (O-E) data module, and the O-E data module comprises an O-E converter. The O-E data module can further comprise a switch arranged to selectively couple at least one signal with the O-E converter. The O-E data module further can comprise a Passive Optical Network (PON) controller interposed between the O-E converter and the switch.

Abstract: A metal ionic antimicrobial surface configured for external use on a surface location in an indoor environment. A surface structure includes a pair of opposed major surfaces, one surface forming an exposed layer having a pattern of conductive strips and corresponding insulative spacings with a power pod structure secured to the surface structure. The power pod structure houses a battery and a power control circuit electrically connected to the conductive strips. In embodiments, the battery has an amp-hour capacity of 150-1500 mAh, an average width of each conductive strip of copper and silver metallic ions and each insulative spacing is between 0.1 to 0.5 millimeters, and the power control circuit includes a voltage booster circuit that maintains a constant low voltage of 2.5V-4.5V.

Abstract: According to an example, configurable workload optimization may include selecting a performance optimized application workload from available performance optimized application workloads. A predetermined combination of removable workload optimized modules may be selected to implement the selected performance optimized application workload. Different combinations of the removable workload optimized modules may be usable to implement different ones of the available performance optimized application workloads. The predetermined combination of the removable workload optimized modules may be managed to implement the selected performance optimized application workload. Data flows directed to the predetermined combination of the removable workload optimized modules may be received.

Abstract: According to an example, configurable network security may include receiving data flows directed to end node modules of a server, and selecting data flows from the received data flows based on an analysis of attributes of the received data flows. The selected data flows may be less than the received data flows. A number of IPS data plane modules of the server that are available for inspection of the selected data flows may be determined. The selected data flows may be distributed between the IPS data plane modules based on the determined number of the IPS data plane modules. The distributed data flows may be inspected using the IPS data plane modules to identify malicious and benign data flows, and to determine whether to drop the malicious data flows, direct the malicious data flows to a predetermined destination, or forward the benign data flows to the end node modules.

Abstract: A wall-mountable outlet comprising an enclosure and a faceplate mechanically coupled to the enclosure. An optical network terminal (ONT) is provided in the enclosure. In one example embodiment, the ONT comprises an optical-electrical (O-E) data module, and the O-E data module comprises an O-E converter. The O-E data module can further comprise a switch arranged to selectively couple at least one signal with the O-E converter. The O-E data module further can comprise a Passive Optical Network (PON) controller interposed between the O-E converter and the switch.

Abstract: A wall-mountable outlet comprising an enclosure and a faceplate mechanically coupled to the enclosure. An optical network terminal (ONT) is provided in the enclosure. In one example embodiment, the ONT comprises an optical-electrical (O-E) data module, and the O-E data module comprises an O-E converter. The O-E data module can further comprise a switch arranged to selectively couple at least one signal with the O-E converter. The O-E data module further can comprise a Passive Optical Network (PON) controller interposed between the O-E converter and the switch.

Abstract: Embodiments of the present disclosure may include methods, systems, and computer readable media with executable instructions. An example method for network virtualization can include providing, by a datacenter (100) having physical and/or virtual resources, a number of virtual tenant datacenters (tDatacenters), each tDatacenter being isolated from other tDatacenters. A tenant virtual local area network (T-VLAN) (226, 228, 682) is associated to each of the number of tDatacenters, and a value of an end-to-end invariant network virtual local area network (VLAN) identification (VID) label (T-VID) is associated to a particular T-VLAN (226, 228, 682). A network packet associated with the particular T-VLAN (226, 228, 682) is modified at an edge network boundary (561) to include the T-VID. The T-VID is configured to have more than 4096 possible values.

Abstract: One example provides a network device including a queue to receive frames from a source, a processor, and a memory communicatively coupled to the processor. The memory stores instructions causing the processor, after execution of the instructions by the processor, to determine whether a flow control threshold of the queue has been exceeded, and in response to determining that the flow control threshold of the queue has been exceeded, generate a message to be sent to the source of the frame that exceeded the flow control threshold. The message includes a pause duration for which the source is to stop transmitting frames.

Abstract: The present invention provides compositions and methods useful in the treatment of wounds, particularly in reducing or preventing scar formation, particularly hypertrophic scar or keloid formation. The invention thus further provides methods of treatment, including methods useful in hypertrophic scar or keloid revision as well as prophylactic, scar inhibiting methods.

Abstract: According to an example, configurable network security may include receiving data flows directed to end node modules of a server, and selecting data flows from the received data flows based on an analysis of attributes of the received data flows. The selected data flows may be less than the received data flows. A number of IPS data plane modules of the server that are available for inspection of the selected data flows may be determined. The selected data flows may be distributed between the IPS data plane modules based on the determined number of the IPS data plane modules. The distributed data flows may be inspected using the IPS data plane modules to identify malicious and benign data flows, and to determine whether to drop the malicious data flows, direct the malicious data flows to a predetermined destination, or forward the benign data flows to the end node modules.

Abstract: According to an example, configurable workload optimization may include selecting a performance optimized application workload from available performance optimized application workloads. A predetermined combination of removable workload optimized modules may be selected to implement the selected performance optimized application workload. Different combinations of the removable workload optimized modules may be usable to implement different ones of the available performance optimized application workloads. The predetermined combination of the removable workload optimized modules may be managed to implement the selected performance optimized application workload. Data flows directed to the predetermined combination of the removable workload optimized modules may be received.

Abstract: One example includes a network device. The network device includes a queue to receive frames from a source, a processor, and a memory coupled to the processor. The memory stores instructions causing the processor, after execution of the instructions by the processor, to deposit tokens into a first token bucket at a first rate, determine whether a frame length of a frame received by the queue is less than the tokens in the first token bucket, remove tokens from the first token bucket in response to the frame length being less than the tokens in the first token bucket, and generate a congestion notification message in response to the frame length not being less than the tokens in the first token bucket. Each token represents a unit of bytes of a predetermined size.

Abstract: One example provides a network device including a queue to receive frames from a source, a processor, and a memory communicatively coupled to the processor. The memory stores instructions causing the processor, after execution of the instructions by the processor, to determine whether a flow control threshold of the queue has been exceeded, and in response to determining that the flow control threshold of the queue has been exceeded, generate a message to be sent to the source of the frame that exceeded the flow control threshold. The message includes a pause duration for which the source is to stop transmitting frames.

Abstract: One example provides a network device including a queue to receive in profile frames and out of profile frames, a processor, and a memory communicatively coupled to the processor. The memory stores instructions causing the processor, after execution of the instructions by the processor, to determine whether a predetermined operating point of the queue has been exceeded, and in response to determining that the predetermined operating point of the queue has been exceeded, forward the in profile frames, sample the out of profile frames, and generate a congestion notification message for each sampled out of profile frame to be sent to a source of the out of profile frames to reduce the transmission rate of frames.

Abstract: A system and method are provided to route packets in a data center network. Individual packets are encapsulated at an edge of the data center network, so that each encapsulated packet includes a set of header fields, such as a tenant identifier. For each encapsulated packet, a hash class is determined from the set of header fields. A routing virtual local area network (VLAN) is selected for the packet based on the tenant identifier and the hash class.

Abstract: The present invention provides compositions and methods useful in the treatment of wounds, particularly in reducing or preventing scar formation, particularly hypertrophic scar or keloid formation. The invention thus further provides methods of treatment, including methods useful in hypertrophic scar or keloid revision as well as prophylactic, scar inhibiting methods.

Abstract: A system and method are provided to route packets in a data center network. Individual packets are encapsulated at an edge of the data center network, so that each encapsulated packet includes a set of header fields, such as a tenant identifier. For each encapsulated packet, a hash class is determined from the set of header fields. A routing virtual local area network (VLAN) is selected for the packet based on the tenant identifier and the hash class.