Abstract: A computer-implemented method to reduce Input/Output (I/O) command latency. The method includes receiving, by a first storage pool, a plurality of I/O commands, wherein the first storage pool includes a first throttling limit, and the first throttling limit. The method further includes determining a first processing rate of the first storage pool is at the first throttling limit. The method also includes determining a second processing rate of a second storage pool is below a second throttling limit, wherein the second storage pool is communicatively coupled to the first storage pool. The method includes sending, by the first storage pool to the second storage pool, one or more of the plurality of I/O commands. The method further includes processing, by the second storage pool, the one or more I/O commands of the plurality of I/O commands. The method includes returning processed I/O commands to the host.

Abstract: A computer-implemented method to reduce Input/Output (I/O) command latency. The method includes receiving, by a first storage pool, a plurality of I/O commands, wherein the first storage pool includes a first throttling limit, and the first throttling limit. The method further includes determining a first processing rate of the first storage pool is at the first throttling limit. The method also includes determining a second processing rate of a second storage pool is below a second throttling limit, wherein the second storage pool is communicatively coupled to the first storage pool. The method includes sending, by the first storage pool to the second storage pool, one or more of the plurality of I/O commands. The method further includes processing, by the second storage pool, the one or more I/O commands of the plurality of I/O commands. The method includes returning processed I/O commands to the host.

Abstract: A transparent display provides eye protection from lasers and other high intensity light sources. The transparent display allows users to view objects clearly through the display while also presenting text, graphics or video on the display surface. Simultaneously, the display assembly comprises a component that provides eye protection against high power radiation sources. The transparent display with eye protection provides both protection from high power light sources and an additional cockpit display surface for presentation of information including graphical images, symbology, video, text, and other data.

Abstract: The disclosure relates to an emissive display configured to operate in a day mode and a night mode. The emissive display comprises a day pixel configured to operate in the day mode. The emissive display also comprises a night pixel configured to operate in the night mode, wherein the night pixel is not operational in the day mode. The emissive display also comprises a common pixel configured to operate in both the day mode and the night mode. The emissive display also comprises a detector configured to selectively change an operating mode of the display between the day mode and the night mode based on a detected indication.

Abstract: Various circuits may benefit from suitable protection. For example, certain displays, such as active matrix liquid crystal displays, may benefit from enclosures configured to protect driver circuits from high intensity radiated fields. A system can include a first protective conductive coating layer. The system can also include a first insulating layer on the first protective conductive layer. The system can further include a signal conductive layer on the insulating layer. The system can additionally include a driver layer mounted to the signal conductive layer. The system can also include a second insulating layer above the driver layer. The system can further include a second protective conductive coating layer on the second insulating layer. The system can additionally include one or a plurality of conductive elements disposed between the first protective conductive coating layer and the second protective conductive coating layer to form an enclosure around the driver layer.

Abstract: Various circuits may benefit from suitable protection. For example, certain displays, such as active matrix liquid crystal displays, may benefit from enclosures configured to protect driver circuits from high intensity radiated fields. A system can include a first protective conductive coating layer. The system can also include a first insulating layer on the first protective conductive layer. The system can further include a signal conductive layer on the insulating layer. The system can additionally include a driver layer mounted to the signal conductive layer. The system can also include a second insulating layer above the driver layer. The system can further include a second protective conductive coating layer on the second insulating layer. The system can additionally include one or a plurality of conductive elements disposed between the first protective conductive coating layer and the second protective conductive coating layer to form an enclosure around the driver layer.

Abstract: The disclosure relates to an emissive display configured to operate in a day mode and a night mode. The emissive display comprises a day pixel configured to operate in the day mode. The emissive display also comprises a night pixel configured to operate in the night mode, wherein the night pixel is not operational in the day mode. The emissive display also comprises a common pixel configured to operate in both the day mode and the night mode. The emissive display also comprises a detector configured to selectively change an operating mode of the display between the day mode and the night mode based on a detected indication.

Abstract: The disclosure relates to an emissive display configured to operate in a day mode and a night mode. The emissive display comprises a day pixel configured to operate in the day mode. The emissive display also comprises a night pixel configured to operate in the night mode, wherein the night pixel is not operational in the day mode. The emissive display also comprises a common pixel configured to operate in both the day mode and the night mode. The emissive display also comprises a detector configured to selectively change an operating mode of the display between the day mode and the night mode based on a detected indication.

Abstract: A transparent display provides eye protection from lasers and other high intensity light sources. The transparent display allows users to view objects clearly through the display while also presenting text, graphics or video on the display surface. Simultaneously, the display assembly comprises a component that provides eye protection against high power radiation sources. The transparent display with eye protection provides both protection from high power light sources and an additional cockpit display surface for presentation of information including graphical images, symbology, video, text, and other data.

Abstract: The disclosure relates to an emissive display configured to operate in a day mode and a night mode. The emissive display comprises a day pixel configured to operate in the day mode. The emissive display also comprises a night pixel configured to operate in the night mode, wherein the night pixel is not operational in the day mode. The emissive display also comprises a common pixel configured to operate in both the day mode and the night mode. The emissive display also comprises a detector configured to selectively change an operating mode of the display between the day mode and the night mode based on a detected indication.

Abstract: An aspect of the disclosure relates to an OLED display compatible for operation in both a day mode and a night mode and methods of operating such a display. In one embodiment, a display comprises a screen, a plurality of sub-pixels including red, green, blue and red-orange pixels. The display also comprises an arrangement scheme for the sub-pixels.

Abstract: A method including, for a set of historical and/or ongoing business initiatives, determining key negative and positive performance factors by a computer from a structured taxonomy of negative and positive performance factors stored in a memory; modeling at least one of the performance factors for the ongoing business initiative or a new business initiative at at least one level of the hierarchical taxonomy. The key negative and positive performance factors are modeled based, at least partially, upon a likelihood of occurrence of the key negative performance factors during the business initiative, and based, at least partially, upon potential impact of the key performance factors on the business initiative. The method further includes providing the modeled performance factors in a report to a user, where the report identifies the modeled performance factors, and the potential impact of the at least one modeled performance factor.

Abstract: An aspect of the disclosure relates to an OLED display compatible for operation in both a day mode and a night mode and methods of operating such a display. In one embodiment, a display comprises a screen, a plurality of sub-pixels including red, green, blue and red-orange pixels. The display also comprises an arrangement scheme for the sub-pixels.

Abstract: Multi-particulate pharmaceutical compositions comprising an antihistamine for immediate release and a decongestant for modified release.

Abstract: A solid state optical interconnect system selectively interconnects a plurality of electromagnetic signals between a plurality of inputs and a plurality of outputs. The system includes a plurality of solid state, selectively actuatable 2×2 optical switching elements; and a plurality of all-optical signal paths extending through said 2×2 optical switching elements between the inputs and outputs. Each of said plurality of all-optical signal paths has substantially the same pathlength. This switch element is relatively robust and insensitive to environmental disturbances and has a reconfiguration time which is an order of magnitude faster than conventional opto-mechanical switches which generally require tens of milliseconds before reconfiguration. The switch element provides constant data pathlength for constant latency, loss, and unskewed data output.

Abstract: A switch element utilizes a single polarizer to couple two discreet inputs to any combination of two discreet outputs along non-blocking optical paths. This switch element may be conveniently networked to additional switch elements for scaling to switches having larger numbers (N) of inputs and outputs. The present invention provides advantages typically associated with conventional polarization gates, including terabit per-second data rates, to facilitate use in fiber-optics networks. This switch element is relatively robust and insensitive to environmental disturbances and has a reconfiguration time which is an order of magnitude faster than conventional optomechanical switches which generally require tens of milliseconds before reconfiguration. The switch element provides constant data pathlength for constant latency, loss, and unskewed data output.