Abstract: The present disclosure relates to glyconucleic acids, such as glycoRNA and glycoDNA described herein. Provided are glycosylated ribonucleic acid (glycoRNA)-related methods and compositions.

Abstract: A processor-implemented method for simultaneously tracking one or more objects includes receiving, via a dynamical system with a set of sensors, a first set of unlabeled measurements from one or more objects. Each of the measurements is a function of time. A set of candidate tracks is determined for the one or more objects. Probabilities of each of the first set of unlabeled measurements being assigned to each of the set of candidate tracks are computed. A track from the set of candidate tracks is determined for each of the one or more objects based on a joint probability distribution of track attributes and the probabilistic assignment of each of the first set of unlabeled measurements to each of the set of candidate tracks.

Abstract: Vacuum insulated storage containers storage containers are provided.

Abstract: Various examples described herein provide for a management controller that includes a virtual universal serial bus (USB) host controller that can emulate an actual USB host controller to a central processor. A particular endpoint from a number of endpoints is associated with a virtual USB device that is coupled to the virtual USB host controller. The particular endpoint is to refer to a location in a management memory.

Abstract: Various examples described herein provide for a management controller that includes a virtual universal serial bus (USB) host controller that can emulate an actual USB host controller to a central processor. A particular endpoint from a number of endpoints is associated with a virtual USB device that is coupled to the virtual USB host controller. The particular endpoint is to refer to a location in a management memory.

Abstract: Various examples described herein provide for a management controller that includes a virtual universal serial bus (USB) host controller that can emulate an actual USB host controller to a central processor. A particular endpoint from a number of endpoints is associated with a virtual USB device that is coupled to the virtual USB host controller. The particular endpoint is to refer to a location in a management memory.

Abstract: An artificial bone is provided comprising an inner core made from a porous material, the porous material comprising at least one fiber component having fibers, a liquid and a binder, and an outer layer comprising at least one fiber component having fibers, a liquid and a binder, wherein the ratio of the at least one fiber component having fibers to liquid to binder of the inner core is different from the ratio of the at least one fiber component having fibers to liquid to binder of the outer layer.

Abstract: In one implementation, a system for peripheral device security includes a hardware interface coupled to an out-of-band manager, and the out-of-band manager is to: authorize a peripheral device via the hardware interface; and load instructions from the peripheral device to a host interface.

Abstract: Various examples described herein provide for a management controller that includes a virtual universal serial bus (USB) host controller that can emulate an actual USB host controller to a central processor. A particular endpoint from a number of endpoints is associated with a virtual USB device that is coupled to the virtual USB host controller. The particular endpoint is to refer to a location in a management memory.

Abstract: An artificial bone is provided comprising an inner core made from a porous material, the porous material comprising at least one fiber component having fibers, a liquid and a binder, and an outer layer comprising at least one fiber component having fibers, a liquid and a binder, wherein the ratio of the at least one fiber component having fibers to liquid to binder of the inner core is different from the ratio of the at least one fiber component having fibers to liquid to binder of the outer layer.

Abstract: Normalization of regions of a sensor panel capable of detecting multi-touch events, or a sensor panel capable of detecting multi-hover events, is disclosed to enable each sensor in the sensor panel to trigger a virtual button in a similar manner, given the same amount of touch or hover. Each sensor produces an output value proportional to the level or amount of touch or hover. However, due to processing, manufacturing and physical design differences, the sensor output values can vary from region to region or panel to panel for a given amount of touch or hover. To normalize the sensor output values across regions, gain and offset information can be obtained in advance, stored in nonvolatile memory, and later used to normalize the sensor output values so that all regions in the sensor panel can trigger virtual buttons similarly, providing a uniform “response function” at any location on the sensor panel.

Abstract: Systems, methods, and computer-readable and executable instructions are provided for providing network attached storage (NAS) devices 232 to management sub-systems 214. Methods for providing a NAS device 232 to a management sub-system 214 can include implementing a network file system (NFS) 220 within the management sub-system 214, 102. Providing a NAS device 232 to a management sub-system 214 also can include communicatively coupling the NFS 220 and the NAS device 232, 104. Furthermore, providing a NAS device 232 to a management sub-system 214 can include providing the management sub-system 214 access to the NAS device 232 via the implemented NFS 220, 106.

Abstract: Systems, methods, and computer-readable and executable instructions are provided for booting a server using a remote read-only memory image. Booting a server using a remote read-only memory (ROM) image can include accessing a remote ROM image from a second server for the first server, wherein the first server does not have a complete ROM image 102, and storing the image in a subsystem memory 104. Booting a server using a remote ROM image can include booting the first server from the remote ROM image in the subsystem memory 106.

Abstract: The testing of a multi-touch sensor panel for opens and shorts on its drive and sense lines is disclosed by placing a substantially ungrounded conductor diagonally over the touch sensor panel so that at least a portion of every drive line and every sense line is covered by the substantially ungrounded conductor. Pixels under the substantially ungrounded conductor can have strongly positive pixels, while pixels outside the substantially ungrounded conductor can have negative pixels. With the substantially ungrounded conductor in place, a backdrop of negative pixels is formed, and an image of touch can be obtained. By analyzing the image of touch, any opens and shorts on the drive and sense lines, any shorts between a drive and a sense line, or any open drive and sense lines can be quickly identified against the backdrop of negative pixels.

Abstract: The efficient calibration of multi-touch sensor panels that have non-flat surfaces is disclosed. The calibration of the sensor panels can be accomplished using a calibration device with a flexible calibration surface. The flexible calibration surface is particularly well-suited for curved or other non-flat touch sensor panels, such as those that might be present on a mouse or other device designed to be grasped by a user's hand. The flexible apparatus can conform to the non-flat touch sensor panel and apply the equivalent of a conductive touch over most or all of the pixels.

Abstract: Normalization of regions of a sensor panel capable of detecting multi-touch events, or a sensor panel capable of detecting multi-hover events, is disclosed to enable each sensor in the sensor panel to trigger a virtual button in a similar manner, given the same amount of touch or hover. Each sensor produces an output value proportional to the level or amount of touch or hover. However, due to processing, manufacturing and physical design differences, the sensor output values can vary from region to region or panel to panel for a given amount of touch or hover. To normalize the sensor output values across regions, gain and offset information can be obtained in advance, stored in nonvolatile memory, and later used to normalize the sensor output values so that all regions in the sensor panel can trigger virtual buttons similarly, providing a uniform “response function” at any location on the sensor panel.

Abstract: Normalization of regions of a sensor panel capable of detecting multi-touch events, or a sensor panel capable of detecting multi-hover events, is disclosed to enable each sensor in the sensor panel to trigger a virtual button in a similar manner, given the same amount of touch or hover. Each sensor produces an output value proportional to the level or amount of touch or hover. However, due to processing, manufacturing and physical design differences, the sensor output values can vary from region to region or panel to panel for a given amount of touch or hover. To normalize the sensor output values across regions, gain and offset information can be obtained in advance, stored in nonvolatile memory, and later used to normalize the sensor output values so that all regions in the sensor panel can trigger virtual buttons similarly, providing a uniform “response function” at any location on the sensor panel.

Abstract: Normalization of regions of a sensor panel capable of detecting multi-touch events, or a sensor panel capable of detecting multi-hover events, is disclosed to enable each sensor in the sensor panel to trigger a virtual button in a similar manner, given the same amount of touch or hover. Each sensor produces an output value proportional to the level or amount of touch or hover. However, due to processing, manufacturing and physical design differences, the sensor output values can vary from region to region or panel to panel for a given amount of touch or hover. To normalize the sensor output values across regions, gain and offset information can be obtained in advance, stored in nonvolatile memory, and later used to normalize the sensor output values so that all regions in the sensor panel can trigger virtual buttons similarly, providing a uniform “response function” at any location on the sensor panel.

Abstract: Normalization of regions of a sensor panel capable of detecting multi-touch events, or a sensor panel capable of detecting multi-hover events, is disclosed to enable each sensor in the sensor panel to trigger a virtual button in a similar manner, given the same amount of touch or hover. Each sensor produces an output value proportional to the level or amount of touch or hover. However, due to processing, manufacturing and physical design differences, the sensor output values can vary from region to region or panel to panel for a given amount of touch or hover. To normalize the sensor output values across regions, gain and offset information can be obtained in advance, stored in nonvolatile memory, and later used to normalize the sensor output values so that all regions in the sensor panel can trigger virtual buttons similarly, providing a uniform “response function” at any location on the sensor panel.

Abstract: The efficient calibration of multi-touch sensor panels that have non-flat surfaces is disclosed. The calibration of the sensor panels can be accomplished using a calibration device with a flexible calibration surface. The flexible calibration surface is particularly well-suited for curved or other non-flat touch sensor panels, such as those that might be present on a mouse or other device designed to be grasped by a user's hand. The flexible apparatus can conform to the non-flat touch sensor panel and apply the equivalent of a conductive touch over most or all of the pixels.