Abstract: A sports videogame such as a baseball videogame allows a user to control the release time of a pitch in order to control the timing of a break on the pitched ball. Other implementations of a baseball videogame allow a user to put extra spin on a pitched ball to thereby create a greater break on the pitch or allow the user to play in a hero mode which enables the user to control a videogame character in a series of specific game play scenarios designed to allow the user to immediately control the videogame character to perform unique skills. Game play may also be customized by allowing the user to incorporate user-created images into screens of game play and/or allow the user to incorporate recorded audio messages into game play.

Abstract: Improved techniques for transferring media assets between a host computer and a media device are disclosed. The transfer of media assets between a host computer and a media device can be referred to as synchronization. According to one aspect of the invention, media assets being transferred can be formatted (e.g., rendered) in advance at the host computer and then delivered to the media device. According to another aspect of the invention, media assets can be grouped into collections and transferred on a collection basis. According to still another aspect of the invention, media assets to be transferred can be limited based on an amount of storage capacity available at the media device. According to yet another aspect of the invention, media assets of different media types can be transferred in accordance with different priorities.

Abstract: In an aspect of this disclosure, a structure is provided comprising a metallic holding layer and an array of semiconductor nanowires. A portion of each semiconductor nanowire is embedded in the metallic holding layer. The embedded nanowires do not penetrate through the metallic holding layer. The metallic holding layer makes electrical contact to the semiconductor nanowires.

Abstract: In an embodiment of the disclosure, a structure is provided which comprises a silicon substrate and a plurality of necklaces of silicon nanowires which are in direct physical contact with a surface of the silicon substrate, wherein the necklaces cover an area of the silicon substrate.

Abstract: Another aspect of the present disclosure relates to a device including a substrate, having a top surface and a bottom surface; an array of nanowires having a base and a top surface, the base contacting the top surface of the substrate; a contacting structure including the same material as the substrate having a non-nanostructured surface of a dimension suitable for forming an electrical contact, located on the same side of the substrate as the array of silicon nanowires; wherein the contacting structure is doped with a greater impurity concentration than the nanowire array, thereby forming a selective emitter.

Abstract: In one aspect, the present disclosure relates to a device including a silicon substrate, wherein at least a portion of the substrate surface can be a silicon nanowire array; and a layer of alumina covering the silicon nanowire array. In some embodiments, the device can be a solar cell. In some embodiments, the device can be a p-n junction. In some embodiments, the p-n junction can be located below the bottom surface the nanowire array.

Abstract: A programming interface for a media management application is described herein. The programming interface allows a media bundle to induce a media presentation at the media management application. More particularly, a media bundle can be provided at a client device, and the media bundle can include program instructions that at least in part use the programming interface to cause the media presentation to be provided at the client device. The media presentation can make use of digital media assets that are stored at a media library on the client device, that are stored within the media bundle, or that are remotely accessible to the client device. The media presentation can provide a multimedia experience for the user of the client device.

Abstract: A process is provided for contacting a nanostructured surface. In that process, a substrate is provided having a nanostructured material on a surface, the substrate being conductive and the nanostructured material being coated with an insulating material. A portion of the nanostructured material is at least partially removed. A conductor is deposited on the substrate in such a way that it is in electrical contact with the substrate through the area where the nanostructured material has been at least partially removed.

Abstract: Embodiments described herein are directed to managing elements within a notification area of a graphical operating system. The elements may include any graphic, logo, or image associated with running software. A user indicates which elements can be displayed in the notification area, consequently creating a list of potentially displayable elements. For each listed element, an order of display, file location, and display status is designated. The user may freely change the order in which elements are displayed in the notification area by repositioning the displayed elements. Elements may be permanently removed from the notification area, resulting in their deletion from the list. Only elements entered into the order list, at the discretion of the user, are displayable within the notification area.

Abstract: Embodiments described herein are directed to managing elements within a notification area of a graphical operating system. The elements may include any graphic, logo, or image associated with running software. A user indicates which elements can be displayed in the notification area, consequently creating a list of potentially displayable elements. For each listed element, an order of display, file location, and display status is designated. The user may freely change the order in which elements are displayed in the notification area by repositioning the displayed elements. Elements may be permanently removed from the notification area, resulting in their deletion from the list. Only elements entered into the order list, at the discretion of the user, are displayable within the notification area.

Abstract: A process is provided for etching a silicon-containing substrate. In the process, the surface of the substrate is cleaned. A film of alumina is deposited on the cleaned substrate surface. A silver film is deposited above the film of alumina. An etchant comprising HF is contacted with the silver film.

Abstract: Techniques for obtaining user feedback related to media content are provided. Sensor data including motion data captured by a motion sensor while media content is played on a media content terminal device may be received. The sensor data may be analyzed for an indication of one or more personal states of one or more users. The indication of a first personal state may be determined based on the motion data. User preferences may be derived from the user feedback. For example, parts of the media content (e.g., specific video frames or scenes) may be analyzed and various entities or features extracted. The entities or features may be matched against user feedback to derive user preferences at a more granular level.

Abstract: In an aspect of this disclosure, a method is provided comprising the steps of: (a) providing a silicon-containing substrate, (b) depositing a first metal on the substrate, (c) etching the substrate produced by step (b) using a first etch, and (d) etching the substrate produced by step (c) using a second etch, wherein the second etch is more aggressive towards the deposited metal than the first etch, wherein the result of step (d) comprises silicon nanowires. The method may further comprise, for example, steps (b1) subjecting the first metal to a treatment which causes it to agglomerate and (b2) depositing a second metal.

Abstract: Another aspect of the present disclosure relates to a device including a substrate, having a top surface and a bottom surface; an array of nanowires having a base and a top surface, the base contacting the top surface of the substrate; a contacting structure including the same material as the substrate having a non-nanostructured surface of a dimension suitable for forming an electrical contact, located on the same side of the substrate as the array of silicon nanowires; wherein the contacting structure is doped with a greater impurity concentration than the nanowire array, thereby forming a selective emitter.

Abstract: A process is provided for contacting a nanostructured surface. The process may include (a) providing a substrate having a nanostructured material on a surface, (b) passivating the surface on which the nanostructured material is located, (c) screen printing onto the nanostructured surface and (d) firing the screen printing ink at a high temperature. In some embodiments, the nanostructured material compromises silicon. In some embodiments, the nanostructured material includes silicon nanowires. In some embodiments, the nanowires are around 150 nm, 250 nm, or 400 nm in length. In some embodiments, the nanowires have a diameter range between about 30 nm and about 200 nm. In some embodiments, the nanowires are tapered such that the base is larger than the tip. In some embodiments, the nanowires are tapered at an angle of about 1 degree, about 3 degrees, or about 10 degrees. In some embodiments, a high temperature can be approximately 700C, 750C, 800C, or 850C.

Abstract: A process is provided for contacting a nanostructured surface. In that process, a substrate is provided having a nanostructured material on a surface, the substrate being conductive and the nanostructured material being coated with an insulating material. A portion of the nanostructured material is at least partially removed. A conductor is deposited on the substrate in such a way that it is in electrical contact with the substrate through the area where the nanostructured material has been at least partially removed.

Abstract: Another aspect of the present disclosure relates to a device including a substrate, having a top surface and a bottom surface; an array of nanowires having a base and a top surface, the base contacting the top surface of the substrate; a contacting structure including the same material as the substrate having a non-nanostructured surface of a dimension suitable for forming an electrical contact, located on the same side of the substrate as the array of silicon nanowires; wherein the contacting structure is doped with a greater impurity concentration than the nanowire array, thereby forming a selective emitter.

Abstract: A secure media device preferably includes a Universal Serial Bus (USB) Mass Storage Class (MSC) interface. A storage media area is also preferably provided. The storage media is preferably divided into a first and second area by arranging the storage media into multiple Logical Units (LUNs). The second area is preferably accessed in a conventional manner using a host USB MSC driver through the USB MSC interface on the storage device. A password dialog application can be located in the second area of the storage device.