Abstract: The invention provides in one aspect a drug delivery device comprising a drug container assembly containing a drug, and a plunger positioned within the container assembly, the drug container assembly having an outlet for dispensing the drug, wherein, in an initial position, the outlet is sealed; a drive mechanism comprising a first stored energy source operable to apply pressure on the plunger or the drug container to pressurise the drug, and a first release mechanism operable to unseal the outlet after the drug has been pressurised.

Abstract: Various embodiments provide methods for validating hardware modifications of an IHS (Information Handling System) by confirming that a hardware modification corresponds to a hardware component supplied for installation in the IHS by a trusted entity. During factory provisioning of an IHS, an inventory certificate that specifies the factory installed IHS hardware is uploaded to the IHS and is also stored for ongoing support of the IHS. Upon a hardware component being supplied for installation in the IHS by a trusted entity, the inventory of the stored inventory certificate is updated to identify the supplied component and the updated certificate is transmitted to the IHS. An inventory of detected hardware components of the IHS is compared against the inventory from the updated inventory certificate in order to validate the detected hardware of the IHS includes the component, supplied by the trusted entity, that is identified in the updated inventory certificate.

Abstract: Methods and system are provided for validating the secure assembly and delivery of an IHS (Information Handling System). During factory provisioning of the IHS, an inventory certificate is uploaded to the IHS. The certificate includes: an inventory of hardware components installed during factory assembly of the IHS, validation schemas the provide instructions for identifying the hardware components, and digital signatures used to confirm the integrity of the validation schemas. Upon delivery of the IHS, a validation process retrieves the inventory certificate and confirms the integrity of the validation schemas. Based on validation schema instructions, the validation process collects an inventory of the detected IHS hardware. The validation schema instructions are further used to compare the collected inventory against the inventory from the inventory certificate in order to validate the detected hardware components of the IHS as the same hardware components installed during factory assembly of the IHS.

Abstract: Various embodiments provide methods for validating secure assembly and delivery of an IHS (Information Handling System) by confirming that the detected hardware components of the IHS include only factory installed hardware components. During factory provisioning of an IHS, an inventory certificate is uploaded to the IHS, where the inventory certificate includes an inventory that identifies the hardware components installed during factory assembly of the IHS. An inventory is collected of the detected hardware components of the IHS. The collected inventory is compared against the inventory from the inventory certificate in order to validate the detected hardware components of the IHS as the same hardware components that were installed during factory assembly of the IHS. Embodiments provide a customer receiving an IHS with a capability of validating that a delivered IHS includes only factory installed hardware components.

Abstract: Embodiments support remote validation of the secure assembly and delivery of an IHS (Information Handling System). A validation process of the IHS initiates a remote management connection with a remote management console. The remote management console retrieves an inventory certificate generated during factory provisioning of the IHS and stored to the IHS and/or to a remote location. The inventory certificate includes an inventory identifying a plurality of hardware components installed during factory assembly of the IHS. The remote management console retrieves an inventory of detected hardware components of the IHS and compares the inventory of detected hardware components against the inventory from the inventory certificate in order to validate the detected hardware components of the IHS as the same hardware components installed during factory assembly of the IHS.

Abstract: Embodiments support secure booting of an IHS (Information Handling System) based on validation of the secure assembly and delivery of the IHS. A validation process of the IHS is initialized that delays further booting of the IHS until detected hardware components of the IHS are validated. An inventory certificate is retrieved that was uploaded to the IHS during factory provisioning of the IHS. The inventory certificate includes an inventory that identifies hardware components installed during factory assembly of the IHS. A collected inventory of detected hardware components of the IHS is compared against the inventory from the inventory certificate in order to validate the detected hardware components of the IHS as the same hardware components installed during factory assembly of the IHS. When the comparison validates the detected hardware components of the IHS as only including factory assembled hardware, further booting of the IHS is allowed.

Abstract: Embodiments validate the secure assembly and delivery of IHSs (Information Handling Systems) that are installed in a shared chassis, such as two 1RU (rack unit) servers installed in a shared 2RU chassis. An inventory certificate is retrieved that was uploaded to a first IHS of the IHSs installed in the shared chassis during factory provisioning of the first IHS. The inventory certificate specifies factory installed hardware components installed in each of the IHSs of the shared chassis. A validation process of the first IHS collects an inventory of hardware components detected by each of the IHSs of the shared chassis. The validation process compares the collected inventory of detected hardware components of the IHSs against the factory installed hardware components specified in the inventory certificate in order to validate the detected hardware components as the same hardware components installed during factory assembly of each of the IHSs.

Abstract: Methods and system are provided for validating the secure assembly and delivery of an IHS (Information Handling System). During factory provisioning of the IHS, an inventory certificate is uploaded to the IHS, where the certificate includes an inventory of the hardware components installed during factory assembly of the IHS and also includes validation schemas the provide instructions for identifying hardware components of the IHS. Upon delivery of the assembled IHS, a validation process is initialized and the inventory certificate is retrieved. Based on the instructions set forth by the validation schemas, the validation process collects an inventory of the detected hardware components of the IHS. The instructions of the validation schemas are further used to compare the collected inventory against the inventory from the signed inventory certificate in order to validate the detected hardware components of the IHS as the same hardware components installed during factory assembly of the IHS.

Abstract: Embodiments provide methods for validating secure delivery of an IHS (Information Handling System) by confirming that the packages by which the IHS was delivered include only the packages used to ship the IHS from a factory or other trusted entity. During factory provisioning of the IHS, a shipping certificate is uploaded to the IHS, where the certificate includes shipping identifiers that are each associated with a package used to ship the IHS. Upon receiving packages by which the IHS has been shipped, shipping identifiers, such as bar codes and RFID codes, are collected from the received packages. The shipping identifiers collected from the received packages are compared against the shipping identifiers from the shipping certificate in order to validate the plurality of received packages as the same packages that were used to ship the IHS.

Abstract: A method for producing an agglomerated solid bio-material comprises providing a particulate torrefied wood mass or a comminuted wood mass and blending with a particulate melt-flowable extract (MFE) recovered from an organosolv pulping process. The particulate torrefied biomass or the comminuted biomass is blended with the MFE to form a blended mixture wherein the particulate torrefied bio-mass or the comminuted wood mass is the primary component. The blend is agglomerated under pressure at a temperature of at least approximately 38° C. (100° F.) to form the agglomerated solid material which exhibits hydrophobic characteristics.

Abstract: A watermark image may be generated that includes a first set of encoded pixels each of which is assigned a first transparency value and a second set of encoded pixels each of which is assigned a second transparency value, the second transparency level being different from the first transparency level. The encoded pixels may be distributed among a set of blank pixels such that each encoded pixel neighbors one or more blank pixels in the watermark image, and in particular at least two blank pixels in the watermark image. Herein, each blank pixel may be assigned the second transparency value. The watermark image may be overlaid and blended over a background source image to create an encoded source image. A decoder system may recover encoded information from the encoded source image.

Abstract: The invention provides in one aspect a drug delivery device comprising a drug container assembly containing a drug, and a plunger positioned within the container assembly, the drug container assembly having an outlet for dispensing the drug, wherein, in an initial position, the outlet is sealed; a drive mechanism comprising a first stored energy source operable to apply pressure on the plunger or the drug container to pressurise the drug, and a first release mechanism operable to unseal the outlet after the drug has been pressurised.

Abstract: A method for verifying licenses is performed by a legacy management controller (LMC) and a non-legacy management controller (NLMC). The method includes obtaining, by the LMC, a first license installation request and a license, wherein the license comprises license data and a plurality of signatures; in response to the first license installation request: making a first determination, by the LMC, that a first signature of the plurality of signatures is valid; in response to the first determination: installing, by the LMC, the license on the LMC; obtaining, by the NLMC, a second license installation request and the license; in response to the second license installation request: making a second determination, by the NLMC, that a second signature of the plurality of signatures is valid; and in response to the second determination: installing, by the NLMC, the license on the NLMC.

Abstract: A folding play structure is provided. The play structure is convertible between a storage position and a use position, and has first, second, third and fourth sidewalls. A center beam is positioned between the first sidewall and the second sidewall. A first foldable frame structure joins one end of the first sidewall to one end of the second sidewall, and a second foldable frame structure joins the other end of the first sidewall to the other end of the second sidewall. A frame lock is provided and is prevented from moving when the play structure is in the use position to retain the structure in the use position. The structure has legs, a slide and a ladder.

Abstract: In one embodiment, a device maintains a metamodel that describes a monitored system. The metamodel comprises a plurality of layers ranging from a sub-symbolic space to a symbolic space. The device tracks updates to the metamodel over time. The device updates the metamodel based in part on sub-symbolic time series data generated by the monitored system. The device receives, from a learning agent, a request for the updates to a particular layer of the metamodel associated with a specified time period. The device provides, to the learning agent, data indicative of one or more updates to the particular layer of the metamodel associated with the specified time period.

Abstract: A computer-implemented method for protecting user identity within online content providing environments uses a security content management system (CMS) including at least one processor and a memory. The method includes identifying a request for an online content item associated with an online device. The online device is associated with actual device data. The method also includes determining a first characteristic value associated with the actual device data of the online device. The method further includes generating, by the processor, substitute device data. The substitute device data represents at least the first characteristic value. The method also includes providing the substitute device data to an online content provider.

Abstract: Embodiments of the present disclosure describe binder materials from birch bark, methods of making the binder materials, fuel compositions comprising the binder materials, methods of forming the fuel compositions in the form of pellets and/or briquettes, and the like.

Abstract: Embodiments of the present disclosure describe water-resistant and durably high energy-density binder materials from cutin-containing materials, methods of making the binder materials, fuel compositions comprising the binder materials, methods of forming the fuel compositions in the form of pellets and/or briquettes, and the like.

Abstract: An automatic drug delivery device is described, comprising: a housing (1); a skin sensor element (15) coupled to the housing and movable relative to the housing, wherein the skin sensor element is biased into a front position relative to the housing and is movable to a rear position relative to the housing when the skin sensor element is pressed against an injection site; a needle assembly comprising a hypodermic needle (11), the hypodermic needle extending outside of the housing when the device is in a needle insertion configuration; a drug delivery mechanism comprising a stored energy source (4), within the housing; wherein the drug delivery mechanism is released when the skin sensor element is moved from the front position towards the rear position and wherein the stored energy source is arranged to expand along an axis that is offset from an axis of travel of the needle assembly in use; a needle retraction mechanism configured to withdraw the hypodermic needle into the housing when the needle retraction m

Abstract: Systems and methods are provided for configuring automatic playback settings on a media playback device. A graphical user interface displays automatic playback settings and receives selections of customized settings for automatic playback. The settings can include context granularity for automatic playback, limiting autoplay to when the media playback device is connected to a wireless network, and activating an audible notification when automatic playback of media content is beginning. An initial queue of media content is selected for playback on the media playback device. The system ascertains whether autoplay is enabled for a particular situation. If autoplay is enabled, the system automatically generates a queue of media that is related to the initial queue and initiates playback on the media playback device after the initial queue concludes.