Abstract: The disclosure herein relates to rechargeable batteries and solid electrolytes therefore which include lithium-stuffed garnet oxides, for example, in a thin film, pellet, or monolith format wherein the density of defects at a surface or surfaces of the solid electrolyte is less than the density of defects in the bulk. In certain disclosed embodiments, the solid-state anolyte, electrolyte, and catholyte thin films, separators, and monoliths consist essentially of an oxide that conducts Li+ ions. In some examples, the disclosure herein presents new and useful solid electrolytes for solid-state or partially solid-state batteries. In some examples, the disclosure presents new lithium-stuffed garnet solid electrolytes and rechargeable batteries which include these electrolytes as separators between a cathode and a lithium metal anode.

Abstract: Disclosed herein an effective detach strategy which suppresses the flow of gradients from context sub-networks through the detection backbone path to obtain a more discriminative context by forcing the representation of context sub-network to be dissimilar from the detection network. A sub-network is defined to generate the context information from early layers of the detection backbone. Because instance and context focus on perceptually different parts of an image, the representations from either of them should also be discrepant. In addition, a stacked complementary loss is generated to and backpropagated to the detection network.

Abstract: The disclosure herein relates to rechargeable batteries and solid electrolytes therefore which include lithium-stuffed garnet oxides, for example, in a thin film, pellet, or monolith format wherein the density of defects at a surface or surfaces of the solid electrolyte is less than the density of defects in the bulk. In certain disclosed embodiments, the solid-state anolyte, electrolyte, and catholyte thin films, separators, and monoliths consist essentially of an oxide that conducts Li+ ions. In some examples, the disclosure herein presents new and useful solid electrolytes for solid-state or partially solid-state batteries. In some examples, the disclosure presents new lithium-stuffed garnet solid electrolytes and rechargeable batteries which include these electrolytes as separators between a cathode and a lithium metal anode.

Abstract: Provided herein are detect-free solid-state separators which are useful as Li| ion-conducting electrolytes in electro-chemical cells and devices, such as, but not limited to, rechargeable batteries. In some examples, the separators have a Li+ ion-conductivity greater than 1*10?3 S/cm at room temperature.

Abstract: Provided herein are defect-free solid-state separators which are useful as Li+ ion-conducting electrolytes in electrochemical cells and devices, such as, but not limited to, rechargeable batteries. In some examples, the separators have a Li+ ion-conductivity greater than 1*10?3 S/cm at room temperature.

Abstract: The present disclosure relates generally to managing access to an enterprise system using remote devices. Techniques are disclosed for provisioning applications on remote devices to access resources in an enterprise system. Specifically, applications may be automatically configured with access information (e.g., account information) and connection information to access a resource in an enterprise system using a remote device. Configuring an application may include determining an account for accessing a resource using the application. An account may be provisioned if one has not been established. Upon configuring an application, the device access management system may provide a configured application to the remote device(s) for which the application is configured. Once the configured application is received, the application may be automatically installed on the remote device, after which the application may be executed to access a resource.

Abstract: Techniques are disclosed for implementation of a data storage device as a security device for managing access to resources. These techniques can be implemented for multi-factor authentication (MFA) to provide multiple layers of security for managing access to resources in an enterprise and/or a cloud computing environments. As a security device, a storage device can be used a portable device to provide a point of trust for multi-factor authentication across any client application or device operated to access resources. A storage device may be configured with security data for authentication with an access management system. After configuration, a portable storage device may be used for authentication of a user without credential information at any client device based on accessibility of the device to the portable storage device. A storage device configured as a security device can ensure that legitimate users have an easy way to authenticate and access the resources.

Abstract: Provided herein are defect-free solid-state separators which are useful as Li+ ion-conducting electrolytes in electrochemical cells and devices, such as, but not limited to, rechargeable batteries. In some examples, the separators have a Li+ ion-conductivity greater than 1*10?3 S/cm at room temperature.

Abstract: The disclosure herein relates to rechargeable batteries and solid electrolytes therefore which include lithium-stuffed garnet oxides, for example, in a thin film, pellet, or monolith format wherein the density of defects at a surface or surfaces of the solid electrolyte is less than the density of defects in the bulk. In certain disclosed embodiments, the solid-state anolyte, electrolyte, and catholyte thin films, separators, and monoliths consist essentially of an oxide that conducts Li+ ions. In some examples, the disclosure herein presents new and useful solid electrolytes for solid-state or partially solid-state batteries. In some examples, the disclosure presents new lithium-stuffed garnet solid electrolytes and rechargeable batteries which include these electrolytes as separators between a cathode and a lithium metal anode.

Abstract: Techniques are disclosed for implementation of a data storage device as a security device for managing access to resources. These techniques can be implemented for multi-factor authentication (MFA) to provide multiple layers of security for managing access to resources in an enterprise and/or a cloud computing environments. As a security device, a storage device can be used a portable device to provide a point of trust for multi-factor authentication across any client application or device operated to access resources. A storage device may be configured with security data for authentication with an access management system. After configuration, a portable storage device may be used for authentication of a user without credential information at any client device based on accessibility of the device to the portable storage device. A storage device configured as a security device can ensure that legitimate users have an easy way to authenticate and access the resources.

Abstract: The present disclosure relates generally to managing access to an enterprise system using remote devices. Techniques are disclosed for provisioning applications on remote devices to access resources in an enterprise system. Specifically, applications may be automatically configured with access information (e.g., account information) and connection information to access a resource in an enterprise system using a remote device. Configuring an application may include determining an account for accessing a resource using the application. An account may be provisioned if one has not been established. Upon configuring an application, the device access management system may provide a configured application to the remote device(s) for which the application is configured. Once the configured application is received, the application may be automatically installed on the remote device, after which the application may be executed to access a resource.

Abstract: Techniques are disclosed for implementation of a data storage device as a security device for managing access to resources. These techniques can be implemented for multi-factor authentication (MFA) to provide multiple layers of security for managing access to resources in an enterprise and/or a cloud computing environments. As a security device, a storage device can be used a portable device to provide a point of trust for multi-factor authentication across any client application or device operated to access resources. A storage device may be configured with security data for authentication with an access management system. After configuration, a portable storage device may be used for authentication of a user without credential information at any client device based on accessibility of the device to the portable storage device. A storage device configured as a security device can ensure that legitimate users have an easy way to authenticate and access the resources.

Abstract: Techniques for providing enrollment services for various types of electronic devices in a communication network is disclosed. The electronic devices may include devices associated with a user and headless devices not associated with any user. In certain embodiments, a device enrollment system is disclosed that controls the authentication and enrollment of both user devices and headless devices within a communication network. The device enrollment system detects a particular device within a communication, identifies a type of enrollment policy to be applied to the device based on a type of the device, applies a set of enrollment rules to the device in accordance with the enrollment policy and enrolls the device if the device satisfies one or more criteria specified by the enrollment rules.

Abstract: Techniques are disclosed for communicating to remote devices information about change events related to changes in access to an enterprise system. A device access management system may facilitate communication about a change event to the remote devices. Information about a change event may be stored in a change event object based on the type of change event (e.g., a policy change, an application change, and a settings change). A change event queue may persistently store information corresponding to change events. One or more computing nodes may be scheduled to execute an action process for each change event based on the type of the change event. A computing node may communicate information (e.g., an instruction to implement adjust access) about a change event to remote devices. A change event may persist on the queue until all remote devices are notified about the change event.

Abstract: The present disclosure relates generally to managing access to an enterprise system using remote devices. Techniques are disclosed for provisioning applications on remote devices to access resources in an enterprise system. Specifically, applications may be automatically configured with access information (e.g., account information) and connection information to access a resource in an enterprise system using a remote device. Configuring an application may include determining an account for accessing a resource using the application. An account may be provisioned if one has not been established. Upon configuring an application, the device access management system may provide a configured application to the remote device(s) for which the application is configured. Once the configured application is received, the application may be automatically installed on the remote device, after which the application may be executed to access a resource.

Abstract: Techniques are disclosed for implementation of a data storage device as a security device for managing access to resources. These techniques can be implemented for multi-factor authentication (MFA) to provide multiple layers of security for managing access to resources in an enterprise and/or a cloud computing environments. As a security device, a storage device can be used a portable device to provide a point of trust for multi-factor authentication across any client application or device operated to access resources. A storage device may be configured with security data for authentication with an access management system. After configuration, a portable storage device may be used for authentication of a user without credential information at any client device based on accessibility of the device to the portable storage device. A storage device configured as a security device can ensure that legitimate users have an easy way to authenticate and access the resources.

Abstract: The present disclosure relates generally to managing compliance of remote devices that access an enterprise system. More particularly, techniques are disclosed for using a compliance policy to manage remediation of non-compliances of remote devices that access an enterprise system. A device access management system may be implemented to automate remediation of non-compliances of remote devices accessing an enterprise system. Remediation may be controlled based on different levels of non-compliance, each defined by one or more different non-compliances. In some embodiments, a level of non-compliance may be conditionally defined by one or more user roles for which non-compliance is assessed. Access to computing resources of an enterprise system may be controlled for a remote device based on compliance of the remote device. Access may be inhibited for those resources not permitted during a time period of a non-compliance.

Abstract: Techniques for providing enrollment services for various types of electronic devices in a communication network is disclosed. The electronic devices may include devices associated with a user and headless devices not associated with any user. In certain embodiments, a device enrollment system is disclosed that controls the authentication and enrollment of both user devices and headless devices within a communication network. The device enrollment system detects a particular device within a communication, identifies a type of enrollment policy to be applied to the device based on a type of the device, applies a set of enrollment rules to the device in accordance with the enrollment policy and enrolls the device if the device satisfies one or more criteria specified by the enrollment rules.

Abstract: The present disclosure relates generally to managing compliance of remote devices that access an enterprise system. More particularly, techniques are disclosed for using a compliance policy to manage remediation of non-compliances of remote devices that access an enterprise system. A device access management system may be implemented to automate remediation of non-compliances of remote devices accessing an enterprise system. Remediation may be controlled based on different levels of non-compliance, each defined by one or more different non-compliances. In some embodiments, a level of non-compliance may be conditionally defined by one or more user roles for which non-compliance is assessed. Access to computing resources of an enterprise system may be controlled for a remote device based on compliance of the remote device. Access may be inhibited for those resources not permitted during a time period of a non-compliance.

Abstract: Techniques for providing enrollment services for various types of electronic devices in a communication network is disclosed. The electronic devices may include devices associated with a user and headless devices not associated with any user. In certain embodiments, a device enrollment system is disclosed that controls the authentication and enrollment of both user devices and headless devices within a communication network. The device enrollment system detects a particular device within a communication, identifies a type of enrollment policy to be applied to the device based on a type of the device, applies a set of enrollment rules to the device in accordance with the enrollment policy and enrolls the device if the device satisfies one or more criteria specified by the enrollment rules.