Abstract: A distributed key management system (KMS) includes a central KMS server and multiple intermediate KMS servers. The central KMS server replicates managed keys to the intermediate KMS servers. An intermediate KMS server receives a KMS service request from a KMS client, where any of the intermediate KMS servers are capable of servicing the request. The intermediate KMS server performs the action requested if it has access to the necessary managed key and returns the response to the KMS client. If it does not have access to the necessary managed key, the intermediate KMS server transmits a request for the managed key to the central KMS server. The intermediate KMS server receives the managed key, performs the action requested, and returns the response to the KMS client.

Abstract: A first intermediate key management system (KMS) server of a distributed KMS receives a key lookup service (KLS) query from a KMS client for determining an identity of KMS server(s) that are capable of performing a first operation with a first managed key. The first intermediate KMS server is one of the intermediate KMS servers of the distributed KMS. The first KMS server determines the identity of one or more of the KMS servers that are capable of performing the first operation with the first managed key. The first KMS server transmits a KLS response to the KMS client that includes the identity of the KMS server(s) that are capable of performing the first operation with the first managed key.

Abstract: A distributed key management system (KMS) includes a central KMS server and multiple intermediate KMS servers. The central KMS server replicates managed keys to the intermediate KMS servers. An intermediate KMS server receives a KMS service request from a KMS client, where any of the intermediate KMS servers are capable of servicing the request. The intermediate KMS server performs the action requested if it has access to the necessary managed key and returns the response to the KMS client. If it does not have access to the necessary managed key, the intermediate KMS server transmits a request for the managed key to the central KMS server. The intermediate KMS server receives the managed key, performs the action requested, and returns the response to the KMS client.

Abstract: A method for producing a volume change compensated (SSLC) material is disclosed. An initially prelithiated SSLC material is produced and delithiated to produce a delithiated SSLC material. Perform at least one iteration involving: (a) re-prelithiating the delithiated SSLC material to produce a re-prelithiated SSLC material; and (b) delithiating the re-prelithiated SSLC material produced in (a). At least one of the following is satisfied: (i) prior to performing the at least one iteration the initially prelithiated SSLC material is essentially completely lithiated; and (ii) at least one iteration produces a re-prelithiated SSLC material that is essentially completely prelithiated. In a final iteration, delithiating the re-prelithiated SSLC material produced in (a) completely delithiates the re-prelithiated SSLC material to produce the volume change compensated SSLC material.

Abstract: A process for producing a silicon:silicon oxide:lithium composite (SSLC) material useful as a negative electrode active material for non-aqueous battery cells includes: producing a partially lithiated SSLC material by way of mechanical mixing; subsequently producing a further prelithiated SSLC material by way of spontaneous lithiation procedure; and subsequently producing a delithiated SSLC material by way of reacting lithium silicide within the dispersed prelithiated SSLC material with organic solvent(s) to extract lithium from the prelithiated SSLC material, until reactivity of lithium silicide within the prelithiated SSLC material with the organic solvent(s) ceases. The delithiated SSLC material is a porous plastically deformable matrix having nano silicon embedded therein. The delithiated SSLC material can have a lithium silicide content of less than 0.5% by weight.

Abstract: A method of managing application installation is provided. The method includes receiving an application by an electronic device, determining an application signature key included in the application, if the application signature key matches a development signature key among the development signature key and a commercial signature key, verifying the application signature key in relation to whether the electronic device corresponds to information on a test electronic device defined in the application signature key, and installing the application based on a verification result of the application signature key.

Abstract: An electronic device comprising: a memory; and at least one processor configured to: install an application by using an installation file associated with the application; grant at least one permission to the application based on a permission setting token that is included in the installation file; and store, in a database, an indication that the application is granted the permission.

Abstract: An electronic device is provided. The electronic device includes a processor, a memory configured to connect to the processor, and an embedded secure element (eSE) configured to connect to the processor over a physical channel to receive secure data sent by the processor over the physical channel, and store the secure data.

Abstract: A method for producing a volume change compensated silicon: silicon oxide: lithium composite (SSLC) material is disclosed. The method includes producing an initially prelithiated SSLC material; delithiating the initially prelithiated material to produce a delithiated SSLC material; and performing at least one iteration of a volume change compensation process involving: (a) re-prelithiating the delithiated SSLC material to produce a re-prelithiated SSLC material; and (b) delithiating the re-prelithiated SSLC material produced in (a), wherein at least one of the following is satisfied: (i) prior to performing the at least one iteration of the volume change compensation process the initially prelithiated SSLC material is essentially completely lithiated; and (ii) at least one iteration of the volume change compensation process produces a re-prelithiated SSLC material that is essentially completely prelithiated.

Abstract: A process for producing a silicon:silicon oxide:lithium composite (SSLC) material useful as a negative electrode active material for non-aqueous battery cells includes: producing a partially lithiated SSLC material by way of mechanical mixing; subsequently producing a further prelithiated SSLC material by way of spontaneous lithiation procedure; and subsequently producing a delithiated SSLC material by way of reacting lithium silicide within the dispersed prelithiated SSLC material with organic solvent(s) to extract lithium from the prelithiated SSLC material, until reactivity of lithium silicide within the prelithiated SSLC material with the organic solvent(s) ceases. The delithiated SSLC material is a porous plastically deformable matrix having nano silicon embedded therein. The delithiated SSLC material can have a lithium silicide content of less than 0.5% by weight.

Abstract: A process for producing a silicon:silicon oxide: lithium composite (SSLC) material useful as a negative electrode active material for non-aqueous battery cells includes: producing a partially lithiated SSLC material by way of mechanical mixing; subsequently producing a further prelithiated SSLC material by way of spontaneous lithiation procedure; and subsequently producing a delithiated SSLC material by way of reacting lithium silicide within the dispersed prelithiated SSLC material with organic solvent(s) to extract lithium from the prelithiated SSLC material, until reactivity of lithium silicide within the prelithiated SSLC material with the organic solvent(s) ceases. The delithiated SSLC material is a porous plastically deformable matrix having nano silicon embedded therein. The delithiated SSLC material can have a lithium silicide content of less than 0.5% by weight.

Abstract: A system and method for changing authority for a secure booting operation and an electronic device thereof are provided. The system includes a memory including a plurality of key bit areas in each of which a root key can be received, and a processor core configured to input a new root key to one of the plurality of key bit areas of the memory in response to an external input.

Abstract: A method of managing keys and an electronic device adapted to the method are provided. The method includes creating a first key, based on information included in a memory space of a processor, creating a second key, based on at least one item of user information, and creating a third key that was created through at least one encryption process, based on the created first key and the created second key.

Abstract: A process for producing a silicon:silicon oxide: lithium composite (SSLC) material useful as a negative electrode active material for non-aqueous battery cells includes: producing a partially lithiated SSLC material by way of mechanical mixing; subsequently producing a further prelithiated SSLC material by way of spontaneous lithiation procedure; and subsequently producing a delithiated SSLC material by way of reacting lithium silicide within the dispersed prelithiated SSLC material with organic solvent(s) to extract lithium from the prelithiated SSLC material, until reactivity of lithium silicide within the prelithiated SSLC material with the organic solvent(s) ceases. The delithiated SSLC material is a porous plastically deformable matrix having nano silicon embedded therein. The delithiated SSLC material can have a lithium silicide content of less than 0.5% by weight.

Abstract: An electronic device is provided. The electronic device includes a processor, a memory configured to connect to the processor, and secure circuitry configured to connect to the processor over a physical channel receive data sent by the processor over the physical channel, and store the data.

Abstract: An electronic device comprising: a memory; and at least one processor configured to: install an application by using an installation file associated with the application; grant at least one permission to the application based on a permission setting token that is included in the installation file; and store, in a database, an indication that the application is granted the permission.

Abstract: An apparatus and method for analyzing malware in a data analysis system are provided. The apparatus includes a data analysis unit and a controller. The data analysis unit sorts data into primary harmful data and primary harmless data using screening data information of malicious code information and virus information. The controller screens or deletes the primary harmful data, and sends a request for precision analysis of the primary harmless data to a server. The data analysis unit sorts secondary harmful data from the primary harmless data using the precision analysis result received from the server.

Abstract: A method of managing keys and an electronic device adapted to the method are provided. The method includes creating a first key, based on information included in a memory space of a processor, creating a second key, based on at least one item of user information, and creating a third key that was created through at least one encryption process, based on the created first key and the created second key.

Abstract: A method of managing application installation is provided. The method includes receiving an application by an electronic device, determining an application signature key included in the application, if the application signature key matches a development signature key among the development signature key and a commercial signature key, verifying the application signature key in relation to whether the electronic device corresponds to information on a test electronic device defined in the application signature key, and installing the application based on a verification result of the application signature key.

Abstract: A system and method for changing authority for a secure booting operation and an electronic device thereof are provided. The system includes a memory including a plurality of key bit areas in each of which a root key can be received, and a processor core configured to input a new root key to one of the plurality of key bit areas of the memory in response to an external input.