A computer system for verifying vehicle software configuration may be provided. The computer system may include a processor and a non-transitory, tangible, computer-readable storage medium having instructions stored thereon that, in response to execution by the processor, cause the processor to: (1) transmit, to a vehicle computing system, an authentication request including a hash algorithm specification; (2) receive, from the vehicle computing system, a current configuration hash value and a vehicle identifier; (3) retrieve a trusted data block from a memory based upon the vehicle identifier, the trusted data block including a stored configuration hash value and a smart contract code segment; (4) execute the smart contract code segment, the smart contract code segment including a failsafe code segment; and/or (5) transmit the authentication response to the vehicle computing system, and cause the vehicle computing system to execute the failsafe code segment.

A self-adaptive security framework for a device is disclosed. A first security level for a device is set wherein the first security level comprises procedures that authenticate a user and allow the user to access the device. Input from sensors associated with the device may be received at a contextual sensing engine, wherein the input at least includes location data, and wherein at least a portion of the input is related to a physical setting where the device is located. A threat level for the device is determined in the physical setting via the contextual sensing engine based on analyzing the input. The first security level is altered to a second security level to provide an altered threat response for the device based on the threat level wherein the second security level has different procedures to authenticate the user compared to the first security level.

A method for performing authentication in a portable electronic device is provided. The method includes identifying whether a peripheral electronic device is located within a certain distance from the portable electronic device, receiving biometrics information from the peripheral electronic device when the peripheral electronic device is located within the certain distance from the portable electronic device, identifying whether the biometrics information received from the peripheral electronic device is identical to biometrics information stored in the portable electronic device, and releasing security set to the portable electronic device when the biometrics information received from the peripheral electronic device is identical to the biometrics information stored in the portable electronic device.

Embodiments of the invention are directed to a system, method, or computer program product for aggregation of machine-initiated resource distribution. The invention generates a smart device portal for linkage of user associated smart devices. The portal generates code to extract data from the smart devices and control the communications disseminated from and received by the smart device from third parties. Thus, the generated portal and coded stored signal fixes the technical challenges within the current network including the need to consolidate and aggregate data across smart devices associated with the user, the need to control and manage the flow of data packets from smart devices to third parties (privacy, filtering, protection), and the need to easily track and refresh an inventory of smart devices in a manner that allows key data to remain associated with the user while the user's inventory, device associations, and personal/business associations change over time.

Techniques for neutralizing malicious malware embedded in a media item being sent to a user equipment (UE) are discussed herein. A network device may receive (e.g., intercept) a medial file in transit via a wireless communication network being sent to a UE. The media file may include some type of perceptible content (e.g., audio, video, image data, etc.) as well as malware embedded in the media file. The network device may generate a transcoded media file based on the received media file that includes the perceptible content while neutralizing the malware.

Techniques for neutralizing malicious malware embedded in a media item being sent to a user equipment (UE) are discussed herein. A network device may receive (e.g., intercept) a medial file in transit via a wireless communication network being sent to a UE. The media file may include some type of perceptible content (e.g., audio, video, image data, etc.) as well as malware embedded in the media file. The network device may generate a transcoded media file based on the received media file that includes the perceptible content while neutralizing the malware.

In some implementations, (i) audio data representing a voice command spoken by a speaker and (ii) a speaker identification result indicating that the voice command was spoken by the speaker are obtained. A voice action is selected based at least on a transcription of the audio data. A service provider corresponding to the selected voice action is selected from among a plurality of different service providers. One or more input data types that the selected service provider uses to perform authentication for the selected voice action are identified. A request to perform the selected voice action and (i) one or more values that correspond to the identified one or more input data types are provided to the service provider.

In a first embodiment, the “one tap” operation of this disclosure enables a user having a mobile device “one tap” mobile application (or “app”) to log-in to the user's desktop or laptop computer by bringing the user's device in physical proximity to the computer and, while in such proximity, accepting a push notification that is received on the mobile device. In a second embodiment, the user uses the “one tap” functionality to access a cloud-based account that has been set up for the user on a third party web application (e.g., SalesForce.com). The technique seamlessly integrates with third party websites using well-known protocols (e.g., SAML2), and it enables secure cross-origin resource sharing in a highly secure, reliable and available manner. Still another aspect of this disclosure is an enhanced proximity detection routine that is used to facilitate the one tap function when the user's mobile device is moved into proximity with the computer.

Systems and methods are provided for securing data using a mobile device. The method may include determining securing global positioning data values of the mobile device; measuring a securing direction of the mobile device relative to a magnetic north direction; capturing a securing password by the mobile device; and securing the data against unauthorized access using the determined global positioning data values, the securing password, and the securing direction as a combined password.

A system includes a plurality of storage units each including a network port operably coupled to the network, where one or more storage vaults is associated with the plurality of storage units and each storage vault of the one or more storage vaults represents a software-constructed grouping of storage units of the plurality of storage units, where the software-constructed grouping of storage units stores encoded data slices, where a data segment is encoded using an information dispersal algorithm to produce the encoded data slices, and where a storage unit: receives, via the network port, a request regarding the data segment stored in the software-constructed grouping of storage units, obtains, from a data structure pertaining to the software-constructed grouping of storage units, information regarding the request, determines whether the request is valid based on the information regarding the request, and when the request is valid, the storage unit executes the request.