A vehicle system may include a memory of a vehicle configured to maintain at least one smart contract between a manufacturer of the vehicle and a supplier of components to the manufacturer, and a processor of the vehicle configured to receive at least one diagnostic code from the vehicle, the diagnostic code being associated with at least one vehicle component, in response to the code being identified by the processor as being associated with the at least one smart contract, update the at least one smart contract within the memory with the code, and transmit the smart contract, as updated, to a third party associated with the vehicle component.

Systems, methods, and computer programmable products are described herein for situational handling using a virtual reality application. A procurement system receives an order including one or more goods and a situation. A cloud platform receives sensor data of a package containing the one or more goods. A scanner scans the package and a storage location of the package. The procurement system provides the storage location to an virtual reality (VR) application for display and a notification of the situation once it occurs.

A device configured to obtain a first graphical code that represents a public encryption key for an organization and to extract the public encryption key for the organization from the first graphical code. The device is further configured to obtain a second graphical code that represents a digital document comprising data and a digital signature that was signed using a private encryption key for the organization. The device is further configured to extract the digital document from the second graphical code and to validate the second graphical code using the public encryption key for the organization. The device is further configured to determine the second graphical code passes validation using the public encryption key for the organization and to store the digital document in a digital document repository.

A vehicle is provided that comprises two or more radio frequency (RF) antennas and two or more RF transceivers to communicate wirelessly sensitive information associated with a user of the vehicle (the two or more RF antennas being at different physical locations on an exterior of the vehicle). The vehicle determines which one of the two or more RF antennas is receiving a strongest signal from a common signal source, selects a first RF transceiver associated with the RF antenna with the strongest signal to send the sensitive information associated with the user to the common signal source, and sends the sensitive information associated with the user to the first RF transceiver for transmission to the common signal source.

A method of monitoring a health of a transportation refrigeration unit including: receiving at least one of an alarm of one or more components of the transportation refrigeration unit, test data on the one or more components of the transportation refrigeration unit, historical trip data of the transportation refrigeration unit, or service data of the transportation refrigeration unit; receiving reefer parameters of the transportation refrigeration unit; determining a health score of the transportation refrigeration unit based on at least the reefer parameters; and determining a maintenance action for transportation refrigeration unit based on the health score and at least one of the alarm, the test data, the historical trip data, or the service data.

A method of monitoring a health of a transportation refrigeration unit including: receiving at least one of an alarm of one or more components of the transportation refrigeration unit, test data on the one or more components of the transportation refrigeration unit, historical trip data of the transportation refrigeration unit, or service data of the transportation refrigeration unit; receiving reefer parameters of the transportation refrigeration unit; determining a health score of the transportation refrigeration unit based on at least the reefer parameters; and determining a maintenance action for transportation refrigeration unit based on the health score and at least one of the alarm, the test data, the historical trip data, or the service data.

Systems and methods provide a warranty updating system for transferal of an Information Handling System (IHS) from a first entity to a second entity. In some embodiments, the warranty updating system includes computer-executable instructions to receive a request to manage a warranty transfer of the IHS in which the first entity is separate and distinct from a vendor of the first IHS. The system may obtain an inventory of the first IHS. determine one or more recommended warranty options for the second entity based on the received inventory, and present the warranty options for consumption by the second entity. When the system receives a selected warranty option from the first entity, it may configure the first IHS for use by the second entity based upon the selected warranty option.

Systems and methods provide a warranty updating system for transferal of an Information Handling System (IHS) from a first entity to a second entity. In some embodiments, the warranty updating system includes computer-executable instructions to receive a request to manage a warranty transfer of the IHS in which the first entity is separate and distinct from a vendor of the first IHS. The system may obtain an inventory of the first IHS. determine one or more recommended warranty options for the second entity based on the received inventory, and present the warranty options for consumption by the second entity. When the system receives a selected warranty option from the first entity, it may configure the first IHS for use by the second entity based upon the selected warranty option.

Systems and methods provide customers with a need-based warranty using a deep learning neural network. After categorizing, a customer need is mapped to a warranty type based on the SLA needs. Warranties may then be suggested based on customer need. In another embodiment, systems and methods detect an optimal warranty based on part failure and performance of a server. A mean time to resolve or replace can be minimized in future failure instances by comparing the derived replacement time with available warranty offerings to identify potential deviations and thereby recommend an optimal warranty from the available offerings. In a further embodiment, systems and methods identify and offer additional service contracts for vender services. A warranty proposer looks for warranty types that are emitted by a warranty-types analyzer and by a technical-support analyzer. The overlapping warranty offers are provided to customers.

Systems and methods provide a logical-physical warranty that is applied to nodes at a logical grouping level, such as a cluster. A logical warranty is associated with the nodes in the logical group or cluster in addition to each node's original individual warranty. The logical warranty stretches the expiration dates for individual warranties to a worst-case date inside the logical group. Customers build, teardown and extend the clusters, and the logical warranty is assigned to nodes in the cluster. The logical warranty is associated with a cluster of a defined size, such as a number of nodes expected, which can be expanded in the future as needed. The logical warranty ensures that there is uniform Service Level Agreement (SLA) for the nodes in the cluster during the warranty lifetime thereby simplifying the support for the cluster.