Abstract: A system includes a processor configured to receive a vehicle identifier identifying a vehicle from a first digital entity. The processor is also configured to digitally obtain a payment account associated with the identifier, responsive to receiving the identifier. The processor is further configured to validate payment rights through input from a second entity, confirming the right to use the account to pay for charging the vehicle and responsive to successful validation, charge the payment account for vehicle charging, following vehicle charging completion.

Abstract: Implementations directed to instantiating adapters for communication between a UAP and one or more RPA platforms, and include receiving, by an intelligent adapter service of the UAP, input representing an RPA platform of a plurality of RPA platforms, querying, by the intelligent adapter service, one or more files of the RPA platform to determine one or more identifiers of the RPA platform, selecting, by the intelligent adapter service, an adapter of a plurality of adapters based on the one or more identifiers of the RPA platform, installing, by the intelligent adapter service, the adapter, and configuring, by the intelligent adapter service, the adapter to be specific to the RPA platform, configuring including setting one or more parameters of the RPA platform.

Abstract: A system includes a processor configured to receive a vehicle identifier identifying a vehicle from a first digital entity. The processor is also configured to digitally obtain a payment account associated with the identifier, responsive to receiving the identifier. The processor is further configured to validate payment rights through input from a second entity, confirming the right to use the account to pay for charging the vehicle and responsive to successful validation, charge the payment account for vehicle charging, following vehicle charging completion.

Abstract: A charging station comprises a processor programmed to receive a vehicle identifier identifying a vehicle from a first digital entity; receive a payment authentication from a second digital entity; electronically identify an account associated with the vehicle identifier and the payment authentication; verify payment rights confirming a right to use the account to pay; and responsive to successful verification, activate the charging station to charge and process payment from the account.

Abstract: A system includes a processor configured to receive a vehicle identifier identifying a vehicle from a first digital entity. The processor is also configured to digitally obtain a payment account associated with the identifier, responsive to receiving the identifier. The processor is further configured to validate payment rights through input from a second entity, confirming the right to use the account to pay for charging the vehicle and responsive to successful validation, charge the payment account for vehicle charging, following vehicle charging completion.

Abstract: A vehicle includes a controller programmed to recognize a park event at a parking location, learn charging intention associated with the parking location, and, responsive to predicting an intention to charge the vehicle at the parking location and recognizing that a user has left a vicinity of the vehicle without connecting a charger, cause a device associated with the user to issue a charge reminder. The controller predicts the intention to charge based on contextual data from previous park events.

Abstract: Implementations directed to direct messaging between one or more robotic process automation (RPA) platforms, and an autonomic platform (AP), and include actions of receiving, by a platform-specific adapter of the AP, data from a RPA platform of a plurality of RPA platforms the AP interacts with, the data indicating occurrence of a scenario, providing, by an application programming interface (API) of the platform-specific adapter, an occurrence message responsive to the occurrence of the scenario, transmitting, by the API, the message to the AP through a first channel, and transmitting, by the platform-specific adapter, a set of messages to the AP through a second channel that is separate from the first channel, the set of messages communicating tagged data records.

Abstract: A vehicle includes a controller programmed to recognize a park event at a parking location, learn charging intention associated with the parking location, and, responsive to predicting an intention to charge the vehicle at the parking location and recognizing that a user has left a vicinity of the vehicle without connecting a charger, cause a device associated with the user to issue a charge reminder. The controller predicts the intention to charge based on contextual data from previous park events.

Abstract: Vehicles such as a combustion engine, electric, and/or hybrid electric vehicles and methods of operation, which include controller(s) configured to respond to cruise control signals, and to generate a route efficiency profile according to instantaneous vehicle performance parameters and environmental conditions. The controller(s) are also modified to adjust a vehicle cruise speed according to the signal and profile, to enable reaching at least one designated destination in a minimum time, and whereby vehicle range is extended to the destination, while one or more reserve energy limits of battery power and fuel are maintained. The controller(s) are also adapted to detect instantaneous feedback signals that include the performance parameters and environmental conditions, and to generate error signals according to an actual vehicle watt-hour per mile efficiency and the route efficiency profile.

Abstract: Implementations directed to direct messaging between one or more robotic process automation (RPA) platforms, and an autonomic platform (AP), and include actions of receiving, by a platform-specific adapter of the AP, data from a RPA platform of a plurality of RPA platforms the AP interacts with, the data indicating occurrence of a scenario, providing, by an application programming interface (API) of the platform-specific adapter, an occurrence message responsive to the occurrence of the scenario, transmitting, by the API, the message to the AP through a first channel, and transmitting, by the platform-specific adapter, a set of messages to the AP through a second channel that is separate from the first channel, the set of messages communicating tagged data records.

Abstract: Implementations directed to instantiating adapters for communication between a UAP and one or more RPA platforms, and include receiving, by an intelligent adapter service of the UAP, input representing an RPA platform of a plurality of RPA platforms, querying, by the intelligent adapter service, one or more files of the RPA platform to determine one or more identifiers of the RPA platform, selecting, by the intelligent adapter service, an adapter of a plurality of adapters based on the one or more identifiers of the RPA platform, installing, by the intelligent adapter service, the adapter, and configuring, by the intelligent adapter service, the adapter to be specific to the RPA platform, configuring including setting one or more parameters of the RPA platform.

Abstract: An exemplary assembly includes, among other things, a group of battery cells, and an array plate assembly having a pressure retention pad that is configured to plastically deform in response to the group of battery cells expanding. An exemplary method includes, among other things, compressing a group of battery cells with an array plate assembly having a pressure retention pad, the pressure retention pad plastically deforming in response to the group of battery cells expanding.

Abstract: An exemplary battery assembly includes an enclosure having a first portion interfacing with a separate, second portion along an interface. A seal is at the interface, and a shear cord is configured to rupture the seal when moved from a first position to a second position. An exemplary battery accessing method includes moving a shear cord from a first to a second position to rupture a seal. The seal is at an interface between a first and a second portion of an enclosure.

Abstract: A method according to an exemplary aspect of the present disclosure includes, among other things, compressing at least one battery module to a desired dimension prior to installing the battery module into an array. Another method according to an exemplary aspect of the present disclosure includes, among other things, inducing a residual stress into a battery module to compress the battery module to a desired dimension prior to being installed in an array. An apparatus, according to an exemplary aspect of the present disclosure includes, among other things, a compression device configured to temporarily compress at least one battery module to a desired dimension prior to installing the battery module into an array.

Abstract: A charging station comprises a processor programmed to receive a vehicle identifier identifying a vehicle from a first digital entity; receive a payment authentication from a second digital entity; electronically identify an account associated with the vehicle identifier and the payment authentication; verify payment rights confirming a right to use the account to pay; and responsive to successful verification, activate the charging station to charge and process payment from the account.

Abstract: This disclosure describes exemplary electrified vehicle charging systems for charging battery packs. An exemplary charging system includes a visual indicator (e.g., pictogram, text, or both) located on-board the vehicle that can be automatically illuminated once the battery pack has been charged to a predefined minimum state of charge (SOC) threshold. The visual indicator communicates charging status messages to other electrified vehicle users, and once illuminated, provides an intuitive indication to the other vehicle users that the electrified vehicle that is currently on-plug has received a sufficient amount of charge and therefore may be unplugged from a charging station. The visual indicator therefore facilitates a courtesy hand-off of charging station components from one electrified vehicle user to another.

Abstract: An exemplary traction battery assembly includes, among other things, a container disposed about a portion of a fastened joint within an interior of a traction battery enclosure. The container is configured to hold contaminants to block the contaminants from contacting a surface of a component housed within the interior. An exemplary contaminant containing method includes, among other things, within an interior area of a traction battery enclosure, holding contaminants within a container to block the contaminants from contacting a surface of a component housed within the interior. The container is disposed about a fastened joint within the interior area.

Abstract: Vehicles such as a combustion engine, electric, and/or hybrid electric vehicles and methods of operation, which include controller(s) configured to respond to cruise control signals, and to generate a route efficiency profile according to instantaneous vehicle performance parameters and environmental conditions. The controller(s) are also modified to adjust a vehicle cruise speed according to the signal and profile, to enable reaching at least one designated destination in a minimum time, and whereby vehicle range is extended to the destination, while one or more reserve energy limits of battery power and fuel are maintained. The controller(s) are also adapted to detect instantaneous feedback signals that include the performance parameters and environmental conditions, and to generate error signals according to an actual vehicle watt-hour per mile efficiency and the route efficiency profile.

Abstract: This disclosure describes exemplary electrified vehicle charging systems for charging battery packs. An exemplary charging system includes a visual indicator (e.g., pictogram, text, or both) located on-board the vehicle that can be automatically illuminated once the battery pack has been charged to a predefined minimum state of charge (SOC) threshold. The visual indicator communicates charging status messages to other electrified vehicle users, and once illuminated, provides an intuitive indication to the other vehicle users that the electrified vehicle that is currently on-plug has received a sufficient amount of charge and therefore may be unplugged from a charging station. The visual indicator therefore facilitates a courtesy hand-off of charging station components from one electrified vehicle user to another.

Abstract: A system includes a processor configured to receive a vehicle identifier identifying a vehicle from a first digital entity. The processor is also configured to digitally obtain a payment account associated with the identifier, responsive to receiving the identifier. The processor is further configured to validate payment rights through input from a second entity, confirming the right to use the account to pay for charging the vehicle and responsive to successful validation, charge the payment account for vehicle charging, following vehicle charging completion.