Abstract: A system for managing an access to an asset is provided. A digital key to the asset is generated and synchronized between a first user device of a first user and an access control device that controls the access to the asset. A key-sharing request is initiated by the first user device to grant a second user the access to the asset. Based on the key-sharing request, an application server communicates the digital key to a second user device of the second user. When the second user device is within a detection range of the access control device, the access control device receives the digital key from the second user device, validates the digital key, and grants the second user the access to the asset for an access duration defined in the key-sharing request.

Abstract: A power management system can smartly allocate the available power at a location to support more electric vehicles than would otherwise be possible. Power managers can intelligently allocate that power based on the real-time needs of vehicles. A smart energy distribution system can estimate each vehicle's current charge level and use such information to efficiently provide electric vehicle charging. The system can respond dynamically to vehicle charge levels, current readings, and/or electrical mains readings, allocating more current where it is needed. The charger profiles can include historic charge cycle information, which can be analyzed under a set of heuristics to predict future charging needs. A local electric vehicle charging mesh network can be provided, which transmits data packets among short-range transceivers of multiple power managers. The local electric vehicle charging mesh network can be connected to a remote server via a cellular connection.

Abstract: A method for facilitating charge transfer is provided. The method includes receiving, via an electronic device, a request to transfer charge stored in an energy storage device. The method includes determining a set of parameters of the energy storage device based on the received request. The set of parameters includes an amount of charge determined to be transferred from the energy storage device or a charge level desired to be achieved for the energy storage device. The method includes identifying charging systems available to receive and store charge corresponding to the set of parameters of the energy storage device. The method further includes allocating one of the identified charging systems to receive charge from the energy storage device and store the received amount of charge. The allocated charging system travels to a location of the energy storage device to receive the determined amount of charge from the energy storage device.

Abstract: A system for managing an access to an asset is provided. A digital key to the asset is generated and synchronized between a first user device of a first user and an access control device that controls the access to the asset. A key-sharing request is initiated by the first user device to grant a second user the access to the asset. Based on the key-sharing request, an application server communicates the digital key to a second user device of the second user. When the second user device is within a detection range of the access control device, the access control device receives the digital key from the second user device, validates the digital key, and grants the second user the access to the asset for an access duration defined in the key-sharing request.

Abstract: A method for facilitating charge transfer is provided. The method includes receiving, via an electronic device, a request to transfer charge stored in an energy storage device. The method includes determining a set of parameters of the energy storage device based on the received request. The set of parameters includes an amount of charge determined to be transferred from the energy storage device or a charge level desired to be achieved for the energy storage device. The method includes identifying charging systems available to receive and store charge corresponding to the set of parameters of the energy storage device. The method further includes allocating one of the identified charging systems to receive charge from the energy storage device and store the received amount of charge. The allocated charging system travels to a location of the energy storage device to receive the determined amount of charge from the energy storage device.

Abstract: A method for facilitating charging is provided. The method includes receiving a charging request from a user device for charging an energy storage device associated with an acceptor node. The method includes determining a set of charging parameters for the energy storage device based on the charging request. The method includes identifying one or more mobile charging systems that are available within a first geographical region associated with the acceptor node and satisfy the set of charging parameters. The method includes allocating, from the one or more mobile charging systems, a first mobile charging system to charge the energy storage device of the acceptor node. Based on the allocation, the first mobile charging system travels from a first location to reach a second location of the acceptor node to charge the energy storage device.

Abstract: A power management system can smartly allocate the available power at a location to support more electric vehicles than would otherwise be possible. Power managers can intelligently allocate that power based on the real-time needs of vehicles. A smart energy distribution system can estimate each vehicle's current charge level and use such information to efficiently provide electric vehicle charging. The system can respond dynamically to vehicle charge levels, current readings, and/or electrical mains readings, allocating more current where it is needed. The charger profiles can include historic charge cycle information, which can be analyzed under a set of heuristics to predict future charging needs. A local electric vehicle charging mesh network can be provided, which transmits data packets among short-range transceivers of multiple power managers. The local electric vehicle charging mesh network can be connected to a remote server via a cellular connection.

Abstract: A method for facilitating charging is provided. The method includes receiving a charging request from a user device for charging an energy storage device associated with an acceptor node. The method includes determining a set of charging parameters for the energy storage device based on the charging request. The method includes identifying one or more mobile charging systems that are available within a first geographical region associated with the acceptor node and satisfy the set of charging parameters. The method includes allocating, from the one or more mobile charging systems, a first mobile charging system to charge the energy storage device of the acceptor node. Based on the allocation, the first mobile charging system travels from a first location to reach a second location of the acceptor node to charge the energy storage device.

Abstract: A power management system can smartly allocate the available power at a location to support more electric vehicles than would otherwise be possible. Power managers can intelligently allocate that power based on the real-time needs of vehicles. A smart energy distribution system can estimate each vehicle's current charge level and use such information to efficiently provide electric vehicle charging. The system can respond dynamically to vehicle charge levels, current readings, and/or electrical mains readings, allocating more current where it is needed. The charger profiles can include historic charge cycle information, which can be analyzed under a set of heuristics to predict future charging needs. A local electric vehicle charging mesh network can be provided, which transmits data packets among short-range transceivers of multiple power managers. The local electric vehicle charging mesh network can be connected to a remote server via a cellular connection.

Abstract: An electricity distribution, monitoring, and control system for recharging electric vehicles. The system may include a plug outlet device having a sensor, and a plug adapter apparatus having a tag. The tag may communicate with the sensor when the plug adapter apparatus is coupled to the plug outlet device. An electric vehicle receives an electric charge from the plug outlet device after an identification number associated with the tag is verified by a remote server. Alternatively, a plug outlet device includes a tag, and an electric vehicle has attached thereto a monitoring and communication device, which may include a sensor. The sensor may communicate with the tag when the electric vehicle is proximally located to the plug outlet device, and obtain authorization from a remote server or the outlet device to charge the electric vehicle. A user account is automatically billed and a provider account is automatically credited.

Abstract: A power management system can smartly allocate the available power at a location to support more electric vehicles than would otherwise be possible. Power managers can intelligently allocate that power based on the real-time needs of vehicles. A smart energy distribution system can estimate each vehicle's current charge level and use such information to efficiently provide electric vehicle charging. The system can respond dynamically to vehicle charge levels, current readings, and/or electrical mains readings, allocating more current where it is needed. The charger profiles can include historic charge cycle information, which can be analyzed under a set of heuristics to predict future charging needs. A local electric vehicle charging mesh network can be provided, which transmits data packets among short-range transceivers of multiple power managers. The local electric vehicle charging mesh network can be connected to a remote server via a cellular connection.

Abstract: A power management system smartly allocates the available power at a location to support more electric vehicles than would otherwise be possible. Power managers can intelligently allocate that power based on the real-time needs of vehicles. A smart energy distribution system can estimate each vehicle's current charge level and use such information to efficiently provide electric vehicle charging. The system can respond dynamically to vehicle charge levels, current readings, and/or electrical mains readings, allocating more current where it is needed. The charger profiles can include historic charge cycle information, which can be analyzed under a set of heuristics to predict future charging needs. A local electric vehicle charging mesh network can be provided, which transmits data packets among short-range transceivers of multiple power managers. The charging mesh network is connected to a remote server.

Abstract: A power management system can smartly allocate the available power at a location to support more electric vehicles than would otherwise be possible. Power managers can intelligently allocate that power based on the real-time needs of vehicles. A smart energy distribution system can estimate each vehicle's current charge level and use such information to efficiently provide electric vehicle charging. The system can respond dynamically to vehicle charge levels, current readings, and/or electrical mains readings, allocating more current where it is needed. The charger profiles can include historic charge cycle information, which can be analyzed under a set of heuristics to predict future charging needs. A local electric vehicle charging mesh network can be provided, which transmits data packets among short-range transceivers of multiple power managers. The local electric vehicle charging mesh network can be connected to a remote server via a cellular connection.

Abstract: A power management system can smartly allocate the available power at a location to support more electric vehicles than would otherwise be possible. Power managers can intelligently allocate that power based on the real-time needs of vehicles. A smart energy distribution system can estimate each vehicle's current charge level and use such information to efficiently provide electric vehicle charging. The system can respond dynamically to vehicle charge levels, current readings, and/or electrical mains readings, allocating more current where it is needed. The charger profiles can include historic charge cycle information, which can be analyzed under a set of heuristics to predict future charging needs. A local electric vehicle charging mesh network can be provided, which transmits data packets among short-range transceivers of multiple power managers. The local electric vehicle charging mesh network can be connected to a remote server via a cellular connection.

Abstract: A method, system, and apparatus include a clustered charge distribution and prioritized charge distribution system for electric vehicles (EVs). Distributed processing units (DPUs) receive member information about an EV or EV user. A power distribution manager (PDM) is coupled to each of the DPUs. The PDM includes a prioritizer. The prioritizer determines a prioritization for charging the EVs based on the member information received by each of the DPUs. A method includes providing clustered charge distribution and charge prioritization for electric vehicles. The method includes sensing whether power is requested by any one of a plurality of EVs within a cluster, generating individual EV-specific information for the EVs using the DPUs, transmitting the EV-specific information to the PDM, and selecting and applying a prioritization algorithm based at least in part on the transmitted information.

Abstract: A method, system, and apparatus for distributing electricity to electric vehicles, monitoring the distribution thereof, and/or controlling the distribution thereof, provides various components to vehicle operators and station owners to track and control energy usage. Plug outlet devices are associated with a station. A coordinator element is configured to receive vehicle information and information about the station from one or more electric vehicles. The information is verified, stored, and/or aggregated for later display. In addition, the information can be used to determine whether or not to deny electrical charging service to a vehicle using a switch component.

Abstract: A method, system, and apparatus include a clustered charge distribution and prioritized charge distribution system for electric vehicles (EVs). Distributed processing units (DPUs) receive member information about an EV or EV user. A power distribution manager (PDM) is coupled to each of the DPUs. The PDM includes a prioritizer. The prioritizer determines a prioritization for charging the EVs based on the member information received by each of the DPUs. Also disclosed is a method for providing clustered charge distribution and charge prioritization for electric vehicles. The method includes sensing whether power is requested by any one of a plurality of EVs within a cluster, generating individual EV-specific information for the EVs using the DPUs, transmitting the EV-specific information to the PDM, and selecting and applying a prioritization algorithm based at least in part on the transmitted information.

Abstract: A method, system, and apparatus for distributing electricity to electric vehicles, monitoring the distribution thereof, and/or controlling the distribution thereof, provides various components to vehicle operators and station owners to track and control energy usage. Plug outlet devices are associated with a station. A coordinator element is configured to receive vehicle information and information about the station from one or more electric vehicles. The information is verified, stored, and/or aggregated for later display. In addition, the information can be used to determine whether or not to deny electrical charging service to a vehicle using a switch component.

Abstract: An electricity distribution, monitoring, and control system for recharging electric vehicles. The system may include a plug outlet device having a sensor, and a plug adapter apparatus having a tag. The tag may communicate with the sensor when the plug adapter apparatus is coupled to the plug outlet device. An electric vehicle receives an electric charge from the plug outlet device after an identification number associated with the tag is verified by a remote server. Alternatively, a plug outlet device includes a tag, and an electric vehicle has attached thereto a monitoring and communication device, which may include a sensor. The sensor may communicate with the tag when the electric vehicle is proximally located to the plug outlet device, and obtain authorization from a remote server or the outlet device to charge the electric vehicle. A user account is automatically billed and a provider account is automatically credited.