Abstract: A computer-implemented navigation method for identifying one or more points of interest (POI) in a geographic location includes calculating a navigation route and receiving a reference point input. The reference point input may be unrelated to the navigation route and usable for identifying one or more POIs. The method further includes receiving one or more search parameters for searching for one or more POIs with respect to the reference point and identifying the one or more POIs based on the search parameters and reference point. The method also includes presenting the one or more POIs on a vehicle computer display.

Abstract: A computer-implemented method of displaying vehicle range includes receiving input corresponding to a level of charge remaining in a vehicle having at least a partial electric power source usable for vehicle locomotion. The method also includes determining a maximum remaining range which the vehicle can travel based at least on the level of charge. The method further includes displaying a maximum range boundary overlaid on a map, including at least an indicator at the center of the range indicating a current location of the vehicle.

Abstract: An information display for a vehicle may convey whether an on-board energy storage device contains surplus energy to propel the vehicle beyond its current destination. The energy surplus may be conveyed in a graphically emotive display to support a driver's emotional motivation to drive the vehicle as well as provide reassurance for successfully making it to a destination before the energy storage device is depleted. The display may include one or more emotive display elements or themes. The energy surplus may be conveyed as surplus distance by a number of surplus indicators that are associated with the emotive display element.

Abstract: An efficiency gauge from a vehicle information display may incorporate vehicle range information in addition to an efficiency indicator. The range information may be displayed as an area on the efficiency gauge indicating a safe operating region for average driving in order for the vehicle to reach a target destination entered by a driver before an on-board energy source is depleted. By maintaining a vehicle's average trip efficiency within the safe operating region through driving behavior, the display may convey that the vehicle will be able to make it to the target destination. Over the course of a trip, the safe operating region may be constantly updated to reflect the current state of the battery and the remaining distance to the target destination. If no target information is received, a default target distance value based on an initial distance to empty estimation may be used.

Abstract: A vehicle display may convey vehicle trip information and vehicle range information graphically to assist drivers in qualitatively visualizing and determining whether they can successfully make it to their destination before an on-board energy source is depleted. A trip gauge may include indicators corresponding to the relative locations of the vehicle, the destination, and a projected zero charge location associated with the vehicle's range or distance to empty value. The positions of the indicators relative to one another may indicate whether the excess energy is available for the vehicle to reach the destination or whether the energy available is insufficient. A battery gauge may also convey information associated with the vehicle range. Portions of the trip gauge and the battery gauge, as well as one or more of the associated indicators, may assigned various color values for display based upon energy consumption, vehicle range, and target distance information.

Abstract: A vehicle display may convey vehicle trip information and vehicle range information graphically to assist drivers in qualitatively visualizing and determining whether they can successfully make it to their destination before an on-board energy source is depleted. A trip gauge may include indicators corresponding to the relative locations of the vehicle, the destination, and a projected zero charge location associated with the vehicle's range or distance to empty value. The positions of the indicators relative to one another may indicate whether the excess energy is available for the vehicle to reach the destination or whether the energy available is insufficient. A battery gauge may also convey information associated with the vehicle range. Portions of the trip gauge and the battery gauge, as well as one or more of the associated indicators, may assigned various color values for display based upon energy consumption, vehicle range, and target distance information.

Abstract: Driver braking performance feedback may be conveyed to a vehicle operator as a braking efficiency score using a vehicle display system. The display system may include a vehicle display for displaying a braking efficiency indicator or gauge corresponding to the braking efficiency score. The braking efficiency score may be based on a comparison of the total regenerative braking energy recaptured during at least one braking event to a either a maximum amount of braking energy that may be recaptured during the at least one braking event or an actual total braking energy expended during the at least one braking event. The braking efficiency score may be displayed upon the completion of a braking event or upon a completion of a trip including a plurality of braking events. The display may also convey a distance corresponding to a portion of a trip distance achieved through regenerative braking.

Abstract: A trip gauge for a vehicle information display may convey vehicle trip information and vehicle range information graphically to assist drivers in qualitatively visualizing and determining whether they can successfully make it to their destination before an on-board energy source is depleted. The trip gauge may include indicators corresponding to the relative locations of the vehicle, the destination, and a projected zero charge location associated with the vehicle's range or distance to empty value. Moreover, the positions of the indicators relative to one another may indicate whether the excess energy is available for the vehicle to reach the destination or whether the energy available is insufficient. Accordingly, drivers may be either reassured that they are expected to reach their destination successfully or warned if they are not so the drivers can modify their driving behavior or change their destination.

Abstract: Driver braking performance feedback may be conveyed to a vehicle operator as a braking efficiency score using a vehicle display system. The display system may include a vehicle display for displaying a braking efficiency indicator or gauge corresponding to the braking efficiency score. The braking efficiency score may be based on a comparison of the total regenerative braking energy recaptured during at least one braking event to a either a maximum amount of braking energy that may be recaptured during the at least one braking event or an actual total braking energy expended during the at least one braking event. The braking efficiency score may be displayed upon the completion of a braking event or upon a completion of a trip including a plurality of braking events. The display may also convey a distance corresponding to a portion of a trip distance achieved through regenerative braking.

Abstract: An efficiency gauge from a vehicle information display may incorporate vehicle range information in addition to an efficiency indicator. The range information may be displayed as an area on the efficiency gauge indicating a safe operating region for average driving in order for the vehicle to reach a target destination before an on-board energy source is depleted. By maintaining a vehicle's average trip efficiency within the safe operating region through driving behavior, the display may convey that the vehicle will be able to make it to the target destination. Over the course of a trip, the safe operating region may be constantly updated to reflect the current state of the battery and the remaining distance to the target destination.

Abstract: One embodiment of the present invention is a vehicle computer system for establishing in-vehicle wireless connectivity to remote computer network, e.g., the Internet. The system may include a processor in communication with a human machine interface (HMI) for control by a user. The processor may also be in communication with one or more wireless transceivers for wireless data communication. The processor may be capable of being paired to a pneumatic commuting device (e.g., cellphone, PDA, etc.) having wireless Internet connectivity. The processor may be configured to wirelessly connect to one or more personal computing devices in the vicinity of the vehicle, and provide a wireless Internet access point to the one or more personal computing devices based on the wireless connection and the Internet connectivity.

Abstract: A computer-implemented navigation method for identifying one or more points of interest (POI) in a geographic location includes calculating a navigation route and receiving a reference point input. The reference point input may be unrelated to the navigation route and usable for identifying one or more POIs. The method further includes receiving one or more search parameters for searching for one or more POIs with respect to the reference point and identifying the one or more POIs based on the search parameters and reference point. The method also includes presenting the one or more POIs on a vehicle computer display.

Abstract: A method for querying a vehicle system from a remote wireless device includes receiving an inquiry at a cellular transceiver included in a vehicle. The inquiry is sent from a remote server in communication with the remote wireless device and initiated by the remote wireless device. The method includes accessing one or more vehicle systems in accordance with the inquiry and querying the accessed one or more systems in accordance with the inquiry. The method also includes receiving information in accordance with the query from the one or more systems that were queried and transmitting the received information to the remote server through the cellular transceiver, for further transmission to the remote wireless device.

Abstract: Embodiments of the present invention include a vehicle human machine interface (HMI) for control by a vehicle occupant. The HMI may include a first graphical display, a second graphical display, a plurality of input controls, and a vehicle computer communicating with the first and second graphical displays. The vehicle computer may be configured to receive user input defining user instructions for controlling one or more functions of the vehicle. In response to the input, the computer may be configured to present on the first and second graphical displays a vehicle function identifier color associated with the vehicle function.

Abstract: A method of vehicle monitoring includes monitoring one or more vehicle safety systems while a vehicle is in operation to detect an unsafe condition. The method also includes sending an alert to a handheld device if an unsafe condition is detected.

Abstract: A method for remotely controlling one or more vehicle components includes receiving over a telecommunications network signals originating from a remote terminal. The signals include remote operation instructions for remotely operating a vehicle entertainment system component. The remote operation instructions are executed. Operation status identifiers transmitted over a vehicle data bus are received from the vehicle entertainment system component. Based on the operation status identifiers, an operating status of the vehicle entertainment system component is determined. A return signal including an operation status message and an instruction for displaying the operation status message at the remote terminal is generated. The signal is transmitted to the remote terminal for display.