Abstract: A method for optimizing climate control in an autonomous vehicle. The method includes receiving a ride request for an autonomous vehicle from a customer. A desired temperature for an interior of the autonomous vehicle may be determined based on the ride request. The current temperature of the vehicle interior may then be adjusted such that the current temperature substantially matches the desired temperature when the autonomous vehicle reaches the customer. The temperature of the vehicle interior may be allowed to deviate from the desired temperature, within a pre-determined temperature deviation range, when the autonomous vehicle is unoccupied. A corresponding system and computer program product are also disclosed and claimed herein.

Abstract: Exemplary embodiments described in this disclosure are generally directed to a collaborative relationship between a UAV and an automobile. In a first exemplary method, a data capture system is provided in a UAV. The data capture system may be used to capture data when the UAV is in flight. A first computer in the UAV determines one or more limitations associated with wirelessly transmitting some or all of the data from the UAV to an automobile. The first computer may be further used to withhold wireless transmission of a portion of the data to the automobile due to the one or more limitations. The portion of data is transferred to a second computer in the automobile after landing the UAV on the automobile. In a second exemplary method, the UAV includes a communication relay system for relaying to an automobile, signals received from a satellite or a cellular base station.

Abstract: Exemplary embodiments described in this disclosure are generally directed to a collaborative relationship between a UAV and an automobile. In a first exemplary method, a data capture system is provided in a UAV. The data capture system may be used to capture data when the UAV is in flight. A first computer in the UAV determines one or more limitations associated with wirelessly transmitting some or all of the data from the UAV to an automobile. The first computer may be further used to withhold wireless transmission of a portion of the data to the automobile due to the one or more limitations. The portion of data is transferred to a second computer in the automobile after landing the UAV on the automobile. In a second exemplary method, the UAV includes a communication relay system for relaying to an automobile, signals received from a satellite or a cellular base station.

Abstract: A method for optimizing climate control in an autonomous vehicle. The method includes receiving a ride request for an autonomous vehicle from a customer. A desired temperature for an interior of the autonomous vehicle may be determined based on the ride request. The current temperature of the vehicle interior may then be adjusted such that the current temperature substantially matches the desired temperature when the autonomous vehicle reaches the customer. The temperature of the vehicle interior may be allowed to deviate from the desired temperature, within a pre-determined temperature deviation range, when the autonomous vehicle is unoccupied. A corresponding system and computer program product are also disclosed and claimed herein.

Abstract: An assembly includes a photovoltaic module including a solar cell and a cooling system including a heat pipe adapted to dissipate heat from the solar cell. A method includes dissipating heat from the solar cell using the heat pipe. The photovoltaic module may be disposed on a vehicle to convert solar energy into electricity.

Abstract: Systems, methods, and computer-readable media are disclosed for providing information related to landmarks during travel. Example methods may include determining a set of landmark options based at least in part on a input indicative of locations, the set of landmark options comprising a landmark option; determining that the landmark option is selected by a user; determining a tour route based on the landmark option, wherein the tour route includes at least one landmark; and determining information to be provided to the user when the user is within a distance of the at least one landmark.

Abstract: An exemplary charger positioning method includes, among other things, positioning a charging plug of a conductive charger relative to a charge port of a vehicle based on a wireless transmission between the conductive charger and the vehicle. An exemplary charger assembly includes a transmitter system associated with one of a vehicle or a conductive charger, a receiver system associated with the other of the vehicle or the conductive charger, and an actuator that moves a charging plug of the conductive charger to a charging position in response to a transmission from the transmitter system.

Abstract: A voltage quality module (VQM) function and a solar power generation function are integrated by sharing a single voltage converter (VC) within the electrical system of an automotive vehicle with an electric-start internal combustion engine. The cost of adding solar power generating capabilities to vehicles, the packaging complexities of the systems, and the number of added components are all decreased. The VC can be a DC-DC converter in a boost mode or a buck mode. A switching circuit selectably couples the VC between a main battery and an accessory bus or to between a solar panel and an auxiliary battery. A VC controller regulating a VC output using the main battery to stabilize an accessory bus voltage when in an engine crank mode and otherwise regulating the VC output to match an auxiliary battery voltage using the solar panel output.

Abstract: A glass roof system includes a first glass layer, a photovoltaic module, a switching film powered by the photovoltaic module, and a control module configured to selectively control the switching film based on a passenger cabin temperature.

Abstract: A glass roof system includes a first glass layer, a photovoltaic module, a switching film powered by the photovoltaic module, and a control module configured to selectively control the switching film based on a passenger cabin temperature.

Abstract: A voltage quality module (VQM) function and a solar power generation function are integrated by sharing a single voltage converter (VC) within the electrical system of an automotive vehicle with an electric-start internal combustion engine. The cost of adding solar power generating capabilities to vehicles, the packaging complexities of the systems, and the number of added components are all decreased. The VC can be a DC-DC converter in a boost mode or a buck mode. A switching circuit selectably couples the VC between a main battery and an accessory bus or to between a solar panel and an auxiliary battery. A VC controller regulating a VC output using the main battery to stabilize an accessory bus voltage when in an engine crank mode and otherwise regulating the VC output to match an auxiliary battery voltage using the solar panel output.

Abstract: An exemplary charger positioning method includes, among other things, positioning a charging plug of a conductive charger relative to a charge port of a vehicle based on a wireless transmission between the conductive charger and the vehicle. An exemplary charger assembly includes a transmitter system associated with one of a vehicle or a conductive charger, a receiver system associated with the other of the vehicle or the conductive charger, and an actuator that moves a charging plug of the conductive charger to a charging position in response to a transmission from the transmitter system.

Abstract: An assembly includes a photovoltaic module including a solar cell and a cooling system including a heat pipe adapted to dissipate heat from the solar cell. A method includes dissipating heat from the solar cell using the heat pipe. The photovoltaic module may be disposed on a vehicle to convert solar energy into electricity.

Abstract: A support structure for a vehicle roof panel includes a solar panel module. The solar panel module is disposed within an opening defined by an outer periphery of a support structure. The solar panel module includes a first part configured to slide underneath a second part containing a solar array adhered to a flange. The flange has a plurality of ribs extending across the solar array. The ribs have a V-shaped cross-section to support the solar panel module within the second part.

Abstract: The present invention is direct to a device and method for diagnosis of enamel cavitation of an interproximal dental surface. And in particular, the invention is directed to a device and method for diagnosing enamel cavitation of an interproximal tooth surface that is not visible or probe-able by instrumentation in human permanent and deciduous teeth. More specifically, the device has a substrate of generally rectangular shape and of a sufficient thickness such that it may be inserted into the interproximal space of teeth. On the substrate is disposed an impressionable material for contacting the interproximal surface and forming an impression thereof. The impressionable material has visco-elastic properties such that an impression of enamel cavitation on the interproximal surface remains on the impressionable material following removal of the substrate from the interproximal surface.