Abstract: A hand-held bioanalytic instrument is described that can perform massively parallel sample analysis including single-molecule gene sequencing. The instrument includes a pulsed optical source that produces ultrashort excitation pulses and a compact beam-steering assembly. The beam-steering assembly provides automated alignment of excitation pulses to an interchangeable bio-optoelectronic chip that contains tens of thousands of reaction chambers or more. The optical source, beam-steering assembly, bio-optoelectronic chip, and coupling optics register to an alignment structure in the instrument that can form at least one wall of an enclosure and dissipate heat.

Abstract: A system for a vehicle includes an electrical port that charges a vehicle battery via a connection to a power source, and a controller configured to interrupt charging and to display an alert responsive to temperature at the connection being greater than a threshold and voltage of a control pilot terminal of the port being at an overtemperature state voltage that is different from each of disconnected, connected, ready, and fault state voltages.

Abstract: A system for a vehicle includes an electrical port that charges a vehicle battery via a connection to a power source, and a controller configured to interrupt charging and to display an alert responsive to temperature at the connection being greater than a threshold and voltage of a control pilot terminal of the port being at an overtemperature state voltage that is different from each of disconnected, connected, ready, and fault state voltages.

Abstract: A vehicle charging system may include a drive system mounted to a chassis, a positionable electrical connector assembly, a position sensor, a proximity sensor, and a control module. The control module may be programmed to operate the drive system to place the chassis proximate a vehicle electrical connector and operate the positionable electrical connector assembly to releasably engage the vehicle electrical connector.

Abstract: An exemplary reporting method includes the steps of receiving diagnostic data from electric vehicle supply equipment, and then reporting the diagnostic data through an interface of an electrified vehicle. An exemplary electrified vehicle assembly includes a controller of an electrified vehicle. The controller is configured to receive diagnostic data from electric vehicle supply equipment. The exemplary assembly further includes an interface of the electrified vehicle configured to report the diagnostic data.

Abstract: An electrified vehicle includes a surface, an electric vehicle supply equipment (EVSE) system attachable to the surface, and a retention assembly configured to removably secure the EVSE system to the surface. The retention assembly includes a first segment affixed to the surface and a second segment affixed to the EVSE system.

Abstract: Electric and plug-in hybrid electric vehicles include a rechargeable traction battery. An automated vehicle charging system is configured to charge the traction battery with minimal operator intervention. The vehicle charging system includes at least one tire pad including a plurality of pressure-sensitive sensors arranged at known locations of the tire pad and outputting signals having a magnitude indicative of a pressure applied by a tire at the known locations. The vehicle charging system also includes at least one controller programmed to receive the signals and control movement of a transmit coil according to a position of the tire on the tire pad that is derived from the signals. The known locations may be generally equally spaced or unevenly spaced across the tire pad. The tire pad may include a tire stop to limit motion of the tire in one direction.

Abstract: An electrified vehicle includes a surface, an electric vehicle supply equipment (EVSE) system attachable to the surface, and a retention assembly configured to removably secure the EVSE system to the surface. The retention assembly includes a first segment affixed to the surface and a second segment affixed to the EVSE system.

Abstract: An exemplary reporting method includes the steps of receiving diagnostic data from electric vehicle supply equipment, and then reporting the diagnostic data through an interface of an electrified vehicle. An exemplary electrified vehicle assembly includes a controller of an electrified vehicle. The controller is configured to receive diagnostic data from electric vehicle supply equipment. The exemplary assembly further includes an interface of the electrified vehicle configured to report the diagnostic data.

Abstract: Electric and plug-in hybrid electric vehicles include a rechargeable traction battery. An automated vehicle charging system is configured to charge the traction battery with minimal operator intervention. The vehicle charging system includes a carousel, including a plurality of transmit coils, configured to move in a longitudinal direction and rotate about an axis. The vehicle charging system further includes at least one controller programmed to move the carousel in the longitudinal direction and rotate the carousel about the axis to align a selected transmit coil from the plurality of transmit coils with a vehicle receive coil. The vehicle charging system may receive positioning data from a vehicle and may move and rotate the carousel according to the positioning data to align the selected transmit coil with the vehicle receive coil.

Abstract: A vehicle charging system may include a drive system mounted to a chassis, a positionable electrical connector assembly, a position sensor, a proximity sensor, and a control module. The control module may be programmed to operate the drive system to place the chassis proximate a vehicle electrical connector and operate the positionable electrical connector assembly to releasably engage the vehicle electrical connector.

Abstract: Electric and plug-in hybrid electric vehicles include a rechargeable traction battery. An automated vehicle charging system is configured to charge the traction battery with minimal operator intervention. The vehicle charging system includes at least one tire pad including a plurality of pressure-sensitive sensors arranged at known locations of the tire pad and outputting signals having a magnitude indicative of a pressure applied by a tire at the known locations. The vehicle charging system also includes at least one controller programmed to receive the signals and control movement of a transmit coil according to a position of the tire on the tire pad that is derived from the signals. The known locations may be generally equally spaced or unevenly spaced across the tire pad. The tire pad may include a tire stop to limit motion of the tire in one direction.

Abstract: Electric and plug-in hybrid electric vehicles include a rechargeable traction battery. An automated vehicle charging system is configured to charge the traction battery with minimal operator intervention. The vehicle charging system includes a carousel, including a plurality of transmit coils, configured to move in a longitudinal direction and rotate about an axis. The vehicle charging system further includes at least one controller programmed to move the carousel in the longitudinal direction and rotate the carousel about the axis to align a selected transmit coil from the plurality of transmit coils with a vehicle receive coil. The vehicle charging system may receive positioning data from a vehicle and may move and rotate the carousel according to the positioning data to align the selected transmit coil with the vehicle receive coil.