Abstract: A method for facilitating automated vehicle charging, which can include one or more of: detecting a charge port cover, determining a cover actuation point, opening the cover, locating a charging connector of the vehicle, locating electrical pins of the charging connector, connecting to the vehicle, and/or disconnecting from the vehicle. A system for facilitating automated vehicle charging, which can include one or more connectors, sensors, and/or actuators. The system is preferably configured to perform the method (e.g., in the presence of an electric vehicle).

Abstract: A method for facilitating automated vehicle charging, which can include one or more of: detecting a charge port cover, determining a cover actuation point, opening the cover, locating a charging connector of the vehicle, locating electrical pins of the charging connector, connecting to the vehicle, and/or disconnecting from the vehicle. A system for facilitating automated vehicle charging, which can include one or more connectors, sensors, and/or actuators. The system is preferably configured to perform the method (e.g., in the presence of an electric vehicle).

Abstract: A method for facilitating automated vehicle charging, which can include one or more of: detecting a charge port cover, determining a cover actuation point, opening the cover, locating a charging connector of the vehicle, locating electrical pins of the charging connector, connecting to the vehicle, and/or disconnecting from the vehicle. A system for facilitating automated vehicle charging, which can include one or more connectors, sensors, and/or actuators. The system is preferably configured to perform the method (e.g., in the presence of an electric vehicle).

Abstract: In some implementations, scene depth is extracted from dual frequency of a cross-correlation signal. A camera may illuminate a scene with amplitude-modulated light, sweeping the modulation frequency. For each modulation frequency in the sweep, each camera pixel may measure a cross-correlation of incident light and of a reference electrical signal. Each pixel may output a vector of cross-correlation measurements acquired by the pixel during a sweep. A computer may perform an FFT on this vector, identify a dual frequency at the second largest peak in the resulting power spectrum, and calculate scene depth as equal to a fraction, where the numerator is the speed of light times this dual frequency and the denominator is four times pi. In some cases, the two signals being cross-correlated have the same phase as each other during each cross-correlation measurement.

Abstract: In some implementations, scene depth is extracted from dual frequency of a cross-correlation signal. A camera may illuminate a scene with amplitude-modulated light, sweeping the modulation frequency. For each modulation frequency in the sweep, each camera pixel may measure a cross-correlation of incident light and of a reference electrical signal. Each pixel may output a vector of cross-correlation measurements acquired by the pixel during a sweep. A computer may perform an FFT on this vector, identify a dual frequency at the second largest peak in the resulting power spectrum, and calculate scene depth as equal to a fraction, where the numerator is the speed of light times this dual frequency and the denominator is four times pi. In some cases, the two signals being cross-correlated have the same phase as each other during each cross-correlation measurement.