Abstract: A detection system for a closure panel of a vehicle and corresponding method of operation are provided. The system includes a detection module including a sensor subassembly for detecting an object in a detection zone and sensing a motion and characteristics of the object and outputting a corresponding sensor signal. The system also includes a gesture selector for accepting a user input from a user to select a valid activation gesture and a controller arrangement coupled to the sensor subassembly. The controller arrangement receives the user input from the gesture selector and adjusts a plurality of predetermined thresholds representing the valid activation gesture by the user required to move the closure panel based on the user input. The controller arrangement analyzes the sensor signal and determines whether the sensor signal is within the plurality of predetermined thresholds and then initiates movement of the closure panel accordingly.

Abstract: A non-contact object and/or gesture detection system includes at least one sensor configured to sense an object or motion within a field of view (FOV) using radio frequency radiation. Various sensor and brackets are provided which may allow a position and/or tilt of the sensor to be adjusted for controlling the FOV. A sensor housing includes a vent filter that breathable but impermeable to liquids. Various antenna designs are provided to provide desired FOV sizes and shapes, particularly for optimizing a radiation pattern that is relatively wide and shallow. A steerable antenna layout is also provided for controlling the location of the FOV without an adjustable bracket. A sensor housing including a projector mount for an icon projector is provided. A seal prevents debris from entering between the antenna and the bumper.

Abstract: A user interface system for controlling a vehicle operation including a printed circuit board (PCB) that has a front side and a back side. A top layer that is electrically conductive defines the front side of the PCB. A plurality of indicia are etched into the top layer. An applique overlies the front side of the PCB. At least one proximity sensor is integrated into the front side of the PCB for detecting user object adjacent to the associated indicia and outputting a corresponding detection signal. The PCB further includes a base layer under the top layer. The base layer is at least partially formed of an optically transparent material. At least one light emitting device is positioned on the back side of the PCB for illuminating the indicia. A controller unit is coupled to the at least one proximity sensor and the at least one light emitting device.

Abstract: An ultrasonic object detection system for a motor vehicle is provided. The system includes an indicator attached to a vehicle body for informing a user of an appropriate location to make an activation gesture for initiating opening of a closure member. At least one ultrasonic transducer is attached to the vehicle body. An electronic control unit is electrically coupled to the indicator and includes at least one ultrasonic driver electrically coupled to the at least one ultrasonic transducer. The electronic control unit is in communication with a plurality of vehicle controllers and is configured to receive a plurality of operational signals from the plurality of vehicle controllers, detect the activation gesture made by the user with the at least one ultrasonic transducer, and transmit an activation signal to the plurality of vehicle controllers in response to detecting the activation gesture made by the user for operating the closure member.

Abstract: A user interface system for controlling a vehicle operation including a printed circuit board (PCB) that has a front side and a back side. A top layer that is electrically conductive defines the front side of the PCB. A plurality of indicia are etched into the top layer. An applique overlies the front side of the PCB. At least one proximity sensor is integrated into the front side of the PCB for detecting user object adjacent to the associated indicia and outputting a corresponding detection signal. The PCB further includes a base layer under the top layer. The base layer is at least partially formed of an optically transparent material. At least one light emitting device is positioned on the back side of the PCB for illuminating the indicia. A controller unit is coupled to the at least one proximity sensor and the at least one light emitting device.

Abstract: A method for determining a capacitance value of a capacitive sensor begins by applying a sensor signal (Vx) to the capacitive sensor. The sensor signal (Vx) includes a number of charge-discharge pulse pairs distributed over a first period of time (T/N), with each pulse pair having a different pulse period. The method then proceeds by accumulating a number (N) of samples of a reference voltage (Vs) measured across a reference capacitor (Cs) that is coupled to the capacitive sensor over a second period of time (T) to produce an accumulated capacitance value (ACCUMULATED). The accumulated capacitance value (ACCUMULATED) is then divided by the number (N) of the samples to determine the capacitance value (Cx) of the capacitive sensor.

Abstract: An obstacle sensor for a closure panel of a vehicle includes an elongate non-conductive case which encloses a first, second, and third elongate conductive electrodes. The first and second electrodes are separated by a portion of the case, with a capacitance between the first and second electrodes changing when an obstacle approaches the first electrode. The changed capacitance of the obstacle sensor provides a proximity indication of the obstacle to the obstacle sensor. The second and third electrodes are separated by an air gap formed in the case, with a resistance between the second and third electrodes changing when the second and third electrodes come into contact upon compression of the case by the obstacle. The changed resistance of the obstacle sensor provides a contact indication of the obstacle with the obstacle sensor.

Abstract: An obstacle sensor for a closure panel of a vehicle includes an elongate non-conductive case which encloses a first, second, and third elongate conductive electrodes. The first and second electrodes are separated by a portion of the case, with a capacitance between the first and second electrodes changing when an obstacle approaches the first electrode. The changed capacitance of the obstacle sensor provides a proximity indication of the obstacle to the obstacle sensor. The second and third electrodes are separated by an air gap formed in the case, with a resistance between the second and third electrodes changing when the second and third electrodes come into contact upon compression of the case by the obstacle. The changed resistance of the obstacle sensor provides a contact indication of the obstacle with the obstacle sensor.

Abstract: A capacitive sensing system for a liftgate of a vehicle includes at least one elongate capacitive sensor mounted on a trim panel of the liftgate. The at least one elongate capacitive sensor is arranged to extend over an area of the trim panel. The capacitive sensing system also includes a controller coupled to the at least one elongate capacitive sensor for monitoring changes in a capacitance value of the at least one elongate capacitive sensor, with the capacitance value changing when an obstacle approaches the area.

Abstract: An obstacle sensor for a closure panel of a vehicle includes an elongate non-conductive case which encloses a first, second, and third elongate conductive electrodes. The first and second electrodes are separated by a portion of the case, with a capacitance between the first and second electrodes changing when an obstacle approaches the first electrode. The changed capacitance of the obstacle sensor provides a proximity indication of the obstacle to the obstacle sensor. The second and third electrodes are separated by an air gap formed in the case, with a resistance between the second and third electrodes changing when the second and third electrodes come into contact upon compression of the case by the obstacle. The changed resistance of the obstacle sensor provides a contact indication of the obstacle with the obstacle sensor.