Abstract: A fluid delivery module includes a housing with a housing interior volume, the housing defining a first brush compartment and a second brush compartment within the housing interior volume; an inlet which introduces fluid into the housing interior volume; an outlet which discharges fluid from the housing interior volume; a fluid pump within the housing interior volume and having a pump section and a motor assembly which receives electric power through a first carbon brush and a second carbon brush such that the first carbon brush is received within a first carbon brush holder of the motor assembly and the second carbon brush is received within a second carbon brush holder of the motor assembly; and a filter within the housing interior volume which circumferentially surrounds the fluid pump. The first brush compartment encloses the first carbon brush holder and the second brush compartment encloses the second carbon brush holder.

Abstract: A valve assembly includes a housing with a bore, a supply port in fluid communication with the bore, a control port in fluid communication with the bore, and a vent port in fluid communication with bore such that the vent port is located at a location of the housing that is between the supply port and the control port. A valve seat assembly with a valve seat body is disposed within the housing and defines a control chamber in constant fluid communication with the control port, a vent path from the control port to the vent port, and a supply passage which provides constant fluid communication from the supply port to the control chamber. A vent valve member is selectively seated and unseated with the vent valve seat to selectively prevent and permit fluid communication from the control port to the vent port respectively.

Abstract: A GDCI engine control system determines if in-cylinder conditions are sufficient to achieve combustion in a given cylinder or if a misfire is likely. Fuel is delivered to that cylinder if combustion is probable, but fuel is disabled to that cylinder if a misfire is probable.

Abstract: A fuel injector includes a nozzle body having a spray tip with at least one spray orifice and a needle slideably arranged in the nozzle body in order to control the spray orifice. A control chamber is associated with the needle, which is filled with high-pressure fuel in order to exert a pressure force on the needle in its closing direction; the control chamber being in communication with a high pressure fuel channel through an inlet restrictor and with a low pressure drain through an outlet restrictor via a control valve to selectively allow or hinder the flow of fuel out of the control chamber through the outlet restrictor. The inlet restrictor and outlet restrictor are designed so that the ratio of outlet fuel flow rate over inlet fuel flow rate increases at low fuel temperatures, in order to cause a greater pressure reduction in the control chamber.

Abstract: A pump unit has an inlet valve, an outlet valve, a supply line for supplying fuel, a pumping chamber, and a plunger for pressurizing fuel in the pumping chamber. The inlet valve includes an inlet valve member movable between a first position and a second position. The inlet valve member has an aperture formed therein. The aperture provides a first fluid pathway between the pumping chamber and the supply line when the inlet valve member is in its first position, and the aperture provides a second fluid pathway between the pumping chamber and the outlet valve when the inlet valve member is in its second position.

Abstract: An object detection system for an automated vehicle includes a radar, a camera, and a controller. The radar detects a cluster of targets characterized by a radar-distance (x) from the host-vehicle. The camera renders an image of an object and a lane-marking present in the area.

Abstract: A cooperative-vehicle system suitable to operate an automated vehicle in a courteous or cooperative manner includes an object-detector and a controller. The object-detector is used by the host-vehicle to detect an other-vehicle attempting to enter a travel-lane traveled by the host-vehicle. The controller is in communication with the object-detector. The controller is configured to control motion of the host-vehicle. The controller is also configured to adjust a present-vector of the host-vehicle to allow the other-vehicle to enter the travel-lane. The decision to take some action to allow the other vehicle to enter the travel-lane may be further based on secondary considerations such as how long the other-vehicle has waited, a classification of the other-vehicle (e.g. an ambulance), an assessment of how any action by the host-vehicle would affect nearby vehicles, the intent of the other-vehicle, and/or a measure traffic-density proximate to the host-vehicle.

Abstract: An object-detection system suitable for an automated vehicle includes a lidar and a controller. The lidar is used to detect a point-cloud that is organized into a plurality of scan-lines. The controller is in communication with the lidar. The controller is configured to classify each detected point in the point-cloud as a ground-point or a non-ground-point, define runs of non-ground-points, where each run characterized by one or multiple instances of adjacent non-ground-points in a scan-line separated from a subsequent run of one or more non-ground-points by at least one instance of a ground-point, define a cluster of non-ground-points associated with the object. The cluster is characterized by a first run from a first scan-line being associated with a second run from a second scan-line when a first point from the first run is displaced less than a distance-threshold from a second point from the second run.

Abstract: A system for monitoring 3D space in front of an output unit for the control of the output unit comprises a 3D imaging unit, a processing and control unit coupled to the 3D imaging unit and an output unit comprising a display area and coupled to the processing and control unit. The 3D imaging unit is configured to monitor an interaction zone in front of the display area of the output unit. The processing and control unit is configured to predict where a finger of a hand that approaches the display area of the output unit and is monitored by the 3D imaging unit will touch the display area and to control the output unit to modify content displayed on the display area based on the predicted touch position.

Abstract: A sealing element for sealing a housing opening in a housing, wherein the sealing element comprises at least one through-opening for the passage of an electrical cable into the housing. The sealing element is formed of a first subcomponent and a second subcomponent, the first subcomponent and the second subcomponent having a different hardness and the two subcomponents are made of silicone.

Abstract: Fuel injection equipment includes a high pressure fuel source able to flow high pressure fuel via connecting pipes to a plurality of injectors. The fuel injection equipment is high pressure fuel reservoir-less, a distributed storage for high pressure fuel being arranged in the pipes and in the injectors.

Abstract: A safe-stop-zone identification system suitable for use on an automated-vehicle includes a digital-map, a transceiver, and a controller. The digital-map indicates a travel-path suitable for travel by a host-vehicle, wherein the digital-map also indicates a safe-stop-zone proximate to the travel-path. The transceiver is operable to broadcast information about the host-vehicle. The controller is in communication with the digital-map and the transceiver. The controller navigates the host-vehicle into the safe-stop-zone when an emergency-situation occurs, and then operates the transceiver to broadcast that the safe-stop-zone is occupied by the host-vehicle.

Abstract: A bussed electrical center includes an electrical-assembly and a single fastening feature. The electrical-assembly includes a lower-housing, a printed-circuit-board, an upper-housing, and electrical-devices. The lower-housing engages an outer-housing that retains electrical-connectors having a plurality of electrical-terminals. The printed-circuit-board has a plurality of corresponding-electrical-terminals configured to mate with the plurality of electrical-terminals of the electrical-connectors. The electrical-assembly defines a guide-hole that passes through the upper-housing, the printed-circuit-board, and the lower-housing, wherein the guide-hole defines a shoulder in the upper-housing. The single fastening feature consists of one first-fastener element positioned within the guide-hole that has a flange and a shank. The shank is operable to engage one second-fastener element in the outer-housing.

Abstract: An illustrative example camera device includes a sensor that is configured to detect radiation. A first portion of the sensor has a first field of vision and is used for a first imaging function. A distortion correction prism directs radiation outside the first field of vision toward the sensor. A lens element between the distortion correcting prism and the sensor includes a surface at an oblique angle relative to a sensor axis. The lens element directs radiation from the distortion correcting prism toward a second portion of the sensor that has a second field of vision and is used for a second imaging function. The sensor provides a first output for the first imaging function based on radiation detected at the first portion of the sensor. The sensor provides a second output for the second imaging function based on radiation detection at the second portion.

Abstract: A cross traffic detection system suitable for use on an automated vehicle includes an object-detector, an alert-device, and a controller. The object detector is used to determine locations of moving objects relative to a host vehicle. The alert device is used to alert an operator of the host vehicle to the location of the moving objects. The controller is in communication with the object detector and the alert device. The controller determines a first trail of a first moving object based on the locations of the first moving object, and determines a road model based on a polynomial of the first trail. The controller also determines a second trail of a second moving object, assigns a lane number to the second moving object based on the road model, and activates the alert device when the path of the second moving object resides in the lane-number overlain by a conflict zone.

Abstract: A sensor-control system for operating an automated vehicle includes a first sensor, a second sensor, and a controller. The first sensor is used to detect objects proximate to a host-vehicle. The first sensor is characterized by a first-sensing-technology. The second sensor is used to detect objects proximate to the host-vehicle. The second sensor is characterized by a second-sensing-technology different from the first-sensing-technology. The controller is in communication with the first sensor and the second sensor. A location of an object detected by the first-sensor is used to select a field-of-view of the second-sensor.

Abstract: A mounting-bracket configured to attach to a mounting-surface includes a base and sides, a retainer, an electrical-assembly, and a blocking-device. The mounting-surface defines a mounting-hole. The base and sides define a cavity. The base includes a retention-device that extends through the mounting-hole. The retention-device has an inner-surface and an outer-surface. The inner-surface defines an aperture and the outer-surface includes locking-tabs. The retainer is received within the aperture of the retention-device. The retainer has an end and walls generally perpendicular to the end. The walls are in direct contact with the inner-surface and prevent an inward-flexure of the locking-tabs. The electrical-assembly has a lower-surface that is received within the cavity. The blocking-device is in direct contact with the lower-surface of the electrical-assembly and the end of the retainer, thereby preventing a removal of the retainer from the aperture when the electrical-assembly is received within the cavity.

Abstract: A lane-keeping system suitable for use on an automated vehicle includes a camera, an inertial-measurement-unit, and a controller. The camera is configured to detect a lane-marking of a roadway traveled by a vehicle. The inertial-measurement-unit is configured to determine relative-motion of the vehicle. The controller in communication with the camera and the inertial-measurement-unit. When the lane-marking is detected the controller is configured to steer the vehicle towards a centerline of the roadway based on a last-position, and determine an offset-vector indicative of motion of the vehicle relative to the centerline of the roadway.

Abstract: An arrangement of a high-pressure valve at the end of a common rail of a fuel injection system, a high-pressure channel of the rail opening out at one extremity of the rail, includes a throttle stopper arranged at the extremity of the rail. An output orifice restricts a section of the high-pressure channel and a valve seat is positioned in the throttle stopper. The output channel is fully formed inside the valve body.

Abstract: A sound emitter device for use on a motor vehicle comprises a casing comprising an axial wall and a bottom wall, the axial wall extending along a vertical axis from the bottom wall toward an opening opposite the bottom wall, a control circuit, an acoustic membrane that closes the opening of the casing and that is provided on its lower face with excitation means controlled by the control circuit a peripheral rim that is arranged in the opening, the external peripheral edge of the acoustic membrane being mounted to bear on the peripheral rim, a secondary wall that is made in one piece with the peripheral rim and that is bent toward the peripheral rim so as to retain the acoustic membrane by clamping its external peripheral edge between the peripheral rim and the secondary wall.