A method for providing accident parameters to a person outside a vehicle after an accident includes ascertaining a first accident parameter that is representative of the severity and/or a consequence severity using a control unit of the vehicle, and determining a display device of the vehicle that can display the first accident parameter following the accident. The first accident parameter is provided on the determined display, and a second accident parameter that is representative of the severity and/or the accident consequence severity is ascertained. The method also includes receiving a release signal for the second accident parameter from the person outside the vehicle following the accident involving the vehicle, and verifying the release signal for the second accident parameter using the control unit of the vehicle. The second accident parameter is provided on the determined display if the release signal was successfully verified by the control unit of the vehicle.

A method for providing accident parameters to a person outside a vehicle after an accident includes ascertaining a first accident parameter that is representative of the severity and/or a consequence severity using a control unit of the vehicle, and determining a display device of the vehicle that can display the first accident parameter following the accident. The first accident parameter is provided on the determined display, and a second accident parameter that is representative of the severity and/or the accident consequence severity is ascertained. The method also includes receiving a release signal for the second accident parameter from the person outside the vehicle following the accident involving the vehicle, and verifying the release signal for the second accident parameter using the control unit of the vehicle. The second accident parameter is provided on the determined display if the release signal was successfully verified by the control unit of the vehicle.

Provided is a determination device capable of safely and reliably causing a vehicle on a side road to enter and merge into a main road when merging into the main road. Information is acquired that indicates the vehicle status of vehicles CA, etc., and vehicles Ca, etc., that are traveling on a side road SR that merges with a main road MR on which the vehicles CA, etc., are traveling. When, on the basis of said information, an intervehicular space is to be formed between the vehicles CA, etc., that will make it possible for a vehicle Ca, etc., to enter, the vehicles CA, etc., are caused to form an interval on the basis of the acceleration applied to each of the vehicles CA, etc., and the entering vehicle Ca, etc., is allowed to move to a position in the intervehicular space.

A canopy of a dump body for a truck comprises a deck having a length and a width greater in dimension that the length defined by a front edge, a rear edge opposite the front edge, a first side edge, and a second side edge opposite the first side edge. The deck can define an upper surface and a lower surface opposite the upper surface. In a front view the deck can define a concave shape, with a center portion and stepped portions between the center portion and the first and second side edges.

A position recognizing device according to one embodiments of the present disclosure includes a ranging point acquiring section, a region determining section, and a ranging point excluding section. The ranging point acquiring section is configured to acquire ranging point information in which distances to ranging points are associated with each of electromagnetic wave applying directions. The region determining section is configured to determine whether an object region that represents a region encompassed by joining ranging points that are in close proximity to one another exists at a position closer than a specific ranging point representing a certain ranging point among the ranging points. The ranging point excluding section is configured to define the ranging point in front of which the object region exists as a false image point at which no object actually exists and exclude the false image point from the ranging point information.

A position recognizing device according to one embodiments of the present disclosure includes a ranging point acquiring section, a region determining section, and a ranging point excluding section. The ranging point acquiring section is configured to acquire ranging point information in which distances to ranging points are associated with each of electromagnetic wave applying directions. The region determining section is configured to determine whether an object region that represents a region encompassed by joining ranging points that are in close proximity to one another exists at a position closer than a specific ranging point representing a certain ranging point among the ranging points. The ranging point excluding section is configured to define the ranging point in front of which the object region exists as a false image point at which no object actually exists and exclude the false image point from the ranging point information.

Aspects of the disclosure relate to computing platforms that utilize machine learning to reduce false positive/negative collision output generation. A computing platform may apply machine learning algorithms on received data to generate a collision output. In response to generating the collision output indicating a collision, the computing platform may identify a data collection location. If the data collection location is within a predetermined radius of a false positive collection location, the computing platform may modify the collision output to indicate a non-collision. If the data collection location is not within the predetermined radius, the computing platform may compute a score using telematics data and compare the score to a predetermined threshold. If the score does not exceed the predetermined threshold, the computing platform may modify the collision output to indicate a non-collision. If the score exceeds the predetermined threshold, the computing platform may affirm the collision output indicating a collision.

Aspects of the disclosure relate to computing platforms that utilize machine learning to reduce false positive/negative collision output generation. A computing platform may apply machine learning algorithms on received data to generate a collision output. In response to generating the collision output indicating a collision, the computing platform may identify a data collection location. If the data collection location is within a predetermined radius of a false positive collection location, the computing platform may modify the collision output to indicate a non-collision. If the data collection location is not within the predetermined radius, the computing platform may compute a score using telematics data and compare the score to a predetermined threshold. If the score does not exceed the predetermined threshold, the computing platform may modify the collision output to indicate a non-collision. If the score exceeds the predetermined threshold, the computing platform may affirm the collision output indicating a collision.

An ultrasonic sensor includes a sensor body, a cushion member, a retainer unit, and a drainage path. The sensor body includes an ultrasonic microphone and a microphone support unit which allows a protruding part of the ultrasonic microphone located at a distal end in an axial direction to protrude and supports the protruding part. The cushion member covers the protruding part. The retainer unit allows exposure of a portion of the cushion member that is located at the distal end in the axial direction, and a portion of the cushion member that is located at a proximal end in the axial direction is sandwiched between the retainer unit and an outer peripheral surface of the protruding part. The drainage path penetrates the retainer unit in a radial direction to allow water to be discharged out of the retainer unit from a gap between the retainer unit and the cushion member.

An ultrasonic sensor includes a sensor body, a cushion member, a retainer unit, and a drainage path. The sensor body includes an ultrasonic microphone and a microphone support unit which allows a protruding part of the ultrasonic microphone located at a distal end in an axial direction to protrude and supports the protruding part. The cushion member covers the protruding part. The retainer unit allows exposure of a portion of the cushion member that is located at the distal end in the axial direction, and a portion of the cushion member that is located at a proximal end in the axial direction is sandwiched between the retainer unit and an outer peripheral surface of the protruding part. The drainage path penetrates the retainer unit in a radial direction to allow water to be discharged out of the retainer unit from a gap between the retainer unit and the cushion member.