Abstract: An unmanned operation vehicle includes a housing, a wheel provided in the housing, and an operation unit provided under the housing. The housing includes a plurality of cameras configured to capture an image of an outside of the unmanned operation vehicle. The plurality of cameras are arranged substantially at a center of an upper surface of the housing in a plan view. The housing may include a single camera unit including the plurality of cameras.

Abstract: An unmanned operation vehicle includes a housing, a wheel provided in the housing, and an operation unit provided under the housing. The housing includes a camera unit, a stop switch configured to stop driving of the wheel and the operation unit when actuated, and a stop switch actuating member configured to actuate the stop switch. The camera unit is arranged substantially at a center of an upper surface of the housing in a plan view, and the stop switch actuating member is arranged immediately above an upper surface of the camera unit.

Abstract: A working machine is provided which can suppress the adhesion of rain water, snow, and melting snow to an electrical connecting portion between a battery containing portion side and a battery side. An electrically driven snowplow as a working machine includes a battery pack incorporating a battery, a battery containing portion disposed so as to allow the battery pack to be inserted and removed in a direction inclined from a vertical direction, and an electrode portion configured to be connected with an output terminal of a battery disposed on an upper surface of the battery containing portion.

Abstract: Ahead protection airbag device includes an airbag. The airbag includes: a hag main body; and an attachment member configured to attach the bag main body to a predetermined attachment part. The attachment member includes: an attachment substrate; a neck part protruding from the attachment substrate; and an engaging head part arranged with being bulged at a tip end of the neck part. The bag main body has an insertion hole in which the neck part is inserted so as to enable the engaging head part to protrude from an outer surface-side of a folded body of the bag main body. The attachment substrate is arranged at a backside of a peripheral edge of the insertion hole so that the attachment member is attached to the bag main body.

Abstract: An unmanned operation vehicle includes a housing, a wheel provided in the housing, and an operation unit provided under the housing. The housing includes a plurality of cameras configured to capture an image of an outside of the unmanned operation vehicle. The plurality of cameras are arranged substantially at a center of an upper surface of the housing in a plan view. The housing may include a single camera unit including the plurality of cameras.

Abstract: An unmanned operation vehicle includes a housing, a wheel provided in the housing, and an operation unit provided under the housing. The housing includes a camera unit, a stop switch configured to stop driving of the wheel and the operation unit when actuated, and a stop switch actuating member configured to actuate the stop switch. The camera unit is arranged substantially at a center of an upper surface of the housing in a plan view, and the stop switch actuating member is arranged immediately above an upper surface of the camera unit.

Abstract: A marking device includes a light-emitting unit configured to emit light, a housing configured to accommodate the light-emitting unit, and a support configured to support the housing. The housing can include a transmitting portion configured to transmit the light from the light-emitting unit through a circumferential portion of the housing, and a roof covering the light-emitting unit accommodated in the housing. The housing can include a side wall formed between every two adjacent windows of the plurality of windows.

Abstract: An automatic operation vehicle that automatically performs an operation in an operation area is provided. A survey unit acquires the position information of the marker using a first angle between the moving direction and a direction to the marker from a first point through which the vehicle passes during the movement in a constant moving direction, a second angle between the moving direction and a direction to the marker from a second different point through which the vehicle passes during the movement in the moving direction, and a distance between the first point and the second point. The survey unit determines the first point and/or the second point during the movement of the vehicle in the moving direction such that the angle difference between the first angle and the second angle becomes close to 90°.

Abstract: An automatic operation vehicle that automatically performs an operation in an operation area is provided. The vehicle includes an image analysis unit configured to extract a marker included in an image captured by a camera provided on the automatic operation vehicle. If a situation in which the marker that was extracted from the image captured by the camera cannot be extracted by the image analysis unit from the image captured by the camera has occurred during a movement of the automatic operation vehicle in a constant direction. The image analysis unit determines whether the marker extracted before an occurrence of the situation and the marker extracted after an elimination of the situation are the same marker.

Abstract: An automatic operation vehicle that automatically performs an operation in an operation area is provided. The vehicle includes a moving direction determination unit configured to determine a moving direction of the vehicle, an image analysis unit configured to extract a marker included in an image captured by a camera provided on the vehicle, and a survey unit configured to acquire, by triangulation, position information of the marker extracted by the image analysis unit. When the survey unit starts acquiring the position information of the marker, the moving direction determination unit determines, as the moving direction, a direction in which the vehicle does not come into contact with the marker, and an angle difference with respect to a direction from a current position of the vehicle to the marker is smaller than 90°.

Abstract: A marking device includes a light-emitting unit configured to emit light, a housing configured to accommodate the light-emitting unit, and a support configured to support the housing. The housing can include a transmitting portion configured to transmit the light from the light-emitting unit through a circumferential portion of the housing, and a roof covering the light-emitting unit accommodated in the housing. The housing can include a side wall formed between every two adjacent windows of the plurality of windows.

Abstract: An automatic operation vehicle that automatically performs an operation in an operation area is provided. The vehicle includes a moving direction determination unit configured to determine a moving direction of the vehicle, an image analysis unit configured to extract a marker included in an image captured by a camera provided on the vehicle, and a survey unit configured to acquire, by triangulation, position information of the marker extracted by the image analysis unit. When the survey unit starts acquiring the position information of the marker, the moving direction determination unit determines, as the moving direction, a direction in which the vehicle does not come into contact with the marker, and an angle difference with respect to a direction from a current position of the vehicle to the marker is smaller than 90°.

Abstract: An automatic operation vehicle that automatically performs an operation in an operation area is provided. A survey unit acquires the position information of the marker using a first angle between the moving direction and a direction to the marker from a first point through which the vehicle passes during the movement in a constant moving direction, a second angle between the moving direction and a direction to the marker from a second different point through which the vehicle passes during the movement in the moving direction, and a distance between the first point and the second point. The survey unit determines the first point and/or the second point during the movement of the vehicle in the moving direction such that the angle difference between the first angle and the second angle becomes close to 90°.

Abstract: An automatic operation vehicle that automatically performs an operation in an operation area is provided. The vehicle includes an image analysis unit configured to extract a marker included in an image captured by a camera provided on the automatic operation vehicle. If a situation in which the marker that was extracted from the image captured by the camera cannot be extracted by the image analysis unit from the image captured by the camera has occurred during a movement of the automatic operation vehicle in a constant direction. The image analysis unit determines whether the marker extracted before an occurrence of the situation and the marker extracted after an elimination of the situation are the same marker.

Abstract: An imaging device (1) includes: an imaging element (33) which outputs a signal expressing an optical image of an imaging object upon an imaging process; a particular object detection unit (14) which successively acquires a frame image based on an output signal of the imaging element and detects the position of the particular object contained in the imaging object on the frame image according to the image signal of the frame image; a cut-out unit (15) which sets in the frame image, a cut-out region smaller than the entire region of the frame image according to the detected position and extracts the image in the cut-out region as a cut-out image; and an image quality compensation unit (16) which improves the resolution of the cut-out image.

Abstract: Electrolyzed water producing method and apparatus are provided which are capable of producing electrolyzed water having a desired property irrespective of the quality of raw water supplied and the like while allowing the size and weight of the apparatus and the cost to be reduced by limiting the capacity of an electrolysis power source. The electrolyzed water producing method includes: circulating an aqueous electrolyte solution to a first electrolytic chamber of a pair of electrolytic chambers opposed to each other across an intervening ion permeable diaphragm while supplying raw water to the second electrolytic chamber; and applying a predetermined voltage to a pair of electrodes disposed in the respective electrolytic chambers with the diaphragm intervening there between, to electrolyze the raw water and the aqueous electrolyte solution, thereby producing electrolyzed water in the second electrolytic chamber.

Abstract: A head-protecting airbag apparatus includes an inflated airbag with a rear inflatable portion covering the vicinity of a rear window of a vehicle, and a gas supply passage that inflates the rear portion. The rear inflatable portion includes a main body portion and an inlet inflatable portion, with a belt-shaped closing portion that partitions the two. The upper communication port and the lower communication port of the belt-shaped closing portion allow the inflation gas to flow from the inlet inflatable portion to the inflatable main body. In both communication ports, the opening area of the lower communication port is larger than the opening area of the upper communication port so that the airbag inflates via the lower communication port upon normal inflation of the airbag, and then inflates via the upper communication port upon abnormal inflation when the lower communication port is obstructed.

Abstract: Sound correction processing is performed for a sound signal obtained from a sound collecting portion. In particular, sound correction processing is performed after determining what is performed as the sound correction processing based on an image signal paired with a sound signal, the image signal obtained from an imaging portion, the sound signal, control data of the imaging portion, and the like.

Abstract: A head-protecting airbag apparatus includes an inflated airbag with a rear inflatable portion covering the vicinity of a rear window of a vehicle, and a gas supply passage that inflates the rear portion. The rear inflatable portion includes a main body portion and an inlet inflatable portion, with a belt-shaped closing portion that partitions the two. The upper communication port and the lower communication port of the belt-shaped closing portion allow the inflation gas to flow from the inlet inflatable portion to the inflatable main body. In both communication ports, the opening area of the lower communication port is larger than the opening area of the upper communication port so that the airbag inflates via the lower communication port upon normal inflation of the airbag, and then inflates via the upper communication port upon abnormal inflation when the lower communication port is obstructed.

Abstract: Sound correction processing is performed for a sound signal obtained from a sound collecting portion. In particular, sound correction processing is performed after determining what is performed as the sound correction processing based on an image signal paired with a sound signal, the image signal obtained from an imaging portion, the sound signal, control data of the imaging portion, and the like.