An optical panel includes a first transparent substrate, a second transparent substrate, an electrochromic assembly, a first transparent electrode layer, and a second transparent electrode layer. The second transparent substrate is arranged opposite the first transparent substrate. The electrochromic assembly is located between the first transparent substrate and the second transparent substrate and includes a plurality of electrochromic pixel-units that are arranged in an array. A shielding and spacing wall is arranged between two adjacent of the plurality of electrochromic pixel-units. The first transparent electrode layer is arranged between the electrochromic assembly and the first transparent substrate. The second transparent electrode layer is arranged between the electrochromic assembly and the second transparent substrate. The first transparent electrode layer and the second transparent electrode layer are configured to provide a driving voltage to the plurality of electrochromic pixel-units to adjust an optical parameter of the plurality of electrochromic pixel-units.

An object detection and display apparatus for mounting in a moveable body includes a far infrared camera (10), a display device (30), and a controller (22) (processor). The controller (22) detects, from a first image outputted by the far infrared camera (10), an image of a display target object at a distance equal to or greater than the distance reached by light from headlights (5) of the moveable body, and causes the display device (30) to display an image element corresponding to the display target object based on the position of the image of the display target object in the first image.

An object detection and display apparatus for mounting in a moveable body includes a far infrared camera (10), a display device (30), and a controller (22) (processor). The controller (22) detects, from a first image outputted by the far infrared camera (10), an image of a display target object at a distance equal to or greater than the distance reached by light from headlights (5) of the moveable body, and causes the display device (30) to display an image element corresponding to the display target object based on the position of the image of the display target object in the first image.

A control method for generating a high quality HDR image is provided. A control device of the technique of this disclosure is a control device configured to control an image capturing element capable of controlling an exposure condition for each of areas, the device including: an acquisition unit configured to acquire an exposure value map obtained by preliminary exposure using the image capturing element; and a setting unit configured to set the exposure condition including a shutter speed and an ISO sensitivity for each of the areas based on the exposure value map.

An optical panel includes a first transparent substrate, a second transparent substrate, an electrochromic assembly, a first transparent electrode layer, and a second transparent electrode layer. The second transparent substrate is arranged opposite the first transparent substrate. The electrochromic assembly is located between the first transparent substrate and the second transparent substrate and includes a plurality of electrochromic pixel-units that are arranged in an array. A shielding and spacing wall is arranged between two adjacent of the plurality of electrochromic pixel-units. The first transparent electrode layer is arranged between the electrochromic assembly and the first transparent substrate. The second transparent electrode layer is arranged between the electrochromic assembly and the second transparent substrate. The first transparent electrode layer and the second transparent electrode layer are configured to provide a driving voltage to the plurality of electrochromic pixel-units to adjust an optical parameter of the plurality of electrochromic pixel-units.

Disclosed are a method for determining semi-synchronous exposure parameters and an electronic device. The method in the embodiments of the present invention comprises: acquiring first exposure parameters corresponding to each lens; if it is determined that a preset EV limit value is not satisfied according to the first exposure parameters of each lens and adjacent lenses, respectively calculating exposure control parameters of each lens; calculating second exposure parameters corresponding to each lens according to the exposure control parameters of each lens and the first exposure parameters corresponding to each lens; if it is determined that the preset EV limit value is satisfied according to the second exposure parameters of each lens and adjacent lenses, determining the second exposure parameters corresponding to each lens to be semi-synchronized exposure parameters of each lens.

Provided are an information processing apparatus and an information processing method, an imaging apparatus, a mobile device, and a computer program that performs processing for controlling exposure of an in-vehicle camera. The information processing apparatus includes: a recognition unit that recognizes an image after an output signal of an image sensor is processed by a processing unit; and a control unit that controls at least one of imaging operation of the image sensor or processing operation in the processing unit on the basis of a recognition result of the recognition unit. The image sensor is mounted on a vehicle and used, and the recognition unit image-recognizes at least a surrounding vehicle or a road surface. Then, the control unit controls detection or development processing of the region of the surrounding vehicle or the road surface in the image.

Provided are an information processing apparatus and an information processing method, an imaging apparatus, a mobile device, and a computer program that performs processing for controlling exposure of an in-vehicle camera. The information processing apparatus includes: a recognition unit that recognizes an image after an output signal of an image sensor is processed by a processing unit; and a control unit that controls at least one of imaging operation of the image sensor or processing operation in the processing unit on the basis of a recognition result of the recognition unit. The image sensor is mounted on a vehicle and used, and the recognition unit image-recognizes at least a surrounding vehicle or a road surface. Then, the control unit controls detection or development processing of the region of the surrounding vehicle or the road surface in the image.

In order to obtain an inspection image without blown-out highlights generated due to specular reflection or the like or blocked-up shadows generated at a position to which light hardly reaches, an image processing device includes a plurality of light sources that irradiates an object with light and a control circuit that controls light emission of the plurality of light sources, a camera that photographs the object, and a processor that controls switching of a light emission pattern of the plurality of light sources and controls photographing execution timing of the camera, controls the plurality of light sources to emit light with a plurality of light emission patterns, performs photographing at timings during at least two or more patterns among the plurality of light emission patterns to obtain a plurality of intermediate images, and generates one final image based on the plurality of obtained intermediate images.

The present technology relates to an information processing device, an information processing method, and a program for achieving improvement of detection accuracy of object detection using an inference model. At least either a parameter associated with imaging or a parameter associated with signal processing for an input image obtained by the imaging is changed according to a type of an object detected from the input image by an inference model that uses a neural network.