A depth data detection apparatus and monitoring apparatus are disclosed. The depth data detection apparatus has at least two infrared light generators (11, 12) alternately operating, thereby ensuring that each of the infrared light generators has a sufficient power-off time while ensuring continuous operation of the system, so that each infrared light generator can reach its service lift as much as possible. Different infrared light generators can project infrared beams with different angles and/or from different positions, and the depth information obtained can be fused with each other in order to acquire the depth information of the object to be measured more completely. In addition, different infrared light generators can also project infrared beams to different areas or the same area of the space to be measured for their respective purposes.

A device that includes an image-acquiring system, a synchronous data-processing system that receives setpoints including at least one image-acquisition setpoint, and that determines, depending on at least one of the setpoints, adjustment data of the acquiring system, said synchronous system comprising a synchronous time-stamping means that time stamps, on acquisition, one of the adjustment data of the acquiring system, a means for associating one of the time-stamped adjustment data of the image-acquiring system with said image acquired at the moment of acquisition of the image by adding metadata to said image, an asynchronous system for processing said image with associated metadata, which generates and sends to the synchronous system the setpoints, the image-acquisition setpoint being determined based on an acquired image with associated metadata.

A device that includes an image-acquiring system, a synchronous data-processing system that receives setpoints including at least one image-acquisition setpoint, and that determines, depending on at least one of the setpoints, adjustment data of the acquiring system, said synchronous system comprising a synchronous time-stamping means that time stamps, on acquisition, one of the adjustment data of the acquiring system, a means for associating one of the time-stamped adjustment data of the image-acquiring system with said image acquired at the moment of acquisition of the image by adding metadata to said image, an asynchronous system for processing said image with associated metadata, which generates and sends to the synchronous system the setpoints, the image-acquisition setpoint being determined based on an acquired image with associated metadata.

The present invention relates to infrared imaging, providing a multi-purpose infrared imaging device. The multi-purpose infrared imaging device comprises a housing. An optical lens module is mounted at a front end of the housing. The housing has an opening. A power module for blocking the opening is detachably mounted in the housing. An infrared sensor module, an infrared signal processing module and an infrared digital image processing module are further mounted in the housing, and both of the infrared sensor module and the infrared digital image processing module are electrically connected to the infrared signal processing module and all of the three modules are electrically connected to the power module. The power module, the infrared sensor module, the infrared signal processing module and the infrared digital image processing module are integrated in the housing in the imaging device, such that the imaging device has multiple functions to effectively meet the multifunctional needs of users. Moreover, the structure of each part is mounted to the housing in a modular form, making it very convenient for installation, disassembly and maintenance.

A method for generating an infrared (IR) beam for illuminating a scene to be imaged comprises providing at least two IR emitters, including a first IR emitter operable to emit a wide beam component of the IR beam, and a second IR emitter operable to emit a narrow beam component of the IR beam, wherein the wide beam component has a linear profile that has a lower standard deviation than a linear profile of the narrow beam component. The method also comprises selecting a desired linear profile for the IR beam, and selecting a power ratio of power directed to the first IR emitter and power directed to the second IR emitter that produces the IR beam with the desired linear profile when the narrow beam component and wide beam component are combined.

Systems and methods are described for providing alerts. In various aspects, sensor data is received at one or more sensors associated with a vehicle, where the sensor data defines an electronic vehicle environment that indicates an electronic location of the vehicle. An electronic pedestrian or cyclist location is identified within the electronic vehicle environment, which is determined by a mobile device associated with a pedestrian or cyclist. Where a determination is made that the pedestrian or cyclist meets predetermined alert criteria based upon the electronic vehicle location and the electronic pedestrian or cyclist location, an alert is generated that indicates the presence of the pedestrian or cyclist within the vicinity of the vehicle. The alert is presented on a display screen.

An imaging device including a condenser lens and an image sensor is provided. The image sensor is configured to sense light penetrating the condenser lens and includes a pixel matrix, an opaque layer, a plurality of microlenses and an infrared filter layer. The pixel matrix includes a plurality of infrared pixels, a plurality of first pixels and a plurality of second pixels. The opaque layer covers upon a first region of the first pixels and a second region of the second pixels, wherein the first region and the second region are mirror-symmetrically arranged in a first direction. The plurality of microlenses is arranged upon the pixel matrix. The infrared filter layer covers upon the infrared pixels.

A system and method for tracking an object within a surgical field are described. A system may include a lighting component to illuminate a surgical field, and a camera device to capture an image of a tracked device within the surgical field. The system may include a rotational component configured to rotate with respect to the lighting component. The camera device may couple to the rotational component to rotate with respect to the lighting component, such as in response to an obstruction of a tracked object being detected.

An electronic device may have an optical system that includes one or more light-based components. The light-based components may include light-emitting components such as light-emitting diodes or lasers and may include light-detecting components such as photodiodes or digital image sensors. The optical system may include a light diffuser. The light diffuser may diffuse light that is being detected by a light-detecting component or may diffuse light that is being emitted by a light-emitting component. Light diffusers in optical systems may be formed from patterned light diffuser layers on transparent substrates. Layers of sealant, thin glass layers, antireflection coatings, and other layers may be incorporated into the light diffusers. The light diffuser layers may operate at visible wavelengths and infrared wavelengths. An infrared light diffuser layer may be formed from a patterned silicon layer such as a patterned layer of hydrogenated amorphous silicon.

A camera apparatus. The camera apparatus includes a housing having a front end and a back end; a lens, wherein the lens is disposed in the front end of the housing; and a thermal core, wherein the thermal core is disposed between the lens and the back end of the housing, the thermal core further comprising: at least one substrate; at least one thermally conductive member configured to remove heat from the thermal core; and an infrared imager affixed to one of the at least one substrate, the infrared imager configured to capture an infrared video stream.