A device for identifying a pattern over a first surface includes a photosensitive layer, and a light-guiding layer disposed between the photosensitive layer and the first surface. The photosensitive layer includes a plurality of photosensitive elements, each configured to convert incident light into an electrical signal. The light-guiding layer includes a plurality of light-guiding units, each positionally corresponding to one of the plurality of photosensitive elements. Each light-guiding unit include a plurality of light-transmitting portions, each configured to guide a light beam reflected from a feature of the pattern positionally corresponding thereto to transmit therethrough and reach one of the plurality of photosensitive elements corresponding to the each of the plurality of light-guiding units. The device can be used for identification of fingerprint, as well as other biometric or non-biometric features, and has a reduced thickness and an improved accuracy for pattern identification.

According to examples, a remote sensing security system that includes a dual-purpose camera system comprising at least one dual-purpose camera is disclosed. The dual-purpose camera may include a visible light sensor that detects one or more of objects and movements in the visible spectrum and an infrared (IR) sensor that detects one or more of objects and movements in the IR spectrum. The data from the dual-purpose camera system may be transmitted to a cloud server which may process the data to identify the detected objects and/or movements. If any objects and/or movements related to an emergency to are identified, then the type of emergency may also be determined and alerts may be transmitted to one or more client devices which may include head-mounted display (HMD) devices.

According to examples, a remote sensing security system that includes a dual-purpose camera system comprising at least one dual-purpose camera is disclosed. The dual-purpose camera may include a visible light sensor that detects one or more of objects and movements in the visible spectrum and an infrared (IR) sensor that detects one or more of objects and movements in the IR spectrum. The data from the dual-purpose camera system may be transmitted to a cloud server which may process the data to identify the detected objects and/or movements. If any objects and/or movements related to an emergency to are identified, then the type of emergency may also be determined and alerts may be transmitted to one or more client devices which may include head-mounted display (HMD) devices.

According to an aspect, a detection device includes: a light source configured to emit light to an object to be detected; a plurality of photodiodes arranged in a detection area; one or more detection circuits; and a coupling switching circuit configured to switch coupling of one or more of the photodiodes to one or more of the detection circuits. The coupling switching circuit is configured to change the number of the detection circuits coupled to one or more of the photodiodes based on an output value from one or more of the photodiodes.

According to an aspect, a detection device includes: a light source configured to emit light to an object to be detected; a plurality of photodiodes arranged in a detection area; one or more detection circuits; and a coupling switching circuit configured to switch coupling of one or more of the photodiodes to one or more of the detection circuits. The coupling switching circuit is configured to change the number of the detection circuits coupled to one or more of the photodiodes based on an output value from one or more of the photodiodes.

A camera assembly, including: an enclosure having at least two mounting surfaces that are orthogonal to each other for alignment with at least two orthogonal surfaces against which the camera assembly is to be mounted; at least one imaging apparatus disposed within the enclosure and having a predetermined orientation with respect to the enclosure; and a communication device disposed within the enclosure; and a server disposed at a location remote from where the camera is mounted. The camera assembly and the server communicate over a computer communication network to identify at least one mounting measurement of the camera assembly to establish a mapping from an image coordinate system for images generated by the imaging apparatus and a real world coordinate system aligned with an orientation defined by the at least two orthogonal surfaces.

A camera assembly, including: an enclosure having at least two mounting surfaces that are orthogonal to each other for alignment with at least two orthogonal surfaces against which the camera assembly is to be mounted; at least one imaging apparatus disposed within the enclosure and having a predetermined orientation with respect to the enclosure; and a communication device disposed within the enclosure; and a server disposed at a location remote from where the camera is mounted. The camera assembly and the server communicate over a computer communication network to identify at least one mounting measurement of the camera assembly to establish a mapping from an image coordinate system for images generated by the imaging apparatus and a real world coordinate system aligned with an orientation defined by the at least two orthogonal surfaces.

A method of viewing image data of local content is disclosed. An augmented reality view is created by storing a first device coordinate frame (DCF), moving a first registration marker to select a first feature point (FP1) and a second feature point (FP2) on at least one real-word object viewable by the user through a display. A uniform coordinate system (UCS) alignment module stores locations of the registration marker when selecting the FP1 and the FP2, determines a user coordinate frame (UCF) based on the locations of the first registration marker when selecting the FP1 and the FP2, transforms the DCF to the UCF and displays image data of local content received on a first data source with a projector through the display to the user based on the transformation from the first DCF to the first UCF.

A method of viewing image data of local content is disclosed. An augmented reality view is created by storing a first device coordinate frame (DCF), moving a first registration marker to select a first feature point (FP1) and a second feature point (FP2) on at least one real-word object viewable by the user through a display. A uniform coordinate system (UCS) alignment module stores locations of the registration marker when selecting the FP1 and the FP2, determines a user coordinate frame (UCF) based on the locations of the first registration marker when selecting the FP1 and the FP2, transforms the DCF to the UCF and displays image data of local content received on a first data source with a projector through the display to the user based on the transformation from the first DCF to the first UCF.

Embodiments of the present systems and methods may provide imaging techniques for multidirectional imaging, light conditioning, illumination sequences, or machine learning to create algorithms created from training by other advanced imaging techniques. In an embodiment, a method for generating an image may comprise obtaining an image of an object produced by a camera and generating, from the obtained image produced by a conventional camera, using an artificial intelligence model and imaging process, an output image including additional information similar to additional information present in an image of the object produced by an advanced imaging system.