Systems and methods for cash verification and remote deposit are provided. A method may include receiving credentials to authenticate a login to a mobile app that is associated with a first financial entity; receiving an instruction to deposit a bill of cash at a physical location associated with a second financial entity that is different from the first financial entity; illuminating a front face of the bill; capturing an image of the illuminated front face; illuminating a back face of the bill; capturing an image of the illuminated back face; extracting a first tier of features from the images; determining a denomination and/or version of the bill; when the denomination and/or version exceeds a predetermined first threshold, extracting a second tier of features; when all of the extracted features are associated with the same denomination and/or version, and all of the features that are associated with said denomination and/or version are detected, verifying the bill; and when the bill is verified and a message is received, from the second financial entity, confirming that the second financial entity received the bill, depositing an amount corresponding to the denomination in an account at the first financial entity.

Disclosed in a movement direction determination system comprising a first detection region, a second detection region and a processing circuit. The first detection region and the second detection region respectively comprises an optical sensor. The processing circuit determines a movement direction of an object according to the optical data generated by the first detection region and the second detection region. The present invention also discloses a movement direction determination system using a single detection region. The present invention also discloses an object volume computation system which can compute an object volume according to sensed optical data. The disclosed movement direction determination system can be used for various applications and the object volume computation system can assist product confirmation.

Provided is an identification method for an identification system, which includes a sensing area and an image sensor. First, a test object is close to the sensing area, so that the image sensor generates a dynamic image. Next, the test object gradually pressurizes the sensing area. Then, the test object completely covers the sensing area, and the image sensor further produces a perspective image. Finally, an identification module is used to determine whether the dynamic image is a biological image according to the perspective image, and to perform a subtraction operation on the dynamic image as a basis to determine whether to unlock the identification system. Therefore, the identification system and the identification method can achieve a real-time determination on whether the dynamic image is a biological image. Also, the identification method greatly improves the false acceptance rate (FAR) and the false rejection rate (FRR) of the identification system.

A sensing device includes a plurality of sensing sets having a plurality of lenses and a plurality of sensing units. The sensing units are configured to collect reflected light which pass through the lenses. Each sensing set adopts a structure which includes one sensing unit and multiple lenses for providing fingerprint sensing with high accuracy.

A sensing device includes a plurality of sensing sets having a plurality of lenses and a plurality of sensing units. The sensing units are configured to collect reflected light which pass through the lenses. Each sensing set adopts a structure which includes one sensing unit and multiple lenses for providing fingerprint sensing with high accuracy.

A vehicular occupant monitoring system includes a camera disposed at an interior rearview mirror of a vehicle. The camera includes an imaging array sensor and a lens. The lens is disposed at the imaging array sensor with a center axis of the lens vertically offset from a center region of the imaging array sensor. A center region of the lens is disposed at and images at a lower region of the imaging array sensor when the camera is disposed at the interior rearview mirror and an upper peripheral region of the lens images at the center region and a lower region of the imaging array sensor when the camera is disposed at the interior rearview mirror. The vehicular occupant monitoring system, responsive to processing by the image processor of image data captured by the camera, determines presence of an occupant of the vehicle.

A vehicular occupant monitoring system includes a camera disposed at an interior rearview mirror of a vehicle. The camera includes an imaging array sensor and a lens. The lens is disposed at the imaging array sensor with a center axis of the lens vertically offset from a center region of the imaging array sensor. A center region of the lens is disposed at and images at a lower region of the imaging array sensor when the camera is disposed at the interior rearview mirror and an upper peripheral region of the lens images at the center region and a lower region of the imaging array sensor when the camera is disposed at the interior rearview mirror. The vehicular occupant monitoring system, responsive to processing by the image processor of image data captured by the camera, determines presence of an occupant of the vehicle.

According to one embodiment, a detection device comprises a base, a sensor layer, a collimator, a plurality of lenses, and a spacer. The sensor layer is placed on the base and includes a plurality of sensors which output detection signals corresponding to incident light. The collimator layer is placed on the sensor layer and includes a collimator having a plurality of openings which overlap the sensors, respectively. The plurality of lenses are placed on the collimator layer and overlap the openings, respectively. The spacer protrudes more than the lenses in a stacking direction of the base, the sensor layer and the collimator layer.

According to one embodiment, a detection device comprises a base, a sensor layer, a collimator, a plurality of lenses, and a spacer. The sensor layer is placed on the base and includes a plurality of sensors which output detection signals corresponding to incident light. The collimator layer is placed on the sensor layer and includes a collimator having a plurality of openings which overlap the sensors, respectively. The plurality of lenses are placed on the collimator layer and overlap the openings, respectively. The spacer protrudes more than the lenses in a stacking direction of the base, the sensor layer and the collimator layer.

A method for fingerprint detection, which may more easily reduce an influence of a brightness change of a display screen on the fingerprint detection and improve performance of the fingerprint detection. The method for the fingerprint detection includes: receiving a synchronization signal of a display screen, the synchronization signal being configured to trigger a pixel array of a fingerprint sensor to expose, where a period of the synchronization signal is synchronized with a dimming period of the display screen, and the dimming period includes a bright period and a dark period; exposing each row of pixels in the pixel array in sequence based on triggering of the synchronization signal, so that a position of the pixel whose exposure time corresponding to the dark period in the pixel array is constant, where data of each row of the pixels after exposure is configured to obtain a fingerprint image.