An image processing system and a setting method capable of performing lighting setting of illumination in a simpler manner are provided. The control device (100) evaluates evaluation lighting patterns (xi) one by one to calculate evaluation values (Pi), and uses coefficients (1i) determined based on the evaluation values (Pi) to linearly combine each evaluation lighting pattern (xi) to determine a lighting pattern for measurement (L).

A setting apparatus comprises a setting unit that sets a virtual light parameter for applying an effect of irradiating virtual light on a plurality of subjects included in an image; and a classification unit that classifies the plurality of subjects into a plurality of groups based on a state of shadow. The setting unit sets the virtual light parameter for each group classified by the classification unit.

Methods and apparatus to monitor environments are disclosed. Example audience measurement devices disclosed herein execute, in connection with a first frame of data, a three-dimensional recognition analysis on an object detected in an environment within a threshold distance from a sensor. Disclosed example audience measurement devices also detect that the object has moved outside the threshold distance from the sensor in a second frame subsequent to the first frame. Disclosed example audience measurement devices further execute a two-dimensional recognition analysis on the object in the second frame.

A method and device for face identification, and a mobile terminal and a storage medium are provided. The method includes: (101) an image sensor is controlled to perform imaging; (102) imaging data obtained by the image sensor through the imaging is acquired; and (103) liveness detection is performed on an imaging object based on the imaging data.

Systems and methods for optical sensing, visualization and detection in media (e.g., turbid media; turbid water; fog; non-turbid media). A light source and an image sensor are positioned in turbid media or external to the turbid media with the light source within a field of view of the image sensor array. Temporal optical signals are transmitted through the turbid media via the light source and multiple perspective video sequence frames are acquired via the image sensor array of light propagating through the turbid media. A three-dimensional image is reconstructed from each frame and the reconstructed three-dimensional images are combined to form a three-dimensional video sequence. The transmitted optical signals are detected from the three-dimensional video sequence by applying a multi-dimensional signal detection scheme.

It is intended to promote enhancement of performance of acquiring a depth image. A depth image acquiring apparatus includes a light emitting diode, a TOF sensor, and a filter. The light emitting diode irradiates modulated light toward a detection area becoming an area in which a depth image is to be acquired to detect a distance. The TOF sensor receives incident light into which the light irradiated from the light emitting diode is reflected by an object lying in the detection area to become, thereby outputting a signal used to produce the depth image. The filter passes more light having a wavelength in a predetermined pass bandwidth than light having a wavelength in a pass bandwidth other than the predetermined pass bandwidth of the light made incident toward the TOF sensor. In this case, at least one of the light emitting diode, the TOF sensor, or arrangement of the filter is controlled in accordance with a temperature of the light emitting diode or the TOF sensor. The present technique, for example, can be applied to a system for with international search report acquiring a depth image by using a TOF system.

A method of determining volume of a deposited skinprint uses an apparatus comprising: a primary electromagnetic radiation source; an electromagnetic radiation detector; and a translucent waveguide comprising a first surface providing a waveguide interface coincident with a skinprint receiving region. The method comprises transmitting primary electromagnetic radiation from the primary electromagnetic radiation source towards the waveguide interface at an angle of incidence relative to and on a first side of a normal line that is perpendicular to the waveguide interface, such that: (a) where the waveguide interface interfaces directly with ambient, the primary electromagnetic radiation incident on the waveguide interface reflects in the waveguide interface at an angle of reflection relative to and on a second side of the normal line opposite the first side; and (b) where a deposited skinprint is present on the skinprint receiving region such that the waveguide interface interfaces with the skinprint and the skinprint interfaces with ambient, at least a portion of the primary electromagnetic radiation incident on the waveguide interface is caused by the skinprint to be transmitted through the waveguide interface. The method further comprises using the electromagnetic radiation detector to determine a primary output value being an amount of primary electromagnetic radiation transmitted through the waveguide interface and/or reflected by the waveguide interface. The method also comprises: using calibration data that provides correspondence between the primary output value and the volume of skinprint on the substrate so as to provide a value for the volume of the deposited skinprint.

A system includes: a light source that emits pulsed light that illuminates a user's head portion; a photodetector that detects at least part of pulsed light returning from the head portion and that outputs one or more signals corresponding to an intensity of the at least part; electrical circuitry; and a memory that stores an emotion model indicating a relationship between the one or more signals and emotions. Based on a change in the one or more signals, the electrical circuitry selects an emotion by referring to the model. The one or more signals include a first signal corresponding to an intensity of first part of the reflection pulsed light and a second signal corresponding to an intensity of second part of the reflection pulsed light. The first part includes part before a falling period is started; and the second part includes at least part in the falling period.

A portable detection system comprises an energy source configured to transmit energy, a retroreflective article, a detector configured to sense retroreflective energy produced by interaction of the energy transmitted from the source and the retroreflective article, and an indicator that indicates the detection of the retroreflective energy, wherein at least one of the energy source and the detector are configured to be worn by a user.

A distance measurement system includes two or more line pattern generators (LPGs), a camera, and a processor. Each LPG emits a line pattern having a first set of dark portions separated by a respective first set of bright portions. A first line pattern has a first angular distance between adjacent bright portions, and a second line pattern has a second angular distance between adjacent bright portions. The camera captures at least one image of the first line pattern and the second line pattern. The camera is a first distance from the first LPG and a second distance from the second LPG. The processor identifies a target object illuminated by the first and second line patterns and determines a distance to the target object based on the appearance of the target object as illuminated by the first and second line patterns.