Approaches presented herein enable tracking a physical object with a holographic projection, and, more specifically, enhancing a view of an object by tracking the object with a 3-D holographic projection. A holographic object tracking projection system receives, from a sensor, a feed of an area containing a physical object and locates a position of the physical object in the area based on the feed. The system creates a visible holographic object to mark the physical object, and projects the holographic object, using a holographic projector, at the position of the physical object. The holographic object can be a shape that surrounds the physical object in order to increase a visibility of the physical object. The physical object may move, and, as the physical object moves, the holographic object tracking projection system tracks this movement and adjusts the holographic object to match the movement of the physical object.

Provided is a processing apparatus (10) including a person detection unit (11) that detects a person from an image generated by a camera that photographs a target area, a computation unit (12) that analyzes the image and computes, for each person, a stay time in the target area and a degree of bias of an appearance position in the target area, and a target person extraction unit (13) that extracts a target person who is a person for whom a computation result by the computation unit (12) satisfies a predetermined condition.

Among other things, one or more systems and/or techniques for improving performance of a dispensing system are provided herein. The dispensing system may comprise an emitter and a detector. The emitter may be configured to transmit light (e.g., and/or one or more other signals). The detector may be configured to measure light, for example. The detector may determine a first measurement of light while the emitter is not transmitting light. The detector may determine a second measurement of light responsive to the emitter transmitting light. The detector may determine a third measurement of light based upon a comparison of the first measurement of light with the second measurement of light. The detector may be direct current (DC) coupled while determining the third measurement of light.

Among other things, one or more systems and/or techniques for improving performance of a dispensing system are provided herein. The dispensing system may comprise an emitter and a detector. The emitter may be configured to transmit light (e.g., and/or one or more other signals). The detector may be configured to measure light, for example. The detector may determine a first measurement of light while the emitter is not transmitting light. The detector may determine a second measurement of light responsive to the emitter transmitting light. The detector may determine a third measurement of light based upon a comparison of the first measurement of light with the second measurement of light. The detector may be direct current (DC) coupled while determining the third measurement of light.

Disclosed is an analysis method for detecting and analyzing light from a sample prepared so as to emit light in accordance with an amount of a test substance, the analysis method including taking an image of a storage member configured to store the sample therein; switching a state of a reflector to a state in which light from the sample is reflected toward a light detection unit and detecting light from the sample by the light detection unit; and outputting an analysis result of the sample on the basis of a light amount detected by the light detection unit.

Disclosed is an analysis method for detecting and analyzing light from a sample prepared so as to emit light in accordance with an amount of a test substance, the analysis method including taking an image of a storage member configured to store the sample therein; switching a state of a reflector to a state in which light from the sample is reflected toward a light detection unit and detecting light from the sample by the light detection unit; and outputting an analysis result of the sample on the basis of a light amount detected by the light detection unit.

The invention relates to a method for determining the origin of a mixture of constituents by spectral analysis. The invention especially relates to a method for determining the concentration and origin of raw gases and/or crude oils in a mixing zone following mixing by the transport of said raw gases and/or crude oils that come from at least two different sources of extraction, said method comprising a specific spectral analysis.

The invention relates to a method for determining the origin of a mixture of constituents by spectral analysis. The invention especially relates to a method for determining the concentration and origin of raw gases and/or crude oils in a mixing zone following mixing by the transport of said raw gases and/or crude oils that come from at least two different sources of extraction, said method comprising a specific spectral analysis.

An electromagnetic radiation sensing system, comprising sensing elements (604, 605, 606) and a Fresnel lens system for converging electromagnetic radiation; the sensing elements (604, 605, 606) are used to sense the electromagnetic radiation converged by the Fresnel lens system; the Fresnel lens system comprises at least two toothed faces (601, 602, 603) located on the same light path, each of the tooth faces comprising at least one Fresnel unit; at least one of the two toothed faces is a complex Fresnel refraction surface or a filled Fresnel refraction surface, or the two tooth faces are at a same physical interface and an element located thereon has a reflective back surface. The electromagnetic radiation sensing system can adequately utilize the advantage of the thinness of a Fresnel lens, and has better convergence without a significant increase in the thickness of the system, thus facilitating reducing of the size of a device and improving of the system performance.

An electromagnetic radiation sensing system, comprising sensing elements (604, 605, 606) and a Fresnel lens system for converging electromagnetic radiation; the sensing elements (604, 605, 606) are used to sense the electromagnetic radiation converged by the Fresnel lens system; the Fresnel lens system comprises at least two toothed faces (601, 602, 603) located on the same light path, each of the tooth faces comprising at least one Fresnel unit; at least one of the two toothed faces is a complex Fresnel refraction surface or a filled Fresnel refraction surface, or the two tooth faces are at a same physical interface and an element located thereon has a reflective back surface. The electromagnetic radiation sensing system can adequately utilize the advantage of the thinness of a Fresnel lens, and has better convergence without a significant increase in the thickness of the system, thus facilitating reducing of the size of a device and improving of the system performance.