Abstract: A free space positioning method for estimating an attitude angle of an object in a free space includes: capturing an image of a light source module that includes four light sources to generate a to-be-judged image; analyzing coordinates of the light sources in the to-be-judged image to obtain to-be-judged information; comparing the to-be-judged information with pre-stored light source orientation data to obtain candidate light source orientation data; and estimating an attitude angle of the object according to a pre-stored attitude angle corresponding to each of the candidate light source orientation data.

Abstract: An eye detection method for detecting a degree of eye opening and closure of a testee includes detecting a location of an eye pupil, a location of an inner eye corner and a location of an outer eye corner of an eye of the testee; calculating an eye width according to the location of the inner eye corner and the location of the outer eye corner; multiplying the eye width by a specific ratio to obtain an eye height; generating a region of interest with a center on the location of the eye pupil, a length equal to the eye width, and a width equal to the eye height; and determining a ratio of the eye occupying a detection area in the region of interest, and determining the degree of eye opening and closure of the testee accordingly.

Abstract: A touch panel including a substrate, a touch-sensing element, transmission lines, a ground electrode, a first electrode layer, an insulation layer and a second electrode layer is provided. The transmission lines are electrically connected to the touch-sensing element. The ground electrode surrounds the touch-sensing element and the transmission lines. The first electrode layer is located around and electrically connected to the ground electrode. The insulation layer is at least disposed on the first electrode layer. The second electrode layer is disposed on the insulation layer to form at least one capacitance storage unit, so that the electro static discharge can be conducted to the ground electrode through the capacitance storage unit.

Abstract: A free space positioning method for estimating an attitude angle of an object in a free space includes: capturing an image of a light source module that includes four light sources to generate a to-be-judged image; analyzing coordinates of the light sources in the to-be-judged image to obtain to-be-judged information; comparing the to-be-judged information with pre-stored light source orientation data to obtain candidate light source orientation data; and estimating an attitude angle of the object according to a pre-stored attitude angle corresponding to each of the candidate light source orientation data.

Abstract: A touch panel including a substrate, a touch-sensing element, transmission lines, a ground electrode, a first electrode layer, an insulation layer and a second electrode layer is provided. The transmission lines are electrically connected to the touch-sensing element. The ground electrode surrounds the touch-sensing element and the transmission lines. The first electrode layer is located around and electrically connected to the ground electrode. The insulation layer is at least disposed on the first electrode layer. The second electrode layer is disposed on the insulation layer to form at least one capacitance storage unit, so that the electro static discharge can be conducted to the ground electrode through the capacitance storage unit.

Abstract: A touch control panel includes a substrate, a touch-control element and a connection part. The substrate has a main portion and a protrusion portion positioned at a side of the main portion. The touch-control element is disposed on the main portion of the substrate and includes a conductive electrode and an electrode wire. The connection part is disposed on the protrusion portion of the substrate, including at least one connecting wire electrically connected to the electrode wire and positioned on the substrate. The connection part is used for coupling the touch-control element to an external system such that the sensing signal of the touch-control element can be delivered to the external system directly through the connecting wire of the connection part without any additional circuit board.

Abstract: The present invention provides a touch panel and a touch display panel including an insulating layer, a first conductive pattern, and a second conductive pattern. The first conductive pattern and the second conductive pattern are respectively disposed on two sides of the insulating layer. The first conductive pattern includes a plurality of first electrode strips, wherein each first electrode strip includes a strip portion and a plurality of protrusion portions protruding from two sides of the strip portion. The second conductive pattern includes a plurality of second electrode strips, crossing the first electrode strips.

Abstract: A touch pen includes a power supply circuit, a signal-receiving electrode, a noise-sensing electrode, an inverted amplifying circuit, and a signal-emitting electrode. The power supply circuit provides the touch pen with a working voltage, the signal-receiving electrode receiving at least one surface signal of a touch-sensing electrode structure of a capacitive touch-sensitive device, and the noise-sensing electrode receives at least one ambient noise signal. The inverted amplifying circuit reversely amplifies a difference between the surface signal and the ambient noise signal to generate a reversely amplified signal, and the signal-emitting electrode emits the reversely amplified signal to attenuate a detection signal of the capacitive touch-sensitive device in a position coinciding with a touch point of the touch pen.

Abstract: A touch panel includes a sensing electrode. The sensing electrode includes a plurality of mesh units pieced together with others. Each of the mesh units is different from at least one of adjacent mesh units in shape. Each of the mesh units has a plurality of side edges connected with one another. At least two side edges of each of the mesh units are different in length.

Abstract: A touch panel includes a substrate, a plurality of first touch-sensing units, and a plurality of first optical mesh patterns. The first touch-sensing units electrically insulated from each other or one another are located on the substrate. Each of the first touch-sensing units includes a plurality of first mesh patterns connected together. The first optical mesh patterns are located on the substrate. Besides, the first optical mesh patterns are overlapped with the first mesh patterns and located on a surface of the first mesh patterns adjacent to a user.

Abstract: A touch panel module with antenna structure includes a touch panel, a structure layer and an antenna coil. The structure layer includes a first surface and a second surface that are opposite to each other, and the first surface of the structure layer faces the touch panel. The antenna coil is disposed on the first surface of the structure layer.

Abstract: A touch display apparatus including a display panel and touch panel is provided. The display panel includes a first surface, a second surface and a first turning corner therebetween. The touch panel includes a flexible substrate having a first area, a second area and a first folding area, touch sensing electrodes, and transmission lines. The touch sensing electrodes are disposed on the first area and traverse across the first area in a direction. The transmission lines electrically connected to the touch sensing electrodes substantially traverse across the first folding area and extend from the first area to the second area. The material of the transmission lines at the first folding area includes metal. When the touch panel is attached on the display panel, the first area, the second area and the first folding area are respectively attached on the first surface, the second surface and the first turning corner.

Abstract: A capacitive touch panel includes at least one first conductive series extending along a first direction and at least one second conductive series extending along a second direction on a substrate. The first conductive series includes a plurality of first electrodes disposed along the first direction and a plurality of first connecting electrodes respectively disposed between two adjacent first electrodes. The second conductive series includes a plurality of second electrodes disposed along the second direction and a plurality of second connecting electrodes respectively disposed between two adjacent second electrodes. The first direction intersects the second direction. At least one kind of elements of the first electrodes, the first connecting electrodes, the second electrodes, and the second connecting electrodes are formed from a metal mash layer, and the first conductive series and the second conductive series are electrically isolated from each other.

Abstract: A touch panel includes a substrate, at least one first axis electrode, and at least one second axis electrode. The first axis electrode is disposed on the substrate and extends along a first direction. The first axis electrode includes at least one first mesh. The second axis electrode is disposed on the substrate and extends along a second direction. The second axis electrode includes at least one second mesh. The first axis electrode at least partially overlaps the second axis electrode along a direction perpendicular to the substrate. An aperture ratio of a region where the first axis electrode overlaps the second axis electrode is substantially equal to an aperture ratio of a region where the first axis electrode does not overlap the second axis electrode.

Abstract: A capacitive touch panel includes a first conductive layer, a second conductive layer and an insulating layer. The first conductive layer includes a plurality of first sensing electrodes, first bridge electrodes and second sensing electrodes. Each of the first sending electrodes and each of the second sending electrodes include a meshed electrode, which has a plurality of openings. The second conductive layer includes a plurality of second bridge electrodes, and each second bridge electrode is electrically connected to two adjacent second sensing electrodes. The insulating layer is disposed between the first conductive layer and the second conductive layer to electrically insulating the first conductive layer from the second conductive layer.

Abstract: A touch panel includes a first substrate and a first composite material conductive layer. The first composite material conductive layer has a first multilayer structure. The first multilayer structure includes a first refraction index compensating layer, a second refraction index compensating layer, and a first metal conductive layer. The first refraction index compensating layer, the first metal conductive layer, and the second compensation layer are stacked on the first substrate, and an equivalent refraction index of the first composite material conductive layer is substantially between a refraction index of the first substrate and 1.1 times the refraction index of the first substrate.

Abstract: A touch apparatus including a touch panel, a sensing controller and a capacitance matching unit is provided. The touch panel has a plurality of scan ports and a plurality of sensing ports, wherein the touch panel outputs a plurality of sensing signals through the sensing ports. The sensing controller drives the touch panel through a plurality of scan lines correspondingly coupled to the scan ports, and receives the sensing signals through a plurality of sensing lines correspondingly coupled to the sensing ports. The capacitance matching unit is coupled between the touch panel and the sensing controller through the scan lines, and is used for tuning an equivalent capacitance of the touch panel.

Abstract: A touch device, having a touch sensing region, includes a touch sensing structure and at least one object detecting device. The touch sensing structure is disposed in the touch sensing region. The touch sensing region is divided into a plurality of sub sensing regions, and the touch structure includes a plurality of sensing units for providing a function of positioning touch points. The object detecting device is disposed outside the touch sensing region. The object detecting device is employed to detect whether an object getting is close to the touch device and to determine which one of the sub sensing regions is going to be touched by the object so as to further enable the sensing units within the sub sensing region that is going to be touched by the object.

Abstract: The present invention provides an integrated panel of a touch panel and a phase modulator including a first transparent substrate, a second transparent substrate, a liquid crystal layer, a first transparent electrode layer, a second transparent electrode layer, a third transparent substrate, and a third transparent electrode layer. The first transparent substrate, the second transparent substrate, the liquid crystal layer, the first transparent electrode layer and the second transparent electrode layer constitute the phase modulator, and the second transparent electrode layer, the second transparent substrate, the third transparent substrate and the third transparent electrode layer constitute the touch panel.