Abstract: The present invention provides a supporting hook structure, comprising a sleeve, a fixing rod, a first limit unit, a hook and a fixing device. The fixing rod is connected to the side surface of the sleeve. The hook body is connected to one end of the sleeve. The first limit unit is arranged on the side surface of the sleeve and adjacent to the hook body. The first limit unit makes the hook body rotates with the axis direction of the sleeve as a rotation axis. The fixing device is connected to the other end of the sleeve to fix the rotating position of the hook body. Through the above, the hook part enters the proximal thigh from a surgical entrance and the hook part rotates to make the hook part abut against the proximal femur to complete the positioning and fixation of the femur hook structure to the femur.

Abstract: An acute kidney injury predicting system and a method thereof are proposed. A processor reads the data to be tested, the detection data, the machine learning algorithm and the risk probability comparison table from a main memory. The processor trains the detection data according to the machine learning algorithm to generate an acute kidney injury prediction model, and inputs the data to be tested into the acute kidney injury prediction model to generate an acute kidney injury characteristic risk probability and a data sequence table. The data sequence table lists the data to be tested in sequence according to a proportion of each of the data to be tested in the acute kidney injury characteristics. The processor selects one of the medical treatment data from the risk probability comparison table according to the acute kidney injury characteristic risk probability.

Abstract: A sensing apparatus including a sensing device, a light-transmitting protective layer, a light-shielding layer, a light-transmitting adhesive layer and a light guide device is provided. The light-transmitting protective layer is disposed on the sensing device. The light-shielding layer is disposed on the light-transmitting protective layer. The light shielding layer has a pinhole corresponding to the sensing device. The light-transmitting adhesive layer is disposed on the light-transmitting protective layer and at least in the pinhole. The light guide device is disposed on the light-transmitting adhesive layer and corresponds to the pinhole. There is a gap between the light guide device and the light shielding layer; and/or the refractive index of the light-transmitting adhesive layer is greater than the refractive index of the light guide device.

Abstract: A fingerprint sensing module includes a first substrate, an active device, a photosensitive element layer, a collimation structure layer, a second substrate, a plurality of micro lenses, and a spacer pattern. The active device is disposed on the first substrate. The photosensitive element layer is disposed on the first substrate and is electrically connected to the active device. The collimation structure layer is disposed on the photosensitive element layer. The second substrate is disposed on the collimation structure layer. The micro lenses are disposed on a surface of the collimation structure layer facing away from the photosensitive element layer, and overlap the photosensitive element layer. The micro lenses are divided into a plurality of microlens groups, and the microlens groups are respectively located in a plurality of sensing pixel areas of the fingerprint sensing module. The spacer pattern extends between the microlens groups.

Abstract: A fingerprint recognition device including a light emitting layer, an image sensing layer and a micro-lens layer is provided. The image sensing layer has a plurality of pixels. The micro-lens layer is disposed between the light emitting layer and the image sensing layer and has a plurality of micro lenses respectively corresponding to the pixels. A distance between the micro-lens layer and the light emitting layer is less than or equal to 800 um and greater than or equal to h1, where h1=(x/2×tan ?), x is the minimum distance between two micro lenses respectively corresponding to different pixels on a plane where the micro-lens layer is disposed, and ? is an FWHM light receiving angle of each of the micro lenses.

Abstract: A biometric identification device is provided. Photosensitive devices are disposed on the substrate. The first dielectric layer is disposed on the photosensitive devices. The first light-shielding parts are disposed on the first dielectric layer. Each of the first light-shielding parts has a first light-transmitting area and a first light-shielding area surrounding the first light-transmitting area. The first light-transmitting area corresponds to and overlaps with the photosensitive device, and at least two of the first light-shielding parts are spaced apart by a spacer area. The second dielectric layer is disposed on the first light-shielding parts. The second light-shielding part is disposed on the second dielectric layer. An orthogonal projection of at least a part of the spacer area on the substrate is within an orthogonal projection of a second light-shielding area on the substrate.

Abstract: A photosensitive device includes a first substrate, a second substrate, a supporting structure, multiple first microlenses, multiple second microlenses, a first photosensitive element, a second photosensitive element, and a collimating structure. The second substrate is opposite to the first substrate, and there is a gap between the first substrate and the second substrate. The supporting structure is located in the gap between the first substrate and the second substrate. The first microlenses and the second microlenses are respectively disposed on a first side and a second side of the gap. The first photosensitive element is overlapping with one of the first microlenses and one of the second microlenses. The second photosensitive element is overlapping with another one of the second microlenses. The collimating structure is located between the first substrate and the first microlenses.

Abstract: A fingerprint recognition device including a light emitting layer, an image sensing layer and a micro-lens layer is provided. The image sensing layer has a plurality of pixels. The micro-lens layer is disposed between the light emitting layer and the image sensing layer and has a plurality of micro lenses respectively corresponding to the pixels. A distance between the micro-lens layer and the light emitting layer is less than or equal to 800 um and greater than or equal to h1, where h1=x/(2×tan ?), x is the minimum distance between two micro lenses respectively corresponding to different pixels on a plane where the micro-lens layer is disposed, and ? is an FWHM light receiving angle of each of the micro lenses.

Abstract: A sensing apparatus including a sensing device, a light-transmitting protective layer, a light-shielding layer, a light-transmitting adhesive layer and a light guide device is provided. The light-transmitting protective layer is disposed on the sensing device. The light-shielding layer is disposed on the light-transmitting protective layer. The light shielding layer has a pinhole corresponding to the sensing device. The light-transmitting adhesive layer is disposed on the light-transmitting protective layer and at least in the pinhole. The light guide device is disposed on the light-transmitting adhesive layer and corresponds to the pinhole. There is a gap between the light guide device and the light shielding layer; and/or the refractive index of the light-transmitting adhesive layer is greater than the refractive index of the light guide device.

Abstract: A fingerprint sensing device has a sensing area, an operation area, and a peripheral area, and the operation area is disposed between the sensing area and the peripheral area. The fingerprint sensing device includes a substrate, a sensing element located at the sensing area, an operation element located at the operation area, a first signal line located at the peripheral area, a first planarization layer, a first insulating layer, and a first shading layer. The first planarization layer is located on the substrate and has a first trench, and the first trench overlaps the first signal line. The first insulating layer is located on the first planarization layer and in the first trench, and the first insulating layer has a first opening located in the first trench. The first shading layer is located on the first insulating layer and connected to the first signal line through the first opening.

Abstract: A fingerprint sensing module includes a first substrate, an active device, a photosensitive element layer, a collimation structure layer, a second substrate, a plurality of micro lenses, and a spacer pattern. The active device is disposed on the first substrate. The photosensitive element layer is disposed on the first substrate and is electrically connected to the active device. The collimation structure layer is disposed on the photosensitive element layer. The second substrate is disposed on the collimation structure layer. The micro lenses are disposed on a surface of the collimation structure layer facing away from the photosensitive element layer, and overlap the photosensitive element layer. The micro lenses are divided into a plurality of microlens groups, and the microlens groups are respectively located in a plurality of sensing pixel areas of the fingerprint sensing module. The spacer pattern extends between the microlens groups.

Abstract: A display device that includes a first substrate, a plurality of scan lines, a plurality of data lines, a plurality of pixel structures, a passivation layer, a bump, a second substrate, and a spacer is provided. The scan lines, the data lines, the pixel structures, and the passivation layer are all located on the first substrate. The bump is arranged on the first substrate. The second substrate is arranged opposite to the first substrate. The spacer is arranged on the second substrate and at least partially overlapped with the bump. One of the bump and the spacer has a first shape and the other has a second shape. Each of lengths of two end sections of the first shape in a first direction is larger than a length of a middle section of the first shape in the first direction.

Abstract: A display device that includes a first substrate, a plurality of scan lines, a plurality of data lines, a plurality of pixel structures, a passivation layer, a bump, a second substrate, and a spacer is provided. The scan lines, the data lines, the pixel structures, and the passivation layer are all located on the first substrate. The bump is arranged on the first substrate. The second substrate is arranged opposite to the first substrate. The spacer is arranged on the second substrate and at least partially overlapped with the bump. One of the bump and the spacer has a first shape and the other has a second shape. Each of lengths of two end sections of the first shape in a first direction is larger than a length of a middle section of the first shape in the first direction.

Abstract: A pixel structure is provided. The pixel structure includes a scan line, a data line, an active device, a covering layer, and a reflective pixel electrode. The active device is electrically connected with the scan line and the data line. The covering layer covers the scan line, the data line, and the active device. The reflective pixel electrode is disposed on the covering layer, and electrically connected with the active device. The reflective pixel electrode includes a first region having a plurality of first protruding structures and a second region having a planar surface. The area occupied by the first region is 50% to 70% of the total area of the reflective pixel electrode, and the area occupied by the second region is 30% to 50% of the total area of the reflective pixel electrode.

Abstract: A substrate structure including an upper surface, a lower surface and a plurality of side surfaces is provided. The lower surface is opposite to the upper surface. The side surfaces connect to the upper surface and the lower surface. Each side surface has a perpendicular surface, a first corner surface and a second corner surface. The perpendicular surface is perpendicular to the upper surface and the lower surface. The first corner surface is located between the perpendicular surface and the upper surface. The second corner surface is located between the perpendicular surface and the lower surface. The roughness of the first corner surface and the second corner surface are smaller than or equal to that of the perpendicular surface.

Abstract: A pixel structure is provided. The pixel structure includes a scan line, a data line, an active device, a covering layer, and a reflective pixel electrode. The active device is electrically connected with the scan line and the data line. The covering layer covers the scan line, the data line, and the active device. The reflective pixel electrode is disposed on the covering layer, and electrically connected with the active device. The reflective pixel electrode includes a first region having a plurality of first protruding structures and a second region having a planar surface. The area occupied by the first region is 50% to 70% of the total area of the reflective pixel electrode, and the area occupied by the second region is 30% to 50% of the total area of the reflective pixel electrode.