Abstract: A recoater collision prediction and calibration method for additive manufacturing and a system thereof are provided.

Abstract: A recoater collision prediction and calibration method for additive manufacturing and a system thereof are provided.

Abstract: A biodegradable iron-based alloy composition, a medical implant applying the iron-based alloy composition, and a manufacturing method of the medical implant are provided. The biodegradable iron-based alloy composition includes at least 98 wt % of iron and 2 wt % or less of an additional material. The additional material includes 0.1 wt %-0.8 wt % of Mn, 0.01 wt %-0.15 wt % of Mo, 0.1 wt %-0.3 wt % of Cr, 0.02 wt %-0.15 wt % of C, and 0.01 wt %-0.15 wt % of Si.

Abstract: A method for fabricating a medical device includes steps as follows: A degradable powder including at least one metal element is firstly provided on a target surface. A focused energy light bean is applied to sinter/cure the biodegradable powder within an oxygen-containing atmosphere; wherein the oxygen concentration of the oxygen-containing atmosphere is adjusted to provide a first oxygen concentration and a second concentration when the focused energy light is driven to a first location and second location of the target surface respectively. The aforementioned processes are then repeatedly carried out to form a three-dimensional (3D) structure of the medical device.

Abstract: A method for fabricating a medical device includes steps as follows: A degradable powder including at least one metal element is firstly provided on a target surface. A focused energy light bean is applied to sinter/cure the biodegradable powder within an oxygen-containing atmosphere; wherein the oxygen concentration of the oxygen-containing atmosphere is adjusted to provide a first oxygen concentration and a second concentration when the focused energy light is driven to a first location and second location of the target surface respectively. The aforementioned processes are then repeatedly carried out to form a three-dimensional (3D) structure of the medical device.

Abstract: A system for displaying images is disclosed. A display device comprises a first substrate comprising a plurality of pixels, each comprising RGB transparent sub-pixel regions. A second substrate comprises RGB regions opposite the first substrate, wherein the transparent sub-pixel regions respectively correspond to the three major color regions. A light blocking layer is disposed in one of the transparent sub-pixel regions of the first substrate. A photo spacer corresponding to the light blocking layer is formed, supporting the opposite first and second substrates.

Abstract: A control method applied to a display panel including a gate driver, a source driver, and a plurality of pixel units. Each pixel unit includes a storage capacitor. At a first time point, a scan signal is provided by the gate driver. At a second time point following the first time point, at least one data signal is provided by the source driver. The storage capacitor stores a corresponding voltage according to the data signal and a common voltage. At the second time point, the common voltage is stable.

Abstract: A system for displaying images is disclosed. A display device comprises a first substrate comprising a plurality of pixels, each comprising RGB transparent sub-pixel regions. A second substrate comprises RGB regions opposite the first substrate, wherein the transparent sub-pixel regions respectively correspond to the three major color regions. A light blocking layer is disposed in one of the transparent sub-pixel regions of the first substrate. A photo spacer corresponding to the light blocking layer is formed, supporting the opposite first and second substrates.

Abstract: A display panel including a first sub-pixel, a second sub-pixel, a third sub-pixel, and a first capacitor is disclosed. The first sub-pixel is coupled to a first gate line. The second sub-pixel is coupled to a second gate line. The third sub-pixel is coupled to the second gate line. The first, the second, and the third sub-pixels are arranged to form a delta pattern. The first capacitor is disposed between the first and the second sub-pixels to compensate for the brightness shift of the first sub-pixel.