Abstract: A power transfer device including an AC power source unit and a single power transfer element, and a power reception device including a single power reception element electrically coupled to the power transfer element and a power reception circuit outputting power are included. The power reception circuit includes a different potential field disposed at a position that is an electric field formed by the power transfer element and at which intensity of the electric field is different from intensity of an electric field formed at a position of the power reception element.

Abstract: A method includes steps of: based on training sets of gastrointestinal images, using a predetermined machine learning algorithm to obtain a preliminary model; feeding preliminary validation sets of gastrointestinal images into the preliminary model to obtain estimation results; based on the estimation results, selecting, from the preliminary validation sets of gastrointestinal images, a series of successive images as a selected validation set of gastrointestinal images; based on the selected validation set of gastrointestinal images, tuning parameters of the preliminary model to result in a speed-determining model for determining a moving speed of an endoscope camera.

Abstract: A power transfer device including an AC power source unit and a single power transfer element, and a power reception device including a single power reception element electrically coupled to the power transfer element and a power reception circuit outputting power are included. The power reception circuit includes a different potential field disposed at a position that is an electric field formed by the power transfer element and at which intensity of the electric field is different from intensity of an electric field formed at a position of the power reception element.

Abstract: A method for detecting objects and labeling the objects with distances in an image includes steps of: obtaining a thermal image from a thermal camera, an RGB image from an RGB camera, and radar information from an mmWave radar; adjusting the thermal image based on the RGB image to generate an adjusted thermal image, and generating a fused image based on the RGB image and the adjusted thermal image; generating a second fused image based on the fused image and the radar information; detecting objects in the images, and generating, based on the fused image, another fused image including bounding boxes marking the objects; and determining motion parameters of the objects.

Abstract: A method for detecting objects and labeling the objects with distances in an image includes steps of: obtaining a thermal image from a thermal camera, an RGB image from an RGB camera, and radar information from an mmWave radar; adjusting the thermal image based on the RGB image to generate an adjusted thermal image, and generating a fused image based on the RGB image and the adjusted thermal image; generating a second fused image based on the fused image and the radar information; detecting objects in the images, and generating, based on the fused image, another fused image including bounding boxes marking the objects; and determining motion parameters of the objects.

Abstract: The present invention provides a display device including: a backlight module, including a back bezel having a bottom surface, and a frame having a side wall portion, where the side wall portion has an inner side surface and an outer side surface, and the back bezel faces the inner side surface of the side wall portion; a display module, disposed on the backlight module and supported by the frame; a tape, attached to the outer side surface of the side wall portion of the frame and extending to the bottom surface of the back bezel; and a sealant, disposed and extending from an end edge of the display module to the bottom surface of the back bezel through an outer side of the outer side surface of the side wall portion of the frame, and at least partially covering the tape.

Abstract: An automatic alignment system of a robot manipulator is provided. The automatic alignment system includes a signal transmission module and a controller. The signal transmission module includes a first signal receiving and transmitting element and a second signal receiving and transmitting element. The first signal receiving and transmitting element is mounted on the robot manipulator. The second signal receiving and transmitting element is disposed neighboring to a target workpiece. A signal is transported between the signal receiving and transmitting elements. The controller is electrically connected with the signal transmission module for receiving the signal outputted from the signal transmission module. The controller acquires a relative position between the first signal receiving and transmitting element and the second signal receiving and transmitting element according to a variation in the signal.

Abstract: An action teaching method is provided for teaching a robotic arm of a robotic arm system through a gesture teaching device. In a step (a), a touch condition of a user's finger is sensed by the touch sensing unit. In a step (b), a sensing result of the touch sensing unit is transmitted to an identification unit, so that a touch information is identified by the identification unit. In a step (c), the touch information is transmitted to a teaching unit, so that the teaching unit actuates a corresponding operation of the robotic arm system according to the touch information. In a step (d), an operating result of the robotic arm system is shown on a display unit, so that the user judges whether the operating result of the robotic arm system is successful through the display unit.

Abstract: The present invention provides a display device including: a backlight module, including a back bezel having a bottom surface, and a frame having a side wall portion, where the side wall portion has an inner side surface and an outer side surface, and the back bezel faces the inner side surface of the side wall portion; a display module, disposed on the backlight module and supported by the frame; a tape, attached to the outer side surface of the side wall portion of the frame and extending to the bottom surface of the back bezel; and a sealant, disposed and extending from an end edge of the display module to the bottom surface of the back bezel through an outer side of the outer side surface of the side wall portion of the frame, and at least partially covering the tape.

Abstract: An automatic alignment system of a robot manipulator is provided. The automatic alignment system includes a signal transmission module and a controller. The signal transmission module includes a first signal receiving and transmitting element and a second signal receiving and transmitting element. The first signal receiving and transmitting element is mounted on the robot manipulator. The second signal receiving and transmitting element is disposed neighboring to a target workpiece. A signal is transported between the signal receiving and transmitting elements. The controller is electrically connected with the signal transmission module for receiving the signal outputted from the signal transmission module. The controller acquires a relative position between the first signal receiving and transmitting element and the second signal receiving and transmitting element according to a variation in the signal.

Abstract: An action teaching method is provided for teaching a robotic arm of a robotic arm system through a gesture teaching device. In a step (a), a touch condition of a user's finger is sensed by the touch sensing unit. In a step (b), a sensing result of the touch sensing unit is transmitted to an identification unit, so that a touch information is identified by the identification unit. In a step (c), the touch information is transmitted to a teaching unit, so that the teaching unit actuates a corresponding operation of the robotic arm system according to the touch information. In a step (d), an operating result of the robotic arm system is shown on a display unit, so that the user judges whether the operating result of the robotic arm system is successful through the display unit.

Abstract: A nanoporous film and fabrication method thereof. The method for fabricating nanoporous film comprising: providing a substrate with a surface; forming a coating of a composition on the surface, curing the coating to polymerize the oxide gel, thereby forming an organic/inorganic hybrid film; and dissolving the template from the organic/inorganic hybrid film by an organic solvent. Specifically, the composition comprises the following components: an oxide gel, a template and an initiator.

Abstract: An antireflective coating composition, antireflection films and fabrication method thereof. The antireflection film is constructed by stacked crosslink colloid particles, having a plurality of nanopores distributed uniformly therein. Due to the nanopores, the antireflection film has a refractive index less than 1.45, reducing the reflectivity of less than 3.0%. Furthermore, since the antireflection film comprises crosslink oxide colloid, the film exhibits superior mechanical strength and is suitable for use in display devices.

Abstract: An antireflective coating composition, antireflection films and fabrication method thereof. The antireflection film is constructed by stacked crosslink colloid particles, having a plurality of nanopores distributed uniformly therein. Due to the nanopores, the antireflection film has a refractive index less than 1.45, reducing the reflectivity of less than 3.0%. Furthermore, since the antireflection film comprises crosslink oxide colloid, the film exhibits superior mechanical strength and is suitable for use in display devices.

Abstract: A nanoporous film and fabrication method thereof. The nanoporous film according to the present invention has a plurality of nanopores distributed uniformly therein. Due to the nanopores, the nanoporous film has a refractive index less than 1.45, reducing the reflectivity of less than 3.0%. Furthermore, since the nanoporous film comprises organic-inorganic hybrid with a high crosslink density, the film exhibits superior mechanical strength and is highly suitable for use as anti-reflection and anti-abrasion coatings.

Abstract: A polymer film with three-dimensional nanopores and fabrication method thereof. The polymer film according to the invention has a plurality of nanopores distributed uniformly thereover and presents a sponge-like profile. Due to the nanopores being sufficiently filled by air, the polymer film has a refractive index less than 1.45, reducing the reflectivity thereof to less than 2.0%. Furthermore, the polymer film exhibits superior antifouling properties as the contact angle of the polymer film to water greater than 90°.