Abstract: An illumination device including at least one light emitting element and a transparent lampshade is provided. The transparent lampshade is disposed on one side of the light emitting element and located on a light emitting path of the light emitting element. The transparent lampshade has a sealed space, a first fluid and a second fluid. The first fluid is a colloidal solution, and the first fluid is immiscible with the second fluid, and the first fluid and the second fluid flow in the sealed space to change a light shape of the emitted light from the light emitting element.

Abstract: A protective cover is detachably assembled to and electrically connected to an electronic device having an image capturing unit and a lens. The protective cover includes a base portion, at least one bending portion, and a plurality of light-emitting units. The electronic device is disposed on the base portion. The bending portion is foldably connected to at least one side of the base portion. There is at least one included angle between a side of the electronic device and the bending portion. The light-emitting units are disposed on the bending portion, and the light-emitting units are not coplanar with the lens.

Abstract: A light source module including a substrate, a plurality of first light emitting diode (LED) chips, and at least one second LED chip is provided. The substrate has an upper surface. The plurality of first LED chips are disposed on the upper surface and electrically connected to the substrate. The second LED chip is disposed on the upper surface and electrically connected to the substrate. A first distance is between a top surface of each of the first LED chips away from the upper surface of the substrate and the upper surface, a second distance is between a top surface of the second LED chip away from the upper surface of the substrate and the upper surface, and the second distance is greater than each of the first distances.

Abstract: An illumination system is provided, including a light emitting device and a control device, wherein the control device is coupled to the light emitting device so as to capture a situation data in a remote end and generate a situation signal correspondingly. The light emitting device receives the situation signal and generates a simulating situation.

Abstract: A light emitting device including a carrier, a substrate, at least one electrode pair, at least one light emitting diode (LED) and at least one positioning element is provided. The substrate is disposed on the carrier and has a body portion and at least one bending portion. The bending portion connects to the body portion. The bending portion is not coplanar with the body portion. The electrode pair is located on the body portion of the substrate. The LED is disposed on the body portion of the substrate and electrically connected to the electrode pair. The positioning element is disposed on the bending portion of the substrate for fixing the substrate on the carrier.

Abstract: A lighting device includes a light base, a light shade, a padding element, at least one light emitting element and a wavelength converting shell. The light shade is disposed on the light base and cooperating with the light base to define an accommodating space. The padding element is disposed on the light base and located in the accommodating space. The light emitting element is disposed on the padding element and emits a light beam. The wavelength converting shell is disposed on the padding element and covers the light emitting element. The light beam is emitted out from the wavelength converting shall by a first refraction, formed a luminous virtual image between a first top end of the light shade and a second top end of the wavelength converting shell by reflecting, and emitted out the light shade by a second refraction.

Abstract: A lighting structure includes a substrate, a light emitting diode, a cover unit, and a hollow column. The substrate has a top surface and a rear surface opposite to the top surface. The light emitting diode is disposed on the top surface and is electrically connected to the substrate. The cover unit is disposed on and cooperates with the substrate to define a receiving space in which the light emitting diode is disposed. The hollow column is connected to the rear surface of the substrate and extends in a vertical direction away from the rear surface. The cover unit and the hollow column respectively have a height in the vertical direction, and the height of the hollow column is 2 times to 10 times the height of the cover unit.

Abstract: A light source module includes a substrate, at least two light emitting diode (LED) chips and at least one dummy chip. The LED chips are disposed on the substrate. The dummy chip is disposed on the substrate and located between the LED chips. The LED chips, the dummy chip and the substrate are electrically connected to one another. The dummy chip is used to redirect a lateral light emitted from the LED chips.

Abstract: A wavelength converting substance is made of semiconductor material. The wavelength converting substance is suitable for absorbing an exciting light with the wavelength range falling between 300 nanometers and 490 nanometers and converting the exciting light to an emitted light with wavelength range falling between 450 nanometers and 750 nanometers.

Abstract: A method of forming light emitting diode dies includes: forming an epitaxial layered structure that defines light emitting units on a front surface of a substrate wafer; forming a photoresist layer over a back surface of the substrate wafer; aligning the substrate wafer and patterning the photoresist layer so as to form openings in the photoresist layer, each of the openings having an area less than a projected area of the respective light emitting unit; forming a solder layer on the photoresist layer such that the solder layer fills the openings in the photoresist layer; removing the photoresist layer and a portion of the solder layer that covers the photoresist layer from the substrate wafer; and dicing the substrate wafer.

Abstract: Solid-state hydrogen fuel with a polymer matrix and fabrication methods thereof are presented. The solid-state hydrogen fuel includes a polymer matrix, and a crushed mixture of a solid chemical hydride and a solid-state catalyst uniformly dispersed in the polymer matrix. The fabrication method for the solid-state hydrogen fuel includes crushing and mixing a solid chemical hydride and a solid-state catalyst in a crushing/mixing machine, and adding the polymer matrix into the mixture of the solid chemical hydride and the solid-state catalyst to process a flexible solid-state hydrogen fuel. Moreover, various geometric and/or other shapes may be formed and placed into suitable vessels to react with a particular liquid and provide a steady rate of hydrogen release.

Abstract: A light-emitting apparatus including a light guide unit, at least one light-emitting component, and a wavelength conversion unit is provided. The light guide unit has a first end and a second end opposite to the first end. The light-emitting component is disposed on the first end and emits a first light. The wavelength conversion unit is disposed on the second end. The light guide unit guides the first light emitted by the light-emitting component from the first end to the second end, and the wavelength conversion unit converts the first light into the second light, wherein the wavelength of the first light is different from the wavelength of the second light.

Abstract: A power supply device is provided. The power supply device includes a fuel cell, a hydrogen generator, a check valve and an exhaust valve. The fuel cell has a hydrogen inlet and a hydrogen outlet. The hydrogen generator is connected to the hydrogen inlet and used for generating hydrogen. The check valve is disposed in the hydrogen inlet and used for preventing the hydrogen within the fuel cell from flowing to the hydrogen generator, and preventing exterior air from entering the fuel cell. The exhaust valve is disposed in the hydrogen outlet for exhausting the hydrogen within the fuel cell.

Abstract: A power supply device is provided. The power supply device includes a fuel cell, a hydrogen generator, a check valve and an exhaust valve. The fuel cell has a hydrogen inlet and a hydrogen outlet. The hydrogen generator is connected to the hydrogen inlet and used for generating hydrogen. The check valve is disposed in the hydrogen inlet and used for preventing the hydrogen within the fuel cell from flowing to the hydrogen generator, and preventing exterior air from entering the fuel cell. The exhaust valve is disposed in the hydrogen outlet for exhausting the hydrogen within the fuel cell.

Abstract: An electronic device including an insulating substrate, a plurality of conductive vias and a chip is provided. The insulating substrate has an upper surface and a lower surface opposite to each other. The conductive vias pass through the insulating substrate. The chip is disposed on the upper surface of the insulating substrate and includes a chip substrate, a semiconductor layer and a plurality of contacts. The semiconductor layer is located between the chip substrate and the contacts. The contacts are electrically connected to the conductive vias. The material of the insulating substrate and the material of the chip substrate are the same.

Abstract: An electronic device including an insulating substrate, a chip and a patterned conductive layer is provided. The insulating substrate has an upper surface and a lower surface opposite to each other. The chip is disposed above the upper surface of the insulating substrate. The patterned conductive layer is disposed between the upper surface of the insulating substrate and the chip. The chip is electrically connected to an external circuit via the patterned conductive layer. Heat generated by the chip is transferred to external surroundings via the patterned conductive layer and the insulating substrate.

Abstract: A light emitting device including an insulating substrate, a plurality of light emitting diode (LED) chips and a patterned conductive layer is provided. The insulating substrate has an upper surface. The LED chips are disposed on the insulating substrate and located on the upper surface. The dominant wavelengths of the LED chips are in a wavelength range of a specific color light and the dominant wavelengths of at least two of the LED chips are different. The patterned conductive layer is disposed between the insulating substrate and LED chips, and electrically connected to the LEDs chip.

Abstract: Disclosed is a magnetic catalyst formed by a single or multiple nano metal shells wrapping a carrier, wherein at least one of the metal shells is iron, cobalt, or nickel. The magnetic catalyst with high catalyst efficiency can be applied in a hydrogen supply device, and the device can be connected to a fuel cell. Because the magnetic catalyst can be recycled by a magnet after generating hydrogen, the practicability of the noble metals such as Ru with high catalyst efficiency is dramatically enhanced.

Abstract: The present invention relates to a single-stage zero-current switching driving circuit for ultrasonic motor, which comprises: a buck-boost converter and a zero-current switching resonant inverter. The driving circuit according to the present invention integrates the buck-boost converter and the resonant inverter into a single-stage structure, so that the buck-boost converter and the resonant inverter share an active switch and a trigger signal, and therefore, the circuit is simplified and the loss caused by stage switching is reduced. Moreover, the buck-boost converter operates in a discontinuous-conduction mode (DCM), which allows the circuit to have high power factor, and enables the active switch to be capable of zero-current switching (ZCS), so that the loss caused by switching is largely reduced. In the driving circuit according to the present invention, there's no interaction of power between the buck-boost converter and the resonant inverter, so that the two circuits can be analyzed individually.

Abstract: Disclosed is a magnetic catalyst formed by a single or multiple nano metal shells wrapping a carrier, wherein at least one of the metal shells is iron, cobalt, or nickel. The magnetic catalyst with high catalyst efficiency can be applied in a hydrogen supply device, and the device can be connected to a fuel cell. Because the magnetic catalyst can be recycled by a magnet after generating hydrogen, the practicability of the noble metals such as Ru with high catalyst efficiency is dramatically enhanced.