Abstract: A backlight module capable of simple manufacture and a display device using the backlight module are provided. A reflective sheet to redirect the light from LEDs or other light source is located in position on the backlight module by means of optical lenses, which also spread the light for better uniformity of lighting. The optical lens includes inclined surfaces which form an opening with a circuit board that allows engagement of a reflective sheet. The reflective sheet is between the optical lens and the circuit board. The manufacturing step of fixing the reflective sheet to the circuit board is not required, and when any LED or other light emitting element, or the circuit board itself, fails, it is only necessary to disassemble the optical lens at the one position. Assembly and maintenance efficiency are improved, and the reliability of the backlight module and the display device is improved.

Abstract: A light source device for a display includes light emitting diode packages. Each light emitting diode package includes a substrate, a first light emitting diode chip emitting a first beam of light, a second light emitting diode chip emitting a second beam of light, and a package layer including a wavelength converting material. Frequency bands of the first and second light beams both have a full width at half maximum of 30 nm to 40 nm. The wavelength converting material is excited by the first and second beams to generate a third beam of light, the frequency band of the third beam of light having a full width at half maximum of 10 nm to 50 nm. A display using the light source device is also disclosed.

Abstract: A packaging structure of an LED comprises a substrate with first surface, a first electrode arranged on the first surface, at least one light emitting chip on the first electrode, and a packaging body arranged on the first surface to cover the light emitting chip. The first surface defines at least one groove, part of the package body is in the groove. By increasing the contact area between the substrate and the packaging body or mounting an embedded structure on the substrate, the firmness of the bond between the packaging body and the substrate is improved.

Abstract: A backlight module capable of simple manufacture and a display device using the backlight module are provided. A reflective sheet to redirect the light from LEDs or other light source is located in position on the backlight module by means of optical lenses, which also spread the light for better uniformity of lighting. The optical lens includes inclined surfaces which form an opening with a circuit board that allows engagement of a reflective sheet. The reflective sheet is between the optical lens and the circuit board. The manufacturing step of fixing the reflective sheet to the circuit board is not required, and when any LED or other light emitting element, or the circuit board itself, fails, it is only necessary to disassemble the optical lens at the one position. Assembly and maintenance efficiency are improved, and the reliability of the backlight module and the display device is improved.

Abstract: A liquid crystal display device comprises a backlight module and a liquid crystal display module in a light emitting path of the backlight module. The liquid crystal display module includes a first conductive substrate facing the backlight module, a second conductive substrate spaced apart from the first conductive substrate, and a liquid crystal layer sandwiched between the first conductive substrate and the second conductive substrate. The second conductive substrate includes a transparent substrate, a color filter layer formed on the transparent substrate, and a light converting layer formed on the color filter layer, and a transparent conductive layer formed on the light converting layer.

Abstract: A narrower LED package structure with sideways output of light suitable for a light guide plate includes two first electrodes, a package body, a cover layer, and two second electrodes. The LED chip is mounted on the first electrodes. The package body encapsulates the first electrodes, and surrounds the LED chip to define a light emitting region. The cover layer infills the light emitting region and covers the LED chip. The second electrodes are positioned outside the package body. Along a plane parallel to the first electrodes, a surface area of the two second electrodes is greater than a surface area of the portion of the two first electrodes positioned in the light emitting region.

Abstract: A narrower LED package structure with sideways output of light suitable for a light guide plate includes two first electrodes, a package body, a cover layer, and two second electrodes. The LED chip is mounted on the first electrodes. The package body encapsulates the first electrodes, and surrounds the LED chip to define a light emitting region. The cover layer infills the light emitting region and covers the LED chip. The second electrodes are positioned outside the package body. Along a plane parallel to the first electrodes, a surface area of the two second electrodes is greater than a surface area of the portion of the two first electrodes positioned in the light emitting region.

Abstract: A liquid crystal display module comprises a thin film transistor array substrate, a liquid crystal layer, a color filter substrate and a plurality of light emitting diode chips. The thin film transistor array substrate has a first surface and a second surface. A circuit structure is formed on the first surface. A plurality of thin film transistors is formed on the second surface and electrically connecting to the circuit structure. The liquid crystal layer faces the second surface. The liquid crystal layer is formed between the thin film transistor array substrate and the color filter substrate. The light emitting diode chips are adhered on the first surface and electrically connecting to the circuit structure. Each light emitting diode chip has a light emitting surface. Light emitted from the light emitting surfaces is incident on the first surface of the thin film transistor array substrate.

Abstract: A liquid crystal display device comprises a backlight module and a liquid crystal display module in a light emitting path of the backlight module. The liquid crystal display module includes a first conductive substrate facing the backlight module, a second conductive substrate spaced apart from the first conductive substrate, and a liquid crystal layer sandwiched between the first conductive substrate and the second conductive substrate. The second conductive substrate includes a transparent substrate, a color filter layer formed on the transparent substrate, and a light converting layer formed on the color filter layer, and a transparent conductive layer formed on the light converting layer.

Abstract: A liquid crystal display base includes a liquid crystal module, both a power circuit and a integration circuit, a electric device mounted on the power circuit. The liquid crystal module includes a TFT array substrate and a color filter substrate mounted on the TFT array substrate. The power circuit board mounted on the TFT array substrate. The TFT array substrate has a first surface and a second surface opposite to the first surface, a plurality of through holes extend through the first surface and the second surface, each through hole has equal inner diameter from the first surface to the second surface. the TFT array substrate 11 is made of glass, sapphire, ceramic, a plurality of conductive layers are in the plurality of through holes, both the electric device, the integration circuit and the power circuit board are coupled with the liquid crystal module.

Abstract: A device for extracting at least one analyte may include: a sample reservoir configured to contain a sample comprising at least one target analyte and interfering materials; at least one extraction chamber connected to the sample reservoir; at least one porous structure lining one or more sides of the at least one extraction chamber; and a voltage source configured to provide a first voltage and a second voltage, wherein, when the first voltage is provided, the at least one target analyte and the interfering materials move towards the at least one extraction chamber or to a predetermined area from the at least one extraction chamber, wherein, when the second voltage is provided, the interfering materials pass through and exit the at least one extraction chamber, and the at least one target analyte is stopped from exiting the at least one extraction chamber by means of the at least one porous structure.

Abstract: A lead frame for an LED package includes a substrate and a bonding electrode, a first connecting electrode, and a second connecting electrode embedded in the substrate. A top surface of the bonding electrode includes a first bonding surface and a second bonding surface spaced from the first bonding surface. A top surface of the first connecting electrode includes separated first and second connecting surfaces. Top surfaces of the bonding electrode, the first connecting electrode, and the second connecting electrode are exposed, and support and electrically connect with light emitting chips. LED packages can be mounted on the lead frame and electrically connect with each other. The conductive layout of the lead frame further permits installation of a zener diode which can be connected to the LED packages in series or in parallel.

Abstract: A method for manufacturing a light emitting diode (LED) die includes providing an LED die including a substrate, an N type semiconductor layer, an active layer, and a P type semiconductor layer grown on the substrate in sequence. The N type semiconductor layer, the active layer, and the P type semiconductor layer are etched to define a plurality of recesses and a groove. An insulating layer to cover side surfaces of the recesses and the P type semiconductor layer is formed and a portion of the insulating layer is etched to define an opening to expose a top portion of the P type semiconductor layer. A pair of electrodes is formed and the LED die is cut along the groove to obtain an individual LED die.

Abstract: A method for manufacturing a light emitting diode (LED) die includes providing an LED die including a substrate, an N type semiconductor layer, an active layer, and a P type semiconductor layer grown on the substrate in sequence. The N type semiconductor layer, the active layer, and the P type semiconductor layer are etched to define a plurality of recesses and a groove. An insulating layer to cover side surfaces of the recesses and the P type semiconductor layer is formed and a portion of the insulating layer is etched to define an opening to expose a top portion of the P type semiconductor layer. A pair of electrodes is formed and the LED die is cut along the groove to obtain an individual LED die.

Abstract: A miniaturized LED package substrate allowing for the better installation of an electrostatic protection device includes an upper substrate, a lower substrate, and a circuit layer. The circuit layer is positioned between the upper substrate and the lower substrate and electrically connected to the upper substrate and the lower substrate. At least one cavity is defined at the lower substrate, and each of the at least one cavity passes through the lower substrate to expose a portion of the circuit layer.

Abstract: A lead frame for an LED package includes a substrate and a bonding electrode, a first connecting electrode, and a second connecting electrode embedded in the substrate. A top surface of the bonding electrode includes a first bonding surface and a second bonding surface spaced from the first bonding surface. A top surface of the first connecting electrode includes separated first and second connecting surfaces. Top surfaces of the bonding electrode, the first connecting electrode, and the second connecting electrode are exposed, and support and electrically connect with light emitting chips. LED packages can be mounted on the lead frame and electrically connect with each other. The conductive layout of the lead frame further permits installation of a zener diode which can be connected to the LED packages in series or in parallel.

Abstract: A photoelectric device includes an electrode structure, an LED (light emitting diode) element, a zener diode and a reflective cup. The LED element, the zener diode and the reflective cup are arranged on the electrode structure. The LED element and the zener diode are electrically connected in anti-parallel with each other. The reflective cup comprises an inner surface defined thereof and a nick defined in an outside of the reflective cup. The LED element is surrounded by the inner surface of the reflective cup and the zener diode is arranged in the nick.

Abstract: The present disclosure provides a light emitting diode die which includes a substrate; an N type semiconductor layer, an active layer, and a P type semiconductor layer formed on the substrate in sequence; at least one recess, and a pair of electrodes. The recess extends to the N type semiconductor layer. The insulating layer covers the all of side surfaces of the N type semiconductor layer, the active layer, the P type semiconductor layer, and covers top of the P type semiconductor layer except an opening on the P semiconductor layer. One of the electrodes is filled in the recess and electrically connected to the N type semiconductor layer, and the other one of the electrodes is connected to the P type semiconductor layer in the opening. The present disclosure further provides an LED package having the LED die and a method for manufacturing the same.

Abstract: The present disclosure provides an LED package which includes electrodes, an LED die electrically connected with the electrodes, an encapsulation covering the LED die; and a casing surrounding the encapsulation and the LED die. The casing includes a base, a reflecting cup and a supporting portion. The reflecting cup extends from the base upwards, the reflecting cup surrounds the LED die, and the supporting portion is located inside the reflecting cup and across the electrodes.

Abstract: An exemplary lead frame includes a substrate and a bonding electrode, a first connecting electrode, and a second connecting electrode embedded in the substrate. A top surface of the bonding electrode includes a first bonding surface and a second bonding surface spaced from the first bonding surface. A top surface of the first connecting electrode includes a first connecting surface and a second connecting surface spaced from the first connecting surface. Top surfaces of the bonding electrode, the first connecting electrode and the second connecting electrode are exposed out of the substrate to support and electrically connect with light emitting chips. Light emitting chips can be mounted on the lead frame and electrically connect with each other in parallel or in series; thus, the light emitting chips can be connected with each in a versatile way.