In an LED display device according to an embodiment of the present disclosure, the LED display device comprises a second pixel driving circuit on a substrate, an LED element attached to a region not overlapping the second pixel driving circuit, including a first LED element, a second LED element and a growth substrate, and providing a double light-emitting spectrum, an element fixing layer surrounding the LED element, a first pixel driving circuit on the element fixing layer, and an element protecting layer on the first pixel driving circuit. In addition, the first LED element is controlled by the first pixel driving circuit, and the second LED element is controlled by the second pixel driving circuit. Therefore, the LED display device provides a dual emission spectrum, can realized high luminance and high definition, and can prevent a pixel defect.

In an LED display device according to an embodiment of the present disclosure, the LED display device comprises a second pixel driving circuit on a substrate, an LED element attached to a region not overlapping the second pixel driving circuit, including a first LED element, a second LED element and a growth substrate, and providing a double light-emitting spectrum, an element fixing layer surrounding the LED element, a first pixel driving circuit on the element fixing layer, and an element protecting layer on the first pixel driving circuit. In addition, the first LED element is controlled by the first pixel driving circuit, and the second LED element is controlled by the second pixel driving circuit. Therefore, the LED display device provides a dual emission spectrum, can realized high luminance and high definition, and can prevent a pixel defect.

A micro light-emitting display device having multiple display regions is provided. The micro light-emitting display device includes a substrate, multiple micro light-emitting elements, and multiple first light-emitting auxiliary structures. The micro light-emitting elements are disposed on the substrate, and positions of the micro light-emitting elements define ranges of the display regions. The micro light-emitting elements have a same first pitch between each other in any one of the display regions. The micro light-emitting elements have a second pitch between each other at a boundary across any two adjacent display regions. The first pitch is different from the second pitch. The light-emitting auxiliary structures are respectively disposed on the micro light-emitting elements. The light-emitting auxiliary structures have a same third pitch between each other.

A micro light-emitting display device having multiple display regions is provided. The micro light-emitting display device includes a substrate, multiple micro light-emitting elements, and multiple first light-emitting auxiliary structures. The micro light-emitting elements are disposed on the substrate, and positions of the micro light-emitting elements define ranges of the display regions. The micro light-emitting elements have a same first pitch between each other in any one of the display regions. The micro light-emitting elements have a second pitch between each other at a boundary across any two adjacent display regions. The first pitch is different from the second pitch. The light-emitting auxiliary structures are respectively disposed on the micro light-emitting elements. The light-emitting auxiliary structures have a same third pitch between each other.

A LED module includes a support including a heat dissipation pad; a circuit board on the support and including contact pads and an electrical connection terminal electrically connected to the contact pads; an LED device including a wiring board having lower and upper surfaces, a lower wiring on the lower surface and facing the heat dissipation pad, an upper wiring on the upper surface and electrically insulated from the lower wiring, contact structures at one side of the upper wiring, an LED chip mounted on another side of the upper wiring, a wavelength conversion film on the LED chip, and a reflective structure covering the upper surface such that a portion of the contact structures and the wavelength conversion film is exposed; a bonding wire electrically connecting the contact pads and the contact structures; and a conductive bump between the heat dissipation pad and the lower wiring.

A LED module includes a support including a heat dissipation pad; a circuit board on the support and including contact pads and an electrical connection terminal electrically connected to the contact pads; an LED device including a wiring board having lower and upper surfaces, a lower wiring on the lower surface and facing the heat dissipation pad, an upper wiring on the upper surface and electrically insulated from the lower wiring, contact structures at one side of the upper wiring, an LED chip mounted on another side of the upper wiring, a wavelength conversion film on the LED chip, and a reflective structure covering the upper surface such that a portion of the contact structures and the wavelength conversion film is exposed; a bonding wire electrically connecting the contact pads and the contact structures; and a conductive bump between the heat dissipation pad and the lower wiring.

A display device may include including a first insulating reflective layer including a distributed Bragg reflector above a substrate, a first electrode and a second electrode above the first insulating reflective layer, a second insulating reflective layer including a distributed Bragg reflector above the first electrode and the second electrode, and a light emitting element above the second insulating reflective layer.

A display device may include including a first insulating reflective layer including a distributed Bragg reflector above a substrate, a first electrode and a second electrode above the first insulating reflective layer, a second insulating reflective layer including a distributed Bragg reflector above the first electrode and the second electrode, and a light emitting element above the second insulating reflective layer.

The invention is a small-sized vertical light emitting diode chip with high energy efficiency, wherein a PN junction structure is arranged on a light-emitting region platform of an interface structure; a highly reflective metal layer is arranged under the light-emitting region platform; the interface structure is provided with a P-type ohmic contact area under an outwardly extending platform adjacent to the light-emitting region platform; an insulating layer is formed on the outwardly extending platform; an N-type ohmic contact electrode is in ohmic contact with the PN junction structure and covers the border covering region at a position opposite to the outwardly extending platform; the current conduction is achieved diagonally on the opposite sides by locally diagonally symmetric geometric positioning of the N-type ohmic contact electrode and the P-type ohmic contact area.

The invention is a small-sized vertical light emitting diode chip with high energy efficiency, wherein a PN junction structure is arranged on a light-emitting region platform of an interface structure; a highly reflective metal layer is arranged under the light-emitting region platform; the interface structure is provided with a P-type ohmic contact area under an outwardly extending platform adjacent to the light-emitting region platform; an insulating layer is formed on the outwardly extending platform; an N-type ohmic contact electrode is in ohmic contact with the PN junction structure and covers the border covering region at a position opposite to the outwardly extending platform; the current conduction is achieved diagonally on the opposite sides by locally diagonally symmetric geometric positioning of the N-type ohmic contact electrode and the P-type ohmic contact area.