Abstract: An electrical device and an operation control method are provided. The electronic device includes a touch module and a processor. The touch module includes a touchable region. The touchable region is divided into at least a first touchable region and a second touchable region. The first touchable region is configured to implement a first function. The second touchable region is configured to implement the first function and a second function. The processor is electrically connected to the touch module. When at least one first touch point is detected in the first touchable region, at least one second touch point is detected in the second touchable region, and the processor determines that a distance between the first touch point and the second touch point is within a predetermined distance, the second touchable region is switched to implementing the first function.

Abstract: A MEMS microphone package includes a substrate including a sound hole, a first conduction part and a second conduction part, a sidewall connected with one end thereof to the substrate and having a conducting line electrically connected to the second conduction part, a cover plate connected to an opposite end of the sidewall and defining a chamber therein and having a solder pad and a fifth contact in conduction with the solder pad and electrically connected to the conducting line, a processor chip mounted on the substrate inside the chamber and electrically connected to the first conduction part and the second conduction part, and a acoustic wave sensor mounted on the substrate inside the chamber to face toward the sound hole and electrically connected to the first conduction part using flip-chip technology.

Abstract: A MEMS microphone package includes a substrate including a base layer, a sound hole cut through the base layer, a conduction part arranged on the base layer, a sidewall connected with one end thereof to the top surface of the base layer and having a conducting line electrically connected to the conduction part, a cover plate connected to an opposite end of the sidewall and having a solder pad and a third contact disposed in conduction with the solder pad and electrically connected to the conducting line, an acoustic wave sensor mounted on the top surface of the base layer to face toward the sound hole, a processor chip mounted on the top surface of the base layer and electrically connected to the acoustic wave sensor and the conduction part, and one or multiple electronic components electrically bonded to the cover plate.

Abstract: A MEMS microphone package includes a substrate including a base layer, a sound hole cut through opposing top and bottom surfaces of the base layer, a conduction part arranged on the base layer and a notch located on the top surface of the base layer, a sidewall connected with one end thereof to the top surface of the base layer and having a conducting line electrically connected to the conduction part, a cover plate connected to an opposite end of the sidewall and having a solder pad and a third contact disposed in conduction with the solder pad and electrically connected to the conducting line, a processor chip mounted in the notch and electrically connected to the conduction part, and an acoustic wave sensor mounted on the base layer to face toward the sound hole and electrically connected to the processor chip.

Abstract: A microphone package structure includes a substrate, sound wave transducer, processing chip, lid, sound aperture, at least one first solder pad and at least one second solder pad. The substrate has a top side, a bottom side and two opposing lateral sides. The top and bottom sides each connect the lateral sides. The sound wave transducer and processing chip are disposed on the top side. The lid covers the substrate to form a chamber for containing the sound wave transducer and the processing chip electrically connected to the substrate and sound wave transducer. The sound aperture is disposed at the substrate or lid. The at least one first solder pad is disposed on the bottom side and in electrical conduction with the processing chip. The at least one second solder pad is disposed on one of the lateral sides and in electrical conduction with the processing chip.

Abstract: A MEMS microphone package includes a substrate including a base layer, a sound hole cut through the base layer, a conduction part arranged on the base layer, a sidewall connected with one end thereof to the top surface of the base layer and having a conducting line electrically connected to the conduction part, a cover plate connected to an opposite end of the sidewall and having a solder pad and a third contact disposed in conduction with the solder pad and electrically connected to the conducting line, an acoustic wave sensor mounted on the top surface of the base layer to face toward the sound hole, a processor chip mounted on the top surface of the base layer and electrically connected to the acoustic wave sensor and the conduction part, and one or multiple electronic components electrically bonded to the cover plate.

Abstract: A microphone package structure includes a substrate, sound wave transducer, processing chip, lid, sound aperture, at least one first solder pad and at least one second solder pad. The substrate has a top side, a bottom side and two opposing lateral sides. The top and bottom sides each connect the lateral sides. The sound wave transducer and processing chip are disposed on the top side. The lid covers the substrate to form a chamber for containing the sound wave transducer and the processing chip electrically connected to the substrate and sound wave transducer. The sound aperture is disposed at the substrate or lid. The at least one first solder pad is disposed on the bottom side and in electrical conduction with the processing chip. The at least one second solder pad is disposed on one of the lateral sides and in electrical conduction with the processing chip.

Abstract: A MEMS microphone package includes a substrate including a sound hole, a first conduction part and a second conduction part, a sidewall connected with one end thereof to the substrate and having a conducting line electrically connected to the second conduction part, a cover plate connected to an opposite end of the sidewall and defining a chamber therein and having a solder pad and a fifth contact in conduction with the solder pad and electrically connected to the conducting line, a processor chip mounted on the substrate inside the chamber and electrically connected to the first conduction part and the second conduction part, and a acoustic wave sensor mounted on the substrate inside the chamber to face toward the sound hole and electrically connected to the first conduction part using flip-chip technology.

Abstract: A microelectromechanical microphone package structure includes a substrate, sidewall, lid, sound wave transducer and processing module. The substrate has a plate, sound aperture penetrating the plate, and conduction portion disposed on the plate. The sidewall has one end disposed on the plate and has a conduction circuit electrically connected to the conduction portion. A chamber is defined between the lid, sidewall and plate. The lid has at least one solder pad and a third contact in electrical conduction with each other. The third contact is electrically connected to the conduction circuit. The sound wave transducer is disposed on the plate and in the chamber and aligned with the sound aperture. The processing module, which is disposed on the plate and in the chamber and electrically connected to the sound wave transducer and conduction portion, includes a processing chip and electronic component which are stacked and disposed on the plate.

Abstract: A MEMS microphone package includes a substrate including a base layer, a sound hole cut through opposing top and bottom surfaces of the base layer, a conduction part arranged on the base layer and a notch located on the top surface of the base layer, a sidewall connected with one end thereof to the top surface of the base layer and having a conducting line electrically connected to the conduction part, a cover plate connected to an opposite end of the sidewall and having a solder pad and a third contact disposed in conduction with the solder pad and electrically connected to the conducting line, a processor chip mounted in the notch and electrically connected to the conduction part, and an acoustic wave sensor mounted on the base layer to face toward the sound hole and electrically connected to the processor chip.

Abstract: A an optical module integrated package includes a substrate, a light-receiving chip mounted in a light-receiving region of the substrate, an electronic component mounted in the substrate, a cover mounted on the substrate and having a light-receiving chip disposed above the light-receiving hole, and a lens fixedly mounted in the light-receiving hole of the cover. Thus, the optical module integrated package not only have the chip and the electronic component integrated therein to reduce the packaging cost and to improve the yield but also provide a light filtering, focusing or diffusing effect to enhance optical recognition accuracy.

Abstract: A package structure of an optical module includes: a substrate having a frame defined with a light-emitting region and a light-admitting region; a light-emitting chip disposed at the light-emitting region of the substrate; a light-admitting chip disposed at the light-admitting region of the substrate; two encapsulants formed in the frame and enclosing the light-emitting chip and the light-admitting chip, respectively; and a shielding layer formed on the frame and the encapsulants and having a light-emitting hole and a light-admitting hole, wherein the light-emitting hole and the light-admitting hole are positioned above the light-emitting chip and the light-admitting chip, respectively. The optical module package structure uses an opaque glue to reduce costs and total thickness of the package structure.

Abstract: A an optical module integrated package includes a substrate, a light-receiving chip mounted in a light-receiving region of the substrate, an electronic component mounted in the substrate, a cover mounted on the substrate and having a light-receiving chip disposed above the light-receiving hole, and a lens fixedly mounted in the light-receiving hole of the cover. Thus, the optical module integrated package not only have the chip and the electronic component integrated therein to reduce the packaging cost and to improve the yield but also provide a light filtering, focusing or diffusing effect to enhance optical recognition accuracy.

Abstract: A an optical module integrated package includes a substrate, a light-receiving chip mounted in a light-receiving region of the substrate, an electronic component mounted in the substrate, a cover mounted on the substrate and having a light-receiving chip disposed above the light-receiving hole, and a lens fixedly mounted in the light-receiving hole of the cover. Thus, the optical module integrated package not only have the chip and the electronic component integrated therein to reduce the packaging cost and to improve the yield but also provide a light filtering, focusing or diffusing effect to enhance optical recognition accuracy.

Abstract: A micro optical package structure with filtration layers includes a substrate having a light-emitting area and a light-receiving area, a light-emitting chip being deposited in a light-emitting area, a light-receiving chip being deposited in a light-receiving area, two packaging resin bodies for enclosing the light-emitting chip and the light-receiving chip, respectively, and being separately deposited in the light-emitting area and the light-receiving area, respectively, and the filtration layers formed on the packaging resin bodies surface for filtering out lights of different wavelengths. The micro optical package structure needs neither barrier nor protective cover between or outside the packaging resin bodies, so can be microminiaturized. The micro optical package structure can filter out visible lights of specific wavelengths without using any additional filters.

Abstract: A package structure of an optical module includes: a substrate defined with a light-emitting region and a light-admitting region; a light-emitting chip disposed at the light-emitting region of the substrate; a light-admitting chip disposed at the light-admitting region of the substrate; two encapsulants for enclosing the light-emitting chip and the light-admitting chip, respectively; and a shielding layer formed on the substrate and the encapsulants and having a light-emitting hole and a light-admitting hole, wherein the light-emitting hole and the light-admitting hole are positioned above the light-emitting chip and the light-admitting chip, respectively. Accordingly, the optical module package structure simplifies a packaging process and cuts manufacturing costs.

Abstract: A an optical module integrated package includes a substrate, a light-receiving chip mounted in a light-receiving region of the substrate, an electronic component mounted in the substrate, a cover mounted on the substrate and having a light-receiving chip disposed above the light-receiving hole, and a lens fixedly mounted in the light-receiving hole of the cover. Thus, the optical module integrated package not only have the chip and the electronic component integrated therein to reduce the packaging cost and to improve the yield but also provide a light filtering, focusing or diffusing effect to enhance optical recognition accuracy.

Abstract: A micro optical package structure with filtration layers includes a substrate having a light-emitting area and a light-receiving area, a light-emitting chip being deposited in a light-emitting area, a light-receiving chip being deposited in a light-receiving area, two packaging resin bodies for enclosing the light-emitting chip and the light-receiving chip, respectively, and being separately deposited in the light-emitting area and the light-receiving area, respectively, and the filtration layers formed on the packaging resin bodies surface for filtering out lights of different wavelengths. The micro optical package structure needs neither barrier nor protective cover between or outside the packaging resin bodies, so can be microminiaturized. The micro optical package structure can filter out visible lights of specific wavelengths without using any additional filters.

Abstract: A package structure of an optical module is provided and includes: a light-emitting chip and a light-admitting chip which are disposed at a light-emitting region and a light-admitting region of a substrate, respectively; two encapsulants for enclosing the light-emitting chip and the light-admitting chip, respectively, and forming hemispherical first and second lens portions above the light-emitting chip and the light-admitting chip, respectively; a cover disposed on the substrate and the encapsulants and having a light-emitting hole and a light-admitting hole, wherein the light-emitting hole and the light-admitting hole are positioned above the light-emitting chip and the light-admitting chip, respectively, and the first and second lens portions are received in the light-emitting hole and the light-admitting hole, respectively.

Abstract: A package structure of an optical module includes: a substrate defined with a light-emitting region and a light-admitting region; a light-emitting chip disposed at the light-emitting region of the substrate; a light-admitting chip disposed at the light-admitting region of the substrate; two encapsulants for enclosing the light-emitting chip and the light-admitting chip, respectively; and a shielding layer formed on the substrate and the encapsulants and having a light-emitting hole and a light-admitting hole, wherein the light-emitting hole and the light-admitting hole are positioned above the light-emitting chip and the light-admitting chip, respectively. Accordingly, the optical module package structure simplifies a packaging process and cuts manufacturing costs.