Abstract: A semiconductor package structure and manufacturing method thereof are provided. Firstly, a first surface mounting unit, a first printed circuit board, and a second printed circuit board are provided. The first surface mounting unit includes a first chip and a first conductive frame, and the first conductive frame has a first carrier board and a first metal member connected to the first carrier board. A first side of the first chip is electrically connected to the first carrier board of the first conductive frame. A second side of the first chip and the first metal member are connected to the first circuit board by a first pad and a second pad respectively. The second circuit board is connected to the first carrier board and hence, the first surface mounting unit is located between the first circuit board and the second circuit board.

Abstract: A semiconductor package structure and manufacturing method thereof are provided. Firstly, a first surface mounting unit, a first printed circuit board, and a second printed circuit board are provided. The first surface mounting unit includes a first chip and a first conductive frame, and the first conductive frame has a first carrier board and a first metal member connected to the first carrier board. A first side of the first chip is electrically connected to the first carrier board of the first conductive frame. A second side of the first chip and the first metal member are connected to the first circuit board by a first pad and a second pad respectively. The second circuit board is connected to the first carrier board and hence, the first surface mounting unit is located between the first circuit board and the second circuit board.

Abstract: A manufacturing method of a chip package structure is provided. Firstly, a conductive frame including a bottom plate and a plurality of partition plates is provided. The bottom plate has a supporting surface and a bottom surface opposite thereto, and the partition plates protrude from the supporting surface to define a plurality of the accommodating regions. Subsequently, a plurality of chips is provided, and each of the chips is correspondingly accommodated in each of the accommodating regions with a back surface facing to the supporting surface. Thereafter, the conductive frame is cut to form a plurality of separated chip package structures.

Abstract: A chip package structure and the manufacturing method thereof are provided. Firstly, a conductive frame including a bottom plate and a plurality of partition plates is provided. The bottom plate has a supporting surface and a bottom surface opposite thereto, and the partition plates protrude from the supporting surface to define a plurality of the accommodating regions. Subsequently, a plurality of chips is provided, and each of the chips is correspondingly accommodated in each of the accommodating regions with a back surface facing to the supporting surface. Thereafter, the conductive frame is cut to form a plurality of separated chip package structures.

Abstract: A brake energy recovery module for an electric vehicle. The electric vehicle includes a motor module and a battery module. The brake energy recovery module includes a first detecting unit, a signal decoder, a power converting unit and a control unit. The first detecting unit is electrically connected to the motor module to detect a first voltage of the motor module. The signal decoder generates a first signal and a second signal according to plural operation signals of the motor module. The power converting unit is electrically connected to the motor module and the battery module. The control unit is electrically connected to the first detecting unit, the signal decoder and the power converting unit. The control unit controls the power converting unit to adjust the first voltage to provide the battery module with a second voltage according to the first voltage, the first signal and the second signal.

Abstract: A manufacturing method of ultra-thin semiconductor device package structure is provided. Firstly, a wafer including a plurality of semiconductor devices is provided, and one of the semiconductor devices has an active surface having an active region and an outer region and a back surface. A first electrode and a second electrode are arranged in the active region, and the outer region has a cutting portion and a channel portion. Subsequently, a trench is formed in the channel portion, and filled with a conductive structure. The wafer is fixed on a supporting board, and then a thinning process and a deposition process of a back electrode layer are performed on the back surface in sequence. Thereafter, the supporting board is removed and a plurality of contacting pads is formed. A cutting process is performed along the cutting portion.

Abstract: A multiple physiological signals sensing chip is provided. The multiple physiological signals sensing chip includes a substrate, a first light-emitting diode, a second light-emitting diode, a sensing array, and a processing unit. The substrate includes a contact surface touched by a finger. The first and second light-emitting diodes respectively emit red light and infrared light to the finger. The sensing array senses the red light or the infrared light reflected or refracted from the finger to obtain first physiological sensing signals according to a first sensing period or senses the red light and the infrared light reflected or refracted from the finger to obtain second physiological sensing signals according to a second sensing period. The first sensing period is shorter than the second sensing period. The processing unit respectively processes the first and second physiological sensing signals to obtain spatial information and energy information corresponding to the finger.

Abstract: A fan-out wafer level chip package structure and the manufacturing method thereof are provided. The method includes the steps of providing a supporting plate having a removable tape formed on the supporting plate, placing a plurality of chips on the removable tape, applying an adhesive layer on a back surface of each of the chips, providing a conductive cover for covering all chips and isolating the chips from each other by a plurality of partitions, injecting a molding compound into an inside of the conductive cover and curing the molding compound for forming an encapsulation, separating the encapsulation from the supporting plate, forming a connection layer on an active surface of each of the chips to establish electrical connections, and performing a cutting process to divide the encapsulation into a plurality of the package structures.

Abstract: A fan-out wafer level chip package structure and the manufacturing method thereof are provided. The method includes the steps of providing a supporting plate having a removable tape formed on the supporting plate, placing a plurality of chips on the removable tape, applying an adhesive layer on a back surface of each of the chips, providing a conductive cover for covering all chips and isolating the chips from each other by a plurality of partitions, injecting a molding compound into an inside of the conductive cover and curing the molding compound for forming an encapsulation, separating the encapsulation from the supporting plate, forming a connection layer on an active surface of each of the chips to establish electrical connections, and performing a cutting process to divide the encapsulation into a plurality of the package structures.

Abstract: A semiconductor package structure and manufacturing method thereof are provided. Firstly, a first surface mounting unit, a first printed circuit board, and a second printed circuit board are provided. The first surface mounting unit includes a first chip and a first conductive frame, and the first conductive frame has a first carrier board and a first metal member connected to the first carrier board. A first side of the first chip is electrically connected to the first carrier board of the first conductive frame. A second side of the first chip and the first metal member are connected to the first circuit board by a first pad and a second pad respectively. The second circuit board is connected to the first carrier board and hence, the first surface mounting unit is located between the first circuit board and the second circuit board.

Abstract: A chip package structure and the manufacturing method thereof are provided. Firstly, a conductive frame including a bottom plate and a plurality of partition plates is provided. The bottom plate has a supporting surface and a bottom surface opposite thereto, and the partition plates protrude from the supporting surface to define a plurality of the accommodating regions. Subsequently, a plurality of chips is provided, and each of the chips is correspondingly accommodated in each of the accommodating regions with a back surface facing to the supporting surface. Thereafter, the conductive frame is cut to form a plurality of separated chip package structures.

Abstract: A manufacturing method of ultra-thin semiconductor device package structure is provided. Firstly, a wafer including a plurality of semiconductor devices is provided, and one of the semiconductor devices has an active surface having an active region and an outer region and a back surface. A first electrode and a second electrode are arranged in the active region, and the outer region has a cutting portion and a channel portion. Subsequently, a trench is formed in the channel portion, and filled with a conductive structure. The wafer is fixed on a supporting board, and then a thinning process and a deposition process of a back electrode layer are performed on the back surface in sequence. Thereafter, the supporting board is removed and a plurality of contacting pads is formed. A cutting process is performed along the cutting portion.

Abstract: A manufacturing method of wafer level chip scale package structure is provided. Firstly, a wafer including a plurality of semiconductor devices is provided. An active surface of one of the semiconductor devices has an active an active region and an outer region. A first electrode and a second electrode are arranged on the active region, and the outer region has a cutting portion and a channel portion. Next, a patterned protecting layer having a plurality of openings is formed on the active surface to respectively expose the first and second electrodes and channel portion. Subsequently, a wafer back thinning process is performed and then a back electrode layer is deposited. Subsequently, the channel portion is etched to form a trench exposing the back electrode layer, and a conductive structure connected to the back electrode layer is formed through the trench. Thereafter, the wafer is cut along the cutting portion.

Abstract: A fan-out wafer level chip package structure and the manufacturing method thereof are provided. The method includes the steps of providing a supporting plate having a removable tape formed on the supporting plate, placing a plurality of chips on the removable tape, applying an adhesive layer on a back surface of each of the chips, providing a conductive cover for covering all chips and isolating the chips from each other by a plurality of partitions, injecting a molding compound into an inside of the conductive cover and curing the molding compound for forming an encapsulation, separating the encapsulation from the supporting plate, forming a connection layer on an active surface of each of the chips to establish electrical connections, and performing a cutting process to divide the encapsulation into a plurality of the package structures.

Abstract: A manufacturing method of wafer level chip scale package structure is provided. Firstly, a wafer including a plurality of semiconductor devices is provided. An active surface of one of the semiconductor devices has an active an active region and an outer region. A first electrode and a second electrode are arranged on the active region, and the outer region has a cutting portion and a channel portion. Next, a patterned protecting layer having a plurality of openings is formed on the active surface to respectively expose the first and second electrodes and channel portion. Subsequently, a wafer back thinning process is performed and then a back electrode layer is deposited. Subsequently, the channel portion is etched to form a trench exposing the back electrode layer, and a conductive structure connected to the back electrode layer is formed through the trench. Thereafter, the wafer is cut along the cutting portion.

Abstract: A package structure and a packaging method of wafer level chip scale package are provided. The packaging method includes: providing a carrier, and disposing a plurality of chips on the carrier; forming a plurality of adhesive layers on a surface of the corresponding chips; covering a conductive cover plate, bonding the conductive cover plate with the chips through the adhesive layers, and dividing out a plurality of packaging spaces by the conductive cover plate for disposing the chips respectively; and providing an insulation material to fill the packaging spaces through via holes on the conductive cover plate to form a first insulation structure; finally, removing the carrier.

Abstract: A package structure and a packaging method of wafer level chip scale package are provided. The packaging method includes: providing a carrier, and disposing a plurality of chips on the carrier; forming a plurality of adhesive layers on a surface of the corresponding chips; covering a conductive cover plate, bonding the conductive cover plate with the chips through the adhesive layers, and dividing out a plurality of packaging spaces by the conductive cover plate for disposing the chips respectively; and providing an insulation material to fill the packaging spaces through via holes on the conductive cover plate to form a first insulation structure; finally, removing the carrier.

Abstract: The present invention is related to an optical recognition system and a method thereof, and more particularly to an optical recognition system and a method that adopts a single-slope analog-to-digital converter to proceed a single-slope analog-to-digital conversion in order to have an image with a wide dynamic range.

Abstract: A pixel array module with a self-test function including a test circuit unit, a plurality of test lines, and a pixel array is provided. The test circuit unit provides the self-test function. The test lines are connected between the test circuit unit and the pixel array. The pixel array is connected to the test circuit unit through the test lines and includes a plurality of pixels. Each pixel includes a transistor. Each transistor has a first terminal and a second terminal. Regarding each of the pixels, a driving signal of the transistor is transmitted from the first terminal to the second terminal thereof under a normal mode, and a test signal of the transistor is transmitted from the second terminal to the first terminal thereof under a test mode. Furthermore, a self-test method of the foregoing pixel array module is also provided.

Abstract: A semiconductor structure comprising a semiconductor unit, a first conductive structure, a first conductive plug, and a second conductive structure is provided. The semiconductor unit has a substrate on a first side of the semiconductor unit. The substrate has at least a hole. The first conductive plug is in the hole and the hole may be full of the conductive plug. The first conductive structure is on the surface of the semiconductor unit. The surface is at the first side of the semiconductor unit. The second conductive structure is on a surface at a second side of the substrate of the semiconductor unit.