Abstract: A decoder for a wireless charging transmitter and a wireless charging transmitter using the same are provided in the present invention. In order to adapt the wide range of the received signal from the wireless charging receiver, which usually results in the error of the decode, the feedback circuit of the wireless charging transmitter is changed, so that the signal in a certain swing is amplified by an original gain, and the signal out of the certain swing is amplified by a limited gain. Therefore, the amplified signal is able to show the characteristic of the original received signal. Thus, the accuracy of decoding is increased.

Abstract: A dual decoder for a wireless charging receiver and a wireless charging receiver using the same are provided. The wireless charging receiver includes a resonant circuit, a rectifier circuit and a dual decoder for the wireless charging receiver. The rectifier circuit coupled to the resonant circuit converts wireless energy received by the resonant circuit into a direct current. The dual decoder includes a frequency decoding circuit and a voltage amplitude decoding circuit. The frequency decoding circuit performs decoding according to a frequency of a voltage of the resonant circuit to obtain an instruction of a wireless transmitter. The voltage amplitude decoding circuit extracts a carrier on the voltage of the resonant circuit through a filter, and decodes the carrier into the instruction of the wireless transmitter. With the complementary of two-way decoding, the communication system becomes robuster.

Abstract: The present invention provides a photosensitive resin composition comprising (a) a polyamide ester represented by formula (1); (b) a polyimide; (c) a photo radical initiator; (d) a radical polymerizable compound; and (e) a solvent for dissolving the photosensitive polyimide in which A, B, R1, R2, and m have the meaning as defined herein.

Abstract: The present invention provides a photosensitive polyimide resin composition, which comprises (a) a photosensitive polyimide represented by formula (1); (b) a filler selected from one or more of alumina, graphene, inorganic clay, silica, and zinc oxide and having a particle diameter ranging from 10 nm to 1.0 ?m; (c) a photo radical initiator; (d) a radical polymerizable compound; and (e) a solvent for dissolving the photosensitive polyimide; wherein X is derived from a tetracarboxylic dianhydride, Y is derived from a diamine, and m is a positive integer from 1 to 5000.

Abstract: The present invention provides a photosensitive polyimide resin composition, which comprises (a) a photosensitive polyimide represented by formula (1); (b) titanium dioxide having a particle size of 0.2 ?m to 10 ?m; (c) a photo radical initiator; (d) a radical polymerizable compound; and (e) a solvent for dissolving the photosensitive polyimide; wherein X is derived from a tetracarboxylic dianhydride, Y is derived from a diamine, and m is a positive integer from 1 to 5000.

Abstract: A decoder for a wireless charging transmitter and a wireless charging transmitter using the same are provided in the present invention. In order to adapt the wide range of the received signal from the wireless charging receiver, which usually results in the error of the decode, the feedback circuit of the wireless charging transmitter is changed, so that the signal in a certain swing is amplified by an original gain, and the signal out of the certain swing is amplified by a limited gain. Therefore, the amplified signal is able to show the characteristic of the original received signal. Thus, the accuracy of decoding is increased.

Abstract: A dual decoder for a wireless charging receiver and a wireless charging receiver using the same are provided. The wireless charging receiver includes a resonant circuit, a rectifier circuit and a dual decoder for the wireless charging receiver. The rectifier circuit coupled to the resonant circuit converts wireless energy received by the resonant circuit into a direct current. The dual decoder includes a frequency decoding circuit and a voltage amplitude decoding circuit. The frequency decoding circuit performs decoding according to a frequency of a voltage of the resonant circuit to obtain an instruction of a wireless transmitter. The voltage amplitude decoding circuit extracts a carrier on the voltage of the resonant circuit through a filter, and decodes the carrier into the instruction of the wireless transmitter. With the complementary of two-way decoding, the communication system becomes robuster.

Abstract: A method of making a multilayer circuit board includes: forming and exposing a first polyimide photoresist layer; forming holes in the first polyimide photoresist layer; forming a second metal layer on the first polyimide photoresist layer; forming a first photoresist mask layer on the second metal layer; patterning the first photoresist mask layer and the second metal layer; forming a second polyimide photoresist layer on the patterned second metal layer; exposing the second polyimide photoresist layer; forming a hole in the second polyimide photoresist layer; forming a third metal layer on the second polyimide photoresist layer; and forming and patterning a second photoresist mask layer on the third metal layer.

Abstract: A polyimide shield includes a base film layer that is made from polyimide, and a colored film layer that overlies the base film layer and that contains a coloring agent dispersed in a polymer. A method of making the polyimide shield includes forming the base film layer from polyimide and applying a liquid composition onto the base film layer. The liquid composition contains a polymer and the coloring agent that is dispersed in the polymer. An integrated circuit structure includes a circuitry substrate and the polyimide shield that covers the circuitry substrate.

Abstract: A flexible circuit substrate includes a laminate which contains a polymer film, a VIB group metal layer sputtered on the polymer film, a nickel-chromium alloy layer sputtered on the VIB group metal layer, and a copper layer formed on the nickel-chromium alloy layer. The VIB group metal layer is selected from the group consisting of chromium, molybdenum, and tungsten. The VIB group metal layer is free of metal oxide. The VIB group metal layer and the nickel-chromium alloy layer are formed by a sputtering process using an oxygen-free inert atmosphere containing argon.

Abstract: A flexible circuit substrate includes a laminate which contains a polymer film, a VIB group metal layer deposited on the polymer film, a nickel-chromium alloy layer deposited on the VIB group metal layer, a first copper layer deposited on the nickel-chromium alloy layer, and a second copper layer plated on the first copper layer. The VIB group metal layer has a reduced expansion coefficient gradient relative to the polymer film as compared to an expansion coefficient gradient between the polymer film and the nickel-chromium alloy layer. The nickel-chromium alloy layer has a reduced expansion coefficient gradient relative to the first copper layer as compared to an expansion coefficient gradient between the first copper layer and the VIB group metal layer.