Abstract: Provided are an adhesive film, and a method of fabricating a semiconductor package using the same. The adhesive film includes a thermoplastic resin containing a hydroxyl group, a thermosetting resin, and an anhydride.

Abstract: Provided is a method of fabricating a semiconductor package. The method includes preparing a package substrate having a substrate pad, and mounting a semiconductor chip on the substrate pad. Mounting the semiconductor chip includes forming a resin layer containing a solder and reducing agent granules having a first capsule layer, between a chip pad of the semiconductor chip and the substrate pad, and bonding the chip pad to the substrate pad using laser irradiated to the semiconductor chip.

Abstract: A pattern-forming method for forming a conductive circuit pattern, the pattern-forming method including the steps of: preparing a pattern-forming composition composed of: Cu powder; solder particles for electrically coupling the Cu powder; a polymer resin; a deforming agent that is selected from among acrylate oligomer, polyglycols, glycerides, polypropylene glycol, dimethyl silicon, simethinecone, tributyl phosphare, and polymethylsiloxane, and that increases bonding force between the Cu powder and the solder particles; a curing agent; and a reductant; forming a circuit pattern by printing the pattern-forming composition on a substrate; heating the circuit pattern at a temperature effective to cure the pattern-forming composition and provide the conductive circuit pattern; and electrolytically plating a metal layer onto the conductive circuit pattern. A circuit pattern having superior conductivity is formed at low cost.

Abstract: Provided is a method of fabricating a semiconductor package. The method includes providing a package substrate including a pad, mounting a semiconductor chip with a solder ball on the package substrate to allow the solder ball to be disposed on the pad, filling a space between the package substrate and the semiconductor chip with a underfill resin including a reducing agent comprising a carboxyl group, and irradiating the semiconductor chip with a laser to bond the solder ball to the pad, wherein the bonding of the solder ball to the pad comprises changing a metal oxide layer formed on surfaces of the pad and the solder ball to a metal layer by heat generated by the laser.

Abstract: Provided is a method of fabricating a semiconductor package. The method includes providing a package substrate including a pad, mounting a semiconductor chip with a solder ball on the package substrate to allow the solder ball to be disposed on the pad, filling a space between the package substrate and the semiconductor chip with a underfill resin including a reducing agent comprising a carboxyl group, and irradiating the semiconductor chip with a laser to bond the solder ball to the pad, wherein the bonding of the solder ball to the pad comprises changing a metal oxide layer formed on surfaces of the pad and the solder ball to a metal layer by heat generated by the laser.

Abstract: Provided is a bonding structure of an electronic equipment including first electrodes extended in a first direction and arranged in a second direction on a stretchable display panel having stretchability, second electrodes extended in a first direction and arranged in a second direction on a substrate and facing the first electrodes, and solder bonding parts interposed between the first electrodes and the second electrodes, facing each other in the second direction, and constituting a plurality of rows in the first direction.

Abstract: Provided is a method for manufacturing a semiconductor package, which includes providing a first substrate, providing, over the first substrate, a second substrate including an active region in which a semiconductor element is disposed and a periphery region surrounding the active region, providing an adhesive membrane between the first and second substrates, and mounting the second substrate on the first substrate, wherein the mounting of the second substrate includes aligning the second substrate on the first substrate by using an alignment member protruding from the periphery region of the second substrate.

Abstract: Provided are a transceiver module and a communication apparatus including the same. The transceiver module includes a lower substrate, a thermoelectric device on the lower substrate, and an upper substrate which is disposed on the thermoelectric device and on which high frequency devices cooled by the thermoelectric device are mounted. The upper substrate includes a ceramic printed circuit board (PCB).

Abstract: Disclosed are a method and an apparatus for transmitting and receiving coherent optical OFDM.

Abstract: Provided is a stack module package including: a first substrate where a first device is mounted, and a second substrate where a second device is mounted. The second substrate has a greater thickness than the first substrate, and the second device has a greater thickness than the first device. The first and second devices are vertically connected to each other.

Abstract: The present invention relates to a pattern-forming composition used to form a conductive circuit pattern. The pattern-forming composition comprises Cu powders, a solder for electrically coupling the Cu powders, a polymer resin, a curing agent and a reductant. According to the present invention, a circuit pattern having superior conductivity can be formed at low cost.

Abstract: Provided is a semiconductor device and a method of manufacturing the same. In the method of manufacturing a semiconductor device, a substrate is prepared which is transparent and has a plurality of first electrodes thereon, and a semiconductor chip having a plurality of second electrodes thereon is disposed on the substrate to allow the first and second electrodes to respectively face each other. A polymer layer including solder particles and an oxidizing agent is formed between the substrate and the semiconductor chip, and the solder particles is locally fused between the first and second electrodes by using a laser beam and a fused solder layer is formed which electrically connects between the first and second electrodes.

Abstract: A method of fabricating a solder-on-pad structure is provided. The method may include providing a substrate with a pad, coating a solder bump maker including a first resin and a solder powder on the substrate, heating the solder bump maker to a temperature lower than a melting point of the solder powder to aggregate the solder powder on the pad, and removing the first resin.

Abstract: Provided is a method of measuring signal transmission time difference of a measuring device. The measuring device according to embodiments, by measuring a skew on two optical paths through signal delays of sufficient sizes for skew measurement on the optical paths, even a skew having a minute size can be measured within a measurable range.

Abstract: The present inventive concept discloses an impact-type piezoelectric micro power generator. The impact-type piezoelectric micro power generator may comprise a base having a cavity and at least one stop area adjacent to the cavity; a frame fastened to the base; a vibrating body comprising a plurality of first vibrating beams extended from the frame toward a top of the cavity, an impact beam connected to between first tips of the plurality of first vibrating beams and extended onto the stop area, and a second vibrating beam extended from the impact beam to between the plurality of first vibrating beams, the second vibrating beam having a second tip; and a piezoelectric device disposed on one of a top and a bottom of the second vibrating beam and the impact beam, the piezoelectric device generating electric power according to impacts of the vibrating body to the stop area and bending of the impact beam and the second vibrating beam.

Abstract: Provided are methods of forming a bump and a semiconductor device with the same. The method may include providing a substrate with pads, forming a bump maker layer to cover the pads and include a resin and solder particles, thermally treating the bump maker layer to aggregate the solder particles onto the pads, removing the resin to expose the aggregated solder particles, forming a resin layer to cover the aggregated solder particles, and reflowing the aggregated solder particles to form bumps on the pads.

Abstract: Provided is a bonding structure of an electronic equipment including first electrodes extended in a first direction and arranged in a second direction on a stretchable display panel having stretchability, second electrodes extended in a first direction and arranged in a second direction on a substrate and facing the first electrodes, and solder bonding parts interposed between the first electrodes and the second electrodes, facing each other in the second direction, and constituting a plurality of rows in the first direction.

Abstract: Provided is a method of fabricating a solder particle including adding a first magnetic bar in a first container including a mixture containing first solder particles formed through a mixing process, disposing the first container in a second container including a second magnetic bar, operating the first magnetic bar and the second magnetic bar, and applying heat to the first container to melt the first solder particles.

Abstract: A conductive composition for a front electrode busbar of a silicon solar cell includes a metallic powder, a solder powder, a curable resin, a reducing agent, and a curing agent. A method of manufacturing a front electrode busbar of a silicon solar cell includes applying the composition to the front surface of the silicon solar cell wherein its front electrode finger line is formed. A substrate includes a front electrode busbar of a silicon solar cell, formed with a conductive composition. A silicon solar cell includes one or more electrodes containing a conductive composition including a conductive powder, a curable resin, a reducing agent, and a curing agent. A method of manufacturing the silicon solar cell includes forming a first electrode array with a first conductive composition, forming a second electrode, and forming a third electrode with a third conductive composition.

Abstract: Provided are methods of forming a bump and a semiconductor device with the same. The method may include providing a substrate with pads, forming a bump maker layer to cover the pads and include a resin and solder particles, thermally treating the bump maker layer to aggregate the solder particles onto the pads, removing the resin to expose the aggregated solder particles, forming a resin layer to cover the aggregated solder particles, and reflowing the aggregated solder particles to form bumps on the pads.