A method of fabricating an INFO package may include at least the following steps. A first buffer pattern and a second buffer pattern are formed on a substrate. A first chip is attached on the substrate through the first buffer pattern. A second chip is attached on the substrate through the second buffer pattern. A squeezing force is provided between an exterior surface of the substrate and a top surface of the first chip and between an exterior surface of the substrate and a top surface of the second chip. The squeezed first buffer pattern and the squeezed second buffer pattern are cured. A molding compound is formed surrounding the first chip, the second chip, the squeezed first buffer pattern and the squeezed second buffer pattern. A redistribution circuit structure layer is formed electrically connected to the first chip and the second chip on the molding compound.

Panel level packaging (PLP) with high accuracy and high scalability is disclosed. The PLP employs an alignment carrier with a low coefficient of expansion which is configured with die regions having local die alignment marks. For example, local die alignment marks are provided for each die attach region. Depending on the size of the panel, it may be segmented into blocks, each with die regions with local die alignment marks. In addition, a block includes an alignment die region configured for attaching an alignment die. Linear and non-linear positional errors are reduced due to local die alignment marks and alignment dies. The use of local die alignment marks and alignment dies results in increase yields as well as scaling, thereby improving throughput and decreasing overall costs.

According to one embodiment, a controller is configured to calculate a matching rate of grid shapes between each semiconductor wafer of a first semiconductor wafer group and each semiconductor wafer of a second semiconductor wafer group, and generate pairing information, into which combinations of semiconductor wafers used in calculation of matching rates are registered when the matching rates fall within a predetermined range. Further, the controller is configured to select a first semiconductor wafer to be held by a first semiconductor wafer holder from the first semiconductor wafer group, and select a second semiconductor wafer from semiconductor wafers of the second semiconductor wafer group, which are paired with the first semiconductor wafer, with reference to the pairing information.

A method of manufacturing a semiconductor package and a semiconductor package in which positional alignment between a wafer and a substrate until the wafer is mounted and packaged on the substrate is achieved accurately. A wafer is mounted on a package substrate by using first alignment marks and D-cuts as benchmarks, and then a mold resin layer is formed on the wafer in a state in which the first alignment mark is exposed. A part of the mold resin layer is removed by using the D-cuts exposed from the mold resin layer as benchmarks, so that the first alignment marks can be visually recognized. A second alignment marks are formed on the mold resin layer by using the first alignment marks as benchmarks. A Cu redistribution layer to be conducted to a pad portion is formed on a mold resin layer by using the second alignment marks as benchmarks.

This mounting device (100) comprises: a base (10) that moves linearly in relation to a substrate (16); a bonding head (20) that is attached to the base (10); a camera (25) that is attached to the base (10) and identifies the position of the substrate (16); a linear scale (33) having a plurality of graduations along the movement direction; a bonding head-side encoder head (31); and a camera-side encoder head (32). A control unit (50) causes the base (10) to move to a position where the bonding head-side encoder head (31) detects the position of a graduation. Due to this configuration, positioning accuracy of a semiconductor die (15) in relation to the substrate (16) is improved.

Electronic module, which comprises a first substrate, a first dielectric layer on the first substrate, at least one electronic chip, which is mounted with a first main surface directly or indirectly on partial region of the first dielectric layer, a second substrate over a second main surface of the at least one electronic chip, and an electrical contacting for the electric contact of the at least one electronic chip through the first dielectric layer, wherein the first adhesion layer on the first substrate extends over an area, which exceeds the first main surface.

A microscale selective laser sintering (-SLS) that improves the minimum feature-size resolution of metal additively manufactured parts by up to two orders of magnitude, while still maintaining the throughput of traditional additive manufacturing processes. The microscale selective laser sintering includes, in some embodiments, ultra-fast lasers, a micro-mirror based optical system, nanoscale powders, and a precision spreader mechanism. The micro-SLS system is capable of achieving build rates of at least 1 cm.sup.3/hr while achieving a feature-size resolution of approximately 1 m. In some embodiments, the exemplified systems and methods facilitate a direct write, microscale selective laser sintering -SLS system that is configured to write 3D metal structures having features sizes down to approximately 1 m scale on rigid or flexible substrates. The exemplified systems and methods may operate on a variety of material including, for example, polymers, dielectrics, semiconductors, and metals.

A mounting apparatus for stacking and mounting two or more semiconductor chips at a plurality of locations on a substrate includes: a first mounting head for forming, at a plurality of locations on the substrate, temporarily stacked bodies in which two or more semiconductor chips are stacked in a temporarily press-attached state; and a second mounting head for forming chip stacked bodies by sequentially finally press-attaching the temporarily stacked bodies formed at the plurality of locations. The second mounting head includes: a press-attaching tool for heating and pressing an upper surface of a target temporarily stacked body to thereby finally press-attach the two or more semiconductor chips configuring the temporarily stacked body altogether; and one or more heat-dissipation tools having a heat-dissipating body which, by coming into contact with an upper surface of another stacked body positioned around the target temporarily stacked body, dissipates heat from the another stacked body.

A method and an apparatus for bonding semiconductor substrates are provided. The method includes at least the following steps. A first position of a first semiconductor substrate on a first support is gauged by a gauging component embedded in the first support and a first sensor facing towards the gauging component. A second semiconductor substrate is transferred to a position above the first semiconductor substrate by a second support. A second position of the second semiconductor substrate is gauged by a second sensor mounted on the second support and located above the first support. The first semiconductor substrate is positioned based on the second position of the second semiconductor substrate. The second semiconductor substrate is bonded to the first semiconductor substrate.

A method of forming a chip assembly may include forming a plurality of cavities in a carrier; The method may further include arranging a die attach liquid in each of the cavities; arranging a plurality of chips on the die attach liquid, each chip comprising a rear side metallization and a rear side interconnect material disposed over the rear side metallization, wherein the rear side interconnect material faces the carrier; evaporating the die attach liquid; and after the evaporating the die attach liquid, fixing the plurality of chips to the carrier.