The present disclosure relates to a microelectronics package with a self-aligned stacked-die assembly and a process for making the same. The disclosed microelectronics package includes a module substrate, a first die with a first coupling component, a second die with a second coupling component, and a first mold compound. The first die is attached to the module substrate. The first mold compound resides over the module substrate, surrounds the first die, and extends above an upper surface of the first die to define a first opening. Herein, the first mold compound provides vertical walls of the first opening, which are aligned with edges of the first die in X-direction and Y-direction. The second die is stacked with the first die and in the first opening, such that the second coupling component is mirrored to the first coupling component.

A base carries a first chip and a second chip oriented differently with respect to the base and packaged in a package. Each chip integrates an antenna and a magnetic via. A magnetic coupling path connects the chips, forming a magnetic circuit that enables transfer of signals and power between the chips even if the magnetic path is interrupted, and is formed by a first stretch coupled between the first magnetic-coupling element of the first chip and the first magnetic-coupling element of the second chip, and a second stretch coupled between the second magnetic-coupling element of the first chip and the second magnetic-coupling element of the second chip. The first stretch has a parallel portion extending parallel to the faces of the base. The first and second stretches have respective transverse portions extending on the main surfaces of the second chip, transverse to the parallel portion.

The instant disclosure includes a magnetic coupling package structure with duo leadframes for a magnetically coupled isolator and a method for manufacturing the same. The method includes a leadframe providing step, a chip connecting step and a coil alignment step. The leadframe providing step includes providing a first and a second leadframe each including a chip carrying portion, a coil portion, a plurality of pins and floating pins. The chip connecting step includes disposing at least a first chip and at least a second chip onto the corresponding chip carrying portions for electrically connecting the chips to the pins. The coil alignment step includes arranging the first leadframe above or beneath the second leadframe and applying a first and a second magnetic field to the first and the second leadframes respectively for aligning the coil portions, thereby controlling the coupling effect between two coil portions.

According to one embodiment, the interconnect layer includes a fourth conductive member and a fifth conductive member. The fourth conductive member is provided between the first region of the first chip and the third region of the second chip. The fourth conductive member connects the first conductive member of the first chip and the second conductive member of the second chip. The fifth conductive member is provided between the second region of the first chip and the fifth region of the third chip. The fifth conductive member connects the first conductive member of the first chip and the third conductive member of the third chip. The first chip is provided between the first terminal and the second terminal.

A method for use with multiple chips, each respectively having a bonding surface including electrical contacts and a surface on a side opposite the bonding surface involves bringing a hardenable material located on a body into contact with the multiple chips, hardening the hardenable material so as to constrain at least a portion of each of the multiple chips, moving the multiple chips from a first location to a second location, applying a force to the body such that the hardened, hardenable material will uniformly transfer a vertical force, applied to the body, to the chips so as to bring, under pressure, a bonding surface of each individual chip into contact with a bonding surface of an element to which the individual chips will be bonded, at the second location, without causing damage to the individual chips, element, or bonding surface.

A semiconductor package device includes: (1) a substrate having a first surface; (2) a permeable element including a first portion disposed on the first surface of the substrate, a second portion protruding from the first portion, and a third portion disposed on the second portion and contacting the second portion of the permeable element; (3) a first electrical element disposed on the substrate and surrounded by the second portion of the permeable element; and (4) a coil disposed on the substrate and surrounding the second portion of the permeable element.

A microelectronic package is described with a wireless interconnect for chip-to-chip communication. In one example, the package includes an integrated circuit chip, a package substrate to carry the integrated circuit chip, the package substrate having conductive connectors to connect the integrated circuit chip to external components, a radio coupled to the integrated circuit chip to receive data from the integrated circuit chip and modulate the data onto a radio frequency carrier, and an antenna on the package substrate coupled to the radio to send the modulated data over the carrier to an external device.

An electronic system supports superior coupling by implementing a communication mechanism that provides at least for horizontal communication for example, on the basis of wired and/or wireless communication channels, in the system. Hence, by enhancing vertical and horizontal communication capabilities in the electronic system, a reduced overall size may be achieved, while nevertheless reducing complexity in printed circuit boards coupled to the electronic system. In this manner, overall manufacturing costs and reliability of complex electronic systems may be enhanced.

The need for specialized machine learning processors has become a major focal point in the industry as the computation demanded by machine learning workloads grows rapidly. However, the industry has quickly come to a roadblock as the industry realizes, in the context of machine learning, the device memory is more important than complex computation ability. As a result, there has been renewed interest in three dimensional and 2.5D machine learning processors, which are more suited to handle large volume of data. However, conventional multi-layer devices use through silicon vias (TSVs) which have a number of disadvantages and drawbacks. To address these issues, method and devices are disclosed that allow wireless communication between processing layers in a 3D and/or 2.5D integrated dice machine learning processors.

In various aspects, a package system includes at least a first package and a second package arranged on a same side of the package carrier. Each of the first package and the second package comprises an antenna to transmit and/or receive radio frequency signals. A cover may be arranged at a distance over the first package and the second package at the same side of the package carrier as the first package and the second package. The cover comprises at least one conductive element forming a predefined pattern on a side of the cover facing the first package and the second package. The predefined pattern is configured as a frequency selective surface. The package system further includes a radio frequency signal interface wirelessly connecting the antennas of the first package and the second package. The radio frequency signal interface comprises the at least one conductive element.