Abstract: On an integrated circuit (IC) die, sensors are configured to receive electromagnetic energy and to generate signals in response to the electromagnetic energy. An encapsulation material encapsulates the IC die and the sensors. A filter structure includes a diffusion of particles within the encapsulation material. The filter structure includes: a first region configured to pass a first band of the electromagnetic energy to the sensors or to block the first band of the electromagnetic energy from passing to the sensors; and a second region configured to pass a second band of the electromagnetic energy to the sensors or to block the second band of the electromagnetic energy from passing to the sensors. The encapsulation material has a first intrinsic property, and the particles have a second intrinsic property that is different from the first intrinsic property.

Abstract: An encapsulated integrated circuit that includes an integrated circuit (IC) die and an encapsulation material encapsulating the IC die. A first portion of the encapsulation material is solid and a second portion of the encapsulation material includes spaces filled with a second material.

Abstract: An encapsulated package is provided that includes an integrated circuit (IC) die. An encapsulation material encapsulates the IC die. A set of broadband spectral sensors on the IC die are configured to generate a set of signals in response to electromagnetic energy received by the spectral sensors. A photonic filter structure within the encapsulation material is positioned adjacent the set of spectral sensors. The photonic filter structure is configured to pass a different frequency band of electromagnetic energy to each of the set of spectral sensors.

Abstract: Integrated circuits may be assembled by placing a batch of integrated circuit (IC) die on a leadframe. Each of the IC die includes a magnetically responsive structure that may be an inherent part of the IC die or may be explicitly added. The IC die are then agitated to cause the IC die to move around on the leadframe. The IC die are captured in specific locations on the leadframe by an array of magnetic domains that produce a magnetic response from the plurality of IC die. The magnetic domains may be formed on the lead frame, or may be provided by a magnetic chuck positioned adjacent the leadframe.

Abstract: An encapsulated integrated circuit is provided that includes an integrated circuit (IC) die. An encapsulation material encapsulates the IC die. An electromagnetic interference (EMI) shield is provided by a photonic bandgap (PBG) structure that is included within the encapsulation material. The PBG structure is configured to have a photonic bandgap with a frequency range approximately equal to a range of frequencies that may cause EMI.

Abstract: An encapsulated package is provided that includes a pair integrated circuit (IC) die. A radio frequency (RF) circuit on one of the IC die is operable to transmit an RF signal having a selected frequency. An RF circuit on the other IC die is operable to receive the RF signal Encapsulation material encapsulates the IC die. A photonic waveguide couples between the RF transmitter and RF receiver to form galvanic path isolation between the two IC die. The photonic waveguide is formed by a photonic structure within the encapsulation material.

Abstract: In described examples, a microelectronic device includes a microelectronic die with a die attach surface. The microelectronic device further includes a nanoparticle layer coupled to the die attach surface. The nanoparticle layer may be in direct contact with the die attach surface, or may be coupled to the die attach surface through an intermediate layer, such as an adhesion layer or a contact metal layer. The nanoparticle layer includes nanoparticles having adjacent nanoparticles adhered to each other. The microelectronic die is attached to a package substrate by a die attach material. The die attach material extends into the nanoparticle layer and contacts at least a portion of the nanoparticles.

Abstract: An encapsulated integrated circuit package is provided that includes an integrated circuit (IC) die. A radio frequency (RF) circuit on the IC die is operable to send and/or receive an RF signal having a selected frequency. Encapsulation material encapsulates the IC die. A photonic waveguide couples to the RF circuit and extends to an external surface of the encapsulated IC. The photonic waveguide may be formed by a photonic bandgap structure within the encapsulation material. A socket may be included with the encapsulated package that is coupled to an end of the photonic waveguide opposite the RF circuit.

Abstract: A microelectronic device includes a photonic die having a die input/output (I/O) port. The microelectronic device includes a photonic connection between the first photonic I/O port and the second photonic I/O port. The photonic connection has a dielectric signal pathway for a photonic signal from the first photonic I/O port to the second photonic I/O port. The second photonic I/O port may be a package photonic I/O port at an exterior of the microelectronic device, or may be another die photonic I/O port on another photonic die of the microelectronic device. The photonic connection is formed using at least one additive process, such as by selectively placing material for the photonic connection in a region for the photonic connection.

Abstract: An antenna includes a metal member having a surface that includes a slot. The metal member includes a plurality of legs orthogonal to the surface of the metal member. The plurality of legs are configured to be attached to a circuit board. A first dielectric material is in the slot.

Abstract: An encapsulated package is provided that includes an integrated circuit (IC) die. An encapsulation material encapsulates the IC die. A set of broadband spectral sensors on the IC die are configured to generate a set of signals in response to electromagnetic energy received by the spectral sensors. A photonic filter structure within the encapsulation material is positioned adjacent the set of spectral sensors. The photonic filter structure is configured to pass a different frequency band of electromagnetic energy to each of the set of spectral sensors.

Abstract: An encapsulated package is provided that includes a pair integrated circuit (IC) die. A radio frequency (RF) circuit on one of the IC die is operable to transmit an RF signal having a selected frequency. An RF circuit on the other IC die is operable to receive the RF signal Encapsulation material encapsulates the IC die. A photonic waveguide couples between the RF transmitter and RF receiver to form galvanic path isolation between the two IC die. The photonic waveguide is formed by a photonic structure within the encapsulation material.

Abstract: An encapsulated integrated circuit is provided that includes an integrated circuit (IC) die. An encapsulation material encapsulates the IC die. An electromagnetic interference (EMI) shield is provided by a photonic bandgap (PBG) structure that is included within the encapsulation material. The PBG structure is configured to have a photonic bandgap with a frequency range approximately equal to a range of frequencies that may cause EMI.

Abstract: An encapsulated integrated circuit package is provided that includes an integrated circuit (IC) die. A radio frequency (RF) circuit on the IC die is operable to send and/or receive an RF signal having a selected frequency. Encapsulation material encapsulates the IC die. A photonic waveguide couples to the RF circuit and extends to an external surface of the encapsulated IC. The photonic waveguide may be formed by a photonic bandgap structure within the encapsulation material. A socket may be included with the encapsulated package that is coupled to an end of the photonic waveguide opposite the RF circuit.

Abstract: An encapsulated integrated circuit is provided that includes an integrated circuit (IC) die. An encapsulation material encapsulates the IC die. A phononic bandgap structure is included within the encapsulation material that is configured to have a phononic bandgap with a frequency range approximately equal to a range of frequencies of thermal phonons produced by the IC die when the IC die is operating.

Abstract: An encapsulated integrated circuit is provided that includes an integrated circuit (IC) die. A phonon device is fabricated on the IC die that is configured to emit or to receive phonons that have a range of ultrasonic frequencies. An encapsulation material encapsulates the IC die. A phononic bandgap structure is included within the encapsulation material that is configured to have a phononic bandgap with a frequency range that includes at least a portion of the range of ultrasonic frequencies. A phononic channel is located in the phononic bandgap structure between the phonon device and a surface of the encapsulated IC.

Abstract: Integrated circuits may be assembled by placing a batch of integrated circuit (IC) die on a leadframe. Each of the IC die includes a magnetically responsive structure that may be an inherent part of the IC die or may be explicitly added. The IC die are then agitated to cause the IC die to move around on the leadframe. The IC die are captured in specific locations on the leadframe by an array of magnetic domains that produce a magnetic response from the plurality of IC die. The magnetic domains may be formed on the lead frame, or may be provided by a magnetic chuck positioned adjacent the leadframe.

Abstract: An encapsulated integrated circuit that includes an integrated circuit (IC) die and an encapsulation material encapsulating the IC die. A first portion of the encapsulation material is solid and a second portion of the encapsulation material includes spaces filled with a second material.

Abstract: Methods and apparatus providing a graded package for a semiconductor are disclosed. An example apparatus includes a die; and a graded package encapsulating the die, the graded package including a material that is spatially varied from a first location of the graded package to a second location of the graded package.

Abstract: An apparatus includes a mass detection circuit coupled to a surface covered with a plurality of electrodes. The mass detection circuit is configured to detect a mass of a first droplet present on the surface. The apparatus further includes a transducer circuit coupled to a transducer, which is coupled to the surface and form a lens unit. The transducer circuit configured to excite a first vibration of the surface at a resonant frequency to form a high displacement region on the surface. The apparatus also includes a voltage excitation circuit coupled to the plurality of electrodes. In response to the detection of the mass of the first droplet, the voltage excitation circuit is configured to apply a sequence of differential voltages on one or more consecutive electrodes which moves the first droplet to the high displacement region.