An isolation system and isolation device are disclosed. An illustrative isolation device is disclosed to include a transmitter circuit to generate a first current in accordance with a first signal, a first elongated conducting element to generate a magnetic field when the first current flows through the first elongated conducting element, a second elongated conducting element adjacent to the first elongated conducting element so as to receive the magnetic field. The second elongated conducting element is configured to generate an induced current when the magnetic field is received. The receiver circuit is configured to receive the induced current as an input, and configured to generate a reproduced first signal as an output of the receiver circuit.

A semiconductor package includes a substrate having a top planar surface and a semiconductor die mounted on the top planar surface of the substrate. Bond wires electrically connect the semiconductor die to the substrate. Flow control dams are integrally formed with the top planar surface of the substrate and each flow control dam protrudes from the top planar surface of the substrate at a location proximate to the bond wires. The flow control dams reduce the occurrence of wire sweep in the bond wires electrically connected to the substrate and semiconductor die.

An isolation system and isolation device are disclosed. An illustrative isolation device is disclosed to include a transmitter circuit, a detector circuit, a first wire bond, and a second wire bond. The detector circuit is configured to generate a first current in accordance with a first signal. The first wire bond is configured to receive the first current from the transmitter circuit to generate a magnetic flux. The second wire bond is configured to receive the magnetic flux. An induced current in the second wire bond is then detected in the detector circuit. The detector circuit is configured to generate a reproduced first signal, as an output of the detector circuit.

Shielding for flip chip devices. In some embodiments, a shielded assembly can include a substrate and a flip chip die having a front side and a back side, with the including an integrated circuit implemented on the front side, and the front side of the flip chip die being mounted to the substrate. The shielded assembly can further include a shielding component implemented over the back side of the flip chip die to provide electromagnetic shielding between a first region within or on the flip chip die and a second region away from the flip chip die.

Shielding for flip chip devices. In some embodiments, a shielded assembly can include a substrate and a flip chip die having a front side and a back side, with the including an integrated circuit implemented on the front side, and the front side of the flip chip die being mounted to the substrate. The shielded assembly can further include a shielding component implemented over the back side of the flip chip die to provide electromagnetic shielding between a first region within or on the flip chip die and a second region away from the flip chip die.

A wire bonding apparatus connecting a lead of a mounted member with an electrode of a semiconductor die through a wire comprises a capillary through which the wire is inserted, a shape acquisition part which acquires the shape of the lead to which the wire is connected, a calculating part which calculates an extending direction of a wire tail extending from the end of the capillary based on the shape of a lead to which the wire is connected next, and a cutting part which moves the capillary in the extending direction and cuts the wire to form the wire tail after the lead is connected with the electrode through the wire. Thus, in the wire bonding using wedge bonding, joining part tails (183a, 283a, 383a) formed in continuation to a first bonding point can be prevented from coming into contact with each other.

A method of determining a sequence for creating a plurality of wire loops is provided. The method includes (a) providing workpiece data for a workpiece. The workpiece data includes (i) position data for bonding locations of the workpiece, and (ii) wire loop data for a plurality of wire loops providing interconnection between ones of the bonding locations. The method also includes (b) analyzing the workpiece data. The step of analyzing includes considering overlap conditions between ones of the plurality of wire loops, considering wire loop heights of ones of the plurality of wire loops, considering lateral bend conditions between ones of the plurality of wire loops, and considering wire loop positions for ones of the plurality of wire loops. The method also includes (c) providing a sequence of creating the plurality of wire loops in connection with the workpiece at least partially based on the results of step (b).

An isolation system and isolation device are disclosed. An illustrative isolation device is disclosed to include a transmitter circuit, a detector circuit, a first wire bond, and a second wire bond. The detector circuit is configured to generate a first current in accordance with a first signal. The first wire bond is configured to receive the first current from the transmitter circuit to generate a magnetic flux. The second wire bond is configured to receive the magnetic flux. An induced current in the second wire bond is then detected in the detector circuit. The detector circuit is configured to generate a reproduced first signal, as an output of the detector circuit.

In some embodiments, a radio-frequency device can be manufactured by a method that includes forming or providing a substrate, fabricating or providing a flip chip die having a front side and a back side, and including an integrated circuit implemented on the front side, and mounting the front side of the flip chip die on the substrate. The method can further include implementing a shielding component over the back side of the flip chip die to provide electromagnetic shielding between a first region within or on the flip chip die and a second region away from the flip chip die.

In some embodiments, a radio-frequency device can be manufactured by a method that includes forming or providing a substrate, fabricating or providing a flip chip die having a front side and a back side, and including an integrated circuit implemented on the front side, and mounting the front side of the flip chip die on the substrate. The method can further include implementing a shielding component over the back side of the flip chip die to provide electromagnetic shielding between a first region within or on the flip chip die and a second region away from the flip chip die.