A semiconductor device includes a pre-molded leadframe mounting substrate. The substrate includes a die pad (configured to have a semiconductor die mounted thereon) and a first electrically conductive pad and a second electrically conductive pad. A strip of insulating material is molded between the first and second electrically conductive pads to provide a mutually electrically insulation and extends in a longitudinal direction with the first electrically conductive pad and the second electrically conductive pad lying on opposite sides of the strip of insulating material. A semiconductor die is arranged on the die pad in register with the strip of insulating material. A single electrically conductive ribbon extending in register with the strip of insulating material electrically couples the semiconductor die with both the first and second electrically conductive pads to provide a common current flow path from the semiconductor die towards the first and the second electrically conductive pads.

The present disclosure is directed to a high throughput clip bonding tool or system which is flexible and easily adapts to different clip bond pitches or sizes. The clip bonding system may be an integrated system with various modules, including a clip singulation module, a feeder module, a transfer module and a clip attach module within a shared footprint. For example, an incoming clip source may be fed to the clip singulation module for clip singulation before the singulated clips are transferred by the feeder and transfer modules to a clip presentation area for clip alignment before pickup. A pickup tool of the clip attach module is configured to facilitate pickup and attachment of clips onto the semiconductor packages to be clip bonded. For example, the pickup head is programmable to facilitate clip bonding process of different applications which may require clips and packages with different sizes.

Embodiments relate to an integrated circuit package having an integrated circuit die connected to a package substrate through conductors of a flex cable. The flex cable includes an insulating housing made of an insulating material and a plurality of conductors disposed inside the insulating housing. Each conductor of the plurality of conductors is connected to a first contact of a plurality of contacts of the integrated circuit die and a second contact of a plurality of contacts of the package substrate.

The present disclosure is directed to a high throughput clip bonding tool or system which is flexible and easily adapts to different clip bond pitches or sizes. The clip bonding system may be an integrated system with various modules, including a clip singulation module, a feeder module, a transfer module and a clip attach module within a shared footprint. For example, an incoming clip source may be fed to the clip singulation module for clip singulation before the singulated clips are transferred by the feeder and transfer modules to a clip presentation area for clip alignment before pickup. A pickup tool of the clip attach module is configured to facilitate pickup and attachment of clips onto the semiconductor packages to be clip bonded. For example, the pickup head is programmable to facilitate clip bonding process of different applications which may require clips and packages with different sizes.

Embodiments relate to an integrated circuit package having an integrated circuit die connected to a package substrate through conductors of a flex cable. The flex cable includes an insulating housing made of an insulating material and a plurality of conductors disposed inside the insulating housing. Each conductor of the plurality of conductors is connected to a first contact of a plurality of contacts of the integrated circuit die and a second contact of a plurality of contacts of the package substrate.

A semiconductor device includes a pre-molded leadframe mounting substrate. The substrate includes a die pad (configured to have a semiconductor die mounted thereon) and a first electrically conductive pad and a second electrically conductive pad. A strip of insulating material is molded between the first and second electrically conductive pads to provide a mutually electrically insulation and extends in a longitudinal direction with the first electrically conductive pad and the second electrically conductive pad lying on opposite sides of the strip of insulating material. A semiconductor die is arranged on the die pad in register with the strip of insulating material. A single electrically conductive ribbon extending in register with the strip of insulating material electrically couples the semiconductor die with both the first and second electrically conductive pads to provide a common current flow path from the semiconductor die towards the first and the second electrically conductive pads.