A semiconductor device includes: a seal portion; a first electronic element; a second lead terminal having one end that is disposed to be close to the one end of the first lead terminal within the seal portion, and another end that is exposed from another end of the seal portion, the other end of the seal portion being along the longitudinal direction; a first connecting element disposed within the seal portion, and having one end that is electrically connected to the first electrode disposed on the first electronic element, and another end that is electrically connected to the one end of the second lead terminal; and a conductive bonding agent.

In an electronic device including an electronic component, a sealing resin body, a first member having at least a portion located in the sealing resin body, and a second member connected to the first member via a solder in the sealing resin body, the first member includes a base material formed of a metal material and a coated film at least on a surface of the base material which is adjacent to a back surface of the first member opposite to a facing surface of the first member facing the second member. The coated film includes a metal thin film on a surface of the base material and an uneven oxide film on the metal thin film and made of an oxide of a same metal as a main component of the metal thin film.

In a power semiconductor device, an IGBT has a collector electrode bonded to a metal plate by a bonding material. A diode has a cathode electrode bonded to the metal plate by the bonding material. An interconnection member is bonded to an emitter electrode of the IGBT by a bonding material. The bonding material includes a bonding material and a bonding material. The bonding material is interposed between the IGBT and the interconnection member. The bonding material fills a through hole formed in the interconnection member. The bonding material reaches the bonding material and is therefore connected to the bonding material.

An electronic device including a die and at least one lead. The electronic device further includes a corresponding at least one connector, each connector for connecting the die to a corresponding lead or leads, and each connector having a first end disposed in bondable proximity to a complementary surface of the corresponding lead and a second end disposed in bondable proximity to a complementary surface of the die. An end portion of at least one of the first end and second end has a formation, the formation in combination with the complementary surface of one, or both, of the respective lead or the die defining therebetween a first region and at least a second region configured to attract by capillary action an electrically conductive bonding material to consolidate therein.

A process for batch fabrication of circuit component is disclosed via simultaneously packaging multiple circuit component dice in a matrix. Each die has electrodes on its tops and bottom surfaces to be electrically connected to a corresponding electrical terminal of the circuit component it's packaged in. For each circuit component in the matrix, the process forms preparative electrical terminals on a copper substrate. Component dice are pick-and-placed onto the copper substrate with their bottom electrodes landing on corresponding preparative electrical terminal. Horizontal conductor plates are then placed horizontally on top of the circuit component dice, with bottom surface at one end of each plate landing on the dice's top electrode. An opening is formed at the opposite end and has vertical conductive surfaces. A vertical conductor block is placed into the opening and lands on the preparative electrical terminal, and the opening's vertical conductive surfaces facing the top end side surface of the vertical block. A thermal reflow then simultaneously melts pre-applied soldering material so that each circuit component die and its vertical conductor block are soldered to the copper substrate below and its horizontal conductor plate above.

A die package component with a jumper structure includes a first lead frame, a second lead frame, a die, a jumper structure and a package body. The first lead frame has a die connection surface. The second lead frame is separated to the first lead frame. The second lead frame has a lead frame connection groove which defines a thermal deformation tolerance allowable route. The jumper structure is thermally deformed in a thermal-variable environment. The jumper structure includes a die welding portion and a lead welding portion. The die welding portion is welded to the die. Upon meeting a thermal deformation, the lead welding portion would be movable welded along the thermal deformation tolerance allowable route to the lead frame connection groove.

A die package component with a jumper structure includes a first lead frame, a second lead frame, a die, a jumper structure and a package body. The first lead frame has a die connection surface. The second lead frame is separated to the first lead frame. The second lead frame has a lead frame connection groove which defines a thermal deformation tolerance allowable route. The jumper structure is thermally deformed in a thermal-variable environment. The jumper structure includes a die welding portion and a lead welding portion. The die welding portion is welded to the die. Upon meeting a thermal deformation, the lead welding portion would be movable welded along the thermal deformation tolerance allowable route to the lead frame connection groove.

Implementations of a clip may include a die attach portion including at least one protrusion extending from the die attach portion and a lead frame alignment portion including at least one alignment feature. The at least one alignment feature may be configured to couple into at least one hole in a lead frame thereby aligning the clip with the lead frame. The at least one protrusion may be configured to couple into at least one recess in the die.

According to one embodiment, a semiconductor device includes a semiconductor chip, first and second conductive members, a first connection member, and a resin portion. The first conductive member includes first and second portions. The second portion is electrically connected to the semiconductor chip. A direction from the semiconductor chip toward the second portion is aligned with a first direction. A direction from the second portion toward the first portion is aligned with a second direction crossing the first direction. The second conductive member includes a third portion. The first connection member is provided between the first and third portion. The first connection member is conductive. The resin portion includes a first partial region. The first partial region is provided around the first and third portions, and the first connection member. The first portion has a first surface opposing the first connection member and including a recess and a protrusion.

A semiconductor device includes a semiconductor element, leads, and an encapsulation resin covering a portion of each of the leads and the semiconductor element. Each of the leads includes an external connection portion projecting from a side surface of the encapsulation resin. The external connection portion of at least one of the leads has opposite ends in a width-wise direction that extends along the side surface of the encapsulation resin. The external connection portion includes two recesses arranged toward a center in the width-wise direction from the opposite ends. The two recesses extend from a distal surface toward the encapsulation resin. The opposite ends in the width-wise direction define an end connection part. The external connection portion includes a part between the two recesses defining a center connection part.