An integrated circuit (IC) includes a lead frame that has a set of leads coupled to a corresponding set of pins. A semiconductor die with contacts is coupled to the set of leads. Encapsulating material encloses the semiconductor die, such that the set of pins extend beyond the encapsulating material. An additive coating covers one or more of the plurality of pins.

A semiconductor package that includes a conductive can, a power semiconductor device electrically and mechanically attached to the inside surface of the can, and an IC semiconductor device copackaged with the power semiconductor device inside the can.

A lead frame device includes a metallic outer frame member, a lead frame package preform, and an encapsulant. The metallic outer frame member includes a pair of spaced apart longitudinal and transverse sections. The lead frame package preform includes at least one die pad surrounded by the metallic outer frame member such that a gap is formed around the die pad within the metallic, and a plurality of spaced apart leads. Each of the spaced apart leads has a first portion connected to the metallic outer frame member, a second portion proximal to and spaced apart from the die pad, a top surface, and a recess indented from the top surface. The encapsulant is filled in the recess. The disclosure also provides a lead frame device assembly.

A semiconductor module includes: a semiconductor element; a first lead frame including a first portion on which the semiconductor element is mounted; a sealing member sealing the semiconductor element and the first portion; and a heat dissipation member which is integrated with the sealing member and dissipates heat generated in the semiconductor element. The heat dissipation member is insulated from the semiconductor element and the first portion by the sealing member. Therefore, the semiconductor module that is applicable to vertical semiconductor elements and ensures electrical insulation between the semiconductor element and the heat dissipation member when implementing the semiconductor module onto a circuit board, can be provided.

An electronic component, in one embodiment, includes a semiconductor die, a die pad supporting the semiconductor die, and a plurality of leads that include a first set of metal lines and a second set of metal lines. The first set of metal lines cross over the second set of metal lines at crossings. The first set of metal lines is separated by a molding compound from the second set of metal line at the crossings. The first set of metal lines is in a same first plane parallel to the semiconductor die. Each of the second set of metal lines include a first portion oriented along the first set of metal lines and disposed in the first plane, and a second portion offset from the first portion. A plurality of electrical connections couple the semiconductor die to the plurality of leads.

A power semiconductor device includes a power semiconductor element, a controlling element, a first lead frame and a second lead frame, respectively, a first metal wire electrically connecting the power semiconductor element and the first lead frame, and a sealing body covering these components. The first lead frame includes a first inner lead having a connecting surface to which one end of the first metal wire is connected. Among surfaces of the sealing body, in a side surface, a resin inlet mark is formed in a side surface portion from which the first lead frame and the second lead frame do not project, the resin inlet mark being greater in surface roughness than another area. The resin inlet mark is formed opposite to a side where the first metal wire is positioned on the connecting surface when seen in the direction along the mounting surface.

A chip package, in some embodiments, comprises: a die flag; one or more die supports; and a die mounted on the die flag and on said one or more die supports, at least one surface of said die having an area larger than an area of at least one surface of the die flag.

Provided is a resin sheet, wherein in a stress measurement in which a dynamic shear strain is applied in a direction parallel to a surface, the difference between a loss tangent as measured when a strain amplitude is 10% of the sheet thickness and a loss tangent as measured when the amplitude is 0.1% is equal to or greater than 1 at a temperature of 80° C. and a frequency of 0.5 Hz. The resin sheet of the present invention can provide a semiconductor device with excellent connection reliability, wherein air bubbles and cracks are less likely to occur in the resin sheet. In the resin composition of the present invention, aggregates are less likely to occur during storage. The resin sheet obtained by forming the resin composition into a sheet has good flatness. The hardened material thereof can provide a circuit board or a semiconductor device with high connection reliability.

A semiconductor device that has at least one semiconductor chip attached to a leadframe made of sheet metal of unencumbered full thickness. The leadframe has leads of a first subset that alternate with leads of a second subset. The leads of the first and second subsets have elongated straight lead portions that are parallel to each other in a planar array. A cover layer of insulating material is located over portions of un-encapsulated lead surfaces. The portions of the leads of the first and second subsets that don't have the cover layer have a metallurgical configuration that creates an affinity for solder wetting.

In one instance, a method of forming a semiconductor package with a leadframe includes cutting, such as with a laser, a first side of a metal strip to a depth D1 according to a cutting pattern to form a first plurality of openings, which may be curvilinear. The method further includes etching the second side of the metal strip to a depth D2 according to a photoresist pattern to form a second plurality of openings. At least some of the first plurality of openings are in fluid communication with at least some of the second plurality of openings to form a plurality of leadframe leads. The depth D1 is shallower than a height H of the metal strip, and the depth D2 is also shallower than the height H. Other embodiments are presented.