A method of forming an electronic device structure includes providing an electronic component having a first major surface, an opposing second major surface, a first edge surface, and an opposing second edge surface. A substrate having a substrate first major surface and an opposing substrate second major surface is provided. The second major surface of the first electronic component is placed proximate to the substrate first major surface and providing a conductive material adjacent the first edge surface of the first electronic component. The conductive material is exposed to an elevated temperature to reflow the conductive material to raise the first electronic component into an upright position such that the second edge surface is spaced further away from the substrate first major surface than the first edge surface. The method is suitable for providing electronic components, such as antenna, sensors, or optical devices in a vertical or on-edge.

A device is provided. The device includes a bridge layer over a first substrate. A first connector electrically connecting the bridge layer to the first substrate. A first die is coupled to the bridge layer and the first substrate, and a second die is coupled to the bridge layer.

A chip structure is provided. The chip structure includes a substrate. The chip structure includes an interconnect layer over the substrate. The chip structure includes a conductive pad over the interconnect layer. The chip structure includes a conductive bump over the conductive pad. The conductive bump has a first portion, a second portion, and a neck portion between the first portion and the second portion. The first portion is between the neck portion and the conductive pad. The neck portion is narrower than the first portion and narrower than the second portion.

A micro LED display panel is provided. The micro LED display panel includes a driving substrate and a plurality of bonding pads disposed on the driving substrate and spaced apart from each other. The micro LED display panel also includes a plurality of micro LED structures electrically connected to the bonding pads. Each micro LED structure includes at least one electrode disposed on the side of the micro LED structure facing the driving substrate. The electrode has a normal contact surface and a side contact surface. The normal contact surface faces the driving substrate, and the side contact surface is laterally connected to the corresponding bonding pad.

In a semiconductor device (SP1) according to an embodiment, a solder resist film (first insulating layer, SR1) which is in contact with the base material layer, and a resin body (second insulating layer, 4) which is in contact with the solder resist film and the semiconductor chip, are laminated in between the base material layer (2CR) of a wiring substrate 2 and a semiconductor chip (3). In addition, a linear expansion coefficient of the solder resist film is equal to or larger than a linear expansion coefficient of the base material layer, and the linear expansion coefficient of the solder resist film is equal to or smaller than a linear expansion coefficient of the resin body. Also, the linear expansion coefficient of the base material layer is smaller than the linear expansion coefficient of the resin body. According to the above-described configuration, damage of the semiconductor device caused by a temperature cyclic load can be suppressed, and thereby reliability can be improved.

Semiconductor packages may include a first semiconductor chip including a first through-electrode and a first upper connection pad and on an upper surface of the first semiconductor chip, a second semiconductor chip on the first semiconductor chip and including a second lower connection pad on a lower surface of the second semiconductor chip, a connection bump between the first and second semiconductor chips and connected to the first upper connection pad and the second lower connection pad, a first insulating layer between the first and second semiconductor chips and surrounding the first upper connection pad, the connection bump, and the second lower connection pad, and a second insulating layer between the first semiconductor chip and the first insulating layer and extending on the upper surface of the first semiconductor chip, a side surface of the first upper connection pad, and a portion of a side surface of the connection bump.

A semiconductor package includes first and second package components stacked upon and electrically connected to each other, and first and second joint structures. The first package component includes first and second conductive bumps, the second package component includes third and fourth conductive bumps having dimensions greater than those of the first and second conductive bumps. The first joint structure partially covers the first and third conductive bumps. The second joint structure partially covers the second and the fourth conductive bumps. A first angle between a sidewall of the first conductive bump and a tangent line at an end point of a boundary of the first joint structure on the first conductive bump is greater than a second angle between a sidewall of the second conductive bump and a tangent line at an end point of a boundary of the second joint structure on the second conductive bump.

A semiconductor device package includes a first electronic component, a plurality of first conductive traces, a second electronic component, a plurality of second conductive traces and a plurality of first conductive structures. The first electronic component has a first active surface. The first conductive traces are disposed on and electrically connected to the first active surface. The second electronic component is stacked on the first electronic component. The second electronic component has an inactive surface facing the first active surface, a second active surface opposite the inactive surface, and at least one lateral surface connecting the second active surface and the inactive surface. The second conductive traces are electrically connected to the second active surface, and extending from the second active surface to the lateral surface. The first conductive structures are electrically connecting the second conductive traces to the first conductive traces, respectively.

The present invention generally relates to a radiation detector element wherein a photodiode is transversely fixed to a detector element substrate through at least one connection comprising two fused solder balls, wherein a first of the two fused solder balls contacts the photodiode and a second of the two fused solder balls (contacts the detector element substrate. The invention further relates to a method of transversally attaching two substrates, in particular constructing the above-mentioned radiation detector element. It also relates to an imaging system comprising at least one radiation detector element.

A printed circuit board (PCB) includes: a base substrate including a top surface including an electronic device mounting region; chip connection pads that are provided on the electronic device mounting region; a conductive pattern group that is provided on the top surface of the base substrate and includes an extended conductive pattern extending between two adjacent chip connection pads from among the chip connection pads, the extended conductive pattern being spaced apart from each of the two adjacent chip connection pads; and a solder resist layer that covers a part of the extended conductive pattern and is spaced apart from the chip connection pads.