Hyperchip structures and methods of fabricating hyperchips are described. In an example, an integrated circuit assembly includes a first integrated circuit chip having a device side opposite a backside. The device side includes a plurality of transistor devices and a plurality of device side contact points. The backside includes a plurality of backside contacts. A second integrated circuit chip includes a device side having a plurality of device contact points thereon. The second integrated circuit chip is on the first integrated circuit chip in a device side to device side configuration. Ones of the plurality of device contact points of the second integrated circuit chip are coupled to ones of the plurality of device contact points of the first integrated circuit chip. The second integrated circuit chip is smaller than the first integrated circuit chip from a plan view perspective.

A chip package structure is provided. The chip package structure includes a substrate. The chip package structure includes a chip over the substrate. The chip package structure includes a bump and a first dummy bump between the chip and the substrate. The bump is electrically connected between the chip and the substrate, the first dummy bump is electrically insulated from the substrate, and the first dummy bump is wider than the bump. The chip package structure includes a first dummy solder layer under the first dummy bump and having a curved bottom surface facing and spaced apart from the substrate.

A semiconductor structure is provided. The semiconductor structure includes a semiconductor substrate and a first conductive bump. The semiconductor substrate has an integrated circuit and an interconnection metal layer, and a tilt surface is formed on an edge of the semiconductor substrate. The first conductive bump is electrically connected to the integrated circuit via the interconnection metal layer, and is disposed on the tilt surface, wherein a profile of the first conductive bump extends beyond a side surface of the edge of the semiconductor layer.

A semiconductor device structure is provided. The semiconductor device structure includes a substrate, an electrical connection structure extending upwardly from an upper surface of the substrate by a first height, and a contact pad electrically disposed on the upper surface of the substrate. The contact pad has a solder-wettable surface with an area configured to support a solder ball having a second height at least twice the first height. The semiconductor device structure further includes a fuse element with a first end electrically coupled to the electrical connection structure and a second end electrically coupled to the contact pad.

A semiconductor package includes a substrate, through-electrodes penetrating the substrate, first bumps spaced apart from each other in a first direction parallel to a top surface of the substrate and electrically connected to the through-electrodes, respectively, and at least one second bump disposed between the first bumps and electrically insulated from the through-electrodes. The first bumps and the at least one second bump constitute one row in the first direction. A level of a bottom surface of the at least one second bump from the top surface of the substrate is a substantially same as levels of bottom surfaces of the first bumps from the top surface of the substrate.

Systems, methods, and devices for a ball grid array with non-linear conductive routing are described herein. Such a ball grid array may include a plurality of solder balls that are electrically coupled by a non-linear conductive routing. The non-linear conductive routing may include a plurality of routing sections where each of the plurality of routing sections is disposed at an angle to adjacent routing sections.

Provided is a semiconductor device which can be prevented from increasing in size. The semiconductor device includes a semiconductor chip having a first main surface and a second main surface opposite to the first main surface and a wiring substrate over which the semiconductor chip is mounted such that the second main surface of the semiconductor chip faces a first main surface of the wiring substrate. Over the second main surface of the semiconductor chip, a plurality of first terminals connected with a first circuit and a plurality of second terminals connected with a second circuit are arranged. An arrangement pattern of the plurality of first terminals and an arrangement pattern of the plurality of second terminals include the same arrangement pattern. In a region of the wiring substrate where the first circuit is close to the second circuit when viewed from the first main surface of the semiconductor chip, a voltage line which supplies a power supply voltage to the first circuit is formed. In a region of the wiring substrate where the second circuit is close to the first circuit, a voltage line which supplies the power supply voltage to the second circuit is formed.

According to an aspect, a display device includes: a substrate including a display region and a non-display region surrounding the display region; at least one driver IC including connecting terminals with a first surface fixed to face the non-display region; first wires supplying a signal to the display region; first bumps connected with the first wires; second wires transferring a signal to and from outside; second bumps connected with the second wires; and inspection wires. The connecting terminals of the driver IC include first connecting terminals overlapping the first or second bumps in plan view, and second connecting terminals not overlapping the first or second bumps in plan view. The inspection wires include a connecting conductor between themselves and at least one of the second connecting terminals. The inspection wires are pulled out to an outside of the driver IC in plan view.

A semiconductor structure is provided. The semiconductor structure includes a semiconductor substrate and a first conductive bump. The semiconductor substrate has an integrated circuit and an interconnection metal layer, and a tilt surface is formed on an edge of the semiconductor substrate. The first conductive bump is electrically connected to the integrated circuit via the interconnection metal layer, and is disposed on the tilt surface, wherein a profile of the first conductive bump extends beyond a side surface of the edge of the semiconductor layer.

An integrated fan-out package and a layout method thereof are provided. One integrated fan-out package includes a die and a fan-out substrate. The die has an interconnect structure therein. The fan-out substrate has a redistribution layer structure therein and a plurality of first conductive bumps on a first surface thereof. The first conductive bumps are in physical contact with an interconnect layer of the interconnect structure and a redistribution layer of the redistribution layer structure, and an aspect ratio of the first conductive bumps ranges from about 1/3 to 1/10.