Semiconductor devices having multiple substrates and die stacks, and associated systems and methods, are disclosed herein. In some embodiments, a semiconductor device includes a package substrate, and a first die stack mounted on the package substrate and including a plurality of first memory dies. The device can include a substrate mounted on the first die stack, the substrate including a plurality of routing elements. The device can also include a second die stack mounted on the substrate, the second die stack including a plurality of second memory dies. The device can further include a controller die mounted on the substrate. The controller die can be configured to communicate with the second die stack via the routing elements of the substrate. The device can include a mold material encapsulating the first die stack, the second die stack, the substrate, and the controller die.

A ceramic encapsulating casing and a mounting structure thereof are provided. The ceramic encapsulating casing includes a ceramic substrate, a ceramic insulator, a cover plate and a pad structure. The ceramic substrate is provided with a cavity with an upward opening. The ceramic insulator is disposed on the ceramic substrate and provided with a radio frequency transmission structure. The pad structure is arranged on a bottom surface of the ceramic substrate. and includes a plurality of second pads that are arranged for transmitting signals and arranged in an array manner. A plurality of solder balls are attached to the plurality of second pads in one-to-one correspondence.

A semiconductor package includes: an encapsulation layer sealing at least one semiconductor chip; a redistribution level layer arranged on the encapsulation layer; a laser mark metal layer arranged on the redistribution level layer; and a laser mark arranged inside the laser mark metal layer. The laser mark includes letters, numbers, figures, symbols, and recognition codes indicating various pieces of information of the semiconductor package.

Methods of forming microelectronic package structures, and structures formed thereby, are described. Those methods/structures may include attaching a first die on a board, attaching an interposer on a top surface of the first die, and attaching a second die on the top surface of the first die that is adjacent the interposer, wherein the second die is offset from a center region of the first die. A first wire conductive structure may be attached to the second die that extends from the second die to a top surface of the interposer. A second wire conductive structure is attached to the interposer and extends from the interposer to the board.

A method for adjusting an optical system is provided, including a positioning device positioning a first optical module; a measuring device measuring an angular difference between a main axis of the first optical module and an optical axis of an optical element sustained by the first optical module to obtain a measurement information; an adjusting device changing the shape of an adjustment assembly of the first optical module according to the measurement information; and assembling the first optical module with an optical object, wherein the optical axis of the optical element is parallel to a central axis of the optical object.

Semiconductor devices having redistribution structures, and associated systems and methods, are disclosed herein. In some embodiments, a semiconductor assembly comprises a die stack including a plurality of semiconductor dies, and a routing substrate mounted on the die stack. The routing substrate includes an upper surface having a redistribution structure. The semiconductor assembly also includes a plurality of electrical connectors coupling the redistribution structure to at least some of the semiconductor dies. The semiconductor assembly further includes a controller die mounted on the routing substrate. The controller die includes an active surface that faces the upper surface of the routing substrate and is electrically coupled to the redistribution structure, such that the routing substrate and the semiconductor dies are electrically coupled to the controller die via the redistribution structure.

A semiconductor module includes an insulating sheet which has a first surface and extends in a first direction and a first terminal. The first terminal has a first region disposed on the first surface of the insulating sheet and having a first width in a second direction perpendicular to the first direction, a second region extending from the first region and having a second width in the second direction narrower than the first width, and a third region located away from the first surface and being electrically connected to both the first region and the second region.

A semiconductor device includes: a semiconductor base body; a semiconductor chip; a sintering material layer bonded to a lower surface of the semiconductor chip and having a thickness decreasing toward an outer periphery of the semiconductor chip; and a conductive plate having a main surface facing the lower surface of the semiconductor chip and a recessed portion which the sintering material layer contacts in the main surface, the recessed portion having a depth decreasing toward the outer periphery of the semiconductor chip.

A module package in which electronic components are packaged. The package module may comprise a base, at least one component, a housing, and a coaxial lead assembly. The component is over the base. The housing is over the base and encompasses the component. The coaxial lead assembly extends out of the housing and facilitates electrical connections with the component. The at least one coaxial lead assembly comprises a dielectric structure, a central conductor, and an outer conductor formed by a top wall extending between two side walls. The central conductor may be between the two side walls. The dielectric structure may reside between the central conductor and the outer conductor, such that the central conductor and outer conductor are isolated from one another.

A semiconductor device manufacturing method, includes: a preparing process for preparing a conductive plate, a semiconductor chip arranged over the conductive plate with a first bonding material therebetween, and a connection terminal including a bonding portion arranged over the semiconductor chip with a second bonding material therebetween; a first jig arrangement process for arranging a first guide jig, through which a first guide hole pierces, over the conductive plate, such that the first guide hole corresponds to the bonding portion in a plan view of the semiconductor device; and a first pressing process for inserting a pillar-shaped pressing jig, which includes a pressing portion at a lower end portion thereof, into the first guide hole, and pressing the bonding portion of the connection terminal to a side of the conductive plate with the pressing portion.