A transmitter component includes an input terminal and a first semiconductor portion with doped regions of a control-side interface circuit. The control-side interface circuit converts a digital input signal received at the input terminal into a transmit radio frequency signal. A control-side metallization structure on at least one of two horizontal main surfaces of the first semiconductor portion includes at least a portion of a control-side antenna structure that emits the transmit radio frequency signal as radio wave. A transceiver circuit may include the transmitter component and a receiver component.

Technology is disclosed herein for a memory system having a dynamic supply voltage to sense amplifiers. In an aspect, the supply voltage has a higher magnitude when charging inhibited bit lines during a program operation and a lower magnitude when verifying/sensing memory cells. Reducing the magnitude of the supply voltage saves power and/or current. However, if the lower magnitude were used when the inhibited bit lines are charged during the program operations, some of the memory cells that should be inhibited from programming might experience at least some programming. Using the higher magnitude supply voltage during bit line charging of the program operation assures that the inhibited bit lines are charged to a sufficient voltage to keep drain side select gates of NAND strings off so that the NAND channel will boost properly to inhibit programming of such memory cells.

Disclosed are semiconductor packages and their fabrication methods. The semiconductor package comprises semiconductor chips stacked on a substrate and including first and second pads on top surfaces thereof, and bonding wires connecting the first and second pads to the substrate. The semiconductor chips alternately protrude in a first direction and its opposite direction. The semiconductor chip has a first lateral surface spaced apart from another semiconductor chip. The top surface of the semiconductor chip is provided thereon with a first arrangement line extending along the first lateral surface and with second arrangement lines extending from opposite ends of the first arrangement line. Wherein as a distance between the first and second arrangement lines increases, a distance between the second arrangement lines and the first lateral surface increases. The first pads are arranged along the first arrangement line. The second pads are arranged along the second arrangement lines.

A die package includes a semiconductor die, a passive component, a molding compound and a redistribution layer (RDL). The semiconductor die includes a first bonding pad. The passive component includes a second bonding pad. The molding compound encloses the semiconductor die and the passive component. The RDL is disposed over the semiconductor die and the passive component and electrically connecting the first bonding pad with the second bonding pad. The semiconductor die is vertically overlapped with the passive component.

The semiconductor module includes: a heat dissipation board including first to third wiring patterns; a first metal plate on the first wiring pattern, a second metal plate on the second wiring pattern, a first semiconductor chip and a first intermediate board which are on the first metal plate, a second semiconductor chip and a second intermediate board which are on the second metal plate. A first metal film on the first intermediate board is electrically connected to the first semiconductor chip and the second metal plate, and a second metal film on the second intermediate board is electrically connected to the second semiconductor chip and the third wiring pattern.

A method for manufacturing a semiconductor package includes: (a) providing a substrate structure, wherein the substrate structure includes a chip attach area, a bottom area opposite to the chip attach area, a lower side rail surrounding the bottom area, a first lower structure and a second lower structure, wherein the first lower structure is disposed in a first lower region of the lower side rail, and a second lower occupancy ratio is greater than a first lower occupancy ratio; (b) attaching at least one semiconductor chip to the chip attach area; and (c) forming an encapsulant to cover the at least one semiconductor chip.

Semiconductor device assemblies having redistribution structures, and associated systems and methods, are disclosed herein. In some embodiments, a semiconductor device assembly includes a substrate, a controller, and an interposer. The substrate has a top surface and a bottom surface. A cavity extends below the top surface. The controller has a first pin-out pattern. The interposer has a top surface with the first pin-out pattern that is directly connected to the controller and a bottom surface that has a second pin-out pattern. The interposer interconnects the first and second pin-out patterns, and the interposer and the second pin-out pattern are configured to be directly attached to a surface of the substrate in the cavity.

A semiconductor package is provided. The semiconductor package includes: a package substrate having a first surface, a second surface that is provided opposite the first surface and has a concave portion, and a through-hole having a side surface that is oblique with respect to the first surface, and a first diameter of a first opening of the through-hole defined through the first surface being less than a second diameter of a second opening of the through-hole defined through a bottom surface of the concave portion; a plurality of first semiconductor chips provided on the first surface; a second semiconductor chip provided on the bottom surface; and a molding portion provided in the through-hole, and covering the plurality of first semiconductor chips and the second semiconductor chip.

Provided is a connection structure for a semiconductor package which includes: a first passivation layer having an opening; a first conductive pattern that penetrates the first passivation layer and protrudes upwardly from the first passivation layer; a second passivation layer on the first passivation layer and covering the first conductive pattern; a second conductive pattern on the second passivation layer and electrically connected to the first conductive pattern; a third passivation layer on the second passivation layer and covering the second conductive pattern; and an external terminal in the opening and electrically connected to the first conductive pattern, wherein the first conductive pattern is thicker than the second conductive pattern.

The present invention discloses embodiments of a semiconductor chip with one or more bottom external (power or ground) connections, a front side power network layer, a device layer, and a grind side power network layer. The device layer has a plurality of devices. One or more of the devices has one or more device power connections and one or more device ground connections and the device layer has a front side and a back grind side. The front side power network layer has power, ground, signal, and other connections that connect to respective device power and device ground connections from/through the top front side layer. In like manner, power, ground, signal, and other connections connect to respective device power and device ground connections from/through the bottom of grind side power network layer. (Alternative, e.g., external conduit connections are disclosed.) Accordingly, one or more first device power connections is connected to one or more of the front side power network layer connections, one or more second device power connections is connected to one or more of grind side power network connections so the front side power network layer and the grind side power network layer provide the device layer with a dual power/ground feed/distribution from both the top/back and bottom/front of the device layer of the chip.