Foldable Compression Attached Memory Modules (fCAMMs) and associated apparatus, assemblies and systems. The fCAMM comprises a compression contact module having a plurality of contact means arranged in one or more arrays on its underside, first and second fold modules including multiple memory devices, and flexible interconnects coupling the compression contact module to the first and second fold modules. Under one assembled configuration, portions of printed circuit boards (PCBs) for the first and second fold modules are folded over portions of the compression contact module. Under another configuration, the first fold module is disposed above the second fold module, which is disposed above the compression contact module. In an assembly or system including a motherboard, a compression mount technology (CMT) connector or a land grid array (LGA) assembly is disposed between the motherboard and the compression contact module. Bolster plates are used to urge the compression contact module toward the motherboard.

Some memory dies in a stack can be connected externally to the stack and other memory dies in the stack can be connected internally to the stack. The memory dies that are connected externally can act as interface dies for other memory dies that are connected internally thereto. The external connections can be used for transmitting signals indicative of data to and/or from the memory dies while the memory dies in the stack can be connected by a cascading connection for transmission of other signals such as command, address, power, ground, etc.

A semiconductor device has laminated therein three or more chips. The plurality of chips are provided with substrates, transmission coils, and reception coils that are disposed in regions where the transmission coils and the reception coils do not overlap with each other in an in-plane direction of the substrates. The transmission coils are disposed in regions that are in a lamination direction and that are adjacent to and overlap with reception coils of other chips. The reception coils are configured to allow data transmission with respect to the transmission coils that are disposed on the same substrates.

A memory system includes semiconductor memory devices and a control device. Each of the semiconductor memory devices includes a first pad to which a first signal is input, a second pad to which a second signal is input, a third pad to which a third signal is input, a memory cell array, a sense amplifier, and a data register. In a first mode, after the first signal is switched, a command set instructing a data out operation is input via the second pad. In a second mode, after the first signal is switched, the command is input via at least the third pad. The control device executes a first operation assigning different addresses to the respective semiconductor memory devices and a second operation causing the modes of the respective semiconductor memory devices to be switched from the first to the second mode.

A semiconductor device including a memory device which has improved reliability is provided. The semiconductor device comprises at least one data pin configured to transfer a data signal, at least one command address pin configured to transfer a command and an address, at least one serial pin configured to transfer a serial data signal, and processing circuitry connected to the at least one data pin and the at least one serial pin. The processing circuitry is configured to receive the data signal from outside through the at least one data pin, and the processing circuitry is configured to output the serial data signal through the at least one serial pin in response to the received data signal.

Memory devices and associated methods and systems are disclosed herein. A representative memory device includes a substrate and a memory controller electrically coupled to the substrate. The memory controller can include a first in/out (I/O) channel and a second I/O channel. The memory device can further include a plurality of first memories and second memories coupled to the substrate and arranged in a stack in which the first memories are interleaved between the second memories. The memory device can further include (i) a plurality of first wire bonds electrically coupling the first memories to the first I/O channel of the memory controller and (ii) a plurality of second wire bonds electrically coupling the second memories to the second I/O channel.

In an embodiment, a memory system may include at least two types of DRAM, which differ in at least one characteristic. For example, one DRAM type may be a high density DRAM, while another DRAM type may have lower density but may also have lower latency and higher bandwidth than the first DRAM type. DRAM of the first type may be on one or more first integrated circuits and DRAM of the second type may be on one or more second integrated circuits. In an embodiment, the first and second integrated circuits may be coupled together in a stack. The second integrated circuit may include a physical layer circuit to couple to other circuitry (e.g. an integrated circuit having a memory controller, such as a system on a chip (SOC)), and the physical layer circuit may be shared by the DRAM in the first integrated circuits.

The present invention provides a multi-die package including main die, a memory die, a first set of pins and a second set of pins. The main die includes a memory controller, a first set of pads, a second set of pads and a third set of pads. The memory die is coupled to the first set of pads and the second set of pads of the main die. The first set of pins is coupled to the third set of pads of the main die. The second set of pins is coupled to the second set of pads of the main die. The memory controller accesses the memory die through the first set of pads and the second set of pads, and the memory controller accesses a memory chip external to the multi-die package through the second set of pads and the third set of pads.

Semiconductor structure, comprising a memory-array unit comprising: a substrate, a memory array disposed on the substrate, and a first bonding region disposed around the memory array. The memory array comprises multiple word lines, multiple bit lines, and multiple source lines. The first bonding region comprises a first substrate-connecting bonding region, a first bit-line bonding region, a first word-line bonding region, and a first source-line bonding region. The first substrate-connecting bonding region is configured to connect the substrate electrically to a surface of the memory-array unit, the first bit-line bonding region is configured to connect the bit lines electrically to the surface of the memory-array unit, the first word-line bonding region is configured to connect the word lines electrically to the surface of the memory-array unit, and the first source-line bonding region is configured to connect the source lines electrically to the surface of the memory-array unit.

Techniques to couple a high bandwidth memory device on a silicon substrate and a package substrate are disclosed. Examples include selectively activating input/out (I/O) or command and address (CA) contacts on a bottom side of a logic layer for the high bandwidth device based on a mode of operation. The I/O and CA contacts are for accessing one or more memory devices include in the high bandwidth memory device via one or more data channels.