Abstract: A semiconductor package includes: a memory sub-package including a first connecting layer and a plurality of memory chips disposed on the first connecting layer; a logic sub-package including a second connecting layer, a controller chip disposed on the second connecting layer, and a buffer chip connected to the controller chip and the plurality of memory chips; and a plurality of inter-package connecting members each of which connects the memory sub-package and the logic sub-package, wherein the buffer chip is connected to the plurality of memory chips via a plurality of first data transfer lines each having a first data transfer rate, the buffer chip is connected to the controller chip via a plurality of second data transfer lines each having a second data transfer rate, and the first data transfer rate is less than the second data transfer rate.

Abstract: A memory device includes a memory cell array formed in a semiconductor die, the memory cell array including a plurality of memory cells to store data and a calculation circuit formed in the semiconductor die. The calculation circuit performs calculations based on broadcast data and internal data and omits the calculations with respect to invalid data and performs the calculations with respect to valid data based on index data in a skip calculation mode, where the broadcast data are provided from outside the semiconductor die, the internal data are read from the memory cell array, and the index data indicates whether the internal data are the valid data or the invalid data. Power consumption is reduced by omitting the calculations and the read operation with respect to the invalid data through the skip calculation mode based on the index data.

Abstract: A method and a memory device therefor for reconfiguring a DQ pad organization of the memory device on-the-fly. A DQ organization reconfiguration control unit generates a control signal for reconfiguring the DQ pad organization into a desired mode based on a user command. A DQ organization reconfiguration unit is provided between P DQ pads and memory cell arrays and reconfigures organization P DQ pads on-the-fly in any one among Xi DQ pad modes, where i=1, 2, 4, 8, 16, 32, 64, and 128, based on the control signal. For the reconfiguration of the organization of the DQ pads, a plurality of bus lines for data transfer, being switchable by a control signal, are provided. The bus lines are implemented utilizing at least one of the M3 and M4 metal layers of the memory device.

Abstract: A magnetic random access memory (MRAM), and a memory module, memory system including the same, and method for controlling the same are disclosed. The MRAM includes magnetic memory cells configured to change between at least two states according to a magnetization direction, and a mode register supporting a plurality of operational modes.

Abstract: A semiconductor device includes a bit-line sense amplifier (S/A) circuit configured to sense and amplify data stored in a resistive memory cell according to a reference current. The bit-line S/A circuit includes a cross-coupled latch circuit and a write latch circuit. The cross-coupled latch circuit is coupled to an input/output circuit via a first line and a complementary first line. The cross-coupled latch circuit is configured to receive write data via the first line, and to latch the write data during a data write operation. The write latch circuit is coupled to the cross-coupled latch circuit, and configured to store the write data in the resistive memory cell via a second line during the data write operation.

Abstract: A method and a memory device therefor for reconfiguring a DQ pad organization of the memory device on-the-fly. A DQ organization reconfiguration control unit generates a control signal for reconfiguring the DQ pad organization into a desired mode based on a user command. A DQ organization reconfiguration unit is provided between P DQ pads and memory cell arrays and reconfigures organization P DQ pads on-the-fly in any one among Xi DQ pad modes, where i=1, 2, 4, 8, 16, 32, 64, and 128, based on the control signal. For the reconfiguration of the organization of the DQ pads, a plurality of bus lines for data transfer, being switchable by a control signal, are provided. The bus lines are implemented utilizing at least one of the M3 and M4 metal layers of the memory device.

Abstract: A memory module includes a memory device, a command/address buffering device, and a processing data buffer. The memory device includes a memory cell array, a first set of input/output terminals, each terminal configured to receive first command/address bits, and a second set of input/output terminals, each terminal configured to receive both data bits and second command/address bits. The command/address buffering device is configured to output the first command/address bits to the first set of input/output terminals. The processing data buffer is configured to output the data bits and second command/address bits to the second set of input/output terminals. The memory device is configured such that the first command/address bits, second command/address bits, and data bits are all used to access the memory cell array.

Abstract: A semiconductor device includes a bit-line sense amplifier (S/A) circuit configured to sense and amplify data stored in a resistive memory cell according to a reference current. The bit-line S/A circuit includes a cross-coupled latch circuit and a write latch circuit. The cross-coupled latch circuit is coupled to an input/output circuit via a first line and a complementary first line. The cross-coupled latch circuit is configured to receive write data via the first line, and to latch the write data during a data write operation. The write latch circuit is coupled to the cross-coupled latch circuit, and configured to store the write data in the resistive memory cell via a second line during the data write operation.

Abstract: A resistive memory device may include a resistive cell array and an on-chip resistance measurement circuit. The resistive cell array may include a plurality of resistive memory cells. The on-chip resistance measurement circuit may be configured to generate a first current and a second current greater or less than the first current based on a cell current corresponding to a cell resistance of a first memory cell of the resistive memory cells, and to generate first and second digital signals based on the first and second current, respectively.

Abstract: A resistive memory device may include first and second resistive memory cells, a reference current generator, and first and second bitline sense amplifiers. The reference current generator may be configured to apply the first and second reference currents to a first common node. A total reference current of the first reference current and the second reference current provided to the first common node may be divided into a first sensing current and a second sensing current by the first common node. The first and second sensing currents may be provided to the first and second bitline sense amplifiers by the first common node, respectively. The first and second bitline sense amplifiers may be configured to sense first data of the first resistive memory cell and second data of the second resistive memory cell based on the first and second sensing currents, respectively.

Abstract: A memory core of a resistive type memory device includes at least a first resistive type memory cell coupled to a bit-line, a first resistance to voltage converter and a bit-line sense amplifier. The first resistance to voltage converter is coupled to the bit-line at a first node. The first resistance to voltage converter converts a resistance of the first resistive type memory cell to a corresponding voltage based on a read column selection signal. The bit-line sense amplifier is coupled to the bit-line at the first node and is coupled to a complementary bit-line at a second node. The bit-line sense amplifier senses and amplifies a voltage difference of the bit-line and the complementary bit-line in response to a sensing control signal.

Abstract: A resistive memory device may include first and second resistive memory cells, a reference current generator, and first and second bitline sense amplifiers. The reference current generator may be configured to apply the first and second reference currents to a first common node. A total reference current of the first reference current and the second reference current provided to the first common node may be divided into a first sensing current and a second sensing current by the first common node. The first and second sensing currents may be provided to the first and second bitline sense amplifiers by the first common node, respectively. The first and second bitline sense amplifiers may be configured to sense first data of the first resistive memory cell and second data of the second resistive memory cell based on the first and second sensing currents, respectively.

Abstract: A memory core of a resistive type memory device includes at least a first resistive type memory cell coupled to a bit-line, a first resistance to voltage converter and a bit-line sense amplifier. The first resistance to voltage converter is coupled to the bit-line at a first node. The first resistance to voltage converter converts a resistance of the first resistive type memory cell to a corresponding voltage based on a read column selection signal. The bit-line sense amplifier is coupled to the bit-line at the first node and is coupled to a complementary bit-line at a second node. The bit-line sense amplifier senses and amplifies a voltage difference of the bit-line and the complementary bit-line in response to a sensing control signal.

Abstract: A resistive memory device may include a resistive cell array and an on-chip resistance measurement circuit. The resistive cell array may include a plurality of resistive memory cells. The on-chip resistance measurement circuit may be configured to generate a first current and a second current greater or less than the first current based on a cell current corresponding to a cell resistance of a first memory cell of the resistive memory cells, and to generate first and second digital signals based on the first and second current, respectively.

Abstract: A semiconductor memory device includes a cell array including one or more bank groups, where each of the one or more bank groups includes a plurality of banks and each of the plurality of banks includes a plurality of spin transfer torque magneto resistive random access memory (STT-MRAM) cells. The semiconductor memory device further includes a source voltage generating unit for applying a voltage to a source line connected to the each of the plurality of STT-MRAM cells, and a command decoder for decoding a command from an external source in order to perform read and write operations on the plurality of STT-MRAM cells. The command includes a combination of at least one signal of a row address strobe (RAS), a column address strobe (CAS), a chip selecting signal (CS), a write enable signal (WE), and a clock enable signal (CKE).

Abstract: Provided is a memory device having a first switch configured to receive a first CSL signal to input or output data. A second switch is configured to receive a second CSL signal. A sensing and latch circuit (SLC) is coupled between the first and second switches. And at least one memory cell is coupled to the second switch. The second switch is configured to control timing of read or write operations of the at least one memory cell in response to the second CSL signal, e.g., where a read operation can be performed in not more than about 5 ns. The SLC operates as a latch in a write mode and as an amplifier in a read mode. The memory device may comprise part of a memory system or other apparatus including such memory device or system. Methods of performing read and write operations using such memory device are also provided.

Abstract: A memory device includes a cell array and a common source line compensation circuit. The cell array includes a plurality of normal cell units connected between a plurality of bit lines and one common source line, respectively. The common source line compensation circuit supplies a plurality of compensation write currents to the common source line to compensate for a plurality of write currents concurrently input into or output from the common source line through the normal cell units.

Abstract: A magneto-resistive random access memory (MRAM) including an MRAM cell array having an MRAM cell, and a control and voltage generation unit configured to generate a back bias voltage for the MRAM cell. The control and voltage generation unit including a command decoder configured to generate a decoding signal in response to a command output from a memory controller, and a voltage controller and generator configured to generate the back bias voltage with a magnitude based on the decoding signal and a reset signal output from the memory controller.

Abstract: Example embodiments include a resistive type memory sense amplifier circuit including differential output terminals, first and second input terminals, a pre-charge section, and other components arranged so that current is re-used during at least a “set” or “amplification” stage of the sense amplifier circuit, thereby reducing overall current consumption of the circuit, and improving noise immunity. A voltage level of a high-impedance output terminal is caused to swing in response to a delta average current between a reference line current and a bit line current. During a “go” or “latch” stage of operation, a logical value “0” or “1” is latched at the differential output terminals based on positive feedback of a latch circuit. Also disclosed is a current mirror circuit, which can be used in conjunction with the disclosed sense amplifier circuit. In yet another embodiment, a sense amplifier circuit includes the capability of read/re-write operation.

Abstract: A non-volatile memory device including a cell array, which includes a plurality of memory cells, and a sense amplification circuit. The sense amplification circuit is configured to receive a data voltage of a memory cell, a first reference voltage and a second reference voltage during a data read operation of the memory cell, generate differential output signals based on a voltage level difference between the data voltage and the first and second reference voltages, and output the differential output signals as data read from the memory cell.