Abstract: A stacked semiconductor memory device is provided which includes a first memory chip including a first transmission line, a second transmission line, and a logic circuit configured to execute a logic operation on a first signal of the first transmission line and a second signal of the second transmission line. The stacked semiconductor memory device further includes a second memory chip stacked over the first memory chip, an inter-chip connection unit electrically coupled between the second memory chip and the first transmission line of the first memory chip, and a dummy inter-chip connection unit electrically coupled to the second transmission line of the first memory chip and electrically isolated from the second memory chip.

Abstract: A semiconductor memory device includes a semiconductor die and an input-output bump pad part. The semiconductor die includes a plurality of memory cell arrays. The input-output bump pad part is formed in a central region of the semiconductor die. The input-output bump pad part provides a plurality of channels for connecting each of the memory cell arrays independently to an external device. The semiconductor memory device may adopt the multi-channel interface, thereby having high performance with relatively low power consumption.

Abstract: A multipath accessible semiconductor memory device provides an interface function between processors. The memory device may include a memory cell array having a shared memory area operationally coupled to two or more ports that are independently accessible by two or more processors, an access path forming unit to form a data access path between one of the ports and the shared memory area in response to external signals applied by the processors, and an interface unit having a semaphore area and mailbox areas accessible in the shared memory area by the two or more processors to provide an interface function for communication between the two or more processors.

Abstract: A multiprocessor system and method thereof are provided.

Abstract: An internal voltage generating method performed in a semiconductor device, the internal voltage generating method including generating a plurality of initialization signals corresponding to a plurality of external power supply voltages; detecting a transition of a lastly-generated initialization signal from among the plurality of initialization signals and generating a detection signal; and generating a first internal voltage according to the detection signal.

Abstract: Provided are a semiconductor chip including a TSV passing through a transistor, and a stack module and a memory card using such a semiconductor chip. The semiconductor chip may include a semiconductor layer that has a first surface and a second surface opposite to each other. A conductive layer may be disposed on the first surface of the semiconductor layer. A TSV may pass through the semiconductor layer and the conductive layer. A side wall insulating layer may surround a side wall of the TSV in order to electrically insulate the semiconductor layer and the conductive layer from the TSV.

Abstract: An internal power generating system for a semiconductor device is disclosed. The device may include a plurality of channels. The system comprises a reference voltage generator configured to generate a reference voltage. The system further comprises a plurality of internal power generators that are allocated to the plurality of channels in one-to-one correspondence and that are configured to commonly use the reference voltage generated by the reference voltage generator. Each internal power generator may be configured to receive a fed back internal power voltage, to compare the fed back internal power voltage to the reference voltage, and to generate an internal power voltage based on the comparison. The system further comprises a plurality of channel state detectors that are allocated to the plurality of channels in one-to-one correspondence, and that are configured to respectively detect operation states of the plurality of channels based on separate respective sets of command signals for each channel.

Abstract: A semiconductor device is provided. The semiconductor device applies data applied through a bump pad on which a bump is mounted through a test pad to a test apparatus such that the reliability of the test can be improved. The amount of test pads is significantly reduced by allowing data output through bump pads to be selectively applied to a test pad. Data and signals applied from test pads are synchronized with each other and applied to bump pads during a test operation such that the reliability of the test can be improved without the need of an additional test chip.

Abstract: Provided is a synchronous dynamic random access memory (DRAM) semiconductor device including multiple output buffers, a strobe control unit and multiple strobe buffers. Each of the output buffers is configured to output one bit of data. The strobe control unit is configured to output multiple strobe control signals in response to an externally input signal. The strobe buffers are connected to the output buffers and the strobe control unit, and each of the strobe buffers is configured to output at least one strobe signal. At least some of the strobe buffers are activated in response to the strobe control signals, and the output buffers are activated in response to the strobe signals output by the activated strobe buffers.

Abstract: A multiprocessor system and method thereof are provided.

Abstract: A semiconductor memory device is disclosed. The semiconductor device includes a memory cell array, a clock signal generator configured to receive an external clock signal from the outside of the memory device and output an internal clock signal, and a data output unit configured to receive an internal data signal from the memory cell array and output a read data signal in response to the internal clock signal. The semiconductor memory device also includes a read data strobe unit configured to output a read data strobe signal having a cycle time of n times (n is an integer equal to or more than 2) a cycle time of the internal clock signal, based on the internal clock signal.

Abstract: A stacked layer type semiconductor device includes N memories each including at least one main via and (N?1) sub vias, the N memories being sequentially stacked on one-another so that central axes of the N memories face each other crosswise, and a plurality of connection units electrically connecting the N memories. Here, N is a natural number greater than 1.

Abstract: Disclosed is a method of controlling a deep power down mode in a multi-port semiconductor memory having a plurality of ports connected to a plurality of processors. Control of the deep power down mode in the multi-port semiconductor memory is performed such that activation/deactivation of the deep power down mode are determined in accordance with signals applied through various ports in the plurality of ports.

Abstract: A multi-port semiconductor memory device having variable access paths and a method therefor are provided. The semiconductor memory device includes a plurality of input/output ports; a memory array divided into a plurality of memory areas; and a select control unit to variably control access paths between the memory areas and the input/output ports so that each memory area is accessed through at least one of the input/output ports.

Abstract: A method of outputting temperature data in a semiconductor device and a temperature data output circuit are provided. A pulse signal is generated in response to a booting enable signal activated in response to a power-up signal and the generation is inactivated in response to a mode setting signal during a power-up operation. A comparison signal is generated in response to the pulse signal by comparing a reference voltage independent of temperature with a sense voltage that varies with temperature change. The temperature data is changed in response to the comparison signal. Thus, the temperature data output circuit can rapidly output the exact temperature of the semiconductor device measured during the power-up operation.

Abstract: A refresh control circuit in a semiconductor memory device includes a refresh controller, a voltage generator and a word line enable circuit. The refresh period controller generates a control signal in response to a self-refresh signal, the control signal indicating a nominal initiation of a refresh period. The voltage generator generates an output voltage in response to the control signal. The output voltage is boosted from a low voltage to a high voltage during the refresh period. The word line enable circuit generates a word line enable signal in response to the control signal, wherein the word line enable signal is activated following a delay after the nominal initiation of the refresh period, and the delay allows the voltage generator to fully boost the output voltage.

Abstract: A multiport semiconductor memory device includes; first and second port units respectively coupled to first and second processors, first and second dedicated memory area accessed by first and second processors, respectively and implemented using DRAM cells, a shared memory area commonly accessed by the first and second processors via respective first and second port units and implemented using memory cells different from the DRAM cells implementing the first and second dedicated memory areas, and a port connection control unit controlling data path configuration between the shared memory area and the first and second port units to enable data communication between the first and second processors through the shared memory area.

Abstract: A semiconductor memory device and a self-refresh method in which the semiconductor memory device includes a plurality of input/output ports having respective independent operation, a period of self-refresh through one of the plurality of input/output ports being subordinate to a kind of operation through another input/output port. Whereby, a refresh characteristic in a multi-port semiconductor memory device including a dual-port semiconductor memory device may be improved.