Abstract: A semiconductor memory device includes a plurality of memory cell blocks including a first memory cell block having bit lines, an edge sense amplifier block including edge sense amplifiers coupled to a portion of the bit lines of the first memory cell block, and a balancing capacitor unit coupled to the edge sense amplifiers.

Abstract: A semiconductor memory cell array includes a plurality of bit-lines, a plurality of word-lines, a plurality of memory cells, a plurality of dummy memory cells, a plurality of dummy bit-lines, and a plurality of dummy word-lines. The dummy bit-lines are in outer regions of the bit-lines. The dummy word-lines are in outer regions of the word-lines. The dummy bit-lines are maintained in a floating state. The dummy word-lines retain a turn-off voltage.

Abstract: A level detector, an internal voltage generator including the level detector, and a semiconductor memory device including the internal voltage generator are provided. The internal voltage generator includes a level detector that compares a threshold voltage that varies with temperature with an internal voltage to output a comparative voltage, and an internal voltage driver that adjusts an external supply voltage in response to the comparative voltage and that outputs an internal voltage.

Abstract: An antifuse circuit includes a protection circuit. The antifuse circuit receives a program voltage using a non-connection (NC) pin or ball of a semiconductor device. The protection circuit prevents an unintended voltage lower than the program voltage from being applied to the antifuse circuit.

Abstract: A semiconductor memory device for controlling an operation of a delay-locked loop (DLL) circuit is provided. The semiconductor memory device includes a DLL circuit that receives an external clock signal and that performs a locking operation on the external clock signal and an internal clock signal, thereby obtaining a locked state. A control unit controls the DLL circuit to constantly maintain the locked state during an updating period of an auto-refresh period of an auto-refresh operation for refreshing memory banks.

Abstract: A data path circuit of a semiconductor memory device includes: a bit line sense amplifier driven by a first power supply voltage; a local input/output line sense amplifier; a column selecting unit operatively connecting a pair of bit lines connected to the bit line sense amplifier and a pair of local input/output lines connected to the local input/output line sense amplifier in response to a column selection signal; and a local input/output line precharge unit precharging the pair of local input/output lines with a second power supply voltage different from the first power supply voltage during a period for which the column selection signal is in an inactive state.

Abstract: A semiconductor device includes a bit line connected to a plurality of memory cells in a memory block and a sense amplifier having a first node connected to the bit line and a second node, which is not connected to any bit line. The second node has a capacitive load less than that of the bit line. The sense amplifier amplifies a first data using a voltage difference between the first node and the second node caused by a charge sharing operation, and a second data using a capacitive mismatch between the first node and the second node.

Abstract: A bit line pre-charge circuit for a dynamic random access memory (DRAM) uses a charge sharing scheme. The pre-charge circuit includes switching elements disposed between a power voltage node and an output node, capacitors connected between intermediate nodes and ground. The switching elements being operated by successively activated control signals to effectively charge a bit line pair to one half a power voltage using charge sharing between the capacitors.

Abstract: A semiconductor memory device for controlling an operation of a delay-locked loop (DLL) circuit includes a DLL circuit that receives an external clock signal and that performs a locking operation on the external clock signal and an internal clock signal, thereby obtaining a locked state. A control unit controls the DLL circuit to constantly maintain the locked state during an updating period of an auto-refresh period of an auto-refresh operation for refreshing memory banks.

Abstract: Provided are a semiconductor device including a fuse and a method of operating the same. The semiconductor device includes a fuse array, a first register unit, and a second register unit. The fuse array includes a plurality of rows and columns. The first register unit receives at least one row of fuse data from the fuse array. Fuse data of the at least one row of fuse data is received in parallel by the first register unit. The second register unit receives the fuse data at least one bit at a time from the first register unit.

Abstract: A data training system and method thereof are provided. The example data training system may include a memory controller transmitting a given data pattern to a memory device, the memory controller first determining whether an error is present within the transmitted data pattern based on at least one error detection code, the at least one error detection code based on at least one of the given data pattern and the transmitted data pattern and second determining a data delay time for reducing an amount of skew based on whether the first determining step determines an error to be present within the transmitted data pattern.

Abstract: A memory cell includes a selection transistor on a substrate and an antifuse on the substrate. The selection transistor includes a first gate connected to a read word line, a first gate insulation layer that insulates the first gate from the substrate, a first source region connected to a bit line, and a first drain region, an impurity concentration of the first drain region being lower than an impurity concentration of the first source region. The antifuse includes a first electrode connected to a program word line and a second electrode connected to the selection transistor.

Abstract: A fuse circuit includes a program unit and a sensing unit. The program unit is programmed in response to a program signal and outputs a program output signal in response to a sensing enable signal. The sensing unit outputs a sensing output signal based on the program output signal and the sensing output signal indicates whether the program unit is programmed or not. The program unit includes an anti-fuse cell, a selection transistor, a program transistor and a sensing transistor. The anti-fuse cell includes at least two anti-fuse elements which are connected in parallel and are respectively broken down at different levels of a program voltage.

Abstract: A fuse circuit includes a program unit, a sensing unit and a control unit. The program unit is programmed in response to a program signal, and outputs a program output signal in response to a sensing enable signal. The sensing unit includes a variable resistor unit that has a resistance that varies based on a control signal, and generates a sensing output signal based on the resistance of the variable resistor unit and the program output signal. The control unit generates the control signal having a value changed depending on operation modes, and performs a verification operation with respect to the program unit based on the sensing output signal to generate a verification result. The program unit may be re-programmed based on the verification result.

Abstract: A three-dimensional (3D) semiconductor device may include a stack of chips, including a master chip and one or more slave chips. I/O connections of slave chips need not be connected to channels on a motherboard, and only electrode pads of a master chip may be connected to the channels. Only the master chip may provide a load to the channels. A through-substrate via (TSV) boundary may be set on a data input path, a data output path, an address/command path, and/or a clock path of a semiconductor device in which the same type of semiconductor chips are stacked.

Abstract: Provided are an anti-fuse, an anti-fuse circuit, and a method of fabricating the anti-fuse. The anti-fuse includes a semiconductor substrate, an isolation region, a channel diffusion region, a gate oxide layer, and a gate electrode. The semiconductor substrate includes a top surface and a bottom portion, the bottom portion of the semiconductor substrate having a first conductivity type. The isolation region is disposed inward from the top surface of the semiconductor substrate to a first depth. The channel diffusion region is disposed inward from the top surface of the semiconductor substrate to a second depth, the second depth located at a depth where the channel diffusion region meets an upper boundary of the bottom portion of the semiconductor substrate.

Abstract: A data transmission/reception system can lessen a skew between data and clock signal by substantially reducing a data reception error. The data transmission/reception system using a first clock signal and a second clock signal having a phase difference corresponding to a half of data bit period as compared with the first clock signal includes a skew information extracting unit and a timing control unit. The skew information extracting unit obtains and outputs skew edge information data necessary for a skew removal by sampling data transmitted in a training operating mode as one of the first and second clock signals in a receiving side. The timing control unit receives the skew edge information data through a transmitting side, and compares its phase with a phase of the transmitted data and controls a timing between transmission data and a transmission sampling clock signal applied to a transmission output unit according to the phase comparison result.

Abstract: DC balance encoded data is transmitted by transmitting a preamble of dummy data that is configured to provide an intermediate number of bits of a given logic value that is at least one bit of the given logic value but less than a maximum number of bits of the given logic value in the DC balance encoded data, to thereby reduce the simultaneous switching noise that is caused by transmission of a first word of DC balance encoded data. The preamble may contain one or more words of fixed and/or variable dummy data.

Abstract: A latency signal generator and method thereof are provided. The example latency signal generator may include a sampling clock signal generator adjusting a plurality of initial sampling clock signals based on a received clock signal to generate a plurality of adjusted sampling clock signals, a latch enable signal supply unit adjusting a plurality of initial latch enable signals based on a given one of the plurality of initial sampling clock signals to generate a plurality of adjusted latch enable signals and a latch unit including a plurality of latency latches, each of the plurality of latency latches selectively latching a given internal read command based on one of the plurality of adjusted sampling clock signals and one of the plurality of adjusted latch enable signals.

Abstract: A bitline sense amplifier includes a pre-sensing unit and an amplification unit. The pre-sensing unit is connected to a first bitline and a second bitline, and is configured to perform a pre-sensing operation by controlling a voltage level of the second bitline based on at least one pre-sensing voltage and variation of a voltage level of the first bitline. The amplification unit is configured to perform a main amplification operation by amplifying a pre-sensed voltage difference based on a first voltage signal and a second voltage signal. The pre-sensed voltage difference indicates a difference between the voltage level of the first bitline and the voltage level of the second bitline after the pre-sensing operation.