Abstract: A data receiver of a semiconductor integrated circuit is configured to detect received data using an equalization function, wherein the data receiver is configured to stop the equalization function during a period in which the data is not received.

Abstract: Data transmitter includes a first and second output nodes terminated to a first level, a controller configured to generate an off signal that is activated by logically combining first and second data during a low-power mode, a first driver configured to drive the first or second output node to a second level in response to the first data and a second driver configured to drive the first or second output node to the second level with a driving force different from that of the first driver in response to the second data, the second driver being turned off when the off signal is activated.

Abstract: A phase locked loop circuit and a control method thereof. A phase locked loop circuit includes a phase detecting and correcting block configured to detect a phase difference between a reference clock and a feedback clock, and to correct the phase of the feedback clock such that the phase of the reference clock and the phase of the feedback clock are consistent with each other, and an initial locking level setting block configured to set a locking level in a normal operation mode in the phase detecting and correcting block. The initial locking level setting block includes a digital-to-analog converting unit configured to generate an analog voltage according to a digital code corresponding to the set frequency, and charges the capacitive element with the analog voltage, and a switching unit configured to connect the digital-to-analog converting unit and the capacitive element in response to an input of an operation start signal.

Abstract: A PLL circuit includes a phase detector that compares the phase of an input clock with the phase of a feedback clock so as to generate pull-up and pull-down control signals. A low pass filter pumps a voltage in response to the pull-up and pull-down control signals, and removes a noise component from the pumped voltage so as to output a control voltage. A buffer that controls voltage so as to generate a bias voltage having a smaller swing width than the control voltage. A voltage controlled oscillator receives the bias voltage and oscillates an output clock. A clock divider divides the frequency of the output clock at a predetermined ratio so as to generate the feedback clock.

Abstract: A data receiver of a semiconductor integrated circuit includes an amplifier that outputs an amplified signal by detecting and amplifying received data using equalization function according to feedback data, a detecting unit that detects a period when data is not received in the amplifier and outputs a detecting signal, and an equalization function control unit that stops the equalization function of the amplifier in response to the detecting signal.

Abstract: A semiconductor device includes transmission lines for conveying signals and transition detectors, each of which checks whether a transmission signal on each of the plurality of transmission lines is transited. If the signal is transited, its transition shape is detected. A signal mode determining unit determines signal transmission modes between adjacent transmission lines in response to output signals from the plurality of transition detectors. Delay units are coupled to the respective transmission lines for adjusting transmission delays of the transmission signals depending on corresponding output signal from the signal mode determining units.

Abstract: A power supply apparatus of a semiconductor integrated circuit includes a power control device that detects a level of power supplied from the outside and outputs a control signal as information on the detected level, and a power supply device that controls an internal resistance component in response to an input of the control signal, controls the level of the power supplied from the outside, and supplies the power having the controlled level to circuit blocks.

Abstract: An apparatus for removing crosstalk in a semiconductor memory device includes pads for receiving externally provided signals, transmission lines for delivering the signals received by each of the pads to corresponding elements in the apparatus, and capacitors, coupled between adjacent ones of the lines, for adjusting the transmission delay of the signals depending on a signal transmission mode between the adjacent lines.

Abstract: A reservoir capacitor includes a first power supply unit and a second power supply unit, and at least two large-capacity capacitors connected in series between the first and second power supply units.

Abstract: A duty ratio correction circuit including a reference clock generation block configured to generate first and second reference clocks that synchronize with rising and falling edges of an external clock and have a primarily corrected duty ratio, and a duty ratio adjustment block for generating first and second internal clocks in response to the first and second reference clocks, and secondarily correcting a duty ratio of the first and second reference clocks by adjusting phases of the first and second reference clocks by means of plural digital control signals generated according to phase difference between the first and second internal clocks.

Abstract: A receiver circuit is capable of improving its operating characteristics. The receiver circuit includes a variable converter configured to output off-set control voltages in a first output range in a first operation mode and output the off-set control voltages in a second output range in a second operation mode according to a test mode activation signal, and a sense amplifier configured to sense input data based on a sensitivity, wherein the sensitivity is controlled by the off-set control voltages.

Abstract: Data transmitter includes a first and second output nodes terminated to a first level, a controller configured to generate an off signal that is activated by logically combining first and second data during a low-power mode, a first driver configured to drive the first or second output node to a second level in response to the first data and a second driver configured to drive the first or second output node to the second level with a driving force different from that of the first driver in response to the second data, the second driver being turned off when the off signal is activated.

Abstract: A data receiver includes a plurality of amplifiers for receiving data in response to clock signals having a predetermined phase difference, and amplifying the received data by performing an equalization function based on feedback data, thereby outputting amplification signals, and a plurality of latches for latching output of the amplifiers, respectively. One amplifier receives the amplification signal, as feedback data, from another amplifier receiving a clock signal having a phase more advanced than a phase of a clock signal received in the one amplifier.

Abstract: A receiver circuit capable of controlling setup/hold time includes a first phase transmission unit configured to generate a first output signal by detecting input data according to plural detection levels while being synchronized with a first clock signal, and controlling setup/hold time of the first output signal based on a level of a first offset voltage, a level converter configured to control a voltage level of the first output signal according to a first code, and a second phase transmission unit configured to receive an output signal of the level converter for as a second offset voltage while being synchronized with a second clock signal, to generate a second output signal by detecting the input data according to the detection levels, and to control setup/hold time of the second output signal.

Abstract: A semiconductor integrated circuit equipped with an equalizer which has a circuit structure simpler than that of a related equalizer according to an FFE scheme or a DFE scheme and is capable of preventing a noise component from being amplified. The data receiver includes a plurality of receiver units, wherein each receiver unit includes a plurality of level detectors which detect different levels, and an encoder, in which the level detectors receive data according to a clock signal having a predetermined phase difference and perform an amplification operation including an equalization function based on feedback data, thereby outputting an amplification signal, and wherein level detectors of one receiver unit receive an amplification signal, as the feedback data, from level detectors of another receiver unit that receives a first clock signal having a phase more advanced than a phase of a second clock signal received in one receiver unit.

Abstract: A data receiver of a semiconductor integrated circuit includes an amplifier that outputs an amplified signal by detecting and amplifying received data using equalization function according to feedback data, a detecting unit that detects a period when data is not received in the amplifier and outputs a detecting signal, and an equalization function control unit that stops the equalization function of the amplifier in response to the detecting signal.

Abstract: A semiconductor integrated circuit can include a first voltage pad, a second voltage pad, and a voltage stabilizing unit that is connected between the first voltage pad and the second voltage pad. The first voltage pad can be connected to a first internal circuit, and the second voltage pad can be connected to a second internal circuit.

Abstract: A semiconductor memory device includes a delay locked loop circuit that can control input/output timing of data according to a system clock of a high frequency. The semiconductor memory device includes a phase comparator configured to detect a phase difference between an internal clock and a reference clock to output a state signal having a pulse width corresponding to the detected phase difference, a phase adjuster configured to generate a digital code for determining a delay time corresponding to the state signal for locking a phase of the internal clock, a digital-to-analog converter configured to convert the digital code to an analog voltage, and a multiphase delay signal generator configured to delay the internal clock according to a bias voltage corresponding to the analog voltage to feed back the delayed internal clock as the internal clock and generate multiphase delay signals.

Abstract: A receiver circuit according to the invention includes a first phase transmission unit that is synchronized with a first clock, detects input data according to a plurality of detection levels, and transmits a first output signal, a first discharging control unit that controls a second phase transmission unit in response to the first output signal and adjusts the transmission speed of the second phase transmission unit by changing a node potential where an output of the second phase transmission is determined, and the second phase transmission unit that is synchronized with a second clock, detects the input data according to an output of the first discharging control unit, and transmits a second output signal.

Abstract: A phase detecting circuit includes a first node that outputs a pull-up control signal, a second node that outputs a pull-down control signal, an initializing unit that initializes voltage levels of the first and second nodes in response to a pre-charge signal, a data input unit to which receives a receiver data, a phase comparison unit that compares a phase of a receiver clock and a phase of the receiver data input to the data input unit to control the voltage levels of the first and second nodes, and a charging/discharging unit that charges or discharges electric charges that are applied to the first and second nodes.