Abstract: An electronic device includes a dock dividing circuit configured to generate sampling clocks, alignment clocks and output clocks by dividing a frequency of a write clock; and a data alignment circuit configured to, in a first operation mode, receive input data having any one level among a first level to a fourth level and generate alignment data by aligning the input data in synchronization with the sampling clocks, the alignment clocks and the output clocks, and to, in a second operation mode, receive the input data having any one level of the first level and the fourth level and generate the alignment data by aligning the input data in synchronization with the sampling clocks, the alignment clocks and the output clocks.

Abstract: An input/output circuit including: an input circuit configured to load differential input data to setup nodes based on a data strobe clock; an output circuit configured to compare and amplify the data loaded to the setup nodes, and output differential output data; and a voltage retention circuit configured to retain the setup nodes at voltage levels corresponding to the differential output data, based on the data strobe clock and the differential output data.

Abstract: A clock distribution circuit includes a global distribution circuit, a first local distribution circuit and a second local distribution circuit. The global distribution circuit receives external clock signals and generates internal clock signals and primary reference clock signal set according to the external clock signals. The first local distribution circuit receives the internal clock signals and the primary reference clock signal set and generates a secondary reference clock signal set according to the internal clock signals and the primary reference clock signal set. The second local distribution circuit receives the internal clock signals and the secondary reference clock signal set and generates a thirdly reference clock signal set according to the internal clock signals and the secondary reference clock signal set.

Abstract: Devices for reducing power consumption and skew for transmission of signals in a clock distribution circuit are described. A global distribution circuit is configured to divide external clock signals to generate first divided multiphase clock signals and divide one of the first divided multiphase clock signals to generate a reference clock signal. A local distribution circuit is configured to generate second divided multiphase clock signals according to a portion of the first divided multiphase clock signals and the reference clock signal.

Abstract: An input/output circuit including: an input circuit configured to load differential input data to setup nodes based on a data strobe clock; an output circuit configured to compare and amplify the data loaded to the setup nodes, and output differential output data; and a voltage retention circuit configured to retain the setup nodes at voltage levels corresponding to the differential output data, based on the data strobe clock and the differential output data.

Abstract: An electronic device includes a dock dividing circuit configured to generate sampling clocks, alignment clocks and output clocks by dividing a frequency of a write clock; and a data alignment circuit configured to, in a first operation mode, receive input data having any one level among a first level to a fourth level and generate alignment data by aligning the input data in synchronization with the sampling clocks, the alignment clocks and the output clocks, and to, in a second operation mode, receive the input data having any one level of the first level and the fourth level and generate the alignment data by aligning the input data in synchronization with the sampling clocks, the alignment clocks and the output clocks.

Abstract: An input/output circuit including: an input circuit configured to load differential input data to setup nodes based on a data strobe clock; an output circuit configured to compare and amplify the data loaded to the setup nodes, and output differential output data; and a voltage retention circuit configured to retain the setup nodes at voltage levels corresponding to the differential output data, based on the data strobe clock and the differential output data.

Abstract: A noise removing circuit may include: a reference voltage control circuit configured to perform a noise detection sequence operation based on noise detection sequence information, and control a reference voltage based on a counting value; a noise detection circuit configured to compare a supply voltage and the reference voltage, and generate a counting value corresponding to noise which has occurred in the supply voltage; a noise calculation circuit configured to generate a loading control signal corresponding to the noise by performing an operation on the counting value and the reference voltage; and a loading control circuit configured to control a loading value for the supply voltage based on the loading control signal.

Abstract: A noise removing circuit may include: a reference voltage control circuit configured to perform a noise detection sequence operation based on noise detection sequence information, and control a reference voltage based on a counting value; a noise detection circuit configured to compare a supply voltage and the reference voltage, and generate a counting value corresponding to noise which has occurred in the supply voltage; a noise calculation circuit configured to generate a loading control signal corresponding to the noise by performing an operation on the counting value and the reference voltage; and a loading control circuit configured to control a loading value for the supply voltage based on the loading control signal.

Abstract: An input/output circuit including: an input circuit configured to load differential input data to setup nodes based on a data strobe clock; an output circuit configured to compare and amplify the data loaded to the setup nodes, and output differential output data; and a voltage retention circuit configured to retain the setup nodes at voltage levels corresponding to the differential output data, based on the data strobe clock and the differential output data.

Abstract: Devices for reducing power consumption and skew for transmission of signals in a clock distribution circuit are described. A global distribution circuit is configured to divide external clock signals to generate first divided multiphase clock signals and divide one of the first divided multiphase clock signals to generate a reference clock signal. A local distribution circuit is configured to generate second divided multiphase clock signals according to a portion of the first divided multiphase clock signals and the reference clock signal.

Abstract: A signal receiver includes a first preliminary receiver circuit suitable for receiving an input signal and generating a first preliminary reception signal based on a first reference voltage, a second preliminary receiver circuit suitable for receiving the input signal and generating a second preliminary reception signal based on a second reference voltage, a reception circuit suitable for selecting one of the first preliminary reception signal and the second preliminary reception signal in response to a voltage level of a reception signal and generating the reception signal using the selected signal, and a reference voltage generation circuit suitable for adjusting a voltage level of the first reference voltage based on a first offset and adjusting a voltage level of the second reference voltage based on a second offset.

Abstract: A signal receiver includes a first preliminary receiver circuit suitable for receiving an input signal and generating a first preliminary reception signal based on a first reference voltage, a second preliminary receiver circuit suitable for receiving the input signal and generating a second preliminary reception signal based on a second reference voltage, a reception circuit suitable for selecting one of the first preliminary reception signal and the second preliminary reception signal in response to a voltage level of a reception signal and generating the reception signal using the selected signal, and a reference voltage generation circuit suitable for adjusting a voltage level of the first reference voltage based on a first offset and adjusting a voltage level of the second reference voltage based on a second offset.

Abstract: A data receiving circuit may include: a variable delay circuit suitable for generating a delayed strobe signal by delaying a strobe signal; a receiving circuit suitable for sampling data in synchronization with the delayed strobe signal; a phase shift circuit suitable for generating a shifted strobe signal by shifting a phase of the delayed strobe signal; a phase comparison circuit suitable for comparing phases of the data and the shifted strobe signal; and a delay adjusting circuit suitable for adjusting a delay value of the variable delay circuit in response to the phase comparison result of the phase comparison circuit.

Abstract: A data transmission circuit includes: a main driver circuit suitable for driving data to an output line; an amplitude equalization window generator circuit suitable for detecting the data transitioning from a first level to a second level; an auxiliary driver circuit suitable for driving the output line with the second level in response to a detection result of the amplitude equalization window generator circuit; and a phase equalization window generator circuit suitable for detecting whether the data consecutively has the first level, wherein the main driver circuit changes a time point of driving the data in response to a detection result of the phase equalization window generator circuit.

Abstract: A parallel-to-serial conversion circuit may include first to fourth data lines; first to fourth parallel-to-serial converters configured to parallel-to-serial convert data of corresponding two data lines, among the first to fourth data lines, at a ratio of 2:1, respectively; and first to fourth drivers configured to transmit converted data of corresponding parallel-to-serial converter, among the first to fourth parallel-to-serial converters, respectively, to an output line, wherein two of the first to fourth drivers are simultaneously activated.

Abstract: A data transmission circuit includes: a main driver circuit suitable for driving data to an output line; an amplitude equalization window generator circuit suitable for detecting the data transitioning from a first level to a second level; an auxiliary driver circuit suitable for driving the output line with the second level in response to a detection result of the amplitude equalization window generator circuit; and a phase equalization window generator circuit suitable for detecting whether the data consecutively has the first level, wherein the main driver circuit changes a time point of driving the data in response to a detection result of the phase equalization window generator circuit.

Abstract: An impedance adjusting circuit includes: a first node coupled to a resistor; a first impedance unit having an impedance value determined based on a first impedance code and coupled between a first voltage terminal and a second node; a first switching unit suitable for electrically connecting the first node and the second node to each other in response to a clock; a first average voltage unit suitable for generating an average voltage of the first node; a first comparison unit suitable for comparing the average voltage of the first node with a first reference voltage to produce a comparison result of the first comparison unit; and a first code generation unit suitable for generating the first impedance code in response to the comparison result of the first comparison unit.

Abstract: A parallel-to-serial conversion circuit may include first to fourth data lines; first to fourth parallel-to-serial converters configured to parallel-to-serial convert data of corresponding two data lines, among the first to fourth data lines, at a ratio of 2:1, respectively; and first to fourth drivers configured to transmit converted data of corresponding parallel-to-serial converter, among the first to fourth parallel-to-serial converters, respectively, to an output line, wherein two of the first to fourth drivers are simultaneously activated.

Abstract: A data receiving circuit may include: a variable delay circuit suitable for generating a delayed strobe signal by delaying a strobe signal; a receiving circuit suitable for sampling data in synchronization with the delayed strobe signal; a phase shift circuit suitable for generating a shifted strobe signal by shifting a phase of the delayed strobe signal; a phase comparison circuit suitable for comparing phases of the data and the shifted strobe signal; and a delay adjusting circuit suitable for adjusting a delay value of the variable delay circuit in response to the phase comparison result of the phase comparison circuit.