Abstract: A delay circuit includes a clock delay line, a command delay line, a delay line control block, and a shared shift register block. The clock delay line delays an input clock and generates a delayed clock. The command delay line delays a command signal and generates a delayed command signal. The delay line control block generates a control signal according to a result of comparing phases of a feedback clock which is generated as the delayed clock is delayed by a modeled delay value and the input clock. The shared shift register block sets delay amounts of the clock delay line and the command delay line to be substantially the same with each other, in response to the control signal.

Abstract: A clock generation circuit includes a delay line, a delay modeling block, a phase detection block, a multi-update signal generation block, and a delay line. The delay line delays an input clock and generates a delayed clock. The delay modeling block delays the delayed clock by a modeled delay value and generates a feedback clock. The phase detection block compares phases of the input clock and the feedback clock and generates phase information, and quantizes a phase difference between the input clock and the feedback clock and generates phase codes. The multi-update signal generation block generates a multi-update signal in response to the phase codes. The delay line control block changes a delay amount of the delay line in response to the multi-update signal and the phase information.

Abstract: An on-die termination circuit includes a reference period signal generation circuit that generates a reference period signal according to a level of a reference voltage, a first period signal generation circuit that generates a first period signal according to a voltage level of a pad, a period comparison circuit that compares a period of the first period signal with a period of the reference period signal and count a plurality of driving signals, and a driver circuit that drives the pad in response to the plurality of driving signals.

Abstract: A reset signal generation apparatus includes a reset signal generation unit and a reset signal expansion unit. The reset signal generation unit enables a reset signal and an enable signal in response to a reset input signal, and disables the reset signal in response to a pulse width extension signal. The reset signal expansion unit generates the pulse width extension signal that is enabled for a predetermined time, in response to the enable signal.

Abstract: A duty cycle correction circuit includes a clock adjustment unit configured to adjust a duty ratio of an input clock signal in response to a duty control signal and generate an output clock signal, a tracking type setting unit configured to generate an tracking type selection signal for setting a first or second tracking type based on a duty locking state of the output clock signal, and a control signal generation unit configured to generate the duty control signal, into which the first or second tracking type is incorporated, in response to the tracking type selection signal and the output clock signal.

Abstract: A clock generation circuit includes a delay line, which delays an input clock and generates a delayed clock, a delay modeling unit, which delays the delayed clock by a modeled delay value and generates a feedback clock, a phase detection unit, which compares phases of the input clock and the feedback clock and generates a phase detection signal, a filter unit, which receives the phase detection signal and generates phase information, generates an update signal when a difference between the numbers of phase detection signals with a first and a second level generated is greater than or equal to a threshold value, and generates the update signal after a lapse of a predetermined time when the difference is less than the threshold value, and a delay line control unit, which sets a delay value of the delay line in response to the update signal and the phase information.

Abstract: A counting circuit of a semiconductor device includes a plurality of counting units configured to count respective bits of counting codes in response to a plurality of counting clocks, respectively, and to control in a counting direction in response to a counting control signal; a clock toggling control unit configured to control the number of counting clocks that toggle among the plurality of counting clocks in response to clock control signals; and a counting operation control unit configured to compare a value of target codes and a value of the counting codes, and to determine a value of the counting control signal according to a comparison result.

Abstract: A phase locked loop includes a phase detector configured to compare a phase of an input clock with a phase of a feedback clock to produce a phase comparison result, an initial frequency value provider configured to detect a frequency of the input clock and provide a frequency detection result, a controller configured to generate a frequency control signal based on the phase comparison result and the frequency detection result, and an oscillator configured to generate an output clock in response to the frequency control signal.

Abstract: A semiconductor device includes a characteristic code storage unit configured to store signal transfer characteristic information input through a given pad and output a control code corresponding to the signal transfer characteristic information, and a characteristic reflection unit configured to reflect the signal transfer characteristic information in an input signal input through the given pad, in response to the control code, and to output the reflected input signal.

Abstract: A system for transmitting data includes a plurality of data lines configured to transmit the data and a transmitting chip configured to output the data to the data lines and perform a crosstalk prevention operation in response to a data pattern of the data to be transmitted through the data lines and array information of the data lines to prevent crosstalk from occurring in the data lines.

Abstract: A counting circuit of a semiconductor device includes a plurality of counting units configured to count respective bits of counting codes in response to a plurality of counting clocks, respectively, and to control in a counting direction in response to a counting control signal; a clock toggling control unit configured to control the number of counting clocks that toggle among the plurality of counting clocks in response to clock control signals; and a counting operation control unit configured to compare a value of target codes and a value of the counting codes, and to determine a value of the counting control signal according to a comparison result.

Abstract: A clock generation circuit includes a delay line, a delay modeling block, a phase detection block, a multi-update signal generation block, and a delay line. The delay line delays an input clock and generates a delayed clock. The delay modeling block delays the delayed clock by a modeled delay value and generates a feedback clock. The phase detection block compares phases of the input clock and the feedback clock and generates phase information, and quantizes a phase difference between the input clock and the feedback clock and generates phase codes. The multi-update signal generation block generates a multi-update signal in response to the phase codes. The delay line control block changes a delay amount of the delay line in response to the multi-update signal and the phase information.

Abstract: A delay circuit includes a clock delay line, a command delay line, a delay line control block, and a shared shift register block. The clock delay line delays an input clock and generates a delayed clock. The command delay line delays a command signal and generates a delayed command signal. The delay line control block generates a control signal according to a result of comparing phases of a feedback clock which is generated as the delayed clock is delayed by a modeled delay value and the input clock. The shared shift register block sets delay amounts of the clock delay line and the command delay line to be substantially the same with each other, in response to the control signal.

Abstract: A reset signal generation apparatus includes a reset signal generation unit and a reset signal expansion unit. The reset signal generation unit enables a reset signal and an enable signal in response to a reset input signal, and disables the reset signal in response to a pulse width extension signal. The reset signal expansion unit generates the pulse width extension signal that is enabled for a predetermined time, in response to the enable signal.

Abstract: A clock generation circuit includes a delay line, which delays an input clock and generates a delayed clock, a delay modeling unit, which delays the delayed clock by a modeled delay value and generates a feedback clock, a phase detection unit, which compares phases of the input clock and the feedback clock and generates a phase detection signal, a filter unit, which receives the phase detection signal and generates phase information, generates an update signal when a difference between the numbers of phase detection signals with a first and a second level generated is greater than or equal to a threshold value, and generates the update signal after a lapse of a predetermined time when the difference is less than the threshold value, and a delay line control unit, which sets a delay value of the delay line in response to the update signal and the phase information.

Abstract: An integrated circuit includes a delay locked loop configured to delay a reference clock signal by a delay time for delay locking and generate a delay locked clock signal, a clock transmission circuit configured to transmit the delay locked clock signal in response to a clock transmission signal, a duty correction circuit configured to perform duty correction operation on an output clock signal of the clock transmission circuit, and a clock transmission signal generation circuit configured to generate the clock transmission signal in response to a command and burst length information.

Abstract: A phase-locked loop includes a phase detection unit configured to compare the phase of a feedback clock with the phase of an input clock, a clock generation unit configured to adjust the frequency of a first clock based on a result of the comparison of the phase detection unit, a first division unit configured to generate an output clock by dividing the first clock at a first division ratio in test mode and generate the output clock by dividing the first clock at a second division ratio that is lower than the first division ratio in normal mode, and a second division unit configured to generate the feedback clock by dividing the output clock.

Abstract: A majority decision circuit includes: a majority decision unit configured to compare first data with second data to decide whether one of the first data and the second data has more bits with a first logical value; and an offset application unit configured to control the majority decision unit so that the majority decision unit decides, in a case when the number of bits with the first logical value among the first data is equal to the number of bits with the first logical value among the second data, that the first data have more bits with the first logical value if offset is a first setting value in a first phase and decides that the second data have more bits with the first logical value if the offset is a second setting value in a second phase.

Abstract: A semiconductor integrated circuit includes: a delay locked loop (DLL) configured to generate a DLL clock signal by delaying a source clock signal by a first delay time for obtaining a lock, wherein an update period of the DLL is controlled in response to an update period control signal after locking is completed; and an update period controller configured to generate the update period control signal based on a second delay time occurring in a loop path of the DLL in response to the source clock signal and a plurality of control signals provided from the DLL.

Abstract: A majority decision circuit includes: a majority decision unit configured to compare first data with second data to decide whether one of the first data and the second data has more bits with a first logical value; and an offset application unit configured to control the majority decision unit so that the majority decision unit decides, in a case when the number of bits with the first logical value among the first data is equal to the number of bits with the first logical value among the second data, that the first data have more bits with the first logical value if offset is a first setting value in a first phase and decides that the second data have more bits with the first logical value if the offset is a second setting value in a second phase.