Abstract: Disclosed are a delay locked loop (DLL) and a method of driving the same. The delay locked loop includes a clock buffer for buffering an inputted external clock to generate an internal clock, the clock buffer generating a control signal for disabling the internal clock depending on whether the power is down, a delayed line for delaying the internal clock, a clock driver for buffering the output of the delayed line to generate a clock signal, the clock driver disabling the clock signal depending on whether the power is down, a delay monitor for delaying the external clock, a phase detector for detecting the difference in a phase between the internal clock and the output of the delayed monitor to generate a detected signal, the phase detector being disabled according to the control signal, and a shift register for controlling the delayed line according to the detected signal from the phase detector.

Abstract: A delay locked loop (DLL) capable of correcting a duty ratio of a clock signal including: a clock buffer which receives an external clock signal for outputting a rising edge clock signal; a delay unit for delaying the rising edge clock signal based on a first comparison signal in order to generate a first internal clock signal, a second internal clock signal, a first delay locking signal and a second delay locking signal; a duty correction unit for receiving the first and the second internal clock signals and the first and the second delay locking signals and generating a delay locked clock signal by correcting a duty cycle of the external clock signal; and a clock feed-back unit for receiving the delay locked clock signal and the external clock signal in order to generate the first comparison signal.

Abstract: A register controlled delay locked loop (DLL), including: a coarse delay line for generating a delayed input clock signal by delaying an external clock signal; a fine delay line unit for receiving the delayed input clock signal in order to generate a first fine delayed clock signal and a second fine delayed clock signal; a phase detector for comparing phases of the external clock signal and a feed-backed clock signal in order to generate a phase detection signal based on the comparison result; a phase mixer for generating a mixed clock signal by mixing phases of the first fine delayed clock signal and the second fine delayed clock signal based on a weight value; and a mixer controller for generating the weight value based on the phase detection signal.

Abstract: An apparatus for adjusting a clock signal, including: a clock multiplexing unit for receiving an external clock signal, an external clock bar signal and a feed-backed clock signal in order to select one of the external clock signal and the external clock bar signal as an output signal of the clock multiplexing unit based on a result of comparing a phase of the external clock signal with a phase of the feed-backed clock signal; and a delay locked loop (DLL) for generating a duty corrected clock signal and the feed-backed clock signal in response to the output signal of the clock multiplexing unit.

Abstract: An apparatus for detecting locking information of a DLL clock in a semiconductor memory device includes a delayed locked loop for generating a first comparison signal and a first delay end signal; a phase state storing block for receiving the first comparison signal and the first delay end signal to thereby generate a locking selection signal; and a locking information detector for generating a locking state signal presenting the locking information in response to the first comparison signal, the first delay end signal and the locking selection signal.

Abstract: A refresh control circuit for use in a semiconductor memory device having a plurality of banks, including: a bank number signal generator for generating a plurality of bank number signals having a predetermined delay time between generation timings of the plurality of bank number signals based on a refresh signal and a reference signal; and a bank selection unit for generating a plurality of bank selection signals in response to the plurality of bank number signals and a piled-refresh control signals to thereby refresh the plurality of banks.

Abstract: A delay locked loop device includes a first delay line for receiving an external clock signal and a first delay control signal to generate a first internal clock signal; a second delay line for receiving the external clock signal and a second delay control signal or the first delay control signal to generate a second internal clock signal; a first delay control block for receiving the external clock signal to generate the first delay control signal; a second delay control block for receiving the external clock signal to generate the second delay control signal; and a phase detecting block for receiving the first internal clock signal and the second internal clock signal to generate the on-off signal by comparing a phase of the first internal clock signal with a phase of the second internal clock signal.

Abstract: A delayed lock loop for preventing a stuck fail in a dead-zone includes a clock buffering block for generating a first and a second internal clock signals; a phase comparison block for delaying a feedback signal by a first predetermined value and for respectively comparing a phase of a delayed feedback signal and a phase of the feedback signal with a phase of the external clock signal; a clock selecting block for selecting one of the first and second internal clock signals based on one comparison result to thereby generate a selected internal clock signal; a stuck checking block for determining a delay value based on the other comparison result; a delay line block for delaying the selected internal clock signal by the delay value; and an output buffer for buffering an outputted signal from the delay line block to thereby generating a DLL clock signal.

Abstract: A power-down mode exit control circuit enables a memory device to exit from an initially set power-down mode state using a clock enable signal. Specifically, although a clock enable signal is inputted in an unstable state at an initial operation indicating that a supply of a supply voltage is started, the present invention provides the power-down mode exit control circuit which is capable of escaping from the power-down mode at an internally set correct time. For this, the present invention comprises: a clock enable signal sensor for sensing an activation or deactivation state of a clock enable signal; and a power-down mode exit signal generator for activating and outputting a power-down mode exit signal in accordance with the activation state of the clock enable signal sensed by the sensor, after storing information related to the deactivation state of the clock enable signal sensed by the sensor.

Abstract: A delayed locked loop in a semiconductor memory device includes a read enable signal generating block for generating a read enable signal, wherein the read enable signal is enabled based on the application of a read command, and is disabled when all data is read out and outputted; a first internal clock controlling block for intermitting the output of a first internal clock through the use of the read enable signal; a second internal clock controlling block for intermitting the output of a second internal clock through the use of the read enable signal; a DLL clock generating block for receiving the first and second internal clocks to thereby generate first and second DLL clocks.

Abstract: A delay locked loop (DLL) capable of correcting a duty ratio including: a clock buffer for receiving an external clock signal and an inverted external clock signal to generate a rising edge clock signal; a delay unit for delaying the rising edge clock signal based on a first comparison signal in order to generate a first internal clock signal, a second internal clock signal, a first delay locking signal and a second delay locking signal; a duty correction unit for receiving the first and the second internal clock signals and the first and the second delay locking signals to generate a mixed clock signal; a delay model unit for delaying the mixed clock signal to generate a feed-backed clock signal; and a first phase detector for receiving the external clock signal and the feed-backed clock signal to generate the first comparison signal.

Abstract: A delay locked loop (DLL) capable of correcting a duty ratio of a clock signal including: a clock buffer which receives an external clock signal for outputting a rising edge clock signal; a delay unit for delaying the rising edge clock signal based on a first comparison signal in order to generate a first internal clock signal, a second internal clock signal, a first delay locking signal and a second delay locking signal; a duty correction unit for receiving the first and the second internal clock signals and the first and the second delay locking signals and generating a delay locked clock signal by correcting a duty cycle of the external clock signal; and a clock feed-back unit for receiving the delay locked clock signal and the external clock signal in order to generate the first comparison signal.

Abstract: A semiconductor device for correcting a duty of a clock signal includes a first clock buffer for receiving an external clock signal through a non-inverting terminal of the first clock buffer and for receiving an external clock bar signal through an inverting terminal of the first clock buffer to thereby output a first clock input signal; a second clock buffer for receiving the external clock bar signal through the non-inverting terminal of the first clock buffer and for receiving the external clock signal through the inverting terminal of the first clock buffer to thereby output a second clock input signal; and a delay locked loop (DLL) for receiving the first clock input signal and the second clock input signal to thereby generate a duty corrected clock signal.

Abstract: Disclosed are a delay locked loop (DLL) and a method of driving the same. The delay locked loop includes a clock buffer for buffering an inputted external clock to generate an internal clock, the clock buffer generating a control signal for disabling the internal clock depending on whether the power is down, a delayed line for delaying the internal clock, a clock driver for buffering the output of the delayed line to generate a clock signal, the clock driver disabling the clock signal depending on whether the power is down, a delay monitor for delaying the external clock, a phase detector for detecting the difference in a phase between the internal clock and the output of the delayed monitor to generate a detected signal, the phase detector being disabled according to the control signal, and a shift register for controlling the delayed line according to the detected signal from the phase detector.

Abstract: A register controlled delay locked loop having an acceleration mode corresponding to an increase of the operation speed of a memory device is used to improve accuracy. The register controlled delay locked loop includes a delay line, a delay model, a delay block, a first phase comparator, and a second phase comparator, a mode decision block, a shift register control block, and a shift register.

Abstract: Disclosed are a delay locked loop (DLL) and a method of driving the same. The delay locked loop includes a clock buffer for buffering an inputted external clock to generate an internal clock, the clock buffer generating a control signal for disabling the internal clock depending on whether the power is down, a delayed line for delaying the internal clock, a clock driver for buffering the output of the delayed line to generate a clock signal, the clock driver disabling the clock signal depending on whether the power is down, a delay monitor for delaying the external clock, a phase detector for detecting the difference in a phase between the internal clock and the output of the delayed monitor to generate a detected signal, the phase detector being disabled according to the control signal, and a shift register for controlling the delayed line according to the detected signal from the phase detector.

Abstract: A delay locked loop device includes a first delay line for receiving an external clock signal and a first delay control signal to generate a first internal clock signal; a second delay line for receiving the external clock signal and a second delay control signal or the first delay control signal to generate a second internal clock signal; a first delay control block for receiving the external clock signal to generate the first delay control signal; a second delay control block for receiving the external clock signal to generate the second delay control signal; and a phase detecting block for receiving the first internal clock signal and the second internal clock signal to generate the on-off signal by comparing a phase of the first internal clock signal with a phase of the second internal clock signal.

Abstract: An apparatus for outputting burst read data is disclosed which divides input data into an odd number data group and an even number data group, selects a data group including a bit to be first outputted and synchronizes the data group including the bit at rising edges of a clock signal and a data group not including the bit at falling edges of a clock signal, thereby continuously outputting burst read data at a high speed according to output mode set in mode register set using sequential or interleave modes.

Abstract: A clock control circuit for a Rambus DRAM is provided which reduces power consumption by determining in advance whether an applied command is a read or current control command, and enabling a clock signal for externally outputting an internal data only during the read or current control command.

Abstract: A clock synchronization circuit using a phase mixer is disclosed. The clock synchronization circuit generates an internal clock signal having a phase between phases of two clock signals generated in two variable delay lines with a predetermined phase difference by using the phase mixer, thereby precisely synchronizing the clock signal. When a shift register for controlling the variable delay line performs a shift operation, the output clock signal from the variable delay line where the shift operation is performed is not inputted to the phase mixer, but the output clock signal from the other variable delay line is inputted to the phase mixer. As a result, jitter elements generated due to the shift operation do not influence the internal clock signal.