초록 ▼

Methods, circuits, devices, and systems are provided, including embodiments with local coarse delay units. One embodiment includes generating a first delayed signal, a second delayed signal, and a third delayed signal by delaying a clock reference signal with various time delays of a coarse delay li

Methods, circuits, devices, and systems are provided, including embodiments with local coarse delay units. One embodiment includes generating a first delayed signal, a second delayed signal, and a third delayed signal by delaying a clock reference signal with various time delays of a coarse delay line and local coarse delay units. This method embodiment also includes generating a clock output signal based on the first delayed signal, the second delayed signal, or the third delayed signal, depending on a phase difference between the clock reference signal and the clock output signal.

대표청구항 ▼

What is claimed is: 1. A method of generating a clock output signal, comprising: generating a first delayed signal by delaying a clock reference signal with a time delay of a coarse delay line; generating a second delayed signal by delaying the clock reference signal with the time delay of the coar

What is claimed is: 1. A method of generating a clock output signal, comprising: generating a first delayed signal by delaying a clock reference signal with a time delay of a coarse delay line; generating a second delayed signal by delaying the clock reference signal with the time delay of the coarse delay line and a time delay of a first local coarse delay unit; generating a third delayed signal by delaying the clock reference signal with the time delay of the coarse delay line, the time delay of the first local coarse delay unit, and a time delay of a second local coarse delay unit; and generating a clock output signal using a phase mixer configured to adjust a particular time delay of the clock output signal by fine-shifting: based on the first delayed signal, when a phase of the clock output signal lags a phase of the clock reference signal by at least the time delay of the first local coarse delay unit; based on the second delayed signal, when the phase of the clock output signal lags the phase of the clock reference signal by less than the time delay of the first local coarse delay unit and leads the phase of the clock reference signal by less than the time delay of the second local coarse delay unit; and based on the third delayed signal, when the phase of the clock output signal leads the phase of the clock reference signal by at least the time delay of the second local coarse delay unit; wherein the phase mixer does not receive the clock reference signal. 2. The method of claim 1, wherein: generating the second delayed signal includes delaying the first delayed signal by the time delay of the first local coarse delay unit; and generating the third delayed signal includes delaying the second delayed signal by the time delay of the second local coarse delay unit. 3. The method of claim 1, wherein: generating the second delayed signal includes delaying an output signal of the first local coarse delay unit with the time delay of the coarse delay line; and generating the third delayed signal includes delaying an output signal of the second local coarse delay unit with the time delay of the coarse delay line. 4. The method of claim 1, wherein generating the third delayed signal includes delaying the clock reference signal with a time delay of the second local coarse delay that is equal to a time delay of the first local coarse delay unit. 5. The method of claim 1, wherein generating the first delayed signal includes delaying the clock reference signal with a time delay of the coarse delay line that is a multiple of the time delay of the first local coarse delay unit. 6. The method of claim 5, wherein generating the third delayed signal includes delaying the clock reference signal with a time delay of the second local coarse delay that is equal to a time delay of the first local coarse delay unit. 7. A method of generating a clock output signal, comprising: generating a plurality of local coarse delay unit output signals, based on a clock reference signal, by using a series of local coarse delay units; coupling a phase selector output signal, selected from the number of local coarse delay unit output signals, from a phase selector to a phase mixer, in response to a phase difference between the clock reference signal and the clock output signal; generating the clock output signal, based on the phase selector output signal, by using the phase mixer; providing the generated clock output signal from the phase mixer to a coarse delay line having a plurality of coarse delay line units wherein the phase mixer does not receive the clock reference signal. 8. The method of claim 7, including fine-shifting with the phase mixer in response to a phase difference between the clock reference signal and the clock output signal that is less than a time delay range of the phase mixer. 9. The method of claim 7, including selecting a local coarse delay unit output signal from a center of the series of local coarse delay units as the phase selector output signal while the clock output signal is phase locking to the clock reference signal. 10. The method of claim 7, including local coarse-shifting with the phase selector to maintain a phase lock of the clock output signal to the clock reference signal. 11. The method of claim 7, including local coarse-shifting with the phase selector in response to a phase difference between the clock reference signal and the clock output signal that is greater than a time delay range of the phase mixer. 12. The method of claim 7, including local coarse-shifting with the phase selector in response to a phase difference between the clock reference signal and the clock output signal that is less than a time delay range of the series of local coarse delay units. 13. The method of claim 7, including remote coarse-shifting with a coarse delay line in response to a phase difference between the clock reference signal and the clock output signal that is greater than a time delay range of the series of local coarse delay units. 14. A delay line system, comprising a coarse delay line, including a coarse delay line input, a number of coarse delay units (CDUs), each with a same particular time delay, and a coarse delay line output connected to an input of an initial local coarse delay unit in a number of local coarse delay units (LCDUs) and connected to a particular input from among a number of inputs of a phase selector; the number of local coarse delay units, connected together in series, each with the same particular time delay, and each with an output connected to a particular input from among the number of inputs of the phase selector; and the phase selector configured to couple a signal from a particular input from among the number of inputs of the phase selector to a phase mixer configured to adjust a particular time delay of the delay line system by fine-shifting, wherein the phase mixer does not receive a clock reference signal provided to at least one of the number of CDUs. 15. The system of claim 14, wherein the number of local coarse delay units is an even number. 16. The system of claim 15, wherein the number of local coarse delay units is two. 17. The system of claim 14, wherein the phase selector is configured to adjust the particular time delay of the delay line system by local coarse-shifting. 18. The system of claim 14, wherein the phase selector is configured to adjust the particular time delay of the delay line system by local coarse-shifting in response to a signal indicating that the phase mixer has fine-shifted to a time delay equal to the same particular time delay of the number of local coarse delay units. 19. The system of claim 14, wherein the phase selector is configured to adjust the particular time delay of the delay line system by local coarse-shifting in response to a signal indicating that the phase mixer has fine-shifted to its full time delay adjustment. 20. The system of claim 19, wherein the coarse delay line is configured to adjust the particular time delay of the delay line system by remote coarse-shifting in response to a signal indicating that the phase selector has local coarse-shifted to its full time delay adjustment. 21. A memory device, comprising: a memory array; a row decoder coupled to the memory array; a column decoder coupled to the memory array; and an input/output (I/O) circuit coupled to the column decoder, wherein the I/O circuit includes a delay line system, configured to generate a clock output signal by adding a delay line system time delay to a clock reference signal, wherein the delay line system includes: a coarse delay line, including a number of coarse delay units, each with a same particular time delay, wherein the coarse delay line is configured to add a coarse delay line time delay to the delay line system time delay, and configured to adjust the coarse delay line time delay by remote coarse-shifting; a number of local coarse delay units, connected together in series, each with the same particular time delay, wherein the number of local coarse delay units are configured to add a local coarse delay unit time delay to the delay line system time delay; a phase selector configured to adjust the local coarse delay unit time delay by local coarse-shifting; and wherein the phase selector is connected to a phase mixer configured to adjust the delay line system time delay by fine-shifting, and wherein the phase mixer does not receive the clock reference signal. 22. The device of claim 21, wherein the I/O circuit includes a control unit to maintain a phase lock of the clock output signal to the clock reference signal by local coarse-shifting. 23. The device of claim 21, wherein the I/O circuit includes a control unit to maintain a phase lock of the clock output signal to the clock reference signal by local coarse-shifting in response to a phase difference between the clock reference signal and the clock output signal that is less than half of a time delay range of the number of local coarse delay units. 24. The device of claim 23, wherein the I/O circuit includes a shift register to maintain a phase lock of the clock output signal to the clock reference signal by remote coarse-shifting in response to a phase difference between the clock reference signal and the clock output signal that is greater than half of the time delay range of the number of local coarse delay units. 25. A method of fabricating a synchronization circuit, comprising: forming a number of coarse delay units (CDUs) in a coarse delay line (CDL) to provide a variable time delay; and forming a number of local coarse delay units (LCDUs), to receive an output of the CDL, proximate to a fine adjust circuit; and wherein forming the number of LCDUs includes forming the number of LCDUs to require a lower power consumption for adding and removing the LCDUs than a power consumption required for adding and removing CDUs in the CDL; and wherein a clock reference signal to be received by at least one of the number of CDUs in the CDL is not received by the fine adjust circuit. 26. The method of claim 25, wherein forming the number of LCDUs includes forming each of the number of LCDUs to provide an equivalent time delay as a CDU in the CDL.