초록

Delay circuitry is described that includes clock mixing circuitry to provide a selectable propagation time. Output signals from the mixing circuitry are selectively coupled through a variable delay line to synchronize two clock signals.

대표청구항 ▼

The invention claimed is: 1. A delay circuit comprising: first and second delay elements, each having a propagation delay time T, wherein the first delay element propagates either an output signal from the second delay element or an output signal from a first mixing circuit to an output node, where

The invention claimed is: 1. A delay circuit comprising: first and second delay elements, each having a propagation delay time T, wherein the first delay element propagates either an output signal from the second delay element or an output signal from a first mixing circuit to an output node, wherein the second delay element propagates an output signal from a second mixing circuit; and a control circuit to select the output signal from the second delay element or the output signal from the first mixing circuit to propagate through the first delay element, wherein each mixing circuit comprises; a first input to receive a first clock signal; a second input to receive a second clock signal, the second clock signal being a time delayed version of the first clock signal such that corresponding edge transitions of the first and second clock signals are separated by a time T; and an output to provide as the output signal from the mixing circuit a mixed clock signal that is a time delayed version of the first clock signal such that corresponding edge transitions of the first clock signal and the mixed clock signal are separated by a time selected from zero to T by providing a continuously variable time delay value to each of the mixing circuits. 2. The delay circuit of claim 1 wherein the control circuitry comprises: a phase detector circuit to compare first and second clock signals; and a shift register coupled to the phase detector circuit and the first and second delay elements. 3. A delay lock loop (DLL) circuit to synchronize an internal clock signal to an external clock signal, the circuit comprising: a plurality of delay line units coupled in series such that an output signal of a first delay line unit is coupled to a first input node of a second delay line unit, each of the plurality of delay line units include a second input node, further wherein each delay line unit has an internal propagation signal delay time of T such that a signal on either the first or second input propagates to an output of the delay line unit in time T; a shift register to selectively enable one or more of the plurality of delay line units, and wherein the shift register further selectively enables either the first or second input nodes of the one or more of the plurality of delay units; and a first mixer circuit or a second mixer circuit coupled to the second input of the plurality of delay units, wherein each mixer circuit has a selectable internal propagation delay time determined by a continuously variable time delay value provided to the first mixer circuit or the second mixer circuit. 4. The DLL circuit of claim 3 further comprises a phase detector coupled to control the shift register. 5. The DLL circuit of claim 3 wherein each mixer circuit comprises: a first input to receive a first clock signal, the first clock signal being a time delayed version of the external clock signal such that corresponding edge transitions of the first clock signal and the external clock signal are separated by a time T; a second input to receive a second clock signal, the second clock signal being a time delayed version of the external clock signal such that corresponding edge transitions of the first clock signal and the external clock signal are separated by a time 2T; and an output to provide a mixed clock signal that is a time delayed version of the external clock signal such that corresponding edge transitions of the external clock signal and the mixed clock signal are separated by a time selected from T to 2T. 6. The DLL circuit of claim 5 wherein each mixer circuit comprises: a first plurality of parallel coupled inverters located between the first input and the output of the mixer circuit; and a second plurality of parallel coupled inverters located between the second input and the output of the mixer circuit, wherein the first and second plurality of inverters are separately controllable to change a propagation time of the first and second plurality of inverters. 7. A delay lock loop (DLL) circuit comprising: a shift register; first and second initial delay circuits, each having an internal propagation delay time of T, wherein an input node to the first initial delay circuit is coupled to receive an input clock signal and provide a first time delayed output clock signal, the first time delayed output clock signal is coupled as an input signal to the second initial delay circuit; a first mixing circuit to provide a first mixed output signal based upon the first time delayed output clock signal and a second time delayed output clock signal from the second initial delay circuit, the first mixing circuit has a controllable internal propagation time; a second mixing circuit to provide a second mixed output signal based upon the first time delayed output clock signal and the second time delayed output clock signal, the second mixing circuit has a controllable internal propagation time; a delay line having a plurality of delay line circuits coupled in series, each of the plurality of delay line circuits have first and second input nodes, wherein the second input node is coupled to receive either the first or second mixed output signal, wherein the shift register selectively enables the delay line circuits. 8. The DLL circuit of claim 7 wherein the first and second mixer circuits each comprise: a first input to receive the first time delayed output clock signal; a second input to receive the second time delayed output clock signal; and an output to provide a mixed clock signal that is a time delayed version of the input clock signal such that corresponding edge transitions of the input clock signal and the mixed clock signal are separated by a time selected from T to 2T. 9. The DLL circuit of claim 7 wherein the first and second mixer circuits have inverse propagation times such that a mixed clock signal from the first mixer circuit is separated from the input clock by time T when a mixed clock signal from the second mixer circuit is separated from the input clock by time 2T. 10. The DLL circuit of claim 7 wherein the first and second mixer circuits each comprise: a first plurality of parallel coupled inverters located between the first input and the output of the mixer circuit; and a second plurality of parallel coupled inverters located between the second input and the output of the mixer circuit, wherein the first and second plurality of inverters are separately controllable to change a propagation time of the first and second plurality of inverters. 11. A memory device comprising: an array of memory cells; an input to receive an external clock signal; a control circuit to perform operations on the array of memory cells and provide output from the memory device in synchronization with transitions of the external clock signal; and a delay lock loop (DLL) circuit to synchronize an internal clock signal to the externally provided clock signal, the DLL circuit comprising: a plurality of delay line units coupled in series such that an output signal of a first delay line unit is coupled to a first input node of a second delay line unit, each of the plurality of delay line units include a second input node, further wherein each delay line unit has an internal propagation signal delay time of T such that a signal on either the first or second input propagates to an output of the delay line unit in time T; a shift register to selectively enable one or more of the plurality of delay line units, and wherein the shift register further selectively enables either the first or second input nodes of the one or more of the plurality of delay units; and a first mixer circuit or a second mixer circuit coupled to the second input of the plurality of delay units, wherein each mixer circuit has a selectable internal propagation delay time that is determined by a continuously variable time delay value provided to the first mixer circuit or the second mixer circuit. 12. The memory device of claim 11 wherein the array of memory cells are volatile memory cells. 13. The memory device of claim 11 further comprises a phase detector coupled to control the shift register. 14. The memory device of claim 11 wherein he each mixer circuit comprises: a first input to receive a first clock signal, the first clock signal being a time delayed version of the external clock signal such that corresponding edge transitions of the first clock signal and the external clock signal are separated by a time T; a second input to receive a second clock signal, the second clock signal being a time delayed version of the external clock signal such that corresponding edge transitions of the second clock signal and the external clock signal are separated by a time 2T; and an output to provide a mixed clock signal that is a time delayed version of the external clock signal such that corresponding edge transitions of the external clock signal and the mixed clock signal are separated by a time selected from T to 2T. 15. The memory device of claim 14 wherein each mixer circuit comprises: a first plurality of parallel coupled inverters located between the first input and the output of the mixer circuit; and a second plurality of parallel coupled inverters located between the second input and the output of the mixer circuit, wherein the first and second plurality of inverters are separately controllable to change a propagation time of the first and second plurality of inverters. 16. A delay circuit comprising: a plurality of delay elements D1, D2, D3 and D4, each delay element has first and second inputs and an output, wherein the output of D4 is coupled to the first input of D3, the output of D3 is coupled to the first input of D2, and the output of D2 is coupled to the first input of D1; the second input of D1 and D3 are coupled to receive a signal from a first mixer circuit; the second input of D2 and D4 are coupled to receive a signal from a second mixer circuit, the first mixer circuit and the second mixer circuit being configured to provide a continuous internal time delay based upon a control value provided to the first mixer circuit and the second mixer circuit; and control circuitry coupled to the plurality of delay elements to selectively enable D1, D2, D3 and D4. 17. A method of operating a delay line circuit comprising: mixing first and second clock signals to provide a third clock signal, wherein the first clock signal is delayed from an input clock signal by one delay unit, U, the second clock signal is delayed from the input clock signal by two delay units, 2U, and the third clock signal is delayed from the input clock signal by a selectable delay between U and 2U; mixing the first and second clock signals to provide a fourth clock signal, wherein the fourth clock signal is delayed from the input clock signal by a selectable delay between 2U and U, the third and fourth clock signals are inverse such that the third clock signal has a delay of U when the fourth clock signal has a delay of 2U; and selectively coupling the third and fourth clock signals to inputs of a delay line circuit. 18. A method of operating a delay line circuit comprising operating a first delay element D1 to couple an output signal from a first mixing circuit on a first input of the first delay element to an output of the first delay element; operating a second delay element D2 to couple an output signal from a second mixing circuit on a first input of the second delay element to an output of the second delay element, wherein the output of the second delay element is coupled to a second input of the first delay element, wherein the first mixer circuit and the second mixer circuit are configured to provide a continuous internal time delay based upon a control value provided to the first mixer circuit and the second mixer circuit; and when operating the second delay element, operating the first delay element D1 to decouple the first input of the first delay element from the output of the first delay element, and couple the second input of the first delay element to the output of the first delay element.