초록 ▼

A circuit for performing clock recovery according to a received digital signal 30. The circuit includes at least an edge sampler 105 and a data sampler 145 for sampling the digital signal, and a clock signal supply circuit. The clock signal supply circuit provides edge clock 25 and data clock 20 sig

A circuit for performing clock recovery according to a received digital signal 30. The circuit includes at least an edge sampler 105 and a data sampler 145 for sampling the digital signal, and a clock signal supply circuit. The clock signal supply circuit provides edge clock 25 and data clock 20 signals offset in phase from one another to the respective clock inputs of the edge sampler 105 and the data sampler 145. The clock signal supply circuit is operable to selectively vary a phase offset between the edge and data clock signals.

대표청구항 ▼

1. A circuit for receiving a digital signal comprising: at least three samplers for sampling the digital signal, each sampler having a clock input, wherein the samplers include an edge sampler and a data sampler and an adaptive sampler; anda clock signal supply circuit for providing respective clock

1. A circuit for receiving a digital signal comprising: at least three samplers for sampling the digital signal, each sampler having a clock input, wherein the samplers include an edge sampler and a data sampler and an adaptive sampler; anda clock signal supply circuit for providing respective clock signals to respective clock inputs of the samplers, wherein each pair of at least two distinct pairs of said clock signals has a relative phase between the two clock signals making up the pair, and wherein the clock signal supply circuit is operative to selectively vary the relative phase for a first pair of said clock signals and to selectively vary the relative phase for a second pair of said clock signals. 2. The circuit of claim 1, wherein the clock signals include a data clock signal, an edge clock signal and an adaptive clock signal, and the clock signal supply circuit includes a clock signal phase adjustment circuit operative to adjust the phase of the edge clock signal and the phase of the data clock signal responsive to a phase adjustment signal. 3. The circuit of claim 2, wherein the clock signal phase adjustment circuit includes a register for storing a phase value and incrementing or decrementing the phase value responsive to the phase adjustment signal, a data clock phase shifter and an edge clock phase shifter, the clock signal supply circuit including a summer for adding a selectively adjustable offset to the phase value, one of the phase shifters having a control input connected to the summer, the other one of the phase shifters having a control input connected to the register. 4. The circuit of claim 2, wherein the clock signal phase adjustment circuit includes a register operative to hold a phase value and increment or decrement the phase value responsive to the phase adjustment signal, a data clock phase shifter, an edge clock phase shifter, and an adaptive clock phase shifter, each phase shifter having a control input, and a plurality of adders, connected to the register, to add offset values to the phase value, the control input of at least two of the phase shifters being connected to a corresponding adder of the plurality of adders. 5. The circuit of claim 4, wherein the plurality of adders includes a data clock adder and an adaptive clock adder, the control inputs of the data clock phase shifter and adaptive clock phase shifter being connected to the data clock adder and adaptive clock adder, respectively, the control input of the edge clock phase shifter being connected to the register. 6. The circuit of claim 1, wherein the clock signals include a data clock signal, an edge clock signal and an adaptive clock signal, wherein the data sampler is responsive to the data clock signal, the edge sampler is responsive to the edge clock signal, and the adaptive sampler is responsive to the adaptive clock signal, wherein the clock signal supply circuit is operative to selectively vary the relative phase between the data clock signal and the adaptive clock signal, and wherein the clock signal supply circuit is operative to selectively vary the relative phase between the edge clock signal and the data clock signal. 7. The circuit of claim 1, wherein the clock signals include a data clock signal, an edge clock signal and an adaptive clock signal, wherein the data sampler is responsive to the data clock signal, the edge sampler is responsive to the edge clock signal, and the adaptive sampler is responsive to the adaptive clock signal, and wherein the clock signal supply circuit is operative to selectively vary at least one of the relative phase between the data clock signal and the adaptive clock signal, and the relative phase between the edge clock signal and the data clock signal. 8. The circuit of claim 7, wherein the clock signal supply circuit includes a clock signal phase adjustment circuit operative to adjust at least one of the phase of the edge clock signal, the phase of the data clock signal and the phase of the adaptive clock signal responsive to a phase adjustment signal. 9. The circuit of claim 8, wherein the clock signal phase adjustment circuit includes a register operative to hold a phase value and increment or decrement the phase value responsive to one of the phase adjustment signals, a data clock phase shifter, an edge clock phase shifter, and an adaptive clock phase shifter, each phase shifter having a control input, and a plurality of adders, connected to the register, to add offset values to the phase value, the control input of at least two of the phase shifters being connected to a corresponding adder of the plurality of adders. 10. The circuit of claim 9, wherein the plurality of adders includes a data clock adder and an adaptive clock adder, the control input of the data clock phase shifter being connected to the data clock adder, the control input of the adaptive clock phase shifter being connected to the adaptive clock adder, and the control input of the edge clock phase shifter being connected to the register. 11. A method of receiving a digital signal comprising: providing, using a clock signal supply circuit, respective clock signals to respective clock inputs of at least three samplers for sampling the digital signal, each sampler having a clock input, wherein the samplers include an edge sampler and a data sampler and an adaptive sampler, wherein each pair of at least two distinct pairs of said clock signals has a relative phase between the two clock signals making up the pair, and wherein the clock signal supply circuit is operative to selectively vary the relative phase for a first pair of said clock signals and to selectively vary the relative phase for a second pair of said clock signals. 12. The method of claim 11, wherein the clock signals include a data clock signal, an edge clock signal and an adaptive clock signal, wherein the clock signal supply circuit includes a clock signal phase adjustment circuit, and wherein the method includes adjusting, using the clock signal phase adjustment circuit, the phase of the edge clock signal and the phase of the data clock signal responsive to a phase adjustment signal. 13. The method of claim 12, wherein the clock signal phase adjustment circuit includes a register, a data clock phase shifter, and an edge clock phase shifter, wherein the clock signal supply circuit includes a summer, and wherein the method includes: storing, in the register, a phase value, and incrementing or decrementing the phase value responsive to the phase adjustment signal; andadding, using the summer, a selectively adjustable offset to the phase value;wherein one of the phase shifters has a control input connected to the summer, and the other one of the phase shifters has a control input connected to the register. 14. The method of claim 12, wherein the clock signal phase adjustment circuit includes a register, a data clock phase shifter, an edge clock phase shifter, and an adaptive clock phase shifter, each phase shifter having a control input, and a plurality of adders, connected to the register, the control input of at least two of the phase shifters being connected to a corresponding adder of the plurality of adders, and the method includes: storing, in the register, a phase value, and incrementing or decrementing the phase value responsive to the phase adjustment signal; andadding respective offset values to the phase value using the plurality of adders. 15. The method of claim 14, wherein the plurality of adders includes a data clock adder and an adaptive clock adder, the control inputs of the data clock phase shifter and adaptive clock phase shifter being connected to the data clock adder and adaptive clock adder, respectively, the control input of the edge clock phase shifter being connected to the register. 16. The method of claim 11, wherein the clock signals include a data clock signal, an edge clock signal and an adaptive clock signal, wherein the data sampler is responsive to the data clock signal, the edge sampler is responsive to the edge clock signal, and the adaptive sampler is responsive to the adaptive clock signal, and wherein the method includes: selectively varying the relative phase between the data clock signal and the adaptive clock signal using the clock signal supply circuit; andselectively varying the relative phase between the edge clock signal and the data clock signal using the clock signal supply circuit. 17. The method of claim 11, wherein the clock signals include a data clock signal, an edge clock signal and an adaptive clock signal, wherein the data sampler is responsive to the data clock signal, the edge sampler is responsive to the edge clock signal, and the adaptive sampler is responsive to the adaptive clock signal, and wherein the method includes selectively varying at least one of the relative phase between the data clock signal and the adaptive clock signal, and the relative phase between the edge clock signal and the data clock signal, using the clock signal supply circuit. 18. The method of claim 17, wherein the clock signal supply circuit includes a clock signal phase adjustment circuit, and the method includes adjusting, using the clock signal phase adjustment circuit, at least one of the phase of the edge clock signal, the phase of the data clock signal and the phase of the adaptive clock signal responsive to a phase adjustment signal. 19. The method of claim 18, wherein the clock signal phase adjustment circuit includes a register, a data clock phase shifter, an edge clock phase shifter, and an adaptive clock phase shifter, each phase shifter having a control input, and a plurality of adders, connected to the register, the control input of at least two of the phase shifters being connected to a corresponding adder of the plurality of adders, and the method includes: storing, in the register, a phase value, and incrementing or decrementing the phase value responsive to one of the phase adjustment signals; andadding respective offset values to the phase value using the plurality of adders. 20. The method of claim 19, wherein the plurality of adders includes a data clock adder and an adaptive clock adder, the control input of the data clock phase shifter being connected to the data clock adder, the control input of the adaptive clock phase shifter being connected to the adaptive clock adder, and the control input of the edge clock phase shifter being connected to the register.