Timing measurement apparatus

What is claimed is: 1. A timing measurement system, comprising: a dispersive device configured to receive an input optical pulse train and to produce a train of pulses that are spectrally dispersed in time domain; a coupler coupled to the dispersive device to receive the train of spectrally dispersed pulses and to produce two outputs; an optical hybrid coupled to a first output of the coupler to receive a first pulse train from the coupler; an optical delay component coupled to a second output of the coupler to provide a second pulse train from the coupler to the optical hybrid, wherein the optical hybrid is configured to produce two or more optical outputs that are each phase shifted with respect to one another based on the first pulse train and the second pulse train; one or more photodetectors coupled to the optical hybrid to convert each of the two or more optical outputs into an associated electrical signal; and one or more analog-to-digital converters coupled to the one or more photodetectors to convert the electrical signals into digital signals, wherein: the one or more analog-to-digital converters are configured to operate at a sample rate that is higher than a repetition rate of the spectrally dispersed pulses, multiple samples that are obtained by the one or more analog-to-digital converters for each pulse correspond to multiple optical frequencies of the pulse, processing of the digital signals enables a determination of timing information of the input optical pulse train and adjustment of the digital signals according to the timing information, and the optical delay component is configured to impart a delay that is larger than or equal to one pulse period. 2. The timing measurement system of claim 1 , including a digital processor configured to process the digital signal, wherein the processing includes processing sample values corresponding to the same pulse to determine a phase offset. 3. The timing measurement system of claim 2 , wherein the phase offset is a function of pulse number, n, and sample points, m, within a single pulse. 4. The timing measurement system of claim 3 , wherein: the optical hybrid is configured to produce two optical outputs that are phase shifted with respect to each other by 90 degrees, and the phase offset, ΔØ(n,m), is determined according to the following relationship: ΔØ( n,m )=α tan 2( P 0° ( n,m ), P 90° ( n,m )), wherein P 0° (n,m) and P 90° (n,m) represent signals associated with the first optical output of the optical hybrid and the second optical output of the optical hybrid. 5. The timing measurement system of claim 2 , wherein the determination of the timing information includes determining a timing error based on determination of a slope of a line that relates optical frequency to phase. 6. The timing measurement system of claim 1 , wherein the determination of the timing information includes determining a timing error for each pulse. 7. The timing measurement system of claim 1 , wherein the optical hybrid is configured to produce two optical outputs that are phase shifted with respect to each other by 90 degrees. 8. The timing measurement system of claim 1 , including an optical source that is configured to produce the input optical pulse train provided to the dispersive device. 9. The timing measurement system of claim 1 , wherein the optical source that is an optical comb source. 10. The timing measurement system of claim 1 , wherein the dispersive device is configured to separate each pulse's optical frequencies temporally. 11. The timing measurement system of claim 1 , wherein the timing measurement system is operable to receive the input optical pulse train from an optical pulse source, and to produce the timing information in real-time on a pulse-by-pulse basis. 12. The timing measurement system of claim 1 , wherein the two or more optical outputs of the hybrid are directly connected to the one or more photodetectors. 13. The timing measurement system of claim 1 , wherein the determination of the timing information includes a determination of timing jitter. 14. A timing measurement system, comprising a dispersive device configured to receive an input optical pulse train and to produce a train of pulses that are spectrally dispersed in time domain; a coupler coupled to the dispersive device to receive the train of spectrally dispersed pulses and to produce two outputs; an optical hybrid coupled to a first output of the coupler to receive a first pulse train from the coupler; an optical delay component coupled to a second output of the coupler to provide a second pulse train from the coupler to the optical hybrid, wherein the optical hybrid is configured to produce two or more optical outputs that are each phase shifted with respect to one another based on the first pulse train and the second pulse train; one or more photodetectors coupled to the optical hybrid to convert each of the two or more optical outputs into an associated electrical signal; and one or more analog-to-digital converters coupled to the one or more photodetectors to convert the electrical signals into digital signals, wherein: the one or more analog-to-digital converters are configured to operate at a sample rate that is higher than a repetition rate of the spectrally dispersed pulses, multiple samples that are obtained by the one or more analog-to-digital converters for each pulse correspond to multiple optical frequencies of the pulse, processing of the digital signals enables a determination of timing information of the input optical pulse train and adjustment of the digital signals according to the timing information, and the two or more optical outputs of the hybrid are coupled to the one or more photodetectors via one or more dispersive elements. 15. The timing measurement system of claim 14 , wherein the optical delay component is configured to impart a delay that is larger than or equal to one pulse period. 16. The timing measurement system of claim 14 , wherein the timing measurement system is operable to receive the input optical pulse train from an optical pulse source, and to produce the timing information in real-time on a pulse-by-pulse basis. 17. The timing measurement system of claim 14 , wherein the determination of the timing information includes determining a timing error for each pulse. 18. A timing measurement system, comprising: a dispersive device configured to receive an input optical pulse train and to produce a train of pulses that are spectrally dispersed in time domain; a coupler coupled to the dispersive device to receive the train of spectrally dispersed pulses and to produce two outputs; an optical hybrid coupled to a first output of the coupler to receive a first pulse train from the coupler; an optical delay component coupled to a second output of the coupler to provide a second pulse train from the coupler to the optical hybrid, wherein the optical hybrid is configured to produce two or more optical outputs that are each phase shifted with respect to one another based on the first pulse train and the second pulse train; one or more photodetectors coupled to the optical hybrid to convert each of the two or more optical outputs into an associated electrical signal; one or more analog-to-digital converters coupled to the one or more photodetectors to convert the electrical signals into digital signals, and a digital processor configured to process the digital signals, wherein: the one or more analog-to-digital converters are configured to operate at a sam