Systems and methods for high precision cable length measurement in a communication system

What is claimed is: 1. A method for cable length measurement in a communication system, the method comprising: transmitting, at a transmitter, a plurality of data symbols at a first data rate via a wired data communication link; in response to the transmitting, receiving, at a receiver, a reflection signal from the wired data communication link; obtaining, at a signal sampler, a phase shift number of shifting sampling phases for sampling the received reflection signal; sampling, at the sampler, the received reflection signal based on the phase shift number of shifting sampling phases to generate reflection samples, each reflection sample corresponding to a sampled value of the received reflection signal shifted by a sampling phase from the phase shift number of shifting sampling phases; combining the reflection samples with different sampling phases to generate a phase shift number of reflection samples corresponding to a second data rate higher than the first data rate; for each data symbol of the plurality of data symbols, generating a phase shift number of data symbols with different shifted phases corresponding to the phase shift number of shifting sampling phases, and for each respective data symbol of the phase shift number of data symbols, subtracting the respective data symbol from a respective reflection sample of the phase shift number of reflection samples, respectively, to obtain a plurality of reflection response samples at the second data rate; determining, at a cable length calculation unit, a delay parameter indicative of a transmission time for a signal to transmit from the transmitter to an end of the wired data communication link based on values of the plurality of reflection response samples of reflection response samples; and generating, at the cable length calculation unit, an estimate of a length of the data communication link based at least in part on the determined delay parameter. 2. The method of claim 1 , further comprising: detecting a first timestamp corresponding to a center of a mass of the plurality of reflection response samples; identifying a second timestamp of a data symbol corresponding to the center of the mass; and generating the delay parameter by comparing the first timestamp and the second timestamp. 3. The method of claim 1 , further comprising: calculating the estimate of the length of the data communication link by multiplying a constant signal transmission speed with the delay parameter associated with the plurality of reflection response samples, wherein the estimate of the length has a resolution that is substantially equivalent to a length estimate based on data transmission at the second data rate. 4. The method of claim 1 , further comprising: shifting a phase of a data symbol from among the plurality of data symbols with the phase shift number of shifting sampling phases to generate a series of data symbols; and transmitting the series of data symbols at the second data rate. 5. The method of claim 4 , further comprising: sampling the reflection signal based on a set of shift sampling phases different from the phase shift number of shift sampling phases to obtain a different set of reflection samples; and generating a different estimate of the length of the data communication link based at least in part on the different set of reflection response samples. 6. The method of claim 5 , further comprising: increasing the number of the set of shift sampling phases for sampling to increase measurement resolution of the set of shift sampling phases. 7. The method of claim 1 , further comprising: removing reflection noise from the plurality of reflection samples; adapting reflection coefficients associated with the plurality of reflection samples; and combining the plurality of reflection samples to obtain a plurality of multi-phase reflection response samples, wherein the plurality of multi-phase reflection samples have the second data rate. 8. The method of claim 1 , further comprising: applying a matching filter to the reflection signal to reduce reflection tail noise, wherein the matching filter increases a signal-to-noise ratio of the analog reflection signal. 9. The method of claim 8 , further comprising: determining a plurality of matching filter coefficients based at least in part on a shape characteristic of the reflection signal at an end of the data communication link, a connector reflection or a bus interface network of the wired data communication link. 10. The method of claim 9 , further comprising: dynamically updating the plurality of matching filter coefficients based at least in part on a shape of the reflection signal to reduce reflection tail noise. 11. A system for cable length measurement in a communication system, the system comprising: a transmitter configured to transmit a plurality of data symbols at a first data rate via a wired data communication link; a receiver configured to, in response to the transmitting, receive a reflection signal from the wired data communication link; a signal sampler configured to: obtain a phase shift number of shifting sampling phases for sampling the received reflection signal, sample the received reflection signal using the phase shift number of shifting sampling phases to generate reflection samples, each reflection sample corresponding to a sampled value of the received reflection signal shifted by a sampling phase from the phase shift number of shifting sampling phases, and combine the reflection samples with different sampling phases to generate a series of reflection samples corresponding to a second data rate higher than the first data rate; a reflection canceller configured to: for each data symbol of the plurality of data symbols, generating a phase shift number of data symbols with different shifted phases corresponding to the phase shift number of shifting sampling phases, and for each respective data symbol of the phase shift number of data symbols, subtracting the respective data symbol from a respective reflection sample from the phase shift number of reflection samples, respectively, to obtain a plurality of reflection response samples at the second data rate; and a cable length calculation unit configured to determine a delay parameter from the plurality of reflection response samples, and generate an estimate of a length of the data communication link based at least in part on the delay parameter. 12. The system of claim 11 , wherein the cable length calculator is further configured to: detect a first timestamp corresponding to a center of a mass of the plurality of reflection response samples; identify a second timestamp of a data symbol corresponding to the center of the mass; and generate the delay parameter by comparing the first timestamp and the second timestamp. 13. The system of claim 11 , wherein the cable length calculator is further configured to: calculate the estimate of the length of the data communication link by multiplying a constant signal transmission speed with the delay parameter associated with the plurality of reflection response samples, wherein the estimate of the length has a resolution that is substantially equivalent to a length estimate based on data transmission at the second data rate. 14. The system of claim 11 , wherein the transmitter is further configured to: shift a phase of a data symbol from among the plurality of data symbols with the phase shift number of shifting sampling phases to generate a series of data symbols; and transmit the series of data symbols at the second data rate. 15. The system o