Asymmetric pulse-shaping in digital communication systems

What is claimed is: 1 . A receiver comprising: a detector circuit operable to receive optical signal data from an optical link; and a filter circuit, coupled to the detector circuit, operable to (i) filter the optical signal data according to an asymmetric filtering scheme and (ii) output the filtered optical signal data, wherein the asymmetric filtering scheme comprises utilizing a shaping filter with first criteria, the first criteria including one or more values greater than one or more values of second criteria utilized by a shaping filter at a transmitter, the transmitter communicating with the receiver. 2 . The receiver of claim 1 , wherein the filter circuit is configured to jointly perform the filtering with the transmitter that transmitted the optical signal data over the optical link. 3 . The receiver of claim 1 , wherein the filter circuit comprises at least one of the root-raised cosine filter, a Gaussian filter, and a sinc filter. 4 . The receiver of claim 1 , further comprising: a clock phase detector circuit coupled to the filter circuit, the clock phase detector circuit operable to (i) determine a clock timing associated with the optical signal data and (ii) adjust a sampling time of one or more analog-to-digital converters in the receiver according to the determined clock timing. 5 . The receiver of claim 4 , wherein the clock phase detector circuit is coupled to an input of the filter circuit and is located prior to the filter circuit in the receiver. 6 . The receiver of claim 1 , wherein the first criteria includes a p-value, and the p-value is a degree of freedom of the shaping filter at the receiver, and the p-value is selected to optimize a power distribution between the shaping filter at the receiver and the shaping filter used at the transmitter. 7 . The receiver of claim 1 , wherein the filter circuit comprises a notch detector circuit, and the notch detector circuit is operable to detect a frequency offset associated with the filtered optical signal data. 8 . The receiver of claim 1 , wherein the optical signal data comprises a plurality of subcarriers and a bandwidth of the plurality of subcarriers corresponds to a bandwidth of the optical link. 9 . A receiver comprising: a detector circuit operable to receive optical signal data over an optical link; and a filter circuit operable to filter the optical signal data according to an asymmetric filtering scheme, wherein the filter circuit comprises a notch detector circuit and the notch detector circuit is configured to: detect a frequency offset associated with the filtered optical signal data; and adjust a frequency of an oscillator in the receiver according to the detected frequency offset. 10 . The receiver of claim 9 , further comprising: a clock phase detector circuit coupled to the filter circuit, the clock phase detector circuit operable to (i) determine a clock timing associated with the optical signal data and (ii) adjust a sampling time of one or more analog-to-digital converters in the receiver according to the determined clock timing. 11 . The receiver of claim 10 , wherein the clock phase detector circuit is coupled to an input of the filter circuit and is located prior to the filter circuit in the receiver. 12 . The receiver of claim 9 , wherein the filter circuit is configured to jointly perform the filtering with a transmitter that transmitted the optical signal data over the optical link. 13 . The receiver of claim 9 , wherein the asymmetric filtering scheme comprises utilizing a shaping filter with first criteria, the first criteria including one or more values greater than one or more values of second criteria utilized by a shaping filter at a transmitter, the transmitter communicating with the receiver. 14 . The receiver of claim 13 , wherein the first criteria includes a p-value, and the p-value is a degree of freedom of the shaping filter at the receiver, and the p-value is selected to optimize a power distribution between the shaping filter at the receiver and the shaping filter used at the transmitter, the receiver configured to communicate with the transmitter. 15 . The receiver of claim 9 , wherein the shaping filter comprises at least one of a root-raised cosine filter, a Gaussian filter, and a sinc filter. 16 . A system comprising: a device for communicating with one or more other devices using subcarrier signals, the device comprising: one or more filter circuits configured to (i) filter data indicative of each subcarrier signal of the subcarrier signals according to an asymmetric filtering scheme, the asymmetric filtering scheme implemented based on a degree of freedom value, and (ii) output the filtered data indicative of the subcarrier signal. 17 . The system of claim 16 , wherein the asymmetric filtering scheme comprises utilizing a shaping filter with first criteria, the first criteria including one or more values greater than one or more values of second criteria utilized by a shaping filter at another device, the other device communicates with the device. 18 . The system of claim 16 , wherein the asymmetric filtering scheme comprises utilizing a shaping filter with first criteria, the first criteria including one or more values less than one or more values of second criteria utilized by a shaping filter at another device, the other device communicates with the device. 19 . The system of claim 16 , wherein the filter circuit comprises at least one of the root-raised cosine filter, a Gaussian filter, and a sinc filter. 20 . The system of claim 16 , wherein the filter circuit is configured to jointly perform the filtering with the one or more other devices using the asymmetric filtering scheme over an optical link.