Optical transmitters and receivers using polarization multiplexing

What is claimed is: 1. An optical transmitter, comprising: a laser having an output; an optical beam splitter having an input coupled to the output of the laser and two outputs configured so as to produce first and second optical signals; first and second optical intensity modulators having respective inputs coupled to the outputs of the optical beam splitter and configured to impress multi-level intensity modulation on the first and second optical signals, respectively, based on respective first and second information streams; a phase modulator coupled in line with the second optical intensity modulator and configured to impress a multi-level phase modulation on the second optical signal, using a multi-level phase modulation signal derived from a third information stream; and an optical beam combiner having first and second inputs coupled to receive the intensity-modulated first optical signal and the intensity-and-phase-modulated second optical signal, respectively, and configured to combine the intensity-modulated first optical signal and the intensity-and-phase-modulated second optical signal to produce a polarization-multiplexed optical signal for transmission; wherein the optical transmitter is configured so that the intensity-modulated first optical signal and the intensity-and-phase-modulated second optical signal in the polarization-multiplexed optical signal have first and second optical states of polarization, respectively. 2. The optical transmitter of claim 1 , wherein the optical beam splitter is a polarizing beam splitter configured to produce first and second optical signals having the first and second optical states of polarization, respectively, wherein the first and second optical states of polarization are substantially orthogonal. 3. The optical transmitter of claim 1 , wherein the optical beam splitter is a non-polarizing beam splitter and wherein the optical transmitter further comprises one or more polarization rotators coupled in line with the first or second optical intensity modulators and configured to produce the first and/or second optical states of polarization. 4. The optical transmitter of claim 1 , further comprising first, second, and third driver circuits configured to generate the first, second, and third multilevel modulation signals from respective first, second, and third information streams. 5. An optical receiver, comprising: an optical receiver front-end configured to receive a polarization- multiplexed optical signal and to split the polarization-multiplexed optical signal into sub-components comprising first and second signals, proportional to a time-varying intensity for each of first and second orthogonal states of polarization of the received signal, respectively, and third and fourth signals proportional to S 2 r =2Re{E x r E y r *} and S 3 r =2Im{E x r E y r *}, respectively, where E x r and E y r are complex time-varying values for the first and second orthogonal states of polarization of the received signal, respectively; a digital signal processing circuit operatively coupled to the optical receiver front-end and configured to receive digitized versions of the first, second, third, and fourth signals, said digital signal processing circuit being further configured to implement a matrix arrangement of Finite Impulse Response, FIR, filters receiving the digitized versions of the first, second, third, and fourth signals and to thereby substantially remove polarization rotation induced by transmission of the polarization-multiplexed optical signal from a polarization-division-multiplexing optical transmitter to the optical receiver and estimate first and second information streams used by the polarization-division-multiplexing optical transmitter to intensity-modulate first and second optical states of polarization in the transmitted polarization-multiplexed optical signal. 6. The optical receiver of claim 5 , wherein the matrix of FIR filters comprises four 1×1 FIR filters, inputs to the four 1×1 FIR filters corresponding to a sum of the digitized versions of the first and second signals, a difference between the digitized versions of the first and second signals, the digitized version of the third signal, and the digitized version of the fourth signal, and wherein the digital processing circuit is configured to: obtain an estimate of the first information stream by summing outputs of the four 1×1 FIR filters; and obtain an estimate of the second information stream by summing outputs of three of the four 1×1 FIR filters and subtracting the summed outputs of the three of the four 1×1 FIR filters from the output of the fourth 1×1 FIR filter, the input to the fourth 1×1 FIR filter being the sum of the digitized versions of the first and second signals. 7. The optical receiver of claim 5 , wherein the matrix of FIR filters comprises a 4×4 filter matrix followed by four 1×1 filters coupled to respective outputs of the 4×4 filter matrix, wherein the inputs to the 4×4 filter matrix are coupled to digitized versions of the first, second, third, and fourth signals, respectively, and wherein the digital processing circuit is configured to: obtain an estimate of the first information stream from the output of a first one of the four 1×1 filters; obtain an estimate of the second information stream from the output of a second one of the four 1×1 filters; and obtain an estimate of a third information stream by summing, in a complex fashion, the outputs of the third and fourth ones of the four 1×1 filters and computing the angle of the result, the third information stream corresponding to a time-varying phase difference between the first and second optical states of polarization in the transmitted polarization-multiplexed optical signal, as imposed by a polarization-division-multiplexing optical transmitter. 8. The optical receiver of claim 5 , wherein the digital signal processing circuit is further configured to generate error signals, based on the differences between the outputs of the matrix arrangement and corresponding desired outputs, and to update coefficients of the FIR filters in the matrix arrangement, based on the error signals, so as to reduce subsequent differences between the outputs of the matrix arrangement and the corresponding desired outputs. 9. The optical receiver of claim 8 , where the digital signal processing circuit is configured to initialize the coefficients of the FIR filters using a portion of the received optical signal having training symbols with known values, and to subsequently switch to a decision-directed mode in which the estimates produced by the multi-input filter correspond to information-carrying symbols. 10. The optical receiver of claim 9 , wherein the digital signal processing circuit is configured to generate the error signals during the decision-directed mode by comparing the outputs of the multi-input filter to desired outputs generated from symbol values obtained by making hard-detection decisions from the information signal estimates. 11. A method of generating a modulated optical signal, comprising: impressing a first intensity modulation on a first optical signal, to obtain a first intensity-modulated signal, wherein the first intensity modulation is based on a first modulation signal derived from a first stream of information bits; impressing a second intensity modulation on a second optical signal, to obtain a second intensity-modulated signal, wherein the second intensity modulation is based on a second modulation signal derived from a second stream of information bits; impressing a multi-level phase modulation on the first intensity-modulated signal, to obtain an intensity-modulated