Polarization insensitive self-homodyne detection receiver for spatial-division multiplexing systems

The invention claimed is: 1. A self-homodyne detection (SHD) receiver comprising: a first polarization beam splitter ( 11 ) which separates an input signal R 1 in two orthogonal polarization components of the input signal R 1 x , R 1 y; a second polarization beam splitter ( 13 ) which separates a pilot tone R 0 in two orthogonal polarization components of the pilot tone R 0 x and R 0 y; a first separator ( 15 ) which separates one of the orthogonal polarization components of the input signal R 1 x in two components R 1 x′; a second separator ( 17 ) which separates another orthogonal polarization component of the input signal R 1 y in two components R 1 y′; a third separator ( 19 ) which separates one of the orthogonal polarization components of the pilot tone R 0 x in two components R 0 x′; a fourth separator ( 21 ) which separates another orthogonal polarization component of the pilot tone R 0 y in two components R 0 y′; a first 90-degree polarization rotator ( 23 ) which aligns polarization of R 0 x ′ with that of R 1 y ′ to obtain aligned component R 0 x″; a second 90-degree polarization rotator ( 25 ) which aligns polarization of R 0 y ′ with that of R 1 x ′ to obtain aligned component R 0 y″; a first hybrid detector ( 31 ) that couples the components R 1 x ′ and R 0 x ′ and outputs electric signals that correspond to real and imaginary parts of Rc, the Rc being an interference signal of the components R 1 x ′ and R 0 x′; a second hybrid detector ( 33 ) that couples the components R 1 x ′ and R 0 y ″ and outputs electric signals that correspond to real and imaginary parts of Rd, the Rd being an interference signal of the components R 1 x ′ and R 0 y″; a third hybrid detector ( 35 ) that couples the components R 1 y ′ and R 0 x ″ and outputs electric signals that correspond to real and imaginary parts of Re, the Re being an interference signal of the components R 1 y ′ and R 0 x″; a fourth hybrid detector ( 37 ) that couples the components R 1 y ′ and R 0 y ′ and outputs electric signals that correspond to real and imaginary parts of Rf, the Rf being an interference signal of the components R 1 y ′ and R 0 y′; a signal processor ( 39 ) which receives the real and imaginary parts of Rc, Rd, Re and Rf and reconstructs complex signals Rx and Ry, the Rx and Ry corresponding to an information signal used to generate the input signal R 1 . 2. The self-homodyne detection (SHD) receiver in accordance with claim 1 , wherein the first hybrid detector ( 31 ) comprises a 90-degree hybrid 41 , a first set of two photodetectors ( 43 a ) in a balanced configuration and a second set of two photodetectors ( 43 b ) in a balanced configuration, wherein the 90-degree hybrid ( 41 ) comprises: a first splitter ( 51 ), which divides R 1 x ′ into two components R 1 x′a and R 1 x′b; a second splitter ( 53 ), which divides R 0 x ′ into two components R 0 x′a and R 0 x′b; a 90 degree phase shifter ( 55 ), which shifts a phase of R 1 x′a by 90 degrees to obtain a phase shifted signal R 1 x′a′; a first 2×2 coupler ( 57 ), which combines the signal R 0 x′a and the phase shifted signal R 1 x′a ′ to generate optical signals R 1 xa and R 1 xb , which are proportional to jR 0 x′a +j R 1 x′a ′ and −R 0 x′a +R 1 x′a ′, respectively; and a second 2×2 coupler ( 59 ), which combines the signal R 1 x′b and the signal R 0 x′b to generate optical signals R 0 xa and R 0 xb , which are proportional to j R 1 x′b −R 0 x′b and −R 1 x′b +j R 0 x′b , respectively; wherein the first set of two photodetectors 43 a detects the electrical signals R 1 xa and R 1 xb and outputs a first electrical signal Rcr, Rcr resulting from the difference between the instantaneous powers of the optical signals R 1 xa and R 1 xb and being proportional to the real part of R 1 x′a ′×R 0 x′a*; wherein the second set of two photodetectors 43 b detects the signals R 0 xa and R 0 xb and outputs a second electrical signal Rci, Rci resulting from the difference between the instantaneous powers of the optical signals R 0 xa and R 0 xb and being proportional to the imaginary part of R 1 x′b ×R 0 x′b *, and wherein the Rcr is a real part of the Rc and the Rci is an imaginary part of Rc. 3. A self-homodyne detection (SHD) receiver comprising: a first separator ( 61 ) which separates an input signal R 1 in two same components R 1 ′; a second separator ( 63 ) which separates a pilot tone R 0 in two same components R 0 ′; a 90-degree polarization rotator ( 65 ) which modifies polarization of the component R 0 ′ by 90 degrees to obtain aligned component R 0 ″; a first hybrid detector ( 67 ) that couples the components R 1 ′ and R 0 ′ and outputs electric signals that correspond to real and imaginary parts of Ra, the Ra being an interference signal of the components R 1 ′ and R 0 ′; a second hybrid detector ( 69 ) that couples the components R 1 ′ and R 0 ″ and outputs electric signals that correspond to real and imaginary parts of Rb, the Rb being an interference signal of the components R 1 ′ and R 0 ″; and a signal processor ( 71 ) which receives the real and imaginary parts of Ra and Rb and reconstructs complex signals Rx and Ry, the Rx and Ry corresponding to an information signal used to generate the input signal R 1 . 4. A self-homodyne detection (SHD) receiver comprising: a first separator ( 61 ) which separates an input signal R 1 in two same components R 1 ′; a second separator ( 63 ) which separates a pilot tone R 0 in two same components R 0 ′; a 90-degree polarization rotator ( 65 b ) which modifies polarization of the component R 1 ′ by 90 degrees to obtain aligned component R 1 ″; a first hybrid detector ( 67 b ) that couples the components R 1 ′ and R 0 ′ and outputs electric signals that correspond to real and imaginary parts of Ra′, the Ra′ being an interference signal of the components R 1 ′ and R 0 ′; a second hybrid detector ( 69 b ) that couples the components R 1 ″ and R 0 ′ and outputs electric signals that correspond to real and imaginary parts of Rb′, the Rb′ being an interference signal of the components R 1 ″ and R 0 ′; and a signal processor ( 71 b ) which receives the real and imaginary parts of Ra′ and Rb′ and reconstructs complex signals Rx and Ry, the Rx and Ry corresponding to an information signal used to generate the input signal R 1 .