Optical circulators integrated into transceivers

What is claimed is: 1. An optical circulator integrated into a transceiver to achieve bi-directional communication in a fiber optic communication network, the optical circulator comprising: a bi-directional propagation core configured to pass a transmission signal in a transmit direction and a received signal in a receive direction, the bi-directional propagation core including: a first polarization beam splitter (PBS); a first polarization shifting assembly optically coupled to the first PBS; a second PBS optically coupled to the first polarization shifting assembly; a second polarization shifting assembly optically coupled to the second PBS; and a third PBS optically coupled to the second polarization shifting assembly; wherein the first polarization shifting assembly is located between the first PBS and the second PBS, and the second polarization shifting assembly is located between the second PBS and the third PBS; wherein the bi-directional propagation core passes the received signal from the first PBS to the third PBS through the first polarization shifting assembly, the second PBS, and the second polarization shifting assembly; wherein the bi-directional propagation core passes the transmission signal from the second PBS to the first PBS through the first polarization shifting assembly; an input port optically coupled to the second PBS of the bi-directional propagation core, the input port configured to deliver the transmission signal to the second PBS; an output port optically coupled to the third PBS of the bi-directional propagation core, the output port configured to receive the received signal from the third PBS; and a network port optically coupled to the first PBS of the bi-directional propagation core, the network port configured to receive the transmission signal from the first PBS and deliver the transmission signal to a fiber optic cable, the network port further configured to receive the received signal from the fiber optic cable and deliver the received signal to the first PBS. 2. The optical circulator of claim 1 , wherein the first polarization shifting assembly includes a first wave plate optically coupled to the first PBS, a second wave plate optically coupled to the first PBS, and a Faraday rotator optically coupled to the first wave plate, the second wave plate, and the second PBS. 3. The optical circulator of claim 2 , wherein: the received signal includes an unpolarized light beam; the first PBS splits the unpolarized light beam into a first beam component with a first polarization state and a second beam component with a second polarization state that is orthogonal to the first polarization state; the first PBS passes the first beam component to the first wave plate and the second beam component to the second wave plate; the first wave plate and the Faraday rotator through which the first beam component propagates are configured to rotate the first beam component from the first polarization state to the second polarization state; and the second wave plate and the Faraday rotator through which the second beam component propagates are configured to maintain the second beam component in the second polarization state. 4. The optical circulator of claim 3 , wherein the first beam component and the second beam component propagate through the first PBS, the Faraday rotator, the second PBS, and the third PBS in common. 5. The optical circulator of claim 3 , wherein: the second polarization shifting assembly includes a third wave plate and a fourth wave plate that are optically coupled to the second PBS and the third PBS; the third wave plate through which the first beam component propagates is configured to rotate the first beam component from the second polarization state to the first polarization state; and the fourth wave plate through which the second beam component propagates is configured to maintain the second beam component in the second polarization state. 6. The optical circulator of claim 5 , wherein: the third PBS aggregates the first beam component that propagates through the third wave plate and the second beam component that propagates through the fourth wave plate; and the third PBS passes the aggregated first beam component and second beam component to the output port. 7. The optical circulator of claim 2 , wherein: the transmission signal from the input port includes a linear polarized light beam; the second PBS passes the linear polarized light beam to the Faraday rotator; the Faraday rotator and the second wave plate through which the linear polarized light beam propagates are configured to rotate a polarization state of the linear polarized light beam by 90 degrees; and the first PBS passes the linear polarized light beam received from the second wave plate to the network port. 8. The optical circulator of claim 2 , wherein the first wave plate is oriented at about 22.5 degrees and the second wave plate is oriented at about 67.5 degrees in a common coordinate system. 9. The optical circulator of claim 1 , further comprising an optical isolator, wherein the optical isolator is located between the input port and the second PBS and is configured to pass the transmission signal from the input port to the second PBS. 10. The optical circulator of claim 9 , wherein the optical isolator includes a free space isolator. 11. An optical circulator integrated into a transceiver to achieve bi-directional communication in a fiber optic network, the optical circulator comprising: a bi-directional propagation core configured to pass a transmission signal in a transmit direction and a receive signal in a receiving direction, the bi-directional propagation core including: a first polarization beam splitter (PBS); a first polarization shifting assembly optically coupled to the first PBS; a second PBS optically coupled to the first polarization shifting assembly; a second polarization shifting assembly optically coupled to the second PBS; a third PBS optically coupled to the second polarization shifting assembly; a third polarization shifting assembly optically coupled to the second PBS; and a fourth PBS optically coupled to the third polarization shifting assembly; wherein the bi-directional propagation core passes the received signal from the first PBS to the third PBS through the first polarization shifting assembly, the second PBS, and the second polarization shifting assembly; wherein the bi-directional propagation core passes the transmission signal from the fourth PBS to the first PBS through the third polarization shifting assembly, the second PBS, and the first polarization shifting assembly; an input port optically coupled to the fourth PBS of the bi-directional propagation core, the input port configured to deliver the transmission signal to the fourth PBS; an output port optically coupled to the third PBS of the bi-directional propagation core, the output port configured to receive the received signal from the third PBS; and a network port optically coupled to the first PBS of the bi-directional propagation core, the network port configured to receive the transmission signal from the first PBS and deliver the transmission signal to a fiber optic cable, the network port further configured to receive the received signal from the fiber optic cable and deliver the received signal to the first PBS. 12. The optical circulator of claim 11 , wherein the first polarization shifting assembly includes a first wave plate optically coupled to the first PBS, a second wave plate optically coupled to the first PBS, and a Faraday rotator optically coupled to the first wave plate, the second wave plate, and t