Single-ended output circulator

What is claimed is: 1. An optical circulator for routing a light beam, the optical circulator comprising: first, second, and third optical ports disposed at a first end of the optical circulator and configured to transmit the light beam; a birefringent crystal disposed in optical communication with the first, second, and third optical ports and configured to refract the light beam based on a polarization direction and a propagation direction; a plurality of half-wave plates disposed in optical communication with the birefringent crystal, each of the half-wave plates configured to shift the polarization direction of the light beam passing therethrough; an optical prism disposed in optical communication with the half-wave plates and configured to transmit the light beam along the propagation direction according to the polarization direction of the light beam; a reflector disposed at a second end of the optical circulator and disposed in optical communication with the optical prism, the reflector configured to reflect the light beam incident thereto back to the optical prism; a polarization rotator disposed in optical communication at least between the plurality of half-wave plates and the optical prism and configured to rotate the polarization direction of the light beam; and a housing comprising a first connecting tube having a first spherical end surface and a second connecting tube having a second spherical end surface matching the first spherical end surface of the first connecting tube, wherein the housing includes the first, second, and third optical ports, the birefringent crystal, the half-wave plates, the optical prism, the polarization rotator, and the reflector. 2. The optical circulator of claim 1 , further comprising a collimating lens disposed in optical communication between the polarization rotator and the optical prism. 3. The optical circulator of claim 1 , wherein each of the first, second, and third optical ports comprises a fiber core. 4. The optical circulator of claim 1 , wherein the optical circulator is configured to: receive, via the first optical port, a first input of the light beam, and output, via the second optical port, a first output of light beam corresponding to the first input of the light beam; and receive, via the second optical port, a second input of the light beam, and output, via the third optical port, a second output of light beam corresponding to the second input of the light beam. 5. The optical circulator of claim 1 , wherein: the first optical port is configured to receive a first input of the light beam; the birefringent crystal is configured to split the first input of the light beam into a first split light beam having a first of the polarization direction and a second split light beam having a second of the polarization direction; at a surface of the birefringent crystal opposite the first optical port, the first of the polarization direction is along a first axis direction, and the second of the polarization direction is along a second axis direction that is perpendicular to the first axis direction; the plurality of half-wave plates are configured to rotate the first of the polarization direction and the second of the polarization direction to a first orientation; the polarization rotator is configured to rotate the first of the polarization direction and the second of the polarization direction to the first axis direction; and the optical prism is configured to transmit the first split light beam and the second split light beam reflected from the reflector along a first optical path, according to the first of the polarization direction and the second of the polarization direction. 6. The optical circulator of claim 5 , wherein: the second optical port is configured to receive a second input of the light beam; the birefringent crystal is configured to split the second input of the light beam into a third split light beam having a third of the polarization direction and a fourth split light beam having a fourth of the polarization direction; at the surface of the birefringent crystal, the third of the polarization direction is along the first axis direction, and the fourth of the polarization direction is along the second axis direction perpendicular to the first axis direction; the plurality of half-wave plates are configured to rotate the third of the polarization direction and the fourth of the polarization direction to a second orientation; the polarization rotator is configured to rotate the third of the polarization direction and the fourth of the polarization direction to the second axis direction; and the optical prism is configured to transmit the third split light beam and the fourth split light beam from the polarization rotator along a second optical path, according to the third of the polarization direction and the fourth of the polarization direction. 7. The optical circulator of claim 1 , wherein the second spherical end surface of the second connecting tube is configured to be adjustable with the first spherical end surface of the first connecting tube to orient the reflector. 8. The optical circulator of claim 1 , further comprising a magnetic ring surrounding a circumference of the polarization rotator. 9. A single-ended output circulator, comprising: a first connecting tube comprising a first end and a second end, the second end having a spherical end surface; a second connecting tube having a first end having a spherical end surface adjustably matched with the spherical end surface of the first connecting tube; a three-core optical fiber head having a first optical fiber core, a second optical fiber core, a third optical fiber core, a first end, and a second opposing end; a walk-off crystal having a first surface facing towards the second end of the three-core optical fiber head and a second surface facing away from the second end of the three-core optical fiber head; a plurality of half-wave plates each having a first surface coupled to the second surface of the walk-off crystal and a second surface facing away from the second surface of the walk-off crystal; a collimating lens having a first end facing towards the plurality of half-wave plates and a second end facing away from the plurality of half-wave plates; a reflection mirror facing towards the second end of the collimating lens and configured to reflect a light beam from the collimating lens; an optical prism between the collimating lens and the reflection mirror and configured to transmit the light beam along a propagation direction according to a polarization direction of the light beam; and a polarization rotator disposed between the plurality of half-wave plates and the collimating lens, wherein the second end of the three-core optical fiber head penetrates into the first end of the first connecting tube, and wherein the first end of the collimating lens penetrates into the second end of the first connecting tube. 10. The single-ended output circulator of claim 9 , wherein: the second connecting tube has a second end opposite the first end of the second connecting tube, and the reflection mirror is attached to the second end of the second connecting tube. 11. The single-ended output circulator of claim 9 , wherein a cross-section of the first connecting tube has an annular shape, and a cross-section of the second connecting tube has an annular shape and wherein the first connecting tube and the second connecting tube are approximately coaxial. 12. The single-ended output circulator of claim 9 , wherein the single-ended output circulator is configured to: receive, via the first optical fiber core,