Reflection-type optical circulator utilizing a lens and...

Details Reflection-type optical circulator utilizing a lens and... Reflection-type optical circulator utilizing a lens and...

2000-11-29

2003-07-22

Shafer, Ricky D. (Department: 2872)

Optical: systems and elements

Polarization without modulation

Polarization using a time invariant electric, magnetic, or...

C359S487030, C359S490020, C359S490020, C359S199200, C385S011000, C385S031000

Reexamination Certificate

active

06597503

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to optical systems, and more particularly to circulators in optical systems.
BACKGROUND OF THE INVENTION
The conventional optical circulator is a non-reciprocal multi-port routing and isolation component used in optical communications systems.
FIG. 1
illustrates the operation of a generalized conventional four-port optical circulator
100
. Light that enters the circulator
100
at port A
102
exits the optical circulator
100
at port B
104
. However, light that enters the conventional optical circulator
200
at port B
104
does not travel to port A
102
but instead exits at port C
106
. Similarly, light entering the port C
106
exits only at port D
108
, and light entering port D
108
exits only at port A
102
. In general, given a set of n equivalent optical input/output ports comprising a certain logical sequence within an optical circulator, light inputted to any port is outputted from the logical next port in the sequence and is prevented from being output from any other port. Since a light signal will travel only one way through any two consecutive ports of the optical circulator
100
, such ports, in effect, comprise an optical isolator. By installing a reflector at one port of a generalized n-port optical circulator (where n≧4) such that light outputted from the port is reflected back into the same port, the circulator may then be utilized as an (n−1)-port circulator. Furthermore, by blocking or failing to utilize one port of a generalized n-port optical circulator (where n≧4), the device may be used as an (n−1)-port quasi-circulator.
The main application of optical circulators is in bi-directional optical fiber communications whereby two signals at the same wavelength may simultaneously propagate in opposite directions through a single fiber. In this way, optical circulators permit a doubling of the bit carrying capacity of an existing unidirectional fiber optic communication link since optical circulators can permit full duplex communication on a single fiber optic link.
FIG. 2
shows the basic components of a conventional optical circulator. The optical circulator comprises two polarization beam splitters
202
and
204
, two 45-degree Faraday rotators
206
and
208
, two half-wave plates
210
and
212
, two mirrors
214
and
216
, and four fiber optic input and output ports
218
,
220
,
222
, and
224
. The two Faraday rotators
206
and
208
rotate the polarization plane of linearly polarized light 45 degrees in one direction (for instance clockwise) as viewed from a fixed reference point (for instance, the left side of FIG.
2
), regardless of the direction of light input. The two half wave plates
210
and
212
also rotate polarized light 45 degrees, but the direction of rotation is constant (for instance clockwise) as viewed from the side at which light enters the plate. Signal light input comprising unpolarized light may be input from any one of the four ports
218
-
224
into either one of the two polarization beam splitters
202
or
204
, which separate the light into two linearly polarized sub-signals, one p-polarized and the other s-polarized. These sub-signals propagate through the other optical elements. By inspection, it may be verified that light input at Port A
218
is transmitted to Port B
220
, light input from Port B
220
is transmitted to Port C
222
, light input from Port C
222
is transmitted to Port D
224
, and light input from Port D
224
is transmitted to Port A
218
. Thus, the circulator
200
is a 4-port optical circulator.
Other conventional circulator designs employ numerous stacked optical elements, such as waveplates, Faraday rotators and polarization beam splitters and optical input/output ports optically coupled to the stacked optics and disposed not all to one side of the apparatus. Such conventional arrangements are bulky and complex and cause difficulties for optical alignment.
Accordingly, there exists a need for an improved optical circulator. The improved optical circulator should minimize the number of required optical elements and should be easier to align than conventional optical circulators. The present invention addresses such a need.
SUMMARY OF THE INVENTION
The present invention provides a reflection-type improved optical circulator. The reflection-type optical circulator includes at least one birefringent plate for receiving at least one signal light ray from a first port; and a mirror optically coupled to the at least one birefringent plate, where the mirror and the at least one birefringent plate causes the at least one signal light ray to be folded back upon itself, where the at least one signal light ray is directed to a second port. The optical circulator in accordance with the present invention is a reflection-type optical circulator, in which the paths of throughgoing light rays are folded back upon themselves. This minimizes the number of required optical elements and the resultant device size by using each optical element two times for each light ray. Furthermore, the reflection-type optical circulator in accordance with the present invention can facilitate the alignment of the optical ports to the remaining optical elements because all ports can be disposed within a tightly constrained geometrical arrangement at only one side of the device.


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