One use of a conventional optical delay line is to separate the particular colors of a chromatic spectrum. An array waveguide grating (AWG) can be useful for this purpose. To use such a grating for extremely high color resolution, the physical size of the AWG must be quite large. Such a size could easily exceed the size of a common silicon wafer. There is thus a need for an optical delay line that provides high color resolution but that is also compact. Such an optical delay line can enable a very high resolution AWG system (a hyper-resolution AWG).
Photonic signals of high bandwidth are input into a winding of optical fiber. The winding of fiber has individual winds of fiber that are adjacently disposed and that form a substantially linear outer surface of the winding. A series of optical taps are defined in the optical fiber along this surface. The fiber includes an inner core surrounded by an outer layer. The taps comprise a diminished outer layer section of the fiber. It is from these taps that optical energy is released from the fiber.
Other objects, advantages and new features will become apparent from the following detailed description when considered in conjunction with the accompanying drawings.
Referring now to
A specific construction of system 10, offered by way of example, has contiguous winds 18 of fiber that, in this example, are disposed immediately adjacent each other to form at least at 20 a substantially linear surface of winding 12. Surface 20 runs from one end 22 of winding 12 to its other end 24, and is brought into contact with planar waveguide 16 upon which winding 12 rests.
Broadband optical energy 26 is received at an input 27 to fiber winding 12 and is released through a series of optical taps 28 that are defined in fiber winds 18 along surface 20 (to be described herein further). End 29 of fiber 14 can be a fiber termination such as a matched load providing minimal reflection. It should be noted that the number of winds of optical fiber shown in
In an understood manner, the length by which optical signals travel in a waveguide affects the phase of the traveling light and hence provides a mechanism by which the colors of the incoming light can be separated. In essence, different waveguide phase lengths permit different frequencies of light to be segregated from other frequencies of light. It is thereby possible to spread the colors of light out by creating a phase length difference that corresponds to a particular desired travel time of the light, wherein 1 divided by this desired travel time creates the approximate upper limit to the frequency resolution of a hyper-resolution AWG.
For example, to create a frequency resolution of approximately 100 MHz (0.1 GHz), a path length (in a vacuum) of approximately 10 feet of travel or 10 nanoseconds of light travel time is required. Because the index of refraction of glass (fiber) differs from that of a vacuum, a shorter length of fiber is suitable to accomplish this delay. In this instance, approximately six feet of fiber, between the first and last optical taps 28 (tap 281 and tap 28n of
Taps 28 are designed to allow light to radiate from winding 12. Referring now to
An example of such a polarization maintaining fiber is known as Corning® PM Specialty Fiber. The version identified as PM 1550 is suitable for a 1550 nm (light wavelength in vacuum) delay line. Version PM 980 is suitable for a 980 nm optical delay line.
Referring now to
The removal of some of outer layer 32 may be performed by polishing on a standard bulk optic polishing plate. This task can be performed once fiber 14 is wound upon a mandrel wherein each winds 181–18n is simultaneously polished along surface 20 of winding 12. As described in
Referring again to
Obviously, many modifications and variations are possible in light of the above description. It is therefore to be understood that within the scope of the claims the invention may be practiced otherwise than as has been specifically described.
Number | Name | Date | Kind |
---|---|---|---|
4068952 | Erbert et al. | Jan 1978 | A |
5002350 | Dragone | Mar 1991 | A |
5113458 | Taylor | May 1992 | A |
6608721 | Turpin et al. | Aug 2003 | B1 |
6744950 | Aleksoff | Jun 2004 | B2 |
20020146206 | Aleksoff | Oct 2002 | A1 |