Dielectric optical filter network

Optical waveguides – With optical coupler – Input/output coupler

Reexamination Certificate

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Details

C385S016000, C385S024000, C359S199200, C359S199200, C359S199200

Reexamination Certificate

active

06301407

ABSTRACT:

BACKGROUND OF THE INVENTION
Multilayer dielectric filter optical interference filters have been known for many years. Developments in their technology have recently made it possible, by the use of high energy deposition processes such as sputtering or ion-assisted deposition, to produce high quality stable narrow-passband optical interference filters with centre wavelengths that exhibit negligible sensitivity to humidity. Moreover, if the dielectric layers that go to make up the filter are deposited on a substrate having the appropriate temperature expansion coefficient, a temperature coefficient of centre wavelength shift of the filter can also be made by very small, typically less than 2 pm/° C. The construction of a wavelength division demultiplexer using a set of such filters, each with a different centre wavelength, is for instance described in ‘Fiber Optics Handbook for Engineers and Scientists,’ Editor F C Allard published by McGraw-Hill. In chapter 3 of this book P Morra & E Vezzoni describe, with particular reference to its Figure 3.80, a demultiplexer in which a set of dielectric interference filters are mounted, regularly spaced, in two lines on opposed faces of a glass block. An input fibre with a collimating graded-index lens termination directs light through the block to be incident obliquely upon the first filter at the appropriate angle to ensure that light, of a wavelength reflected by all the filters of the set, is reflected so as to be similarly obliquely incident in turn upon each of the other filters of the set. Associated with each filter is an output fibre with a similar collimating graded-index lens termination mounted so that its lens termination receives the transmitted component of the light obliquely incident upon that filter. Each of the collimating graded-index lens terminations is shown as being located in appropriate orientation with respect to the glass block and its filters by means of an associated wedge-shaped spacer.
In principle the structure is quite simple and elegant; in practice there are considerable difficulties in implementing such a structure with satisfactory manufacturing yield and with an acceptable degree of precision and long-term stability to suit dense wavelength division multiplexing (DWDM) applications. In this respect it is to be noted that, since all the filters are mounted in nominally fixed orientation with respect to each other, while there may be limited scope for altering the angle of incident upon the first filter of the set for the purpose of fine-tuning to centre wavelength, no corresponding facility is then possible for further fine-tuning the centre wavelengths of any of the succeeding filters of the set. Then there is the additional problem that individual filters are subject to alignment errors as the result of the trapping of dust particles and the like between the filters and the glass block. A simulation of the effects of such particles upon filters considered to be perfectly prepared at the correct centre wavelength spacing and then bonded on to the block indicated that particles of only 2 &mgr;m diameter are liable to introduce errors in channel position exceeding a 100pm tolerance threshold. These alignment problems can be circumvented by separately bonding free-standing filters by their side edges to a common substrate. Each such filter then has three translational and three rotational degrees of freedom. Then the positioning of the end of each of the collimating graded-index lens terminated fibre on the substrate relative to its associated filter involves a further three translational and three rotational degrees of freedom. A certain number of these degrees of freedom are of little or no practical consequence, examples being the translational movement of a lens terminated fibre along its axis, and rotation of the fibre or its associated filter about that axis. There remain however a large number of degrees of freedom for which such scale movement can have a significant effect upon the optical operation of the device.
SUMMARY OF THE INVENTION
An object of the invention is to provide an assembly method in which the necessary degrees of freedom for the satisfactory alignment of its components can be achieved in a manner that does not involve having movement-sensitive components bonded by thicknesses of adhesive large enough to give rise to temperature and long-term instability effects of unacceptably large magnitudes.
In this context it has been found that, when using fibres with pre-assembled collimating graded-index lens terminations, generally the optimum alignment of such terminated fibres with dielectric interference filters secured by their side edges to a planar surface of a substrate does not result in the physical axes of the terminations of the individual fibres lying in a common place. Accordingly these terminations can not be secured in direct line contact with the same or some other planar surface of the substrate, but have to be secured in some manner that allows individual terminations to be inclined at different angles to such a surface.
In the method of assembly according to the present invention these problems are avoided by arranging to delay the securing of each fibre to its associated graded-index lens termination until after that termination has been mounted. In this manner optimum alignment of the fibres, their terminations, and the dielectric interference filters can be achieved with all the terminations in line contact with a supporting substrate, preferably with each termination secured in line contact with both surfaces of an associated V-groove formed in the substrate surface.
Other features and advantages of the invention will be readily apparent from the following description of preferred embodiments of the invention, the drawings and the claims.


REFERENCES:
patent: 4244045 (1981-01-01), Nosu et al.
patent: 4991924 (1991-02-01), Shankar et al.
patent: 5583683 (1996-12-01), Scobey
patent: 5859717 (1999-01-01), Scobey et al.
patent: 6075632 (2000-06-01), Braun
Fiber Optics Handbook (F C Allard Ed.) Selected pages including Figure 3.80 and related text. No Date Available.

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