GB2219871A - Integrated optic device having an optical waveguide bend - Google Patents

Abstract

An integrated optic device includes a waveguide which is curved and includes a section 14 at the bend which is capable of supporting more than one waveguide mode at the operating frequency. The amount of shading indicates the intensity of light in the structure, light being transmitted along the waveguide from the left as shown. Bend angles of greater than 5 DEG may be accommodated without excessive power losses. In another embodiment, the multi-moded section 22 may be achieved by increasing its refractive index compared to that of adjacent parts of the waveguide. <IMAGE>

Description

INTEGRATED OPTIC DEVICES This invention relates to integrated optic devices and more particularly to those devices which include an optical waveguide having a bend.

A fundamental consideration in the design of integrated optical circuits is the packing density of components on a substrate. This is limited principally by the angles through which waveguides may be turned in order to access each component. In presently known semiconductor optical circuits, much of the substrate area is taken up with waveguides fanning into and out of devices, or clusters of devices, at low angles, typically about 1 degree.

A number of techniques have been proposed to enable the bend angle of optical waveguides to be increased without unacceptable losses being sustained in bending light around corners. One proposed solution is to "chamfer" the bend so that its outer region is removed.

This method is illustrated in Figure 1 where the waveguide 1 includes a bend at 2, the outer part of which is chamfered, as shown at 3. The intensity of light entering from the left of the waveguide, in the direction shown by the arrow, is represented by the weight of shading of different regions of the waveguide 1 and the surrounding structure. Although chamfering gives satisfactory results for low angle bends of, say, less than one degree in the case of weakly guiding structures, it does not offer good enough performance to make it a viable technique for higher angle bends.

The present invention arose in an attempt to provide a waveguide structure capable of handling large angle bends without unacceptable power losses.

According to the invention, there is provided an integrated optic device comprising an optical waveguide having a bend and a waveguide section at the bend capable of supporting more than one waveguide mode at the operating frequency. By employing the invention, it has been found that high angle bends, for weakly guiding structures in the region of 50 or more, may be accommodated without large power losses being sustained.

When light is transmitted in two modes along the section, the locus of maximum intensity in the waveguide oscillates from side to side so that the combined wavefront tilts to the left and then to the right. It is believed that, by including the section of more than one mode, this effect may be used to assist in bending light around corners, although other unidentified factors are also thought to be present. The section may be a bi-moded guide or a multimoded guide in which three or more modes are present.

It is preferred that the waveguide is substantially symmetrical in configuration about the bend in the region of the bend. The parts of the waveguide adjacent to the section are then inclined with respect to that section. by the same amount, such that if, for example, a total bend angle of 60 is required, there is a 30 angle between each of the adjacent parts and the section. However, there may be some applications in which it is more convenient to employ an asymmetric configuration.

In one advantageous embodiment, there is a smooth transition between the inner bound of the section and that of at least one of the adjacent parts ofthe waveguide, and it is further advantageous that there is a smooth transition between the outer bound of the section and that of at least one of the adjacent parts of the waveguide. It has been found that a structure which includes smooth transitions between the section and adjacent parts of the waveguide has particularly low losses. However, it is possible to employ an arrangement in which the bounds of the waveguide are stepped between the section and the adjacent parts of the waveguide and still achieve satisfactory performance.

It is preferred that the dimensions of the waveguide are arranged such that the amount of optical power transmitted in each mode of the section is substantially equal. It is believed that, when this condition is fulfilled, the cleanest interchange of energy from one side of the section to the other will occur. Both symmetric and antisymmetric modes may be present,- and it is desirable that the power transmitted in each mode is substantially the same. In a preferred embodiment of the invention, at an end of the section, the centre line of a portion of the waveguide adjacent the section is offset from the centre line of the section. By suitably choosing the amount of offset, the relative power distribution between the modes of the section may be at least partially controlled.The amount of offset required to give the best results may be determined empirically for a particular structure.

In a particularly advantageous embodiment of the invention, the outer bound of the section is curved. This enables a relatively smooth transition to be obtained between the section and adjoining portions of the waveguide so that there is no discontinuity of slope on the outer bound of the waveguide at the bend. The inner bound of the section may also be curved.

In another advantageous embodiment of the invention, the refractive index within the section is greater than that of parts of the waveguide adjacent to it. By selecting appropriate values for the refractive indices of the section and the adjacent parts, the section may be made to support a plurality of modes whereas the adjacent parts are monomode. The section may have more than one index value or there could be a continuous gradient change in refractive index within the section. The waveguide may be of uniform width, this being particularly convenient where it is wished to minimize the area of a device occupied by optical waveguides.

Some ways in which the invention may be performed are now described by way of example, with reference to the accompanying drawings, in which: Figures 2 to 7 illustrate various embodiments of the invention, in which, for Figures 2 to 4 and Figure 6, the amount of shading is representative of the intensity of light within the device when light is transmitted from the left-hand side as shown.

With reference to Figure 2, an integrated optic device has a substrate of InP and includes a waveguide 4 of InGaAsP having a bi-moded section 5 and adjacent waveguide portions 6 and 7 which are inclined relative to the section 5 to give a total bend angle of 60. The inner and outer bounds of the waveguide are stepped where the section 5 and adjacent portions 6 and 7 of the waveguide meet. The centre-lines of the section 5 and portions 6 and 7 are indicated by broken lines. It can be seen that, in this embodiment, the centre lines of portions 6 and 7 are not offset from the centre line of section 5 at the ends of that section. The wavelength of light transmitted along the waveguide is 1.55 microns and the width of the lead-in and lead-out portions 6 and 7 is of the order of 2 microns. The bi-moded section 5 is between about 150 and 200 microns long and has a width of about 4 microns. This arrangement has losses which are reduced compared to those of previously known structures.

Figure 3 illustrates another embodiment of the invention, in which there is a smooth transition between the inner bounds 8 and 9 of the lead-in and lead-out portions 10 and 11 and the inner bound 12 of adjacent a bi-moded section 13, the outer bounds being stepped.

Also in this embodiment, the centre lines of portions 10 and 11 are offset from the centre line of section 13 by an amount a. The dimensions of the portions 10 and 11 and the section 13 are the same as those of the arrangement illustrated in Figure 2 except that the section 13 is somewhat longer. In this case, it was found that an offset of about 1 micron produced mode powers differing by only a small amount, giving a geometry having low losses for a total bend angle oZ 60.

With reference to Figure 4, in another integrated optic device in accordance with the invention, a multimoded section 14 and adjacent lead-in and lead-out portions 15 and 16 are such that there is a smooth transition between the inner and outer bounds of the section 14 and adjacent portions 15 and 16. This is a particularly advantageous structure, having low losses.

Figure 5 shows another structure in which there is a smooth transition between the inner and outer bounds of different parts of the waveguide. In this embodiment, the outer bound is curved to eliminate the discontinuity of slope present in the structure illustrated in Figure 4.

The maximum width of the bi-moded section 17 is about a micron larger than the widths of the sections shown in Figures 2 to 4 and again this structure exhibits particularly low power losses at the bend.

With reference to Figure 6, another device includes a waveguide 18 which comprises a multi-moded section 19, the outer and inner bounds 20 and 21 of which are both curved, the radius of curvature of the outer bound 20 being smaller than that of the inner bound 21.

In another advantageous embodiment of the invention, illustrated in Figure 7, a multi-moded section 22 is located at a bend in a waveguide 23. The width of the section 22 and the rest of the waveguide 23 is substantially the same, the multi-moded capability of the section 22 being achieved by increasing its refractive index compared to that of adjacent parts of the waveguide.

Claims (13)

1. An integrated optic device comprising an optical waveguide having a bend and a waveguide section at the bend capable of supporting more than one waveguide mode at the operating frequency.

2. A device as claimed in claim 1 wherein the waveguide in substantially symmetrical in configuration about the bend in the region of the bend.

3. A device as claimed in claim 1 or 2 wherein there is a smooth transition between the inner bound of the section and that of at least one of the adjacent parts of the waveguide.

4. A device as claimed in claim 1, 2 or 3 wherein there is a smooth transition between the outer bound of the section and that of at least one of the adjacent parts of the waveguide.

5. A device as claimed in any preceding claim wherein the outer bound of the section is curved.

6. A device as claimed in any preceding claim wherein the inner bound of the section is curved.

7. A device as claimed in any preceding claim wherein the dimensions of the waveguide are arranged such that the amount of optical power transmitted in each mode of the section is substantially equal.

8. A device as claimed in claim 7 wherein, at an end of the section, the centre line of a part of the waveguide adjacent the section is offset from the centre line of the section.

9. A device as claimed in any preceding claim wherein the width of the section at its widest point is approximately twice the width of the parts of the waveguide on each side of the section.

10. A device as claimed in claim 1 or 2 wherein the refractive index of the section is greater than that of parts of the waveguide adjacent to it.

11. A device as claimed in claim 10 wherein the width of the waveguide at the section and adjacent to it is substantially the same.

12. A device as claimed in any preceding claim wherein the bend undergone by light between entering and leaving the section is greater than about 50.

13. An integrated optic device substantially as illustrated in and described with reference to Figure 2, 3, 4, 5, 6 or 7 of the accompanying drawings.