AU2001294025A1 - Optical multi-band device with grating - Google Patents

Description

OPTICAL MULTI-BAND DEVICE WITH GRATING

Field of Invention

This invention relates to an optical waveguide multi-band Bragg grating device. Background to the Invention

High speed, high capacity optical communication systems require high performance devices that introduce minimum degradation. Such devices are required, for example, to introduce minimal insertion losses and should show no spurious reflection peaks or unwanted dispersion slopes. The adoption of wavelength- division-multiplexing (WDM) technology, as a means of increasing the optical system bandwidth and speed, is increasingly shifting the emphasis towards the use of multiband optical devices. The implementation of a 128-channel optical network, for example, will require the development of complex devices with up to 128 different transmission bands.

Multiband reflective optical devices have already been successfully demonstrated by using fibre Bragg grating technology. Multiband operation can be achieved by multi-element arrays formed by splicing together a series of single-band gratings with different central wavelengths and strong side-lobe suppression. Such an approach can result in high total insertion loss, due to finite splice losses. Their performance can also be compromised by residual backreflections introduced by the splices, especially if the individual gratings are written in fibres with different characteristics, such as different numerical apertures or core/cladding compositions, in order to increase photosensitivity and/or eliminate short-wavelength cladding-mode losses. Multiband operation can also be achieved by overwriting and essentially superimposing different gratings, corresponding to the different reflection bands, on the same fibre length. However, such an approach quickly saturates the available fibre photosensitivity and results in a small number of bands with relatively small reflectivity. Also, since this process involves multiple exposures, any error during the writing of a certain grating (e.g., due to different exposure conditions and UN-fluence stability) is quite likely to affect the other gratings as well.

Finally, multiband operation can also be achieved by single, complex superstructured gratings, such as sampled or sinc-apodised superstructured gratings. These complex-grating structures can be viewed as resulting from a linear, coherent superposition of the individual gratings that correspond to each different band. Such linear coherent superposition is essentially an additive process and results in complex refractive-index-variation patterns and very large required peak refractive index changes. This can potentially limit the number or types of photosensitive fibres that can be used. Also, it can severely limit the maximum achieved reflectivity at each band.

None of these prior-art approaches achieve multiband operation provide multichannel, high-reflectivity devices (>50%) having low dispersion. This is a serious problem for high-speed (eg lOGB/s and 40GB/s) communication systems.

An aim of the present invention is to improve the performance of gratings that reflect optical radiation at more than one wavelength.

Summary of the Invention

According to a non-limiting embodiment of the present invention there is provided apparatus for filtering optical radiation, which apparatus comprises a waveguide, wherein the waveguide comprises a grating having a first reflection wavelength band having a first average wavelength and a first group delay, and a second reflection wavelength band having a second average wavelength and a second group delay, wherein the first group delay and the second group delay are different in at least a portion of the second reflection wavelength band.

The first reflection wavelength band can have at least one maximum reflectivity. The maximum reflectivity can be greater than 50%. The maximum reflectivity can be greater than 90%. The maximum reflectivity can be greater than 95%. Preferably, the maximum reflectivity is greater than 99%.

The first average wavelength can be shorter than the second average wavelength.

The first group delay can have an average first time delay, and the second group delay can have an average second time delay. The average first time delay can be equal to, less than, or greater than the average second time delay.

The grating can have a time delay difference equal to the modulus of the difference between the average first time delay and the average second time delay.

The time delay difference can be between lfs (femtosecond) and lOOOps (picosecond).

The grating comprises a plurality of lines, each line being defined by a respective strength, and each line having a relative displacement from adjacent lines. The time delay difference is preferably the time taken for light to propagate along the waveguide through an odd integral number of the lines. The integral number of lines can be between one and one million. The first group delay can have a first chirp. By "chirp" we mean that the time delay varies with wavelength. The first chirp can be positive or negative. The first chirp can be linear or non-linear.

The second group delay can have a second chirp. The second chirp can be positive or negative. The second chirp can be linear or non-linear.

The overall length of the grating can be reduced and/or the peak to peak variation in coupling constant modulus n-ii-nimised by selecting an appropriate first chirp and second chirp and selecting an appropriate difference between the first group delay and the second group delay. The first chirp and the second chirp can be equal.

The grating can comprise at least one additional reflection wavelength band having an additional average wavelength and an additional group delay, and wherein the first, second and the additional average wavelengths are different from each other.

The grating can be such that the first, second and additional average wavelengths are configured to reflect non-adjacent wavelength channels. Wavelength channels are usually quoted in terms of their optical frequencies and these have been defined on internationally recognized 25GHz, 50GHz, 100GHz and 200GHz grids. The first, second and additional average wavelengths can be uniformly spaced. Such a device is commonly known as an interleaver.

There can be a circulator connected to the grating. The apparatus can then further comprise a first demultiplexer, and wherein the circulator is connected to the first demultiplexer. Alternatively, or in addition, the apparatus can further comprise a second demultiplexer, and wherein the grating is connected to the second demultiplexer.

The apparatus can comprise a plurality of such apparatus configured in a linear array, and wherein each apparatus is configured to reflect different wavelengths. At least one of the circulators can be connected to a demultiplexer.

At least one circulator can be connected to another appropriate unit of apparatus, and wherein the apparatus is configured to reflect different wavelengths. The apparatus can further comprise at least one demultiplexer.

The invention can also provide an apparatus, which apparatus can be configured as at least one of an interleaver, a demultiplexer, or a multiplexer. The apparatus comprises at least one coupler, and at least one grating having a plurality of wavelengtli reflection bands. The coupler can be an optical fibre coupler, a beam splitter, or a planar optics coupler. The coupler is preferably a circulator. The apparatus can also comprise at least one demultiplexing device such as an arrayed waveguide array or a demultiplexer comprising an assembly of thin-film filters.

Brief Description of the Drawings

Embodiments of the invention will now be described solely by way of example and with reference to the accompanying drawings in which:

Figure 1 shows a fibre Bragg grating according to the present invention;

Figure 2 shows the variation in coupling constant with the length of a fibre Bragg grating;

Figure 3 shows the variation of reflectivity and group delay with wavelength;

Figure 4 shows a multiband fibre Bragg grating according to the present invention;

Figure 5 shows a multiband fibre Bragg grating according to the present invention;

Figure 6 (not in accordance with the invention) shows the reflectivity of a single band grating; Figure 7 (not in accordance with the invention) shows the coupling constant of the single band grating of Figure 6;

Figure 8 (not in accordance with the invention) shows the reflectivity of a two- band grating;

Figure 9 (not in accordance with the invention) shows the coupling constant of the two-band grating of Figure 8;

Figure 10 (not in accordance with the invention) shows the reflectivity of a three-band grating;

Figure 11 (not in accordance with the invention) shows the coupling constant of the three-band grating of Figure 10;

Figure 12 (not in accordance with the invention) shows the reflectivity of a four-band grating;

Figure 13 (not in accordance with the invention) shows the coupling constant of the four-band grating of Figure 12;

Figure 14 (not in accordance with the invention) summarises the coupling constant data shown in Figures 7, 9, 11 and 13;

Figure 15 (not in accordance with the invention) shows the coupling constant of four band gratings having different reflectivities;

Figure 16 shows the reflectivity of a two-band grating according to the present invention;

Figures 17 to 20 show the coupling constant of the two band gratings of Figure 16;

Figure 21 shows the reflectivity of a four-band grating according to the present invention; Figures 22 and 23 show the coupling constant of the four-band grating of Figure 21;

Figure 24 compares the coupling constant of four band gratings according to the present invention with an entangled grating;

Figure 25 shows the reflectivity of a four-band grating according to the present invention;

Figure 26 shows the coupling constant of the four-band grating of Figure 25;

Figure 27 shows the reflectivity of a four-band grating according to the present invention;

Figure 28 shows the coupling constant of the four-band grating of Figure 27;

Figure 29 (not in accordance with the invention) shows the reflectivity of a chirped grating;

Figure 30 (not in accordance with the invention) shows the coupling constant of the chirped grating of Figure 29;

Figure 31 shows the reflectivity of a two-band chirped grating according to the present invention;

Figure 32 shows the coupling constant of the two-band chirped grating of Figure 31 ;

Figures 33, 34 and 35 show the coupling constant of the two-band chirped grating of Figure 31 ;

Figure 36 shows the reflectivity of a two-band chirped grating with a negative time delay discontinuity according to the present invention;

Figure 37 shows the coupling constant of the two-band chirped grating of Figure 36;

Figure 38 (not in accordance with the invention) shows an interleaver; Figure 39 shows an interleaver according to the present invention;

Figure 40 shows an interleaver according to the present invention in which the interleaver has two multiband gratings;

Figure 41 shows a demultiplexer according to the present invention;

Figure 42 shows a generalized M-port interleaver according to the present invention;

Figure 43 shows a composite demultiplexer according to the present invention;

Figure 44 shows a demultiplexer according to the present invention comprising multiband gratings and circulators in a tree configuration;

Figure 45 shows a demultiplexer according to the present invention that uses the demultiplexer of Figure 44;

Figure 46 shows a wavelength combiner according to the present invention;

Figure 47 shows a wavelength multiplexer according to the present invention;

Figure 48 shows a preferred embodiment of the present invention;

Figure 49 and 50 (not in accordance with the invention) show the refractive index envelope for a four band grating;

Figures 51 and 52 show the performance achieved from a preferred embodiment of the four band grating according to the present invention; and

Figures 53 and 54 show the performance achieved from another preferred embodiment of the four band grating according to the present invention.

Detailed Description of Preferred Embodiments of the Invention

Referring to Figure 5, there is shown apparatus for filtering optical radiation, which apparatus comprises a waveguide 50, wherein the waveguide 50 comprises a grating 51 having a first reflection wavelength band 52 having a first average wavelength 53 and a first group delay 54, and a second reflection wavelength band 55 having a second average wavelength 56 and a second group delay 57, wherein the first group delay 54 and the second group delay 57 are different in at least a portion of the second reflection wavelength band 55.

The grating 51 can be designed using an inverse scattering technique, a layer peeling method or an iterative or non-iterative analytical or computational process.

The first reflection wavelength band 52 can have at least one maximum reflectivity 58. The maximum reflectivity 58 can be greater than 50%. The maximum reflectivity 58 can be greater than 90%. The maximum reflectivity 58 can be greater than 95%. Preferably, the maximum reflectivity 58 is greater than 99%.

The first average wavelength 53 can be shorter than the second average wavelength 56.

The first group delay 54 can have an average first time delay 59, and the second group delay 57 can have an average second time delay 510. The average first time delay 59 can be equal to, less than, or greater than the average second time delay 510.

The grating 51 can have a time delay difference 511 equal to the modulus of the difference between the average first time delay 59 and the average second time delay 510.

The time delay difference 511 can be between lfs (femtosecond) and lOOOps (picosecond).

The grating 51 has been shown for convenience as comprising three separate sub-gratings 512, 513 and 514. A more usual depiction is as shown in figure 1, which shows a waveguide 1 comprising a core 2 and a cladding 3. A grating 4 has been written into the waveguide 1. The grating 4 has a length 7. Optical radiation 6, which is launched into the waveguide 1 is reflected by the grating 4 resulting in reflected optical radiation 5. The grating 4 comprises a plurality of lines 8, each line 8 being defined by a respective strength, and each line 8 having a relative displacement 9 from adjacent lines.

Referring again to Figure 5, the time delay difference 511 is preferably the time taken for light to propagate along the waveguide 50 through an odd integral number of the lines 8. The integral number of lines 8 can be between one and one million. Note that the time delay difference 511 corresponds to the time difference in reflection. Thus if the integral number of lines 8 is one (ie the light propagates along the waveguide 1 from one line to the next line) then this corresponds to a longitudinal shift of half the line spacing 515, and so, in the depiction shown in Figure 5, the subgrating 513 would be shifted longitudinally by a length 516 of half the line spacing 515. Note that the line spacing 515 will vary along the grating 51 and thus the definition of "an odd integral number of lines" should be interpreted as an average or based on a localised line spacing. It is preferable that the time delay difference 511 is chosen to reduce the maximum strength of the lines 8.

The first group delay 54 can have a first chirp 517. By "chirp" we mean that the time delay varies with wavelength as shown in Figure 5. The first chirp 517 can be positive or negative. The first chirp 517 can be linear or non-linear.

The second group delay 57 can have a second chirp 518. The second chirp 518 can be positive or negative. The second chirp 518 can be linear or non-linear.

The grating 51 can comprise at least one additional reflection wavelength band 519 having an additional average wavelength 520 and an additional group delay 521, and wherein the first, second and the additional average wavelengths 53, 56, 520 are different from each other. The additional group delay 54 can have an average additional group time delay 522. The additional group delay 54 can have an additional chirp 523. The additional chirp 523 can be positive or negative. The additional chirp 523 can be linear or non-linear.

Figure 39 shows an apparatus 390 comprising a circulator 391, a grating 392, an input 393, a first output 394, and a second output 395, wherein the grating 392 comprises first, second and additional reflection wavelength bands 399, 3910, 3911. Optical radiation 396 comprising a plurality of wavelength channels 397 is input into the apparatus 390. The grating 392 can be configured to reflect non-adjacent wavelength channels 398 as shown in Figure 39. Wavelength channels are usually quoted in terms of their optical frequencies and these have been defined on internationally recognized 25GHz, 50GHz, 100GHz and 200GHz grids. The non- adjacent wavelength channels 398 can be uniformly spaced. Alternatively, they can be non-uniformly spaced. The grating 392 can be configured to reflect groups of wavelength channels 397 some or all of which can be adjacent. A coupler such as an optical fibre coupler, a planar waveguide coupler, or a beam splitter can replace the circulator 391.

Figure 41 shows the apparatus 390 connected to a first demultiplexer 4100 and a second demultiplexer 4110. The first and second demultiplexers 4100, 4110 can be an arrayed waveguide array, a demultiplexer comprising an assembly of thin-film filters, or an assembly of fibre Bragg gratings and couplers. The couplers are preferably circulators.

Figure 42 shows an apparatus 420 comprising a plurality of apparatus 390 configured in a linear array, and wherein each apparatus 390 is configured to reflect different wavelengths. Figure 43 shows the apparatus 420 connected to demultiplexers 430. Figure 44 shows an apparatus 440 comprising the apparatus 420, circulators 391, gratings 392, inputs 441 and outputs 442. The apparatus is configured to reflect different groups of wavelengths to different ones of the outputs 442. Figure 45 shows the apparatus 440 connected to demultiplexers 430.

Figures 46 and 47 show similar arrangements to Figures 42 and 45 but configured as wavelength combiners or multiplexers. The multiplexers 471 can comprise an arrayed waveguide array, an assembly of couplers, thin-film filters, or an assembly of fibre Bragg gratings and couplers or circulators.

Figure 1 is a schematic of a fibre Bragg grating 4 of length E_gr 7 showing also the input light 6 and the reflected light 5. Figure 2 shows a schematic of the variation

of the coupling constant modulus |Λ Z)| 20 and the local-period change 4(z) variation

22, along the grating length z 21. Figure 3 shows a schematic of the reflectivity

spectrum R(λ) 30 and the corresponding group delay Aτ(λ) 31, as a function of the

wavelength λ 32, over the grating bandwidth BW 33. By the word "bandwidth" or

"band" we mean a wavelength range in which a substantial proportion of the optical radiation is reflected. The grating bandwidth 33 can be the 3dB bandwidth.

Fibre Bragg Gratings (FBGs) can be characterised in terms of their period uniformity and the spatial variation of refractive-index modulation (apodisation profile). The refractive index variation along the FBG length is, generally, given by:

where no is the fibre effective refractive index, h(z) describes the amplitude variation of

the induced refractive-index modulation, is the reference Bragg wavevector

( 1₀ is the reference Bragg period). The positive peaks of h(z) are referred to as the "lines" of the grating. φ(z) is used to express the slowly varying spatial phase along the

grating length, as well as specific phase shifts at particular points, z is the coordinate measured along the grating axis. In the case, for example, of linearly chirped gratings

φ(z) = KQCZ¹, where C (in m^"1) is the chirp parameter, while for standard uniform

gratings φ(z) is constant (usually taken as zero). The reference Bragg period ΛQ is

typically of the order of 0.1 μm to lμm. The slowly varying grating phase φ(z)

corresponds to a slowly varying local grating period Λ(z) given by:

The difference

^Λ0 dφ(z)

ΔΛ(z) = Λ(z) - Λ₀ = - (3) 2π dz

defines the local period change.

The index modulation h(z) is, in general, expressed as h(z) = hoflz), where ho is the peak refractive-index modulation an.d z) is the apodisation profile. The grating

coupling constant κ(z) is, in general, a complex number with a magnitude |κ(z)| that is

proportional to the modulus of the refractive-index modulation h(z) and a phase

arg[x(z)] that depends on the local period change 4(z). Therefore, the grating can be

fully described by |κ(z)| and the local period change Δ l(z). The grating reflection coefficient is, in general, a complex number expressed as:

where |.| denotes modulus and 6(λ) is the relative phase of the reflected light at the grating input end. The grating reflectivity R is given by

The group delay Aτ(λ), associated with the grating reflection, is given by:

_4t(i),---S_,-J-_«» ₍₆₎

C_Q dβ 2πc_Q dλ

where c₀ is the phase velocity of light in vacuum, β is the propagation constant in the

fibre, and λ is the free-space wavelength. The group delay Aτ(λ) is sometimes referred to in the specification and the figures as an equivalent time delay or time delay, and variations in the group delay is sometimes referred to as relative time delay.

The reflectivity spectrum R(λ) and the group delay Aτ(λ) of the light reflected

by a grating, which is characterised by a coupling constant |κ(z)| and local-period

change Δ/l(z), can be calculated by a number of different methods such as coupled-mode theory, transfer-matrix method, or Bloch wave analysis. This procedure is usually called grating analysis process. Practical gratings can be fully characterised using a number of different measurement set-ups and methods. The opposite process can also be followed. Given a desired reflectivity

spectrum R(λ) and group delay Aτ(λ), the corresponding unique grating structure,

which is characterised by a coupling constant |/c(z)| and local-period change AA(z), can

be determined. This procedure is usually called grating synthesis or grating design. Gratings can be designed using Fourier-transform-based methods or more advanced integral and differential Inverse Scattering (IS) techniques.

As already mentioned in the introduction, in addition to splicing together different gratings, multiband operation can be achieved by overwriting a number of different gratings or by using sampled and complex superstructured gratings. Figure 4 shows a schematic of a multiband reflectivity spectrum 400 and group delay 401, respectively, of such a grating 402. It also shows a schematic of the fibre core 403 with the overwritten ("entangled") sub-gratings 404, 405, 406 each one reflecting a different wavelength band 407, 408, 409. In case of a sampled or complex superstructured grating, the sub-gratings 404, 405, 406 correspond to different spatial harmonics (the individual superimposed sub-gratings 404, 405, 406 are displaced vertically to facilitate visualisation). The individual-grating superposition is also manifested by the fact that the corresponding group delay responses 410, 411, 412 show no relative temporal shift. It should be stressed again that such linear coherent superposition is essentially an additive process and results in complex refractive-index-variation patterns and very large required peak refractive index changes, which can potentially limit the number or types of photosensitive fibres that can be used. Also, it can severely limit the maximum achieved reflectivity at each band and have deleterious effects on the group delay characteristic of the grating.

A purpose of this patent application is to define fibre Bragg gratings with multiband reflectivity response with reduced spatial complexity and minimum peak- refractive-index requirements. This is achieved by introducing a relative time-delay

difference (Δt_y) between the time responses of the various individual reflection bands.

Extra time delay (Δτ_y) is effectively associated with extra total propagation length (ΔL_U)

given by ΔL_y = Vg_rΔt_y, where g_r is the corresponding group velocity. Therefore, if we

consider that each reflection band originates effectively from a certain area within the grating, the introduction of such time delay between reflection bands results in a relative spatial displacement of the individual reflection effective areas. In reflection, the equivalent spatial displacement is given by:

^Lϋ = 2 ^τU ^vsr (7)

where is the group index). The typical values

eo^~3xl0⁸m/s and > =1.5 are assumed in all the following calculations.

Figure 5 shows the reflectivity 550 and equivalent-time-delay 560 spectra, with

the relative time-delay differences (Δt_y) 511, 551 clearly marked, and a schematic of the

spatially separated ("disentangled") gratings, corresponding to different reflection bands.

The associated spatial separations (ΔL_y) 516, 552 are also clearly shown. If the time

delays Δτ_y 511, 551 are chosen appropriately, the spatial overlap between the different

reflection effective areas is minimised and the refractive-index modulation is distributed over the entire grating length. This spatial-overlap minimisation results in much smaller peak refractive-index modulation. However, the reflection and dispersion characteristics of each individual peak remain largely unaffected. DISENTANGLED MULTIBAND GRATING DESIGN EXAMPLES

A number of different disentangled multiband fibre Bragg grating designs corresponding to various reflectivity and equivalent-time-delay spectra are now shown and discussed.

EXAMPLE 1: SQUARE DISPERSIONLESS FILTERS

We first consider the design of multiband square dispersionless filters. Figure 6

shows the desired reflectivity spectrum R(λ) 600 and the group delay Δτ(λ) 601 of a

single band grating (not shown). In this example, the reflectivity spectrum 600 has sloping edges 602, and the inner bandwidth BWn 604 is 0.4nm while the outer bandwidth BWι₂ 605 is 0.6nm. The peak reflectivity 606 is 99%. The group delay 600

is substantially constant, equal to Δto=Ops, over the outer bandwidth BW₁ . The

corresponding coupling constant modulus 700 (thicker line-left axis) and the

local-period change ΔΛ(z) 701 (thinner line-right axis) are shown in Figure 7 plotted in

arbitrary units (au). The coupling constant modulus 700 |κ(z)| has a peak value 702. It

is shown that the local period change is substantially zero over the entire grating length. This implies that the grating period is constant. The observed spikes are numerical

artefacts and denote a sudden jump in the grating spatial phase φ(z). All phase jumps, in

this case, are equal to π. Referring to Figure 6, the peak reflectivity 606 can be between

0.1%) and 99.99999%. The group delay 601 can be a linear or non-linear function of wavelength.

Figure 8 shows the desired reflectivity spectrum R(λ) 800 and the group delay

Aτ(λ) 801 of a two-band grating (not shown). The reflectivity spectrum of each band

802, 803 has sloping edges 804. The inner bandwidths 805, are 0.4nm and outer bandwidths 807, 808 BWι₂=BW₂ are 0.6nm. The inter-band spacing 809 Δλ₂ι is l.Onm. The peak reflectivities 810, 811 are 99%. The group delay 801 is

substantially constant, equal to Δτ0=0ps, over the total outer bandwidth 812 BW_0Ut. The

resulting coupling constant modulus 900 |κ(z)] (thicker line-left axis) and the local-

period change 901 Δ/l(z) (thinner line-right axis) are shown in Figure 9. The coupling

constant modulus 900 |κ(z)| has a peak value 902 approximately twice the peak value

702 in Figure 7. It is shown that the local period is substantially unchanged over the entire grating length. This implies that the grating period is constant. The observed spikes are numerical artefacts, due to numerical differentiation, and denote a sudden

jump in the grating spatial phase φ(z). All phase jumps, in this case, are equal to π.

Figure 10 shows the desired reflectivity spectrum 100 R(λ) and the group delay

1016 Aτ(λ) of a three-band grating. The reflectivity spectrum 100 of each band 101, 102,

103 has sloping edges 104 with inner bandwidths 105, 106, 107 BW =BW₂₁=BW₃₁ equal to 0.4nm and outer bandwidths 108, 109, 1010 BWιr=BW₂₂=BW₃₂ equal to

0.6nm. The inter-band spacings 1011, 1012 Δλ ₁=Δλ₃₂ are lnm. The peak reflectivities

1013, 1014, 1015 are 99%. The group delay 1016 is substantially constant, equal to

Δτ0=0ps, over the total outer bandwidth 1017 BW_0Ut. The resulting coupling constant

modulus 110 \κ z)\ (thicker line-left axis) and the local-period change 111 ΔΛ(z)

(thinner line-right axis) are shown in Figure 11. It is shown again that the local period is substantially unchanged over the entire grating length. This implies that the grating period is constant. The observed spikes are numerical artefacts, due to numerical

differentiation, and denote a sudden jump in the grating spatial phase φ(z). All phase

jumps, in this case, are equal to it.

Figure 12 shows the desired reflectivity spectrum 120 R(λ) and the group delay

121 Aτ(λ) of a four-band grating. The reflectivity spectrum 120 of each band 122, 123, 124, 125 has sloping edges 126 with inner bandwidths 127, 128, 129, 1210 BW_π=BW₂₁=BW₃₁=BW₄₁ equal to 0.4nm and an outer bandwidths 1211, 1212, 1213, 1214 BWι₂=BW₂₂=BW₃₂=BW₄₂ equal to 0.6nm. The inter-band spacings 1215, 1216,

1217 Δλ₂ι=Δλ₃₂=Δλ₄₂ are lnm. The peak reflectivities 1218, 1219, 1220, 1221 are 99%.

The group delay 121 is substantially constant, equal to ΔτO^Ops, over the total outer

bandwidth 1222 BWout. The resulting coupling constant modulus 130 \κ(z)\ (thicker

line-left axis) and the local-period change 131 ΔΛ(z) (thinner line-right axis) are shown

in Figure 13. It is shown that the local period is substantially unchanged over the entire grating length. This implies that the grating period is constant. The observed spikes are numerical artefacts, due to numerical differentiation, and denote a sudden jump in the

grating spatial phase φ(z). All phase jumps, in this case, are equal to π.

From Figures 7, 9, 11 and 13 it is observed that adding spectral peaks in the required reflection spectrum and demanding the group delay to be constant across the entire outer bandwidth results in a progressively more complex coupling constant profile with large peak values. These complex-grating structures can be viewed as resulting from a linear, coherent superposition of the individual gratings that correspond to each different band BWi2, i=l ,2,3,4. Such linear coherent superposition is essentially an additive process and results in complex coupling constant profiles with large coupling- constant peak values, which require large peak refractive-index changes and can potentially put severe limitations on the type of the photosensitive fibre. Figure 14

summarises the coupling constant modulus 140 \κ(z)\ as a function of grating length 141

for the four designs shown in Figures 7, 9, 11 and 13 for direct comparison. It is shown

that the peak 142 |κ(z)| of the four-band device is about four times the peak 143 |κ z)| of

the single-band device. In general, the peak |κ(z)| of the N-band device will be about N

times the peak \κ z)\ of the single-band device. The peak coupling constant modulus 142 \κ(z)\ varies with the desired peak reflectivity 1218 (shown in Figure 12). Figure 15

shows the required coupling constant modulus 150 |κ(z)| of a four-band reflector as a

function of grating length 141 for peak reflectivities 1218 of 0.99, 0.50 and 0.10. The rest of the parameters are similar to the ones in Figure 12. It is shown that as the peak

reflectivity 1218 decreases, both the required peak coupling constant modulus 142 |κ(z)|

and the effective grating length 141 decrease accordingly.

The "individual-grating superposition" has been forced by the fact that all the individual reflection bands 122, 123, 124, 125 (shown in Figure 12) are characterised by the same group delay 121. It is now shown that introducing relative time-delay shifts between individual reflection bands, disentangles the various "individual gratings" and results in a less complicated coupling constant function requiring much smaller peak refractive-index changes.

Figure 16 shows the desired reflectivity spectrum 160 R(λ) and the group delay

168 Aτ(λ) of a two-band grating. The reflectivity spectrum of each band 52, 55 has

sloping edges 162 with inner bandwidths 163, 164 BWπ=BW₂₁ of 0.4nm and outer

bandwidths 165, 166 BW₁₂=BW₂ of 0.6nm. The inter-band spacing 809 Δλ₂₁ is lnm.

The peak reflectivities 58, 167 are 99%. The group delay 168 is substantially constant across each individual outer bandwidth 165, 166 BWι₂ and BW₂ and shows a time

delay difference 511 Δτ₁₂ equal to the modulus of the difference between the average

first time delay 59 and the average second time delay 510.

Figures 17 and 18 show the coupling constant modulus 170 |κ(z)| (thicker line-

left axis) and the local-period change 171 Δτl(z) (thinner line-right axis), corresponding

to Figure 16 where the time delay difference 511 Δτ₁₂=400ps and Δτ₁₂=300ps,

respectively. It is first observed that the coupling constant modulus 170 \κ(z)\ in this

case is fundamentally different from the corresponding one shown in Figure 9. In the present case, two clear peaks 172, 173 can be identified corresponding to the first and

second wavelength reflection bands 52, 55 of Figure 16, respectively. Each |Λ(Z)| peak

172, 173 is essentially identical with the |« z)| distribution that corresponds to a single-

band device (eft, Figure 7). The relative spatial separation 174 ΔZ,ι₂ between the two

|Λ(Z)| peaks 172, 173 is related to the value of the introduced time-delay difference 511

Δrι₂ (of Figure 16) by Equation 7. The introduced time-delay difference 511 ΔTΪ can be

used to control the relative spatial separation ΔZ.₁₂ 174 and effectively disentangle

various wavelength reflection bands. For the time delay differences 511 Δr₁₂ = 400ps

and 3 OOps, the relative spatial separation 174 Δ ι₂ is about 40mm and 30mm,

respectively. These values are in very good agreement with the relative spatial

separation 174 Δ ₁₂ shown in Figures 17 and 18, respectively.

The local period change 171 Δτl(z) (thinner line - right axis), on the other hand,

is substantially piecewise constant with a step 175 AΛu, which is related to the interband

spacing 809 Δ/l ι (of Figure 16) by:

Aλ

ΔΛ₁₂ = 21 (8)

2 ₀

In both Figures 17 and 18, the local period step 175 Δ-4₁₂ is about 0.35nm and

that corresponds to an interband spacing 174 Aλχ_\ of lnm. The typical value «₀ ⁼ 45

was used in the calculations. The grating period over the regions I and II are

substantially equal to Λι=Λo-|/ ι₂|/2 and Λπ⁼Λo+|ΔΛι₂|/2, respectively. This

confirms the fact that the disentangled regions I and II of the grating contribute predominantly to the spectral bands I and II (in Figure 16), with central wavelengths

^i₍π₎ ⁼2woΛ-i₍π). Again, the observed spikes in the local period variation are numerical artefacts, due to numerical differentiation, and denote a sudden jump in the grating

spatial phase φ(z). All phase jumps, in this case, are substantially equal to π.

Referring to Figure 16,, the peak reflectivities 58, 167 can be dissimilar, and can each vary independently between 0.1% and 99.99999%. The group delay 168 can be a linear or non-linear function of wavelength.

Comparing the grating designs shown in Figures 17 and 18 with the corresponding design shown in Figure 9, it is deduced that introducing a differential time delay discontinuity between reflection spectral bands results in spatial disetanglement of the coupling function profile and reduces significantly the required peak coupling-

constant value. The peak \κ(z)\ value 172, 173 in Figures 17 and 18 remains

substantially equal to the peak |x(z)| 702 of the single-band device shown in Figure 7

and, therefore, it is substantially half the peak value 902 of the two-band device of Figure 9. However, as a direct consequence of the spatial disentanglement, the reduction

in peak |κ(z)| value is achieved at the expense of a longer grating length 141. The

coupling constant distribution is spread out over the grating length avoiding large peak values and fast spatial variations.

Figure 19 shows the coupling constant modulus 170 |κ(z)| (thicker line-left

axis) and the local-period change 171 Δ l(z) (thinner line-right axis) for the two-band

grating shown in Figure 16 but with a smaller interband time-delay discontinuity 511

Δr₁₂-100ps. In this case, the relative spatial separation 174 Δ ι₂ is about 10mm. It is

shown that decreasing the design time-delay discontinuity 511 Δτ₁₂ between the two

reflection bands 52, 55 results in relatively shorter effective grating lengths. However, in this case, due to the smaller relative spatial separation 174, the two peaks 172, 173

interfere to a larger extent, resulting in much faster \κ(z)\ changes and larger local period

variations over peak II. The relative amount of interference reduces significantly as the target peak

reflectivity 58, 167 reduces. Figure 20 shows the coupling constant modulus 170 |κ(z)|

(thicker line-left axis) and the local-period change 171 Δτl(z) (thinner line-right axis) for

a two-band grating with spectral characteristics similar to the ones shown in Figure 19 but with a smaller peak reflectivity 58, 167 of 50% (see Figure 16). From Figures 17-20,

it is deduced that the minimum time-delay discontinuity 511 Δrι₂, required to

disentangle the reflectivity bands 172, 173 depends on the target peak reflectivity 58,

167. It can also be shown that the required minimum time-delay discontinuity 511 Δrι₂

also depends on the reflection-band "squareness" (defined as the ratio BWii BWj₂, i=l,2) and the reflection band outer bandwidth (BWQ, i=l,2).

Figure 21 shows the desired reflectivity spectrum 210 R(λ) and the group delay

211 Aτ(λ) spectrum of a four-band dispersionless grating. The reflectivity spectrum of

each band 52, 55, 212, 213 has sloping edges 162 with inner bandwidths 163, 164, 129, 1210 BWn=BW₂₁=BW₃₁=BW₄₁ of 0.3nm and outer bandwidths 165, 166, 1213, 1214 BW₁₂=BW₂₂=BW₃₂=BW₄₂ of 0.5nm. In this case, the inter-band spacings 809, 214, 215

Δλ ι=Δλ₃₂=Δλ₄₃ are 0.8nm and the peak reflectivities 58, 167, 1220, 1221 are all equal

to 90%. The group delay 211 Aτ(λ) is substantially constant across each individual outer

bandwidth 165, 166, 1213, 1214 BWβ (i=l-4) and shows time delay discontinuities 511,

551, 216 Δτi , Δr₃₂ and Δr₄₃ between the bands 52, 55, 212, 213.

Figures 22 and 23 show the resulting coupling constant modulus 220 |κ(z)|

(thicker line-left axis) and the local-period change 221 Δ l(z) (thinner line-right axis),

corresponding to the time-delay discontinuities 511, 551, 216 Δn₂=Δr₂₃ =Δr₃₄ equal to

150ps and 75ps, respectively (as defined in Figure 21). The relative spatial separations

222, 223, 224 ΔEι₂ =Δ ₂₃ =ΔZ₃ between the peak coupling constant modulus 225, 226, 227, 228 are about 15mm and 7.5mm, respectively. The local period change 221 Δ (z),

on the other hand, is substantially piecewise constant over each disentangled peak 225, 226, 227, 228, with local period steps 229, 230, 231 proportional to the interband

spacing 809, 214, 215 Δλ₂₁, Δλ₃₂ and Δλ-β, respectively. The local period steps 229,

230, 231 AΛn, Δvl₂₃ and Δ/l₃₄ are all approximately equal to about 0.28nm, which

corresponds to an interband spacing 809 Δ l₂₁ of about 0.8nm. Again, the observed

spikes are numerical artefacts, due to numerical differentiation, and denote a sudden

jump in the grating spatial phase φ(z). All phase jumps, in this case, are substantially

equal to π. As before, smaller time delay discontinuities 511, 551, 216 Δη₂, Δr₃₂ and

Δr₄₃ result in smaller relative spatial separations 222, 223, 224 and stronger overlap

between the partially disentangled wavelength peaks 225, 226, 227, 228. The peak reflectivities 58, 167, 1220, 1221 can also be dissimilar, varying between 0.1% and 99.99999%. The group delay 211 can also be a linear or non-linear function of wavelength.

Figure 24 summarises the coupling constant moduli |x(z)|, corresponding to the

disentangled grating designs shown in Figures 22 and 23, and compares them with an "entangled" grating design with the same four-band reflectivity spectrum 210 but with

zero interband time delays 511, 551, 216 (Δrι =Δr₂₃=Δr₃₄=0ps) as defined in Figure 21.

It is shown that the disentangled grating designs result in much smoother coupling

constant 220 \κ(z)\ variations and require much lower peak \κ(z)\ values of the coupling

constant 220. The peak coupling constant 241 \κ(z)\ for the disentangled designs is

about one fourth of the corresponding value of the peak coupling constant 242 of the "entangled" (super-imposed) design.

So far, all the shown examples are fully disentangled and as a result each reflection band can be easily associated with a distinct feature in the coupling constant profile. A similar design approach can also be followed for partially disentangled multiband devices, or devices disentangled by groups.

Figure 25 shows the desired reflectivity spectrum 210 R(λ) and the group delay

211 Aτ(λ) spectrum of a partially disentangled four-band dispersionless grating. The

reflectivity spectrum of each band 52, 55, 1220, 1221 has sloping edges 162 with inner bandwidths 163, 164, 129, 1210 BWn=BW₂ι=BW₃₁=BW₄ι of 0.3nm and outer bandwidths 165, 166, 1213, 1214 BWι₂=BW₂₂-BW₃₂=BW₄₂ of 0.5nm. In this case, the

inter-band spacings 809, 214, 215 Δλ₂₁=Δλ₃r=Δλ₄₃ are 0.8nm and the peak reflectivities

58, 167, 1220, 1221 are all equal to 90%. The group delay 211 Aτ(λ) is substantially

constant across each individual outer bandwidth 212, 213 BWa (i=l-4) and shows

discontinuities 551, 216 Δr₃ and Δr₃ between the bands 52 and 55, and 55 and 213

(II/III and IMN), respectively.

Figures 26 shows the coupling constant modulus 220 \κ z)\ (thicker line -left

axis) and the local-period change ΔΛ(z) 221 (thinner line - right axis) corresponding to

Figure 25 where the time-delay discontinuities 551, 216 Δr ₃=Δτ₃₄=150ps. Because the

reflection bands 212, 52 (I and II) have no relative time-delay discontinuity (Δrι₂=0) the

corresponding grating parts remain entangled (super-imposed). As a result, the first part of the coupling constant modulus 220 and local period change 221 are similar to the ones

shown in Figure 9. However, due to the finite time delays 551, 216 Δr₂₃ and Δr₃₄, the

grating components corresponding to reflection bands 227, 228 (III and IV) are fully

disentangled. The relative spatial separations 223, 224 ΔZ,₂₃ =ΔL₃₄ are about 15mm (in

close agreement with Equation 7). The local period change 221 is substantially piecewise constant over each disentangled peak 227, 228 (Til and IV), with a step 231

proportional to the interband spacing 224 Δλ₃₄. The local-period step 231 Δ/l₃₄ is approximately 0.28nm, which corresponds to an interband spacing 224 Aλu of about

0.8nm.

Since peaks I and II are now entangled (superimposed), the local period 221 is constant over the corresponding local super-structure with a relative shift of about - 0.28nm, with respect to a reference point corresponding to a local period change

Δ- l=0nm. As expected, this relative local-period shift corresponds to the average of

the relative shifts of band I and II shown in Figure 22. The local-period step Δ l₂₃ is

then approximately equal to about 0.4nm. Again, the observed spikes are numerical artefacts, due to numerical differentiation, and denote a sudden jump in the grating

spatial phase φ(z). All phase jumps, in this case, are substantially equal to π. As before,

smaller for time-delay discontinuities Δr^₊i) result in smaller relative spatial separations

ΔZ._ι(1+1) and stronger overlap between the partially disentangled peaks. Figure 27 shows

the desired reflectivity spectrum 210 R(λ) and the group delay 211 Aτ(λ) spectrum of a

four-band dispersionless grating, disentangled by groups. The two groups comprise bands 212 and 52 (I and II), and 55 and 213 (III and IV). The reflectivity spectrum 210 of each band 212, 52, 55, 213 has sloping edges with inner bandwidths 163, 164, 129, 1210 BWn=BW₂₁=BW₃₁=BW₄i of 0.3nm and outer bandwidths 165, 166, 1213, 1214 BWι₂=BW₂₂=BW₃₂=BW₄₂ of 0.5nm. In this case, the inter-band spacings 809, 214, 215

Δλ₂₁=Δλ₃₂=Δλ₄₃ are 0.8nm and the peak reflectivities 1220, 58, 167, 1221 are all equal

to 90%. The group delay 211 Aτ(λ) is substantially constant across each individual outer

bandwidth 165, 166, 1213, 1214 BW_& (i=l-4) and shows a time discontinuity 551 Aτx

between the bands 52 and 55 (Will).

Figure 28 shows the coupling constant modulus 220 |κ(z)| (thicker line —left

axis) and the local-period change 221 / 4(z) (thinner line - right axis) corresponding to Figure 27 with the time-delay discontinuity Δτ"₂₃ =150ps . Because the reflection bands

I/II and I-Q/IN have no relative time-delay discontinuity (Δ ι₂-Δr₃₄=0) the corresponding

grating parts remain entangled (super-imposed). As a result, the two parts of the coupling constant modulus 220 and local period change 221 are similar to the ones shown in Figure 9. The grating components corresponding to the super-imposed reflection bands I/II and III/IV are fully disentangled due to the time delay difference

551 Δ ,. The relative spatial separation ΔZ₂ is about 15mm (again in close

agreement with Equation 7). The local period change 221 Δ (z) is substantially

piecewise constant over each disentangled peak 281, 282. The local-period step 230

ΔΛ₂₃ is approximately equal to about 0.28nm, which corresponds to an interband

spacing 223 Δ/l₃₂ of about 0.8nm.

Since the peak groups 281, 282 (III/IV and I/II) are now entangled (superimposed), the local period 221 is constant over the corresponding local super¬

structure with a relative shift of about ±0.28nm, respectively, with respect to a

reference point corresponding to Δ l=0nm. Again, as expected, this relative local-

period shift corresponds to the average of the relative shifts of the bands III, IV and I,

II shown in Figure 22. The local-period step 230 Δτl₂₃ is then approximately equal to

about 0.56nm. Again, the observed spikes are numerical artefacts, due to numerical

differentiation, and denote a sudden jump in the grating spatial phase φ(z). All phase

jumps, in this case, are substantially equal to π. As before, smaller for time-delay

discontinuities and stronger

overlap between the partially disentangled peaks. The peak reflectivities can also be dissimilar, varying between 0.1% and 99.99999%. The group delay can also be a linear or non-linear function of wavelength. EXAMPLE II: CHIRPED-GRATI G DISPERSION COMPENSATORS

In this example, we apply the same disentangling design approach to a device suitable for dispersion compensation in communication systems. Figure 29 shows the

desired reflectivity spectrum 220 R(λ) and the group delay 221 Aτ(λ) of a single band

grating. The reflectivity spectrum 220 has sloping edges 162, and the inner bandwidth 163 BWn is 0.3nm and the outer bandwidth 165 BWι₂ is 0.5nm. The peak reflectivity

58 is 90%. The group delay 221 varies linearly from Δt₀=750ps to Ops over the outer

bandwidth 165 BWι₂. The corresponding linear dispersion, given by the slope of the group delay 221 with wavelength, is 1500ps/nm. The corresponding coupling constant

modulus 220 \κ(z)\ (thicker line-left axis) and the local-period change 221 ΔΛ(z)

(thinner line-right axis) are shown in Figure 30. It is shown that the local period change 221 varies non-linearly over the entire grating length 141. The total local-period change

300 ΔΛ is about 0.17nm, which corresponds to the reflection band outer bandwidth 165

(BW₁₂«2noΔΛ). The observed spike 301 is numerical artefact and denotes a sudden

jump in the grating spatial phase φ(z) equal to π. Gratings can be designed with a peak

reflectivity 58 from 0.1% and 99.99999% and with a group delay 221, which is a nonlinear function of wavelength.

Figure 31 shows the desired reflectivity spectrum 220 R(λ) and the group delay

221 Aτ(λ) of a two-band grating. The reflectivity spectrum 220 of each band 52, 55 has

sloping edges 162 with inner bandwidths 163, 164 BWπ=BW₂₁ of 0.3nm and outer

bandwidths 165, 166 BWι₂=BW₂₂ of 0.5nm. The inter-band spacing 809 Δλ₂ι is 0.8nm.

The peak reflectivities 58, 167 are 90%. The group delay 221 varies linearly from a time

delay 310 Δto=750ps to Ops over the outer bandwidth 166 BW₂₂ of reflection band 55

(II). The group delay 221 also varies linearly from Δτ₀+Δτι₂ to Δtι₂ over the outer

bandwidth 165 BW₁₂ of reflection band 52 (I). The corresponding linear dispersion, given by the slope of the time delay curve 221 with wavelength, is -1500ps/nm, for both reflection bands 52, 55. The average first time delay 59 can be greater or less than the

average second time delay 510. The time delay 310 Δτ₀ can be negative giving rise to

positive linear dispersion.

Figure 32 shows the coupling constant modulus |x(z)| (thicker line-left axis) and

the local-period change Δτl(z) (thinner line-right axis) for the two-band reflector shown

in Figure 21 with the delay 511 Δτι₂=0ps. The rest of the parameters are equal to the

ones shown in Figure 31. It is shown that the coupling constant modulus 220 |«(z)|

varies quite fast in a periodic manner along the entire grating length 141. However, the

observed envelope of the coupling constant modulus 220 \tύ(z)\ is the same as in the

case of single-band reflector (see Figure 30). The period of the coupling constant

modulus 220 |x z)| variation depends on the interband spacing 809 Δλ₂₁. The local

period change 221 ΔΛ(z) follows the same overall change and shape observed in Figure

30 indicating again a spatially chirped grating structure. However, in the current case the

presence of sharp spikes indicates again the existence of spatial phase shift equal to π.

The fast periodic variations in \κ(z)\ and the periodic phase shifts along the grating length

are essentially a result of the spatial superposition of two individual gratings corresponding to each reflection band 52 and 55 (I and II). Apart from a small

difference in their reference spatial periods Λi and An, the characteristics of the two

subgratings are identical (similar to the ones shown in Figure 26). The difference |Λτ -

ΛΠ| = Δλ₂ι/2n₀. The resulted entangled design is a consequence of the fact that the time

delay 511 Δtι₂-0ps.

Figures 33, 34 and 35 show the resulting coupling constant modulus 220 \κ z)\

(thicker line-left axis) and the local-period change 221 z 4(z) (thinner line - right axis), for the two-band reflectorshown in Figure 31 with time delay discontinuities 511 Δtι₂=

+750ps, +900ps and +1000ps, respectively. The rest of the parameters are equal to the ones shown in Figure 31. It is first observed that the coupling constant modulus 220

\κ(z)\ in these cases is fundamentally different from the one shown in Figure 32. In the

present case, two clear peaks 225, 226 (I and II) can be identified corresponding to the reflection spectral bands 53, 56 (I and II), respectively. The disentaglement of the two

peaks 225, 226 is a direct result of the introduced time delay discontinuity 511 Δτ₁₂.

Each coupling constant modulus 220 |x z)| distribution and local period change 221 are

essentially identical with the ones corresponding to a single-band device (c.fi, Figure

30). As before, the relative spatial separation 174 ALn between the two \κ(z)\ peaks is

related to the value of the introduced time-delay discontinuity 511 Δη₂ through Equation

7. The observed relative spatial separations 174 Jι₂ are about 75mm, 90mm and

100mm, respectively.

The local period changes 221 Δ (z) (thinner line - left axis) over each band 225,

226 are relatively displaced by a an amount Δ ₁₂ 229, which is again related to the

interband spacing 809 Δ/L₂₁ by Equation 8. In all cases, Δ ι₂=0.26nm. The second \κ(z)\

peak 226 at the back of the grating is characterised by negative local period change 221

(with respect to a reference period Λ₀), which implies that it reflects the shorter-

wavelength ("blue") part of the incident spectrum. This part of the grating (denoted I)

corresponds to band I of the reflection spectrum of Figure 31. The first \κ(z)\ peak 225 at

the front of the grating is characterised by positive local period change 221 (with respect

to the same reference period Λ₀), which implies that it reflects the longer-wavelength

("red") part of the incident spectrum. This part of the grating (denoted II) corresponds, therefore, to band II of the reflection spectrum of Figure 31. Therefore, the "blue" part of the spectrum (band I), been reflected at the far end of the grating (part I), suffers on

average larger time delay (Δtι₂>0) than the "red" counterpart (band II), which is

reflected predominantly at the front part of the grating (part II).

Figure 36 shows a preferred embodiment of the invention corresponding to grating designs with a negative time delay discontinuity 511. Figure 36 shows the

desired reflectivity spectrum 220 R(λ) and the group delay 221 Aτ(λ) of a two-band

grating. The reflectivity spectrum 220 of each band 52, 55 has sloping edges 162 with inner bandwidths 163, 164 BWπ=BW ₁ of 0.3nm and outer bandwidths 165, 166

BWι =BW₂₂ of 0.5nm. The inter-band spacing 809 Δλ ₁ is 0.8nm. The peak

reflectivities 58, 167 are 90%. The group delay 221 varies linearly from a time delay 310

Δτ₀=750ps to Ops over the outer bandwidth 165 BWι₂ of reflection band 52 (I). The

group delay 221 also varies linearly from Δto+|Δtι₂| to |Δtι₂| over the outer bandwidth

166 BW₂₂ of reflection band 56 (II). The corresponding linear dispersion, given by the slope of the time delay 221, is -1500ps/nm, for both reflection bands 52 and 55. Compared to Figure 31, the time delay discontinuity 511 is negative resulting in reflection band II 55 being more delayed that reflection band 1 52.

Figure 37 shows the coupling constant modulus 220 \κ z)\ (thicker line-left

axis) and the local-period change 221 Δ (z) (thinner line-right axis), for the two-band

reflector of Figure 36 with a time delay discontinuity 511 Δtι = -lOOOps. The rest of the

parameters are equal to the ones shown in Figure 35. It is first observed that the

coupling constant modulus 220 \κ(z)\ in these cases is the same as the coupling constant

modulus 220 shown in Figure 35. The local period changes 221 Δ l(z) (thinner line -

left axis) over each band 225, 226 are again relatively displaced by the same amount

Ann 229 of about 0.26nm, as in Figure 35. However, the sign of the relative local

period changes 221 over the front and back parts of the grating have now been reversed. The second |κ z)| peak 226 at the back of the grating is characterised now by a positive

local period change (with respect to a reference period Λ₀), which implies that reflects

the longer-wavelength ("red") part of the incident spectrum. This part of the grating (denoted II) corresponds to band II of the reflection spectrum of Figure 36. The first

\κ z)\ peak 225, on the other hand, at the front of the grating is characterised by a

negative local period change 221 (with respect to the same reference period Λ₀), which

implies that it reflects the shorter-wavelength ("blue") part of the incident spectrum. This part of the grating (denoted I) corresponds, therefore, to band I of the reflection spectrum of Figure 36. Therefore, the "blue" part of the spectrum (band I), reflected at the front end of the grating (part I), suffers on average shorter time delay (corresponding

to Δtι₂<0) than the "red" counterpart (band II), which is reflected predominantly at the

back part of the grating (part II).

The design shown in Figure 37 (corresponding to a negative time delay

discontinuity 511 Δτ₁₂ - see Figure 36) is superior to the equivalent design shown in

Figure 35 (corresponding to a positive time delay discontinuity 511 Δτ₁ - see Figure 31)

when used for linear dispersion compensation in optical transmission systems. Because

in the design with Δτι₂<0 (Figure 37) the "blue" part of the spectrum which is reflected

at the front end of the grating (part I) never reaches part II and, therefore, does not suffer

from cladding-mode losses originating from "red" part II. In the design with Δtι₂>0

(Figure 37) the "blue" part of the spectrum is reflected at the far end of the grating (part I). In this case it propagates through part II and, therefore, suffers from cladding-mode losses originating from the preceding "red" part II.

Cladding-mode losses pose a very serious problem, limiting the useful bandwidth of grating dispersion compensators. To suppress them special fibre designs should be used. The design shown in Figure 37 (corresponding to negative time delay discontinuity Δτχ - see Figure 36), however, solves this problem by disentangling the

different reflection bands and arranging them in such a way that they are not affected by the deleterious effects of cladding modes. This solution does not depend on the type of photosensitive fibre used.

The same design approach can be applied to multi-band (linear and/or nonlinear) disentangled dispersion compensators, extending over very large bandwidths, for example extending over the C- and/or L-Bands. The "bluer" bands are arranged in such a way so that they experience progressively shorter average time delays.

Figure 48 shows a preferred embodiment of a four band dispersion- compensating grating. The group delay 211 is linearly chirped in each of the wavelength bands 52, 55, 212, 213 with a chirp 480.

Figures 49 and 50 show the performance of the four band grating of Figure 48

where the time delay discontinuities 511, 216 Δτ₁₂ = Δr₄₃ = Ops, inner bandwidths 163,

164, 129, 1210 BWn=BW₂ι=BW₃₁=BW_4I = 0.5nm and outer bandwidths 165, 166, 1213, 1214 BWι₂=BW₂₂=BW₃₂=BW₄₂ = 0.55nm. The chirp 480 is 600 ps/nm. The peak reflectivities 58, 167 are equal to 90%. Figure 49 shows the slowly- varying positive envelope of the refractive index modulation 490 (defined in equation 1) and the local period change 221 in nm versus the grating length 141 in metres. Figure 50 shows part of the response shown in Figure 48 to show more detail. The peak to peak variation in refractive index modulation is over 0.001 (ie twice 0.0005). This magnitude of variation can lead to saturation effects of the refractive index modulation induced in the grating writing process, which results in deteriorated grating performance and is very undesirable.

Figure 51 shows the performance of a preferred embodiment of the four band grating of Figure 48. The grating has the same parameters as used in Figure 49, but with the time delay discontinuities 511, 216 Δτι₂ = Δr₃ = 10 fs (femtoseconds). Figure 52 is

an enlargement of Figure 50.

Figure 53 shows the performance of another preferred embodiment of the four band grating of Figure 48. The grating has the same parameters as used in Figures 49,

but with the time delay discontinuity Aτχι = Δr₄₃ = 5 fs (femtoseconds). Figure 54 is an

enlargement of Figure 53.

It is clear by comparing Figures 51 to 54 with Figures 49 and 50 that partially disentangling the first and second reflection wavelength bands 52 and 55 by making the first group delay 54 different from the second group delay 57 has reduced the peak to peak variation in refractive index modulation 490. Comparing Figures 51 to 54 with Figure 28 shows that secondary interference effects evidenced by the large peak to peak variation in the coupling constant modulus 220 have been significantly reduced in Figures 51 to 54, and also that the length of the grating has been significantly shortened. Thus the overall length of the grating can be minimised and/or the peak to peak variation in coupling constant modulus 220 (or refractive index modulation 490) m imised by selecting an appropriate chirp 480 and selecting an appropriate difference between the first group delay 54 and the second group delay 57.

It should also be stressed that, in all the disentangled and partially disentangled designs of multiband dispersion compensators discussed above, the dispersion on each individual band can also be varied or non-linearly chirped so that we compensate for the dispersion slope across the total device band BW_mi. APPLICATIONS

The new grating designs, discussed in the section above, can be used in a number of different arrangements to achieve high performance devices.

SINGLE-GRATING MULTIBAND WDM INTERLEAVERS / DEMULTIPLEXERS

Figure 38 shows a schematic of a conventional optical interleaver 380 using a series of Ni single-band gratings 381 spliced together at splices 382. An incoming dense

wavelength-division-multiplexed (DWDM) signal 396, consisting of N channels 397 λi,

λ , λ₃, ...λ>j, is separated into two output streams 383, 384 of Ni and N₂ channels,

respectively, where Nι+N₂=N. Each member of the Ni-channel subgroup 383 is reflected by a different one of the gratings 382. Such topology, however, involves N_t splices 382, introducing a large cumulative insertion loss and spurious multiple back- reflections that can compromise severely the overall device performance. Additionally, splices have to be packaged in a final product, and the more there are, the bigger the final product and the less the reliability.

Figure 39 shows a schematic of a novel arrangement 390 using a single multi- band (Ni-band) grating 392 instead. The incoming dense wavelength-division-

multiplexed (DWDM) signal 396, consisting of N channels 397 λi, λ₂, λ₃, ...λπ, is

separated into two output streams of Ni and N channels, respectively, where N]+N =N. Each member of the Ni-channel subgroup 398 is now reflected by the same multiband grating 392. Such a topology involves only one splice 382 and the arrangement 390 therefore does not suffer from large cumulative insertion losses and multiple spurious back-reflections. The Ni-channel subgroup at output#l can also be reflected by a small number (β<Nι) of complimentary multiband subgratings 4010 (Gj) in series. Each Q subgrating 4010 (G) reflects P_q (q=l,2, ...Q) bands and ∑ P_q = N_λ . Figure 40 shows q = l

an example of two complimentary subgratings 4010 G_\ and <-r₂, reflecting P_\ and -P₂ bands, respectively, where ι+P₂=Nι.

Figure 41 shows a schematic of a composite demultiplexer comprising two conventional demultiplexers 4100, 4110 (DEMUXl and DEMUX2) connected at each output 4120, 4130 of the apparatus 390, which is configured as an interleaver 4140. The main function of the interleaver 4140 is to separate an incoming Ν-channel DWDM

signal, with channel spacing Δλi_n, into two streams of Νi- and Ν₂-channel outputs with

coarser channel spacing Δλ_out = 2Δλi„. This relaxes considerably the requirements on

the optical characteristics of the subsequent conventional demultiplexers 4100, 4110. Each conventional demultiplexer 4100, 4110 divide the incoming Ni (i=l,2) channel signal into separate single-channel signals at each output. The conventional demultiplexer can be implemented by using arrayed-waveguide-grating (AWG) technology or multilayer thin-film technology.

Figure 42 shows a schematic of a generalised M-port interleaver 420 comprising

(M-l) multiband gratings 392 (G, i=1_.2, ...M-l) and (M-l) circulators 391 in series.

The input 421 of the interleaver 420 constitutes an N-channel WDM signal. Each

multiband grating 392 reflects N_m (m=1.2,...M-l) channels, where N_m≥l, which are

routed to the corresponding output by the preceding circulator 391. The remaining N_M

M-l channels, where N^ = N - ^ N_{w .} appear at output#M 422. An incoming Ν-channel m=\

DWDM signal, with channel spacing Δλj_n, is divided into M streams of Ν_m

(m=l,2,...M) channel outputs with much coarser channel spacing = p_m Aλ_in where p_m = int[ J (pit means integer). In general, jc_m≥2. In case of course that

Nι=N₂=N₃=...=NM, the channel spacings of the output signals are the same.

Figure 43 shows a schematic of a composite demultiplexer 431 that comprises the interleaver 420 and M conventional demultiplexers 430 (DMUX1 to DMUX(M)) connected as shown. Such a composite demultiplexer 431 relies on a number of conventional demultiplexers 430 with very low-port-count and large output-channel spacing. Conventional demultiplexers 430 with such relaxed specifications are easily achieved using arrayed-waveguide-grating (AWG) technology or multilayer thin-film technology.

A generalised M-port interleaver can also be realised by combining (M-l) multiband gratings (G_\, 1=1,2, ...M-l) and (M-l) circulators in a tree configuration. Such a device 440 is shown schematically in Figure 44. The M outputs 442 of this generalised grating-based interleaver can be connected to equal number of conventional low-port-count, wide-channel-spacing demultiplexers 430, as shown in Figure 45, to implement a high performance full optical demultiplexer. Conventional demultiplexers with such relaxed specifications are easily achieved for example by using arrayed- waveguide-grating (AWG) technology or multilayer thin-film technology.

The multiple-band grating/circulator cascade 420 of Figure 42 can also be rearranged to function as a wavelength combiner. Figure 46 shows a schematic of a generalised M-input device 460 consisting of M multiband gratings 391 (G_\, i=l,2, ...M) and M circulators 392. Each multiband grating 391 reflects N_m (m=l,2, ...M)

incoming channels, where N_m≥l, which are subsequently routed, through the succeeding

circulators 392, to the device output 462. The device output consists of Ν WDM

M channels, where N = N_m . The M inputs 463 of this generalised grating-based

7« = 1 wavelength combiner 460 can be connected to the outputs of equal number of conventional low-port-count, wide-channel-spacing multiplexers 470, as shown in Figure 47, to implement a high performance full composite optical multiplexer 471. Conventional multiplexers 470 with such relaxed specifications are easily achieved using arrayed-waveguide-grating (AWG) technology or multilayer thin-film technology.

The multiband gratings used for the implementation of the devices discussed in Figures 39-47 can be of any type detailed in Figures 8-37.

It is to be appreciated that the embodiments of the invention described above with reference to the accompanying drawings have been given by way of example only and that modifications and additional components can be provided to enhance performance.

Claims (36)

Claims

1. Apparatus for filtering optical radiation, which apparatus comprises a waveguide, and which waveguide comprises a grating having a first reflection wavelength band having a first average wavelength and a first group delay, and a second reflection wavelength band having a second average wavelength and a second group delay, wherein the first group delay and the second group delay are different in at least a portion of the second reflection wavelength band.

2. Apparatus according to claim 1 wherein the first reflection wavelength band has at least one maximum reflectivity.

3. Apparatus according to claim 2 wherein the maximum reflectivity is greater than 50%.

4. Apparatus according to claim 2 wherein the maximum reflectivity is greater than 90%.

5. Apparatus according to claim 2 wherein the maximum reflectivity is greater than 95%.

6. Apparatus according to claim 2 wherein the maximum reflectivity is greater than 99%.

7. Apparatus according to any one of the preceding claims wherein the first average wavelength is shorter than the second average wavelength.

8. Apparatus according to any one of the preceding claims wherein the first group delay has an average first time delay, and the second group delay has an average second time delay.

9. Apparatus according to claim 8 wherein the average first time delay is equal to the average second time delay.

10. Apparatus according to claim 8 wherein the average first time delay is less than the average second time delay.

11. Apparatus according to claim 8 wherein the average first time delay is greater than the average second time delay.

12. Apparatus according to any one of claims 8, 10 or 11 wherein the grating has a time delay difference equal to the modulus of the difference between the average first time delay and the average second time delay.

13. Apparatus according to claim 12 wherein the time delay difference is between lfs and lOOOps.

14. Apparatus according to claim 12 or claim 13 wherein the grating comprises a plurality of lines, each line being defined by a respective strength, and each line having a relative displacement from adjacent lines, and wherein the time delay difference is equal to the time taken for light to propagate along the waveguide through an odd integral number of the lines.

15. Apparatus according to claim 14 wherein the integral number of lines is between one and one million.

16. Apparatus according to any one of the preceding claims wherein the first group delay has a first chirp.

17. Apparatus according to claim 16 wherein which the first chirp is positive.

18. Apparatus according to claim 16 wherein the first chirp is negative.

19. Apparatus according to any one of claims 16 to 18 wherein the first chirp is linear.

20. Apparatus according to any one of claims 16 to 18 wherein the first chirp is non-linear.

21. Apparatus according to any one of the preceding claims wherein the second group delay has a second chirp.

22. Apparatus according to claim 21 wherein the second chirp is positive.

23. Apparatus according to claim 21 wherein the second chirp is negative.

24. Apparatus according to any one of claims 21 to 23 wherein the second chirp is linear.

25. Apparatus according to any one of claims 21 to 23 wherein the second chirp is non-linear.

26. Apparatus according to any one of the preceding claims wherein the grating comprises at least one additional reflection wavelength band having an additional average wavelength and an additional group delay, and wherein the first, second and the additional average wavelengths are different from each other.

27. Apparatus according to claim 26 wherein the grating is such that the first, second and additional average wavelengths are configured to reflect non- adjacent wavelength channels.

28. Apparatus according to claim 26 or claim 27 wherein the first, second and additional average wavelengths are uniformly spaced.

29. Apparatus according to any one of the preceding claims and comprising a circulator connected to the grating.

30. Apparatus according to claim 29 and further comprising a first demultiplexer, and wherein the circulator is connected to the first demultiplexer.

31. Apparatus according to claim 29 or claim 30 and further comprising a second demultiplexer, and wherein the grating is connected to the second demultiplexer.

32. Apparatus according to claim 29, or claim 30 or claim 31 and further comprising a plurality of such apparatus configured in a linear array, and wherein each apparatus is configured to reflect different wavelengths.

33. Apparatus according to claim 32 wherein at least one of the circulators is connected to a demultiplexer.

34. Apparatus according to claim 32 wherein at least one of the circulators is connected to another apparatus according to any one of claims 27 to 29, and wherein the apparatus is configured to reflect different wavelengths.

35. Apparatus according to claim 34 and further comprising at least one demultiplexer.

36. Apparatus for filtering optical radiation substantially as herein described with reference to the accompanying drawings.