AU4703599A - Single mode optical waveguide - Google Patents

Description

WO 00/04410 PCT/US99/13993 SINGLE MODE OPTICAL WAVEGUIDE Background of the Invention The invention is directed to a single mode optical waveguide fiber designed for long repeater spacing, high data rate telecommunication systems. 5 In particular, the single mode waveguide combines excellent bend resistance, low dispersion slope, and large effective area, Aeff. A waveguide having large effective area reduces non-linear optical effects, including self phase modulation, four wave mixing, cross phase modulation, and non-linear scattering processes, all of which can cause 10 degradation of signals in high power systems. In general, a mathematical description of these non-linear effects includes the ratio, P/Aeff, where P is optical power. For example, a non-linear optical effect usually follows an equation containing a term, exp [P x Leff/Aeff], where Lef is effective length. Thus, an increase in Aen produces a decrease in the non-linear contribution to 15 the degradation of a light signal. The requirement in the telecommunication industry for greater information capacity over long distances, without electronic signal regeneration, has led to a reevaluation of single mode fiber index profile design. The genera of these profile designs, which are called segmented core designs in this 20 application, are disclosed in detail in U. S. patent 4,715,679, Bhagavatula. The focus of this reevaluation has been to provide optical waveguides which: - reduce non-linear effects such as those noted above; WO 00/04410 PCTIUS99/13993 2 - are optimized for the lower attenuation operating wavelength range around 1550 nm; - are compatible with optical amplifiers; and, - retain the desirable properties of optical waveguides such as high 5 strength, fatigue resistance, and bend resistance. The definition of high power and long distance is meaningful only in the context of a particular telecommunication system wherein a bit rate, a bit error rate, a multiplexing scheme, and perhaps optical amplifiers are specified. There are additional factors, known to those skilled in the art, which have 10 impact upon the meaning of high power and long distance. However, for most purposes, high power is an optical power greater than about 10 mw. In some applications, signal power levels of 1 mW or less are still sensitive to non linear effects, so that Aen is still an important consideration in some lower power systems. A long distance is one in which the distance between electronic 15 regenerators can be in excess of 100 km. The regenerators are to be distinguished from repeaters which make use of optical amplifiers. Repeater spacing, especially in high data density systems, can be less than half the regenerator spacing. To provide a suitable waveguide for multiplexed transmission, the total 20 dispersion should be low, but not zero, and have a low slope over the window of operating wavelength. A typical application for such a waveguide fiber is undersea systems that, in order to be economically feasible, must carry high information densities over long distances without regenerators and over an extended window of 25 wavelengths. The present invention describes a novel profile which is singularly suited to meeting the stringent requirements of this kind of use. The detailed requirements of the use system are set forth below. Definitions 30 The following definitions are in accord with common usage in the art. - The radii of the segments of the core are defined in terms of the index of refraction. A particular segment has a first and a last refractive index point.

WO 00/04410 PCT/US99/13993 3 The radius from the waveguide centerline to the location of this first refractive index point is the inner radius of the core region or segment. Likewise, the radius from the waveguide centerline to the location of the last refractive index point is the outer radius of the core segment. 5 The segment radius may be conveniently defined in a number of ways, as will be seen in the description of Figs. 1 & 2 below. In the case of Fig. 2, from which Tables 1 & 2 are derived, the radii of the index profile segments are defined as follows, where the reference is to a chart of A % vs. waveguide radius: 10 * the radius of the central core segment, r 1 , is measured from the axial centerline of the waveguide to the intersection of the extrapolated central index profile with the x axis, i.e., the A % = 0 point; * the outer radius, r 2 , of the first annular segment is measured from the axial centerline of the waveguide to the intersection of the first annular segment 15 profile with the line representing the A % of the second annular segment profile; *the outer radius, r 3 , of the second annular segment is measured from the axial centerline of the waveguide to the point at which the relative index is midway between the relative indexes of the second and third annular segments; and, 20 *the outer radius, r 4 , of the third annular segment is measured from the axial centerline of the waveguide to the point at which the relative index is midway between the relative indexes of the third annular segment and the clad layer. In the more general refractive index profile of Fig. 1, alternative 25 definitions are used. No particular significance is attached to the definition of index profile geometry. Of course, in carrying out a model calculation the definitions must be used consistently as is done herein. - The effective area is Aen = 2rr (JE 2 r dr) 2 /(fE 4 r dr), where the integration limits 30 are 0 to -, and E is the electric field associated with the propagated light. An effective diameter, Deff, may be defined as, Aeff = T(Deff/2) 2

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WO 00/04410 PCTIUS99/13993 4 - The relative index, A%, is defined by the equation, A% = 100 x (n 1 2 - n 2 2 )/2n 1 2 , where n 1 is the maximum refractive index of the index profile segment 1, and n 2 is a reference refractive index which is taken to be, in this application, the refractive index of silica. 5 - The term refractive index profile or simply index profile is the relation between A % or refractive index and radius over a selected portion of the core. The term alpha profile refers to a refractive index profile which follows the equation, n(r) = no (1- A[r/a]a) where r is core radius, A is defined above, a is the last point in the profile, r is chosen to be zero at the first point of the profile, and 10 a is an exponent which defines the profile shape. Other index profiles include a step index, a trapezoidal index and a rounded step index, in which the rounding is typically due to dopant diffusion in regions of rapid refractive index change. - Total dispersion is defined as the algebraic sum of waveguide dispersion and material dispersion. Total dispersion is sometimes called chromatic dispersion 15 in the art. The units of total dispersion are ps/nm-km. - The bend resistance of a waveguide fiber is expressed as induced attenuation under prescribed test conditions. Standard test conditions include 100 turns of waveguide fiber around a 75 mm diameter mandrel and 1 turn of waveguide fiber around a 32 mm diameter mandrel. In each test condition the bend 20 induced attenuation, usually in units of dB/(unit length), is measured. In the present application, the bend test used is one turn of the waveguide fiber around a 20 mm diameter mandrel, a more demanding test which is required for the more severe operating environment of the present waveguide fiber. 25 Summary of the Invention The novel single mode waveguide fiber of this application meets the high performance telecommunication system requirements set forth herein. A first aspect of the invention is a single mode optical waveguide fiber having a segmented core surrounded by a cladding glass layer. The core has 30 at least four segments, at least one of which has a negative relative index, -A %. The segmented core is defined in terms of the relative index percents, the refractive index profiles and the radii of the segments. The radii are measured WO 00/04410 PCT/US99/13993 5 from the centerline of the waveguide fiber and extend to a point of the segment defined in terms of the relative refractive indexes as stated in the "Definitions" section and as shown in Figs. 1 & 2. Throughout this application, the core extent, i.e., the outer radius of the core, is defined in terms of the segment 5 geometry. The largest part of the light energy is carried in the core, but it is understood that the portion of the cladding layer adjacent the core does carry a significant amount of light. The portion of the cladding layer adjacent the core in the novel waveguide preferably contains a refractive index increasing dopant. 10 In one embodiment of the invention, the central segment is made to have a negative relative index, -A 1 %. In another embodiment of the invention, the core region has four segments, all having positive relative indexes except for the central segment which has a negative relative index. For this case, the A %'s follow the 15 inequality, A 2 % > A 4 % > A 3 % > A 1 %, in which the numbering of segments is consecutive and begins with 1 at the central segment. In this embodiment the refractive index profiles of the first and third annular segments may be an a profile, a step index, a trapezoid, or a rounded step or trapezoid. The second annular region may have the form of a step index profile, a term used to identify 20 an index segment consisting of a constant horizontal portion. In addition, the portion of the cladding layer which contains an index increasing dopant, thus providing a cladding layer portion having a refractive index greater than that of silica, may have a step index profile. Particular ranges of values for A 1 %, A 2 %, A 3 %, A 4 %, the relative 25 indexes, and radii, r 1 , r 2 , r 3 , r 4 , of a core region having four segments, which provide the set of target properties of the novel waveguide are set forth in the tables below. The appropriate range of the relative index, A 5 %, of the preferred doped cladding layer portion is also given in the tables. A radius for the doped cladding layer portion is not required. In effect the doped portion of M0 the clad layer extends to a radius whereat the light intensity carried in the waveguide is negligible. This radius value is typically determined by testing methods known in the art, such as measurement near field intensity.

WO 00/04410 PCT/US99/13993 6 This aspect of the invention, including its embodiments of profile segment shape and size, is capable of providing a single mode optical waveguide having an effective area > 70 jim 2 and a total dispersion slope < 0.08 ps/nm 2 -km over a pre-selected range operating of operating wavelengths. 5 As is noted above, the window about 1550 nm to 1560 nm is at present preferred because of the low attenuation in this range and its correspondence with the gain curve of erbium doped optical amplifiers. The minimum effective area can be increased and the total dispersion slope can be decreased substantially by tuning the radii, A %'s, and shape of one or more profile 10 segment. The effect of such tuning is seen by comparing the data in Table 1 to that in Table 2 below. The ranges of Table 2 provide a waveguide fiber having Aeff > 80 pm 2 and a total dispersion slope < 0.07 ps/nm 2 -km. A second aspect of the invention is a waveguide fiber having at least four segments. A portion of the cladding layer adjacent the core contains an 15 index increasing dopant. The A 's, radii and profile shapes are chosen to provide the waveguide fiber properties listed in Table 3. Brief Description of the Drawings Fig. 1 is a chart of A % vs. radius illustrating a refractive index profile in accord 20 with the invention and the definitions of Ai and ri. Fig. 2 is a chart showing an alternative embodiment of the refractive index profile. Detailed Description of the Invention 25 The invention described herein is a family of single mode optical waveguide fibers defined by the parameters of a family of refractive index profiles. The refractive index profiles include at least four core segments, one of which has a negative relative index percent, -Al %, and a cladding layer which preferably contains a refractive index increasing dopant at least in the cladding 30 portion adjacent the core region.

WO 00/04410 PCT/US99/13993 7 The refractive index profile of the novel waveguide may be described in terms of the A %'s and radii shown in Fig. 1. Thus relative index values, indicated as 2, 4, 6, 8, 10 and 12, in Fig. 1 are the respective relative index values of the central segment, the first, second, third, and nth annular segment 5 of the core. Relative index 14 is that of the cladding layer portion, adjacent the outermost segment of the core, which contains a refractive index increasing dopant. The respective radii, ri, i=1, 2, 3,...,n are shown as 16, 18, 20, and 22. Radius 16 is measured from the waveguide fiber centerline to the point of intersection of the central segment with the first annular segment. Radius 18 is 10 measured from the centerline to the point of zero relative index, i.e., the intersection of the second annular segment profile with the x-axis. Dashed lines 24, 26, 28, and 30 show alternative shapes of the index profile of the respective segments. What these dashed lines represent are alternative members of the family of profiles which provide the pre-selected set 15 of waveguide properties set forth in Table 3. These alternatives are regarded as perturbations of the base profile not large enough to appreciably change the energy distribution in the waveguide fiber of the light carried therethrough. The embodiment of the novel profile illustrated in Fig. 2 is used to calculate the refractive index profile geometry set forth in Tables 1 and 2. A 20 waveguide fiber having a profile as set forth in Tables 1 or 2 can have the waveguide fiber the corresponding performance requirements stated in Table 3. The definitions of r 1 , r 2 , r 3 , and r 4 illustrated in Fig. 2 follow exactly those given in the "Definitions" section above. The relative index percents, A 1 , A2, A 3 ,

A

4 , and As are shown in Fig. 2 as 32, 34, 36, 38, and 40, respectively. It will be 25 understood that small variations of this profile will not appreciably change the waveguide properties. For example, the horizontal profiles of segments 32, 36, or 40 could be slightly concave or convex, or contain a small dip or rise in relative index without having an effect on the calculated waveguide properties. However, a comparison of the two tables shows that sub-micron 30 changes in certain of the radii, for example the lower limit of radius r 1 , can markedly affect the total dispersion slope. Other small changes in certain of the profile variables can impact the waveguide performance.

WO 00/04410 PCT/US99/13993 8 Table 1 Slopes ' 1% A2% A 3 % A 4 % As% r 1 ptm r 2 p4m r 3 pm R 4 pm 0.08 Aeff>70 Low -0.32 1.24 -0.02 0.40 0.09 1.69 3.72 8.32 9.30 Limit High -0.24 1.39 0.03 0.52 0.11 1.82 3.87-1 8.63 9.65 Limit I In Table 1, the refractive index profile segments are constrained by the requirement that the total dispersion slope be less than or equal to 0.08 ps/nm 2 -km and the effective area be greater than 70 pm 2 , over a wavelength 5 range centered about 1550 nm. The effective wavelength range is set by the limit on the total dispersion slope and the total dispersion value at 1555 nm, which in the embodiments of Tables 1 and 2 is taken to be less than about -3 ps/nm-km. Table 2 Slopes 10.07 A 1 % A 2 % A 3 % A 4 % A 5 % r 1 m r 2 JAm r 3 pim r 4 pm Aeff>80 Low i -0.32 1.26 -0.02 0.41 0.09 1.76 3.72 8.32 9.30 Limit I HighI i -0.25 1.33 0.01 0.52 0.11 1.82 3.82 8.60 9.65 Limit 10 To improve the total dispersion slope to a value less than or equal to 0.07 ps/nm 2 -km and the effective area to a value greater than or equal to 80 pm2, as in Table 2, a comparison of tabulated values show that the overall core radius r 4 , and the cladding layer relative index may be held constant, while 15 incremental changes are made in the other profile variables. The values of A 2 %, A 3 %, and r 1 would seem to be more important than the other variables in WO 00/04410 PCT/US99/13993 9 reaching target Aeff and total dispersion slope. However, the variables interact to provide a profile which satisfies all waveguide performance requirements set forth in Table 3. The overall profile geometry must be considered in each case. Table 3 Aeff Disp. Att.1550 Disp.1560 X, Macro-bend (prm 2 ) Slope (dB/km) (ps/nm- (nm) (dB/m) (ps/nm 2 km) -km) Table 1 >80 <0.07 <0.25 -2.0 <1500 <10 fiber Table 2 >70 <0.08 <0.25 -2.0 <1500 <10 fiber 5 For example the low limit of A 1 , A 2 , and A 3 in Table 1 are set by the requirement that the total dispersion be less negative than -3 ps/nm-km in the operating window about 1555 nm. The edges of the profile family envelope are found by changing a variable or set of variables until the model predicts a 10 performance parameter that is out of specification. Although particular embodiments of the invention have been herein disclosed and described, the invention is nonetheless limited only by the following claims.

Claims (11)

1. A single mode optical waveguide fiber comprising: a core region surrounded by and in contact with a cladding layer, the core region comprises at least a central segment and a first, second, 5 and third annular segment, each of the segments having a refractive index profile, a relative index percent, Ai %, for which the reference refractive index is that of silica, and an associated radius, ri, at least one of the at least central, first, second, or third segments having a negative relative index, and wherein at least a portion of the cladding layer, 10 adjacent the outermost annular core segment, has a positive relative index.

2. The single mode waveguide of claim 1 in which the segment having a negative relative index percent, -A 1 %, is the central segment. 15 3. The single mode waveguide of claim 2, having four core segments, in which, the magnitudes of the relative indexes of the respective segments, the segments being numbered consecutively beginning with 1 at the central segment, follow the relationship, A 2 %>A 4 %>A 3 %>A1 %. 20

4. The single mode waveguide of claim 2, in which, the first and third annular segments have a refractive index profile selected from the group consisting of an a-profile, a step index profile, a rounded step index profile, and a trapezoidal profile. 25

5. The single mode waveguide of claim 4, in which, the second annular region is a step index profile.

6. The single mode waveguide of claim 5, in which, the index profile of the 30 cladding layer portion, surrounding and in contact with the third annular region, is a step index profile. WO 00/04410 PCTIUS99/13993 11

7. The single mode waveguide of claim 1, in which, the core has four segments, the segments being numbered consecutively beginning with 1 at the central segment, and the relative indexes of the segments have respective values, A 1 % in the range of about -0.32 to -0.24, A 2 % in the range of about 5 1.24 to 1.39, A 3 % in the range of about -0.02 to 0.03, and A 4 % in the range of about 0.40 to 0.52 and the radii of the segments have respective values, r 1 in the range of about 1.69 pm to 1.82 pim, r 2 in the range of about 3.72 pm to 3.87 pm, r 3 in the range of about 8.32 pm to 8.63 pm, and r 4 in the range of about

9.3 p~m to 9.65 pm. 10 8. The single mode waveguide of any one of claims 1-7, in which, the cladding layer portion has a relative index, A 5 %, in the range of about 0.09 to 0.11. 9. The single mode waveguide of claim 8, in which, the core and clad relative 15 indexes and the core radii are chosen to provide a waveguide fiber having an effective area greater than or equal to 70 pm 2 and a dispersion slope less than or equal to 0.08 ps/nm 2 -km.

10. The single mode waveguide of claim 1, in which, the core and clad relative 20 indexes and the core radii are chosen to provide a waveguide fiber having an effective area greater than or equal to 70 pm 2 and a dispersion slope less than or equal to 0.08 ps/nm 2 -km.

11. A single mode optical waveguide fiber comprising: 25 a core region surrounded by and in contact with a cladding layer, in which, the core region comprises a central segment and a first, second, and third annular segment, each of the segments having a refractive index profile, a relative index percent, Ai %, for which the reference refractive index is that of 30 silica, and an associated radius, ri, where i is an integer greater than or equal to WO 00/04410 PCT/US99/13993 12 1, and a cladding layer portion adjacent the outermost core segment containing a refractive index increasing dopant, in which, the refractive index profile, A %, and r of each segment is selected to provide a waveguide having: 5 - an effective area greater than or equal to 70 pm 2 ; - a total dispersion slope less than or equal to 0.08 ps/nm 2 -km; - attenuation at 1550 nm less than or equal to 0.25 dB/km; - cutoff wavelength measured in the cable less than 1500 nm; - dispersion at 1560 nm of about -2 ps/nm-km; and, 10 - macrobend loss for 1 turn about a 20 mm mandrel less than or equal to 10 dB/m.

12. The single mode waveguide of claim 11, having four core segments, in which, the magnitudes of the relative indexes of the respective segments, the 15 segments being numbered consecutively beginning with 1 at the central segment, follow the relationship, A 2 %>A 4 %>A 3 %> A 1 %.

13. The single mode waveguide of claim 12, in which, the core has four 20 segments, the segments being numbered consecutively beginning with 1 at the central segment, and the relative indexes of the segments have respective values, A 1 % in the range of about -0.32 to -0.24, A 2 % in the range of about 1.24 to 1.39, A 3 % in the range of about -0.02 to 0.03, and A 4 % in the range of about 25 0.40 to 0.52 and the radii of the segments have respective values, r 1 in the range of about 1.69 pim to 1.82 pm, r 2 in the range of about 3.72 pm to 3.87 pm, r 3 in the range of about 8.32 ptm to 8.63 pm, and r 4 in the range of about 9.3 pm to 9.65 pam. 30 14. The single mode waveguide of claim 11, in which, the core has four segments, the segments being numbered consecutively beginning with 1 at the WO 00/04410 PCT/US99/13993 13 central segment, and the relative indexes of the segments have respective values, A1 % in the range of about -0.32 to -0.24, A 2 % in the range of about 1.24 to 1.39, A 3 % in the range of about -0.02 to 0.03, and A 4 % in the range of about 0.40 to 0.52 and the radii of the segments have respective values, r 1 in 5 the range of about 1.69 pm to 1.82 pm, r 2 in the range of about 3.72 gm to 3.87 pm, r 3 in the range of about 8.32 pm to 8.63 pm, and r 4 in the range of about 9.3 pm to 9.65 pm.