This application claims priority from Japanese Patent Application No. 2002-214575 filed Jul. 23, 2002, which is incorporated hereinto by reference.
1.Field of the Invention
The present invention relates to a dispersion monitoring method and apparatus as well as a dispersion slope temperature dependency compensation method and apparatus, more specifically, relates to a method of monitoring a dispersion variation amount on a transmission optical fiber in a wavelength division multiplexing (WDM) optical transmission system and a compensation method of a dispersion of a transmission line.
2. Description of the Related Art
At present, research/development has been promoted on optical communication of high speed/large capacity for carrying a photonic network in the future. In realizing such an optical communication, there is compensation of a dispersion of a transmission line as one of important problems. As shown in
What poses a problem here is that a dispersion of the transmission optical fiber is varied by temperature. In the case of a 1.3 μm zero dispersion fiber (single mode fiber: SMF) or a dispersion-shifted fiber, it is known that the dispersion is changed by the following equation by shifting a zero dispersion wavelength by a temperature change ΔT(deg) (K. S. Kim and M. E. Lines, “Temperature dependence of chromatic dispersion in dispersion-shifted fibers: Experiment and analysis”, J. Appl. Phys., Vol. 73, No. 5, pp. 2069-2074, 1993).
ΔD=Z·S·L·ΔT (1)
where ΔD(ps/nm) designates a dispersion change amount, Z(nm/deg) designates a temperature constant of zero dispersion wavelength shift, S(ps/nm2/km) designates a dispersion slope (wavelength differential of dispersion) and L(km) designates an optical fiber length.
Heretofore, a variation amount of the dispersion by the temperature change has been regarded as constant without depending on the wavelength. Therefore, according to an adaptive dispersion equalization technology which has been proposed until present time, the variation of the dispersion is equalized among respective channels by the same amount (T. Inui et al. “Adaptive dispersion slope equalizer using a nonlinearly chirped fiber Bragg grating pair with a novel dispersion detection technique”, IEEE Photon. Technol. Lett., vol. 14, no. 4, P. 549 (2002), H. Ooi et al., “40-Gbit/s WDM automatic dispersion compensation with virtually imaged phased array (VIPA) variable dispersion compensators”, IEICE Trans. Commun., vol. E85-B, no. 2, p. 463 (2002)).
A reverse dispersion fiber (RDF) which has been developed recently (K. Mukasa et. al., “Novel network fiber to manage dispersion at 1.55 μm with combination of 1.3 μm zero dispersion single mode fiber”, ECOC'97, 1, p. 127 (1997)) is a fiber in which a dispersion/a dispersion slope are provided with signs reverse to the sign of the 1.3 μm zero dispersion optical fiber (single mode fiber: SMF) and absolute values thereof are near to those of SMF. By combining RDF with SMF, a transmission line in which both of dispersion and dispersion slope are near to zero can be realized. Therefore, a transmission line combined with SMF and RDF is used in WDM transmission (K. Yonenaga et al., “Dispersion-compensation-free 40 Gbit/s×4-channel WDM transmission experiment using zero-dispersion flattened transmission line”, OFC'98, PD20 (1998), E. Yamada et al., “106 channel×10 Gbit/s, 640 km DWDM transmission with 25 GHz spacing with supercontinuum multi-carrier source”, Electron. Lett., vol. 37, p. 1534 (2001)), and in ultra high speed OTDM transmission (M. Nakazawa et al., “1.28 Tbit/s-70 km OTDM transmission using third- and fourth-order simultaneous dispersion compensation with a phase modulator”, Electron Lett., vol. 36, p. 2027 (2000)). Further, RDF is utilized not simply as a transmission medium but a fiber for Raman amplification by utilizing the fact that a core diameter thereof is smaller than that of SMF or a dispersion-shifted fiber (H. Kawakami et al., “Highly efficient distributed Raman amplification system in a zero-dispersion flattened transmission line”, OA&A'99, ThB5 (1999), E. Yamada et al., “106 channel×10 Gbit/s, 640 km DWDM transmission with 25 GHz spacing with supercontinuum multi-carrier source”, Electron Lett., vol. 37, p. 1534 (2001)).
Although it has been known that the dispersion of the optical fiber is provided with temperature dependency, the temperature dependency of the dispersion slope has not been investigated. However, it has been known that a fiber having negative dispersion/dispersion slope as in RDF is provided with temperature dependency of the dispersion slope, that is, the wavelength dependency of the temperature dependency of the dispersion which cannot be disregarded. When a high speed/wide bandwidth WDM transmission line is constructed by SMF and RDF without taking the characteristic into consideration, a dispersion having a different value among channels is lo produced by temperature change exceeding an allowable dispersion value depending on channels.
<Temperature Dependency of Dispersion Slope of RDF>
In this case, when changes of dispersions at wavelengths λ1 and λ2 in the case of changing temperature of the fiber from T1 to T2 are observed, when the dispersion curves are shifted by temperature change, in the case of SMF of
<Influence Effected by Temperature Dependency of Dispersion Slope>
When a wavelength bandwidth of an optical signal in an optical transmission system is defined as Δλ(nm) and a temperature dependency constant and a length of a dispersion slope of a transmission optical fiber are defined respectively as αT(ps/nm2/km/deg) and L(km) and a temperature variation is defined as ΔT(deg), a dispersion change amount difference ΔD(ps/nm) is represented by the following equation.
ΔD=αT·L·ΔT·Δλ (2)
Therefore, for example, when a transmission line is provided with a value αT=1.48×10−5(ps/nm2/km/deg) similar to that of RDF and the optical fiber length is set to L=100(km), the temperature change is set to ΔT=50(deg) and the wavelength bandwidth is set to Δλ=100(nm), the dispersion change amount difference becomes ΔD=62.5(ps/nm). That is, even when the dispersion is set to 0 in a total range of the wavelength bandwidth of 100 nm at an initial time of operating a WDM transmission system and a variation amount of the dispersion is compensated by an adaptive type dispersion equalizer by the same amount over a total wavelength bandwidth, by the temperature dependency of the dispersion slope, a difference of a dispersion of 62.5(ps/nm) is produced between channels of the shortest wavelength and the longest wavelength. In this case, application to a WDM transmission system (allowable dispersion of about 40 ps/nm) of 40 Gbit/s/ch becomes difficult.
As described above, a dispersion of a value which differs among channels is produced by a temperature change in WDM transmission of high speed/wide bandwidth by the temperature dependency of the dispersion slope provided to the optical fiber. Therefore, even when the variation amount of the dispersion is compensated by the adaptive type dispersion equalizer by the same amount over a total wavelength bandwidth, there poses a problem that the variation amount exceeds the allowable dispersion value depending on channels.
It is an object of the invention to monitor and compensate a wavelength dependency of a temperature dependency of a dispersion, in other words, a temperature dependency of a dispersion slope in a WDM optical transmission system.
According to a first aspect of the invention, in a dispersion monitoring method according to the invention, there is provided a method of monitoring a dispersion on a transmission optical fiber in a wavelength division multiplexing optical transmission system, the method comprising the steps of extracting two or more of wavelength channels 1 to n from the transmission optical fiber and monitoring dispersions of the extracted wavelength channels.
Here, the step of monitoring the dispersions can include the steps of measuring a first dispersion value in the extracted wavelength channels 1 to n (wavelength:λmon1 to λmonn) at a certain temperature T1(° C.), measuring a second dispersion value in the wavelength channels 1 to n at a certain other temperature T2(° C.), providing dispersion variation amounts ΔDmon1 to ΔDmonn in the extracted wavelength channels 1 to n from a difference between the measured first dispersion value and the measured second dispersion value, and a step of providing a dispersion variation amount at an arbitrary wavelength (λ) based on the provided dispersion variation amounts ΔDmon1 to ΔDmonn.
Here, the n may be 2 and the step of providing the dispersion variation amount can calculate a dispersion variation amount ΔD(λ) in an arbitrary wavelength (λ) by the following equation.
Further, the step of monitoring the dispersions can include the steps of measuring a first dispersion value in a desired wavelength channel at a certain temperature T1(° C.), measuring a second dispersion value in the desired wavelength channel at a certain other temperature T2(° C.), and a step of providing a dispersion variation amount in the desired wavelength channel from a difference between the measured first dispersion and the measured second dispersion value.
According to a second aspect of the invention, in a dispersion slope temperature dependency compensating method according to the invention, there is provided a method of compensating a temperature dependency of a dispersion slope in a wavelength division multiplexing optical transmission system, the method comprising the steps of providing the dispersion variation amount ΔD(λ) by the above-described method and compensating the temperature dependency of the dispersion slope by using the provided dispersion variation amount ΔD(λ).
Here, the step of compensating the temperature dependency of the dispersion slope can include the steps of dividing a signal light on the transmission optical fiber to one or more wavelength channel groups constituted by at least one wavelength channel, and compensating the dispersion in accordance with each of the divided one or more wavelength channel groups.
Further, the step of compensating the dispersion can be carried out by using one or more tunable dispersion equalizers with a fiber Bragg grating.
Further, the step of compensating the dispersion can be carried out by using one or more tunable dispersion equalizers with a filter.
Further, the step of compensating the temperature dependency of the dispersion slope can summarizingly compensate a wavelength dependency of the temperature dependency of the dispersion in all of bandwidths in a wavelength division multiplexing optical transmission system.
Further, the step of compensating the temperature dependency of the dispersion slope can be carried out by using one or more tunable dispersion equalizers with a fiber Bragg grating.
Further, the step of compensating the temperature dependency of the dispersion slope can include the step of providing a temperature change in a dispersion compensating optical fiber installed at an optical node.
According to a third aspect of the invention, in a dispersion monitoring apparatus according to the invention, there is provided a dispersion monitoring apparatus for monitoring a dispersion on a transmission optical fiber in a wavelength division multiplexing optical transmission system, the dispersion monitoring apparatus comprising extracting means for extracting two or more of wavelength channels from the transmission optical fiber and monitoring means for monitoring dispersions of the extracted wavelength channels.
According to a fourth aspect of the invention, in a dispersion slope temperature dependency compensating apparatus according to the invention, there is provided a dispersion slope temperature dependency compensating apparatus for compensating a temperature dependency of a dispersion slope in a wavelength division multiplexing optical transmission system, the dispersion slope temperature dependency compensating apparatus comprising monitoring means for monitoring dispersions of two or more of wavelength channels on a transmission optical fiber, and compensating means for compensating a wavelength dependency of the temperature dependency of the dispersion in an arbitrary wavelength channel by using the monitored dispersions.
Here, the compensating means can include means for dividing a signal light on the transmission optical fiber into one or more wavelength channel groups constituted by at least one wavelength channel, and means for compensating the dispersion in accordance with each of the divided one or more wavelength channel groups.
Further, the compensating means can include one or more tunable dispersion equalizers with a fiber Bragg grating.
Further, the compensating means can include one or more tunable dispersion equalizers with a filter.
Further, the compensating means can summarizingly compensate the wavelength dependency of the temperature dependency of the dispersion in all of bandwidths in a wavelength division multiplexing optical transmission system.
Further, the compensating means can include one or more tunable equalizers with a fiber Bragg grating.
Further, the compensating means can include a dispersion compensating optical fiber installed in an optical node, and means for providing a temperature change to the dispersion compensating optical fiber.
According to the invention, a wavelength division multiplexing optical transmission system without a deterioration in a transmission characteristic by an influence of a temperature dependency of a dispersion slope can be realized.
The above and other objects, effects, features and advantages of the present invention will become more apparent from the following description of embodiments thereof taken in conjunction with the accompanying drawings.
The dispersion slope temperature dependency compensating apparatus includes a dispersion detection apparatus and a tunable dispersion equalizer 406. The dispersion detection apparatus includes a wavelength tunable filter 408, an optical coupler 409, dispersive media 410 and 412, nonlinear photo-detecting means 414, a difference signal outputting means 416 and a controller 404. The wavelength tunable filter 408 is constituted to be able to set a wavelength of light to be picked up. The dispersion media 410 and 412 use media having the same absolute value D of a dispersion value and signs different from each other. The nonlinear photo-detecting means 414 outputs a voltage in proportion to a square of an intensity of light. The difference signal outputting means 416 detects a difference between output voltages of the nonlinear photo-detecting means 414 and outputs a difference signal (voltage difference).
In order to know an influence amount of temperature dependency of a dispersion slope, dispersion variations of two channels are monitored. For example, by controlling the wavelength tunable filter 408 by the controller 404 comprising PC (personal computer) of the dispersion detection apparatus while setting a center wavelength thereof to extract a monitor channel 1(λmon1), a dispersion value in λmon1 at a certain temperature T1(° C.) is measured. Light having a wavelength λmon1 which has passed the wavelength tunable filter 408 is branched at the optical coupler 409 and inputted to the dispersion media 410 and 412. Light which has passed the dispersion medium 410 is broadened in a pulse width thereof, light which has passed the dispersion medium 412 is reduced in a pulse width thereof and these are inputted to the nonlinear photo-detecting means 414. The difference signal outputting means 416 calculates a dispersion value from a difference between outputs of the two nonlinear photo-detecting means 414 and stores the dispersion value to the controller 404.
Similarly, the center wavelength of the wavelength tunable filter 408 is set to extract a monitor channel 2 (λmon2), a dispersion value in λmon2 at T1 (° C.) is measured and the dispersion value is stored to the controller 404.
Next, the dispersion detection apparatus measures a dispersion value in λmon1 when there is a change in environment (temperature change) to change from the temperature T1(° C.) to a certain temperature T2(° C.), and outputs the dispersion value to the controller 404. The controller 404 calculates a difference between the dispersion value in λmon1 at temperature T1(° C.) and the dispersion value in λmon1 at T2(° C.) to provide a dispersion variation amount ΔDmon1.
Similarly, measurement of a dispersion value T2(° C.) in λmon2 is carried out. Then, a dispersion variation amount ΔDmon2 in λmon2 is derived from a difference between the dispersion value at temperature T2(° C.) and the dispersion value at temperature T1(° C.).
As shown in
From a result of the calculation, adaptive dispersion equalization is carried out by controlling the tunable dispersion equalizer 406 by the controller 404 to provide an appropriate dispersion compensation amount in WDM channel.
When the dispersion is monitored more finely, or when the dispersion slope temperature dependency of the transmission optical fiber cannot be approximated by a linear line, there may be constructed a constitution in which the dispersion is monitored in wavelength channels of a number larger than two and appropriate dispersion compensation amounts are provided to respective channels.
A differential amplifier 616 detects a difference between output voltages of Si-APDs 614 of the two paths and outputs a difference signal (voltage difference). The difference signal shows a value in accordance with a magnitude of the dispersion (chirp) and therefore, the difference signal can detects and measures the dispersion of the transmission optical fiber.
In order to measure temperature dependency of a dispersion slope of the transmission optical fiber, dispersion variations of two channels in a WDM signal are monitored. A wavelength tunable filter 608 is installed before a branch to the two paths in the dispersion detection apparatus, the filter is controlled by a controller 604 comprising PC (personal computer) and a center wavelength thereof is set to extract a monitor channel 1 (λmon1) 5 Further, a dispersion value in λmon1 at a certain temperature T1(° C.) is measured and the dispersion value is stored to the controller 604. Similarly, the center wavelength of the wavelength tunable filter is set to extract a monitor channel 2(λmon2), a dispersion value λmon2 at T1(° C.) is measured and the dispersion value is stored to the controller 604.
Next, a dispersion value in λmon1 when there is a change in temperature to constitute a certain temperature T2(° C.) is measured and a dispersion variation amount ΔDmon2 in λmon1 is derived from a difference from a dispersion value at temperature T1(° C.). Similarly, measurement of a dispersion value at T2(° C.) in λmon2 is carried out. Then, a dispersion variation amount ΔDmon2 in λmon2 is derived from a difference between the dispersion value at temperature T2(° C.) and the dispersion value at temperature T1(° C.).
When the dispersion slope temperature dependency of the transmission optical fiber can be approximated by a linear line, a dispersion variation amount ΔD(λ) in a certain arbitrary wavelength (λ) is represented as follows 25 and therefore, the dispersion variation amounts, that is, dispersion amounts to be compensated in respective wavelength channels are known from the equation.
In a transmission line in which a transmission optical fiber of a wavelength division multiplexing optical transmission system is constituted by SMF and RDF, there is constructed a constitution of using a dispersion detection apparatus described as a dispersion variation amount monitoring method in T. Inui, K. R. Tamura, K. Mori and T. Morioka, “Bit rate flexible chirp measurement technique using two-photon absorption”, Electronic Letters, vol. 38, no. 23., 7 Nov. 2002, similar to the first embodiment shown in
Center wavelengths of a wavelength tunable filter are set one by one for all of wavelength channels by the controller 604 comprising PC (personal computer) and dispersion values are monitored. For example, in a wavelength division multiplexing optical transmission system comprising 32 channels, dispersion values in wavelength channels 1 to 32 (λmon1 to λmon32) at a certain temperature T1(° C.) are measured and the dispersion values are stored to the controller 604. Next, by measuring dispersion values in λmon1 to λmon32 when a certain other temperature T1(° C.) is constituted, dispersion variation amounts ΔDmon1 to ΔDmon32 in all of the wavelength channels λmon1 to λmon32 can be monitored by differences from the dispersion values at temperature T1(° C.) for the respective wavelength channels. By monitoring the dispersion variation amounts of the respective channels, appropriate dispersion compensation amounts in the respective channels can be known.
In a transmission line in which a transmission optical fiber of a wavelength division multiplexing optical transmission system is constituted by SMF and RDF, there is constructed a constitution of using a dispersion detecting apparatus described as a dispersion variation amount monitoring method in T. Inui, K. R. Tamura, K. Mori and T. Morioka, “Bit rate flexible chirp measurement technique using two-photon absorption”, Electronics Letters, vol. 38, no. 23, 7 Nov. 2002, similar to the first embodiment shown in
Center wavelengths of a wavelength tunable filter are set one by one for a plurality of wavelength channels by the controller 604 comprising PC (personal computer) and dispersion values are monitored. For example, in a wavelength division multiplexing optical transmission system comprising 128 channels, dispersion values in monitor channels 1 to 32 (λmon1 to λmon32) at certain intervals (at intervals of 4 channels in this case) at a certain temperature T1(° C.) are measured and the dispersion values are stored to the controller 604. Next, by measuring dispersion values in λmon1 to λmon32 when a certain other temperature T2(° C.) is constituted, dispersion variation amounts ΔDmon1, to ΔDmon32 in wavelength channels of λmon1 to λmon32 at intervals of 4 channels are monitored from differences from the dispersion values at temperature T1(° C.). There is constructed a constitution of calculating a dispersion variation amount ΔD(λ) at a certain arbitrary wavelength (λ) by plotting values of the dispersion variation amounts on a graph and providing an approximated curve thereof by, for example, a least squares method.
The dispersion variation monitoring method can deal with also a case in which the dispersion slope temperature dependency of the transmission optical fiber cannot be approximated by a linear line.
The differential amplifier 616 outputs a difference signal (voltage difference) by detecting a difference between output voltages of Si-APDs 614 of the two paths. The difference signal shows a value in accordance with a magnitude of dispersion (chirp) and therefore, a dispersion of the transmission optical fiber can be detected and measured. Dispersion compensation can be carried out by controlling the tunable dispersion equalizer 606 in the controller 604 comprising PC (personal computer) by using the difference signal.
In order to measure temperature dependency of a dispersion slope of the transmission optical fiber, dispersion variation amounts of two channels in a WDM signal are monitored. The wavelength tunable filter 608 is installed before a branch to the two paths in the dispersion detection apparatus and a center wavelength thereof is set to extract a monitor channel 1(λmon1 ) by controlling a filter by the controller 604. Further, a dispersion value in λmon1 at a certain temperature T1(° C.) is measured and a dispersion value is stored to the controller 604. Similarly, the center wavelength of the wavelength tunable filter is set to extract a monitor channel 2 (λmon2), a dispersion value in λmon2 at T1(° C.) is measured and the dispersion value is stored to the controller 604.
Next, when -there is a change in environment (temperature change) to change from the temperature T1(° C.) to a certain temperature T2(° C.), a dispersion value in λmon1 is measured and a dispersion variation amount ΔDmon1 in λmon1 is derived from a difference from the dispersion value at temperature T1(° C.). Similarly, measurement of a dispersion value at T2(° C.) in λmon2 is carried out. Then, a dispersion variation amount ΔDmon2 in λmon2 is derived from a difference between the dispersion value at temperature T2(° C.) and the dispersion value at temperature T1(° C.).
When the dispersion slope temperature dependency of the transmission optical fiber can be approximated by a linear line, a dispersion variation amount ΔD(λ) in a certain arbitrary wavelength (λ) is represented as follows and therefore, dispersion variation amounts, that is, dispersion amounts to be compensated in respective wavelength channels are known from the equation.
An optical signal transmitted through the transmission optical fiber is branched to respective wavelength channels by an arrayed waveguide grating (AWG) 607 and inputted to the tunable dispersion equalizer 606. Further, dispersion variation amounts in accordance with respective channels derived from the above-described calculation are compensated by controlling a tunable dispersion equalizer 606 by the controller 604. The tunable dispersion equalizer 606 in which a dispersion of a chirped fiber Bragg grating is made variable by using a heater can be used. When this is illustrated, as shown by
The optical signal transmitted to the transmission optical fiber may be divided into one or more wavelength channel groups constituted by a plurality of wavelength channels by an arrayed waveguide grating (AWG). In this case in a constitution shown in
In the constitution shown in
In the constitution shown in
According to the embodiment, as shown in
A tunable dispersion equalizer 806 of a dispersion slope temperature dependency compensating apparatus introduces an optical signal on the transmission optical fiber to a chirped fiber Bragg grating 803 by an optical circulator 804 and outputs the optical signal again to the transmission optical fiber. As shown in
In the constitution shown in
As shown in
An optical fiber accommodation apparatus 1202 of the invention includes a temperature control circuit 1204 and contains a dispersion compensating fiber 1208 in an optical node. The transmission optical fiber is provided with a length of L1(km) and a dispersion slope temperature constant of αT1(ps/nm2/km/deg) and the dispersion compensating fiber in the optical fiber accommodation apparatus is provided with a length of L2(km) and a dispersion slope temperature constant of αT2(ps/nm2/km/deg). When a wavelength bandwidth of an optical system in an optical transmission system is Δλ(nm) and a range of an allowable dispersion in the transmission system is equal to or larger than −ΔD0(ps/mn, however, ΔD0>0) and equal to or smaller than ΔD0 and a temperature change throughout a year to which the transmission optical fiber is subjected is ΔT1(deg), a temperature change ΔT2(deg) to which the dispersion compensating fiber 1208 is subjected is set to satisfy the following equation by using the temperature control circuit 1204.
|αT1·L1·ΔT1+αT2·L2·ΔT2|·Δλ≦ΔD0 (4)
Thereby, the influences of the temperature dependencies of the dispersion slopes of the transmission optical fiber 1206 and the dispersion compensating fiber 1208 can be restrained.
The present invention has been described in detail with respect to preferred embodiments, and it will now be apparent from the foregoing to those skilled in the art that changes and modifications may be made without departing from the invention in its broader aspect, and it is the intention, therefore, in the apparent claims to cover all such changes and modifications as fall within the true spirit of the invention.
Number | Date | Country | Kind |
---|---|---|---|
2002-214575 | Jul 2002 | JP | national |