JPS6317434A - Method and device for light signal amplification - Google Patents

Abstract

PURPOSE:To amplify a frequency multiplex signal without spoiling reliability, etc., by generating a frequency component required to amplify frequency multiplex signal light by imposing proper modulation on an exciting signal source. CONSTITUTION:Light signals emitted by signal light sources 11-13 are phase- modulated by a phase shift quantity pi with binary code electric pulses applied to electric signal input terminals 31-33 of external modulators 21-23. Respective frequencies of the respective phase-modulated light signals are fs1-fs3 and the light signals are multiplexed by an optical multiplexer 5 and coupled with an optical fiber 4. On the other hand, frequency modulation is imposed on an excitation light source 8 so that frequency components fp1-fp3 are generated by a modulating power source 9 and fpi-fsi=nuB (i=1-3 and nuB is the Brillouin shift quantity of the optical fiber). Then this exciting light is coupled with the fiber 4 through a directional coupler 6. Signal light amplified by the induction Brillouin effect in the fiber 4 is separated and extracted by an optical demultiplexer 7 as exciting light.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an optical signal amplification method for amplifying signal light within an optical fiber using the stimulated Brillouin effect of an optical fiber, and an apparatus for implementing the method.

[Conventional technology]

With the recent development of high-performance single-axis mode semiconductor lasers and low-loss single-mode optical fibers, transmission speeds have increased to 2G.
A high-speed, long-distance optical communication system with a speed of more than b/s and a transmission distance of more than 1001 is now possible at the laboratory level. In order to take advantage of the broadband properties of optical fibers and further expand transmission capacity, consideration is being given to frequency division multiplexing optical communication systems that multiplex and transmit multiple lights of different frequencies at high density.

In this frequency multiplexing optical communication system, an optical multiplexing/demultiplexing circuit is not required in order to multiplex/demultiplex signal lights having close frequencies. However, the current optical multiplexing/demultiplexing circuit has a large insertion loss, which causes the problem that the transmission distance cannot be increased in the frequency division multiplexing optical communication system.

As a method of compensating for such insertion loss, research on optical amplification that directly amplifies signal light has been actively conducted in recent years. One promising method is a method that uses the stimulated scattering effect of optical fibers [Optical Engineering, Vol. 24, 1985, pages 600-608]. The stimulated scattering effect used is the stimulated Raman effect. , the induced Brillouin effect, and the induced photon mixing effect. Among them, the stimulated Brillouin effect is the most useful because it has a very large amplification gain coefficient, so compared to other stimulated scattering effects, it can obtain a large amplification even with a small pumping light power. It is.

To amplify signal light using this stimulated Brillouin effect, pump light whose frequency is higher than the frequency of the signal light by the amount of Brillouin shift is incident on the optical fiber so that it propagates in the opposite direction of the signal light. . The amplification degree G obtained at this time is expressed by the following equation.

G-exp (gl ・-・L,)・・・・・・・・・
・・・・・・・・・(1) α However, g is the induced Brillouin gain coefficient of the peak (4,
6×1Q-11m/W), P is the pumping input power to the optical fiber, A is the core effective cross-sectional area, α is the transmission loss of the optical fiber, and l is the fiber length. Here, L gives the net fiber length contributing to amplification and is called the effective length.

[Problem that the invention seeks to solve]

Optical signal amplification using the stimulated Brillouin effect is characterized in that a large amplification degree can be obtained with a low pumping input, as described above. However, the gain bandwidth (Brillouin gain bandwidth) is as narrow as several tens of MHz at most, and it has been difficult to amplify frequency-multiplexed signal light in the past.

As a solution to this problem, for example, it is possible to use a plurality of excitation light sources corresponding to signal lights of respective frequencies. However, the use of a plurality of excitation light sources has disadvantages in that the apparatus becomes bulky and expensive. Furthermore, a large number of excitation light sources must be maintained, which creates a new problem that significantly impairs the reliability of this device.

The object of the present invention is to provide an optical signal amplification method using the induced Brillouin effect in an optical fiber, which eliminates the conventional drawbacks as described above and makes it possible to amplify frequency-multiplexed signal light without impairing reliability or the like. The objective is to provide a device for implementing this.

[Means for solving problems]

In the optical signal amplification method of the present invention, excitation light is input from one end of an optical fiber, and each frequency is fsi (i-L 2+ . . . from the other end of the optical fiber).

In the optical signal amplification method of inputting a signal light of N) and amplifying the signal light by the stimulated Brillouin effect within the optical fiber, at least fI, 1 (i=1.2... . . . , N), and f, , −fs 丑νm (
i=1.2. . . . , N)(νl: Characterized by satisfying the Brillouin shift condition of the optical fiber.

An optical signal amplification device of the present invention includes an optical fiber, a pumping light source that emits pumping light to be input to one end of the optical fiber,
Each frequency is fs(i=1゜2,...
N) means for multiplexing the signal light and inputting the multiplexed signal light from the other end of the optical fiber; and a means for separating the signal light amplified by the stimulated Brillouin effect in the optical fiber from the excitation light. at least fpt (
i=1.2. ......, N) frequency components, and fpi fsi= 2m (i
=1. 2. ...”, N) (ν3:
and a modulation means for modulating the excitation light source so as to satisfy a condition of the amount of Brillouin shift of the optical fiber.

[Effect]

In the optical signal amplification method and apparatus for carrying out the method of the present invention, the pumping light is modulated by an appropriate modulation means, and the pumping light is modulated by at least fpi (t = 11 21 . . . ).

N) frequency components are generated. As a result, f p
By setting i-f si' = ν3, it becomes possible to amplify frequency-multiplexed signal light even if there is only one pumping light source, and it is possible to realize optical signal amplification with excellent reliability at a low cost. .

In the present invention, when the optical power of the fpl frequency component generated by the modulation of the pumping light is P and A, the signal light having the frequency f1 can be amplified by the following.

Here, as a modulation method of the excitation light, at least r, ,
Since it is sufficient to generate frequency components of (i=1.2......,N), intensity modulation9 frequency modulation.

Any method such as phase modulation may be used.

In addition, in the present invention, since the excitation light is modulated, there is a possibility that the degree of amplification varies over time. However, in amplification using the stimulated Brillouin effect, the signal light propagates in the optical fiber in the opposite direction to the pumping light, so the effective length of the signal light increases, and the time required to propagate through the optical fiber is LII/ Time fluctuations with a period shorter than C do not occur.

Therefore, this problem can be avoided by making the modulation period sufficiently shorter than L#/C.

〔Example〕

Next, an optical signal amplification method of the present invention and an apparatus for implementing the method will be described in detail with reference to the drawings.

FIG. 1 shows an example of an optical signal amplification device used in an embodiment of the optical signal amplification method of the present invention. In this example, the configuration is such that three-wave multiplexed signal light is amplified.

In FIG. 1, the signal light sources 11, 12, 13 and the excitation light source 8 are all InGaAsP/
InP distributed feedback semiconductor laser, external modulator 21.22
．． 23 is LiNb0. The phase modulator and optical fiber 4 have a core diameter of lOμ- and a fiber length of 100 km.

It is a single mode silica fiber with a transmission loss of 0.38 dB/Iua at a wavelength of 1.3μ steel. The optical multiplexer 5 and the optical demultiplexer 7 are both made by creating Matsuhatsu Enda interference type optical waveguides on a LiNb01 substrate by Ti diffusion, and cascade-connecting them in two stages, and are equipped with optical fiber pigtails for input and output. ing. Here, the loss of this element is about 8d
It is B. Furthermore, the directional coupler 6 for making the excitation light enter the optical fiber 4 is a single mode optical fiber coupler with a branching ratio of 1:0.5.

In this example, the signal lights emitted from the semiconductor lasers 11, 12, and 13 are L i N b O
Electrical signal input terminal 31 of s-phase modulator 21.22.23
．． The phase is modulated to a phase shift amount π by a 32 Mb/s binary code electric pulse applied at 32°33.

Each frequency of each phase-modulated signal light is f 11+
fs! fs3, and the interval between the center frequencies of each signal light is set to 3 GHz. After being multiplexed by an optical multiplexer 5, the signals are coupled to an optical fiber 4.

On the other hand, the semiconductor laser 8 serving as the excitation light source is directly frequency-modulated by a modulation power source 9. Here, the amount of frequency deviation per unit current of this semiconductor laser is approximately 200 H.
z/mA. Therefore, in this embodiment, in order to realize the amplification of the frequency-multiplexed signal light mentioned above, 3GHz
Frequency modulation is performed by the applied current shown in FIG. 2 to produce spaced frequency components (r pi, f pz, f , s).

Further, the modulation period is about 15 ns, which is selected to be sufficiently smaller than L@/C. This excitation light is then coupled to the optical fiber 4 through the single mode optical fiber coupler 6. The signal light amplified by the stimulated Brillouin effect in the optical fiber 4 is separated from the excitation light by an optical demultiplexer 7 and extracted.

FIG. 3 is a diagram showing the relationship between the frequencies of the pumping light and the frequency-multiplexed signal light frequency-modulated by the applied current in FIG. 2. FIG. The frequencies of the excitation light and signal light are rp, fs
i = 13GH2 (i = 1.2.3) and the wavelength 1
．． The amount of Brillouin shift is made to match the amount of Brillouin shift in the 3 μm band.

In this example, the fiber input power of the pump light is approximately 6 mW.
The frequency components of fpt (i=1.2.3) at this time were each about 1 mW. A value of about 25 dB was obtained as the degree of amplification. This value almost coincided with the value estimated from equation (3).

Although the optical signal amplification method and optical signal amplification device according to the present invention have been described above using one embodiment, the present invention is not limited to this embodiment, and several modifications can be made.

For example, in this embodiment, frequency modulation is used as a modulation method for the excitation light source, but other modulation methods such as intensity modulation and phase modulation may be employed. In addition, the excitation light source 8 is made of InGa.
Although an AsP/InP semiconductor laser is used, semiconductor lasers made of other materials, or other types of lasers such as solid lasers and gas lasers may also be used. Furthermore, optical fibers, including dispersion-shifted fibers, include Ge0z + PgO
Optical fibers of other compositions may also be used, such as s.

Furthermore, it goes without saying that the optical multiplexer/demultiplexer or directional coupler may have any structure as long as it has the required performance.

〔Effect of the invention〕

As described above, in the optical signal amplification method and apparatus according to the present invention, frequency components necessary for amplification of frequency-multiplexed signal light are generated by applying appropriate modulation to the pumping light source.

As a result, there is an advantage that even if there is only one pumping light source, it is possible to amplify frequency-multiplexed signal light using the stimulated Brillouin effect. Further, there is an advantage that an optical signal amplification method and a device for carrying out the same can be obtained at low cost and with excellent reliability.

[Brief explanation of the drawing]

FIG. 1 is a block diagram of an embodiment of the present invention, FIG. 2 is a diagram showing a modulated current waveform of an excitation light source in an embodiment of the invention, and FIG. 3 is a diagram showing the modulation current waveform of an excitation light source in an embodiment of the invention. FIG. 3 is a diagram showing the relationship between the frequencies of light and signal light. 11.12.13... Signal light source 21.22.23... External modulator 31.32.33... Electric signal input terminal 4... Optical fiber 5... Optical multiplexer 6... Directional coupler 7...Optical demultiplexer 8...Excitation light source 9...Modulated power supply Attorney Yoshiyuki Iwasa -~ ^ -Shun-

Claims (2)

[Claims] (1) Pumping light is input from one end of the optical fiber, and each frequency is f_s (i=1
, 2, . f_p(i=1, 2,...
..., N), and f_p_i-f_s_i=ν_B(i=1, 2,...
..., N) (ν_B: Brillouin shift amount of an optical fiber). (2) An optical fiber, an excitation light source that emits excitation light that is input to one end of the optical fiber, and each frequency is f.
means for multiplexing the signal lights of __s_i (i=1, 2,..., N) and inputting the multiplexed signal lights from the other end of the optical fiber; and a guiding amplifier in the optical fiber. means for separating the signal light amplified by the pumping light from the pumping light, and at least f_p_i (i=1, 2
, ..., N), and f_p_i-f_s_i=ν_B(i=1, 2,...
. . , N) (ν_B: amount of Brillouin shift of the optical fiber).