JPH02144506A - Start type optical transmission system - Google Patents

Abstract

PURPOSE:To suppress the variation of a speckle pattern and to obtain stable coupling characteristics by using a dynamic single-mode laser diode which oscillates in single longitudinal mode in modulation as the light source of an optical transmitter and using a single-mode optical fiber between the input part optical fiber of a start coupler and the optical transmitter. CONSTITUTION:The distribution feedback type laser with wavelength lambda which oscillates in single longitudinal mode even in fast modulation is used as the light source of the optical transmitter 1 to remove model noises due to the oscillation spectrum variation. Then the input part optical fibers 5, 10, and 11 of the start coupler 4 and the optical transmitter 1 are connected by an up optical fiber 15 which uses a single-mode optical fiber to prevent a speckle pattern from being formed in the output end surface of the up optical fiber 15. The single mode optical fiber has a smaller core diameter than a multi-mode optical fiber, so the stable coupling of the speckle pattern is performed in the output end surface of the up optical fiber 15. Consequently, the generation of modal noises is reduced and stable coupling characteristics are obtained.

Description

[Detailed Description of the Invention] (Industrial Application Field) This invention relates to a star-type optical transmission system that performs optical fiber transmission using an optical transmission device that uses a star coupler as a center node and a laser diode (LD) as a light source. It is.

[Conventional technology]

Figure 5 shows, for example, "Toshiba Review" Vol. 40, No. 7 (Showa 6).
0) is a diagram showing the configuration of a conventional star-shaped optical transmission system disclosed in "Wavelength Multiplexing Optical Star Network" by P. P., 627-629. In the figure, (1) is a transmitting device, and (2) is a laser diode (LD).

(3) is an upstream optical fiber using a multimode optical fiber, (4) is a star coupler for multimode optical fiber, (5), (10), and (11) are input optical fibers of star coupler (4). , Iba, (6) is a star coupler (
(4) is the mixer section, (7), (8), (9) are the output optical fibers of the star coupler (4), (12) is the downlink optical fiber using a multimode optical fiber, (13)
) is a receiver (X device, and (14) is a light receiving element.

FIG. 6 is an explanatory diagram showing the operation of the star-shaped optical transmission system of FIG. 5. In the figure, (3a) is the upstream optical fiber (3
), (5a) is the core outer diameter of one end of the input optical fiber (5), (5b) is the core outer diameter of the other end of the input optical fiber (5), (7a) is the output optical fiber Fiber (1)
is the outer diameter of the core. In addition, the same reference numerals as in FIG. 5 indicate the same or corresponding parts, and detailed explanation thereof will be omitted.

Next, the operation of the conventional star-shaped optical transmission system described above will be explained. The transmitter (1) converts the transmission signal into an optical signal with a wavelength λ using a laser diode (2), and transmits the light (
The signal is output to an upstream optical fiber (3) using a multimode optical fiber exhibiting multimode transmission characteristics for No. 8.

The laser diode (2) is a normal Fabry-Perot type, and oscillates in multiple longitudinal modes during modulation. The upstream optical fiber (3) is connected to the human power optical fiber (5) of the star coupler (4) for multimode optical fiber. The optical signal input to the input optical fiber (5) is manually input to the mixer section (6).
During propagation, the beam expands and is in principle evenly distributed and coupled to a plurality of output optical fibers (7), (3), and (9). Other input optical fiber (10), (
11), the output of each optical fiber is evenly distributed and coupled to the output optical fibers (7), (81, (9), and then the human power optical fibers (5), (10), (1)
1) and output optical fibers (7), (8), (
9) has multimode transmission characteristics with respect to wavelength λ.

The output optical fiber (7) of the star coupler (4) has a wavelength of λ
It is connected to a downlink optical fiber (12) using a multimode optical fiber that exhibits multimode transmission characteristics for optical signals. The optical signal transmitted to the downlink optical fiber (12) is optical-to-electrically converted by the light receiving element (14) of the receiving device (13), and the signal transmitted from the transmitting device (1) is received.

The laser diode (2) is a highly coherent light source, and when the optical signal output from the laser diode (2) is coupled to the upstream optical fiber (3) and transmitted, its output end face will be As shown in FIG. 2, the power intensity distribution within the core outer diameter (3a) becomes a speckle pattern with large grains due to the interference. Then, the core outer diameter (3a) of the upstream optical fiber (3) and the input optical fiber (5) of the star coupler (4) are connected.
) If there is an axis misalignment in the core outer diameter (5a) at one end,
Only some speckle patterns are combined. Also, at the end face of the connection part between the input part optical fiber (5) and the mixer part (6).

A speckle pattern is generated within the core outer diameter (5b) at the other end of the input optical fiber (5). Star coupler (4)
In the mixer section (6), the human power section optical fiber (5
) is propagated while undergoing multiple reflections on the wall surface of the mixer section (6), and a uniform optical power distribution is formed on the output end surface, but a speckle pattern still remains. As long as the speckle pattern described above is stable, stable optical power is coupled to the core outer diameter (a) of the output optical fiber (7).

(Problem to be solved by the invention) Since the conventional star-shaped optical transmission system is configured as described above, the optical fiber (3) may vibrate and the oscillation spectrum of the laser diode (2) may be distorted. Due to fluctuations in Laser diodes have the problem of changing the coupling ratio with fibers (7), (8), and (9), generating noise called modal noise, and deteriorating the S/N ratio of transmission No. 43. It is oscillating in longitudinal mode, and lo
During high-speed data transmission of OMb/s or higher, the oscillation spectrum varies for each pulse of transmitted data due to a phenomenon called mode distribution characteristics, and the influence of modal noise becomes even greater.

This invention was made to solve the above-mentioned problems, and speckles on the output end face of the mixer output section of the star coupler are caused by vibration of the optical fiber, temperature characteristics of the laser diode, or mode distribution characteristics. High S/ by suppressing pattern fluctuations and obtaining stable coupling characteristics.
The purpose of this invention is to obtain a star-shaped optical transmission system that can perform N-ratio signal transmission.

(Means for Solving the Problems) A star optical transmission system according to the present invention uses a dynamic single mode laser diode with a wavelength λ that oscillates in a single longitudinal mode during modulation as a light source of an optical transmitter, and a star coupler. The wavelength λ is
A single-mode optical fiber exhibiting single-mode transmission characteristics is used for connection with an upstream optical fiber.

(Function) In the star-shaped optical transmission system of the present invention, the wavelength λ that oscillates in a single longitudinal mode even during high-speed modulation is used as a light source of an optical transmitter.
By using a distributed feedback laser of By connecting with
In addition, single-mode optical fiber, which is the upstream optical fiber, has a smaller core diameter than multimode optical fiber, so the speckle pattern is stably coupled at the end surface of the connection between the upstream optical fiber and the star coupler, resulting in 5-modal noise. is reduced.

(Embodiment) FIG. 1 is a diagram showing the configuration of a star-shaped optical transmission system which is an embodiment of the present invention, FIG. 2 is an explanatory diagram showing the operation of the star-shaped optical transmission system of FIG. The same reference numerals as those in the figures and FIG. 6 indicate the same or corresponding parts, and detailed explanation thereof will be omitted. In FIG. 1, (15) is an optical fiber using a single mode optical fiber. Moreover, in FIG. 2, (15a) is the core outer diameter of the upstream optical fiber (15).

(16) is a dynamic single mode laser diode that oscillates in a single longitudinal mode during modulation.

Next, the operation of the star optical transmission system which is an embodiment of the present invention will be described. When transmitting signals from an optical transmitter (1) via a star coupler (4) for multimode optical fiber, modal noise generation factors include speckle patterns due to vibration of the optical fiber and fluctuations in the emission spectrum of the light source. There are fluctuations.

First, consider the effect when the upstream optical fiber (15) vibrates in FIG. 1.

As shown in FIG. 1, in the upstream optical fiber (15) using a single mode optical fiber, the mode excited from the dynamic single mode laser diode (16) is a single mode, so the star coupler ( 4) No speckle pattern is generated on the end surface of the connection part with the human power section optical fiber (5). On the other hand, when the human power section optical fiber (5) of the star coupler (4) is a multimode optical fiber, a speckle pattern is formed on the end surface of the connection part between the human power section optical fiber (5) and the mixer section (6). occurs. However, since the upstream optical fiber (15) is a single mode optical fiber, the optical fiber (15) vibrates and
However, the speckle pattern on the end face of the connection between the mixer section (6) and the input section optical fiber (5) does not change. Therefore, the mixer section (6) and the output section optical switch? Since the speckle pattern on the end face of the connecting portion of the fiber (7) does not vary and stable coupling characteristics are obtained, the generation of modal noise is reduced.

Next, consider the influence of fluctuations in the emission spectrum of the light source. Fluctuations in the emission spectrum can be classified into emission spectrum variations due to mode distribution characteristics during high-speed modulation and emission wavelength variations due to temperature. Speckle pattern fluctuations caused by fluctuations in emission wavelength due to temperature are generally slow enough, and the noise caused by them is small, so they will be ignored here. Sx
In the figure, the light source of the optical transmitter (1) is a dynamic single-mode laser diode (16) that oscillates in a single longitudinal mode during modulation. There are no fluctuations in the emission spectrum due to Therefore, the speckle patterns generated at the connections between the mixer section (6) and the input optical fiber (5) and between the mixer section (6) and the output optical fiber (7) do not change, and the mixer section (
6) and the output optical fiber (7) are obtained, and modal noise is reduced.

FIG. 3 is a diagram showing the configuration of a star-shaped optical transmission system according to another embodiment of the present invention, and FIG. 4 is an explanatory diagram showing the operation of the star-shaped optical transmission system of FIG. 3. In the embodiment shown in FIG. 3, the input optical fiber (17) of the star coupler (4) is
), and according to this embodiment, the occurrence of the above-mentioned modal noise is further reduced.

Further, as shown in FIG. 4, if the input optical fiber (17) of the star coupler (4) is a single mode optical fiber, speckles will appear on the end surface of the connection between the input optical fiber (17) and the mixer section (li). No pattern occurs. Therefore,
Even when vibration is applied to the star coupler (4), the excitation of the mixer section (6) is stably performed from the human power section optical fiber (17), so that the mixer section (6) and the output section optical fiber (7) , (8) and (9), the speckle pattern on the end face of the connection part is stable and no modal noise occurs. Here, (17a) in FIG. 4 is the core outer diameter of the input optical fiber (17).

In the above embodiment, the case where the transmitting unit fiffi (1) is Urajiro is explained, but if a plurality of transmitting units fiffi (1)
) and the star coupler (4) may be connected by an upstream optical fiber (15) using a plurality of single mode optical fibers, and the same effect as in the above embodiment can be achieved.

Furthermore, in the above implementation color, the transmitting device (1) may be a transmitting section of a repeater, the receiving device (13) may be a receiving section of a reheater, and signal transmission to red and white the star coupler (4) is possible. , it is possible to achieve transmission with reduced generation of modal noise, similar to the above embodiment.

〔Effect of the invention〕

As explained above, the present invention uses a dynamic single 1,000-laser diode that oscillates in the east-longitudinal mode during modulation as a light source of an optical transmitter in a star-type optical transmission system, and also uses an optical fiber in the human power section of a star coupler. and the optical transmitter are connected by an upstream optical fiber using a single-mode optical fiber that exhibits single-mode transmission characteristics for the wavelength λ, so there is a speckle pattern on the end surface of the connection between the upstream optical fiber and the star coupler. This provides an excellent effect in that stable coupling is performed, and thereby signal transmission can be performed in which modal and noise generation is suppressed.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing the configuration of a star-shaped optical transmission system that is an embodiment of the present invention, FIG. 2 is an explanatory diagram showing the operation of the star-shaped optical transmission system of FIG. 1, and FIG. FIG. 4 is a diagram showing the configuration of a star-shaped optical transmission system as another embodiment.
FIG. 5 is an explanatory diagram showing the operation of the star-shaped optical transmission system shown in FIG. 5. FIG. 5 is an explanatory diagram showing the configuration of the conventional star-shaped optical transmission system. FIG. is 0
In the figure, (1)... transmitter, (3)... uplink optical fiber using multimode optical fiber, (4)... star coupler for multimode optical fiber, (5), (10)... ), (11)... Input optical fiber, (7), (8), (9)... Output optical fiber, (12)... Downlink optical fiber using multimode optical fiber, ( 13)... Receiving device, (14)... Light receiving element, (15)... Uplink optical fiber using single mode optical fiber, (16)... Single longitudinal mode oscillation during modulation. Dynamic single mode laser diode, (17)...This is a manual optical fiber using a single mode optical fiber. In addition, in the figures, the same reference numerals indicate the same or corresponding parts. Agent Masuo Oiwa Procedural amendment (voluntary) 2. Name of the invention Star optical transmission system 3. Name of the person making the amendment (601) Moriya Shiki, representative of Mitsubishi Electric Corporation. 4. Fence of claims in attorney's specification. 6. Contents of the amendment The scope of claims in the specification will be amended as shown in the attached sheet. 7. A document stating the amended scope of claims in the list of attached documents IA or above A document stating the amended scope of claims In a star network with a star coupler as the center node, an optical signal passing through the star coupler On the other hand, a star coupler equipped with an optical fiber showing a multi-mode transmission at the input and output parts,
An optical transmitting device having a dynamic single mode laser diode with a wavelength λ that oscillates in a single longitudinal mode during modulation, and a single mode transmission characteristic for the wavelength λ connecting between the optical transmitting device and the star coupler. an upstream optical fiber having
1. A star-shaped optical transmission system, comprising: an optical receiver; and a downlink optical fiber having multimode transmission characteristics for a wavelength λ that connects the optical receiver and the star coupler.

Claims (1)

[Claims] In a star network with a star coupler as the center node,
A star coupler with optical fibers at the input and output sections that exhibit multimode transmission for optical signals passing through the star coupler, and a dynamic single mode laser diode with a wavelength λ that oscillates in a single longitudinal mode during modulation as a light source. an optical transmission device, an uplink optical fiber having a single mode transmission characteristic for a wavelength λ connecting the optical transmission device and the star coupler, an optical reception device, and an optical reception device and the star coupler. A star-shaped optical transmission system characterized by comprising a downlink optical fiber having multimode transmission characteristics for the wavelength λ connecting between the two.