DE4427090A1 - Optical signal transmission system for FM signals - Google Patents

Abstract

The optical transmitter handles frequency modulated signals and employs two lasers (1,2) interconnected by a coupling arrangement (3) and optical conductors (6,7). Each laser has a separate control unit (4,5). One unit (4) provides optical frequency modulation of the output of the first laser, while the second unit is used to regulate the intensity of the second laser output which is then transmitted. The optical conductor (7) supplies the second laser via a coupling stage (11).

Description

The invention relates to an optical transmission device for frequency modulated signals.

Frequency-modulated optical signals are e.g. B. in one EP-A-0 554 736 known optical transmission system. There, an FSK-modulated optical signal is transmitted to the Operating wavelength of dispersion-prone optical waveguide sent and one on the intensity curve of its optical Input signal responsive optical receiver supplied.

An FSK-modulated optical signal, i.e. one in its optical Frequency shift keyed optical signal (frequency shift keying, FSK), z. B. generated by a laser by a current is modulated directly with a small modulation stroke. At this Direct modulation of the laser occurs in addition to the desired one Frequency modulation in the optical signal an additional, possibly unwanted amplitude modulation.  

Furthermore, from H. Burkhard et al: "Multigigabit-per-second standard-fiber transmission by injection-locked directly modulated lasers", Optical Fiber Communication OFC'94, February 22 to 25, 1994, San Jose, California, Technical Digest Volume 4 a device known that emits an amplitude-modulated optical signal. In Fig. 1, an experimental setup is shown, can be reduced in the "slave" by injection of light of a "master" Lasers in a directly modulated laser, an undesired "chirp" to the extent that emerges from the "slave" laser only amplitude modulated light . "Chirp" means the frequency modulation associated with the amplitude modulation. For this purpose, a direct current is fed to the "master" laser. If the optical frequencies of both lasers are within a defined range, the optical frequency of the "slave" laser snaps into the optical frequency of the "master" laser. This is commonly known as "injection locking". With this structure, an amplitude-modulated optical signal is emitted. A frequency-modulated optical signal does not occur.

The invention has for its object an optical Transmission device for frequency-modulated optical signals specify where the unwanted amplitude modulation in emitted optical signal is significantly reduced. A the Objective optical transmission device is the subject of Claim 1. Advantageous embodiments of the invention are in specified in the subclaims.  

An advantage of the invention is that when using the optical Transmitting device in the optical transmission system according to EP-A-0 554 736, the route length over which an optical signal high bit rate is transferable compared to systems that transmit amplitude-modulated signals, can be extended.

The invention will now be described with reference to the drawings explained. Show it:

Fig. 1 shows a first embodiment of an optical transmitter and

Fig. 2 shows a second embodiment of an optical transmitter.

In Fig. 1 a first embodiment is shown of an optical transmitting means for frequency-modulated optical signals. It has two lasers 1 , 2 , two control devices 4 , 5 , two connecting lines 8 , 9 , three polarization-maintaining optical fibers 6 , 7 , 12 , an optical isolator 3 and a coupling device 11 . The lasers 1 , 2 are e.g. B. DFB semiconductor lasers, which are usually available as a complete laser module. A laser module has, among other things, a current control for the laser current and a control for the temperature of the laser. In a laser module, an optical waveguide is coupled to a first end face of the laser, so that the light emerging from the laser is coupled into the optical waveguide. Light, which is detected by a monitor diode, also emerges on the second end face opposite this end face. This allows the optical power of the laser light to be regulated. In Fig. 1 is an optical fiber into which the light emerging at the first end face of the laser is coupled, for. B. the first optical fiber 6 connected to the output 13 of the first laser 6 or the third optical fiber 12 connected to the output 10 of the second laser 2 .

The light emitted by the first laser 1 has a first optical frequency ν₁ and the light emitted by the second laser 2 has a second optical frequency ν₂. The lasers 1 , 2 are chosen so that their optical frequencies ν₁, ν₂ are within a specified range; the optical frequencies ν₁, ν₂ may be the same or closely adjacent (e.g. some 10 GHz difference), ie ν₁ = ν₂ or ν₁ ≈ ν₂. The optical frequencies ν₁, ν₂ can for example be in the range around 1500 nm or in the range around 1300 nm.

The light emitted by the first laser 1 is fed via the first optical waveguide 6 to the optical isolator 3 , which blocks light that propagates against the direction of the light emitted by the first laser 1 . Starting from the optical isolator 3 , the light emitted by the first laser 1 is fed via the second optical waveguide 7 to the coupling device 11 and thus to the second laser 2 . The coupling device 11 couples the light emitted by the first laser 1 into the second laser 2, specifically in its second end face.

To make this possible, a laser module has to be created which has the coupling device 11 instead of the monitor diode. Light for the monitor diode in such a laser module z. B. are coupled out of the second optical fiber 7 . As a result, the optical power of the light emerging from the laser can also be regulated here. Two optical fibers 7 , 12 are thus coupled to the laser 2 .

The first control device 4 is connected to the first laser 1 via the first connecting line 9 and the second control device 5 is connected to the second laser 2 via the second connecting line 8 . Preferably, the first control device 4 supplies a current modulated by a data signal, which is fed to the first laser 1 via the first connecting line 9 , so that the light of the first laser 1 is modulated ν₁ in its optical frequency. The amount of current that the control device 4 supplies is selected so that a frequency-modulated optical signal is produced. The control of the first laser 1 takes place here according to a data signal. If the data signal is a digital signal, the first laser 1 generates an FSK-modulated light as a frequency-modulated signal, which, as already mentioned, can have an undesired amplitude modulation. This FSK-modulated light is fed to the second laser 2 via the coupling means ( 3 , 6 , 7 , 11 ).

The second control device 5 preferably supplies a direct current which is fed to the second laser 2 via the second connecting line 8 . Because the second laser 2 is controlled by a direct current, the second laser 2 emits light of constant intensity, ie the optical power of the emitted light is constant. The amount of the intensity can be set by the amount of the direct current.

Both control devices 4 , 5 have the task, on the one hand, of controlling the laser 1 , 2 respectively connected to them according to a signal (data signal, direct current), and, on the other hand, of regulating the optical power of the light emitted by the lasers to a predetermined value. They therefore have a control function.

Due to the injection of light (Injection Locking), the second optical frequency ν₂ of the light emitted by the second laser 2 follows the first optical frequency ν₁ of the light emitted by the first laser 1 . At the output 10 of the second laser 2 , an FSK-modulated light of constant intensity emerges, the frequency of which is characterized by the first laser 1 , and the intensity of which is predetermined by the second laser 2 . This optical transmission device therefore emits an FSK-modulated optical light in which the undesired amplitude modulation is suppressed.

A second exemplary embodiment of the optical transmission device is shown in FIG. 2. It also has two lasers 1 , 2 , two control devices 4 , 5 , optical fibers 6 , 7 , 12 and an optical isolator 3 . Their functions and modes of operation have already been described in connection with FIG. 1, so that a description is not given here. In addition, the optical transmission device in Fig 2 has. A coupler 21, the three terminals 22, 23, 24 has, and a fourth light waveguide 27. The light emitted by the first laser 1 is fed via the optical fibers 6 , 7 and the optical isolator 3 to the second output 24 of the coupler 21 . At the first connection 23 this light enters the third optical waveguide 12 and is thus supplied to the connection 10 of the second laser 2 . Two opposing light waves, which do not interfere with each other, thus propagate in this third optical waveguide 12 : one light wave fed to the second laser 2 and one emitted by it, which is fed to the fourth optical waveguide 27 at the third connection 22 .

An advantage of this embodiment is that a conventional laser module can be used for the second laser 2 . A coupling device 11 as in FIG. 1 is not necessary.

In this second exemplary embodiment too, the first control device 4 preferably supplies a current modulated by a data signal and the second control device 5 preferably supplies a direct current. As a result, an FSK-modulated optical signal of constant amplitude is also generated here, which exits at the third connection 22 of the coupler 21 .

As an alternative to this, there is another possibility for the control of the lasers 1 , 2 by the control devices 4 , 5 :
The first control device 4 and the second control device 5 each deliver a current modulated by a data signal. As a result, an optical signal with a defined frequency modulation can be generated in the first laser 1 and an optical signal with a defined amplitude modulation in the second laser 2 .

The first control device 4 always supplies a current which controls the first laser 1 in such a way that a frequency-modulated optical signal is generated. As already mentioned, this is done by a current with a small modulation stroke.

Claims (6)

1. Optical transmission device for frequency-modulated optical signals,

• there are two lasers ( 1 , 2 ) and coupling means ( 3 , 6 , 7 , 11 , 12 , 21 ) through which light from the first laser ( 1 ) can be coupled into the second laser ( 2 ),
• - The light of the first laser ( 1 ) can be modulated in its optical frequency (ν₁) by a first control device ( 4 ),
• - The intensity of the light of the second laser ( 2 ) can be adjusted by a second control device ( 5 ), and
• - In the light of the second laser ( 2 ) is shaped in its optical frequency by the optical frequency (ν₁) of the light emitted by the first laser ( 1 ).

2. Optical transmission device according to claim 1, in which as coupling means ( 3 , 6 , 7 , 11 ) two optical fibers ( 6 , 7 ), an optical isolator ( 3 ) and a coupling device ( 11 ) are provided, which are arranged such that Light from the first laser ( 1 ) can be fed to the second laser ( 2 ) via the optical fibers ( 6 , 7 ), the optical isolator ( 3 ) and the coupling device ( 11 ) ( FIG. 1). 3. Optical transmission device according to claim 1, in which as coupling means ( 3 , 6 , 7 , 12 , 21 ) three optical fibers ( 6 , 7 , 12 ), an optical isolator ( 3 ) and a coupler ( 21 ), the three connections ( 22 , 23 , 24 ) are provided, which are arranged such that light from the first laser ( 1 ) via the optical waveguides ( 6 , 7 ) and the optical isolator ( 3 ) to the second connection ( 24 ) of the coupler ( 21 ) Can be supplied in which the light from the first connection ( 23 ) of the coupler ( 21 ) can be supplied via the third optical waveguide ( 12 ) to the output ( 10 ) of the second laser ( 2 ), and in which the light of the second laser ( 2 ) can be fed to the coupler ( 21 ) via the third optical fiber ( 12 ), at whose third connection ( 22 ) it emerges ( FIG. 2). 4. Optical transmission device according to claim 2 or 3, wherein the first control device ( 4 ) controls the first laser ( 1 ) by a data signal, and the second control device ( 5 ) controls the second laser ( 2 ) by a direct current. 5. Optical transmission device according to claim 2 or 3, wherein each control device ( 4 , 5 ) controls the laser ( 1 , 2 ) connected to it by a data signal. 6. Optical transmission device according to claim 2 or 3, in which the optical fibers ( 6 , 7 , 12 ) are polarization-maintaining.