JPH06338860A - Optical transmission device - Google Patents

Abstract

PURPOSE:To provide the optical transmission device without deteriorating the distortion characteristic when drive current-output light intensity characteristic of laser diode is changed by the fluctuation of the surrounding temperature and secular change. CONSTITUTION:The two mutually similar frequencies which don't affect on a main signal are multiplexed with a main signal to be sent to a light transmission line by using an optical multiplexer 19. The multiplexed signal is converted into a optical signal by a laser diode 11 and the optical signal is monitored by a photodiode 13. The bias current to be supplied to a laser diode 11 is controlled by a bias driving circuit 12 so as to prevent the signal level of the three- dimensional mutual modulation distortion component between the two frequencies outputted from oscillators 17 and 18 included in the monitored light signal from exceeding a prescribed set value.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transmitter,
For example, the present invention relates to an optical transmitter that converts an analog signal into an optical signal using a laser diode and transmits the optical signal.

[0002]

2. Description of the Related Art An optical transmitter is a device used for converting an input electric signal into an optical signal when transmitting data using an optical transmission line such as an optical fiber. In such a device, a laser diode is used as an electro-optical conversion element when performing high-speed transmission of several tens of MHz or more. FIG. 3 shows the relationship between the drive current I of the laser diode and the output light output L. As shown in the figure, the relationship between the optical output L of the laser diode and the current I is approximated by two straight lines. When the current value exceeds the threshold current I _th , laser oscillation starts and the optical output L rapidly increases. To do. In optical transmission, an electric signal is converted into an optical signal by using the IL characteristic in the laser oscillation region. When performing analog modulation, as shown, it leaves supplying the threshold current I _th or more of the bias current I _b to the laser diode, in addition to analog signals centered on it, the light output corresponding to analog signals obtain.

Since the IL characteristics of this laser diode greatly change due to changes in environmental temperature and changes with time of the laser diode, it is necessary to compensate for this change when the laser diode is used in the optical transmitter. is there.
Further, when analog modulation is performed, it is particularly necessary to suppress the occurrence of distortion. Distortion is a phenomenon in which a frequency component different from the input signal frequency is generated, and is generated due to the nonlinearity of the IL characteristic in the laser oscillation region. Of these distortions, the second-order intermodulation distortion occurs in a frequency band different from the signal band, so it is not a problem, but
Third-order intermodulation distortion occurs in the signal band, and thus becomes a particular problem in data transmission.

An apparatus for correcting this distortion is disclosed in Japanese Patent Laid-Open No.
No. 1-102837. FIG. 4 shows the circuit configuration of this device. The device includes a light receiving element 21, a reception amplifier 22, a distortion compensation circuit 23, and a bandpass filter 24.
And a detector 25. A signal including distortion converted into an electric signal by the light receiving element 21 is amplified by the reception amplifier 22 and input to the distortion compensation circuit 23. A control signal corresponding to the level of the distortion signal detected by the detector 25 is input to the distortion compensating circuit 23, and the distortion compensating circuit performs distortion compensation according to the control signal. As the distortion signal, a signal obtained by extracting a high-order harmonic component of the AGC pilot signal superimposed on the video signal using the bandpass filter 24 is used.

[0005]

Since the apparatus for compensating for distortion by detecting the high-order harmonic components of the AGC pilot signal allows the optical signal to include distortion,
There were problems that the versatility was not high and that a complicated circuit called a distortion compensation circuit had to be provided. Further, since the high-order harmonic component of the signal of one frequency is detected, there is a problem that the frequency for detection becomes high.

Therefore, an object of the present invention is to provide an optical transmitter in which the distortion characteristics do not deteriorate when the current / light output characteristics of the laser diode change due to environmental temperature fluctuations or changes over time.

[0007]

According to a first aspect of the present invention, two frequencies close to each other that are close to the frequency of the main signal sent to the optical transmission line and that do not affect the main signal are set. An oscillator for outputting, a combiner for combining two frequencies with the main signal, and a laser diode for outputting an optical signal corresponding to the signal combined by the combiner,
The light receiving means for receiving a part of the optical signal output from the laser diode, and the third-order mutual relation between the two frequencies generated by the non-linearity of the current / optical characteristics of the laser diode from the optical signal received by the light receiving means. In order to control the current and optical characteristics of the laser diode so that the bandpass filter that extracts the frequency component where modulation distortion appears and the signal level of this extracted frequency component are compared with a predetermined set value and this does not exceed this set value. And a bias current adjusting means for adjusting the bias current.

That is, according to the first aspect of the present invention, the main signal to be transmitted to the optical transmission line is combined with _two frequencies f ₁ and f ₂ which are close to each other and which do not affect the main signal. The multiplexed signal is converted into an optical signal by a laser diode, and the optical signal is monitored by a light receiving means composed of a photodiode or the like, and the third order between the two frequencies included in the monitored optical signal is used. Intermodulation distortion component f _d (f _d = 2 × f ₁ −f ₂ , f _d = 2 × f ₂ −
The bias current supplied to the laser diode is adjusted so that the signal level of f ₁ ) does not exceed a predetermined set value. As a result, even when the current / light output characteristics of the laser diode change due to environmental temperature fluctuations or changes over time,
It does not deteriorate the distortion characteristics.

According to the second aspect of the invention, a laser diode that outputs an optical signal corresponding to a main signal in which signals using carrier waves having different frequencies are multiplexed, and a part of the optical signal output by the laser diode are received. And a bandpass filter for extracting a frequency component from the optical signal received by the light receiving means, in which a third-order intermodulation distortion between the carriers caused by the non-linearity of the current / optical characteristics of the laser diode appears, and And a bias current adjusting means for adjusting the bias current for controlling the current / optical characteristics of the laser diode so that the signal level of the frequency component is compared with a predetermined set value and does not exceed the set value.

That is, according to the second aspect of the present invention, the main signal in which the signals using the carriers having different frequencies are multiplexed is converted into the optical signal by the laser diode, and the monitor of the optical signal is constituted by the photodiode or the like. The bias current supplied to the laser diode is adjusted so that the signal level of the third-order intermodulation distortion component between the two carriers included in the monitored optical signal does not exceed a predetermined set value. . As a result, even if the current / light output characteristics of the laser diode change due to environmental temperature fluctuations or changes over time, the distortion characteristics are not deteriorated.

[0011]

EXAMPLES The present invention will be described in detail below with reference to examples.

FIG. 1 shows an outline of the configuration of the optical transmitter according to the first embodiment. The optical transmitter includes a laser diode 11
It comprises a bias drive circuit 12, a photodiode 13, a bandpass filter 14, a peak voltage detection circuit 15, a voltage comparison circuit 16, two oscillators 17 and 18, and a multiplexer 19. The optical transmitter of the embodiment uses a laser diode having a built-in monitor photodiode. The oscillators 17 and 18 are circuits that oscillate frequencies f ₁ and f ₂ close to each other in the vicinity of the frequency of the main signal to be transmitted and that do not affect the main signal, and these signals are combined by a multiplexer. At 19, it is multiplexed with the main signal to be transmitted. The combined signal is used as a drive current for the laser diode 11 together with the bias current from the bias drive circuit 12.

The optical signal output from the laser diode 11 is converted into an electric signal by the photodiode 13. The electric signal output from the photodiode 13 is input to the bandpass filter 14, and only the frequency f _d that reflects the distortion component is extracted from the electric signal. Where frequency f _d
As the two-tone third-order intermodulation distortion of frequencies f ₁ and f ₂ appears f _d = 2 × f ₁ −f ₂ or f _d = 2 × f
_2- f ₁ is used. The extracted frequency component is input to the peak voltage detection circuit 15. The peak voltage detection circuit 15 compares the level V _{d of the} frequency component with the voltage comparator 16
Output to. The voltage comparison circuit 16 compares the level V _d with the reference value V _ref, and the level V _d is the reference value V _ref.
When it exceeds, the control signal is output to the bias drive circuit 12 to change the bias current of the laser diode 11. The reference value V _ref is a value set from the distortion level that is allowed to be included in the transmission signal.

By thus configuring the optical transmitter, for example, when the IL characteristics of the laser diode fluctuate due to fluctuations in ambient temperature and the bias current currently supplied becomes an inappropriate value. , as the level V _d of two-tone third-order intermodulation distortion is less than the reference value V _{re f,} it is possible to automatically control the bias current supplied to the laser diode, always less light signal distortion transmission Can be used for.

In this optical transmitter, two oscillators are provided to detect the distortion. However, if the main signal contains a signal of a certain frequency and intensity, the two signals are used. Therefore, the number of oscillators can be reduced. further,
When the main signal contains signals of two or more constant frequencies and intensities, the device can be configured as follows.

Second Embodiment FIG. 2 shows the outline of the configuration of the optical transmitter according to the second embodiment. The optical transmitter comprises a laser diode 11, a bias drive circuit 12, a photodiode 13, a bandpass filter 14, a peak voltage detection circuit 15 and a voltage comparison circuit 16. A bias current from the bias driving circuit 12 and a signal to be transmitted are input to the laser diode 11, and the laser diode converts the input signal into an optical signal. The input signal here is a so-called frequency-multiplexed signal, and includes a plurality of carriers having different frequencies.

The optical signal output from the laser diode 11 is converted into an electric signal by the photodiode 13,
Of the electric signal, the frequency that reflects the distortion is extracted by the bandpass filter 14. The frequency to be extracted depends on the frequency of the above-mentioned carrier, and here, a band-pass filter that can extract those third-order intermodulation distortion components is used. The extracted frequency component is input to the peak voltage detection circuit 15, and the level V _{d of the} frequency component is input to the voltage comparator 16. The voltage comparator 16 compares this level V _d with the reference value V _ref, and when the level V _d exceeds the reference value V _ref , the bias drive circuit 12
A control signal is output to change the bias current of the laser diode 11.

[0018]

As described in detail above, according to the first aspect of the invention, by monitoring the two-tone third-order intermodulation distortion of two frequencies close to the main signal, fluctuations in ambient temperature and laser diode Even if the IL characteristic changes due to aging, it is possible to prevent the third harmonic distortion, which is a particular problem in analog transmission, from exceeding a predetermined value.
Further, since the control of the distortion of the optical output is performed on the transmitting device side, there is an advantage that the versatility is high.

According to the second aspect of the present invention, by monitoring the intermodulation distortion of the frequency component always included in the input signal, the third-order intermodulation distortion, which is particularly problematic in narrow band analog transmission, does not exceed a predetermined value. You can Further, since the control of the distortion of the optical output is performed on the transmitting device side, there is an advantage that the versatility is high.

[0020]

[Brief description of drawings]

FIG. 1 is a block diagram showing a circuit configuration of an optical transmitter according to a first embodiment of the present invention.

FIG. 2 is a block diagram showing a circuit configuration of an optical transmitter according to a second embodiment of the present invention.

FIG. 3 is a characteristic diagram showing a relationship between a drive current I of a laser diode and an optical output L.

FIG. 4 is a block diagram showing a circuit configuration of a conventional optical transmission device that performs distortion compensation.

[Explanation of symbols]

 11 ... Laser diode 12 ... Bias drive circuit 13 ... Photodiode 14, 24 ... Bandpass filter 15 ... Peak voltage detection circuit 16 ... Voltage comparison circuit 17, 18 ... Oscillator 19 ... Combiner 21 ... Photodetector 22 ... Receiving amplifier 23 … Distortion compensation circuit 25… Detector

Continuation of front page (51) Int.Cl. ⁵ Identification number Office reference number FI technical display location 9372-5K H04B 9/00 Y

Claims (2)

[Claims] 1. An oscillator which outputs two frequencies close to each other which are close to the frequency of a main signal sent to an optical transmission line and which does not affect the main signal, the main signal and the two A multiplexer for multiplexing the frequencies, a laser diode for outputting an optical signal corresponding to the signal multiplexed by the multiplexer, and a light receiving means for receiving a part of the optical signal output by the laser diode, A bandpass filter for extracting from the optical signal received by the light receiving means a frequency component in which a third-order intermodulation distortion between the two frequencies appears due to the non-linearity of the current / optical characteristics of the laser diode, and this bandpass filter. The signal level of the frequency component is compared with a preset value, and the bias current for controlling the current / optical characteristics of the laser diode is adjusted so that it does not exceed this preset value. Optical transmission apparatus characterized by comprising a bias current regulating means. 2. A laser diode that outputs an optical signal corresponding to a main signal in which signals using carrier waves of different frequencies are multiplexed, and a light receiving unit that receives a part of the optical signal output by the laser diode. A bandpass filter for extracting from the optical signal received by the light receiving means a frequency component in which a third-order intermodulation distortion between the carrier waves appears due to non-linearity of the current / optical characteristics of the laser diode, and a frequency component Bias current adjusting means for comparing the signal level with a predetermined set value and adjusting the bias current for controlling the current / optical characteristics of the laser diode so that the signal level does not exceed the set value is provided. Optical transmitter.