JP3131319B2 - Frequency division multiplexing optical transmission system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to frequency division multiplexing (FD).
M) Optical transmission system. In particular, the present invention relates to a system that prevents a decrease in C / N ratio due to a change in the number of channels used.

[0002]

2. Description of the Related Art Recently, there has been proposed an FDM signal light transmission system in which laser light is directly amplitude-modulated with a frequency multiplexed signal and transmitted to an optical transmission line. This method has excellent compatibility with conventional CATV systems using coaxial cables, and
Since the non-relay transmission distance can be long, the number of repeater amplifiers can be reduced, the cost of transmission equipment per channel is low, and it is suitable for the trunk of a CATV network.

[0003]

However, the CAT
In the case of the V system, the number of channels used is not fixed but varies with time. That is, the sum of the signal levels in the entire transmission band is not constant, and the sum of the signal levels increases in proportion to the number of channels used. On the other hand, when the oscillation light of the laser diode is amplitude-modulated by the frequency multiplexed electric signal, the frequency modulation is performed at the same time. This phenomenon is called chirping, and the spectrum line width at the time of chirping becomes wider as the number of carriers of the frequency multiplexed signal increases. As a result, C / N in the optical transmission line
The ratio decreases as the number of carriers decreases. That is,
If the level of the modulation signal to be input to the laser diode is set in a state where all the channels are used, there is a problem that the C / N ratio decreases as the number of channels used decreases.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to prevent the C / N ratio from being reduced even if the number of used channels fluctuates in an optical transmission system. It is.

[0005]

Means for Solving the Problems The structure of the invention for solving the above problems is as follows: a center device, a first electric transmission line, a first conversion device, an optical transmission line, a second conversion device, and a second electric transmission line. In a system in which a laser beam is directly amplitude-modulated by a frequency division multiplexed signal in an optical transmission line, data relating to the number of used channels of the frequency division multiplexed signal is transmitted to the data channel of the first electric transmission line to the center device. A channel number data transmission device, a first conversion device, a variable gain amplifier for amplifying an electric signal of the first electric transmission line,
A demodulation device for demodulating channel number data from a data channel of the first electric transmission line, and a control device for controlling the gain of the variable gain amplifier to increase as the channel number data demodulated by the demodulation device takes a smaller value. And an electrical / optical conversion element that amplitude-modulates the laser light with an electrical signal output from the variable gain amplifier and converts the laser light into an optical signal.
An optical / electrical conversion element that performs amplitude demodulation on an optical signal transmitted through an optical transmission line and converts the signal into an electrical signal;
A variable gain amplifier that amplifies the electric signal demodulated by the electric conversion element; a demodulation device that demodulates the number-of-channels data from the electric signal of the data channel; And a control device for controlling the gain of the variable amplifier to be small.

According to a second aspect of the present invention, in the above-mentioned system, the second converter includes an optical / electrical conversion element for amplitude-demodulating the optical signal transmitted through the optical transmission line and converting the signal into an electric signal; / Variable gain amplifier for amplifying electric signal demodulated by electric conversion element, predetermined frequency level detector for detecting signal level of signal of predetermined frequency among electric signals output from variable gain amplifier, predetermined frequency level detector And a comparator for calculating a deviation of the detected level from the predetermined level and outputting the deviation signal as a variable gain signal of the variable gain amplifier to the variable gain amplifier.

[0007]

The frequency multiplexed electric signal is sent from the center device to the first electric transmission line, and the frequency multiplexed electric signal is converted into the frequency multiplexed optical signal in the first converter, and the optical transmission is performed. The signal is sent to a second conversion device, and is converted into a frequency multiplexed electric signal by a second converter, and is sent to a second electric transmission line. At this time, the center device transmits data on the number of used channels of the frequency-multiplexed electric signal, that is, data on the number of carrier waves to the data channel of the first electric transmission line. In the demodulator of the first converter, the channel number data is received from the data channel and demodulated. The control device controls the gain of the variable gain amplifier to increase as the channel number data takes a smaller value. Therefore, if the number of channels used decreases, the amplification factor increases, and the signal level of the channels used increases. In this state, even if the laser light is amplitude-modulated and the amplitude-modulated light is transmitted through an optical transmission line such as an optical fiber, C
The / N ratio does not decrease.

On the other hand, in the second converter, channel number data is demodulated from the data channel of the electric signal demodulated by the optical / electrical conversion element. Control is performed so that the smaller the value of the channel number data, the smaller the gain of the variable gain amplifier. As a result, the frequency multiplexed electric signal transmitted through the second electric transmission path is adjusted so that the signal level of each channel becomes a predetermined level. Therefore, transmission standards such as a CATV system using a coaxial transmission line can be sufficiently satisfied, and the distortion characteristics and the C / N ratio do not deteriorate.

In the second invention, when the optical signal is demodulated into an electric signal, the variable gain amplifier adjusts the signal level of the demodulated electric signal in a used channel to a predetermined level. As a result, the frequency multiplexed electric signal transmitted through the second electric transmission path is adjusted so that the signal level of each channel becomes a predetermined level. Therefore, transmission standards such as a CATV system using a coaxial transmission line can be sufficiently satisfied, and the distortion characteristics and the C / N ratio do not deteriorate.

[0010]

FIG. 1 is a diagram showing a configuration of an optical transmission system according to a specific embodiment of the present invention. Center device 6
Is a transmitter 64 for multiplexing a television reception wave and an independent broadcast wave in a predetermined frequency arrangement and sending the multiplexed transmission wave to a coaxial cable (first electric transmission line) 4, an oscillator 61 for generating a pilot signal, and scanning the entire transmission band. A carrier detector 62 measures the number of carriers in the entire transmission band, and a modulator 63 modulates numerical data into an RF signal of a data channel. The coaxial cable 4 is connected to the first conversion device 1. The first converter 1 includes an amplifier 11, a PIN diode variable attenuator 13, an amplifier 1
2, demodulator 14, memory 15, D / A converter 17, DF
And a B laser diode 16. Among them, the amplifier 11, the PIN diode variable attenuator 13, and the amplifier 12 constitute a variable gain amplifier, and the memory 15 and the D
The / A converter 17 forms a control device. The first conversion device 1 is a device that converts a frequency-multiplexed electric signal into a frequency-multiplexed optical signal and sends the signal to an optical fiber (optical transmission line) 3.

The receiving end of the optical fiber 3 is connected to a second converter 2 for converting a frequency multiplexed optical signal into a frequency multiplexed electric signal. The second conversion device 2 has P
It comprises an IN photodiode 28, an amplifier 21, a PIN diode variable attenuator 22, an amplifier 23, a demodulator 71, a memory 72, and a D / A converter 73. The amplifier 21, the PIN diode variable attenuator 22, and the amplifier 23 constitute a variable gain amplifier, and the memory 72 and the D
The / A converter 73 constitutes a control device. The second conversion device 2 is a device for transmitting a frequency-multiplexed electric signal obtained by the conversion to a coaxial cable (second electric transmission line) 5.

Next, the operation of the present system will be described. In the center device 6, the entire transmission band is scanned by the carrier detector 62, video carriers of all CATV channels are detected, and the number of the carriers is measured. This number is stored as channel number data, modulated by the modulator 63 into an RF signal of the data channel, and transmitted to the coaxial cable (first electric transmission line) 4. The detection of the carrier is executed at predetermined time intervals. Further, the received television signal and independent broadcast wave are multiplexed in a predetermined frequency arrangement by the transmission device 64 and transmitted to the coaxial cable 4.

The frequency multiplexed electric signal (CATV signal) transmitted by the coaxial cable 4 is amplified by the amplifier 11, attenuated by the PIN diode variable attenuator 13, and amplified by the amplifier 12. The signal output from the amplifier 12 is input to a DFB laser diode 16, and a single-mode laser is amplitude-modulated (luminance-modulated) by the signal and converted into a frequency-multiplexed optical signal. This frequency multiplexed optical signal propagates through the optical fiber 3 toward the second converter 2.

On the other hand, a part of the output signal of the amplifier 11 is split by the splitter 18 and is demodulated by the demodulator 14 from the RF signal of the data channel to data. This data is channel number data transmitted from the center device 6 and is output to the address line of the memory 15. The memory 15 stores the relationship between the number of channels and the gain of the variable gain amplifier in a map format. That is, the gain value corresponding to the number of channels is stored in the address indicated by the channel number data. This relationship is set such that the amplification factor increases proportionately as the number of channels used decreases. The gain value read from the memory 15 is converted by the D / A converter 17 into a voltage signal of an analog signal,
It is input to the IN diode variable attenuator 13.

The amount of attenuation of the PIN diode variable attenuator 13 is controlled by this voltage signal. That is, the level of the signal output from the amplifier 12 is adjusted so as to increase in inverse proportion to the decrease in the number of used channels. Therefore, as the number of channels used decreases, the amplifier 11
The sum of the signal levels in all the transmission bands of the signals input to the amplifier 12 becomes small, but the sum of the signal levels in the entire transmission band output from the amplifier 12 becomes equal to a predetermined value.
The attenuation of the N-diode variable attenuator 13 is reduced.

The level-adjusted frequency-multiplexed electric signal output from the amplifier 12 is input to a DFB laser diode 16 to modulate the amplitude of the laser light to obtain a frequency-multiplexed optical signal. This frequency multiplexed optical signal propagates through the optical fiber 3 and is transmitted to the second converter 2. Second conversion device 2
Then, the frequency multiplexed optical signal is received by the PIN photodiode 28 and demodulated into a frequency multiplexed electric signal. The frequency multiplexed electric signal is input to the amplifier 21 and amplified, input to the PIN diode variable attenuator 22 to perform level adjustment, input to the amplifier 23 and amplified, and then coaxial cable (second electric transmission). Route 5).
A part of the output signal of the amplifier 21 is branched by the branching unit 74, the RF signal of the data channel is demodulated by the demodulator 71, and the channel number data is decoded. This channel number data becomes an address signal of the memory 72. Memory 7
2 stores the relationship between the number of channels and the gain of the variable gain amplifier in a map format. That is, the gain value corresponding to the number of channels is stored in the address indicated by the channel number data. This relationship is such that, in the first conversion device 1, in order to return the signal level increased according to the decrease in the number of channels to the original signal level, the amplification factor decreases in proportion to the decrease in the number of channels. Set in a relationship. The gain value read from the memory 72 is converted into a voltage signal of an analog signal by the D / A
It is input to the IN diode variable attenuator 22.

The amount of attenuation of the PIN diode variable attenuator 22 is controlled by this voltage signal. As a result, the amplifier 2
In the signal output by No. 3, the signal level in a predetermined use channel becomes equal to a predetermined reference level. Therefore, the signal level of the frequency multiplexed electric signal output to the coaxial cable 5 becomes the operation level of the predetermined coaxial transmission system again.

In the above embodiment, the C / N ratio deviation of the frequency multiplexed electric signal converted by the second converter 2 was measured by changing the number of channels used. C / N ratio deviation is 4
The C / N ratio when channel 0 is used is shown as a reference. For comparison, a similar experiment was performed to measure the C / N ratio deviation when the level adjustment of the modulation signal was not performed in the first converter 1. The result is shown in FIG. FIG.
It can be understood from the graph that when the level adjustment is performed as in the present embodiment, the C / N ratio is improved with the decrease in the number of channels, as compared with the case where the level adjustment is not performed. I understand.

Next, another embodiment will be described. This embodiment is different from the above embodiment only in the second converter. As shown in FIG. 3, the second conversion device 2
A photodiode 28, an amplifier 21, a PIN diode variable attenuator 22, an amplifier 23, a bandpass filter 24,
It comprises an amplifier 25, a detection circuit 26, and a differential amplifier 27. The second conversion device 2 is a device for transmitting a frequency-multiplexed electric signal obtained by the conversion to a coaxial cable (second electric transmission line) 5.

In the second converter 2, the frequency multiplexed optical signal is received by the PIN photodiode 28 and demodulated into a frequency multiplexed electric signal. The frequency multiplexed electric signal is input to the amplifier 21 and amplified, input to the PIN diode variable attenuator 22 to perform level adjustment, input to the amplifier 23 and amplified, and then coaxial cable (second electric transmission). Route 5). A part of the output signal of the amplifier 23 is split by the splitter 29, and a pilot signal of a predetermined frequency is extracted by the band-pass filter 24.
After being amplified by 5, the signal is detected by the detection circuit 26, and the level of the pilot signal is detected. Detection circuit 2
6 is input to the differential amplifier 27. The reference voltage Vr2 is input to the differential amplifier 27, and the differential amplifier 27
Is a signal representing the deviation of the level of the pilot signal output from the detection circuit 26 from the reference voltage Vr2. This signal is input to the PIN diode variable attenuator 22 to change the attenuation of the attenuator 22.

As described above, in the present system, the signal level in the entire transmission band increases as the number of channels used decreases, but the receiving side detects a pilot signal of a predetermined frequency, and In the device after the PIN photodiode, the level of the electric signal is adjusted so that the level becomes a predetermined value. Therefore, the signal level of the frequency multiplexed electric signal output to the coaxial cable 5 becomes the operation level of the predetermined coaxial transmission system again.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a configuration of an optical transmission system according to a specific embodiment of the present invention.

FIG. 2 is a measurement diagram showing the relationship between the C / N ratio deviation at the receiving end and the number of channels used in the optical transmission system.

FIG. 3 is a block diagram showing a configuration of an optical transmission system according to another embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... 1st converter 2 ... 2nd converter 3 ... Optical fiber (optical transmission line) 4 ... Coaxial cable (1st electric transmission line) 5 ... Coaxial cable (2nd electric transmission line) 13 ... PIN diode variable attenuator ( Variable gain amplifier) 12 Amplifier (variable gain amplifier) 14 Demodulator (demodulator) 15 Memory (controller) 17 D / A converter (controller) 16 DFB laser diode (electrical / optical conversion element) 22: PIN diode variable attenuator (variable gain amplifier) 23: amplifier (variable gain amplifier) 24: band-pass filter (predetermined frequency level detector) 26: detection circuit (predetermined frequency level detector) 27: differential amplifier (comparison) 28) PIN photodiode (optical / electrical conversion element) 61 ... Oscillator 62 ... Carrier detector (channel number data transmission device) 63 ... Modulator (channel) Data transmission device) 71 demodulator (demodulation device) 72 memory (control device) 73 D / A converter (control device)

Continuation of the front page (58) Field surveyed (Int. Cl. ⁷ , DB name) H04B 10/00-10/28 H04J 14/00-14/08 H04N 7/22 H01S 5/06

Claims (2)

(57) [Claims] 1. A first electric transmission line for transmitting a multi-channel electric signal from a center device by a frequency division multiplexing signal, and a second electric transmission line for amplitude-modulating a laser beam by the electric signal and transmitting a modulated optical signal. 1 converter, an optical transmission line for transmitting an optical signal modulated by the first converter, an optical signal received from the optical transmission line, amplitude demodulated into an electric signal, and a demodulated electric signal is transmitted. An optical transmission system comprising: a second conversion device for transmitting an electric signal output from the second conversion device; and a center device, wherein the center device includes data on the number of used channels of the frequency division multiplexed signal. A number-of-channels data transmission device for transmitting the data signal to the data channel of the first electric transmission line, the first conversion device comprising: a variable gain amplifier for amplifying an electric signal of the first electric transmission line; A demodulation device for demodulating the channel number data from the data channel of the first electric transmission path; and increasing the gain of the variable gain amplifier as the channel number data demodulated by the demodulation device takes a smaller value. And an electric / optical conversion element for amplitude-modulating a laser beam with the electric signal output from the variable gain amplifier to convert the laser light into an optical signal. Amplitude demodulation of the optical signal transmitted by
An optical / electrical conversion element that converts the electric signal into an electric signal; a variable gain amplifier that amplifies the electric signal demodulated by the optical / electrical conversion element; a demodulation device that demodulates channel number data from the electric signal of the data channel; A frequency division multiplexing optical transmission system, comprising: a control device that controls the gain of the variable gain amplifier to decrease as the number-of-channels data demodulated by the demodulation device takes a smaller value. 2. A first electric transmission line for transmitting a multi-channel electric signal from a center device by a frequency division multiplexing signal, and a first electric transmission line for amplitude-modulating a laser beam with the electric signal and transmitting a modulated optical signal. 1 converter, an optical transmission line for transmitting an optical signal modulated by the first converter, an optical signal received from the optical transmission line, amplitude demodulated into an electric signal, and a demodulated electric signal is transmitted. An optical transmission system comprising: a second conversion device for transmitting an electric signal output from the second conversion device; and a center device, wherein the center device includes data on the number of used channels of the frequency division multiplexed signal. A number-of-channels data transmission device for transmitting the data signal to the data channel of the first electric transmission line, wherein the first conversion device comprises: a variable gain amplifier for amplifying an electric signal of the first electric transmission line; A demodulation device for demodulating the channel number data from the data channel of the first electric transmission path, wherein the gain of the variable gain amplifier is increased as the channel number data demodulated by the demodulation device takes a smaller value. And an electric / optical conversion element that amplitude-modulates the laser light with the electric signal output from the variable gain amplifier and converts the laser light into an optical signal. The second conversion device includes: Amplitude demodulation of the optical signal transmitted by
An optical / electrical conversion element for converting the electric signal into an electric signal; a variable gain amplifier for amplifying the electric signal demodulated by the optical / electrical conversion element; and a signal level of a signal of a predetermined frequency among the electric signals output from the variable gain amplifier. And a deviation of a level detected by the predetermined frequency level detector with respect to a predetermined level, and outputs the deviation signal to the variable gain amplifier as a variable gain signal of the variable gain amplifier. A frequency division multiplexing optical transmission system comprising a comparator.