JPH04280521A - Optical transmission system - Google Patents

Abstract

PURPOSE:To avoid degradation in the quality of a signal by changing the frequency band of a transmission signal so that intermodulation secondary distortion due to the added frequency is caused at a frequency higher than a transmission band and secondary distortion due to difference frequency is caused at a frequency lower than the transmission band. CONSTITUTION:A signal (d) is converted into an optical signal by a synthesizer 11, a signal generator 12, an HPF 13 and an amplifier 14 and transmitted so that intermodulation secondary distortion (f1+f2) by carriers f1, f2 is set to a frequency higher than a transmission band and intermodulation secondary distortion (f60-f1) by carriers f1, f60 is set to a frequency lower than the transmission band. The frequency band of the signal (d) is set to 490-868MHz, then the intermodulation secondary distortion (fn+fa) is set to 988.5MHz or above and the secondary distortion (fn-fa) is selected to be 354MHz or below so that they are not overlapped with the transmission band while holding a sufficient guard band therebetween. Thus, even when the analog optical signal (e) of 1.55mum is transmitted through an optical fiber cable 21 whose zero dispersion wavelength is 1.3mum, the transmission signal (a) is not affected by the intermodulation secondary distortion.

Description

[Detailed description of the invention]

0001

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical transmission system for transmitting light having a wavelength λ0 different from a specific wavelength through an optical fiber cable that does not cause dispersion distortion for light having a specific wavelength. Note that the specific wavelength that does not cause dispersion distortion is called the zero dispersion wavelength λ.
It's called C.

0002

[Prior Art] The optical fiber cable currently installed in the subscriber section has a zero dispersion wavelength λC of 1.3 μm (hereinafter, this optical fiber cable is referred to as "1.3 μm optical fiber cable"). The wavelength of the transmitted light is also 1.3 μm. On the other hand, in response to the wavelength multiplexing method that aims to expand transmission capacity by multiplexing and transmitting light of multiple wavelengths, existing 1.3 μm optical fiber cables are equipped with wavelengths λ0 (for example, 1.3 μm) other than the zero dispersion wavelength. 55μ
There is an increasing demand for transmitting light of m).

[0003]Also, for example, a technology that converts an electrical signal obtained by frequency multiplexing a multi-channel video signal into an optical signal and transmits it has become common, and this optical signal (wavelength λ0) is Its zero dispersion wavelength λ
When transmitting by wavelength multiplexing with light of C, intermodulation 2
It is known that second-order distortion causes deterioration in transmission quality. Note that this intermodulation second-order distortion is thought to be caused by transmitting light of a wavelength other than the zero-dispersion wavelength of the optical fiber cable, but investigation of its cause is a future subject.

FIG. 3 shows that compared to an FM-FDM (frequency modulation-frequency multiplexing) signal, a CSO (composite
AM with strict requirements for Second Order)
- When a 1.55 μm optical signal obtained by electrical-to-optical conversion of an FDM (amplitude modulation-frequency multiplexing) signal is transmitted using a 1.3 μm optical fiber cable, intermodulation second-order distortion increases as the transmission distance increases. This shows how CSO is deteriorating (M. Shigematsu et al.
, ” Field test of multicha
nnel AM-VSB transmission
using erbium doped optica
l fiber amplifier at 1.5
5μm wave length range in t
he CATV network. ”OSA/IEE
E, Topical Meeting on Opti
cal Amplifiers and Theier
Application, WB3, Monter
ey, Aug. 1990).

[0005] The AM-FDM signal used in the conventional coaxial CATV service is in the frequency band of 90 MHz to 468 MHz, but the electrical signal in this band is converted into an optical signal with a wavelength λ0 other than the zero dispersion wavelength λC. Intermodulation second-order distortion that occurs during transmission will be explained with reference to FIG. 4. Note that in FIG. 4, f1 to f60 indicate carriers corresponding to each frequency-multiplexed channel (the frequency intervals of each channel are not necessarily equal).

In FIG. 4(1), carrier f18 (
193.25MHz) and carrier f19 (199.2
Intermodulation second-order distortion f18+f19(3
92.5MHz) is carrier f50 (391.25M
occurs within the sidebands of Hz). In addition, in Fig. 4 (2), intermodulation second-order distortion f16-f1 (92 MHz) due to carrier f1 (91.25 MHz) and carrier f16 (183.25 MHz) is equal to carrier f1 (91 MHz).
．． 25 MHz) sidebands.

[0007]

[Problem to be Solved by the Invention] In this way, it is possible to use an optical fiber cable with a zero dispersion wavelength of λC to reduce the wavelength λ0.
When transmitting light, intermodulation second-order distortion occurs. Therefore, if the light with wavelength λ0 is obtained by electrical-to-optical conversion of an AM-FDM signal in the frequency band used in coaxial CATV, for example, the intermodulation secondary distortion caused by various carriers will occur as shown in Figure 4 (3). occurs within the transmission band.

[0008] That is, the range (■) of intermodulation second-order distortion fn-fm due to the difference frequency of carriers is 6 MHz (f2-f
1) ~ 354MHz (f60 - f1), and the range of intermodulation second-order distortion fn + fm due to the carrier sum frequency is 188.5MHz (f1 + f2) ~ 884
．． 5MHz (f59+f60), coaxial CAT
It can be said that some kind of intermodulation second-order distortion occurs in the transmission band used for V.

[0009] Therefore, when a transmission signal within a predetermined frequency band is converted to light with wavelength λ0 and transmitted using an optical fiber cable with zero dispersion wavelength λC, the deterioration characteristics of CSO shown in Fig. 3 will occur. As shown, long-distance transmission was becoming difficult. In the present invention, the zero dispersion wavelength is λC
An object of the present invention is to provide an optical transmission system that can avoid signal quality deterioration due to intermodulation second-order distortion when transmitting light of wavelength λ0 using an optical fiber cable.

0010

Means for Solving the Problems The invention as set forth in claim 1 provides an optical transmission system in which a transmission signal frequency-multiplexed in a predetermined frequency band is converted into light of a predetermined wavelength and transmitted.
Of the intermodulation second-order distortion caused by each of the transmission signals, the transmission signal is so arranged that the intermodulation second-order distortion due to the sum frequency is above the transmission band, and the intermodulation second-order distortion due to the difference frequency is below the transmission band. It is characterized by converting frequency bands.

[0011] The invention according to claim 2 converts a transmission signal frequency-multiplexed in a predetermined frequency band into light having a wavelength different from the zero dispersion wavelength of an optical fiber cable, and transmits the light through the optical fiber cable. In the optical transmission system, on the transmitting side, intermodulation 2 is performed by each transmission signal within the frequency band.
Frequency conversion means for converting the frequency band of the transmission signal so that the intermodulation second-order distortion due to the sum frequency is above the transmission band and the intermodulation second-order distortion due to the difference frequency is below the transmission band. and a filtering means for removing the low-frequency side output signal of the frequency-converted output signal, and the receiving side is provided with intermodulation 2 that has occurred in the up-converted and transmitted signal on the transmitting side. A first filtering means for removing a signal of the intermodulation second-order distortion component due to the difference frequency among the first-order distortions, and converting the frequency band of the output signal of the first filtering means to the frequency band of the original transmission signal. It is characterized by comprising a frequency conversion means and a second filtering means for removing a high-frequency side output signal from the frequency-converted output signal.

0012

[Operation] The present invention converts a transmission signal frequency-multiplexed in a predetermined frequency band into light with a wavelength λ0, and
When transmitting using C optical fiber cable,
By up-converting the frequency band of the transmission signal so that the generated intermodulation second-order distortion is outside the transmission band,
Transmission can be performed without being affected by intermodulation second-order distortion.

Furthermore, on the receiving side, since the frequency band of the transmission signal and the frequency band of intermodulation second-order distortion are separated, the frequency band of intermodulation second-order distortion is removed and then down-converted to the original frequency band. Therefore, it is possible to obtain a transmission signal that is completely unaffected by intermodulation second-order distortion.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 is a block diagram showing the configuration of an embodiment of a system implementing the method of the present invention. In this embodiment, a case will be explained in which a frequency multiplexed signal is transmitted in the frequency band (90 MHz to 468 MHz) used for the coaxial CATV service shown in FIG. 4.

In the figure, a frequency-multiplexed transmission signal a is input to a multiplexer 11, where it is multiplexed with a signal b having a frequency of 400 MHz output from a signal generator 12, resulting in a modulated signal c. The signal c passes through the high-pass filter 13 and is converted into a high-frequency component signal (490 MHz to 868 MHz).
MHz)d is extracted, amplified via an amplifier 14, and input to an electrical/optical converter (E/O) 15.

The electrical/optical converter 15 converts the signal d into 1.55
Convert to μm analog optical signal e, zero dispersion wavelength 1.3
The light is incident on the μm optical fiber cable 21. The optical signal e transmitted via the optical fiber cable 21 enters an optical/electrical converter (O/E) 31 and is converted into an electrical signal, and then passes through a high-pass filter 32 to generate a low frequency wave of intermodulation second-order distortion. The signal f is obtained by removing the side. The signal f is input to the multiplexer 33, and the frequency 40 is output from the signal generator 34.
It is combined with the 0 MHz signal g to become a modulated signal h. The signal h passes through a low-pass filter 35 to become a low frequency component signal (90 MHz to 468 MHz) i, which is extracted as a transmission signal a via an amplifier 36.

The operation of this embodiment will be explained below with reference to FIG. Transmission signal a is carrier f1 to f6
0 signals are frequency multiplexed. Here, as explained in FIG.
) is caused by a signal with a frequency of Note that the minimum value of intermodulation second-order distortion fn+fm is f1+f2, and the maximum value of intermodulation second-order distortion fn-fm is f60-f1.

Therefore, in this embodiment, for the entire transmission band, the intermodulation second-order distortion f1+f2 due to carrier f1 and carrier f2 is above the transmission band, and the intermodulation second-order distortion f6 due to carrier f1 and carrier f60 is above the transmission band.
Combiner 1 so that 0-f1 is below the transmission band.
1. The signal generator 12, high-pass filter 13, and amplifier 14 up-convert the signal, and then convert it into an optical signal and transmit it. Note that between the transmission band and the lower limit value of the sum frequency or the upper limit value of the difference frequency, sufficient filtering characteristics can be obtained when frequency separation is performed, and there is sufficient guard to avoid the influence of group delay distortion of the transmitted signal. Set the band.

In this embodiment, by setting the frequency band of the up-converted signal d to 490 MHz to 868 MHz, the intermodulation second-order distortion fn+fm becomes 988 MHz.
．． 5MHz or higher, and the intermodulation second-order distortion fn-fm becomes
354 MHz or less, so that it does not overlap with the transmission band with a sufficient guard band in between. Therefore, even if the analog optical signal e of 1.55 μm is transmitted through the optical fiber cable 21 with a zero dispersion wavelength of 1.3 μm, the intermodulation second-order distortion will be within the transmission band, so the transmitted signal a
is not affected by intermodulation second-order distortion.

On the receiving side, after converting the received optical signal into an electrical signal, the intermodulation second-order distortion fn - fm signal is removed via a high-pass filter 32, and the signal is then passed through a multiplexer 33 and a signal generator. 34, low-pass filter 35 and amplifier 36, the original frequency band 90MHz~
The original transmission signal a is extracted by down-converting it to 468MHz. Therefore, even if intermodulation second-order distortion occurs in the transmission path (optical fiber cable 21), its influence can be completely eliminated on the transmission signal a taken out on the receiving side.

[0021] In the embodiment shown in Fig. 1, 90MHz
Although a configuration has been shown in which the frequency band of ~468 MHz is up-converted by one multiplexer 11, it is expected that with one multiplexer, the intermodulation second-order distortion occurring within the band will be large. In this case, even if the frequency band from 90 MHz to 468 MHz is divided into multiple parts and up-converted for each divided band (for example, in octave units),
Similarly, the frequency conversion according to the present invention can be realized. In addition, in the case of down conversion, one multiplexer 33
Even when processing is performed, the influence of intermodulation second-order distortion occurring within the band can be ignored compared to during up-conversion.

[0022]

Effects of the Invention As explained above, the present invention provides a method for converting a transmission signal frequency-multiplexed in a predetermined frequency band into light having a wavelength different from the zero dispersion wavelength of an optical fiber cable and transmitting the signal. By upconverting the frequency band, it is possible to separate the transmission band and the band where intermodulation second-order distortion occurs.

[0023] Therefore, it is possible to avoid the effects of intermodulation second-order distortion of the transmission signal, so even when transmitting light of a wavelength other than the zero-dispersion wavelength using the wavelength multiplexing method, high-quality and long-distance optical transmission can be achieved. It can be realized.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing the configuration of an embodiment of a system that implements the method of the present invention.

FIG. 2 is a diagram showing the relationship between the frequency band, carrier of each channel, and intermodulation second-order distortion during up-conversion.

FIG. 3 is a diagram showing the relationship between the optical fiber length and CSO when an optical signal (AM-FDM signal) with a wavelength of 1.55 μm is transmitted through a 1.3 μm optical fiber cable.

FIG. 4 is a diagram showing the relationship between the frequency band of a conventional transmission signal, the carrier of each channel, and intermodulation second-order distortion.

[Explanation of symbols]

11 Multiplexer 12 Signal generator 13 High pass filter 14 Amplifier 15 Electrical/optical converter (E/O) 21 Optical fiber cable 31 Optical/electrical converter (O/E) 32 High pass filter 33 Multiplexer 34 Signal generator 35 Low pass filter 36 Amplifier

Claims (2)

[Claims] Claim 1. In an optical transmission system in which a transmission signal frequency-multiplexed in a predetermined frequency band is converted into light of a predetermined wavelength and transmitted, among the intermodulation second-order distortion caused by each of the transmission signals, the sum frequency An optical transmission system characterized by converting the frequency band of the transmission signal so that intermodulation second-order distortion is above the transmission band and intermodulation second-order distortion due to difference frequency is below the transmission band. 2. In an optical transmission system in which a transmission signal frequency-multiplexed in a predetermined frequency band is converted into light of a wavelength different from the zero dispersion wavelength of an optical fiber cable, and transmitted via the optical fiber cable, the transmission side Among the intermodulation second-order distortion caused by each transmission signal in the frequency band, the intermodulation second-order distortion due to the sum frequency is above the transmission band, and the intermodulation second-order distortion due to the difference frequency is below the transmission band. The receiving side includes a frequency conversion means for converting the frequency band of the transmission signal so that the frequency band of the transmission signal becomes A first filtering means for removing a signal of an intermodulation second-order distortion component due to a difference frequency among intermodulation second-order distortion occurring in the converted and transmitted signal, and an output signal of the first filtering means. The transmitter is characterized by comprising a frequency conversion means for converting the frequency band of the original transmission signal into the frequency band of the original transmission signal, and a second filtering means for removing the output signal on the high frequency side of the frequency-converted output signal. Optical transmission method.