JPH08331049A - Long distance optical transmission system - Google Patents

Long distance optical transmission system

Info

Publication number
JPH08331049A
JPH08331049A JP8064285A JP6428596A JPH08331049A JP H08331049 A JPH08331049 A JP H08331049A JP 8064285 A JP8064285 A JP 8064285A JP 6428596 A JP6428596 A JP 6428596A JP H08331049 A JPH08331049 A JP H08331049A
Authority
JP
Japan
Prior art keywords
optical
fiber
dispersion
chromatic dispersion
side section
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
JP8064285A
Other languages
Japanese (ja)
Inventor
Shinji Kusaka
眞二 日下
Hideki Shimane
英樹 島根
Takeyoshi Takuma
勇悦 詫摩
Kazumasa Osono
和正 大薗
Tsutomu Yabuki
勉 矢吹
Kimimichi Yamada
公道 山田
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Hitachi Cable Ltd
Original Assignee
Hitachi Cable Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Hitachi Cable Ltd filed Critical Hitachi Cable Ltd
Priority to JP8064285A priority Critical patent/JPH08331049A/en
Publication of JPH08331049A publication Critical patent/JPH08331049A/en
Pending legal-status Critical Current

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  • Optical Communication System (AREA)
  • Light Guides In General And Applications Therefor (AREA)
  • Optical Fibers, Optical Fiber Cores, And Optical Fiber Bundles (AREA)

Abstract

PURPOSE: To compensate wavelength dispersion in an optical fiber transmission line to be almost zero over a broad wavelength region. CONSTITUTION: An optical fiber transmission line 10 of the long distance optical transmission system is made up of a normal dispersion fiber 8 whose wavelength dispersion value is distributed in a negative range not including zero for an operating wavelength band and having a wavelength dispersion characteristic with a positive or negative inclination with respect to the operating wavelength and up of an abnormal dispersion fiber 9 whose wavelength dispersion value is distributed in a positive range not including zero for an operating wavelength band and having a wavelength dispersion characteristic with a reverse gradient to the wavelength dispersion characteristic of the fiber 8.

Description

【発明の詳細な説明】Detailed Description of the Invention

【0001】[0001]

【発明の属する技術分野】本発明は光ファイバ伝送路と
光増幅器を用いて構成される長距離光伝送システムに関
し、特に、四光波混合過剰雑音や自己位相変調による波
形劣化を招かずに広波長領域にわたる光伝送を可能にし
た長距離光伝送システムに関する。BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a long-distance optical transmission system configured by using an optical fiber transmission line and an optical amplifier, and particularly to a wide wavelength without causing deterioration of waveform due to four-wave mixing excess noise or self-phase modulation. The present invention relates to a long-distance optical transmission system that enables optical transmission over an area.

【0002】[0002]

【従来の技術】長距離光伝送システムは、光ファイバ伝
送路に光増幅器を介在させて光ファイバの伝送損失を補
償することで光信号の長距離伝送を可能にしている。2. Description of the Related Art A long-distance optical transmission system enables an optical signal to be transmitted over a long distance by interposing an optical amplifier in an optical fiber transmission line to compensate for a transmission loss of an optical fiber.

【0003】この長距離光伝送システムでは、光ファイ
バの波長分散が累積して、累積波長分散が大きくなるに
従い波長分散効果により伝送波形に劣化が生じる。この
ため、光ファイバの零分散波長と信号波長が一致するよ
うに光ファイバを選択する必要がある。すなわち、長距
離光伝送では光増幅器で高い利得が得られ、光ファイバ
の伝送損失の低い1550nm帯の波長の信号光を使用す
ることから、零分散波長を1550nm帯にシフトした分
散シフト光ファイバを使用する。In this long-distance optical transmission system, chromatic dispersion of optical fibers accumulates, and as the accumulated chromatic dispersion increases, the transmission waveform deteriorates due to the chromatic dispersion effect. Therefore, it is necessary to select the optical fiber so that the zero dispersion wavelength of the optical fiber and the signal wavelength match. That is, in long-distance optical transmission, a high gain is obtained by an optical amplifier, and signal light having a wavelength in the 1550 nm band with low transmission loss of the optical fiber is used. use.

【0004】しかし、信号光の使用波長における光ファ
イバの分散値が零であると、四光波混合過剰累積雑音が
著しく増大する。四光波混合過剰累積雑音は、分散値が
正、或いは零となる信号波長を使用して超長距離伝送や
高速通信を行うと、その雑音の影響が無視できなくなる
程大きくなるものであり、前述のように光ファイバの分
散値が零となる零分散波長を信号波長として使用した場
合においては、特にその影響が増大し、伝送波形の変形
が大きくなって受信不良が生じる。However, if the dispersion value of the optical fiber at the used wavelength of the signal light is zero, the four-wave mixing excess cumulative noise increases remarkably. The four-wave mixing excess cumulative noise is so large that the influence of the noise cannot be ignored when ultra-long-distance transmission or high-speed communication is performed using a signal wavelength with a dispersion value of positive or zero. When the zero-dispersion wavelength at which the dispersion value of the optical fiber is zero is used as the signal wavelength as described above, the influence is particularly increased, the deformation of the transmission waveform becomes large, and reception failure occurs.

【0005】そこで、この四光波混合過剰累積雑音の影
響を抑制する、従来の長距離光伝送システムとして、例
えば、信号光波長における波長分散値が負の値をとるよ
うな分散シフト光ファイバ(以下、正常分散ファイバと
いう)を使用したものが種々提案されている。Therefore, as a conventional long-distance optical transmission system that suppresses the influence of this four-wave mixing excess cumulative noise, for example, a dispersion-shifted optical fiber (hereinafter , A normal dispersion fiber) have been proposed.

【0006】図8は、上記した長距離光伝送システムの
一例を示し、波長1550nmの光信号を出力する光送信
器1と、前述した正常分散ファイバ5と1300nm帯に
零分散波長を有する通常の零分散非シフト光ファイバ6
(波長1550nmにおける波長分散値が正の値をとる)
を組み合わせた光ファイバ伝送路2と、光ファイバ伝送
路2において光信号を増幅して、光ファイバの伝送損失
を補償する光増幅器3と、伝送されてきた光信号を受信
する光受信器4より構成されている。FIG. 8 shows an example of the above-mentioned long-distance optical transmission system. An optical transmitter 1 which outputs an optical signal having a wavelength of 1550 nm, the above-mentioned normal dispersion fiber 5 and a normal dispersion having a zero dispersion wavelength in the 1300 nm band. Zero-dispersion non-shift optical fiber 6
(Wavelength dispersion value at wavelength 1550nm takes positive value)
From the optical fiber transmission line 2 that combines the optical fiber transmission line 2, the optical amplifier 3 that amplifies the optical signal in the optical fiber transmission line 2 to compensate the transmission loss of the optical fiber, and the optical receiver 4 that receives the transmitted optical signal. It is configured.

【0007】このような長距離光伝送システムの構成で
は、零分散非シフト光ファイバ6を波長分散調整用とし
て使用しており、正常分散ファイバ5で累積した波長分
散を零分散非シフト光ファイバ6で補償するようにして
いる。図9は、図8の光ファイバ伝送路2に対応する使
用波長における波長分散を示し、正常分散ファイバ5の
領域では正常分散(負分散)に、また、零分散非シフト
光ファイバ6の領域では異常分散(正分散)になってお
り、光ファイバ伝送路2全体の波長分散が零近傍に補償
されている。In the configuration of such a long-distance optical transmission system, the zero-dispersion non-shift optical fiber 6 is used for chromatic dispersion adjustment, and the chromatic dispersion accumulated by the normal dispersion fiber 5 is zero-dispersion non-shift optical fiber 6. I am trying to compensate. FIG. 9 shows the chromatic dispersion at the used wavelength corresponding to the optical fiber transmission line 2 of FIG. 8, showing normal dispersion (negative dispersion) in the normal dispersion fiber 5 region and zero dispersion non-shift optical fiber 6 region. The dispersion is anomalous (normal dispersion), and the wavelength dispersion of the entire optical fiber transmission line 2 is compensated for near zero.

【0008】また、図10に示すように、正常分散ファ
イバ5と信号光波長における波長分散値が正の値をとる
ような分散シフト光ファイバ(以下、異常分散ファイバ
という)7を組み合わせて光ファイバ伝送路2を構成し
たものも提案されており、このような構成でも正常分散
ファイバ5で累積した波長分散を補償することができ
る。図11は、図10の光ファイバ伝送路2に対応する
使用波長における波長分散を示し、正常分散ファイバ5
の領域では正常分散(負分散)に、また、異常分散ファ
イバ7の領域では異常分散(正分散)になっており、光
ファイバ伝送路2全体の波長分散が零近傍に補償されて
いる。Further, as shown in FIG. 10, an optical fiber is formed by combining a normal dispersion fiber 5 and a dispersion shift optical fiber (hereinafter referred to as an anomalous dispersion fiber) 7 having a positive chromatic dispersion value at a signal light wavelength. A transmission line 2 is also proposed, and even with such a configuration, the chromatic dispersion accumulated in the normal dispersion fiber 5 can be compensated. FIG. 11 shows the chromatic dispersion at the used wavelength corresponding to the optical fiber transmission line 2 of FIG.
In this region, normal dispersion (negative dispersion) is exhibited, and in the region of the anomalous dispersion fiber 7, abnormal dispersion (positive dispersion) is exhibited, and the chromatic dispersion of the entire optical fiber transmission line 2 is compensated for near zero.

【0009】[0009]

【発明が解決しようとする課題】しかし、従来の長距離
光伝送システムによると、大容量伝送するために波長多
重伝送を行う、つまり、使用波長帯域の幅を広範囲(例
えば、使用波長1535〜1565nmからなる帯域幅3
0nm)にすると波長分散値の正負が逆転することがあ
る。例えば、図10の長距離光伝送システムの場合、使
用波長を1550nmより高くすると、図12に示すよう
に、使用波長1550nmでは波長分散値が負の値をとる
正常分散ファイバ(実線)が、正の値をとるようにな
り、その結果、異常分散ファイバ(一点鎖線)と同じ正
分散となる。このため、光ファイバ伝送路の波長分散を
零近傍に補償することができなくなり、受信不良が生じ
るという問題がある。However, according to the conventional long-distance optical transmission system, wavelength-division multiplexing transmission is performed for large-capacity transmission, that is, the wavelength band used is wide (for example, wavelengths 1535 to 1565 nm). Bandwidth consisting of 3
(0 nm), the positive and negative of the chromatic dispersion value may be reversed. For example, in the case of the long-distance optical transmission system in FIG. 10, if the wavelength used is higher than 1550 nm, as shown in FIG. 12, the normal dispersion fiber (solid line) having a negative chromatic dispersion value at the wavelength used 1550 nm becomes positive. , And as a result, the same positive dispersion as that of the anomalous dispersion fiber (dashed line) is obtained. Therefore, it becomes impossible to compensate the chromatic dispersion of the optical fiber transmission line near zero, which causes a problem of poor reception.

【0010】従って、本発明の目的は広波長領域にわた
り光ファイバ伝送路の波長分散を零近傍に補償すること
ができる長距離光伝送システムを提供することである。Therefore, it is an object of the present invention to provide a long-distance optical transmission system capable of compensating the chromatic dispersion of an optical fiber transmission line to near zero over a wide wavelength range.

【0011】[0011]

【課題を解決するための手段】本発明は上記問題点に鑑
み、広波長領域にわたり光ファイバ伝送路の波長分散を
零近傍に補償するため、光ファイバ伝送路が使用波長帯
域において波長分散値が零を含まない負の領域に分布
し、使用波長に対して正または負の傾きをもつ波長分散
特性を有する正常分散ファイバと、使用波長帯域におい
て波長分散値が零を含まない正の領域に分布し、波長分
散値が零の直線に対して正常分散ファイバの波長分散特
性とほぼ対称の波長分散特性を有する異常分散ファイバ
によって構成された長距離光伝送システムを提供するも
のである。In view of the above problems, the present invention compensates for the chromatic dispersion of an optical fiber transmission line in the vicinity of zero over a wide wavelength range. Normal dispersion fiber that has a chromatic dispersion characteristic that has a positive or negative slope with respect to the used wavelength and is distributed in the negative region that does not include zero, and has a chromatic dispersion value that is distributed in the positive region that does not include zero in the used wavelength band. However, the present invention provides a long-distance optical transmission system composed of an anomalous dispersion fiber having a chromatic dispersion characteristic that is substantially symmetrical to the chromatic dispersion characteristic of a normal dispersion fiber with respect to a straight line having a chromatic dispersion value of zero.

【0012】また、本発明は、光ファイバ伝送路が使用
波長帯域において波長分散値が零を含まない負の領域に
分布し、使用波長に対して正の傾きをもつ波長分散特性
を有する正常分散ファイバと、前記使用波長帯域におい
て波長分散値が零を含まない正の領域に分布し、使用波
長に対して負の傾きをもつ波長分散特性を有する異常分
散ファイバとによって構成された長距離光伝送システム
を提供するものである。Further, according to the present invention, the optical fiber transmission line is distributed in a negative region where the chromatic dispersion value does not include zero in the used wavelength band, and the normal dispersion has a chromatic dispersion characteristic having a positive slope with respect to the used wavelength. Long-distance optical transmission composed of a fiber and an anomalous dispersion fiber having a chromatic dispersion characteristic in which the chromatic dispersion value is distributed in a positive region that does not include zero in the used wavelength band and has a negative slope with respect to the used wavelength It provides a system.

【0013】上記光ファイバ伝送路は、送信側区間と受
信側区間に2分割され、送信側区間に正常分散ファイバ
が配置され、受信側区間に異常分散ファイバが配置され
る構成が好ましい。It is preferable that the optical fiber transmission line is divided into a transmission side section and a reception side section, a normal dispersion fiber is arranged in the transmission side section, and an abnormal dispersion fiber is arranged in the reception side section.

【0014】上記光ファイバ伝送路は、所定の間隔で配
置された複数の光増幅器を有しており、複数の光増幅器
の間で送信側区間と受信側区間に2分割され、送信側区
間に正常分散ファイバが配置され、受信側区間に前記異
常分散ファイバが配置される構成が好ましい。The optical fiber transmission line has a plurality of optical amplifiers arranged at predetermined intervals, and is divided into a transmission side section and a reception side section between the plurality of optical amplifiers, and the transmission side section is divided into two sections. It is preferable that a normal dispersion fiber is arranged and the abnormal dispersion fiber is arranged in the reception side section.

【0015】上記光ファイバ伝送路は、送信側区間と受
信側区間の合計区間長の差、送信側区間と受信側区間の
波長分散値の勾配の絶対値の差、及び送信側区間と受信
側区間の使用波長帯域における単位長さ当たりの波長分
散値の絶対値の差がそれぞれ10%以内である構成が好
ましい。In the optical fiber transmission line, the difference between the total length of the transmitting side section and the receiving side section, the difference in absolute value of the slope of the chromatic dispersion value between the transmitting side section and the receiving side section, and the transmitting side section and the receiving side. It is preferable that the difference in absolute value of chromatic dispersion value per unit length in the used wavelength band of each section is within 10%.

【0016】上記光ファイバ伝送路は、最終段の光増幅
器と光受信器によって形成された最終中継区間において
異常分散ファイバが所定の長さに設定され、線路全体の
使用波長帯域の総合分散値が零近傍に補償されている構
成が好ましい。In the above optical fiber transmission line, the abnormal dispersion fiber is set to a predetermined length in the final repeater section formed by the final stage optical amplifier and optical receiver, and the total dispersion value of the wavelength band used for the entire line is set. A configuration in which compensation is performed near zero is preferable.

【0017】上記光ファイバ伝送路は、正常分散ファイ
バと異常分散ファイバの波長分散値の勾配の絶対値が
0.1〜0.01(PS/nm2 ・km)の範囲にある構成
が好ましい。ここで、0.01(PS/nm2 ・km)とい
う下限値は、波長分散値の勾配を維持するために必要な
生産ばらつきを考慮した管理値である。It is preferable that the optical fiber transmission line has a configuration in which the absolute value of the gradient of the chromatic dispersion value of the normal dispersion fiber and the abnormal dispersion fiber is in the range of 0.1 to 0.01 (PS / nm 2 · km). Here, the lower limit value of 0.01 (PS / nm 2 · km) is a control value in consideration of the production variation required to maintain the slope of the chromatic dispersion value.

【0018】光送信器から出力された光信号は、光ファ
イバ伝送路を伝送して光受信器で受信される。このと
き、光信号は光ファイバ伝送路の正常分散ファイバにお
いて負分散の影響を受け、また、異常分散ファイバにお
いて正分散の影響を受ける。その結果、光ファイバ伝送
路の波長分散値が零近傍に補償される。また、正常分散
ファイバとして広波長使用帯域において波長分散値が負
の領域に分布し正または負の傾きをもつ波長分散特性を
有するものを使用し、異常分散ファイバとして広波長使
用帯域において波長分散値が正の領域に分布し波長分散
値が零の直線に対して前記正常分散ファイバの波長分散
特性とほぼ対称の波長分散特性を有するものを使用する
ため、使用波長範囲において正常分散ファイバと異常分
散ファイバの波長分散値の正負が逆転することがなく、
広波長領域で波長多重伝送を行う場合でも光ファイバ伝
送路の波長分散を零近傍に補償する。The optical signal output from the optical transmitter is transmitted through the optical fiber transmission line and received by the optical receiver. At this time, the optical signal is affected by negative dispersion in the normal dispersion fiber of the optical fiber transmission line and is also affected by positive dispersion in the abnormal dispersion fiber. As a result, the chromatic dispersion value of the optical fiber transmission line is compensated for near zero. Also, as the normal dispersion fiber, a fiber having a chromatic dispersion characteristic that the chromatic dispersion value is distributed in the negative region in the wide wavelength use band and has a positive or negative slope is used, and as the abnormal dispersion fiber, the chromatic dispersion value is used in the wide wavelength use band. Is distributed in the positive region and has a chromatic dispersion characteristic that is approximately symmetrical to the chromatic dispersion characteristic of the normal dispersion fiber with respect to a straight line with a chromatic dispersion value of zero. The positive and negative of the chromatic dispersion value of the fiber does not reverse,
Even when wavelength division multiplexing transmission is performed in a wide wavelength region, the chromatic dispersion of the optical fiber transmission line is compensated for near zero.

【0019】また、正常分散ファイバとして広波長使用
波長帯域において波長分散値が零を含まない負の領域に
分布し、使用波長に対して正の傾きをもつ波長分散特性
を有するものを使用し、異常分散ファイバとして広波長
使用波長帯域において波長分散値が零を含まない正の領
域に分布し、使用波長に対して負の傾きをもつ波長分散
特性を有するものを使用することによって、不要の光ノ
イズを低く抑えた低コストの長距離光伝送システムを構
築することができる。Further, as the normal dispersion fiber, a fiber having a chromatic dispersion characteristic in which a chromatic dispersion value is distributed in a negative region not including zero in a wide wavelength use wavelength band and has a positive slope with respect to a use wavelength is used. By using an extraordinary dispersion fiber that has a chromatic dispersion characteristic in which the chromatic dispersion value is distributed in the positive region that does not include zero in the wide wavelength use wavelength band and has a negative slope with respect to the used wavelength, It is possible to construct a low-cost long-distance optical transmission system with low noise.

【0020】[0020]

【発明の実施の形態】以下、本発明の長距離光伝送シス
テムを添付図面を参照しながら詳細に説明する。DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The long-distance optical transmission system of the present invention will be described in detail below with reference to the accompanying drawings.

【0021】図1には、本発明の一実施例の長距離光伝
送システムの構成が示されている。この長距離光伝送シ
ステムは、広波長領域(例えば、1535〜1565n
m)の光信号を送信する光送信器1と、正常分散ファイ
バ8と異常分散ファイバ9を組み合わせて成る光ファイ
バ伝送路10と、光ファイバ伝送路10において光信号
を増幅する複数の光増幅器3と、伝送されてきた光信号
を受信する光受信器4より構成されている。FIG. 1 shows the configuration of a long distance optical transmission system according to an embodiment of the present invention. This long-distance optical transmission system has a wide wavelength range (for example, 1535 to 1565n).
m) an optical transmitter 1 for transmitting an optical signal, an optical fiber transmission line 10 formed by combining a normal dispersion fiber 8 and an abnormal dispersion fiber 9, and a plurality of optical amplifiers 3 for amplifying the optical signal in the optical fiber transmission line 10. And an optical receiver 4 for receiving the transmitted optical signal.

【0022】光ファイバ伝送路10は、図2に示すよう
に、複数の光増幅器3の各中継区間の間の伝送路を2分
割し、比較的強い光信号が伝送される光増幅器3の出力
側区間aに正常分散ファイバ8を、また、比較的弱い光
信号が伝送される光増幅器3の入力側区間bに異常分散
ファイバ9をそれぞれ配置して、各中継区間毎でこれら
を直列に接続することにより構成されている。As shown in FIG. 2, the optical fiber transmission line 10 divides the transmission line between the relay sections of the plurality of optical amplifiers 3 into two, and outputs the relatively strong optical signal from the optical amplifier 3. The normal dispersion fiber 8 is arranged in the side section a, and the abnormal dispersion fiber 9 is arranged in the input side section b of the optical amplifier 3 through which a relatively weak optical signal is transmitted, and these are connected in series in each relay section. It is configured by

【0023】ここで、正常分散ファイバ8と異常分散フ
ァイバ9の波長分散特性について説明する。Here, the chromatic dispersion characteristics of the normal dispersion fiber 8 and the abnormal dispersion fiber 9 will be described.

【0024】図3、及び図7には、正常分散ファイバ8
と異常分散ファイバ9の波長分散値と使用波長の関係が
示されている。正常分散ファイバ8は使用波長範囲R内
でその波長分散値が負の領域に分布すると共に、図3に
示すように使用波長に対して負の傾き(負分散スロー
プ)、或いは図7に示すように使用波長に対して正の傾
き(正分散スロープ)を有し、また、異常分散ファイバ
9は使用波長範囲R内でその波長分散値が正の領域に分
布すると共に、図3に示すように使用波長に対して正の
傾き(正分散スロープ)、或いは図7に示すように使用
波長に対して負の傾き(負分散スロープ)を有してい
る。また、両ファイバ8、9の各波長における波長分散
の絶対値が略等しくなっており、波長分散値の分布が波
長分散零ラインに対して線対称になっている。3 and 7, the normal dispersion fiber 8 is shown.
And the relationship between the chromatic dispersion value of the anomalous dispersion fiber 9 and the wavelength used. The normal dispersion fiber 8 has a chromatic dispersion value distributed in a negative region within the use wavelength range R, and has a negative slope (negative dispersion slope) with respect to the use wavelength as shown in FIG. 3 or as shown in FIG. Has a positive slope (positive dispersion slope) with respect to the used wavelength, and the anomalous dispersion fiber 9 has its chromatic dispersion value distributed in the positive region within the used wavelength range R, and as shown in FIG. It has a positive slope (positive dispersion slope) with respect to the used wavelength, or a negative slope (negative dispersion slope) with respect to the used wavelength as shown in FIG. 7. In addition, the absolute values of the chromatic dispersion at the respective wavelengths of both fibers 8 and 9 are substantially equal, and the distribution of the chromatic dispersion values is line-symmetric with respect to the chromatic dispersion zero line.

【0025】なお、後でも述べるように正常分散ファイ
バと異常分散ファイバとの距離に差がある場合には、そ
れに応じて、光ファイバ伝送路全体の波長分散を零近傍
に補償すべく両者の波長分散の絶対値を異ならせる(す
なわち、両者の波長分散特性の傾きの度合を異ならせ
る)ことは言うまでもない。As will be described later, when there is a difference in distance between the normal dispersion fiber and the abnormal dispersion fiber, the wavelengths of the two fibers are correspondingly adjusted to compensate for the chromatic dispersion of the entire optical fiber transmission line. It goes without saying that the absolute value of dispersion is made different (that is, the degree of inclination of the wavelength dispersion characteristics of both is made different).

【0026】また、正常分散ファイバ8と異常分散ファ
イバ9の合計区間長の差、正常分散ファイバ8と異常分
散ファイバ9の波長分散値の勾配の絶対値の差、及び正
常分散ファイバ8と異常分散ファイバ9の使用波長帯域
における単位長さ当たりの波長分散値の絶対値の差がそ
れぞれ10%以内になっている。更に、正常分散ファイ
バ8と異常分散ファイバ9の波長分散値の勾配の絶対値
は、0.1〜0.01(PS/nm2 ・km)の範囲になっ
ている。Further, the difference in the total section length of the normal dispersion fiber 8 and the abnormal dispersion fiber 9, the difference in the absolute value of the gradient of the chromatic dispersion values of the normal dispersion fiber 8 and the abnormal dispersion fiber 9, and the normal dispersion fiber 8 and the abnormal dispersion. The difference between the absolute values of the chromatic dispersion values per unit length in the wavelength band used by the fiber 9 is within 10%. Furthermore, the absolute value of the gradient of the chromatic dispersion values of the normal dispersion fiber 8 and the abnormal dispersion fiber 9 is in the range of 0.1 to 0.01 (PS / nm 2 · km).

【0027】上記の正常分散ファイバ8、及び異常分散
ファイバ9は、次のようにして光ファイバの波長分散特
性を設計することによって実現可能である。The normal dispersion fiber 8 and the abnormal dispersion fiber 9 can be realized by designing the chromatic dispersion characteristics of the optical fiber as follows.

【0028】所定の波長帯域で負の傾きを有する波長分
散特性とするためには、W形屈折率分布をもつ光ファイ
バ等を使用し、正の傾きを有する波長分散特性とするた
めにはステップ形屈折率分布をもつ光ファイバ等を使用
する。波長分散特性のx軸、或いはy軸方向への移動量
は、光ファイバのコア、及びクラッドの材料を適宜選定
することによって制御することができる。また、波長分
散特性の傾き量は、光ファイバのコア、及びクラッドの
構造、即ち、コア及びクラッドの寸法や比屈折率を適宜
変えることによって制御することができる。An optical fiber or the like having a W-shaped refractive index distribution is used to obtain a chromatic dispersion characteristic having a negative slope in a predetermined wavelength band, and a step is provided to obtain a chromatic dispersion characteristic having a positive slope. An optical fiber having a refractive index profile is used. The amount of movement of the wavelength dispersion characteristic in the x-axis or y-axis direction can be controlled by appropriately selecting the materials of the core and the clad of the optical fiber. The amount of inclination of the wavelength dispersion characteristic can be controlled by appropriately changing the structures of the core and the clad of the optical fiber, that is, the dimensions and the relative refractive index of the core and the clad.

【0029】波長分散特性が正の傾きをもつファイバ
は、上述したように通常のステップ形屈折率分布をもつ
簡易なファイバ構造をしているため、標準的な設計およ
び製造により低コストで生産することができる(以下、
このようなファイバを汎用ファイバという)。A fiber having a positive slope of chromatic dispersion characteristics has a simple fiber structure having a normal step-shaped refractive index distribution as described above, and therefore can be produced at a low cost by standard design and manufacture. You can (below,
Such a fiber is called a general-purpose fiber).

【0030】これに対し、波長分散特性が負の傾きをも
つファイバは、上述したようにW形屈折率分布等の複雑
な屈折率分布構造をもたせなければならないため、特殊
な設計および製造が必要であり、波長分散特性が正の傾
きをもつ前記汎用ファイバよりもコストがかなり高いも
のである(以下、このようなファイバを高コスト特殊フ
ァイバという)。On the other hand, the fiber having the negative slope of the chromatic dispersion characteristic has to have a complicated refractive index distribution structure such as the W-shaped refractive index distribution as described above, and therefore, special design and manufacture are required. Therefore, the cost is considerably higher than that of the general-purpose fiber having a positive chromatic dispersion characteristic (hereinafter, such a fiber is referred to as a high-cost special fiber).

【0031】従って、長距離光伝送路を構成する際に
は、汎用ファイバを高コスト特殊ファイバよりも長く用
いる方が経済的である。Therefore, when constructing a long-distance optical transmission line, it is more economical to use a general-purpose fiber longer than a high-cost special fiber.

【0032】一方、使用波長帯域において波長分散値が
負の値をもつファイバで伝送した方が、使用波長帯域に
おいて波長分散値が正の値或いは零の値をもつファイバ
で伝送したときより、不要の光ノイズが小さい。On the other hand, it is unnecessary to use a fiber having a negative chromatic dispersion value in the used wavelength band than a fiber having a positive or zero chromatic dispersion value in the used wavelength band. Light noise is small.

【0033】これらのことから、汎用ファイバとして不
要の光ノイズが小さいファイバすなわち、使用波長帯域
において波長分散値が負の値をもつものを用いる(すな
わち、正の傾きをもつ正常分散ファイバを用いる)と共
に、高コスト特殊ファイバとして使用波長帯域において
波長分散値が正の値をもつものを用いれば(すなわち、
負の傾きをもつ異常分散ファイバを用いる)、総合的に
みて光ノイズの低い高信頼性な低コストの長距離光伝送
システムを構築することができることが分かる。 な
お、光ファイバ全長の波長分散値は、光ファイバの長さ
に比例するので、この場合、正常分散ファイバと異常分
散ファイバのそれぞれの使用距離の違いに応じて、それ
ぞれの波長分散特性の傾きの度合を異ならせる必要があ
ることは言うまでもない。From these facts, a general-purpose fiber having a small unnecessary optical noise, that is, a fiber having a negative chromatic dispersion value in the used wavelength band is used (that is, a normal dispersion fiber having a positive slope is used). At the same time, if a high-cost special fiber with a positive chromatic dispersion value in the used wavelength band is used (that is,
By using an anomalous dispersion fiber with a negative slope), it can be seen comprehensively that a highly reliable low-cost long-distance optical transmission system with low optical noise can be constructed. Since the chromatic dispersion value of the total length of the optical fiber is proportional to the length of the optical fiber, in this case, the slope of the chromatic dispersion characteristics of each of the normal dispersion fiber and the abnormal dispersion fiber depends on the difference in the working distance between them. It goes without saying that it is necessary to vary the degree.

【0034】以下、本発明の動作を説明する。The operation of the present invention will be described below.

【0035】光送信器1から使用波長範囲の波長の光信
号が出力されると、その光信号が所定の間隔で設けられ
た光増幅器3で増幅されながら光ファイバ伝送路10を
伝送し、光受信器4で受信される。When the optical transmitter 1 outputs an optical signal having a wavelength in the used wavelength range, the optical signal is transmitted through the optical fiber transmission line 10 while being amplified by the optical amplifier 3 provided at a predetermined interval. It is received by the receiver 4.

【0036】ここで、光増幅器3から出力された光信号
は、図4に示すように、光増幅器3の出力側区間aにお
いて正常分散ファイバ8を伝送することにより負分散の
影響を受け、続いて次の光増幅器3の入力側区間bにお
いて異常分散ファイバ9を伝送することにより正分散の
影響を受ける。その結果、光送信器1から光受信器4に
至る光ファイバ伝送路10の波長分散値が零近傍に補償
されることになり、自己位相変調による波形劣化を防い
で光受信器4に波形劣化がない光信号を伝送することが
できる。なお、光増幅器3の出力側区間に正常分散ファ
イバ8を用いているため、光信号強度の大きさに伴って
増大する四光波混合過剰累積雑音の影響を低く抑えるこ
とができる。Here, as shown in FIG. 4, the optical signal output from the optical amplifier 3 is affected by negative dispersion by being transmitted through the normal dispersion fiber 8 in the output side section a of the optical amplifier 3, Then, the anomalous dispersion fiber 9 is transmitted in the section b on the input side of the next optical amplifier 3 to be affected by the positive dispersion. As a result, the chromatic dispersion value of the optical fiber transmission line 10 from the optical transmitter 1 to the optical receiver 4 is compensated for near zero, and the waveform deterioration due to self-phase modulation is prevented and the optical receiver 4 is deteriorated. There is no optical signal can be transmitted. Since the normal dispersion fiber 8 is used in the output side section of the optical amplifier 3, it is possible to suppress the influence of the four-wave mixing excess cumulative noise that increases with the magnitude of the optical signal intensity.

【0037】この長距離光伝送システムでは、使用波長
範囲内において、正常分散ファイバ8として波長分散値
が零を含まない負の領域に分布すると共に使用波長に対
して負の傾き、或いは正の傾きをもつものを使用し、異
常分散ファイバ9として波長分散値が零を含まない正の
領域に分布すると共に波長分散値が零の直線に対して前
記正常分散ファイバ8の波長分散特性とほぼ対称の波長
分散特性をもつものを使用するため、使用波長範囲にお
いて正常分散ファイバ8と異常分散ファイバ9の波長分
散値の正負が逆転することがなく、波長多重伝送を行う
場合でも広波長領域にわたり光ファイバ伝送路の波長分
散を零近傍に補償することができる。In this long-distance optical transmission system, within the usable wavelength range, the normal dispersion fiber 8 has a chromatic dispersion value distributed in a negative region that does not include zero, and has a negative slope or a positive slope with respect to the used wavelength. Of the anomalous dispersion fiber 9 is distributed in a positive region where the chromatic dispersion value does not include zero, and is substantially symmetrical to the chromatic dispersion characteristic of the normal dispersion fiber 8 with respect to a straight line having a chromatic dispersion value of zero. Since the one having the chromatic dispersion characteristic is used, the positive and negative signs of the chromatic dispersion values of the normal dispersion fiber 8 and the abnormal dispersion fiber 9 do not reverse in the used wavelength range, and the optical fiber is spread over a wide wavelength range even when wavelength division multiplexing transmission is performed. The wavelength dispersion of the transmission line can be compensated for near zero.

【0038】なお、正常分散ファイバ8として使用波長
範囲内において波長分散値が零を含まない負の領域に分
布し、使用波長に対して正の傾きをもつ波長分散特性を
有するものを使用し、異常分散ファイバ9として使用波
長範囲内において波長分散値が零を含まない正の領域に
分布し、使用波長に対して負の傾きをもつ波長分散特性
を有するものを使用することが好ましく、この場合、正
常分散ファイバ8を異常分散ファイバ9よりも長く使用
して光ファイバ伝送路を構成することによって、不要の
光ノイズを低く抑えた低コストの長距離光伝送システム
を構築することができる。As the normal dispersion fiber 8, a fiber having a chromatic dispersion characteristic in which the chromatic dispersion value is distributed in a negative region that does not include zero and has a positive slope with respect to the used wavelength in the used wavelength range, As the anomalous dispersion fiber 9, it is preferable to use an anomalous fiber having a chromatic dispersion characteristic in which the chromatic dispersion value is distributed in a positive region that does not include zero in the used wavelength range and has a negative slope with respect to the used wavelength. By configuring the optical fiber transmission line by using the normal dispersion fiber 8 longer than the abnormal dispersion fiber 9, it is possible to construct a low-cost long-distance optical transmission system that suppresses unnecessary optical noise.

【0039】また、最終段の光増幅器3と光受信器4に
よって形成された最終中継区間において異常分散ファイ
バ9の長さを調整して、線路全体の使用波長帯域の総合
分散値を零近傍に補償する方法を併用することも可能で
ある。なお、上記の実施例において、使用波長範囲を1
535〜1565nmとして波長多重伝送を行った場合、
0.8nm間隔で38波の多重伝送が可能となる。Further, the length of the anomalous dispersion fiber 9 is adjusted in the final repeater section formed by the final stage optical amplifier 3 and the optical receiver 4 so that the total dispersion value of the used wavelength band of the entire line is brought to near zero. It is also possible to use the method of compensation together. In the above embodiment, the wavelength range used is 1
When wavelength multiplexing transmission is performed at 535 to 1565 nm,
38 waves can be multiplexed at intervals of 0.8 nm.

【0040】図5には、本発明の第2の実施例の長距離
光伝送システムの構成が示されている。この長距離光伝
送システムは、光送信器1の直後に光増幅器3Aを接続
して成る送信局舎11と、光受信器4の直前に光増幅器
3Bを接続して成る受信局舎12と、送信局舎11と受
信局舎12の間に挿入された光ファイバ伝送路10より
構成され、送信局舎11から受信局舎12へ光信号を無
中継で伝送するようにしている。FIG. 5 shows the configuration of a long distance optical transmission system according to the second embodiment of the present invention. This long-distance optical transmission system includes a transmitting station 11 formed by connecting an optical amplifier 3A immediately after an optical transmitter 1, and a receiving station 12 formed by connecting an optical amplifier 3B immediately before an optical receiver 4. The optical fiber transmission line 10 is inserted between the transmitting station 11 and the receiving station 12, and the optical signal is transmitted from the transmitting station 11 to the receiving station 12 without relay.

【0041】光ファイバ伝送路10は、送信局舎11の
出力側に正常分散ファイバを、受信局舎12の入力側に
異常分散ファイバを使用し、これらを直列に接続して構
成されている。この正常分散ファイバと異常分散ファイ
バには、第1の実施例で前述した光ファイバが使用され
ている。The optical fiber transmission line 10 is constructed by using a normal dispersion fiber on the output side of the transmission station 11 and an abnormal dispersion fiber on the input side of the reception station 12 and connecting them in series. The optical fibers described in the first embodiment are used as the normal dispersion fiber and the abnormal dispersion fiber.

【0042】このような実施例でも第1の実施例と同
様、四光波混合過剰雑音や自己位相変調による波形劣化
を招かずに広波長領域にわたる光伝送が可能となる他、
無中継距離の拡大が図れると同時に光増幅器の保守管理
を容易にすることができる。In this embodiment, as in the first embodiment, optical transmission over a wide wavelength range is possible without causing waveform deterioration due to four-wave mixing excess noise or self-phase modulation.
The repeater-free distance can be increased and the maintenance of the optical amplifier can be facilitated.

【0043】図6には、本発明の第3の実施例の長距離
光伝送システムの構成が示されている。この長距離光伝
送システムは、送信局舎11と受信局舎12の間に第
1、及び第2の実施例で前述した2種類の光ファイバを
組み合わせた光ファイバ伝送路10とエルビウムドープ
ファイバ13を挿入し、受信局舎12に信号光を増幅す
るための励起光を光合分波器14を介して送り込む励起
光源16と、一方向の光信号のみを通過させるアイソレ
ータ15を設けて構成されている。このような構成で
は、リモートポンプ式光増幅無中継システムにおいて第
1、及び第2の実施例と同様な効果を得ることができ
る。FIG. 6 shows the configuration of a long distance optical transmission system according to the third embodiment of the present invention. In this long-distance optical transmission system, an optical fiber transmission line 10 and an erbium-doped fiber 13 in which the two types of optical fibers described in the first and second embodiments are combined between a transmitting station 11 and a receiving station 12. And a pumping light source 16 for sending pumping light for amplifying signal light to the receiving station 12 through the optical multiplexer / demultiplexer 14, and an isolator 15 for passing only one-direction optical signal. There is. With such a configuration, the same effects as those of the first and second embodiments can be obtained in the remote pump type optical amplification repeaterless system.

【0044】なお、第2の実施例において光増幅器3B
を省略しても良く、更に、第3の実施例において前置光
増幅器、もしくは後置光増幅器、もしくは前置光増幅器
と後置光増幅器を両端の局舎11、12内の伝送路に挿
入しても良い。In the second embodiment, the optical amplifier 3B
May be omitted, and further, in the third embodiment, the pre-optical amplifier, the post-optical amplifier, or the pre-optical amplifier and the post-optical amplifier are inserted in the transmission lines in the stations 11 and 12 at both ends. You may.

【0045】[0045]

【発明の効果】以上説明した通り、本発明の長距離光伝
送システムによると、光ファイバ伝送路が使用波長帯域
において波長分散値が零を含まない負の領域に分布し、
使用波長に対して正または負の傾きをもつ波長分散特性
を有する正常分散ファイバと、使用波長帯域において波
長分散値が零を含まない正の領域に分布し、正常分散フ
ァイバの波長分散特性と逆の傾きをもつ波長分散特性を
有する異常分散ファイバによって構成されているため、
広波長領域にわたり光ファイバ伝送路の波長分散を零近
傍に補償して、広波長領域での波長多重伝送の信頼性を
向上させることができる。As described above, according to the long-distance optical transmission system of the present invention, the optical fiber transmission line is distributed in the negative region where the chromatic dispersion value does not include zero in the used wavelength band,
A normal dispersion fiber that has a chromatic dispersion characteristic that has a positive or negative slope with respect to the wavelength used, and a chromatic dispersion value distributed in the positive region that does not include zero in the used wavelength band Since it is composed of an anomalous dispersion fiber with chromatic dispersion characteristics having a slope of
By compensating the chromatic dispersion of the optical fiber transmission line in the vicinity of zero over a wide wavelength region, it is possible to improve the reliability of wavelength multiplex transmission in the wide wavelength region.

【図面の簡単な説明】[Brief description of drawings]

【図1】本発明の一実施例を示す説明図。FIG. 1 is an explanatory diagram showing an embodiment of the present invention.

【図2】一実施例に係る光増幅器間の伝送路を示す説明
図。FIG. 2 is an explanatory diagram showing a transmission line between optical amplifiers according to an embodiment.

【図3】一実施例に係る光ファイバの波長分散特性を示
す説明図。FIG. 3 is an explanatory diagram showing chromatic dispersion characteristics of an optical fiber according to an example.

【図4】一実施例に係る光増幅器間の伝送路の波長分散
を示す説明図。FIG. 4 is an explanatory diagram showing chromatic dispersion of a transmission line between optical amplifiers according to an example.

【図5】本発明の第2の実施例を示す説明図。FIG. 5 is an explanatory diagram showing a second embodiment of the present invention.

【図6】本発明の第3の実施例を示す説明図。FIG. 6 is an explanatory diagram showing a third embodiment of the present invention.

【図7】一実施例に係る光ファイバの他の波長分散特性
を示す説明図。FIG. 7 is an explanatory diagram showing another chromatic dispersion characteristic of the optical fiber according to the embodiment.

【図8】従来の長距離光伝送システムを示す説明図。FIG. 8 is an explanatory diagram showing a conventional long-distance optical transmission system.

【図9】従来の長距離光伝送システムの伝送路の波長分
散を示す説明図。FIG. 9 is an explanatory diagram showing chromatic dispersion of a transmission line of a conventional long-distance optical transmission system.

【図10】従来の他の長距離光伝送システムを示す説明
図。FIG. 10 is an explanatory diagram showing another conventional long-distance optical transmission system.

【図11】従来の他の長距離光伝送システムの伝送路の
波長分散を示す説明図。FIG. 11 is an explanatory diagram showing chromatic dispersion of a transmission line of another conventional long-distance optical transmission system.

【図12】光ファイバの波長分散特性を示す説明図。FIG. 12 is an explanatory diagram showing chromatic dispersion characteristics of an optical fiber.

【符号の説明】[Explanation of symbols]

1 光送信器 2 光ファイバ伝送路 3 光増幅器 4 光受信器 5 正常分散ファイバ 6 零分散非シフト光ファイバ 7 異常分散ファイバ 8 正常分散ファイバ 9 異常分散ファイバ 10 光ファイバ伝送路 11 送信局舎 12 受信局舎 13 エルビウムドープファイバ 14 光合分波器 15 アイソレータ 16 励起光源 1 Optical Transmitter 2 Optical Fiber Transmission Line 3 Optical Amplifier 4 Optical Receiver 5 Normal Dispersion Fiber 6 Zero Dispersion Non-Shift Optical Fiber 7 Abnormal Dispersion Fiber 8 Normal Dispersion Fiber 9 Abnormal Dispersion Fiber 10 Optical Fiber Transmission Line 11 Transmission Station 12 Reception Station 13 Erbium-doped fiber 14 Optical multiplexer / demultiplexer 15 Isolator 16 Excitation light source

───────────────────────────────────────────────────── フロントページの続き (51)Int.Cl.6 識別記号 庁内整理番号 FI 技術表示箇所 H04B 10/16 (72)発明者 大薗 和正 茨城県日立市日高町5丁目1番1号 日立 電線株式会社オプトロシステム研究所内 (72)発明者 矢吹 勉 茨城県日立市日高町5丁目1番1号 日立 電線株式会社日高工場内 (72)発明者 山田 公道 茨城県日立市日高町5丁目1番1号 日立 電線株式会社日高工場内─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. 6 Identification number Internal reference number FI Technical indication location H04B 10/16 (72) Inventor Kazumasa Ozono 5-1-1 Hidaka-cho, Hitachi-shi, Ibaraki Hitachi (72) Inventor Tsutomu Yabuki 5-1-1, Hidaka-cho, Hitachi, Ibaraki Hitachi Cable, Ltd. Hidaka Plant (72) Inventor, Koichi Yamada Hidaka-cho, Hitachi, Ibaraki 5-1-1, Hitachi Cable Co., Ltd. Hidaka Factory

Claims (8)

【特許請求の範囲】[Claims] 【請求項1】光送信器から出力された光信号を光増幅器
で増幅し、増幅された光信号を光ファイバ伝送路を介し
て光受信器まで伝送する長距離光伝送システムにおい
て、 前記光ファイバ伝送路は、使用波長帯域において波長分
散値が零を含まない負の領域に分布し、使用波長に対し
て正または負の傾きをもつ波長分散特性を有する正常分
散ファイバと、前記使用波長帯域において波長分散値が
零を含まない正の領域に分布し、波長分散値が零の直線
に対して前記正常分散ファイバの波長分散特性とほぼ対
称の波長分散特性を有する異常分散ファイバによって構
成されることを特徴とする長距離光伝送システム。1. A long-distance optical transmission system in which an optical signal output from an optical transmitter is amplified by an optical amplifier and the amplified optical signal is transmitted to an optical receiver via an optical fiber transmission line, wherein the optical fiber The transmission line is a normal dispersion fiber having a chromatic dispersion characteristic in which the chromatic dispersion value is distributed in a negative region not including zero in the use wavelength band and has a positive or negative slope with respect to the use wavelength, and the use wavelength band. The chromatic dispersion value is distributed in a positive region that does not include zero, and is composed of an anomalous dispersion fiber having a chromatic dispersion characteristic that is approximately symmetrical to the chromatic dispersion characteristic of the normal dispersion fiber with respect to a straight line having a chromatic dispersion value of zero. Long-distance optical transmission system characterized by. 【請求項2】光送信器から出力された光信号を光増幅器
で増幅し、増幅された光信号を光ファイバ伝送路を介し
て光受信器まで伝送する長距離光伝送システムにおい
て、 前記光ファイバ伝送路は、使用波長帯域において波長分
散値が零を含まない負の領域に分布し、使用波長に対し
て正の傾きをもつ波長分散特性を有する正常分散ファイ
バと、前記使用波長帯域において波長分散値が零を含ま
ない正の領域に分布し、使用波長に対して負の傾きをも
つ波長分散特性を有する異常分散ファイバとによって構
成されることを特徴とする長距離光伝送システム。2. A long-distance optical transmission system for amplifying an optical signal output from an optical transmitter by an optical amplifier and transmitting the amplified optical signal to an optical receiver via an optical fiber transmission line, wherein the optical fiber The transmission line has a normal dispersion fiber whose chromatic dispersion value is distributed in a negative region that does not include zero in the used wavelength band and has a positive slope with respect to the used wavelength, and chromatic dispersion in the used wavelength band. A long-distance optical transmission system characterized by being constituted by an anomalous dispersion fiber whose value is distributed in a positive region not including zero and which has a chromatic dispersion characteristic having a negative slope with respect to a used wavelength. 【請求項3】前記光ファイバ伝送路は、送信側区間と受
信側区間に2分割され、前記送信側区間に前記正常分散
ファイバが配置され、前記受信側区間に前記異常分散フ
ァイバが配置される構成の請求項1、或いは2の長距離
光伝送システム。3. The optical fiber transmission line is divided into a transmission side section and a reception side section, the normal dispersion fiber is arranged in the transmission side section, and the abnormal dispersion fiber is arranged in the reception side section. The long-distance optical transmission system according to claim 1 or 2, which is configured. 【請求項4】前記光ファイバ伝送路は、所定の間隔で配
置された複数の光増幅器を有する構成の請求項1、或い
は2の長距離光伝送システム。4. The long-distance optical transmission system according to claim 1, wherein the optical fiber transmission line has a plurality of optical amplifiers arranged at predetermined intervals. 【請求項5】前記光ファイバ伝送路は、前記複数の光増
幅器の各中継区間の間で送信側区間と受信側区間に2分
割され、前記送信側区間に前記正常分散ファイバが配置
され、前記受信側区間に前記異常分散ファイバが配置さ
れる構成の請求項4の長距離光伝送システム。5. The optical fiber transmission line is divided into a transmission side section and a reception side section between relay sections of the plurality of optical amplifiers, and the normal dispersion fiber is arranged in the transmission side section. The long-distance optical transmission system according to claim 4, wherein the abnormal dispersion fiber is arranged in a receiving side section. 【請求項6】前記光ファイバ伝送路は、前記送信側区間
と前記受信側区間の合計区間長の差、前記送信側区間と
前記受信側区間の波長分散値の勾配の絶対値の差、及び
前記送信側区間と前記受信側区間の使用波長帯域におけ
る単位長さ当たりの波長分散値の絶対値の差がそれぞれ
10%以内である構成の請求項3、4、或いは5の長距
離光伝送システム。6. The optical fiber transmission line, a difference in total section length between the transmitting side section and the receiving side section, a difference in absolute value of gradients of chromatic dispersion values between the transmitting side section and the receiving side section, and The long-distance optical transmission system according to claim 3, 4 or 5, wherein the difference between the absolute values of the chromatic dispersion values per unit length in the used wavelength band of the transmission side section and the reception side section is within 10%, respectively. . 【請求項7】前記光ファイバ伝送路は、最終段の光増幅
器と前記光受信器によって形成された最終中継区間にお
いて前記異常分散ファイバが所定の長さに設定され、線
路全体の使用波長帯域の総合分散値が零近傍に補償され
ている構成の請求項5の長距離光伝送システム。7. In the optical fiber transmission line, the anomalous dispersion fiber is set to a predetermined length in the final repeater section formed by the final stage optical amplifier and the optical receiver, and the wavelength band of the entire line is used. The long-distance optical transmission system according to claim 5, wherein the total dispersion value is compensated near zero. 【請求項8】前記光ファイバ伝送路は、前記正常分散フ
ァイバと前記異常分散ファイバの波長分散値の勾配の絶
対値が0.1〜0.01(PS/nm2 ・km)の範囲にあ
る構成の請求項1、2、3、4、5、6、或いは7の長
距離光伝送システム。8. The optical fiber transmission line has an absolute value of a gradient of chromatic dispersion values of the normal dispersion fiber and the abnormal dispersion fiber in a range of 0.1 to 0.01 (PS / nm 2 · km). The long-distance optical transmission system according to claim 1, 2, 3, 4, 5, 6, or 7 of the configuration.
JP8064285A 1995-03-27 1996-03-21 Long distance optical transmission system Pending JPH08331049A (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
JP8064285A JPH08331049A (en) 1995-03-27 1996-03-21 Long distance optical transmission system

Applications Claiming Priority (3)

Application Number Priority Date Filing Date Title
JP7-68229 1995-03-27
JP6822995 1995-03-27
JP8064285A JPH08331049A (en) 1995-03-27 1996-03-21 Long distance optical transmission system

Publications (1)

Publication Number Publication Date
JPH08331049A true JPH08331049A (en) 1996-12-13

Family

ID=26405404

Family Applications (1)

Application Number Title Priority Date Filing Date
JP8064285A Pending JPH08331049A (en) 1995-03-27 1996-03-21 Long distance optical transmission system

Country Status (1)

Country Link
JP (1) JPH08331049A (en)

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6157754A (en) * 1997-05-09 2000-12-05 Sumitomo Electric Industries, Ltd. Optical transmission line
US6985285B2 (en) 2002-03-12 2006-01-10 Fujitsu Limited Optical transmission system using Raman amplification
JP2006518579A (en) * 2003-02-07 2006-08-10 フランス・テレコム Apparatus and method for high-speed optical transmission, and use of the apparatus and method
US7194208B2 (en) 2002-02-01 2007-03-20 Nec Corporation Wavelength-division multiplexing optical transmission system and optical communication method
CN100338488C (en) * 1999-08-20 2007-09-19 古河电气工业株式会社 Optical fiber and optical transmission line including same

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US6157754A (en) * 1997-05-09 2000-12-05 Sumitomo Electric Industries, Ltd. Optical transmission line
CN100338488C (en) * 1999-08-20 2007-09-19 古河电气工业株式会社 Optical fiber and optical transmission line including same
US7194208B2 (en) 2002-02-01 2007-03-20 Nec Corporation Wavelength-division multiplexing optical transmission system and optical communication method
US6985285B2 (en) 2002-03-12 2006-01-10 Fujitsu Limited Optical transmission system using Raman amplification
JP2006518579A (en) * 2003-02-07 2006-08-10 フランス・テレコム Apparatus and method for high-speed optical transmission, and use of the apparatus and method

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