JP4192364B2 - Optical amplifier - Google Patents

Description

なる式で表される。
【００１６】
例えば、第１増幅部１１、第２増幅部１２および第３増幅部１３それぞれは、ＡＧＣ制御を行うものとして、利得Ｇ1，Ｇ2およびＧ3が一定であるとする。損失媒体１５は、損失α2が一定であるとする。また、損失媒体１４は、損失α1が可変である可変光減衰器（ＶＯＡ: Variable Optical Attenuator）であるとして、入力信号光レベル変動量と等しい量だけ損失α1を変化させる。すなわち、損失媒体１４の損失α1は、入力信号光レベルに応じて調整されて、入力信号光レベルが最も小さい値（ダイナミックレンジ下限値）であるときには、挿入損失のみの最低値とされ、入力信号光レベルが最も大きい値（ダイナミックレンジ上限値）であるときには、挿入損失とダイナミックレンジ幅とを加えた値とされる。
【００１７】
光増幅器１の雑音指数ＮＦtに関して重要な事項は、入力信号光レベルがダイナミックレンジ下限値であるときにおける雑音指数ＮＦtの値、および、入力信号光レベルの増加量に対する雑音指数ＮＦtの劣化量である。入力信号光レベルがダイナミックレンジ下限値であるときにおける雑音指数ＮＦtをよくする為には、上記(1)式から判るように、第１増幅部１１の利得Ｇ1をできる限り大きくし、損失媒体１４の損失α1をできる限り小さくするのが好ましい。
【００１８】
しかし、第１増幅部１１が固定値の利得Ｇ1で利得一定制御で信号光を光増幅する場合には、その利得Ｇ1は、入力信号光レベルがダイナミックレンジ下限値であるときよりも寧ろダイナミックレンジ上限値であるときの条件で決定される。そして、入力信号光レベルが小さいときには、利得Ｇ1は、第１増幅部１１が有することができる本来の利得（励起パワーを最大にして得られる利得）より小さい値となる。それ故、光増幅器１は、第１増幅部１１が利得一定制御で信号光を光増幅する場合には、雑音指数ＮＦtに関して不利である。本発明は、以上のような考察に基づいてなされたものである。
【００１９】
次に、本発明に係る光増幅器の実施形態について説明する。図２は、本実施形態に係る光増幅器２の概略構成図である。この光増幅器２は、入力端から出力端へ順に、第１増幅部２１、第２増幅部２２および第３増幅部２３を備えており、多段構成とされている。また、この光増幅器２は、第１増幅部２１と第２増幅部２２との間に可変光減衰器２４を備え、第２増幅部２２と第３増幅部２３との間に利得等化器２５および分散補償器２６を備えている。
【００２０】
第１増幅部２１は、入力端に入力した信号光を励起パワー一定制御（ＡＣＣ制御）または出力一定制御（ＡＰＣ制御）で光増幅して出力する。可変光減衰器２４は、信号光に対する減衰率が可変であり、入力信号光レベル変動量と等しい量だけ減衰量が変化するようフィードフォワード制御され、第１増幅部２１から出力された信号光を該減衰量だけ減衰させて出力する。第２増幅部２２は、可変光減衰器２４から出力された信号光をＡＰＣ制御で光増幅して出力する。利得等化器２５は、第２増幅部２２から出力された多波長の信号光を入力し、出力端から出力される多波長の信号光それぞれのレベルを均一にする。分散補償器２６は、利得等化器２５から出力された信号光を入力し、この光増幅器２が挿入される光伝送路の分散を補償するものである。第３増幅部２３は、分散補償器２６から出力された信号光を利得一定制御（ＡＧＣ制御）で光増幅して出力端へ出力する。
【００２１】
より具体的な光増幅器２の構成は以下のとおりである。第１増幅部２１、第２増幅部２２および第３増幅部２３それぞれは、Ｅｒ元素添加光ファイバ（ＥＤＦ）を光増幅媒体として用いるＥＤＦＡとした。第１増幅部２１は、励起光の波長を０．９８μｍとし、ＥＤＦへの励起光供給方式を前方励起とした。第２増幅部２２は、励起光の波長を１．４８μｍとし、励起光供給方式を双方向励起とした。第３増幅部２３は、励起光の波長を１．４８μｍとし、励起光供給方式を双方向励起とした。分散補償器２６は、損失１０ｄＢの分散補償光ファイバ（ＤＣＦ）とした。
【００２２】
このように構成される光増幅器２に対し、波長帯域１５３７．３９ｎｍ〜１５６２．２３ｎｍにおいて１００ＧＨｚ間隔の３２波の信号光が入力端に入力するものとして、出力端から出力される３２波の信号光の出力レベルが＋２０．６ｄＢｍ（各波の信号光の出力レベルが＋５．６ｄＢｍ）となるよう設計した。入力端に入力する各波の信号光の入力レベルは、互いに等しく、−２５ｄＢｍ〜−８ｄＢｍの範囲（ダイナミックレンジ幅１７ｄＢ）で変化させた。また、第１増幅部２１をＡＣＣ制御とした。このような光増幅器２の利得および雑音指数それぞれの波長特性を評価した。
【００２３】
図３は、各入力信号光レベルについて利得の波長特性を示すグラフである。このグラフから判るように、ダイナミックレンジ１７ｄＢでの動的利得傾斜（ＤＧＴ: Dynamic Gain Tilt）は０．２ｄＢ以下に抑制された。すなわち、各波の信号光のレベルが一定になるようにＡＬＣ制御を広ダイナミックレンジで高精度に実現することができた。図４は、各入力信号光レベルについて雑音指数の波長特性を示すグラフである。このグラフから判るように、各波の入力信号光レベルがダイナミックレンジ下限である−２５ｄＢｍであるときに光増幅器２の雑音指数は４ｄＢ以下に抑制された。また、第１増幅部２１をＡＰＣ制御とした場合も同様に良好な結果が得られる。
【００２４】
以上のように、スパンロス変動に因り各波の入力信号光レベルが変動しても、第１増幅部２１は、ＡＣＣ制御またはＡＰＣ制御を行うことにより、最大の利得が得られる。したがって、この光増幅器２は、広ダイナミックレンジで、出力される各波の信号光のレベルが一定になるようにＡＬＣ制御を高精度に実現することができ、また、広ダイナミックレンジに亘って良好な雑音特性が得られる。
【００２５】
また、この光増幅器２において、可変光減衰器２４は、入力端に入力する信号光のレベルの波長依存性に基づいて減衰率の波長依存性を調整して、出力端から出力される多波長の信号光それぞれのレベルの偏差が小さくなるようにするのも好適である。例えば、前段の送信器または中継器から出力された多波長の信号光それぞれのレベルが均一であったとしても、光増幅器２の入力端に入力する各波の信号光のレベルは、光伝送路を伝搬する際に生じるラマン散乱に因り不均一になる場合がある。このとき、光増幅器２に入力する各波の信号光のレベルの波長依存性は、図５に示すように略線形である。入力する各波の信号光のレベルの偏差が５ｄＢ程度であっても、可変光減衰器２４の減衰率を調整することで、出力端から出力される各波の信号光のレベルの偏差が小さくなるようにすることができる。図６は、光増幅器２から出力する各波の信号光のレベルの波長特性を示すグラフである。このグラフに示すように、可変光減衰器２４の減衰率を調整することで、出力端から出力される各波の信号光のレベルの偏差を１ｄＢ以下に抑制することができる。
【００２６】
また、図７に示す光増幅器３のように、第３増幅部２３の後段に更に可変光減衰器２７を備えるのも好適である。この可変光減衰器２７は、信号光に対する減衰率が可変であり、第３増幅部２３から出力された信号光を減衰させて出力する。このように可変光減衰器２７を備えることにより、光増幅器３から出力される信号光レベルを可変とすることができる。
【００２７】
さらに、光増幅器２（図２）または光増幅器３（図７）において、第１増幅部２１、第２増幅部２２および第３増幅部２３それぞれは、多波長の信号光の波数が変動したときには信号光を利得一定制御で光増幅するのが好適である。このようにすることにより、ＯＡＤＭやＯＸＣ等による伝送中の信号光の波数の変動があったとしても、このときに信号光を利得一定制御で光増幅することにより、各波の信号光のレベルが一定になるようにＡＬＣ制御を実現することができる。
【００２８】
【発明の効果】
以上、詳細に説明したとおり、本発明によれば、前段増幅部により励起パワー一定制御または出力一定制御で光増幅され、第１の可変光減衰器により減衰され、後段増幅部により出力一定制御で光増幅されて、出力端に出力される。スパンロス変動に因り各波の入力信号光レベルが変動しても、前段増幅部は、励起パワー一定制御または出力一定制御を行うことにより、最大の利得が得られる。したがって、この光増幅器は、広ダイナミックレンジに亘って良好な雑音特性が得られる。
【００２９】
また、第１の可変光減衰器が入力端に入力する信号光のレベルに基づいて減衰率を調整する場合には、この光増幅器は、広ダイナミックレンジで、出力端から出力される各波の信号光のレベルが一定になるようにＡＬＣ制御を実現することができる。
【００３０】
また、第１の可変光減衰器が入力端に入力する信号光のレベルの波長依存性に基づいて減衰率の波長依存性を調整する場合には、入力端に入力する各波の信号光のレベルがラマン散乱に因り不均一であっても、この光増幅器は、出力端から出力される各波の信号光のレベルの偏差を小さくすることができる。
【００３１】
また、信号光に対する減衰率が可変であって後段増幅部から出力された信号光を減衰させて出力する第２の可変光減衰器を更に備える場合には、光増幅器から出力される信号光レベルを可変とすることができる。
【００３２】
また、前段増幅部および後段増幅部それぞれが入力端に入力する信号光の波数が変動したときには信号光を利得一定制御で光増幅する場合には、ＯＡＤＭやＯＸＣ等による伝送中の信号光の波数の変動があったとしても、各波の信号光のレベルが一定になるようにＡＬＣ制御を実現することができる。
【図面の簡単な説明】
【図１】光増幅器の概略構成図である。
【図２】本実施形態に係る光増幅器の概略構成図である。
【図３】各入力信号光レベルについて利得の波長特性を示すグラフである。
【図４】各入力信号光レベルについて雑音指数の波長特性を示すグラフである。
【図５】光増幅器に入力する各波の信号光のレベルの波長特性を示すグラフである。
【図６】光増幅器から出力する各波の信号光のレベルの波長特性を示すグラフである。
【図７】本実施形態に係る光増幅器の概略構成図である。
【符号の説明】
２…光増幅器、２１…第１増幅部、２２…第２増幅部、２３…第３増幅部、２４…可変光減衰器、２５…利得等化器、２６…分散補償器、２７…可変光減衰器。[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an optical amplifier that collectively amplifies multi-wavelength signal light.
[0002]
[Prior art]
An optical amplifier optically amplifies signal light propagating through an optical transmission line in an optical communication system. Even in a wavelength division multiplexing (WDM) communication system using multi-wavelength signal light, the multi-wavelength optical amplifier is used. Signal light can be optically amplified in a lump. As such an optical amplifier, an optical fiber amplifier (EDFA: Erbium-Doped Fiber Amplifier) using an optical fiber (EDF: Erbium-Doped Fiber) to which an erbium (Er) element is added is known. .
[0003]
For example, the document “S. Kinoshita, et al.,“ Low-Noise and Wide-Dynamic-Range Erbium-Doped Fiber Amplifiers with Automatic Level Control for WDM Transmission Systems. ”OAA'96, SaA5-1, pp.211-214 In the optical amplifier described in (1996), a pre-amplifier, a variable optical attenuator, and a post-amplifier are sequentially connected. Each of the pre-amplifier and the post-amplifier uses an Er-doped optical fiber as an optical amplifying medium. The pre-amplifier optically amplifies the signal light by AGC control (Automatic Gain Control) so that the gain obtained from the input signal light level and the output signal light level of the pre-amplifier is constant. The post-stage amplifier unit optically amplifies the signal light by APC control (Automatic Power Control) so that the power of all the signal lights output from the post-stage amplifier unit is constant. The variable optical attenuator sets the attenuation rate by ALC control (Automatic Level Control) so that the level of the signal light of each wave output from the variable optical attenuator is constant, and the set attenuation rate To attenuate the signal light. In this way, this optical amplifier makes the output signal light level constant even if the input signal light level fluctuates due to fluctuations in the loss (span loss) of the optical transmission line connected to the input end. is there.
[0004]
[Problems to be solved by the invention]
However, the optical amplifier having the configuration described in the above document has a problem that although the output signal light level can be made constant with respect to the span loss variation, the noise characteristics deteriorate as the dynamic range of the ALC control becomes wider. .
[0005]
The present invention has been made to solve the above-described problems, and an object of the present invention is to provide an optical amplifier that can make the output signal light level constant even when there is a span loss variation and has good noise characteristics. .
[0006]
[Means for Solving the Problems]
An optical amplifier according to the present invention is a multistage optical amplifier that collectively amplifies multi-wavelength signal light input to an input terminal and outputs the amplified signal light to an output terminal, and (1) pumps the signal light input to the input terminal. A pre-amplifier that amplifies and outputs light with constant power control or constant output control, and (2) Attenuation rate is variable based on the wavelength dependence of the level of signal light input to the input terminal. A first variable optical attenuator that adjusts the rate and attenuates and outputs the signal light output from the pre-amplifier, and (3) the signal light output from the first variable optical attenuator is output with constant control. And a post-stage amplifying unit for optically amplifying and outputting.
[0007]
According to this optical amplifier, the multi-wavelength signal light input to the input terminal is optically amplified by the upstream amplification unit with constant pumping power control or constant output control, attenuated by the first variable optical attenuator, and the downstream amplification unit Is optically amplified by the constant output control and output to the output terminal. Even if the input signal light level of each wave fluctuates due to the span loss fluctuation, the pre-amplifier can obtain the maximum gain by performing constant excitation power control or constant output control. Therefore, this optical amplifier can obtain good noise characteristics over a wide dynamic range.
[0009]
In the optical amplifier according to the present invention, the first variable optical attenuator adjusts the attenuation rate based on the wavelength dependency of the level of the signal light input to the input end. In this case, even if the level of the signal light of each wave input to the input terminal is non-uniform due to Raman scattering, this optical amplifier is capable of deviation of the output level of the signal light of each wave output from the output terminal. Can be reduced.
[0010]
The optical amplifier according to the present invention further includes a second variable optical attenuator that has a variable attenuation factor with respect to the signal light and attenuates and outputs the signal light output from the subsequent amplification unit. . In this case, the signal light level output from the optical amplifier can be made variable.
[0011]
In the optical amplifier according to the present invention, each of the front-stage amplifying section and the rear-stage amplifying section is characterized by optically amplifying the signal light with constant gain control when the wave number of the signal light input to the input terminal varies. In this case, ALC control can be realized so that the output level of the signal light of each wave is constant even if the wave number of the signal light during transmission by OADM, OXC, or the like is changed.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.
[0013]
First, the background to the idea of the present invention will be described. It is important for an optical amplifier used in a WDM communication system to perform ALC control so that the level of signal light of each wave to be output is constant even when the level of input signal light varies. There are mainly two causes of fluctuations in the input signal light level. The first factor is a fluctuation in the wave number of signal light during transmission by OADM (Optical Add / Drop Multiplexer), OXC (Optical Cross Connect) or the like. The optical amplifier can cope with this first factor by optically amplifying the signal light by AGC control. The second factor is the fluctuation of span loss and the fluctuation of optical component loss. For this second factor, it has been proposed that the optical amplifier includes an AGC-controlled amplification unit and a variable optical attenuator. The span loss is different for each optical transmission line, and may change with time. For this reason, the optical amplifier is required to expand the fluctuation range of the input signal light level capable of ALC control, that is, to widen the dynamic range. In addition, an optical amplifier is required to have excellent noise characteristics.
[0014]
Consider a three-stage optical amplifier 1 as shown in FIG. The optical amplifier 1 includes a first amplifying unit 11, a second amplifying unit 12, and a third amplifying unit 13 in order from the input end to the output end. The optical amplifier 1 further includes a loss medium 14 between the first amplification unit 11 and the second amplification unit 12, and a loss medium 15 between the second amplification unit 12 and the third amplification unit 13. Yes. Here, the gain of the first amplifying unit 11 is represented as G1, and the noise factor of the first amplifying unit 11 is represented as NF1. The gain of the second amplifying unit 12 is represented as G2, and the noise figure of the second amplifying unit 12 is represented as NF2. The gain of the third amplifying unit 13 is represented as G3, and the noise figure of the third amplifying unit 13 is represented as NF3. Further, the loss of the loss medium 14 is expressed as α1, and the loss of the loss medium 15 is expressed as α2. At this time, the overall noise figure NFt of the optical amplifier 1 is
[0015]
[Expression 1]

It is expressed by the following formula.
[0016]
For example, it is assumed that the first amplifying unit 11, the second amplifying unit 12, and the third amplifying unit 13 perform AGC control, and the gains G1, G2, and G3 are constant. The loss medium 15 is assumed to have a constant loss α2. Further, the loss medium 14 is assumed to be a variable optical attenuator (VOA) in which the loss α1 is variable, and the loss α1 is changed by an amount equal to the input signal light level fluctuation amount. That is, the loss α1 of the loss medium 14 is adjusted according to the input signal light level. When the input signal light level is the smallest value (dynamic range lower limit value), the loss α1 is set to the minimum value of only the insertion loss. When the light level is the largest value (dynamic range upper limit value), the value is obtained by adding the insertion loss and the dynamic range width.
[0017]
Important matters regarding the noise figure NFt of the optical amplifier 1 are the value of the noise figure NFt when the input signal light level is the lower limit of the dynamic range, and the deterioration amount of the noise figure NFt with respect to the increase amount of the input signal light level. . In order to improve the noise figure NFt when the input signal light level is the lower limit of the dynamic range, the gain G1 of the first amplifying unit 11 is increased as much as possible, as can be seen from the above equation (1), and the loss medium 14 The loss α1 is preferably made as small as possible.
[0018]
However, when the first amplifying unit 11 optically amplifies the signal light with a fixed gain G1 and a constant gain control, the gain G1 has a dynamic range rather than when the input signal light level is the dynamic range lower limit value. It is determined by the condition when it is the upper limit. When the input signal light level is small, the gain G1 becomes a value smaller than the original gain (gain obtained by maximizing the pumping power) that the first amplifying unit 11 can have. Therefore, the optical amplifier 1 is disadvantageous with respect to the noise figure NFt when the first amplifying unit 11 optically amplifies the signal light with constant gain control. The present invention has been made based on the above consideration.
[0019]
Next, an embodiment of an optical amplifier according to the present invention will be described. FIG. 2 is a schematic configuration diagram of the optical amplifier 2 according to the present embodiment. The optical amplifier 2 includes a first amplifying unit 21, a second amplifying unit 22, and a third amplifying unit 23 in order from the input end to the output end, and has a multistage configuration. The optical amplifier 2 includes a variable optical attenuator 24 between the first amplifying unit 21 and the second amplifying unit 22, and a gain equalizer between the second amplifying unit 22 and the third amplifying unit 23. 25 and a dispersion compensator 26.
[0020]
The first amplifying unit 21 optically amplifies the signal light input to the input terminal by constant excitation power control (ACC control) or constant output control (APC control) and outputs the amplified signal light. The variable optical attenuator 24 has a variable attenuation factor with respect to the signal light, is feedforward controlled so that the attenuation amount changes by an amount equal to the input signal light level fluctuation amount, and the signal light output from the first amplifying unit 21 is The output is attenuated by the amount of attenuation. The second amplifying unit 22 optically amplifies the signal light output from the variable optical attenuator 24 by APC control and outputs the amplified signal light. The gain equalizer 25 receives the multi-wavelength signal light output from the second amplifying unit 22 and equalizes the levels of the multi-wavelength signal lights output from the output terminal. The dispersion compensator 26 receives the signal light output from the gain equalizer 25 and compensates for dispersion in the optical transmission line into which the optical amplifier 2 is inserted. The third amplifying unit 23 optically amplifies the signal light output from the dispersion compensator 26 by constant gain control (AGC control), and outputs the amplified signal light to the output terminal.
[0021]
A more specific configuration of the optical amplifier 2 is as follows. Each of the first amplifying unit 21, the second amplifying unit 22, and the third amplifying unit 23 is an EDFA using an Er element-doped optical fiber (EDF) as an optical amplifying medium. The first amplifying unit 21 has a pumping light wavelength of 0.98 μm, and a pumping light supply system to the EDF is forward pumping. In the second amplification unit 22, the wavelength of the excitation light is 1.48 μm, and the excitation light supply method is bidirectional excitation. In the third amplifying unit 23, the wavelength of the excitation light is 1.48 μm, and the excitation light supply method is bidirectional excitation. The dispersion compensator 26 is a dispersion compensating optical fiber (DCF) with a loss of 10 dB.
[0022]
As for the optical amplifier 2 configured in this manner, 32 wave signal lights at 100 GHz intervals in the wavelength band 1537.39 nm to 1562.23 nm are input to the input terminal, and 32 signal light beams output from the output terminal are input. Is designed to be +20.6 dBm (the output level of the signal light of each wave is +5.6 dBm). The input levels of the signal lights of the respective waves input to the input terminal are equal to each other, and are changed in the range of −25 dBm to −8 dBm (dynamic range width 17 dB). Further, the first amplifying unit 21 is set to ACC control. The wavelength characteristics of the gain and noise figure of the optical amplifier 2 were evaluated.
[0023]
FIG. 3 is a graph showing the wavelength characteristics of gain for each input signal light level. As can be seen from this graph, the dynamic gain tilt (DGT) in the dynamic range of 17 dB was suppressed to 0.2 dB or less. That is, ALC control can be realized with high accuracy in a wide dynamic range so that the level of signal light of each wave is constant. FIG. 4 is a graph showing the wavelength characteristic of the noise figure for each input signal light level. As can be seen from this graph, when the input signal light level of each wave is −25 dBm, which is the lower limit of the dynamic range, the noise figure of the optical amplifier 2 is suppressed to 4 dB or less. Similarly, good results can be obtained when the first amplifying unit 21 is APC controlled.
[0024]
As described above, even if the input signal light level of each wave varies due to the span loss variation, the first amplifying unit 21 can obtain the maximum gain by performing the ACC control or the APC control. Therefore, this optical amplifier 2 can realize ALC control with high accuracy so that the level of the output signal light of each wave is constant in a wide dynamic range, and is excellent over a wide dynamic range. Noise characteristics can be obtained.
[0025]
In this optical amplifier 2, the variable optical attenuator 24 adjusts the wavelength dependency of the attenuation rate based on the wavelength dependency of the level of the signal light input to the input end, and outputs the multiple wavelengths output from the output end. It is also preferable to make the level deviation of each signal light smaller. For example, even if the levels of the multi-wavelength signal lights output from the transmitter or repeater at the previous stage are uniform, the levels of the signal lights of the respective waves input to the input terminal of the optical amplifier 2 are May be non-uniform due to the Raman scattering that occurs when propagating through. At this time, the wavelength dependence of the level of the signal light of each wave input to the optical amplifier 2 is substantially linear as shown in FIG. Even if the deviation of the level of the signal light of each input wave is about 5 dB, the level deviation of the signal light of each wave output from the output terminal is reduced by adjusting the attenuation rate of the variable optical attenuator 24. Can be. FIG. 6 is a graph showing the wavelength characteristics of the level of the signal light of each wave output from the optical amplifier 2. As shown in this graph, by adjusting the attenuation rate of the variable optical attenuator 24, the deviation of the level of the signal light of each wave output from the output end can be suppressed to 1 dB or less.
[0026]
Moreover, it is also preferable to further include a variable optical attenuator 27 at the subsequent stage of the third amplifying unit 23 as in the optical amplifier 3 shown in FIG. The variable optical attenuator 27 has a variable attenuation factor with respect to the signal light, attenuates the signal light output from the third amplifying unit 23, and outputs the attenuated signal light. Thus, by providing the variable optical attenuator 27, the signal light level output from the optical amplifier 3 can be made variable.
[0027]
Furthermore, in the optical amplifier 2 (FIG. 2) or the optical amplifier 3 (FIG. 7), each of the first amplifying unit 21, the second amplifying unit 22, and the third amplifying unit 23 changes when the wave number of the multi-wavelength signal light fluctuates. It is preferable to optically amplify the signal light with constant gain control. By doing so, even if there is a fluctuation in the wave number of the signal light being transmitted by OADM, OXC, etc., the signal light level of each wave is obtained by optically amplifying the signal light with constant gain control at this time. ALC control can be realized so that is constant.
[0028]
【The invention's effect】
As described above in detail, according to the present invention, optical amplification is performed with constant pump power control or constant output control by the pre-amplifier, attenuated by the first variable optical attenuator, and constant output control by the post-stage amplifier. The light is amplified and output to the output terminal. Even if the input signal light level of each wave fluctuates due to the span loss fluctuation, the pre-amplifier can obtain the maximum gain by performing constant excitation power control or constant output control. Therefore, this optical amplifier can obtain good noise characteristics over a wide dynamic range.
[0029]
Further, when the attenuation factor is adjusted based on the level of the signal light input to the input terminal by the first variable optical attenuator, this optical amplifier has a wide dynamic range and each wave output from the output terminal. ALC control can be realized so that the level of the signal light is constant.
[0030]
Further, when the wavelength dependency of the attenuation factor is adjusted based on the wavelength dependency of the level of the signal light input to the input terminal by the first variable optical attenuator, the signal light of each wave input to the input terminal is adjusted. Even if the level is non-uniform due to Raman scattering, this optical amplifier can reduce the deviation of the level of the signal light of each wave output from the output end.
[0031]
Further, in the case of further comprising a second variable optical attenuator that has a variable attenuation factor with respect to the signal light and that attenuates and outputs the signal light output from the subsequent amplification unit, the signal light level output from the optical amplifier Can be made variable.
[0032]
In addition, when the wave number of the signal light input to the input terminal of each of the front stage amplification unit and the rear stage amplification unit fluctuates, when the signal light is optically amplified with constant gain control, the wave number of the signal light being transmitted by OADM, OXC, or the like ALC control can be realized so that the level of the signal light of each wave is constant even if there is a fluctuation.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram of an optical amplifier.
FIG. 2 is a schematic configuration diagram of an optical amplifier according to the present embodiment.
FIG. 3 is a graph showing wavelength characteristics of gain for each input signal light level.
FIG. 4 is a graph showing wavelength characteristics of noise figure for each input signal light level.
FIG. 5 is a graph showing the wavelength characteristics of the level of signal light of each wave input to the optical amplifier.
FIG. 6 is a graph showing the wavelength characteristics of the level of signal light of each wave output from the optical amplifier.
FIG. 7 is a schematic configuration diagram of an optical amplifier according to the present embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 2 ... Optical amplifier, 21 ... 1st amplifier, 22 ... 2nd amplifier, 23 ... 3rd amplifier, 24 ... Variable optical attenuator, 25 ... Gain equalizer, 26 ... Dispersion compensator, 27 ... Variable light Attenuator.

Claims (3)

A multi-stage optical amplifier that collectively amplifies multi-wavelength signal light input to an input terminal and outputs the amplified signal light to an output terminal,
A pre-amplifying unit that optically amplifies the signal light input to the input terminal and outputs the signal light with constant excitation power control or constant output control; and
The attenuation factor with respect to the signal light is variable, the attenuation factor is adjusted based on the wavelength dependency of the level of the signal light input to the input terminal, and the signal light output from the preceding amplification unit is attenuated and output. A first variable optical attenuator;
An optical amplifier, comprising: a post-amplifier that optically amplifies the signal light output from the first variable optical attenuator and outputs the signal light with constant output control.   2. The optical amplifier according to claim 1, further comprising a second variable optical attenuator that has a variable attenuation factor with respect to the signal light and attenuates and outputs the signal light output from the subsequent amplification unit.   2. The optical amplifier according to claim 1, wherein each of the front stage amplification unit and the rear stage amplification unit optically amplifies the signal light with constant gain control when the wave number of the signal light input to the input terminal varies.

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