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JP2005215196A - Optical modulation device and optical modulation method - Google Patents

Optical modulation device and optical modulation method Download PDF

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JP2005215196A
JP2005215196A JP2004020225A JP2004020225A JP2005215196A JP 2005215196 A JP2005215196 A JP 2005215196A JP 2004020225 A JP2004020225 A JP 2004020225A JP 2004020225 A JP2004020225 A JP 2004020225A JP 2005215196 A JP2005215196 A JP 2005215196A
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bias voltage
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phase
modulation device
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JP4527993B2 (en
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Takeshi Nakatogawa
剛 中戸川
Mikio Maeda
幹夫 前田
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Japan Broadcasting Corp
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Nippon Hoso Kyokai NHK
Japan Broadcasting Corp
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  • Optical Modulation, Optical Deflection, Nonlinear Optics, Optical Demodulation, Optical Logic Elements (AREA)

Abstract

<P>PROBLEM TO BE SOLVED: To provide optical modulation device, with which a light carrier wave components are suppressed down to an arbitrary level. <P>SOLUTION: The optical modulation device 30 is equipped with a MZ-type optical modulator 33 to branch and modulate an optical signal 110, a MZ-type optical modulator 34 to branch and modulate an optical signal 111, a multiplexing means 35 to multiplex optical signals 116, 117 outputted from the MZ-type optical modulators 33, 34, a voltage operation control part 36 to calculate direct current bias voltages to be supplied to the MZ-type optical modulators 33, 34 and to the multiplexing means 35, an electrical signal source 37 to generate an electrical signal 102, a π/2 phase shifter 38 to shift a phase of an electrical signal 105 by π/2, a variable direct current voltage source 39 to supply a direct current bias voltage 107 to the MZ-type optical modulator 33, a variable direct current voltage source 40 to supply a direct current bias voltage 108 to the MZ-type optical modulator 34, and a variable direct current voltage source 41 to supply a direct current bias voltage 109 to the multiplexing means 35. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

本発明は、電気信号を光ファイバ網で伝送する光変調装置及び光変調方法に関する。   The present invention relates to an optical modulation device and an optical modulation method for transmitting an electrical signal through an optical fiber network.

一般に、光変調方式としては、レーザーダイオードへの注入電流を電気信号で変調することにより光強度を変調する「直接変調方式」と、レーザーダイオードは一定出力で動作させ、外部の変調素子で変調を行う「外部変調方式」とがある。直接変調方式は簡便な方式であるが、電流注入により半導体の屈折率が大きく変動し、動的な波長広がりとなり、受信端で光波形に歪みをもたらす場合がある。一方、外部変調方式はこの動的波長広がりを十分低く抑えることができるという特長を有する。   In general, the light modulation method is the "direct modulation method", which modulates the light intensity by modulating the current injected into the laser diode with an electrical signal, and the laser diode is operated at a constant output and modulated by an external modulation element. There is an “external modulation method” to be performed. Although the direct modulation method is a simple method, the refractive index of the semiconductor greatly fluctuates due to current injection, resulting in dynamic wavelength broadening, which may cause distortion of the optical waveform at the receiving end. On the other hand, the external modulation system has a feature that the dynamic wavelength broadening can be sufficiently suppressed.

外部変調方式が用いられた変調器には、一般にニオブ酸リチウム(LiNbO:以下、LNという。)が使用されている。このLNは、大きな電気光学定数を有することや、Ti熱拡散、イオン交換により通信波長帯で低損失な光導電路を形成できること、高品質な結晶が安定して得られることなどの特長を有している。LNが使用されたLN外部変調器には、位相変調、強度変調、偏波変調の各動作があるが、基本となるのは位相変調を利用した位相変調器である。この位相変調器を2つ組み合わせて、マッハツェンダ(以下、MZという。)型構成をとることで、強度変調器を構成することができる。 In general, lithium niobate (LiNbO 3 : hereinafter referred to as LN) is used for a modulator using an external modulation system. This LN has features such as having a large electro-optic constant, being able to form a low-loss photoconductive path in the communication wavelength band by Ti thermal diffusion and ion exchange, and obtaining high-quality crystals stably. ing. The LN external modulator using LN has operations of phase modulation, intensity modulation, and polarization modulation, but the basic is a phase modulator using phase modulation. An intensity modulator can be configured by combining two phase modulators and adopting a Mach-Zehnder (hereinafter referred to as MZ) type configuration.

しかしながら、LN外部変調器の電気・光変換特性は非直線性であることが知られている。例えば、地上デジタル放送などで用いられるOFDM(直交周波数分割多重)信号を伝送する場合、OFDM信号の振幅の瞬時値は平均値と比較して大きいため、多チャンネル伝送時には非直線性により発生する3次相互変調歪み(以下、IM3という。)の影響が顕著になる。伝送信号帯域内に発生するIM3は、等価的に伝送信号のCN比(搬送波電力対雑音電力比)を低下させる。光変調度を高くしていくと伝送信号のCN比が高くなる一方で、CI比(搬送電力対IM3電力比)が低下し、実効的にCN比を低下させる。つまり、光変調器の非線形性の影響を避けるため、光変調度が自ずと制限されることになる。   However, it is known that the electrical / optical conversion characteristics of the LN external modulator are non-linear. For example, when transmitting an OFDM (Orthogonal Frequency Division Multiplexing) signal used in terrestrial digital broadcasting or the like, the instantaneous value of the amplitude of the OFDM signal is larger than the average value. The influence of the next intermodulation distortion (hereinafter referred to as IM3) becomes significant. IM3 generated in the transmission signal band equivalently reduces the CN ratio (carrier power to noise power ratio) of the transmission signal. Increasing the degree of optical modulation increases the CN ratio of the transmission signal, while the CI ratio (carrier power to IM3 power ratio) decreases, effectively reducing the CN ratio. That is, the degree of light modulation is naturally limited to avoid the influence of nonlinearity of the light modulator.

一般に、CN比は送信側の性能で決まる値に飽和するものの、受光電力を高くすることができれば、受信CN比を高くとることができる。したがって、長距離伝送を行うために、光変調器の出力を光増幅器で増幅させた後、光ファイバ伝送路に入力したり、光ファイバ伝送路の中継点で光信号を増幅したりする方法が用いられる。   In general, the CN ratio saturates to a value determined by the performance on the transmission side, but if the received light power can be increased, the received CN ratio can be increased. Therefore, in order to perform long-distance transmission, there is a method in which the output of the optical modulator is amplified by an optical amplifier and then input to an optical fiber transmission line or an optical signal is amplified at a relay point of the optical fiber transmission line. Used.

LN外部変調器の出力信号は、光搬送波成分信号と光変調された変調信号成分とに分けられるが、LN外部変調器は、変調信号成分の電力以上に光搬送波成分の電力が支配的であるために、増幅器を用いても光変調された伝送信号が十分に増幅されないといった問題がある。   The output signal of the LN external modulator is divided into an optical carrier component signal and an optically modulated modulation signal component. In the LN external modulator, the power of the optical carrier component is dominant over the power of the modulation signal component. For this reason, there is a problem that even if an amplifier is used, the optically modulated transmission signal is not sufficiently amplified.

前述のように、LN外部変調器は、そのままでは光変調度を高くすることができない。伝送信号の光変調度を高くするためには、光変調された伝送信号成分の電力のみを増幅させるか、光搬送波成分の電力のみを抑圧しなければならない。   As described above, the LN external modulator cannot increase the light modulation degree as it is. In order to increase the optical modulation degree of the transmission signal, it is necessary to amplify only the power of the optically modulated transmission signal component or suppress only the power of the optical carrier component.

ところで、光DSB(両側波帯)変調信号の場合、受信端で自己ヘテロダイン検波して得られる信号は、「上側波と光搬送波との差信号(上側波成分)」及び「光搬送波と下側波との差信号(下側波成分)」の和となる。光搬送波の位相のみがずれた場合や、波長分散の影響で両側波の位相がずれた場合には、上側波成分と下側波成分との位相差で決定される分だけ、受信信号のCN比を直接的に低下させてしまう。このような問題を解決するためには、片方の第1側波と光搬送波とを伝送する光SSB(単側波帯)変調を用いる手法が有用である。   By the way, in the case of an optical DSB (double sideband) modulation signal, signals obtained by self-heterodyne detection at the receiving end are “difference signal between upper wave and optical carrier (upper wave component)” and “optical carrier and lower wave”. The sum of the difference signal from the wave (lower side wave component) ". When only the phase of the optical carrier wave is shifted or when the phase of both side waves is shifted due to the influence of chromatic dispersion, the CN of the received signal is determined by the amount determined by the phase difference between the upper side wave component and the lower side wave component. Directly reducing the ratio. In order to solve such a problem, a technique using optical SSB (single sideband) modulation for transmitting one first side wave and an optical carrier wave is useful.

従来の光SSB変調を用いる光SSB変調装置としては、図4に示すようなものが知られている。図4に示された従来の光SSB変調装置は、π/2の位相差を有する電気信号403及び405と、直流電圧源6及び7から出力された直流バイアス電圧406及び407とを電極4及び5に入力し、電極4側の光信号と電極5側の光信号との位相差がπ/2になるよう各バイアス電圧406及び407が与えられるようになっている(例えば、非特許文献1参照。)。   As a conventional optical SSB modulation apparatus using optical SSB modulation, the one shown in FIG. 4 is known. The conventional optical SSB modulation device shown in FIG. 4 uses electrical signals 403 and 405 having a phase difference of π / 2 and DC bias voltages 406 and 407 output from DC voltage sources 6 and 7 as electrodes 4 and 4. The bias voltages 406 and 407 are applied so that the phase difference between the optical signal on the electrode 4 side and the optical signal on the electrode 5 side is π / 2 (for example, Non-Patent Document 1). reference.).

また、MZ型の光SSB変調器を2組用いた従来の光周波数シフター装置としては、図5に示すようなものが知られている。図5に示された従来の光周波数シフター装置は、光搬送波成分及び第1下側波成分を完全に抑圧するよう直流電圧源17、18及び19の電圧を設定し、出力信号から光搬送波成分を除去するようになっている(例えば、非特許文献2参照。)。
G.H.Smith, D.Novak, and Z.Ahmed :"Novel technique for generation of optical SSB with carrier using a single MZM to overcome fiber chromatic dispersion", MWP96, PDP-2,1996 川西ら「光SSB変調器を用いた光周波数シフター」信学技報 OCS2002-49,PS2002-33,OFT2002-30(2002-08)
As a conventional optical frequency shifter device using two sets of MZ type optical SSB modulators, a device as shown in FIG. 5 is known. The conventional optical frequency shifter device shown in FIG. 5 sets the voltages of the DC voltage sources 17, 18 and 19 so as to completely suppress the optical carrier component and the first lower side wave component, and the optical carrier component from the output signal. (For example, refer nonpatent literature 2).
GHSmith, D. Novak, and Z. Ahmed: "Novel technique for generation of optical SSB with carrier using a single MZM to overcome fiber chromatic dispersion", MWP96, PDP-2,1996 Kawanishi et al. "Optical frequency shifter using optical SSB modulator" IEICE Technical Report OCS2002-49, PS2002-33, OFT2002-30 (2002-08)

しかしながら、図4に示された従来の光SSB変調装置は、一般的なMZ型変調器を光SSB変調に用いただけであり、光搬送波成分を任意のレベルまで抑圧することができないという問題があった。   However, the conventional optical SSB modulation device shown in FIG. 4 only uses a general MZ type modulator for optical SSB modulation, and there is a problem that the optical carrier component cannot be suppressed to an arbitrary level. It was.

また、図5に示された従来の光周波数シフター装置を光SSB変調装置として動作させようとした場合は、光搬送波成分のレベルを任意の値に抑圧しようとしても、各電極に供給すべき直流バイアス電圧及びその算出方法について開示されていないので、光搬送波成分を任意のレベルまで抑圧することができないという問題があった。   Further, when the conventional optical frequency shifter device shown in FIG. 5 is operated as an optical SSB modulation device, the direct current to be supplied to each electrode even if the level of the optical carrier component is suppressed to an arbitrary value. Since the bias voltage and its calculation method are not disclosed, there is a problem that the optical carrier component cannot be suppressed to an arbitrary level.

本発明は、このような問題を解決するためになされたものであり、光搬送波成分を任意のレベルまで抑圧することができる光変調装置を提供するものである。   The present invention has been made to solve such a problem, and provides an optical modulation device that can suppress an optical carrier wave component to an arbitrary level.

本発明の光変調装置は、第1及び第2の光導波路に導かれた第1の光信号を変調する第1の光変調器と、第3及び第4の光導波路に導かれた第2の光信号を変調する第2の光変調器と、光信号を合成する合成手段と、バイアス電圧を算出するバイアス電圧算出手段とを有し、前記第1の光変調器は、前記第1の光信号の位相を調整する第1のバイアス電圧を入力する第1の電極を備え、前記第2の光変調器は、前記第2の光信号の位相を調整する第2のバイアス電圧を入力する第2の電極を備え、前記合成手段は、前記第1及び前記第2の光変調器から出力される光信号の位相を調整する第3のバイアス電圧を入力する第3の電極を備え、前記バイアス電圧算出手段は、前記第1のバイアス電圧、前記第2のバイアス電圧及び前記第3のバイアス電圧を光搬送波成分レベルと光変調信号成分レベルとの比を表す搬送波抑圧度によって算出することを特徴とする構成を有している。   The optical modulation device of the present invention includes a first optical modulator that modulates the first optical signal guided to the first and second optical waveguides, and a second optical waveguide that is guided to the third and fourth optical waveguides. A second optical modulator that modulates the optical signal, a synthesizing unit that synthesizes the optical signal, and a bias voltage calculating unit that calculates a bias voltage, wherein the first optical modulator includes the first optical modulator A first electrode for inputting a first bias voltage for adjusting the phase of the optical signal is provided, and the second optical modulator inputs a second bias voltage for adjusting the phase of the second optical signal. A second electrode; and the combining unit includes a third electrode for inputting a third bias voltage for adjusting a phase of an optical signal output from the first and second optical modulators, The bias voltage calculation means includes the first bias voltage, the second bias voltage, and the third bias voltage. It has a configuration and calculates the scan voltage by carrier suppression degree representing the ratio between the optical carrier component levels and the modulated optical signal component level.

この構成により、本発明の光変調装置は、バイアス電圧算出手段が、第1のバイアス電圧、第2のバイアス電圧及び第3のバイアス電圧を搬送波抑圧度によって算出するので、搬送波抑圧度を予め所望の値に設定することにより、光搬送波成分を任意のレベルまで抑圧することができる。   With this configuration, in the optical modulation device of the present invention, the bias voltage calculation unit calculates the first bias voltage, the second bias voltage, and the third bias voltage based on the carrier wave suppression degree. By setting to the value of, the optical carrier component can be suppressed to an arbitrary level.

また、本発明の光変調装置は、前記光搬送波成分レベル及び前記光変調信号成分レベルを前記合成手段の出力信号から検出するレベル検出手段を備えたことを特徴とする構成を有している。   Further, the optical modulation device of the present invention has a configuration characterized by comprising level detection means for detecting the optical carrier component level and the optical modulation signal component level from the output signal of the synthesizing means.

この構成により、本発明の光変調装置は、レベル検出手段が、光搬送波成分レベル及び光変調信号成分レベルを合成手段の出力信号から検出するので、検出された搬送波抑圧度と予め設定された搬送波抑圧度とを比較し、両者に差がある場合は第1〜第3のバイアス電圧の調整によって差を小さくすることができ、搬送波抑圧度の精度を向上させることができる。   With this configuration, in the optical modulation device of the present invention, the level detection unit detects the optical carrier component level and the optical modulation signal component level from the output signal of the synthesis unit, so that the detected carrier suppression degree and a preset carrier wave are detected. When the degree of suppression is compared and there is a difference between the two, the difference can be reduced by adjusting the first to third bias voltages, and the accuracy of the carrier suppression degree can be improved.

さらに、本発明の光変調装置は、前記第1及び前記第2の光変調器は、マッハツェンダ型の光変調器であることを特徴とする構成を有している。   Furthermore, the optical modulation device of the present invention has a configuration characterized in that the first and second optical modulators are Mach-Zehnder optical modulators.

この構成により、本発明の光変調装置は、入力された光信号を強度変調することができる。   With this configuration, the light modulation device of the present invention can intensity-modulate the input optical signal.

さらに、本発明の光変調装置は、単側波帯の光変調を行うことを特徴とする構成を有している。   Furthermore, the light modulation device of the present invention has a configuration characterized by performing single sideband light modulation.

この構成により、本発明の光変調装置は、光搬送波成分及び第1下側波成分のレベル比により算出された搬送波抑圧度に基づいて第1〜第3のバイアス電圧を設定することができ、光搬送波成分を任意のレベルまで抑圧することができる。   With this configuration, the optical modulation device of the present invention can set the first to third bias voltages based on the carrier suppression degree calculated by the level ratio of the optical carrier component and the first lower side wave component, The optical carrier component can be suppressed to an arbitrary level.

本発明の光変調方法は、第1の光信号の位相を第1のバイアス電圧で調整するとともに、第2の光信号の位相を第2のバイアス電圧で調整し、位相が調整された前記第1及び前記第2の光信号に対して第3のバイアス電圧で位相を調整する光変調方法であって、前記第1のバイアス電圧、前記第2のバイアス電圧及び前記第3のバイアス電圧は、光搬送波成分レベルと光変調信号成分レベルとの比を表す搬送波抑圧度によって設定されることを特徴とする方法である。   In the optical modulation method of the present invention, the phase of the first optical signal is adjusted with the first bias voltage, the phase of the second optical signal is adjusted with the second bias voltage, and the phase is adjusted. 1 and the optical modulation method for adjusting a phase with a third bias voltage with respect to the second optical signal, wherein the first bias voltage, the second bias voltage, and the third bias voltage are: The method is characterized in that it is set by a carrier suppression degree representing a ratio between the optical carrier component level and the optical modulation signal component level.

この方法により、搬送波抑圧度を予め所望の値に設定することにより、第1のバイアス電圧、第2のバイアス電圧及び第3のバイアス電圧を可変することができ、光搬送波成分を任意のレベルまで抑圧することができる。   By this method, the first bias voltage, the second bias voltage, and the third bias voltage can be varied by setting the carrier wave suppression degree to a desired value in advance, and the optical carrier wave component can be set to an arbitrary level. Can be suppressed.

本発明は、光搬送波成分を任意のレベルまで抑圧することができるという効果を有する光変調装置を提供することができるものである。   The present invention can provide an optical modulation device having an effect that the optical carrier component can be suppressed to an arbitrary level.

以下、本発明の実施の形態について図面を用いて説明する。   Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(第1の実施の形態)
まず、本発明の第1の実施の形態の光変調装置の構成について説明する。
(First embodiment)
First, the configuration of the light modulation device according to the first embodiment of the present invention will be described.

図1に示すように、本実施の形態の光変調装置30は、光源31から出力された光信号101を分岐部32において光信号110及び111に分岐し、光信号110をさらに分岐して変調するMZ型光変調器33と、光信号111をさらに分岐して変調するMZ型光変調器34と、MZ型光変調器33及び34から出力される光信号116及び117を合成する合成手段35と、MZ型光変調器33、MZ型光変調器34及び合成手段35に供給する直流バイアス電圧を算出する電圧演算制御部36と、電気信号102を発生する電気信号源37と、電気信号105の位相をπ/2シフトするπ/2移相器38と、MZ型光変調器33に直流バイアス電圧107を供給する可変直流電圧源39と、MZ型光変調器34に直流バイアス電圧108を供給する可変直流電圧源40と、合成手段35に直流バイアス電圧109を供給する可変直流電圧源41とを備えている。   As shown in FIG. 1, the optical modulation device 30 of this embodiment branches an optical signal 101 output from a light source 31 into optical signals 110 and 111 at a branching unit 32, and further branches and modulates the optical signal 110. MZ type optical modulator 33, MZ type optical modulator 34 that further divides and modulates optical signal 111, and combining means 35 that combines optical signals 116 and 117 output from MZ type optical modulators 33 and 34. A voltage calculation control unit 36 for calculating a DC bias voltage to be supplied to the MZ type optical modulator 33, the MZ type optical modulator 34, and the combining means 35, an electric signal source 37 for generating the electric signal 102, and an electric signal 105 A π / 2 phase shifter 38 that shifts the phase of π / 2, a variable DC voltage source 39 that supplies a DC bias voltage 107 to the MZ type optical modulator 33, and a DC bias voltage 108 to the MZ type optical modulator 34. And a variable DC voltage source 41 for supplying a DC bias voltage 109 to the combining means 35.

なお、本実施の形態の光変調装置30は、例えば、結晶方位をXカットとしたLN基板の表面にTiの熱拡散によって形成された光導波路と、LN基板に設けられた電極によって構成されている。光導波路のうち、光信号112及び113が導かれる光導波路は、本発明の第1及び第2の光導波路をそれぞれ構成し、また光信号114及び115が導かれる光導波路は、本発明の第3及び第4の光導波路をそれぞれ構成している。また、MZ型光変調器33及びMZ型光変調器34は、同一のLN基板上に並列に形成されている。   The light modulation device 30 according to the present embodiment includes, for example, an optical waveguide formed by thermal diffusion of Ti on the surface of an LN substrate having an X-cut crystal orientation, and an electrode provided on the LN substrate. Yes. Of the optical waveguides, the optical waveguides to which the optical signals 112 and 113 are guided constitute the first and second optical waveguides of the present invention, respectively, and the optical waveguides to which the optical signals 114 and 115 are guided are the first of the present invention. The third and fourth optical waveguides are respectively configured. Further, the MZ type optical modulator 33 and the MZ type optical modulator 34 are formed in parallel on the same LN substrate.

MZ型光変調器33は、光信号110を分岐して光信号112及び113の位相を調整する直流バイアス電圧107と光信号112及び113を変調する電気信号104とを入力する電極33aを備えている。   The MZ type optical modulator 33 includes an electrode 33a that inputs the DC bias voltage 107 that branches the optical signal 110 and adjusts the phase of the optical signals 112 and 113, and the electric signal 104 that modulates the optical signals 112 and 113. Yes.

MZ型光変調器34は、光信号111を分岐して光信号114及び115の位相を調整する直流バイアス電圧108と光信号114及び115を変調する電気信号106とを入力する電極34aを備えている。   The MZ type optical modulator 34 includes an electrode 34a that inputs a DC bias voltage 108 that branches the optical signal 111 and adjusts the phases of the optical signals 114 and 115, and an electric signal 106 that modulates the optical signals 114 and 115. Yes.

合成手段35は、光信号116及び117の位相を調整する直流バイアス電圧109を入力する電極35aと光信号116及び117を合成する合成部35bとを備えている。   The synthesizing unit 35 includes an electrode 35a for inputting a DC bias voltage 109 for adjusting the phases of the optical signals 116 and 117, and a synthesizing unit 35b for synthesizing the optical signals 116 and 117.

光源31は、例えばレーザーダイオードにより構成されている。   The light source 31 is composed of, for example, a laser diode.

電圧演算制御部36は、例えばマイクロプロセッサ、メモリ等により構成され、光搬送波成分レベルと光変調信号成分レベルとの比(以下、搬送波抑圧度という。)のデータがメモリに予め記憶されている。また、電圧演算制御部36は、後述のように搬送波抑圧度に基づき、可変直流電圧源39、40及び41の出力電圧をそれぞれ制御し、直流バイアス電圧107、108及び109を設定するようになっている。   The voltage calculation control unit 36 includes, for example, a microprocessor, a memory, and the like, and data of a ratio between the optical carrier component level and the optical modulation signal component level (hereinafter referred to as a carrier suppression level) is stored in the memory in advance. In addition, the voltage calculation control unit 36 controls the output voltages of the variable DC voltage sources 39, 40, and 41 based on the carrier wave suppression degree as described later, and sets the DC bias voltages 107, 108, and 109, respectively. ing.

なお、本実施の形態の光変調装置30において、電圧演算制御部36を備える構成を説明したが、本発明はこれに限定されるものではなく、電圧演算制御部36を光変調装置30から分離し、光変調装置30の外部から可変直流電圧源39、40及び41の出力電圧をそれぞれ制御するよう構成してもよい。   In addition, although the structure provided with the voltage calculation control part 36 was demonstrated in the light modulation apparatus 30 of this Embodiment, this invention is not limited to this, The voltage calculation control part 36 is isolate | separated from the light modulation apparatus 30. The output voltages of the variable DC voltage sources 39, 40, and 41 may be controlled from the outside of the light modulation device 30, respectively.

次に、本実施の形態の光変調装置30の動作について説明する。   Next, the operation of the light modulation device 30 of the present embodiment will be described.

まず、光源31によって、光信号101が出力され、光信号101は分岐部32で光信号110と111とに分岐され、それぞれ、MZ型光変調器33及び34に出力される。   First, the optical signal 101 is output from the light source 31, and the optical signal 101 is branched into optical signals 110 and 111 by the branching unit 32 and output to the MZ type optical modulators 33 and 34, respectively.

さらに、MZ型光変調器33において光信号110は、光信号112と113とに分岐される。また、MZ型光変調器34において光信号111は、光信号114と115とに分岐される。   Further, in the MZ type optical modulator 33, the optical signal 110 is branched into optical signals 112 and 113. In the MZ type optical modulator 34, the optical signal 111 is branched into optical signals 114 and 115.

MZ型光変調器33及びMZ型光変調器34からそれぞれ出力された光信号116及び117は、直流バイアス電圧109によって位相が調整された後、合成部35bで合成されて光信号118となる。   The phases of the optical signals 116 and 117 output from the MZ type optical modulator 33 and the MZ type optical modulator 34 are adjusted by the DC bias voltage 109, and then combined by the combining unit 35b to become the optical signal 118.

一方、電気信号源37によって出力された電気信号102は、電気信号104と105とに分岐され、それぞれ、MZ型光変調器33の電極33a及びπ/2移相器38に出力される。π/2移相器38において電気信号105の移相はπ/2シフトされ、MZ型光変調器34の電極34aに出力される。したがって、光信号112、113、114及び115は、各位相が互いに90度異なる電気信号で変調される。   On the other hand, the electrical signal 102 output from the electrical signal source 37 is branched into electrical signals 104 and 105, which are output to the electrode 33a of the MZ type optical modulator 33 and the π / 2 phase shifter 38, respectively. In the π / 2 phase shifter 38, the phase shift of the electric signal 105 is shifted by π / 2 and output to the electrode 34 a of the MZ type optical modulator 34. Therefore, the optical signals 112, 113, 114, and 115 are modulated with electrical signals whose phases are different from each other by 90 degrees.

光信号112及び113、光信号114及び115、光信号116及び117の各位相は、それぞれ、可変直流電圧源39、40及び41からそれぞれ出力される直流バイアス電圧107、108及び109によって制御される。   The phases of the optical signals 112 and 113, the optical signals 114 and 115, and the optical signals 116 and 117 are controlled by DC bias voltages 107, 108, and 109 output from the variable DC voltage sources 39, 40, and 41, respectively. .

ここで、可変直流電圧源39によって、光信号112と113とは逆極性となる位相変化が与えられる。同様に、可変直流電圧源40によって、光信号114と115とは逆極性となり、可変直流電圧源41によって、光信号116と117とは逆極性となる。   Here, the variable DC voltage source 39 gives a phase change having a polarity opposite to that of the optical signals 112 and 113. Similarly, the optical signals 114 and 115 are reversed in polarity by the variable DC voltage source 40, and the optical signals 116 and 117 are reversed in polarity by the variable DC voltage source 41.

直流バイアス電圧107、108及び109は、電圧演算制御部36によって、後述のように搬送波抑圧度に基づいて算出され、可変直流電圧源39、40及び41の出力電圧をそれぞれ制御することにより設定される。   The DC bias voltages 107, 108 and 109 are calculated by the voltage calculation control unit 36 based on the carrier wave suppression degree as will be described later, and are set by controlling the output voltages of the variable DC voltage sources 39, 40 and 41, respectively. The

以下、直流バイアス電圧107、108及び109の算出方法について説明する。   Hereinafter, a method of calculating the DC bias voltages 107, 108, and 109 will be described.

図1において、光信号112を含む経路をPath1、光信号113を含む経路をPath2、光信号114を含む経路をPath3、光信号115を含む経路をPath4とする。また、電極33a、電極34a、電極35aへのバイアス電圧印加による光信号の位相変位をそれぞれθ、θ、θとする。このとき、各経路を経たn番目の側波について、相対的な位相は、式(1)〜(4)のように表現できる。 In FIG. 1, the path including the optical signal 112 is Path1, the path including the optical signal 113 is Path2, the path including the optical signal 114 is Path3, and the path including the optical signal 115 is Path4. In addition, the phase displacement of the optical signal due to the application of the bias voltage to the electrode 33a, the electrode 34a, and the electrode 35a is set to θ A , θ B , and θ C , respectively. At this time, with respect to the nth side wave that has passed through each path, the relative phase can be expressed as shown in equations (1) to (4).

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

ところで、極座標系は式(5)のようにベクトル表示に相互に変換することができる。   By the way, the polar coordinate system can be mutually converted into a vector display as shown in Equation (5).

Figure 2005215196
Figure 2005215196

電極33a、電極34aでの位相変調指数をmpA、mpBとすると、n次側波の振幅はベッセル関数J(mpA)、J(mpB)で表現されることから、図1に示された出力1の第1上側波成分をベクトル表示すると、式(6)、式(7)のようになる。ただし、kは経路(Pathk)を意味し、変調前の各経路における光搬送波の振幅を1と正規化する。 Assuming that the phase modulation indexes at the electrodes 33a and 34a are m pA and m pB , the amplitude of the nth order side wave is expressed by Bessel functions J n (m pA ) and J n (m pB ). When the first upper side wave component of the output 1 shown in FIG. 5 is represented by a vector, Equations (6) and (7) are obtained. However, k means a path (Pathk), and the amplitude of the optical carrier wave in each path before modulation is normalized to 1.

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

式(6)、式(7)に式(1)〜(4)を代入し、整理すると式(8)、式(9)が得られる。   When Expressions (1) to (4) are substituted into Expressions (6) and (7) and rearranged, Expressions (8) and (9) are obtained.

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

ここで、図1に示された出力1の第1側波成分が0になる条件は、(x,y)=(0,0)である。つまり、式(10)及び式(11)、又は、式(12)及び式(13)が成立することが条件である。   Here, the condition that the first side wave component of the output 1 shown in FIG. 1 is 0 is (x, y) = (0, 0). That is, the condition is that Expression (10) and Expression (11) or Expression (12) and Expression (13) are satisfied.

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

ここで、バイアス電圧の調整により、θ=θとした場合、式(14)が成立するならば、式(11)は常に成立する。 Here, when θ A = θ B is set by adjusting the bias voltage, if equation (14) holds, equation (11) always holds.

Figure 2005215196
Figure 2005215196

なお、本実施の形態の光変調装置30のように、同一基板上に並列に形成した2組のMZ構造では、式(14)が成立すると考えて実用上差し支えない。   Note that, in the case of two sets of MZ structures formed in parallel on the same substrate as in the light modulation device 30 of the present embodiment, it may be practically considered that Expression (14) holds.

したがって、式(14)が成立する場合、式(15)、式(10)がSSBになる条件である。   Therefore, when the formula (14) is satisfied, the formula (15) and the formula (10) are conditions for becoming an SSB.

Figure 2005215196
Figure 2005215196

もしも、式(14)と式(15)とが同時に成立しない場合は、次の(a)、(b)のように対処できる。
(a)直流バイアス電圧107及び108を微調整して、式(11)を満たす。
(b)電気信号104及び106のレベルを微調整して、式(14)及び式(15)を同時に満たす。
If the equations (14) and (15) do not hold at the same time, the following (a) and (b) can be dealt with.
(A) The DC bias voltages 107 and 108 are finely adjusted to satisfy the expression (11).
(B) Finely adjust the levels of the electrical signals 104 and 106 to simultaneously satisfy equations (14) and (15).

また、式(10)と式(12)との関係は、電極35aに対して逆バイアスを印加した場合であり、式(11)と式(13)との関係は、電極34aに対して逆バイアスを印加した場合と同じである。   Further, the relationship between Equation (10) and Equation (12) is the case where a reverse bias is applied to the electrode 35a, and the relationship between Equation (11) and Equation (13) is opposite to that of the electrode 34a. This is the same as when a bias is applied.

次に、光搬送波成分と第1下側波成分とのレベル比を導入する。   Next, a level ratio between the optical carrier component and the first lower side wave component is introduced.

まず、光搬送波成分は、式(16)、式(17)で表される。   First, the optical carrier component is expressed by Expression (16) and Expression (17).

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

式(16)、式(17)に対して、式(1)〜(4)と式(10)とを代入すると、式(18)、式(19)が得られる。   By substituting Equations (1) to (4) and Equation (10) into Equations (16) and (17), Equations (18) and (19) are obtained.

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

式(14)と式(15)とが成立する場合、式(20)、式(21)が得られる。   When Expression (14) and Expression (15) hold, Expression (20) and Expression (21) are obtained.

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

したがって、光搬送波成分の振幅レベルは、式(22)で表される。   Therefore, the amplitude level of the optical carrier component is expressed by Equation (22).

Figure 2005215196
Figure 2005215196

続いて、第1下側波成分を導出する。式(6)、式(7)に対して式(1)〜式(4)と式(10)とを代入すると、式(23)と式(24)とが得られる。   Subsequently, a first lower side wave component is derived. When Expression (1) to Expression (4) and Expression (10) are substituted into Expression (6) and Expression (7), Expression (23) and Expression (24) are obtained.

Figure 2005215196
Figure 2005215196

Figure 2005215196
Figure 2005215196

式(15)より、第1下側波成分のレベルは、式(25)で表される。   From equation (15), the level of the first lower side wave component is represented by equation (25).

Figure 2005215196
Figure 2005215196

式(25)に式(14)を代入すると、式(26)が得られる。   Substituting equation (14) into equation (25) yields equation (26).

Figure 2005215196
Figure 2005215196

式(22)及び式(26)より、光搬送波成分と第1下側波成分とのレベル比は、式(27)で表される。   From Expression (22) and Expression (26), the level ratio between the optical carrier wave component and the first lower side wave component is expressed by Expression (27).

Figure 2005215196
Figure 2005215196

なお、位相変調指数mpAが十分小さい場合は、J(mpA)は正数であるため、J(mpA)の絶対値記号は省略可能である。 When the phase modulation index m pA is sufficiently small, J n (m pA ) is a positive number, and thus the absolute value symbol of J n (m pA ) can be omitted.

したがって、所望の光搬送波信号成分レベル対第1下側波成分レベル(搬送波抑圧度)を式(27)の左辺に代入し、式(27)を満足するθを求めることで、光搬送波成分レベルを任意の値に抑圧することが可能である。 Therefore, by substituting the desired optical carrier signal component level versus the first lower side wave component level (carrier suppression degree) into the left side of Equation (27) and obtaining θ A that satisfies Equation (27), the optical carrier component It is possible to suppress the level to an arbitrary value.

なお、式(14)、式(15)が成立しない場合、前述の手順と同様に式(18)及び式(19)から光搬送波成分レベルAが求まり、式(23)及び式(24)から第1下側波成分レベルA−1が求まる。 In the case where Expression (14) and Expression (15) are not satisfied, the optical carrier component level A 0 is obtained from Expression (18) and Expression (19) in the same manner as described above, and Expression (23) and Expression (24) are obtained. To obtain the first lower side wave component level A- 1 .

一般に、位相変調器への印加電圧Vと半波長電圧Vπ及び位相変位θとの関係は、式(28)で表される。 In general, the relationship between the voltage V applied to the phase modulator, the half-wave voltage Vπ, and the phase displacement θ is expressed by Expression (28).

Figure 2005215196
Figure 2005215196

したがって、算出したθ、θ、θに対して、装置の半波長電圧VπA、VπB、VπC
代入することで、直流バイアス電圧107、108、109が求まる。
Therefore, the calculated theta A, theta B, relative theta C, half-wave voltage V? Pa of the device, V PaiB, by substituting V PaiC, DC bias voltage 107, 108 and 109 is obtained.

なお、VπA、VπB、VπCは位相変調装置に固有の定数であるが、これらの定数は、例えば「"60GHz共振型LiNbO3光変調器の基礎検討"及川他著、住友大阪セメントテクニカルレポート http://www.socnb.com/product/htech/ln_tech.html」に開示されている方法等により算出することができる。 V πA , V πB , and V πC are constants specific to the phase modulator. These constants are, for example, “" Basic study of 60 GHz resonant LiNbO3 optical modulator ”, Oikawa et al., Sumitomo Osaka Cement Technical Report. It can be calculated by the method disclosed in “http://www.socnb.com/product/htech/ln_tech.html”.

ここで、直流バイアス電圧107、108、109をDC、DC、DCと置く。例えば、半波長電圧VπA=2.9(V)、VπB=2.9(V)、VπC=6.0(V)である場合、SSB信号となるバイアス電圧の一例は、DC=DC=2.9(V)、DC=3.0(V)となる。この例では搬送波成分が完全に抑圧され、第1下側波成分のみが出力される。 Here, the DC bias voltages 107, 108, and 109 are set as DC A , DC B , and DC C , respectively. For example, when the half-wave voltage V πA = 2.9 (V), V πB = 2.9 (V), and V πC = 6.0 (V), an example of the bias voltage that becomes the SSB signal is DC A = DC B = 2.9 (V), DC C = 3.0 (V). In this example, the carrier wave component is completely suppressed, and only the first lower side wave component is output.

また、位相変調指数mpA、mpBがともに0.01である場合に、|A/A−1|が30dBとなるSSB信号を出力するバイアス電圧の一例は、式(27)より算出でき、DC=DC=5.55(V)、DC=3.0(V)となる。 In addition, when the phase modulation indices m pA and m pB are both 0.01, an example of a bias voltage that outputs an SSB signal with | A 0 / A −1 | of 30 dB can be calculated from Equation (27). DC A = DC B = 5.55 (V), DC C = 3.0 (V).

図2は、本実施の形態の光変調装置30によって光信号を生成し、生成した光信号を40GHz帯の周波数までダウンコンバートした信号のスペクトルの一例を示している。   FIG. 2 shows an example of a spectrum of a signal obtained by generating an optical signal by the optical modulation device 30 of the present embodiment and down-converting the generated optical signal to a frequency of 40 GHz band.

以上のように、本実施の形態の光変調装置30によれば、電圧演算制御部36は、MZ型光変調器33及び34と合成手段35とに供給する直流バイアス電圧を予め指定された搬送波抑圧度に基づいて算出する構成としたので、光搬送波成分を任意のレベルまで抑圧することができる。   As described above, according to the optical modulation device 30 of the present embodiment, the voltage calculation control unit 36 uses the DC bias voltage supplied to the MZ type optical modulators 33 and 34 and the synthesizing unit 35 as a predetermined carrier wave. Since the calculation is based on the degree of suppression, the optical carrier component can be suppressed to an arbitrary level.

なお、本実施の形態の光変調装置30は、前述のように光搬送波成分レベルを抑圧して低減させることができるので、光変調装置30の出力信号を増幅器により増幅し、光信号電力を大きくすることができる。その結果、同一受光電力時の受信端でのCN比は大きくなる。したがって、本実施の形態の光変調装置30によれば、光電力を大きくするために従来使用されていたダミー信号等の付加的な電気信号を印加することなく、周波数のずれた散乱光(ストークス光)を生む現象である誘導ブリルアン散乱の抑圧と等価的な受信CN比向上効果を得ることができる。   Since the optical modulation device 30 of this embodiment can suppress and reduce the optical carrier component level as described above, the output signal of the optical modulation device 30 is amplified by an amplifier to increase the optical signal power. can do. As a result, the CN ratio at the receiving end at the same received light power increases. Therefore, according to the light modulation device 30 of the present embodiment, the scattered light (Stokes) having a shifted frequency can be obtained without applying an additional electrical signal such as a dummy signal conventionally used to increase the optical power. The reception CN ratio improvement effect equivalent to suppression of stimulated Brillouin scattering, which is a phenomenon that produces light), can be obtained.

(第2の実施の形態)
まず、本発明の第2の実施の形態の光変調装置の構成について説明する。
(Second Embodiment)
First, the configuration of the light modulation device according to the second embodiment of the present invention will be described.

図3に示すように、本実施の形態の光変調装置50は、本発明の第1の実施の形態の光変調装置30にカプラ51及びレベル検出部52を追加したものである。したがって、光変調装置30と同様な構成については同一の符号を付し、構成の説明は省略する。   As shown in FIG. 3, the light modulation device 50 according to the present embodiment is obtained by adding a coupler 51 and a level detection unit 52 to the light modulation device 30 according to the first embodiment of the present invention. Accordingly, the same components as those of the light modulation device 30 are denoted by the same reference numerals, and the description of the components is omitted.

本実施の形態の光変調装置50は、光信号を分岐するカプラ51と、カプラ51から出力される光信号のレベルを検出するレベル検出部52とを備えている。   The optical modulation device 50 according to the present embodiment includes a coupler 51 that branches an optical signal, and a level detector 52 that detects the level of the optical signal output from the coupler 51.

カプラ51は、合成手段35により合成されて出力された光信号118を2つに分岐し、一方を光変調装置50の出力2として出力し、他方をレベル検出部52に供給する光信号319として出力するようになっている。   The coupler 51 branches the optical signal 118 synthesized and outputted by the synthesizing unit 35 into two, outputs one as the output 2 of the optical modulation device 50, and supplies the other as the optical signal 319 supplied to the level detection unit 52. It is designed to output.

レベル検出部52は、電圧演算制御部36に接続されており、電圧演算制御部36から搬送波抑圧度の設定値(以下、設定搬送波抑圧度という。)のデータを取得するようになっている。また、レベル検出部52は、光信号302に含まれる光搬送波成分レベル及び第1側波帯信号成分レベルを検出して搬送波抑圧度を算出し、算出した搬送波抑圧度(以下、検出搬送波抑圧度という。)と設定搬送波抑圧度とを比較するようになっている。   The level detection unit 52 is connected to the voltage calculation control unit 36, and acquires data of a set value of the carrier wave suppression degree (hereinafter referred to as a set carrier wave suppression degree) from the voltage calculation control unit 36. The level detector 52 detects the optical carrier component level and the first sideband signal component level included in the optical signal 302 to calculate the carrier suppression degree, and calculates the calculated carrier suppression degree (hereinafter, detected carrier suppression degree). And the set carrier suppression degree.

次に、本実施の形態の光変調装置50の動作について説明する。なお、光変調装置30と同様な動作については、詳細な説明を省略する。   Next, the operation of the light modulation device 50 of the present embodiment will be described. Note that detailed description of operations similar to those of the light modulation device 30 is omitted.

合成手段35により合成されて出力された光信号118は、カプラ51によって、光信号301と光信号302とに分岐される。次いで、レベル検出部52によって、光信号302に含まれる光搬送波成分レベル及び第1側波帯信号成分レベルが検出される。さらに、レベル検出部52によって、検出搬送波抑圧度が算出される。   The optical signal 118 synthesized and output by the synthesizing unit 35 is branched into an optical signal 301 and an optical signal 302 by the coupler 51. Next, the level detection unit 52 detects the optical carrier component level and the first sideband signal component level included in the optical signal 302. Further, the level detection unit 52 calculates the detected carrier suppression degree.

引き続き、レベル検出部52によって、電圧演算制御部36から設定搬送波抑圧度のデータが読み出され、設定搬送波抑圧度と検出搬送波抑圧度とが比較される。   Subsequently, the level detection unit 52 reads the data on the set carrier suppression degree from the voltage calculation control unit 36, and compares the set carrier suppression degree with the detected carrier suppression degree.

ここで、設定搬送波抑圧度と検出搬送波抑圧度とが一致しないとき、レベル検出部52によって、電圧演算制御部36を介し、可変直流電圧源39、40及び41からそれぞれ出力される直流バイアス電圧107、108及び109が例えば積分制御により、設定搬送波抑圧度と検出搬送波抑圧度とが一致するよう微調整される。なお、設定搬送波抑圧度と検出搬送波抑圧度との一致は完全な一致のみに限定されるものではなく、例えば予め定められた閾値によって一致しているか否かが判断される。   Here, when the set carrier suppression degree and the detected carrier suppression degree do not match, the DC bias voltage 107 output from the variable DC voltage sources 39, 40, and 41 via the voltage calculation control unit 36 by the level detection unit 52, respectively. , 108 and 109 are finely adjusted, for example, by integration control so that the set carrier suppression degree and the detected carrier suppression degree coincide. Note that the coincidence between the set carrier suppression degree and the detected carrier suppression degree is not limited to perfect coincidence, and for example, it is determined whether or not they coincide with each other based on a predetermined threshold.

以上のように、本実施の形態の光変調装置50によれば、レベル検出部52は、設定搬送波抑圧度と検出搬送波抑圧度とが一致するよう直流バイアス電圧107、108及び109を微調整する構成としたので、出力する光信号301の搬送波抑圧度の精度を向上させることができる。   As described above, according to the optical modulation device 50 of the present embodiment, the level detection unit 52 finely adjusts the DC bias voltages 107, 108, and 109 so that the set carrier suppression degree matches the detected carrier suppression degree. Since the configuration is adopted, the accuracy of the carrier wave suppression degree of the output optical signal 301 can be improved.

本発明の第1の実施の形態の光変調装置のブロック図1 is a block diagram of a light modulation device according to a first embodiment of the present invention. 本発明の第1の実施の形態の光変調装置で生成した光信号を40GHz帯の周波数にダウンコンバートした信号のスペクトル例を示す図The figure which shows the spectrum example of the signal which downconverted the optical signal produced | generated with the optical modulation apparatus of the 1st Embodiment of this invention to the frequency of 40 GHz band 本発明の第2の実施の形態の光変調装置のブロック図The block diagram of the light modulation apparatus of the 2nd Embodiment of this invention 従来の光変調装置のブロック図Block diagram of a conventional light modulation device 従来の光変調装置のブロック図Block diagram of a conventional light modulation device

符号の説明Explanation of symbols

30、50 光変調装置
31 光源
32 分岐部
33 MZ型光変調器(第1の光変調器)
33a 電極(第1の電極)
34 MZ型光変調器(第2の光変調器)
34a 電極(第2の電極)
35 合成手段
35a 電極(第3の電極)
35b 合成部
36 電圧演算制御部(バイアス電圧算出手段)
37 電気信号源
38 π/2移相器
39、40、41 可変直流電圧源
51 カプラ
52 レベル検出部(レベル検出手段)
101、110、111、116、117、118、301、302 光信号
102、104、105、106 電気信号
107 直流バイアス電圧(第1のバイアス電圧)
108 直流バイアス電圧(第2のバイアス電圧)
109 直流バイアス電圧(第3のバイアス電圧)
112 光信号(第1の光信号)
113 光信号(第1の光信号)
114 光信号(第2の光信号)
115 光信号(第2の光信号)
30, 50 Light modulation device 31 Light source 32 Branching unit 33 MZ type light modulator (first light modulator)
33a electrode (first electrode)
34 MZ type optical modulator (second optical modulator)
34a electrode (second electrode)
35 synthesis means 35a electrode (third electrode)
35b synthesis unit 36 voltage calculation control unit (bias voltage calculation means)
37 Electric signal source 38 π / 2 phase shifter 39, 40, 41 Variable DC voltage source 51 Coupler 52 Level detection unit (level detection means)
101, 110, 111, 116, 117, 118, 301, 302 Optical signal 102, 104, 105, 106 Electrical signal 107 DC bias voltage (first bias voltage)
108 DC bias voltage (second bias voltage)
109 DC bias voltage (third bias voltage)
112 optical signal (first optical signal)
113 optical signal (first optical signal)
114 optical signal (second optical signal)
115 optical signal (second optical signal)

Claims (5)

第1及び第2の光導波路に導かれた第1の光信号を変調する第1の光変調器と、第3及び第4の光導波路に導かれた第2の光信号を変調する第2の光変調器と、光信号を合成する合成手段と、バイアス電圧を算出するバイアス電圧算出手段とを有し、
前記第1の光変調器は、前記第1の光信号の位相を調整する第1のバイアス電圧を入力する第1の電極を備え、
前記第2の光変調器は、前記第2の光信号の位相を調整する第2のバイアス電圧を入力する第2の電極を備え、
前記合成手段は、前記第1及び前記第2の光変調器から出力される光信号の位相を調整する第3のバイアス電圧を入力する第3の電極を備え、
前記バイアス電圧算出手段は、前記第1のバイアス電圧、前記第2のバイアス電圧及び前記第3のバイアス電圧を光搬送波成分レベルと光変調信号成分レベルとの比を表す搬送波抑圧度によって算出することを特徴とする光変調装置。
A first optical modulator that modulates the first optical signal guided to the first and second optical waveguides, and a second that modulates the second optical signal guided to the third and fourth optical waveguides An optical modulator, a combining means for combining optical signals, and a bias voltage calculating means for calculating a bias voltage,
The first optical modulator includes a first electrode for inputting a first bias voltage for adjusting a phase of the first optical signal,
The second optical modulator includes a second electrode for inputting a second bias voltage for adjusting a phase of the second optical signal,
The combining unit includes a third electrode for inputting a third bias voltage for adjusting a phase of an optical signal output from the first and second optical modulators,
The bias voltage calculation means calculates the first bias voltage, the second bias voltage, and the third bias voltage based on a carrier suppression degree that represents a ratio between an optical carrier component level and an optical modulation signal component level. A light modulation device characterized by the above.
前記光搬送波成分レベル及び前記光変調信号成分レベルを前記合成手段の出力信号から検出するレベル検出手段を備えたことを特徴とする請求項1又は請求項2に記載の光変調装置。 3. The optical modulation device according to claim 1, further comprising level detection means for detecting the optical carrier component level and the optical modulation signal component level from an output signal of the synthesis means. 前記第1及び前記第2の光変調器は、マッハツェンダ型の光変調器であることを特徴とする請求項1から請求項3までのいずれか1項に記載の光変調装置。 4. The light modulation device according to claim 1, wherein the first and second light modulators are Mach-Zehnder type light modulators. 5. 単側波帯の光変調を行うことを特徴とする請求項1から請求項4までのいずれか1項に記載の光変調装置。 5. The light modulation device according to claim 1, wherein single-sideband light modulation is performed. 6. 第1の光信号の位相を第1のバイアス電圧で調整するとともに、第2の光信号の位相を第2のバイアス電圧で調整し、位相が調整された前記第1及び前記第2の光信号に対して第3のバイアス電圧で位相を調整する光変調方法であって、前記第1のバイアス電圧、前記第2のバイアス電圧及び前記第3のバイアス電圧は、光搬送波成分レベルと光変調信号成分レベルとの比を表す搬送波抑圧度によって設定されることを特徴とする光変調方法。 The phase of the first optical signal is adjusted by the first bias voltage, the phase of the second optical signal is adjusted by the second bias voltage, and the first and second optical signals whose phases are adjusted are adjusted. The optical modulation method adjusts the phase with a third bias voltage, wherein the first bias voltage, the second bias voltage, and the third bias voltage are an optical carrier component level and an optical modulation signal. An optical modulation method characterized in that the optical modulation method is set by a carrier wave suppression degree representing a ratio to a component level.
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