JP2008135992A - Optical ofdm receiving circuit, optical ofdm receiver, optical ofdm transmission system, optical ofcdm receiving circuit, optical ofcdm receiver and optical ofcdm transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical receiving circuit, an optical receiver and an optical transmission system capable of performing receiving with a fixed code error rate without depending upon a multiplex number because signal light intensity rapidly attenuates according to the square of the multiple number according as the multiple number increases to increase a code error rate in the conventional practice. <P>SOLUTION: The optical receiving circuit, the optical receiver and the optical transmission system convert an optical signal into an electric signal, and subsequently perform discrete Fourier transformation of integral control action and an identification operation in an electrical area. The number M of branches of an electrical branching means included in an electrical integrating means is not related to the multiplex number N of an optical OFDM signal. Consequently, a BER (Bit-Error-Rate) is prevented from deteriorating because the number of branches does not change the a receiving circuit even if the multiplex number N increases while signal light intensity to be inputted to the receiving circuit is in a fixed state. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical OFDM receiver circuit, an optical OFDM receiver, an optical OFDM transmission system, an optical OFCDM receiver circuit, an optical OFCDM receiver, and an optical OFCDM transmission system.

  In order to increase the transmission capacity in an optical fiber transmission system, an optical frequency division multiplex transmission system that multiplexes and transmits optical signals having different optical frequencies on one optical fiber has been realized.

FIG. 1 is a configuration example of an optical frequency division multiplex transmission system. Transmitting circuit ₁₁ -1 _{to 11 -N} transmits a different signal light of optical frequencies. The transmitted signal lights are multiplexed by the optical frequency multiplexing means 12 and output to the optical fiber transmission line 13. In the receiving apparatus 16, the multiplexed signal light transmitted, and demultiplexed by the optical frequency dividing means 14 for each optical frequency, received by each receiving circuit 15 _-1 to 15 _-N.

  In an optical frequency division multiplexing transmission system, in order to transmit more signals in a certain optical frequency band, improvement in frequency use efficiency is required. Here, the frequency utilization efficiency can be expressed as B / Δf, where B is an optical signal band and Δf [Hz] is an optical frequency interval between adjacent signal lights.

  In a conventional optical frequency division multiplexing transmission system, in order to receive a desired signal light without being affected by the adjacent signal light, the adjacent signal light can be separated by an optical frequency demultiplexer. It was necessary to widen the optical frequency interval between the lights. For this reason, B / Δf≈0.4 when both sidebands are transmitted without limiting the signal band such as filtering one sideband on the transmission circuit side and polarization multiplexing is not performed.

By using an optical discrete Fourier transform circuit as shown in FIG. 2 as a method for improving frequency utilization efficiency, an optical frequency division multiplexed signal multiplexed with B / Δf ≦ 1 is received without using an optical frequency demultiplexer. An optical orthogonal frequency division multiplexing transmission system is described in Patent Document 1. Here, FIG. 2 of Patent Document 1 shows a case where the multiplexing number is four.
JP 2003-51810 A

  However, since the signal light input to the optical discrete Fourier transform circuit of FIG. 2 is branched by the optical branching means 21 and 23 according to the multiplexing number N, the branching loss in the circuit increases when the circuit is enlarged. . Therefore, when the signal light intensity input to the optical discrete Fourier transform circuit is constant, the signal light intensity attenuates in the conversion circuit as the multiplexing number N increases, and a code error rate (BER: Bit− There is a problem that the error-rate is deteriorated.

  Furthermore, in order to obtain a constant reception sensitivity when the multiplexing number N is increased, it is necessary to increase the signal light intensity input to the optical discrete Fourier transform circuit. However, since the signal light intensity output from the transmission circuit is limited, the permissible loss of signal light between the transmitting and receiving apparatuses is reduced. Therefore, there has been a problem that the number N of multiplexing is limited in order to obtain a certain allowable loss between the transmitting and receiving apparatuses.

  The present invention has been made to solve the above-described problems, and provides an optical receiving circuit and an optical receiving apparatus capable of preventing BER deterioration accompanying an increase in the number of multiplexed signal lights, and an increase in the number of multiplexed signal lights. An object of the present invention is to provide an optical transmission system capable of preventing a reduction in allowable loss of received light due to the above.

  In order to achieve the above object, the optical OFDM receiver circuit according to the first invention, the optical OFDM receiver according to the second invention, and the optical OFDM transmission system according to the third invention are provided in the electrical domain after converting an optical signal into an electrical signal. The discrete Fourier transform of the integration operation and the identification operation is performed in FIG.

  Specifically, the first invention of the present application is an optical OFDM receiving circuit to which an optical OFDM signal obtained by multiplexing signal light in the optical signal band B [Hz] at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1 is input. One of the bit phase adjusting means for adjusting the bit phases of the respective signal lights constituting the optical OFDM signal and the signal light constituting the optical OFDM signal from the bit phase adjusting means Is converted into a baseband electric signal, and the other is converted into an intermediate frequency band electric signal carried by a carrier wave having a frequency that is an integer multiple of Δf, and output from the coherent detection means. An optical OFDM receiving circuit comprising: an electrical integration unit that integrates and outputs over Δf [s]; and an identification unit that determines a threshold value of the output from the electrical integration unit.

  Further, the electrical integration means of the optical OFDM receiver circuit according to the first invention of the present application has M electrical signals from the coherent detection means (M is not related to the number of signal lights constituting the optical OFDM signal). An electrical branching means for branching to an integer), an electrical delaying means for adding a different delay by 1 / (M · Δf) [s] to each output of the electrical branching means, and the electrical An electrical multiplexing unit that multiplexes and outputs each component from the delay unit, and a low-pass filter that transmits and outputs a component having a frequency of Δf [Hz] or less among the outputs from the electrical multiplexing unit And the discriminating means uses (M−1) / (M · Δf) based on the component with the smallest delay among the M components included in the output from the low-pass filtering means. The threshold value is determined in a portion corresponding to ˜1 / Δf [s].

  The optical OFDM receiver circuit according to the first invention of the present application first converts an input optical signal into an electric signal by the coherent detection means. Next, an integration operation is performed on the electrical signal by electrical integration means. The branching number M of the electrical branching means included in the electrical integrating means is not related to the multiplexing number N of the optical OFDM signal. For this reason, even if the number N of multiplexed signals increases when the intensity of signal light input to the receiving circuit is constant, the number of branches in the receiving circuit does not change, so that deterioration of the BER can be prevented.

  Therefore, the first invention of the present application can provide an optical receiver circuit capable of preventing the deterioration of BER due to an increase in the number of multiplexed signal lights. Furthermore, since coherent detection with higher reception sensitivity compared to direct detection is used, there is an effect that high sensitivity reception can be achieved.

  A second invention of the present application is an optical OFDM receiving apparatus comprising: an optical branching means for branching an optical OFDM signal into a plurality of outputs; and a plurality of optical OFDM receiving circuits according to the first invention of the present application, wherein the optical branching means Is an optical OFDM receiver characterized in that an optical OFDM signal from the outside is branched and coupled to each of the optical OFDM receiver circuits.

  In the optical discrete Fourier transform circuit described in the cited document 1, the branch loss is proportional to the square of N. On the other hand, the optical branching performed by the optical OFDM receiver according to the second invention of the present application is one time at the optical branching means, and the branching loss is proportional to N.

  Therefore, the second invention of the present application can provide an optical receiver that can significantly reduce the branching loss compared to the conventional optical discrete Fourier transform circuit and can prevent the deterioration of the BER accompanying the increase in the number of multiplexed signal lights. Furthermore, since coherent detection with higher reception sensitivity compared to direct detection is used, there is an effect that high sensitivity reception can be achieved.

  The second invention of the present application has a plurality of output ports each having a unique center transmission optical frequency equal to the optical frequency of each optical carrier wave of the signal light constituting the optical OFDM signal, and each of the output ports is an optical OFDM signal. And optical frequency demultiplexing means for transmitting and outputting signal light whose optical frequency of the optical carrier coincides with the inherent central transmitted optical frequency, and a plurality of optical OFDM receivers according to the first invention of the present application An optical OFDM receiver comprising: a circuit; and an optical frequency demultiplexing unit that outputs signal light constituting an optical OFDM signal from the outside from each of the output ports and couples the signal light to the optical OFDM receiver circuit An optical OFDM receiver characterized by this may be used.

  The optical OFDM receiver includes optical frequency demultiplexing means as an alternative to the optical branching means. Therefore, the optical OFDM receiving apparatus including the optical frequency demultiplexing means has an effect that the allowable loss between the transmitting and receiving apparatuses can be further expanded in addition to the effect described in the optical OFDM receiving apparatus using the optical branching means. .

  The third invention of the present application includes an optical OFDM transmitter for transmitting an optical OFDM signal obtained by multiplexing the signal light having an optical signal band of B [Hz] at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1, and an optical fiber. An optical OFDM transmission system comprising: an optical OFDM receiver according to the second invention of the present application connected to the optical OFDM transmitter via a transmission line.

  Since the optical OFDM transmission system according to the third invention of the present application receives the optical OFDM signal from the optical OFDM transmission apparatus by the optical OFDM receiver according to the second invention of the present application, compared to the optical transmission system described in Patent Document 1, The increase in branching loss due to the increase in the number N of multiplexing is small, and the allowable loss between the transmitting and receiving apparatuses can be increased.

  Therefore, the third invention of the present application can provide an optical transmission system capable of preventing a reduction in allowable loss of received light accompanying an increase in the number of multiplexed signal lights. Further, since coherent detection with higher reception sensitivity compared to direct detection is used, it is possible to further increase the allowable loss, and the number of multiplexing N that is limited to obtain a constant allowable loss between the transmitting and receiving apparatuses. Can be further expanded.

  In order to achieve the above object, the optical OFCDM receiving circuit according to the fourth invention of the present application, the optical OFCDM receiving device according to the fifth invention of the present application, and the optical OFCDM transmission system according to the sixth invention convert the optical OFCDM signal into an electrical signal. Later, discrete Fourier transform of integration operation and discrimination operation was performed in the electrical domain.

  Specifically, the fourth invention of the present application is an optical OFCDM receiving circuit to which a unique code consisting of a code element (1) and a code element (0) is assigned, and the interval between adjacent optical frequency components is Δf [Hz. Of the components of the multi-wavelength light to which the code element (1) or the code element (0) of the code is assigned, the component to which the code element (1) is assigned satisfies B / Δf ≦ 1 Each component corresponding to the code element (1) carries an optical OFCDM signal which is an optical carrier wave of the signal light of the signal band B [Hz] and which carries the same signal corresponding to the component corresponding to the code element (1). An optical OFCDM signal separation device that separates each signal, converts the signal into an electrical signal, and outputs the electrical signal; and an electrical addition / subtraction unit that adds and subtracts each output from the optical OFCDM signal separation device according to the unique code. Features The optical OFCDM receiving circuit.

  The optical OFCDM signal separation device of the optical OFCDM receiver circuit according to the fourth invention of the present application may be the optical OFDM receiver device according to the second invention of the present application.

  Further, the optical OFCDM signal separation device of the optical OFCDM receiving circuit according to the fourth invention of the present application has a plurality of outputs each having a unique central transmitted optical frequency equal to the optical frequency of each optical carrier wave of the signal light constituting the optical OFCDM signal. Each of the output ports transmits a signal light whose optical frequency of the optical carrier wave coincides with the specific center transmission optical frequency among the signal lights constituting the optical OFCDM signal, and outputs the signal light. A wave phase adjusting means for adjusting the bit phase of signal light output from each output port of the optical frequency demultiplexing means, and an optical OFCDM signal from the bit phase adjusting means are directly detected. A threshold is determined for the direct detection means, the electrical integration means for integrating the output of the direct detection means over 1 / Δf [s], and the output of the electrical integration means. An optical OFCDM signal input from the outside is demultiplexed by the optical frequency demultiplexing unit, and adjusted by the bit phase adjusting unit so that the bit phases of the signal light constituting the optical OFCDM signal coincide with each other An optical OFCDM receiving circuit may be used.

  The optical OFCDM receiving circuit according to the fourth invention of the present application first demultiplexes an input optical signal into frequency components of the optical signal by the optical OFCDM signal separation device, and converts the signal light carried by the component into an electrical signal. is doing. Since the optical OFCDM signal is a special form of optical OFDM, the same effect as described in the first invention of the present application can be obtained.

  A fifth invention of the present application is an optical OFCDM receiving apparatus comprising: an optical branching means for branching an optical OFCDM signal into a plurality of outputs; and a plurality of optical OFCDM receiving circuits according to the fourth invention of the present application, wherein the optical branching means Is an optical OFCDM receiving apparatus that branches an optical OFCDM signal from the outside and couples the optical OFCDM signal to each of the optical OFCDM receiving circuits.

  The optical branching performed by the optical OFCDM receiver according to the fifth invention of the present application is one time at the optical branching means, and the branching loss is proportional to N. Therefore, the fifth invention of the present application can obtain the same effects as those described in the second invention of the present application.

  The sixth invention of the present application relates to one or more optical OFCDM transmission circuits that transmit the optical OFCDM signal corresponding to the assigned unique code, and the optical multiplexing that combines the optical OFCDM signals transmitted by the optical OFCDM transmission circuit. An optical OFCDM transmission system comprising: an optical OFCDM transmission apparatus having means; and an optical OFCDM reception apparatus according to the fifth invention of the present application connected to the optical OFCDM transmission apparatus via an optical fiber transmission line, wherein the optical OFCDM The optical OFCDM receiving circuit included in the receiving apparatus receives only the optical OFCDM signal transmitted by the optical OFCDM transmitting circuit assigned the same code as the code assigned to the optical OFCDM receiving circuit. This is an OFCDM transmission system.

  The optical OFCDM transmission system according to the sixth invention of the present application receives the optical OFCDM signal from the optical OFCDM transmitter by the optical OFCDM receiver according to the fifth invention of the present application. The optical OFCDM transmission system according to the sixth invention of the present application has a smaller amount of increase in branching loss due to the increase in the number N of multiplexing than the optical transmission system described in Patent Document 1, and can increase the allowable loss between the transmitting and receiving apparatuses. It becomes possible.

  Therefore, the sixth invention of the present application can obtain the same effects as those described in the third invention of the present application.

  According to the present invention, for an optical OFDM signal or an optical OFCDM signal, an optical receiving circuit and an optical receiving apparatus capable of preventing BER deterioration accompanying an increase in the number of multiplexed signal lights, and a reception associated with an increase in the number of multiplexed signal lights. It is possible to provide an optical transmission system that can prevent a reduction in allowable loss of light.

  Embodiments of the present invention will be described with reference to the accompanying drawings. The embodiment described below is an example of the configuration of the present invention, and the present invention is not limited to the following embodiment.

(First embodiment)
The first embodiment is an optical OFDM receiving circuit to which an optical OFDM signal obtained by multiplexing signal light in an optical signal band B [Hz] at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1 is input. Bit phase adjusting means for adjusting the bit phases of the respective signal lights constituting the optical OFDM signal, and one of the signal lights constituting the optical OFDM signal from the bit phase adjusting means as baseband electricity Coherent detection means for converting the signal into an intermediate frequency band electric signal carried by a carrier wave whose frequency is an integer multiple of Δf, and outputting the output from the coherent detection means to 1 / Δf [s] An optical OFDM receiving circuit comprising: an electrical integration means that integrates and outputs the output; and an identification means for determining a threshold value of the output from the electrical integration means.

  FIG. 3 shows a configuration diagram of an optical orthogonal frequency division multiplexing (OFDM) receiving circuit in the first embodiment. An optical OFDM signal S (t) obtained by multiplexing an optical signal in the optical signal band B [Hz] at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1 is input to the receiving circuit. FIG. 3 shows a case where B / Δf = 1. In the signal light whose optical signal band is B [Hz], the signal transmission speed differs depending on the modulation method. For example, the signal transmission speed in the case of the binary ASK modulation system is B [bit / s], but the speed can be increased by multi-level modulation.

  The optical OFDM signal S (t) input to the receiving circuit is adjusted by the bit phase adjusting means 31 so that the bit phases of the signal lights constituting the optical OFDM signal S (t) are matched, and the coherent detection means 32 is supplied. Entered. At this time, the optical OFDM signal S (t) at the input end of the coherent detection means 32 can be expressed by Equation 1.

Here, f ₀ is the optical frequency of the optical carrier having the lowest optical frequency among the optical carriers of each signal light constituting the optical OFDM signal S (t), and N is the number of multiplexed optical OFDM signals. _{Also, P i, θ i, a} i (t) are each intensity of i-th and is signal light from the side the optical frequency is low, the optical carrier initial phase, the signal value at time _{t, a} i (t ) Is constant during the symbol time T = 1 / B [s].

In the coherent detection means 32, the optical OFDM signal S (t) is mixed with local light and detected. The polarization state of the local light is adjusted so as to match at least a desired signal light among the signal lights constituting the optical OFDM signal S (t). Although a local light source may be disposed in the coherent detection means 32, light supplied from the outside to the optical OFDM receiver circuit may be local light. The optical frequency f _LO of the local light carries a desired signal a _k (t) (k = 1, 2,... N) among the optical carriers of the signal lights constituting the optical OFDM signal S (t). It is almost equal to the optical frequency of the optical carrier. The fact that the optical frequency of the optical carrier that carries the desired signal and the local light is approximately equal means that α is sufficiently smaller than Δf when the optical frequency difference is α [Hz], and coherent detection means At 32, homodyne detection can be performed.

  In homodyne detection, the optical frequencies of the signal light and the local light should ideally match. For example, when the frequency difference α [Hz] is sufficiently smaller than the signal speed B [bit / s], α = 6.8 MHz (B = 680 [Mbit / s]), α = 5 MHz (B = 5 [Gbit / s]) and so on.

At this time, the optical frequency dispersion f _LO of the local light can be expressed by Equation 2.

If α << Δf and ignoring α, the local light can be expressed as in Equation 3.

Here, P _LO is the local light intensity, and θ _LO is the initial phase. At this time, the output P ₁ (t) of the coherent detection means 32 can be expressed as in Expression 4.

That is, a desired signal a _k (t) carried by an optical carrier whose optical frequency is substantially equal to that of local light is converted into a baseband signal. On the other hand, a signal a _i (t) (i ≠ k) carried by an optical carrier having an optical frequency different from that of local light is converted into an intermediate frequency band electric signal carried by a carrier that is an integral multiple of Δf.

From Equation 4, when the initial phase difference θ _k −θ _LO between the optical carrier that carries the desired signal a _k (t) and the local light becomes 90 °, the output of the desired signal becomes zero. Therefore, the phase synchronization between the optical carrier that carries at least the desired signal a _k (t) and the local light or the initial phase difference θ _k − among the optical carriers of the signal lights constituting the optical OFDM signal S (t). Phase diversity is required to obtain a constant output regardless of θ _LO .

An optical OFDM receiving circuit using phase diversity is realized, for example, by a configuration as shown in FIG. The optical OFDM signal S (t) from the bit phase adjusting means 31 and the local light from the local light source 41 are input to the 90 ° optical hybrid 43 and mixed. At this time, the polarization state of the local light is adjusted by the polarization adjusting means 42 so as to match at least a desired signal light among the signal lights constituting the optical OFDM signal S (t). In FIG. 4, the light source arranged in the coherent detection unit 32 is the local light source 41, but the light supplied from the outside to the optical OFDM receiving circuit is not emitted from the local light source in the coherent detection unit 32. It is good. The 90 ° optical hybrid 43 includes two output ports. If the initial phase difference between the optical carrier carrying the desired signal a _k (t) at one output port and the local light is φ, the initial phase difference at the other output port is φ + 90 °. Here, the output light intensities at the two output ports are equal. The output after detection by the photo detector 44, and the baseband signal obtained by the integration by electrical integration means 33 _a k (t) · cosφ and _a k (t) · cos a (φ + 90 °) by squaring each By adding together, it is possible to obtain a constant output regardless of the initial phase difference θ _k −θ _LO .

  The electrical integrating means is an electrical branching means for branching M electrical signals from the coherent detection means into M (M is an integer of 2 or more unrelated to the number of signal lights constituting the optical OFDM signal); An electrical delay means for adding a delay different by 1 / (M · Δf) [s] to each output of the electrical branching means, and components from the electrical delay means are combined and output. An electrical multiplexing unit; and a low-pass filtering unit that transmits and outputs a component having a frequency of Δf [Hz] or less among outputs from the electrical multiplexing unit.

As shown in FIG. 3, the output P _l (t) of the coherent detection unit 32 includes an electrical branching unit 35, (M−1) electrical delay units 36, an electrical multiplexing unit 37, and a low-pass filtering unit. The signal is input to the electrical integration means 33 constituted by 38, and only the baseband signal a _k (t) is taken out. Hereinafter, the integration operation will be described.

P _l (t) is branched into M pieces by the electric branching means 35, and different delays of 1 / (M · ΔfS) [s] are respectively added by the electric delay means 36. Here, M is an integer greater than or equal to 2 regardless of the multiplexing number N of the multiplexed signal light, and the electrical branching means 35 corresponds to a configuration in which 1 × M dividers or 1 × 2 dividers are connected in cascade. As the electrical delay means 36, a phase shifter or the like can be used as a variable delay line. The M signals delayed in each branch are multiplexed by electrical multiplexing means 37 configured by cascading M × 1 couplers and 2 × 1 couplers.

The transmission frequency characteristics from the electrical branching means 35 to the electrical multiplexing means 37 up to the preceding stage of the low-pass filtering means 38 in the electrical integration means 33 are Δf = 10 [GHz] and M = 5. As shown in FIG. 5, the frequency corresponding to an integral multiple of Δf has a transmittance of 0 except for 50 GHz, 100 GHz,. Therefore, by removing a high frequency component that is an integral multiple of M · Δf from the output of the electrical multiplexing means 37 by the low-pass filtering means 38 that transmits a component equal to or less than Δf, the output P _l (t ), An intermediate frequency band electric signal carried by a carrier wave having an integer multiple of Δf can be removed, and only a desired baseband signal a _k (t) can be extracted.

The state of the baseband signal a _k (t) output from the electrical integration means 33 is shown in FIG. B / Δf = 1 and M = 5. In FIG. 6, a portion corresponding to 4 / (5 · Δf) to 1 / Δf [s] on the basis of the signal with the smallest delay among the five electric signals to be combined is the sum of the same symbols. . This part is taken out using the identification means 34.

  The discriminating unit 34 uses (M−1) / (M · Δf) to 1 / Δf [s] based on the component with the smallest delay among the M components included in the output from the low-pass filtering unit. ] In the portion corresponding to].

For example, when the symbol rate of the desired signal a _k (t) is B ′ [Symbol / s], the identification unit 34 outputs the sum of the same symbols from the electrical integration unit 33. This can be realized by supplying a B ′ [Hz] clock whose timing is adjusted so as to determine the threshold value of the portion to the discriminator.

  In the first embodiment, the branching number M of the electrical branching means in the electrical integrator is not related to the multiplexing number N of the optical OFDM signal, so that the branching number in the receiving circuit changes even if the multiplexing number N increases. do not do. Therefore, when the signal light intensity input to the receiving circuit is constant, the BER does not deteriorate even if the multiplexing number N increases. Furthermore, since coherent detection with higher reception sensitivity compared to direct detection is used, high-sensitivity reception can be achieved.

(Second Embodiment)
The second embodiment is an optical OFDM receiver circuit that performs heterodyne synchronous detection in the coherent detection means 32 in the optical OFDM receiver circuit of the first embodiment. A configuration example of the coherent detection means 32 is shown in FIG. The optical frequency of the local light from the local light source 71 is set to an optical frequency separated from the optical frequency f _k [Hz] of the optical carrier carrying the desired signal a _k (t) by f _IF [Hz]. The polarization state of the local light is adjusted by the polarization adjusting means 72 so as to coincide with at least a desired signal light among the signal lights constituting the optical OFDM signal S (t). In FIG. 7, the output of the local light source 71 disposed in the coherent detection means 32 is local light, but the light supplied from the outside to the optical OFDM receiver circuit without using the light source in the coherent detection means. Local light emission may be used.

If the optical frequency f _LO of local light is expressed by _Equation 5, the local light can be expressed by Equation 6. Here, P _LO is the local light intensity, and θ _LO is the initial phase.

At this time, the detection output B ₂ (t) of the light receiver 73 can be expressed as shown in Equation 7.

Synchronize B ₂ (t) with a high-frequency electrical signal of frequency f _IF [Hz] synchronized with the initial phase θ _k −θ _LO of the electrical carrier wave having the frequency f _IF [Hz] carrying the desired signal a _k (t). Detect. That is, when the high-frequency electric signal C ₂ (t) is expressed by Equation 8, the output P ₂ (t) of the coherent detection unit can be expressed by Equation 9, and similarly to the coherent detection unit 32 in the optical OFDM receiving circuit according to the first embodiment, The desired signal a _k (t) is converted into a baseband signal, and the other signals a _i (t) (i ≠ k) are converted into an intermediate frequency band electric signal carried on a carrier wave that is an integral multiple of Δf. .

（ｋ＝１，２，・・・，Ｎ）

(K = 1, 2,..., N)

Thereafter, similarly to the first embodiment, only the desired signal a _k (t) can be extracted by performing the integration operation and the identification operation.

  In the second embodiment, the branching number M of the electrical branching means in the electrical integrator is not related to the multiplexing number N of the optical OFDM signal, so that the branching number in the receiving circuit changes even if the multiplexing number N increases. do not do. Therefore, when the signal light intensity input to the receiving circuit is constant, the BER does not deteriorate even if the multiplexing number N increases. Furthermore, since coherent detection with higher reception sensitivity compared to direct detection is used, high-sensitivity reception can be achieved.

(Third embodiment)
The third embodiment includes an optical OFDM transmitter that transmits an optical OFDM signal obtained by multiplexing the signal light having an optical signal band of B [Hz] at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1, and an optical An optical OFDM transmission system comprising: an optical OFDM receiver according to the second invention of the present application connected to the optical OFDM transmitter via a fiber transmission line.

  Here, an optical OFDM receiving apparatus according to the second invention of the present application comprises an optical branching means for branching and outputting an optical OFDM signal into a plurality, and a plurality of optical OFDM receiving circuits according to the first invention of the present application. The optical branching means is an optical OFDM receiver characterized in that an optical OFDM signal from the outside is branched and coupled to each of the optical OFDM receiver circuits.

As shown in FIG. 8, the optical OFDM transmission system in the third embodiment is an optical OFDM signal S obtained by multiplexing optical signals in the optical signal band B [Hz] at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1. The optical OFDM transmitter 81 that transmits (t) is connected to the optical OFDM receiver 82 by an optical fiber transmission line 83. The optical OFDM receiver 83 includes at least an optical branching unit 84 and a plurality of optical OFDM receiver circuits 85 _-k (k is a natural number of 1 to N) described in the first embodiment. In FIG. 8, B / Δf = 1. In the following description, when “optical OFDM receiving circuit 85” is described, all optical OFDM receiving circuits 85- _k are included.

  The optical OFDM signal S (t) input to the optical OFDM receiver 82 is branched into at least the number of optical OFDM receiver circuits 85 by the optical branching means 84 and input to each optical OFDM receiver circuit 85. The optical OFDM receiver circuit 85 sets the optical frequency of the local light in the coherent detection means 32 so as to be approximately equal to the optical carrier wave that carries the desired signal, so that a desired optical signal from the optical OFDM signal S (t) can be obtained. It is possible to selectively receive signal light.

Each optical OFDM receiving circuit 85 includes a bit phase adjusting unit 31 that adjusts the bit phase of each signal light constituting the input optical OFDM signal so as to match at the input end of the coherent detection unit. When the bit phase shift from 84 to each optical OFDM receiving circuit can be ignored, the bit phase adjusting means 31 is omitted from each optical OFDM receiving circuit 85, and optical OFDM reception is performed as in the optical OFDM receiving device 92 of FIG. The bit phase adjusting means 91 can be shared between the circuits 95 _-k (k is a natural number of 1 to N). In the following description, when “optical OFDM reception circuit 95” is described, it is assumed that all optical OFDM reception circuits 95- _k are included.

In FIG. 8, the output of the light source arranged in the coherent detection unit 32 in the optical OFDM reception circuit 85 is the local light, but the optical OFDM reception in FIG. 10 is not provided without arranging the local light source in the coherent detection unit 32. As in the apparatus 102, the light supplied from the outside to each optical OFDM receiving circuit 85 may be local light. A multiwavelength light whose optical frequency interval between adjacent components is Δf [Hz] and whose optical frequency is the lowest among the optical frequency components is f ₀ [Hz] is converted into an array waveguide diffraction grating. It is possible to separate each optical frequency component by using (AWG: arrayed waveguide grating), a dielectric multilayer filter, or the like, and supply each optical OFDM receiving circuit 85 as local light. The multi-wavelength light output means has a configuration in which single mode lasers having different optical frequencies of output light by Δf [Hz] are arranged, and the output of the single mode laser is intensity modulated or phased with a high frequency signal of Δf [Hz]. This is a configuration that modulates to have multiple wavelengths, a mode-locked laser having a repetition frequency of Δf [Hz], and the like.

At this time, at least one of the signal lights constituting the optical OFDM signal is received by adjusting at least one polarization of the optical OFDM signal branched by the optical branching means 84 and the local light by the polarization adjusting means 109. The circuit 85 is adjusted so that the desired signal light and the local light polarization state coincide. Further, in order to perform homodyne detection in the coherent detection means 32, phase synchronization between the optical carrier that carries at least a desired signal a _k (t) and the local light among the optical carriers of each signal light constituting the optical OFDM signal, or , Phase diversity is required.

  In the optical OFDM transmission system described in Patent Document 1, in addition to the 1 × N optical branching means, N branching is also performed in the N × N optical multiplexing means, so that the input signal light intensity to the optical discrete Fourier transform circuit is constant. In this case, as the multiplexing number N increases, the intensity of the optical signal decreases in proportion to the square of N. On the other hand, in the third embodiment, the optical branching is performed once, the branching loss is proportional to N, and the allowable loss between the transmitting and receiving apparatuses is smaller than that of the optical OFDM transmission system described in Patent Document 1. Can be enlarged. Further, since coherent detection with higher reception sensitivity compared to direct detection is used, it is possible to further increase the allowable loss. Therefore, in the optical OFDM transmission system described in Patent Document 1, it is possible to increase the number of multiplexing N that is limited in order to obtain a certain allowable loss between the transmitting and receiving apparatuses.

(Fourth embodiment)
In the fourth embodiment, an optical OFDM transmitter that transmits an optical OFDM signal obtained by multiplexing the signal light having an optical signal band of B [Hz] at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1, and an optical An optical OFDM transmission system comprising: an optical OFDM receiver according to the second invention of the present application connected to the optical OFDM transmitter via a fiber transmission line.

  Here, the optical OFDM receiver according to the second invention of the present application has a plurality of output ports each having a unique central transmitted optical frequency equal to the optical frequency of each optical carrier of the signal light constituting the optical OFDM signal, An optical frequency demultiplexing means for transmitting and outputting signal light having an optical frequency of the optical carrier that matches the specific center transmission optical frequency among the signal light constituting the optical OFDM signal; An optical OFDM receiver comprising a plurality of optical OFDM receiver circuits according to one invention, wherein the optical frequency demultiplexing means outputs signal light constituting an optical OFDM signal from the outside from each of the output ports. The optical OFDM receiver is coupled to the optical OFDM receiver circuit.

  In the optical OFDM transmission system according to the fourth embodiment, an optical signal in the optical signal band B [Hz] is transmitted at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1 as in the optical OFDM receiver 112 of FIG. An optical OFDM transmitter 111 that transmits a multiplexed optical OFDM signal S (t) is connected to an optical OFDM receiver 112 by an optical fiber transmission line 113. The optical OFDM receiver 112 includes at least an optical frequency demultiplexing unit 114 and a plurality of optical OFDM receiver circuits 85 described in the first embodiment. In FIG. 11, B / Δf = 1.

  The center transmitted light frequency of each output port of the optical frequency demultiplexing means 114 is equal to the optical frequency of the optical carrier wave of each signal light constituting the optical OFDM signal S (t). Further, the signal light in the optical signal band B [Hz] carried by the optical carrier having the same optical frequency as the center transmitted optical frequency of the output port is transmitted without band limitation. That is, the transmission bandwidth of each output port is 2B [Hz] or more, and the transmission bandwidth is wider than that of the optical frequency demultiplexing means used in the conventional optical frequency multiplexing transmission system. FIG. 12 shows the transmission characteristics of the output ports (# 1 to #N). In FIG. 12, the transmission bandwidth of each output port is 2B [Hz].

  The optical OFDM signal S (t) input to the optical OFDM receiver 112 is output to each output port of the optical frequency demultiplexing means 114. The optical OFDM receiver circuit 85 selects the desired signal light from the optical OFDM signals by setting the optical frequency of the local light in the coherent detection means 32 to be approximately equal to the optical carrier wave that carries the desired signal. Can be received automatically.

  Each optical OFDM receiving circuit 85 includes a bit phase adjusting unit 31 that adjusts the bit phase of each signal light constituting the input multiplexed signal light so as to match at the input end of the coherent detection unit 32. When the bit phase shift from the demultiplexing means 114 to each optical OFDM receiving circuit 85 can be ignored, the bit phase adjusting means 31 is omitted from each optical OFDM receiving circuit 85, as in the optical OFDM receiving apparatus 132 in FIG. The bit phase adjusting means 91 can be shared between the optical OFDM receiving circuits 95.

Instead of providing a local light source in the coherent detection means in the optical OFDM receiver circuit, the light supplied from the outside to each optical OFDM receiver circuit 85 may be used as a local light source as in the optical OFDM receiver 142 of FIG. . Multi-wavelength light having an optical frequency interval between adjacent components of Δf [Hz] and the optical frequency of the optical frequency component having the lowest optical frequency of f ₀ [Hz] is converted into AWG or dielectric multilayer Each optical frequency component can be separated by a membrane filter or the like and supplied to each optical OFDM receiving circuit 85 as local light.

At this time, at least one of the signal lights constituting the optical OFDM signal is adjusted by adjusting the polarization of at least one of the signal light and the local light output from the optical frequency demultiplexing means 114 by the polarization adjusting means 149. Adjustment is made so that the polarization state of the desired signal light and the local light in the receiving circuit 85 match. Further, in order to perform homodyne detection in the coherent detection means 32, phase synchronization between the optical carrier that carries at least a desired signal a _k (t) and the local light among the optical carriers of each signal light constituting the optical OFDM signal, or , Phase diversity is required.

  Further, the multi-wavelength light is not separated for each optical frequency component, and the light from the other wavelength light output means 157 is at least of the optical OFDM receiving circuit 85 by the optical branching means 154 as in the optical OFDM receiver 152 of FIG. It is also possible to branch into a number and supply each optical OFDM receiving circuit 85 as local light.

Further, as in the optical OFDM receiver 162 of FIG. 16, the optical OFDM signal S (t) and the multi-wavelength light are mixed, then demultiplexed by the optical frequency demultiplexing means 114 and input to each optical OFDM receiving circuit 85. It is also possible to do. When performing phase diversity in the configuration of FIG. 16, although the respective optical OFDM receiver circuit 85 is 90 ° optical hybrid is required, the configuration described of the optical OFDM receiver 172 of FIG. 17, the optical OFDM receiver circuit _{175 -k} ( k is a natural number from 1 to N.) 90 ° optical hybrid 178 can be shared between them. In the following description, when “optical OFDM receiving circuit 175” is described, it is assumed that all optical OFDM receiving circuits 175- _k are included.

  In the optical OFDM transmission system described in Patent Document 1, as the number of multiplexed optical OFDM signals N increases, the branching loss in the optical branching unit increases and is allowed to obtain a constant reception sensitivity. There is a problem that the loss between the receiver and the receiving apparatus is reduced. On the other hand, in the fourth embodiment, since the optical branching means is not used, the multiplexing number N is not limited in order to obtain a certain allowable loss between the transmitting apparatus and the receiving apparatus. Furthermore, since coherent detection having higher reception sensitivity than direct detection is used, the allowable loss can be increased. Therefore, in the optical OFDM transmission system described in Patent Document 1, it is possible to increase the number of multiplexing N that is limited in order to obtain a certain allowable loss between the transmitting and receiving apparatuses.

(Fifth embodiment)
In the fifth embodiment, the optical OFDM receiver 82 in the optical OFDM transmission system of FIG. 8 in the third embodiment includes at least an optical branching unit 84 and a plurality of optical OFDM receiver circuits 85 described in the second embodiment. This is an optical OFDM transmission system configured by:

The optical OFDM signal input to the optical OFDM receiver 82 is branched into at least the number of optical OFDM receiver circuits 85 by the optical branching means 84 and input to each optical OFDM receiver circuit 85. The optical OFDM receiver circuit 85 sets the optical frequency of the local light in the coherent detection means 32 so that the optical frequency difference from the optical carrier carrying the received signal becomes a predetermined intermediate frequency f _IF [Hz]. The desired signal light can be selectively received from the optical OFDM signals.

  Each optical OFDM receiving circuit 85 includes a bit phase adjusting unit 31 that adjusts the bit phase of each signal light constituting the input optical OFDM signal so as to match at the input end of the coherent detection unit 32. If the bit phase shift from the means 84 to each optical OFDM receiving circuit 85 can be ignored, the bit phase adjusting means 31 is omitted from each optical OFDM receiving circuit 85 and the bit phase adjusting means is shared between the optical OFDM receiving circuits. You can also

  Further, in the optical OFDM transmission system of FIG. 8, the optical OFDM receiver 102 of FIG. 18 may be used instead of the optical OFDM receiver 82. The optical OFDM receiver 102 uses local light as the light supplied from the outside to each optical OFDM receiver circuit 85 without arranging a local light source in the coherent detection means 32 in the optical OFDM receiver circuit 85. At this time, at least one of the signal lights constituting the optical OFDM signal is received by adjusting at least one polarization of the optical OFDM signal branched by the optical branching means 84 and the local light by the polarization adjusting means 109. The circuit 85 is adjusted so that the desired signal light and the local light polarization state coincide.

The multi-wavelength light whose optical frequency interval between adjacent components is Δf [Hz] and whose optical frequency is the lowest among the optical frequency components is f ₀ + f _IF [Hz] is converted into AWG or dielectric It is possible to separate each optical frequency component by a body multilayer filter or the like and supply it to each optical OFDM receiving circuit 85 as local light.

  In the optical OFDM transmission system described in Patent Document 1, in addition to the 1 × N optical branching means, N branching is also performed in the N × N optical multiplexing means, so that the input signal light intensity to the optical discrete Fourier transform circuit is constant. In this case, as the multiplexing number N increases, the intensity of the signal light decreases in proportion to the square of N. On the other hand, in the fifth embodiment, the optical branching is one time, the branching loss is proportional to N, and compared with the optical OFDM transmission system described in Patent Document 1, the allowable loss between the transmitting and receiving apparatuses is reduced. Can be enlarged. Further, since coherent detection with higher reception sensitivity compared to direct detection is used, it is possible to further increase the allowable loss. Therefore, in the optical OFDM transmission system described in Patent Document 1, it is possible to increase the number of multiplexing N that is limited in order to obtain a certain allowable loss between the transmitting and receiving apparatuses.

(Sixth embodiment)
In the sixth embodiment, the optical OFDM receiver 112 of the optical OFDM transmission system of FIG. 11 in the fourth embodiment includes at least an optical frequency demultiplexing unit 114 and a plurality of optical OFDM receiver circuits described in the second embodiment. 85 is an optical OFDM transmission system.

The optical OFDM signal input to the optical OFDM receiver 112 is output to each output port (# 1 to #N) of the optical frequency demultiplexing means 114. The center transmitted optical frequency of each output port of the optical frequency demultiplexing means 114 is equal to the optical frequency of the optical carrier wave of each signal light constituting the optical OFDM signal. Further, the signal light in the optical signal band B [Hz] carried by the optical carrier having the same optical frequency as the center transmitted optical frequency of the output port is transmitted without band limitation. That is, the transmission bandwidth of each output port is 2B [Hz] or more. The optical OFDM receiver circuit sets the optical frequency of the local light in the coherent detection means so that the optical frequency difference from the optical carrier carrying the desired signal becomes a predetermined intermediate frequency f _IF [Hz]. It is possible to selectively receive desired signal light from among OFDM signals.

  Each optical OFDM receiving circuit 85 includes a bit phase adjusting unit 31 that adjusts the bit phase of each signal light constituting the input optical OFDM signal so as to match at the input end of the coherent detection unit 32, but the optical frequency When the bit phase shift from the demultiplexing means 114 to each optical OFDM receiving circuit 85 can be ignored, the bit phase adjusting means 31 is omitted from each optical OFDM receiving circuit 85, and the bit phase adjusting means is provided between the optical OFDM receiving circuits 85. Can also be shared.

  In the optical OFDM transmission system of FIG. 11, the optical OFDM receiver 142 of FIG. 19 may be used instead of the optical OFDM receiver 112. The optical OFDM receiver 142 uses local light as the light supplied from the outside to each optical OFDM receiver circuit 85 without arranging a local light source in the coherent detection means 32 in the optical OFDM receiver circuit 85. At this time, at least one of the signal lights constituting the optical OFDM signal is adjusted by adjusting the polarization of at least one of the signal light and the local light output from the optical frequency demultiplexing means 114 by the polarization adjusting means 149. Adjustment is made so that the polarization state of the desired signal light and the local light in the receiving circuit 85 match.

The multi-wavelength light whose optical frequency interval between adjacent components is Δf [Hz] and whose optical frequency is the lowest among the optical frequency components is f ₀ + f _IF [Hz] is converted into AWG or dielectric It is possible to separate each optical frequency component by a body multilayer filter or the like and supply it as local light to each optical OFDM receiving circuit.

  Further, the multi-wavelength light is not separated for each optical frequency component, and is branched into at least the number of the optical OFDM receiving circuits 85 by the optical branching means 154 as in the optical OFDM receiving device 152 of FIG. 85 can be supplied as local light.

  In the optical OFDM transmission system described in Patent Document 1, as the number of multiplexed optical OFDM signals N increases, the branching loss in the optical branching unit increases and is allowed to obtain a constant reception sensitivity. There is a problem that the loss between the receiver and the receiving apparatus is reduced. On the other hand, in the sixth embodiment, since the optical branching unit is not used, the multiplexing number N is not limited in order to obtain a certain allowable loss between the transmission device and the reception device. Furthermore, since homodyne detection, which has higher reception sensitivity than direct detection, is used, it is possible to increase the allowable loss. Therefore, in the optical OFDM transmission system described in Patent Document 1, it is possible to increase the number of multiplexing N that is limited in order to obtain a certain allowable loss between the transmitting and receiving apparatuses.

(Seventh embodiment)
The seventh embodiment is an optical OFCDM receiving circuit to which a unique code consisting of a code element (1) and a code element (0) is assigned, and the interval between adjacent optical frequency components is Δf [Hz]. Among the components of the multi-wavelength light to which the code element (1) or code element (0) of the code is assigned, the optical signal band B [in which the component to which the code element (1) is assigned satisfies B / Δf ≦ 1 Hz] optical signal carrier wave, and the signals carried by all components corresponding to the code element (1) are the same, and the optical OFCDM signal is separated for each signal carried by each component corresponding to the code element (1). And an optical OFCDM signal separation device that converts the output into an electrical signal and outputs, and an electrical addition / subtraction unit that adds and subtracts each output from the optical OFCDM signal separation device according to the unique code. Light O This is an FCDM receiving circuit.

  The optical orthogonal code division multiplexing (OFCDM) receiving circuit according to the seventh embodiment is a receiving circuit in an optical code division multiplexing (CDM) transmission system to which optical OFDM is applied.

  FIG. 21 shows a configuration example of an optical CDM transmission system. Each transmission circuit transmits an optical CDM signal encoded by an encoder corresponding to the assigned code. On the receiving side, the input optical CDM signal is decoded and received by a decoder corresponding to the code assigned to each receiving circuit. At this time, the code assigned to the transmission circuit and the reception circuit is a code that allows the reception circuit to receive only the optical CDM signal output from the transmission circuit assigned the same code as the assigned code. . Therefore, it is possible to selectively receive only a desired signal from the multiplexed optical CDM signal.

The pseudo bipolar encoding method in the optical frequency domain is one of the encoding methods in the optical CDM method. A conceptual diagram is shown in FIG. In the encoding, the code element (1) and code element (0) constituting the code assigned to the transmission circuit are assigned to each optical frequency component of the broadband light source, and only the component corresponding to the code element (1) is output. By doing. FIG. 22 shows a case where each code element of a code having a code length of 4 is assigned to each optical frequency component f _{1 to} f ₄ of the broadband light source. The desired user signal is encoded with a code (0, 0, 1, 1), and is composed of optical frequency components f ₃ and f ₄ . On the other hand, the other user signal is encoded with a code (0, 1, 0, 1) and is composed of optical frequency components f ₂ and f ₄ . On the receiving side, when the code element (1) and code element (0) constituting the code assigned to the receiving circuit are assigned to the respective optical frequency components of the broadband light source on the transmitting circuit side, the input optical CDM signal is constituted. By adding and subtracting the component whose optical frequency is equal to the optical frequency component of the broadband light source corresponding to the sign element (1) as positive and the component equal to the optical frequency component corresponding to the sign element (0) as negative among the optical frequency components Realize positive and negative sign elements. By assigning each user a code that cancels the other user signal by addition / subtraction, the other user signal can be removed.

  The optical OFCDM signal separation device of the optical OFCDM reception circuit in the seventh embodiment can be the optical OFDM reception device according to the second invention of the present application.

  FIG. 23 shows an optical OFCDM receiving circuit according to the seventh embodiment. The optical OFCDM receiving circuit includes the optical OFDM apparatus (the optical OFDM receiving apparatus 112 in FIG. 23) and the electrical add / subtract means 235 in the optical OFDM transmission system according to any one of the third to sixth embodiments. .

  The optical OFCDM signal S ′ (t) input to the optical OFCDM receiving circuit includes a code element (1) and a code element (0) for each component of multi-wavelength light whose interval between adjacent optical frequency components is Δf [Hz]. Is a signal that is an optical carrier wave of signal light in the optical signal band B [Hz] that satisfies B / Δf ≦ 1 as a component that corresponds to the code element (1). Each component that hits the code element (1) carries the same signal a (t).

The optical OFCDM signal S ′ (t) can be expressed as in Expression 10.

Here, f ₀ is the code element (1) constituting the code l, the optical frequency of the lowest optical frequency among the optical frequency components of the multi-wavelength light assigned the code element (0), and N is the code length It is. P _i is the intensity of the signal light carried by the i-th component from the lower optical frequency, θ _i is the initial phase of the i-th component, and c _{l, i} are the i-th code elements of the code l. . The i-th code element c _{l, i} is assigned to a component whose optical frequency is f ₀ + (i−1) · Δf.

The optical OFCDM signal S ′ (t) is output separately for each signal carried by each optical frequency component in the optical OFDM receiver in the optical OFCDM receiving circuit. At this time, if the optical OFDM receiver circuit i in the optical OFDM receiver outputs the signal a (t) carried by the i-th optical frequency component, the output of the optical OFDM receiver circuit i is c _{l, i} · a It can be expressed as (t).

The code element (1) and code element (0) constituting the code assigned to the optical OFCDM receiving circuit are assigned to each optical OFDM receiving circuit, and the output of the optical OFDM receiving circuit corresponding to the element of the code element (1) is obtained. If the addition / subtraction is performed by adding the output of the optical OFDM receiving circuit corresponding to the positive and sign element (0) as a negative value, the output of the adder / subtracter can be expressed as Equation 11.

d _{m, i} is the i-th code element of the code m assigned to the optical OFCDM receiving circuit, and is assigned to the optical OFDM receiving circuit i. 2 _{m, i} −1 is 1 when the code element (1) is assigned to the optical OFDM receiver circuit i, and −1 when the code element (0).

数１２とすると、光ＯＦＣＤＭ受信回路に割り当てられた符号と異なる符合を割り当てられた光ＯＦＣＤＭ信号を除去することができる。

If Expression 12 is used, an optical OFCDM signal assigned with a code different from the code assigned to the optical OFCDM receiving circuit can be removed.

  In FIG. 23, although the output of the light source arranged in the coherent detection means 32 in the optical OFDM receiving circuit 85 is the local light, the light supplied from outside is not provided in the coherent detection means 32 but the light supplied from the outside is It is good also as light emission.

  Each optical OFDM receiving circuit 85 includes a bit phase adjusting unit 31 that adjusts the bit phase of each signal light constituting the input optical OFCDM signal so as to match at the input end of the coherent detection unit 32. Optical branching means (when using the optical OFDM receiver 82 of the optical OFDM transmission system of FIG. 8 in the third or fifth embodiment) or optical frequency demultiplexing means (fourth embodiment or sixth embodiment) When the optical OFDM receiver 112 in the optical OFDM transmission system of FIG. 11 in the embodiment) to each optical OFDM receiver circuit 85 can be ignored, the bit phase from each optical OFDM receiver circuit 85 is ignored. The adjustment means 31 is omitted, and the bit phase between the optical OFDM receiver circuits 95 is changed as in the optical OFDM receiver shown in FIG. It is also possible to share the integer unit 91.

  Furthermore, in the coherent detection means 32, when performing homodyne detection using phase diversity, each optical OFDM receiver circuit requires a 90 ° optical hybrid as shown in FIG. 4, but each optical OFDM receiver circuit as shown in FIG. It is possible to share the 90 ° optical hybrid 178 among the 175.

  As described above, the configuration of the optical OFCDM receiving circuit can be simplified as shown in FIG. Further, as shown in FIG. 25, the electric adder / subtracter 235a is arranged in front of the electric integrator 255a and the electric adder / subtracter 235b is arranged in front of the electric integrator 255b, and the electric integration is performed between the optical OFDM receiving circuits. By using the means 255a, the electrical integration means 255b, the square detection means 253a, the square detection means 253b, and the identification means 254 in common, the configuration can be further simplified.

(Eighth embodiment)
The optical OFCDM signal separation device of the optical OFCDM receiving circuit according to the eighth embodiment includes a plurality of output ports each having a unique center transmission optical frequency equal to the optical frequency of each optical carrier of the signal light constituting the optical OFCDM signal. Optical frequency demultiplexing means for transmitting and outputting the signal light whose optical carrier frequency matches the specific center transmission optical frequency among the signal lights constituting the optical OFCDM signal. A bit phase adjusting means for adjusting the bit phase of the signal light output from each output port of the optical frequency demultiplexing means, and a direct detection for directly detecting the optical OFCDM signal from the bit phase adjusting means Means, an electric integration means for integrating the output of the direct detection means over 1 / Δf [s], and the output of the electric integration means is determined as a threshold value. And an optical OFCDM signal input from the outside is demultiplexed by the optical frequency demultiplexing unit, and adjusted by the bit phase adjusting unit so that the bit phases of the signal light constituting the optical OFCDM signal coincide with each other It is characterized by doing.

  FIG. 26 shows a configuration diagram of an optical OFCDM receiving circuit according to the eighth embodiment. The optical OFCDM receiving circuit includes an optical OFCDM signal separation device 264 and an electrical addition / subtraction means 235. The optical OFCDM signal separation device 264 receives the optical OFCDM signal, separates and outputs each signal carried by each optical carrier wave. The electrical addition / subtraction means 235 adds / subtracts each signal output from the optical OFCDM signal separator 264 according to the code assigned to the optical OFCDM reception circuit.

  The optical OFCDM signal input to the optical OFCDM signal separator 264 is input to the optical frequency demultiplexing means 114 having transmission characteristics as shown in FIG. From the output ports (# 1 to #N) of the optical frequency demultiplexing means 114, of the signal light constituting the optical OFCDM signal, a desired signal carried by an optical carrier whose optical frequency is equal to the center transmission optical frequency of the output port The crosstalk component of the signal light carried by the light and the adjacent optical carrier is output.

  The output signal light is adjusted by the bit phase adjusting means 31 so that the bit phases of the respective signal lights are matched, and directly detected by the direct detecting means 262. The direct detection means 262 outputs a baseband signal obtained by directly detecting desired signal light and adjacent signal light, and a beat component between the signal lights.

  The output of the direct detection means 262 is input to the electrical integration means 33 and the identification means 34. Here, since the beat component between the signal lights is conveyed to a carrier wave that is an integral multiple of Δf [Hz] that is the optical frequency interval of the optical carrier wave, the light of FIG. 3 in the first embodiment or the second embodiment is used. It can be removed by performing an integration operation and an identification operation similar to those of the OFDM receiving circuit. Further, since each carrier wave of the optical OFCDM signal carries the same signal, a component obtained by directly detecting adjacent signal light can also be regarded as a desired signal.

  In the optical OFCDM receiving circuit of FIG. 26, the bit phase adjusting means 31 for adjusting the bit phases of the respective signal lights to the output terminals (# 1 to #N) of the respective output ports of the optical frequency demultiplexing means 114 is provided. If the bit phase shift from the optical frequency demultiplexing means 114 to each direct detection means 262 can be ignored, the bit phase adjusting means 31 is arranged in front of the optical frequency demultiplexing means 114 and shared. You can also. Further, as shown in FIG. 27, the electrical addition / subtraction means 235 is arranged in front of the electrical integration means, and the configuration is simplified by sharing the electrical integration means and the identification means between the optical OFDM reception circuits. Is possible.

(Ninth embodiment)
In the ninth embodiment, one or more optical OFCDM transmission circuits that transmit the optical OFCDM signal corresponding to an assigned unique code, and the optical multiplexing that combines the optical OFCDM signal transmitted by the optical OFCDM transmission circuit. An optical OFCDM transmission system comprising: an optical OFCDM transmission device having a wave means; and an optical OFCDM reception device according to the fifth invention of the present application connected to the optical OFCDM transmission device via an optical fiber transmission line, The optical OFCDM receiving circuit included in the OFCDM receiving apparatus receives only the optical OFCDM signal transmitted by the optical OFCDM transmitting circuit assigned the same code as that assigned to the optical OFCDM receiving circuit. This is an optical OFCDM transmission system.

  Here, an optical OFCDM receiving apparatus according to the fifth invention of the present application includes an optical branching means for branching an optical OFCDM signal into a plurality of outputs and a plurality of optical OFCDM receiving circuits according to the fourth invention of the present application. The optical branching means is an optical OFCDM receiving apparatus that splits an optical OFCDM signal from outside and couples the optical OFCDM signal to each optical OFCDM receiving circuit.

  An optical OFCDM transmission system according to the ninth embodiment is shown in FIG. The optical OFCDM transmission apparatus 281 and the optical OFCDM reception apparatus 282 are connected by an optical fiber transmission line 283.

  The optical OFCDM transmission apparatus 281 includes at least a plurality of optical OFCDM transmission circuits 284 and an optical multiplexing unit 285 that combines optical OFCDM signals output from the optical OFCDM transmission circuits 284.

  The optical OFCDM transmission circuit 284 has means for outputting multi-wavelength light in which the interval between adjacent optical frequency components is Δf [Hz] and the number of components is greater than or equal to the code length. The multi-wavelength light output means has a configuration in which single mode lasers having different optical frequencies of output light by Δf [Hz] are arranged, and the output of the single mode laser is intensity modulated or phased with a high frequency signal of Δf [Hz]. This is a configuration that modulates to have multiple wavelengths, a mode-locked laser having a repetition frequency of Δf [Hz], and the like.

  In the optical OFCDM transmission circuit 284, for example, the code element (1) and the code element (0) constituting the code assigned to the optical OFCDM transmission circuit 284 are configured as shown in FIGS. 29 (i) and (ii). An optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1 for signal light in the optical signal band B [Hz] assigned to each optical frequency component of the multi-wavelength light and having a component corresponding to the code element (1) as an optical carrier wave The optical OFCDM signal multiplexed in (1) is transmitted. Here, each component corresponding to the code element (1) carries the same signal a (t).

  In the optical OFCDM transmission circuit 284 of FIG. 29 (i), the multi-wavelength light is demultiplexed for each optical frequency component by the optical frequency demultiplexing means 292 such as AWG or dielectric multilayer filter, and input to the optical switch 293, respectively. Each code element is assigned to each optical switch 293, only the optical switch 293 corresponding to the element of the code element (1) is turned ON, and only the optical frequency component corresponding to the element of the code element (1) is modulated. To modulate with the same data signal a (t). The order of the optical switch 293 and the modulation means 294 can be switched. The outputs of the modulation means 294 are combined to output an optical OFCDM signal. When multiplexing, optical multiplexing means such as a configuration in which N × 1 couplers or 2 × 1 couplers are connected in cascade can be used. Further, the optical frequency component having the transmission characteristics as shown in FIG. 12 in which the center transmission optical frequency of each output port is equal to the optical frequency of each optical frequency component of the multi-wavelength light and the transmission bandwidth is 2 B [Hz] or more. Even if the wave means is reversed and used as the optical frequency multiplexing means, the wave can be multiplexed. In FIG. 29 (i), the optical frequency multiplexing means 295 is connected.

  In the optical OFCDM transmission circuit 284 of FIG. 29 (ii), each optical frequency component of the multi-wavelength light demultiplexed for each optical frequency component by the optical frequency demultiplexing means 292 is input to the optical switch 293, respectively. Each code element is assigned to each optical switch 293, only the optical switch 293 corresponding to the element of the code element (1) is turned ON, and only the optical frequency component corresponding to the element of the code element (1) is multiplexed and modulated. The means 296 outputs an optical OFCDM signal that is collectively modulated with the data signal a (t).

  The optical OFCDM signals output from the optical OFCDM transmission circuits 284 are combined by the optical combining means 285 and transmitted to the optical OFCDM receiver 282 through an optical fiber.

  The optical OFCDM receiving apparatus 282 includes at least an optical branching unit 286 and a plurality of optical OFCDM receiving circuits 287. The optical OFCDM receiving circuit 287 is exemplified as the optical OFCDM receiving circuit according to the seventh embodiment described with reference to FIG. 23 or the optical OFCDM receiving circuit according to the eighth embodiment described with reference to FIG. The optical OFCDM signal transmitted to the optical OFCDM receiving device 282 is branched into at least the number of optical OFCDM receiving circuits 287 by the optical branching unit 286 and input to each optical OFCDM receiving circuit 287.

  In the optical OFCDM reception circuit 287, a code that cancels other than the optical OFCDM signal output from the optical OFCDM transmission circuit 284 assigned the same code as the assigned code is assigned to each transmission / reception circuit. It becomes possible to selectively receive a desired optical OFCDM signal from the signals.

  The optical OFDM transmission system and the optical OFCDM transmission system according to the present invention can be used not only for optical signals but also for transmitting radio signals.

It is the block diagram which showed the structure of the conventional optical frequency division multiplexing transmission system. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the conventional optical discrete Fourier-transform circuit. 1 is a block diagram illustrating a configuration of an optical OFDM receiver circuit according to the present invention, which is described in the first embodiment. FIG. The frequency spectrum of the signal between each block is also shown. 1 is a block diagram illustrating a configuration of an optical OFDM receiver circuit using phase diversity according to the present invention, which is described in the first embodiment. FIG. It is a transmission frequency characteristic between the electrical branching means and the electrical multiplexing means of the optical OFDM receiver circuit according to the present invention. 3 shows the output of the electrical integration means of the optical OFDM receiver circuit according to the present invention. The horizontal axis indicates time. FIG. 5 is a block diagram showing a configuration of coherent detection means of an optical OFDM receiver circuit according to the present invention, which will be described in a second embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM transmission system which concerns on this invention demonstrated in 3rd Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 3rd Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 3rd Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM transmission system which concerns on this invention demonstrated in 4th Embodiment. The frequency spectrum of the signal between each block is also shown. 2 shows the light transmission characteristics of the optical frequency demultiplexing means of the optical OFDM receiver according to the present invention. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 4th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 4th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 4th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 4th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 4th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 5th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 6th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFDM receiver based on this invention demonstrated in 6th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the conventional optical CDM transmission system. It is a conceptual diagram of the pseudo bipolar encoding system in the conventional optical frequency domain. FIG. 10 is a block diagram illustrating a configuration of an optical OFCDM receiving circuit according to the present invention, which is described in a seventh embodiment. The frequency spectrum of the signal between each block is also shown. FIG. 10 is a block diagram illustrating a configuration of an optical OFCDM receiving circuit according to the present invention, which is described in a seventh embodiment. The frequency spectrum of the signal between each block is also shown. FIG. 10 is a block diagram illustrating a configuration of an optical OFCDM receiving circuit according to the present invention, which is described in a seventh embodiment. The frequency spectrum of the signal between each block is also shown. The optical OFDM receiving circuit of the present optical OFCDM receiving circuit is a circuit (k is 1 to N) (photodetector 44a- _k -electric addition / subtraction means 235a-electric integration means 255a-2 power detection means 253a-identification means 254). ), (Light receiver 44b _-1 -electrical addition / subtraction means 235b-electric integration means 255b-2 power detection means 253b-identification means 254) (k is 1 to N), 2N circuits. It is the block diagram which showed the structure of the optical OFCDM receiving circuit based on this invention demonstrated in 8th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFCDM receiving circuit based on this invention demonstrated in 8th Embodiment. The frequency spectrum of the signal between each block is also shown. It is the block diagram which showed the structure of the optical OFCDM transmission system which concerns on this invention demonstrated in 9th Embodiment. (I) and (ii) are block diagrams showing the configuration of the optical OFCDM transmission circuit of the optical OFCDM transmission system according to the present invention, which will be described in the ninth embodiment.

Explanation of symbols

In FIG. 1 to FIG. 29, the same reference numerals are used when the same reference numerals are used across the drawings.
10 transmitter 11 _-k transmitter circuit (k is a natural number of 1 to N)
12 optical frequency multiplexing means 13 optical fiber transmission line 14 optical frequency demultiplexing means 15 _-k receiving circuit (k is a natural number of 1 to N)
16 receiver 21 optical branching means 22 delay means 23 optical branching means 24 phase shifter 25 optical multiplexing means 27 optical multiplexing means 28 time gate 31 bit phase adjustment means 32 coherent detection means 33 electrical integration means 34 identification means 35 electrical branching means 36 Electrical delay means 37 Electrical multiplexing means 38 Low-pass filtering means 41 Local light source 42 Polarization adjusting means 43 90 ° optical hybrid 71 Local light source 72 Polarization adjusting means 73 Light receiver 81 Optical OFDM transmitter 82 Optical OFDM Receiver 83 Optical fiber transmission line 84 Optical branching means 85 _-k optical OFDM receiver circuit (k is a natural number from 1 to N)
91 bit phase adjusting means 92 optical OFDM receiver 94 optical branching means 95 _-k optical OFDM receiver circuit (k is a natural number from 1 to N)
DESCRIPTION OF SYMBOLS 102 Optical OFDM receiver 109 Polarization adjustment means 111 Optical OFDM transmission apparatus 112 Optical OFDM reception apparatus 113 Optical fiber transmission line 114 Optical frequency demultiplexing means 132 Optical OFDM reception apparatus 142 Optical OFDM reception apparatus 149 Polarization adjustment means 152 Optical OFDM reception Device 154 Optical branching means 157 Multi-wavelength light output means 162 Optical OFDM receiver 167 Multi-wavelength light output means 172 Optical OFDM receiver 175 _-k optical OFDM receiver circuit (k is a natural number from 1 to N)
178 90 ° optical hybrid 235, 235a, 235b Electrical addition / subtraction means 253a, 253b Square detection means 254 Identification means 255a, 255b Electrical integration means 258 90 ° optical hybrid 262 Direct detection means 264 Optical OFCDM signal separation device 265 _-k light OFDM receiver circuit (k is a natural number from 1 to N)
273 Electrical integration means 274 Identification means 281 Optical OFCDM transmission device 282 Optical OFCDM reception device 283 Optical fiber transmission line 284 Optical OFCDM transmission circuit 285 Optical multiplexing means 286 Optical branching means 287 Optical OFCDM reception circuit 291 Multi-wavelength optical output means 292 Optical frequency Demultiplexing means 293 Optical switch 294 Modulating means 295 Optical frequency multiplexing means 296 Modulating means S (t) Optical OFDM signal S ′ (t) Optical OFCDM signal

Claims (10)

An optical OFDM receiving circuit to which an optical OFDM signal obtained by multiplexing signal light of an optical signal band B [Hz] at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1 is input,
A bit phase adjusting means for adjusting the bit phases of the respective signal lights constituting the optical OFDM signal, and
One of the signal lights constituting the optical OFDM signal from the bit phase adjusting means is converted into a baseband electric signal, and the other is converted into an intermediate frequency band electric signal carried on a carrier wave whose frequency is an integer multiple of Δf. Coherent detection means for converting and outputting;
Electrical integration means for integrating and outputting the output from the coherent detection means over 1 / Δf [s];
Identifying means for determining a threshold value of the output from the electrical integrating means;
An optical OFDM receiver circuit. The electrical integration means includes
Electrical branching means for branching M electrical signals from the coherent detection means into M (M is an integer of 2 or more unrelated to the number of signal lights constituting the optical OFDM signal);
Electrical delay means for adding a different delay by 1 / (M · Δf) [s] to each output of the electrical branch means;
Electrical combining means for combining and outputting the components from the electrical delay means;
Low-pass filtering means that transmits and outputs a component having a frequency of Δf [Hz] or less among the outputs from the electrical multiplexing means;
Have
The identification means uses (M−1) / (M · Δf) to 1 / Δf [s] based on the component with the smallest delay among the M components included in the output from the low-pass filtering means. Threshold judgment is performed in the corresponding part,
The optical OFDM receiver circuit according to claim 1. An optical branching means for branching an optical OFDM signal into a plurality of outputs;
A plurality of optical OFDM receiver circuits according to claim 1 or 2,
An optical OFDM receiver comprising:
The optical OFDM receiving apparatus characterized in that the optical branching means branches an optical OFDM signal from the outside and couples the optical OFDM signal to each optical OFDM receiving circuit. A plurality of output ports each having a unique center transmission optical frequency equal to the optical frequency of each optical carrier of the signal light constituting the optical OFDM signal, each of the output ports of the signal light constituting the optical OFDM signal; Among them, optical frequency demultiplexing means for transmitting and outputting signal light whose optical frequency of the optical carrier wave coincides with the inherent central transmitted optical frequency,
A plurality of optical OFDM receiver circuits according to claim 1 or 2,
An optical OFDM receiver comprising:
An optical OFDM receiving apparatus characterized in that the optical frequency demultiplexing means outputs signal light constituting an external optical OFDM signal from each output port and couples it to the optical OFDM receiving circuit. An optical OFDM transmitter for transmitting an optical OFDM signal obtained by multiplexing the signal light having an optical signal bandwidth of B [Hz] at an optical frequency interval Δf [Hz] satisfying B / Δf ≦ 1;
The optical OFDM receiver according to claim 3 or 4 connected to the optical OFDM transmitter via an optical fiber transmission line;
An optical OFDM transmission system comprising: An optical OFCDM receiving circuit to which a unique code consisting of a code element (1) and a code element (0) is assigned,
The interval between adjacent optical frequency components is Δf [Hz], and among the components of the multi-wavelength light to which the code element (1) or the code element (0) of the code is assigned, the code element (1) is assigned An optical OFCDM signal in which the component is an optical carrier wave of signal light in an optical signal band B [Hz] satisfying B / Δf ≦ 1 and signals carried by all the components corresponding to the code element (1) are the same An optical OFCDM signal separation device for separating and converting each signal corresponding to the code element (1) into an electric signal and outputting the electric signal;
Electrical addition / subtraction means for adding / subtracting each output from the optical OFCDM signal separation device according to the unique code;
An optical OFCDM receiving circuit comprising:   7. The optical OFCDM reception circuit according to claim 6, wherein the optical OFCDM signal separation device is the optical OFDM reception device according to claim 3 or 4. The optical OFCDM signal separator is
A plurality of output ports each having a unique center transmission optical frequency equal to the optical frequency of each optical carrier of the signal light constituting the optical OFCDM signal, and each of the output ports of the signal light constituting the optical OFCDM signal; Among them, optical frequency demultiplexing means for transmitting and outputting signal light whose optical frequency of the optical carrier wave coincides with the inherent central transmitted optical frequency,
Bit phase adjusting means for adjusting the bit phase of the signal light output from each output port of the optical frequency demultiplexing means; and
Direct detection means for directly detecting the optical OFCDM signal from the bit phase adjustment means;
Electrical integration means for integrating the output of the direct detection means over 1 / Δf [s];
Identification means for determining a threshold value of the output of the electrical integration means;
The optical OFCDM signal input from the outside is demultiplexed by the optical frequency demultiplexing means, and adjusted by the bit phase adjusting means so that the bit phases of the signal light constituting the optical OFCDM signal coincide with each other. The optical OFCDM receiving circuit according to claim 6. An optical branching means for branching an optical OFCDM signal into a plurality of outputs;
A plurality of optical OFCDM receiving circuits according to any one of claims 6 to 8,
An optical OFCDM receiving device comprising:
The optical OFCDM receiving apparatus, wherein the optical branching means branches an optical OFCDM signal from the outside and couples the optical OFCDM signal to each optical OFCDM receiving circuit. Optical OFCDM transmission having one or more optical OFCDM transmission circuits for transmitting the optical OFCDM signal corresponding to the assigned unique code, and the optical multiplexing means for combining the optical OFCDM signals transmitted by the optical OFCDM transmission circuit Equipment,
The optical OFCDM receiving apparatus according to claim 9 connected to the optical OFCDM transmitting apparatus via an optical fiber transmission line;
An optical OFCDM transmission system comprising:
The optical OFCDM receiving circuit included in the optical OFCDM receiving apparatus receives only the optical OFCDM signal transmitted by the optical OFCDM transmitting circuit assigned the same code as that assigned to the optical OFCDM receiving circuit. Optical OFCDM transmission system.

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