JP2004222255A - Optical network unit, wavelength splitter and optical wavelength-division multiplexing access system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical wavelength multiplex access system by which many ONUs (optical network units) can be connected while reducing necessity of a temperature control circuit when generating an optical signal and attaining commonalization (product kind reduction) of ONUs. <P>SOLUTION: A center unit (OSU (optical subscriber unit)) and a plurality n of the optical network unit(ONU)s are connected through the wavelength divider and the optical fiber transmission line. In the optical wavelength multiplex access system which bi-directionally transmits a downstream optical signal from the OSU to the each ONU and an upstream optical signal from the each ONU to the OSU, the wavelength interval of the downstream optical signal Δλd ( optical frequency interval Δfd ) is set to two or more times of the wavelength interval of the upstream optical signal Δλu ( optical frequency interval Δfu ), each ONU transmits the upstream optical signal whose optical spectrum width is two or more times of Δλu (Δfu ), respectively, the upstream optical signals transmitted from each ONU are spectrum-sliced into signals whose optical spectrum width are within Δλu (Δfu ) and which have different wavelength (optical frequency) each other by the wavelength divider, and additionally outputted to the OSU after performing a wavelength multiplex. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

  The present invention relates to an optical wavelength division multiplexing access system for transmitting optical signals bidirectionally between a center unit (OSU) and a plurality of optical network units (ONUs).

  As one form of the optical multiplex access system, an optical wavelength multiplex access system in which each ONU occupies a different wavelength on a star-type optical access line that multiplexes and separates a plurality of signals via a wavelength splitter has been studied.

  FIG. 14 shows a configuration example of a conventional optical wavelength division multiplexing access system (Patent Document 1). Here, one wavelength band λd is allocated for a downstream signal from the OSU to the ONU, one wavelength band λu (≠ λd) is allocated for the upstream signal from the ONU to the OSU, and the wavelengths λd1 to λdn of the wavelength band λd are further allocated. And an example in which wavelengths λu1 to λun of a wavelength band λu are assigned to respective ONUs.

  The transmission unit 51 of the OSU 50 wavelength-multiplexes the downstream optical signal in the wavelength band λd (wavelengths λd1 to λdn) and the upstream carrier light in the wavelength band λu (wavelengths λu1 to λun), and wavelength-divisions via the optical fiber transmission line 1. To the device 60. The wavelength splitter 60 separates the downstream optical signal of the wavelength band λd and the upstream carrier light of the wavelength band λu, respectively, and converts the downstream optical signal of the wavelengths λd1 to λdn and the upstream carrier light of the wavelengths λu1 to λun into an optical fiber. The data is transmitted to the corresponding ONUs 70-1 to 70-n via the transmission path 3.

  The ONU 70-1 separates the transmitted downstream optical signal of the wavelength λd1 and the upstream carrier light of the wavelength λu1 by the WDM coupler 71, receives the downstream optical signal of the wavelength λd1 by the optical receiver 32, and The upstream carrier light is modulated by the optical modulator 73 and transmitted to the wavelength splitter 60 via the optical fiber transmission line 4 as an upstream optical signal. The same applies to other ONUs. The upstream optical signals of wavelengths λu1 to λun transmitted from each ONU are wavelength-multiplexed by the wavelength splitter 60, transmitted to the OSU 50 via the upstream optical fiber transmission line 2, and received by the receiving unit 52.

  Here, the wavelength band λd (wavelength λd1 to λdn) of the downstream optical signal and the wavelength band λu (wavelength λu1 to λun) of the upstream carrier light are arranged so as not to overlap on the wavelength axis as shown in FIG. Is done. An arrayed waveguide diffraction grating (AWG) used as the wavelength splitter 60 has a characteristic of simultaneously multiplexing / demultiplexing wavelengths at FSR (free spectral range) intervals. Due to the characteristics of the FSR, the downstream signal wavelength (for example, λd1) and the upstream signal wavelength (for example, λu1) can be split to the same port. In this conventional example, by using this function, the components of each ONU are shared (smaller types). That is, in each ONU, the downstream optical signal and the upstream carrier light can be separated by using the same specification WDM coupler 71 for separating the wavelength band λd and the wavelength band λu. Light is no longer causing interference.

  The upstream carrier light having the wavelengths λu1 to λun is a broadband light including the wavelengths λu1 to λun when transmitted from the transmission unit 51 of the OSU 50, and the wavelength splitter 60 converts the upstream carrier light into the upstream carrier light having the wavelengths λu1 to λun. A method of slicing and sending to each ONU has also been proposed (Patent Document 2).

  By the way, such a device is aimed at sharing the components of the ONUs 70-1 to 70-n as described above (smaller variety). That is, first, the upstream carrier light of each wavelength is supplied from the OSU 50 to each ONU, so that each ONU does not need to individually have a light source of a wavelength assigned to each ONU, and can be shared. Next, the wavelength band λd for the downstream signal and the wavelength band λu for the upstream signal are separated by using the function of the AWG as described above, so that the WDM coupler 71 of each ONU can be shared.

  Also, Patent Documents 3 and 4 propose that the ONU is made into a single product type by the spectrum slicing method to reduce the manufacturing cost.

  In addition, as a unidirectional point-to-point transmission system, there is an example in which a light source portion is configured using a broad-spectrum light source and a band-pass one-input one-output optical filter to apply a spectrum slicing method. (Patent Document 5).

  As shown in FIG. 15, in a configuration in which the OSU 50 and the plurality of ONUs 70-1 to 70-n face each other via the wavelength splitter 60 using an AWG or a multi-port wavelength filter, each ONU has a wide wavelength range. An optical transmitter 75 for modulating a broadband light having a spectrum width is arranged in common, and this broadband light (λu) is modulated by each ONU and transmitted as an upstream optical signal. In addition, a configuration for transmitting data to the OSU 50 has also been proposed (Non-Patent Document 1). This configuration is substantially equivalent to a configuration in which upstream optical signals of different wavelengths are transmitted from each ONU, but is characterized in that light sources having the same specifications can be arranged in each ONU.

In order to obtain a modulated light having a wide optical spectrum width, a superluminescent diode or a semiconductor optical amplifier is directly modulated with an electric signal, or an output light of a semiconductor optical amplifier or an erbium-doped optical fiber amplifier (broadband unmodulated light). ) Can be modulated by an external modulator.
JP 2000-196536 A JP 2001-177505 A JP-A-8-8878 Japanese Patent Application No. 2002-231632 (Japanese Unexamined Patent Application Publication No. 2003-134058) JP-A-7-177127 Akimoto, K. et al., "Spectrum-sliced, 25-GHz spaced, 155 Mbps x 32 channel WDM access", The 4th Pacific Rim Conference on Lasers and Electro-Optics, 2001 (CLEO / Pacific Rim 2001), Vol. 2, pp. II-556-557

  On the other hand, as another form of the optical multiplex access system, each ONU occupies a different wavelength on a star-type optical access line that couples and distributes a plurality of signals via an optical power splitter, and performs bidirectional communication with the OSU. There is a system to do. As such a system, a time division multiplexing system in which different time slots are assigned to each ONU is generally used (such as the ITU-T standard G.983.1 B-PON system).

  By the way, a laser light source used to generate an optical signal of a specified wavelength requires a wavelength control circuit for temperature control or the like when the wavelength interval of a plurality of multiplexed optical signals is, for example, several nm or less. Rising is inevitable. If a general distributed feedback (DFB) laser is used without a temperature control circuit, for example, a wavelength change of about ± 6 to 7 nm occurs in a range of about ± 35 ° C. It is standardized by ITU-T (International Telecommunication Union Telecommunication Standardization Sector) (ITU-T G.694.2).

  When the optical wavelength division multiplexing access system shown in FIG. 14 is configured based on this criterion, the wavelengths λu1 to λun of the upstream carrier light are spaced at 20 nm, and the wavelength band required for the optical modulator 73 of n ONUs is 20 × About n (nm) is required. On the other hand, when a semiconductor optical amplifier or an electroabsorption type optical modulator is used as the optical modulator 73, its operating wavelength band is about 20 to 60 nm. Only the ONUs can be connected.

  When the optical wavelength division multiplexing access system shown in FIG. 15 is configured based on the above criteria, the wavelength band required for the optical transmitter 75 of n ONUs needs to be about 20 × n (nm). On the other hand, when a superluminescent diode, a semiconductor optical amplifier, or an erbium-doped optical fiber amplifier is used as the light source of the optical transmitter 75, the light spectrum width is about 20 to 60 nm, so that one kind of light source will be used. Then, only one to three ONUs can be connected.

  On the other hand, as described above, when each ONU occupies a different wavelength and performs bidirectional communication with the OSU on a star-type optical access line that combines and distributes a plurality of signals via an optical power splitter, , It is necessary to mount light sources having different wavelengths from each other, which raises a problem of cost increase due to diversification of ONUs. Also, an ONU configuration for performing bidirectional communication between an OSU and each ONU by applying a spectrum slicing method on a star type optical access line that combines and distributes a plurality of signals via an optical power splitter is provided. I don't see anything revealed.

  The present invention relates to an optical wavelength division multiplexing access system capable of connecting a large number of ONUs while reducing the necessity of a temperature control circuit when generating an optical signal and using a common ONU (smaller variety). It is an object to provide a wavelength splitter to be used.

  Further, the present invention is also applicable to a configuration in which each ONU occupies a different wavelength on a star-type optical access line that combines and distributes a plurality of signals via an optical power splitter and performs bidirectional communication with the OSU. It is an object of the present invention to provide an optical wavelength division multiplexing access system capable of achieving common use (smaller variety) and to present a specific configuration of an ONU applied to the optical wavelength division multiplexing access system.

In the optical wavelength division multiplexing access system of the present invention, a center unit (OSU) and a plurality of n optical network units (ONUs) are connected via a wavelength splitter and an optical fiber transmission line. An optical wavelength division multiplexing access system for bidirectional transmission of a downstream optical signal and an upstream optical signal from each ONU to an OSU, wherein the wavelength interval Δλd (optical frequency interval Δfd) of the downstream optical signal is the wavelength interval Δλu of the upstream optical signal (The optical frequency interval Δfu) is set to be twice or more, and at least between the OSU and the wavelength splitter, the center wavelength (center frequency) of each downstream optical signal corresponding to each ONU has the same wavelength interval Δλd (optical frequency interval Δfd) is arbitrarily selected from the equally-spaced wavelength grids (equally-spaced frequency grids) determined by Δfd, and the wavelength error (optical frequency error) thereof is ± Δλd / 2 (± Δfd). / 2), and at least between the wavelength splitter and the OSU, the center wavelength (center frequency) of each upstream optical signal corresponding to each ONU is equally spaced determined by an equal wavelength interval Δλu (optical frequency interval Δfu). Each wavelength grid (equally-spaced frequency grid) is arbitrarily selected, and its wavelength error (optical frequency error) is set within ± Δλu / 2 (± Δfu / 2) (claims 1 to 4).
In the optical wavelength division multiplexing access system according to the first aspect, each ONU transmits an upstream optical signal having an optical spectrum width twice or more of Δλu (Δfu), and the wavelength splitter transmits the upstream optical signal transmitted from each ONU. In this configuration, a signal is spectrally sliced into wavelengths (optical frequencies) different from each other within an optical spectrum width of Δλu (Δfu), further wavelength-multiplexed, and transmitted to the OSU.

  In the optical wavelength division multiplexing access system according to the second aspect, the OSU transmits an upstream carrier light corresponding to the wavelength interval (optical frequency interval) of the upstream optical signal, and the wavelength splitter demultiplexes the upstream carrier light. Each ONU modulates the upstream carrier light and transmits it as an upstream optical signal, and the wavelength splitter wavelength-multiplexes the upstream optical signal transmitted from each ONU and sends it to the OSU. It is.

  Further, in the optical wavelength division multiplexing access system according to the third aspect, the OSU transmits an upstream carrier light having an optical spectrum width twice or more of Δλu (Δfu), and the wavelength splitter transmits the upstream carrier light to the optical spectrum width. Is spectrally sliced into different wavelengths (optical frequencies) within Δλu (Δfu) and supplied to each ONU, and each ONU modulates the upstream carrier light of each wavelength (each optical frequency) and transmits it as an upstream optical signal. The wavelength splitter has a configuration in which the upstream optical signal transmitted from each ONU is wavelength-multiplexed and transmitted to the OSU.

  In the optical wavelength division multiplexing access system according to the fourth aspect, the OSU transmits an upstream carrier light having an optical spectrum width twice or more of Δλu (Δfu), and the wavelength splitter n-divides the upstream carrier light. To each ONU, each ONU modulates the upstream carrier light and transmits it as an upstream optical signal, and the wavelength splitter transmits the upstream optical signal transmitted from each ONU within an optical spectrum width of Δλu (Δfu). In this configuration, the spectrum is sliced into wavelengths (optical frequencies) different from each other, further wavelength-multiplexed, and transmitted to the OSU.

The wavelength branching device of the present invention is a wavelength branching device applied to the above-described optical wavelength division multiplexing access system according to claims 1 to 4 (claims 13 to 16).
That is, the wavelength branching device according to claim 13 is a wavelength branching device having a first input / output terminal and a second input / output terminal, wherein the light input from the transmission line on the second input / output terminal side. An optical signal having a spectral width twice or more the wavelength interval Δλu (optical frequency interval Δfu) is spectrally sliced into wavelengths (optical frequencies) different from each other within the optical spectral width Δλu (optical frequency interval Δfu), and further wavelength multiplexed. Then, the signal is transmitted to the transmission line on the first input / output end side, is input from the transmission line on the first input / output end side, and the wavelength interval Δλd (optical frequency interval Δfd) is changed to the wavelength interval Δλu (optical frequency interval Δfu). ) Is divided and transmitted to the transmission line on the second input / output end side.

  A wavelength splitter according to claim 14 is a wavelength splitter having a first input / output terminal and a second input / output terminal, wherein the wavelength input from the transmission line on the second input / output terminal side. The optical signal having the interval Δλu (optical frequency interval Δfu) is wavelength-multiplexed and transmitted to the transmission line on the first input / output end side, input from the transmission line on the first input / output end side, and A wavelength-division multiplexed optical signal corresponding to an optical signal having a wavelength interval Δλu (optical frequency interval Δfu) input from the input / output transmission line is demultiplexed and supplied to the second input / output transmission line, respectively. A wavelength-division multiplexed optical signal input from the transmission line on the first input / output terminal side and having a wavelength interval Δλd (optical frequency interval Δfd) set to be at least twice the wavelength interval Δλu (optical frequency interval Δfu). And supply them to the transmission paths on the second input / output end side.

  The wavelength splitter according to claim 15 is a wavelength splitter having a first input / output terminal and a second input / output terminal, wherein the wavelength input from the transmission line on the second input / output terminal side. An optical signal having an interval Δλu (optical frequency interval λfu) is wavelength-multiplexed and transmitted to the transmission line on the first input / output end side, and is input from the transmission line on the first input / output end side, and the optical spectrum width is The second input / output is performed by spectrally slicing an optical signal having a wavelength interval Δλu (optical frequency interval Δfu) twice or more into wavelengths (optical frequencies) different from each other within an optical spectrum width within the wavelength interval Δλu (optical frequency interval Δfu). Are supplied from the transmission line on the first input / output end side, and the wavelength interval Δλd (optical frequency interval Δfd) is set to be at least twice the wavelength interval Δλu (optical frequency interval Δfu). Splits the wavelength-division multiplexed optical signal into It is configured to respectively transmitted to the transmission path of the input and output end.

  The wavelength splitter according to claim 16 is a wavelength splitter having a first input / output terminal and a second input / output terminal, wherein light input from the transmission line on the second input / output terminal side. An optical signal whose spectral width is set to be twice or more of Δλu (optical frequency interval Δfu) is spectrally sliced into wavelengths (optical frequencies) different from each other within an optical spectral width of wavelength interval Δλu (optical frequency interval Δfu). The signals are multiplexed and transmitted to the transmission line on the first input / output terminal side, input from the transmission line on the first input / output terminal side, and the wavelength interval Δλd (optical frequency interval Δfd) is changed to the wavelength interval Δλu (optical frequency interval). The wavelength-division multiplexed optical signal set to be twice or more of Δfu) is demultiplexed and transmitted to the transmission line on the second input / output terminal side, and is input from the transmission line on the first input / output terminal side. The optical spectrum width is Δλu (optical frequency interval Δfu) 2 In this configuration, an optical signal having a frequency of twice or more is branched and transmitted to the transmission line on the second input / output end side.

  In the optical wavelength division multiplexing access system of the present invention, a center unit (OSU) and a plurality of n optical network units (ONUs) are connected via an optical power splitter and an optical fiber transmission line. An optical wavelength division multiplexing access system for bidirectionally transmitting a downstream optical signal having a different wavelength to each of said ONUs and an upstream optical signal having a different wavelength from each of said ONUs to said OSU, wherein at least each of said ONUs and said OSU , The center wavelength (center frequency) of each upstream optical signal corresponding to each ONU is the same wavelength grid (equidistant frequency grid) determined by equal wavelength intervals Δλu (optical frequency intervals Δfu). The wavelength error (frequency error) is set arbitrarily within ± Δλu / 2 (± Δfu / 2). Each of the ONUs includes an optical transmitting and receiving unit including a broad spectrum light source unit for transmitting an upstream optical signal having an optical spectrum width twice or more the wavelength interval Δλu (Δfu) and an optical receiver for receiving a downstream optical signal; An electrical processing unit connected to the optical transmitting / receiving unit and performing a predetermined electrical process, disposed at the input / output end of each ONU on the side of the optical fiber transmission line, and receiving all the downlinks input from the optical fiber transmission line. From the optical signals, the downstream optical signal corresponding to each ONU is separated to the optical receiver, and the upstream optical signal from the broad spectrum light source unit is centered on the center wavelength (center frequency) set for each ONU. Optical filter means for performing spectrum slicing at a wavelength width (frequency width) within a wavelength interval Δλu (frequency interval Δfu) and sending out the optical fiber transmission path to the optical fiber transmission line; A configuration in which an optical connector removably attached removably (claim 29).

  An optical network unit according to the present invention is applied to each ONU of the optical wavelength division multiplexing access system according to claim 29, wherein the optical signal has an optical spectrum width of a wavelength width Δλ (or a frequency width Δf). A light transmitting / receiving unit including a broad spectrum light source unit for transmitting an optical signal and an optical receiver for receiving an optical signal; an electric processing unit connected to the optical transmitting / receiving unit and performing a predetermined electric process; and an optical network unit. The input / output terminal on the transmission line side of the optical network unit, from among all the optical signals input from the transmission line, separates the received optical signal corresponding to the optical network unit to the optical receiver, and the broad spectrum light source unit An optical filter means for spectrally slicing the transmission optical signal from the optical disc with a wavelength width (frequency width) equal to or less than の of the wavelength width Δλ (frequency width Δf), and transmitting the signal to the transmission line; An optical connector for detachably attaching a filter means to the optical transmitting / receiving unit is provided (claim 25).

  As described above, the optical wavelength division multiplexing access system according to claims 1 to 4 has a configuration in which the wavelength interval of an upstream optical signal is narrower than the wavelength interval of a downstream optical signal, and spectrum slicing is performed by a wavelength splitter. Therefore, it is possible to use a light source that generates an upstream optical signal in each ONU or an optical modulator that modulates the upstream carrier light supplied from the OSU with the same specifications and does not require temperature control in each ONU. Yes, many ONUs can be connected.

  According to the optical wavelength division multiplexing access system of the present invention, in an optical access system for combining and distributing a plurality of signals via an optical power splitter, a spectrum slice method is applied, and each ONU occupies a different wavelength. Thus, communication with the center unit (OSU) can be realized. The ONU unit having a broad spectrum light source unit, an optical receiving unit, and an electrical processing unit and having an active function can be easily separated from a passive function unit corresponding to an optical filter means, so that a single ONU is provided. Variations can be made and total manufacturing costs can be reduced. The optical filter means is configured so that it can be easily attached to and detached from the optical transmission / reception unit by the optical connector means. The introduction can be realized by mounting the optical filter means assigned to each user to a single type of ONU. And operability is improved.

(First embodiment of optical wavelength division multiplexing access system of the present invention)
FIG. 1 shows a first embodiment of the optical wavelength division multiplexing access system of the present invention. In the figure, an OSU 10 wavelength-multiplexes downstream optical signals of wavelengths λd1 to λdn and transmits the multiplexed signals to a wavelength splitter 20 via an optical fiber transmission line 1. The wavelength splitter 20 demultiplexes the downstream optical signals of the wavelengths λd1 to λdn and sends them to the corresponding ONUs 30-1 to 30-n via the optical fiber transmission line 3.

  The ONUs 30-1 to 30-n receive the transmitted downstream optical signals of the wavelengths λd1 to λdn, respectively. Each of the ONUs 30-1 to 30-n generates an upstream optical signal of the same wavelength band λu and transmits the upstream optical signal to the wavelength splitter 20 via the optical fiber transmission line 3. The upstream optical signal transmitted from each ONU is spectrally sliced by the wavelength splitter 20 into wavelengths λu1 to λun, wavelength-multiplexed, and transmitted to the OSU 10 via the optical fiber transmission line 1.

As is clear from the above description, the application of the wavelength branching device 20 is not limited to “branching”, and when the optical signal is propagated in the opposite direction to the case where the branching is performed, it is used as a coupler. Function. That is, although the wavelength branching device 20 functions as a wavelength branching coupler, it is simply referred to as a “wavelength branching device” in this specification for simplicity.
As will be described later in detail with reference to FIGS. 2 to 5, in the optical wavelength division multiplexing access system of the present embodiment, the OSU 10 and the wavelength splitter 20 are connected by a single optical fiber transmission line. The branch unit 20 and each of the n ONUs 30-1 to 30-n are connected via one or two optical fiber transmission lines.

  The downstream optical signals of the wavelengths λd1 to λdn are arbitrarily selected from equally spaced wavelength grids (equally spaced frequency grids) determined by equal wavelength intervals Δλd (optical frequency intervals Δfd), and the wavelength error (optical frequency error) is It is within ± Δλd / 2 (± Δfd / 2). The upstream optical signals of the wavelengths λu1 to λun are arbitrarily selected from equally spaced wavelength grids (equally spaced frequency grids) determined by equal wavelength intervals Δλu (optical frequency intervals Δfu), and their wavelength errors (optical frequency errors) are determined. ) Is within ± Δλu / 2 (± Δfu / 2).

  Here, a feature of the present invention resides in that the wavelength interval Δλd (optical frequency interval Δfd) of the downstream optical signal is set to be at least twice the wavelength interval Δλu (optical frequency interval Δfu) of the upstream optical signal. That is, the band of the upstream optical signal of the wavelength λu1 to λun is narrower than the band of the downstream optical signal of the wavelength λd1 to λdn, and for example, the entire upstream optical signal of λu1 to λun is added to the wavelength band of the downstream optical signal of one channel. Make the channel enter. In this way, by narrowing the wavelength interval of the upstream optical signal, light sources having the same specifications can be used for each ONU to generate the upstream optical signal, so that many ONUs can be connected. Hereinafter, a specific example will be described.

  Downlink optical signals of wavelengths λd1 to λdn propagating through the optical fiber transmission line 1 are, for example, of an equally spaced wavelength grid 1270 + 20n [nm] with a wavelength interval Δλd = 20 nm (defined as n = 0 to 17 in ITU-T G.694.2). Each is arbitrarily selected from among them. If the wavelength error is, for example, ± 6 to 7 nm, the DFB laser can sufficiently cope with the wavelength error in the range of approximately ± 35 ° C.

  On the other hand, assuming that the optical spectrum width of the upstream optical signal transmitted from the ONUs 30-1 to 30-n is, for example, 11.2 nm in the range of the wavelength 1544.5 to 1555.7 nm, the wavelength splitter 20 has the optical spectrum width of, for example, 200 GHz (at around 1550 nm). By performing spectrum slicing at about 1.6 nm, eight upstream optical signals can be obtained from 194,100 GHz (= 1544.5 nm) to 192,700 GHz (= 1555.7 nm) ± 100 GHz. That is, the upstream optical signals from the eight ONUs can be wavelength-multiplexed.

  Further, assuming that the optical spectrum width of the upstream optical signal transmitted from the ONUs 30-1 to 30-n is, for example, 16.0 nm in the wavelength range of 1299.5 to 1315.5 nm, the wavelength splitter 20 uses the optical spectrum width of, for example, 400 GHz (in the vicinity of 1300 nm). By performing spectrum slicing at about 2.3 nm, eight upstream optical signals can be obtained from 230700 GHz (= 1299.5 nm) to 227900 GHz (= 1315.5 nm) ± 200 GHz. That is, the upstream optical signals from the eight ONUs can be wavelength-multiplexed. The wavelength of the downstream optical signal at this time is, for example, 8 waves of 1450 nm to 1590 nm ± 6 to 7 nm at intervals of 20 nm.

  Such an upstream optical signal having a minimum optical spectrum width of about 11.2 nm or 16.0 nm can be generated using a light source such as a superluminescent diode, a semiconductor optical amplifier, or an erbium-doped optical fiber amplifier. In the example, eight ONUs can be handled with the same specifications.

  By the way, in the present embodiment, since the spectrum slice is applied only to the transmission of the upstream optical signal, the transmission system is different between the upstream and the downstream, and the transmittable bit rate may be different. Even in this case, the OSU and the ONU can be provided with an interface having the same bit rate (Patent Document 4). For example, if the bit rate of an upstream optical signal using a spectrum slice cannot be increased to several hundred Mbit / s or more, the OSU and the ONU are provided with Gigabit Ethernet (registered trademark) interfaces, and the bit rate of the downstream optical signal is set to 1.25 Gbit / s. s (the normal transmission speed of Gigabit Ethernet (registered trademark)) and the bit rate of the upstream optical signal can be set to 125 Mbit / s.

(First Configuration Example of the Wavelength Divider 20 of the First Embodiment)
FIG. 2 shows a first configuration example of the wavelength splitter 20 according to the first embodiment of the optical wavelength division multiplexing access system of the present invention.

  In the figure, a wavelength branching device 20 has one coupling port and (n + 1) branching ports, and is included in an equally-spaced wavelength grid (equally-spaced frequency grid) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). CWDM (Coarse Wavelength-Division Multiplexing) that separates into wavelength regions (optical frequency regions) within a transmission width ± Δλd / 2 (± Δfd / 2) centered on (n + 1) wavelengths (optical frequencies) selected from It has a coupler 21, one coupling port and n branch ports, and n kinds of equidistant wavelength grids (equidistant frequency grids) selected from equal wavelength intervals Δλu (optical frequency intervals Δfu) determined by equal wavelength intervals Δλu (optical frequency intervals Δfu). It is composed of a DWDM (Dense Wavelength-Division Multiplexing) coupler 22 that separates into a wavelength region (optical frequency region) within a transmission width ± Δλu / 2 (± Δfu / 2) centered on the wavelength (optical frequency).

  When optical signals are input to the branch ports # 1 to #n of the DWDM coupler 22, the DWDM coupler 22 spectrally slices the input optical signals, and wavelength-multiplexes and combines the spectrally sliced optical signals. Output from port # 0. This is the same for the DWDM couplers 24-1 and 24-2 described later.

  The connection port # 0 of the CWDM coupler 21 is connected to the OSU 10 via the optical fiber transmission line 1. The n branch ports # 1 to #n of the CWDM coupler 21 are connected to the ONUs 30-1 to 30-n via the optical fiber transmission line 3. Branch port # n + 1 of CWDM coupler 21 is connected to coupling port # 0 of DWDM coupler 22. The n branch ports # 1 to #n of the DWDM coupler 22 are connected to the ONUs 30-1 to 30-n via the optical fiber transmission line 4.

  Downlink optical signals of wavelengths λd1 to λdn input to the coupling port # 0 of the CWDM coupler 21 are branched to branch ports # 1 to #n, and are respectively transmitted to the corresponding ONUs 30-1 to 30-n via the optical fiber transmission line 3. Transmitted. The upstream optical signals of wavelength λu input from the ONUs 30-1 to 30-n to the branch ports # 1 to #n of the DWDM coupler 22 are spectrally sliced into wavelengths λu1 to λun and wavelength-multiplexed to the coupling port # 0. The n-wave upstream optical signal is input to the branch port # n + 1 of the CWDM coupler 21, and the n-wave upstream optical signal is transmitted from the coupling port # 0 of the CWDM coupler 21 in the same manner as one downstream optical signal. You. FIG. 2 shows a specific example of wavelength assignment when n = 8.

  Here, the CWDM coupler 21 is a multi-port wavelength filter in which wavelength filters (for example, dielectric multilayer filters) that transmit (or reflect) different wavelengths and reflect (or transmit) other wavelengths are connected in multiple stages, or It can be constituted by an arrayed waveguide grating (AWG) filter published as a planar optical circuit on a glass substrate. The DWDM coupler 22 can be configured by a multi-port wavelength filter or an AWG filter having a wavelength interval different from that of the CWDM coupler 21.

(Second Configuration Example of the Wavelength Divider 20 of the First Embodiment)
FIG. 3 shows a second configuration example of the wavelength splitter 20 of the first embodiment of the optical wavelength division multiplexing access system of the present invention.

  In the figure, a wavelength branching device 20 has one coupling port and (n + 2) branching ports, and is included in an equally-spaced wavelength grid (equally-spaced frequency grid) determined by equal wavelength intervals Δλd (optical frequency intervals Δfd). A CWDM coupler 23 for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) centering on (n + 2) wavelengths (optical frequencies) selected from It has a coupling port and m branch ports, and centers on m kinds of wavelengths (optical frequencies) selected from equidistant wavelength grids (equidistant frequency grids) determined by equal wavelength intervals Δλu (optical frequency intervals Δfu). It has a DWDM coupler 24-1 for separating into a wavelength region (optical frequency region) within the transmission width ± Δλu / 2 (± Δfu / 2), one coupling port, and (nm) branch ports. Similar DWDM cap It constituted by 24-2.

  The coupling port # 0 of the CWDM coupler 23 is connected to the OSU 10 via the optical fiber transmission line 1. The n branch ports # 1 to #n of the CWDM coupler 23 are connected to the ONUs 30-1 to 30-n via the optical fiber transmission line 3. The branch ports # n + 1 and # n + 2 of the CWDM coupler 23 are connected to respective connection ports # 0 of the DWDM couplers 24-1 and 24-2. The m branch ports # 1 to #m of the DWDM coupler 24-1 and the (nm) branch ports # m + 1 to #n of the DWDM coupler 24-2 are connected to the ONU 30-1 via the optical fiber transmission line 4. To 30-n.

  Downlink optical signals of wavelengths λd1 to λdn input to the coupling port # 0 of the CWDM coupler 23 are branched to branch ports # 1 to #n, and are respectively transmitted to the corresponding ONUs 30-1 to 30-n via the optical fiber transmission line 3. Transmitted. The upstream optical signals of wavelength λu input from the ONUs 30-1 to 30-m to the branch ports # 1 to #m of the DWDM coupler 24-1 are spectrally sliced into wavelengths λu1 to λum and wavelength-multiplexed to the coupling port # 0. . The upstream optical signals of the wavelength λu input from the ONUs 30- (m + 1) to 30-n to the branch ports # m + 1 to #n of the DWDM coupler 24-2 are spectrally sliced into the wavelengths λu (m + 1) to λun and connected to the connection ports. Wavelength multiplexing is performed on # 0. The m-wave and (nm) upstream optical signals are input to the branch ports # n + 1 and # n + 2 of the CWDM coupler 23, and the m-wave and (nm) upstream optical signals are converted into two downstream optical signals. The signal is transmitted from the coupling port # 0 of the CWDM coupler 23 in the same manner as the signal. FIG. 3 shows a specific example of wavelength assignment when n = 16 and m = 8.

  In the present configuration example, when the optical spectrum width of the upstream optical signal transmitted from the ONUs 30-1 to 30-n is 30 nm in the range of the wavelength 1525.7 to 1555.7 nm, the optical signal is divided into two groups, and the DWDMs 24-1 and 24-2. By slicing the spectrum with an optical spectrum width of 200 GHz (approximately 1.6 nm around 1550 nm), 16 upstream optical signals from 196500 GHz (= 1525.7 nm) to 192700 GHz (= 1555.7 nm) ± 100 GHz can be obtained. I have.

(Third Configuration Example of the Wavelength Divider 20 of the First Embodiment)
FIG. 4 shows a third configuration example of the wavelength splitter 20 according to the first embodiment of the optical wavelength division multiplexing access system of the present invention.

  In the figure, a wavelength splitter 20 has one coupling port and two branch ports, and a WDM coupler 25 that branches and couples a downstream optical signal of wavelengths λd1 to λdn and an upstream optical signal of wavelengths λu1 to λun. N wavelengths (lights) having one coupling port and n branch ports, and selected from equally spaced wavelength grids (equally spaced frequency grids) determined by equal wavelength intervals Δλd (optical frequency intervals Δfd). A CWDM coupler 26 for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) centered on the frequency), one coupling port and n branch ports, Transmission width ± Δλu / 2 (± Δfu /) centered on n kinds of wavelengths (optical frequencies) selected from equally spaced wavelength grids (equally spaced frequency grids) determined by equal wavelength intervals Δλu (optical frequency intervals Δfu). 2) Within the wavelength range (optical frequency (DWDM coupler 22).

  The connection port # 0 of the WDM coupler 25 is connected to the OSU 10 via the optical fiber transmission line 1. The two branch ports # 1 and # 2 of the WDM coupler 25 are connected to respective coupling ports # 0 of the CWDM coupler 26 and the DWDM coupler 22. The n branch ports # 1 to #n of the CWDM coupler 26 are connected to the ONUs 30-1 to 30-n via the optical fiber transmission line 3. The n branch ports # 1 to #n of the DWDM coupler 22 are connected to the ONUs 30-1 to 30-n via the optical fiber transmission line 4.

  Downlink optical signals of wavelengths λd1 to λdn input to the coupling port # 0 of the WDM coupler 25 are branched to the branch port # 1, and further branched from the coupling port # 0 of the CWDM coupler 26 to the branch ports # 1 to #n. The data is transmitted to the corresponding ONUs 30-1 to 30-n via the fiber transmission path 3. The upstream optical signals of wavelength λu input from the ONUs 30-1 to 30-n to the branch ports # 1 to #n of the DWDM coupler 22 are spectrally sliced into wavelengths λu1 to λun and wavelength-multiplexed to the coupling port # 0. The n-wave upstream optical signal is input to the branch port # 2 of the WDM coupler 25 and transmitted from the coupling port # 0. FIG. 4 shows a specific example of wavelength assignment when n = 16.

(Fourth Configuration Example of Wavelength Divider 20 of First Embodiment)
FIG. 5 shows a fourth configuration example of the wavelength splitter 20 of the first embodiment of the optical wavelength division multiplexing access system of the present invention.

  In the first configuration example shown in FIG. 2, two optical fiber transmission lines 3 and 4 are used to connect the wavelength splitter 20 to the ONUs 30-1 to 30-n. In this configuration example, the WDM couplers 25-1 to 25-n for branching the downstream optical signal of the wavelength λd1 to λdn and the upstream optical signal of the wavelength λu are used, and the branch ports # 1 to #n of the CWDM coupler 21 and the DWDM coupler 22 are used. Are connected to WDM couplers 25-1 to 25-n, respectively, and connected to ONUs 30-1 to 30-n via one optical fiber transmission line 3.

  Here, an example in which the present invention is applied to the first configuration example shown in FIG. 2 is shown, but the same applies to the second configuration example shown in FIG. 3 and the third configuration example shown in FIG. Can be.

(Second to fourth embodiments of the optical wavelength division multiplexing access system of the present invention)
FIG. 6 shows a second embodiment of the optical wavelength division multiplexing access system of the present invention. In the figure, the OSU 10 wavelength-multiplexes downstream optical signals of wavelengths λd1 to λdn and upstream carrier light of wavelengths λu1 to λun, and transmits the resulting signal to the wavelength splitter 20 via the optical fiber transmission line 1. The wavelength splitter 20 demultiplexes the downstream optical signals of the wavelengths λd1 to λdn and the upstream carrier light of the wavelengths λu1 to λun, and sends them to the corresponding ONUs 30-1 to 30-n via the optical fiber transmission line 3. .

  The ONUs 30-1 to 30-n receive the transmitted downstream optical signals of the wavelengths λd1 to λdn, respectively. The upstream carrier light having the wavelengths λu1 to λun is demultiplexed from the downstream optical signal, modulated, returned as an upstream optical signal, and transmitted to the wavelength splitter 20 via the optical fiber transmission line 3. The upstream optical signals of wavelengths λu1 to λun transmitted from the ONUs 30-1 to 30-n are wavelength-multiplexed by the wavelength splitter 20, and transmitted to the OSU 10 via the optical fiber transmission line 1.

  The present embodiment is characterized in that, in the ONUs 30-1 to 30-n, the upstream carrier light of the wavelengths λu1 to λun supplied from the OSU 10 is modulated and turned back, and the other configurations are the same as those of the first embodiment. The same is true. That is, by setting the wavelength interval Δλd (optical frequency interval Δfd) of the downstream optical signal to be at least twice the wavelength interval Δλu (optical frequency interval Δfu) of the upstream optical signal and narrowing the wavelength interval of the upstream optical signal, As the optical modulator that modulates the upstream optical signal by the ONU, one having the same specification can be used.

  The upstream carrier light transmitted from the OSU 10 is a broadband light having a wavelength λu including the wavelengths λu1 to λun as in the third embodiment shown in FIG. A configuration may be adopted in which the spectrum is sliced into carrier light and supplied to each ONU.

  The upstream carrier light transmitted from the OSU 10 is a broadband light having the wavelength λu including the wavelengths λu1 to λun as in the fourth embodiment shown in FIG. The light is distributed to each ONU without spectrum slicing, and each ONU modulates the upstream carrier light of wavelength λu and returns it to the wavelength splitter 20, and the wavelength splitter 20 spectrally slices the upstream optical signal of wavelengths λu1 to λun. Then, wavelength multiplexing may be performed, and the resultant signal may be transmitted to the OSU 10.

  As described above, in the configuration in which the upstream carrier light of the broadband is supplied from the OSU 10 to each ONU, the upstream carrier light spectrum-sliced in the downstream direction is supplied to each ONU, or the upstream carrier light transmitted from each ONU in the upstream direction is transmitted. Any configuration may be adopted in which the optical signal is spectrally sliced and wavelength-multiplexed.

  As described below with reference to FIGS. 9 and 10, in the optical wavelength division multiplexing access systems of the second to fourth embodiments, a two-core optical fiber transmission line is provided between the OSU 10 and the wavelength splitter 20. At the same time, the wavelength splitter 20 and each of the n ONUs 30-1 to 30-n are connected by two optical fiber transmission lines.

(First Configuration Example of Wavelength Divider 20 of Second to Fourth Embodiments)
FIG. 9 shows a first configuration example of the wavelength splitter 20 of the second to fourth embodiments of the optical wavelength division multiplexing access system of the present invention.

  In the figure, a wavelength branching device 20 has one coupling port and (n + 1) branching ports, and is included in an equally-spaced wavelength grid (equally-spaced frequency grid) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). A CWDM coupler 21 for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) centered on (n + 1) wavelengths (optical frequencies) selected from It has a coupling port and n branch ports, and centers on n kinds of wavelengths (optical frequencies) selected from equally spaced wavelength grids (equally spaced frequency grids) determined by equal wavelength intervals Δλu (optical frequency intervals Δfu). DWDM couplers 22-1 and 22-2 for demultiplexing into wavelength regions (optical frequency regions) within transmission width ± Δλu / 2 (± Δfu / 2), and downstream optical signals of wavelengths λd1 to λdn and wavelengths λu1 to λun The upstream carrier light And WDM couplers 25-1 to 25-n.

  When an optical signal is input to the branch ports # 1 to #n of the DWDM coupler 22-1 or 22-2, the DWDM coupler 22-1 or 22-2 multiplexes the input optical signals by wavelength multiplexing. Output from port # 0.

  The connection port # 0 of the CWDM coupler 21 is connected to the OSU 10 via the optical fiber transmission line 1. The n branch ports # 1 to #n of the CWDM coupler 21 are connected to the ONUs 30-1 to 30-n via the WDM couplers 25-1 to 25-n and the optical fiber transmission line 3. Branch port # n + 1 of CWDM coupler 21 is connected to coupling port # 0 of DWDM coupler 22-1. The n branch ports # 1 to #n of the DWDM coupler 22-1 are connected to the ONUs 30-1 to 30-n via the WDM couplers 25-1 to 25-n and the optical fiber transmission line 3. The n branch ports # 1 to #n of the DWDM coupler 22-2 are connected to the ONUs 30-1 to 30-n via the optical fiber transmission line 4. The connection port # 0 of the DWDM coupler 22-2 is connected to the OSU 10 via the optical fiber transmission line 2.

  Downlink optical signals of wavelengths λd1 to λdn input to the coupling port # 0 of the CWDM coupler 21 are branched to branch ports # 1 to #n, and are respectively transmitted through the WDM couplers 25-1 to 25-n and the optical fiber transmission line 3. It is transmitted to the corresponding ONUs 30-1 to 30-n. The upstream carrier light having the wavelength λu is branched to the branch port # n + 1 of the CWDM coupler 21 and further spectrum-sliced to the branch ports # 1 to #n of the DWDM coupler 22-1, and the WDM couplers 25-1 to 25- n and the corresponding ONUs 30-1 to 30-n via the optical fiber transmission line 3. The upstream optical signals of wavelengths λu1 to λun input from the ONUs 30-1 to 30-n to the branch ports # 1 to #n of the DWDM coupler 22-2 are multiplexed and transmitted to the coupling port # 0.

  Note that this is a configuration (corresponding to the third embodiment in FIG. 7) in which upstream carrier light spectrum-sliced in the downstream direction is supplied to each ONU (in this case, a DWDM coupler that wavelength-multiplexes upstream optical signals). 22-2 may be an optical splitter / coupler having no wavelength selectivity. In the case of a configuration in which the upstream optical signal transmitted from each ONU is spectrally sliced and wavelength-division multiplexed (corresponding to the fourth embodiment in FIG. 8) in the upstream direction, the DWDM coupler 22-1 has a wavelength selectivity. It is sufficient to supply the upstream carrier light of wavelength λu to each ONU without any change.

  Also, as in the configuration of the second embodiment shown in FIG. 6, when transmitting upstream carrier light of wavelengths λu1 to λun from the OSU 10, it is collectively branched to the branch port # n + 1 of the CWDM coupler 21. Uplink carrier light of each wavelength similar to that in the case of spectrum slicing is supplied to each ONU from branch ports # 1 to #n of DWDM coupler 22-1.

(Second Configuration Example of Wavelength Divider 20 of Second to Fourth Embodiments)
FIG. 10 shows a second configuration example of the wavelength splitter 20 of the second to fourth embodiments of the optical wavelength division multiplexing access system of the present invention.

  The wavelength splitter 20 of this configuration example includes the same CWDM coupler 21, DWDM couplers 22-1, 22-2, and WDM couplers 25-1 to 25-n as in the first configuration example, and the connection relationship is also the same. is there. However, the directions of the signals are different.

  Downlink optical signals of wavelengths λd1 to λdn input to the coupling port # 0 of the CWDM coupler 21 are branched to branch ports # 1 to #n, and are respectively transmitted through the WDM couplers 25-1 to 25-n and the optical fiber transmission line 3. It is transmitted to the corresponding ONUs 30-1 to 30-n. The upstream carrier light of wavelength λu input to the coupling port # 0 of the DWDM coupler 22-2 is branched to branch ports # 1 to #n, and the corresponding ONUs 30-1 to 30 through the optical fiber transmission line 4. -N.

  The upstream optical signals of wavelengths λu1 to λun transmitted from the ONUs 30-1 to 30-n and input to the branch ports # 1 to #n of the DWDM coupler 22-1 via the WDM couplers 25-1 to 25-n are combined. Wavelength multiplexed to port # 0. The n-wave upstream optical signal is input to the branch port # n + 1 of the CWDM coupler 21, and the n-wave upstream optical signal is transmitted from the coupling port # 0 of the CWDM coupler 21 in the same manner as one downstream optical signal. You.

  Note that this is a configuration (corresponding to the third embodiment in FIG. 7) in which upstream carrier light spectrum-sliced in the downstream direction is supplied to each ONU (in this case, a DWDM coupler that wavelength-multiplexes upstream optical signals). 22-1 may be an optical splitter / coupler having no wavelength selectivity. In the case of a configuration in which the upstream optical signal transmitted from each ONU is spectrally sliced and wavelength-division multiplexed (corresponding to the fourth embodiment in FIG. 8) in the upstream direction, the DWDM coupler 22-2 has a wavelength selectivity. No optical branching coupler is provided, and the upstream carrier light of wavelength λu is supplied to each ONU as it is.

  Further, as in the configuration of the second embodiment shown in FIG. 6, when transmitting upstream carrier light of wavelengths λu1 to λun from the OSU 10, the spectrum is transmitted from the branch ports # 1 to #n of the DWDM coupler 22-2. Uplink carrier light of each wavelength similar to that in the case of slicing is supplied to each ONU.

  9 and 10 correspond to the first configuration example of the wavelength splitter 20 of the first embodiment shown in FIG. 2 or the fourth configuration example shown in FIG. Is what you do. Similarly, in correspondence with the second configuration example of the wavelength splitter 20 of the first embodiment shown in FIG. 3, the DWDM coupler for spectrum slicing may be divided into a plurality. In addition, corresponding to the third configuration example of the wavelength branching device 20 of the first embodiment shown in FIG. 4, each coupling port # 0 of the CWDM coupler 21 and the DWDM coupler 22-1 is connected to the optical fiber via the WDM coupler 25. You may make it connect to the transmission path 1.

  Also, for example, the WDM couplers 25, 25-1 to 25-n used in the wavelength splitters 20 shown in FIGS. 4, 5, 9, and 10 reflect a downstream optical signal or an upstream optical signal and have other wavelengths. It can be constituted by an optical wavelength filter that transmits an optical signal. Alternatively, a three-port optical circulator that outputs a downstream optical signal or an upstream optical signal to one optical fiber transmission line and takes in an upstream optical signal or a downstream optical signal input from one optical fiber transmission line may be used. it can. Alternatively, an optical coupler may be used.

(Fifth Embodiment of Optical WDM Access System of the Present Invention)
FIG. 11 is a diagram illustrating an optical wavelength division multiplexing access system according to a fifth embodiment of the present invention. In this system, a center unit (OSU) 110 and a plurality of n optical network units (ONUs) 130-1 to 130-n are connected via an optical power splitter 120 and optical fiber transmission lines 101 and 103. ing. As a result, the same system transmits downstream optical signals (wavelengths λd1,..., Λdn) having different wavelengths transmitted from the OSU 110 to the ONUs 130-1 to 130-n, and from the ONUs 130-1 to 130-n. Uplink optical signals (wavelengths λu1,..., Λun) transmitted to the OSU 110 having different wavelengths are bidirectionally transmitted.

Hereinafter, each configuration will be described in more detail.
The optical fiber transmission line includes an optical fiber transmission line 101 connecting the OSU 110 and the optical power splitter 120, and a plurality of optical fiber transmission lines 103 connecting the optical power splitter 120 and the ONUs 130-1 to 130-n.

  The OSU 110 wavelength-multiplexes the downstream optical signals of the wavelengths λd1,..., Λdn, and transmits the wavelength-multiplexed downstream optical signals to the optical power splitter 120 via the optical fiber transmission line 101.

  The optical power splitter 120 distributes the optical power of the downstream optical signal input from the optical fiber transmission line 101, and distributes the distributed downstream optical signal to the ONUs 130-1 to 130-n via the optical fiber transmission line 103, respectively. Send out. The optical power splitter 120 combines the upstream optical signals of the wavelengths λu1,..., Λun respectively transmitted from the ONUs 130-1 to 130-n via the optical fiber transmission line 103, and combines the upstream optical signals. To the OSU 110 via the optical fiber transmission line 101.

  As is clear from the above description, the application of the optical power splitter 120 is not limited to “branch (distribution)”, and the optical power splitter 120 may be used in a case where an optical signal is propagated in a direction opposite to the case of branching. Functions as a coupler. That is, the optical power splitter 120 functions as an optical power splitter / coupler, but is simply referred to as an “optical power splitter” for simplicity in this specification.

  Each of the ONUs 130-1 to 130-n receives the downstream optical signal of the wavelength assigned to itself from among the downstream optical signals of the wavelengths λd1,..., Λdn transmitted via the optical fiber transmission line 103. Each of the ONUs 130-1 to 130-n generates an upstream optical signal having a wavelength assigned to the ONU 130-1 to 130-n, and transmits the upstream optical signal to the optical power splitter 120 via the optical fiber transmission line 103. In the example of FIG. 11, the wavelengths λdk and λuk are assigned to the ONUs 130-k (k = 1 to n).

  In the present embodiment, at least in the optical fiber transmission line between each of the ONUs 130-1 to 130-n and the OSU 110, the center wavelength λuk (center frequency) of each upstream optical signal corresponding to each ONU has the same wavelength interval Δλu (optical Each of them is arbitrarily selected from equally spaced wavelength grids (equally spaced frequency grids) determined by the frequency interval Δfu), and the wavelength error (frequency error) is set within ± Δλu / 2 (± Δfu / 2). For example, when the center frequency (center wavelength λun) of the upstream optical signal corresponding to the ONU 130-n is Δλu = 200 [GHz], 193100 [GHz] (= about 1552.5 [nm]) in the optical fiber transmission line. It is arranged to be + 200 × n [GHz].

  Each ONU includes a broad spectrum light source unit 131 for transmitting an upstream optical signal having an optical spectrum width twice or more the wavelength interval Δλu (optical frequency interval Δfu) and an optical receiver 132 for receiving a downstream optical signal and converting it into an electric signal. An optical transmitter / receiver 133 and an electrical receiver that performs predetermined electrical processing on an electrical signal output from the optical receiver 132 and outputs an electrical signal for controlling the broad spectrum light source 131 to the broad spectrum light source 131. The processing unit 134 is provided.

  Optical filter units 140-1 to 140-n are arranged at input and output ends of the ONUs 130-1 to 130-n on the optical fiber transmission line 103 side (OSU 110 side) via optical connectors 150, respectively. By these optical connectors 150, the optical filter units 140-1 to 140-n can be easily attached to and detached from the optical transmitting / receiving unit 133 in the ONUs 130-1 to 130-n. Although not shown in FIG. 11, the other input / output terminals of the ONUs 130-1 to 130-n are user interfaces (see FIGS. 13A and 13B).

  Each optical filter unit 140-k separates an optical signal of the wavelength λdk assigned to the ONU 130-k corresponding to the optical filter unit from all the downstream optical signals input from the optical fiber transmission line 103. , And to the optical transmission / reception unit 133 in the ONU 130-k, and spectrum-slices the upstream optical signal from the optical transmission / reception unit 133 at the wavelength λdk, and transmits the signal to the optical fiber transmission line 103. As shown in FIG. 11, for example, the broadband light output from the broad spectrum light source 131 of the ONU 130-n is spectrally sliced by the optical filter unit 140-n, and the upstream optical signal having the center wavelength of the wavelength λun is transmitted through the optical fiber. It is sent to the path 103.

  More specifically, the upstream optical signal is converted by the optical filter unit 140-k into a wavelength width (frequency) within a wavelength interval Δλu (frequency interval Δfu) around the center wavelength (center frequency) set for each ONU. Width).

  For example, as described above, the center frequency (center wavelength) of the upstream optical signal corresponding to the ONU 130-n is 193100 [GHz] (= about 1552.5 [nm]) + 200 × n [GHz] in the optical fiber transmission line. When arranged such that the optical spectrum width of the upstream optical signal output from the broad spectrum light source 131 in each ONU is 200 × n from 193100 [GHz] to 193100 + 200 × n [GHz]. It has a width of [GHz]. Therefore, if a broad spectrum light source 131 having a spectrum width of 200 [GHz] (= approximately 0.8 [nm]) × 8 to 16, that is, a spectral width of approximately 6.4 nm to 12.8 [nm] is used, n = 8 to 8 Sixteen optical wavelength division multiplexing access systems can be realized.

  The ONUs 130-1 to 130-n have the same configuration except for the optical filter units 140-1 to 140-n. Each of the optical filter units 140-k has the same basic configuration, and transmits an optical signal having a unique wavelength λdk assigned to the ONU 130-k corresponding to the optical filter unit to the optical power splitter 120. They differ from each other in that they are designed to transmit and receive between them. For this reason, the optical filter units 140-1 to 140-n can be attached to and detached from the optical transceiver 133.

  According to the present embodiment, in an optical access system that combines and distributes a plurality of signals via an optical power splitter, a system is realized in which each ONU occupies a different wavelength and communicates with the OSU by applying a spectrum slicing method. Is done. In addition, since the active functional portion including the broad spectrum light source 131, the optical receiver 132, and the electrical processing unit 134 can be easily separated from the passive functional portion including the optical filter unit 140-k, the ONUs 130-1 to 130-130 can be easily separated. −n can be made into a single product, and the total manufacturing cost can be reduced. In addition, since the optical filter unit 140-k can be easily attached to and detached from the optical transmission / reception unit 133 by the optical connector 150, it is sufficient to mount the optical filter unit assigned to each user to a single type of ONU, which improves operability. improves.

(Sixth embodiment of the optical wavelength division multiplexing access system of the present invention)
FIG. 12 is a diagram illustrating a configuration of an optical wavelength division multiplexing access system according to a sixth embodiment of the present invention. 12, the same components as those shown in FIG. 11 are denoted by the same reference numerals, and description thereof will be omitted.

  In the present embodiment, in the optical wavelength division multiplexing access system of the fifth embodiment, the wavelength interval Δλd (optical frequency interval Δfd) of the downstream signal in the optical fiber transmission line is changed to the wavelength interval Δλu (optical frequency interval Δfu) of the upstream signal. Is set to at least twice or more.

  Also, at least between the OSU 110 and each of the ONUs 130-1 to 130-n, the center wavelengths (center frequencies) λd1,..., Dn of the respective downstream optical signals corresponding to each of the ONUs 130-1 to 130-n are equal wavelength intervals. Each of them is arbitrarily selected from equally spaced wavelength grids (equally spaced frequency grids) determined by Δλd (optical frequency interval Δfd), and the wavelength error (frequency error) is set within ± Δλd / 2 (± Δfd / 2). You.

  As a specific example, it is assumed that the wavelength of the downstream optical signal is arbitrarily selected from an equally-spaced wavelength grid at an interval of 20 nm. In this case, the wavelengths of the downstream optical signals corresponding to the ONUs 130-1 to 130-8 are set to, for example, 1430, 1450, 1470, 1490, 1510, 1570, 1590, and 1610 nm, respectively. The wavelength λu1,..., Λun of the upstream optical signal is arbitrarily selected from the equally-spaced wavelength grid at 20 nm intervals, and is located near 1530 and 1550 nm jumping between 1510 nm and 1570 nm. .

  In this embodiment, it is preferable to use an individual laser (LD) for each wavelength for generating the downstream optical signal in the OSU 110. When an LD is used, the requirement for the wavelength stability of the LD becomes looser when the wavelength interval of the wavelength grid is coarse, so that the device can be easily reduced in weight and cost.

  By adopting the configuration and wavelength arrangement as in the present embodiment, it is possible to realize a single type of ONU and to realize a light weight and low cost OSU.

(Seventh embodiment of the optical wavelength division multiplexing access system of the present invention)
FIGS. 13A and 13B are explanatory diagrams of the seventh embodiment of the present invention, and are configuration examples of the optical filter unit according to the fifth embodiment or the sixth embodiment. 13 (a) and 13 (b), the same components as those shown in FIG. 11 or FIG. 12 are denoted by the same reference numerals, and description thereof will be omitted.

  The optical filter unit 140-k in FIG. 13A is a wavelength λ send ± α (α is the light of the optical signal transmitted from the broad spectrum light source 131) to be obtained by spectrum slicing the optical signal transmitted from the broad spectrum light source 131. A wavelength filter 141 for multiplexing / demultiplexing a wavelength width (frequency width) equal to or less than の of the spectral width Δλ (frequency width Δf) and a wavelength range other than λsend ± α including at least the wavelength λreceive of the received optical signal; And a wavelength filter 142 for selecting an optical signal of λreceive ± β (β is an arbitrary wavelength width). In FIG. 13A, the wavelength λsend is the wavelength λuk, and the wavelength λreceive is the wavelength λdk. Α is set to １ ／ or less of the wavelength interval Δλu, and β is set to 以下 or less of the wavelength interval Δλd.

  The optical signal generated from the broad-spectrum light source 131 is spectrally sliced through the wavelength filter 141 at a wavelength centered on the wavelength λsend and, at the same time, directionally multiplexed with the optical signal from the optical fiber transmission line 103. The data is transmitted to the fiber transmission line 103.

  On the other hand, the optical signal from the optical fiber transmission line 103 is separated by the wavelength filter 141 from the optical signal of λsend ± α sent to the optical fiber transmission line 103 and output to the wavelength filter 142, and then the wavelength filter 142 , Λdk ± β are separated from other optical signals not related to the ONU 130-k and output to the optical receiver 132.

  13B includes a wavelength filter 143 that selects λsend ± α to be obtained by spectrally slicing an optical signal transmitted from the broad-spectrum light source 131, and a wavelength λreceive ± of the received optical signal. The wavelength filter 144 multiplexes and separates β and a wavelength range other than λreceive ± β, including at least λsend ± α. In FIG. 13B, the wavelength λsend is the wavelength λuk, and the wavelength λreceive is the wavelength λdk. Α is set to １ ／ or less of the wavelength interval Δλu, and β is set to 以下 or less of the wavelength interval Δλd.

  The optical signal generated from the broad spectrum light source 131 is sent through a wavelength filter 143 to a wavelength filter 144 after being spectrum-sliced at a wavelength centered on the wavelength λsend, and transmitted from the optical fiber transmission line 103 by the wavelength filter 144. And is sent to the optical fiber transmission line 103.

  On the other hand, from the optical signal input from the optical fiber transmission line 103, the wavelength filter 144 separates the optical signal of λdk ± β from other optical signals not related to the ONU 130-k and the optical signal of the wavelength λsend ± α. , To the optical receiver 132.

  The embodiments of the present invention have been described with reference to the drawings. However, these embodiments are merely examples of the present invention, and it is apparent that the present invention is not limited to these embodiments. Therefore, additions, omissions, substitutions, and other modifications of the components may be made without departing from the spirit and scope of the present invention. That is, the present invention is not limited to the above description, but is limited only to the scope of the claims described below.

FIG. 1 is a diagram illustrating a first embodiment of an optical wavelength division multiplexing access system according to the present invention. FIG. 2 is a diagram illustrating a first configuration example of a wavelength splitter 20 according to the first embodiment. FIG. 3 is a diagram illustrating a second configuration example of the wavelength splitter 20 according to the first embodiment. FIG. 5 is a diagram illustrating a third configuration example of the wavelength splitter 20 according to the first embodiment. FIG. 6 is a diagram illustrating a fourth configuration example of the wavelength splitter 20 according to the first embodiment. FIG. 5 is a diagram illustrating a second embodiment of the optical wavelength division multiplexing access system of the present invention. FIG. 11 is a diagram illustrating a third embodiment of the optical wavelength division multiplexing access system of the present invention. FIG. 11 is a diagram illustrating a fourth embodiment of the optical wavelength division multiplexing access system of the present invention. It is a figure showing the 1st example of composition of wavelength splitter 20 of a 2nd-4th embodiment. It is a figure showing the 2nd example of composition of wavelength splitter 20 of a 2nd-4th embodiment. It is a figure showing a 5th embodiment of an optical wavelength division multiplex access system of the present invention. FIG. 13 is a diagram illustrating a sixth embodiment of the optical wavelength division multiplexing access system of the present invention. It is a figure showing a 7th embodiment of the present invention, and is the 1st composition example (a) and the 2nd composition example (b) of an optical filter unit in a 5th embodiment or a 6th embodiment. . FIG. 1 is a diagram showing a first configuration example of a conventional optical wavelength division multiplexing access system. FIG. 2 is a diagram illustrating a second configuration example of the conventional optical wavelength division multiplexing access system.

Explanation of reference numerals

1,2,3,4,101,103 Optical fiber transmission line 10,110 Center unit (OSU)
20 wavelength splitter 21 CWDM coupler (1 × (n + 1))
22 DWDM coupler (1 × n)
23 CWDM coupler (1 × (n + 2))
24 DWDM coupler (1 × m)
25 WDM coupler (1 × 2)
26 CWDM coupler (1 × n)
30, 130-1, 130-k, 130-n Optical Network Unit (ONU)
Reference Signs List 120 optical power splitter 131 broad spectrum light source 132 optical receiver 133 optical transmitting / receiving unit 134 electric processing units 140-1, 140-k, 140-n optical filter unit 150 optical connector

Claims (33)

A center device (OSU) and a plurality of n optical network units (ONUs) are connected via a wavelength splitter and an optical fiber transmission line, and a downstream optical signal from the OSU to each ONU and each ONU. In an optical wavelength division multiplexing access system for bidirectional transmission of an upstream optical signal from the OSU to the OSU,
At least between the OSU and the wavelength splitter, the center wavelength (center frequency) of each downstream optical signal corresponding to each ONU has an equally-spaced wavelength grid (equally-spaced frequency) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). Grid), the wavelength error (optical frequency error) thereof is set within ± Δλd / 2 (± Δfd / 2),
At least between the wavelength splitter and the OSU, the center wavelength (center frequency) of each upstream optical signal corresponding to each ONU has an equal interval wavelength grid (equal interval frequency) determined by an equal wavelength interval Δλu (optical frequency interval Δfu). Grid), the wavelength error (optical frequency error) is set within ± Δλu / 2 (± Δfu / 2),
The wavelength interval Δλd (optical frequency interval Δfd) of the downstream optical signal is set to be at least twice the wavelength interval Δλu (optical frequency interval Δfu) of the upstream optical signal,
Each of the ONUs transmits an upstream optical signal whose optical spectrum width is at least twice as large as Δλu (Δfu), and the wavelength splitter converts the upstream optical signal transmitted from each ONU into an optical spectrum width within Δλu (Δfu). The optical wavelength division multiplexing access system is characterized in that the spectrum is sliced into wavelengths (optical frequencies) different from each other, and further wavelength multiplexed and transmitted to the OSU. A center device (OSU) and a plurality of n optical network units (ONUs) are connected via a wavelength splitter and an optical fiber transmission line, and a downstream optical signal from the OSU to each ONU and each ONU. In an optical wavelength division multiplexing access system for bidirectional transmission of an upstream optical signal from the OSU to the OSU,

At least between the OSU and the wavelength splitter, the center wavelength (center frequency) of each downstream optical signal corresponding to each ONU has an equally-spaced wavelength grid (equally-spaced frequency) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). Grid), the wavelength error (optical frequency error) thereof is set within ± Δλd / 2 (± Δfd / 2),
At least between the wavelength splitter and the OSU, the center wavelength (center frequency) of each upstream optical signal corresponding to each ONU has an equal interval wavelength grid (equal interval frequency) determined by an equal wavelength interval Δλu (optical frequency interval Δfu). Grid), the wavelength error (optical frequency error) is set within ± Δλu / 2 (± Δfu / 2),
The wavelength interval Δλd (optical frequency interval Δfd) of the downstream optical signal is set to be at least twice the wavelength interval Δλu (optical frequency interval Δfu) of the upstream optical signal,
The OSU transmits an upstream carrier light corresponding to a wavelength interval (optical frequency interval) of the upstream optical signal, and the wavelength splitter demultiplexes the upstream carrier light and supplies it to each ONU. Each ONU modulates the upstream carrier light and transmits the modulated upstream optical signal as an upstream optical signal, and the wavelength splitter wavelength-multiplexes the upstream optical signal transmitted from each ONU and transmits the multiplexed upstream optical signal to the OSU. WDM access system. A center device (OSU) and a plurality of n optical network units (ONUs) are connected via a wavelength splitter and an optical fiber transmission line, and a downstream optical signal from the OSU to each ONU and each ONU. In an optical wavelength division multiplexing access system for bidirectional transmission of an upstream optical signal from the OSU to the OSU,
At least between the OSU and the wavelength splitter, the center wavelength (center frequency) of each downstream optical signal corresponding to each ONU has an equally-spaced wavelength grid (equally-spaced frequency) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). Grid), the wavelength error (optical frequency error) thereof is set within ± Δλd / 2 (± Δfd / 2),
At least between the wavelength splitter and the OSU, the center wavelength (center frequency) of each upstream optical signal corresponding to each ONU has an equal interval wavelength grid (equal interval frequency) determined by an equal wavelength interval Δλu (optical frequency interval Δfu). Grid), the wavelength error (optical frequency error) is set within ± Δλu / 2 (± Δfu / 2),
The wavelength interval Δλd (optical frequency interval Δfd) of the downstream optical signal is set to be at least twice the wavelength interval Δλu (optical frequency interval Δfu) of the upstream optical signal,
The OSU transmits upstream carrier light having an optical spectrum width twice or more as large as Δλu (Δfu), and the wavelength splitter converts the upstream carrier light into wavelengths (lights) having different optical spectrum widths within Δλu (Δfu). Frequency), and supplies the ONUs to each of the ONUs. Each ONU modulates the upstream carrier light of each wavelength (each optical frequency) and transmits it as an upstream optical signal. An optical wavelength division multiplexing access system characterized in that the wavelength division multiplexing is performed on an upstream optical signal transmitted from the OSU and the resultant signal is transmitted to the OSU. A center device (OSU) and a plurality of n optical network units (ONUs) are connected via a wavelength splitter and an optical fiber transmission line, and a downstream optical signal from the OSU to each ONU and each ONU. In an optical wavelength division multiplexing access system for bidirectional transmission of an upstream optical signal from the OSU to the OSU,
At least between the OSU and the wavelength splitter, the center wavelength (center frequency) of each downstream optical signal corresponding to each ONU has an equally-spaced wavelength grid (equally-spaced frequency) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). Grid), the wavelength error (optical frequency error) thereof is set within ± Δλd / 2 (± Δfd / 2),
At least between the wavelength splitter and the OSU, the center wavelength (center frequency) of each upstream optical signal corresponding to each ONU has an equal interval wavelength grid (equal interval frequency) determined by an equal wavelength interval Δλu (optical frequency interval Δfu). Grid), the wavelength error (optical frequency error) is set within ± Δλu / 2 (± Δfu / 2),
The wavelength interval Δλd (optical frequency interval Δfd) of the downstream optical signal is set to be at least twice the wavelength interval Δλu (optical frequency interval Δfu) of the upstream optical signal,
The OSU transmits an upstream carrier light having an optical spectrum width twice or more of Δλu (Δfu), and the wavelength splitter n-divides the upstream carrier light and supplies it to the ONUs. The upstream carrier light is modulated and transmitted as an upstream optical signal, and the wavelength splitter converts the upstream optical signal transmitted from each ONU to a different wavelength (optical frequency) within an optical spectrum width of Δλu (Δfu). An optical wavelength division multiplexing access system characterized in that the spectrum is sliced, and the wavelength is multiplexed and transmitted to the OSU. The optical wavelength division multiplexing access system according to claim 1,
The wavelength branching device has one coupling port and (n + 1) branching ports, and is selected from equally spaced wavelength grids (equally spaced frequency grids) determined by equal wavelength intervals Δλd (optical frequency intervals Δfd). A first wavelength branching means for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) centered on (n + 1) kinds of wavelengths (optical frequencies); It has a coupling port and n branch ports, and centers on n kinds of wavelengths (optical frequencies) selected from equally spaced wavelength grids (equally spaced frequency grids) determined by equal wavelength intervals Δλu (optical frequency intervals Δfu). A second wavelength branching means for separating the light into a wavelength region (optical frequency region) within the transmission width ± Δλu / 2 (± Δfu / 2).
The coupling port of the first wavelength branching unit is connected to the OSU via the optical fiber transmission line, and the n branch ports of the first wavelength branching unit are connected to the OSU via the optical fiber transmission line. Each of the ONUs, another one of the first wavelength branching means is connected to a coupling port of the second wavelength branching means, and the n number of branching ports of the second wavelength branching means are An optical wavelength division multiplexing access system connected to each of the ONUs via the optical fiber transmission line. The optical wavelength division multiplexing access system according to claim 1,
The wavelength splitter has one coupling port and (n + 2) branch ports, and is selected from an equally-spaced wavelength grid (equally-spaced frequency grid) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). A first wavelength branching means for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) around (n + 2) wavelengths (optical frequencies); It has a coupling port and m branch ports, and centers on m kinds of wavelengths (optical frequencies) selected from equidistant wavelength grids (equidistant frequency grids) determined by equal wavelength intervals Δλu (optical frequency intervals Δfu). A second wavelength branching unit that separates into a wavelength region (optical frequency region) within the transmission width ± Δλu / 2 (± Δfu / 2), one coupling port and (nm) branch ports. Third wave similar to the second wavelength branching means having Is constituted by the branching means,
The coupling port of the first wavelength branching unit is connected to the OSU via the optical fiber transmission line, and the n branch ports of the first wavelength branching unit are connected to the OSU via the optical fiber transmission line. The other two branch ports are connected to each ONU, and the other two branch ports of the first wavelength branching means are connected to respective coupling ports of the second and third wavelength branching means, and m number of the second wavelength branching means are connected to each other. And the (nm) branch ports of the third wavelength branching means are connected to the respective ONUs via the optical fiber transmission line. The optical wavelength division multiplexing access system according to claim 1,
The wavelength branching device has one coupling port and two branch ports, upper and lower wavelength branching means for branching and coupling the downstream optical signal and the upstream optical signal, one coupling port and n number of It has a branch port and has a transmission width ± Δλd centered on n kinds of wavelengths (optical frequencies) selected from equally-spaced wavelength grids (equally-spaced frequency grids) determined by equal wavelength intervals Δλd (optical frequency intervals Δfd). / 2 (± Δfd / 2), having a first wavelength branching means for separating into a wavelength range (optical frequency range), one coupling port and n branch ports, and having an equal wavelength interval Δλu (optical frequency A wavelength region within a transmission width ± Δλu / 2 (± Δfu / 2) centered on n kinds of wavelengths (optical frequencies) selected from the equally-spaced wavelength grid (equally-spaced frequency grid) determined by the interval Δfu). Second wavelength splitting into optical frequency domain) It is composed of a stage,
A coupling port of the upper and lower wavelength branching means is connected to the OSU via the optical fiber transmission line, and two branch ports of the upper and lower wavelength branching means are coupled to each of the first and second wavelength branching means. Connected to a port, the n branch ports of the first wavelength branching unit are connected to the respective ONUs via the optical fiber transmission line, and the n branch ports of the second wavelength branching unit are: An optical wavelength division multiplexing access system connected to each of the ONUs via the optical fiber transmission line. The optical wavelength division multiplexing access system according to any one of claims 2 to 4,
The wavelength branching device has one coupling port and (n + 1) branching ports, and is selected from equally spaced wavelength grids (equally spaced frequency grids) determined by equal wavelength intervals Δλd (optical frequency intervals Δfd). A first wavelength branching means for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) centered on (n + 1) kinds of wavelengths (optical frequencies); It has a coupling port and n branch ports, and centers on n kinds of wavelengths (optical frequencies) selected from equally spaced wavelength grids (equally spaced frequency grids) determined by equal wavelength intervals Δλu (optical frequency intervals Δfu). A second and a third wavelength branching means for separating into a wavelength region (optical frequency region) within the transmission width ± Δλu / 2 (± Δfu / 2), and combining the downstream optical signal and the upstream carrier light; Or the downstream optical signal and the upstream optical signal It is constituted by n number of vertical wave branching means for branching a
A coupling port of the first wavelength branching unit is connected to the OSU via the optical fiber transmission line, and n branch ports of the first wavelength branching unit are the upper and lower wavelength branching units and the optical fiber. Another one of the first wavelength branching means is connected to each of the ONUs via a transmission line, and another one of the first wavelength branching means is connected to a coupling port of the second wavelength branching means. The n branch ports are connected to the respective ONUs via the upper and lower wavelength branching means and the optical fiber transmission line, and the n branch ports of the third wavelength branching means are connected via the optical fiber transmission line. An optical wavelength multiplexing access system, wherein a connection port of the third wavelength branching means is connected to the OSU via the optical fiber transmission line. The optical wavelength division multiplexing access system according to any one of claims 5 to 7,
The wavelength branching unit and each of the ONUs are connected via one optical fiber transmission line, respectively.
The wavelength branching means includes upper and lower wavelength branching means connected to each one optical fiber transmission line respectively connected to each of the ONUs, and branching and coupling the downstream optical signal and the upstream optical signal. WDM access system. The optical wavelength division multiplexing access system according to any one of claims 7 to 9,
At least one of the upper and lower wavelength branching units is an optical wavelength filter that reflects the downstream optical signal or the upstream optical signal and transmits optical signals of other wavelengths. The optical wavelength division multiplexing access system according to any one of claims 7 to 9,
At least one of the upper and lower wavelength branching units outputs the downstream optical signal or the upstream optical signal to the one optical fiber transmission line, and receives the upstream optical signal or the upstream optical signal input from the one optical fiber transmission line. An optical wavelength-division multiplexing access system comprising a three-port optical circulator for receiving a downstream optical signal. The optical wavelength division multiplexing access system according to any one of claims 7 to 9,
An optical wavelength division multiplexing access system, wherein at least one of the upper and lower wavelength branching means is an optical coupler. A wavelength splitter having a first input / output terminal and a second input / output terminal,
An optical signal having an optical spectrum width input from the transmission line on the second input / output end side and having an optical spectrum width twice or more the wavelength interval Δλu (optical frequency interval Δfu) is within the wavelength interval Δλu (optical frequency interval Δfu). In the above, the spectrum is sliced into wavelengths (optical frequencies) different from each other, further wavelength-multiplexed, and transmitted to the transmission line on the first input / output end side
The wavelength division multiplexed optical signal inputted from the transmission line on the first input / output end side and having a wavelength interval Δλd (optical frequency interval Δfd) set to be twice or more the wavelength interval Δλu (optical frequency interval Δfu) is demultiplexed. And transmitting the signal to the transmission line on the second input / output end side. A wavelength splitter having a first input / output terminal and a second input / output terminal,
Wavelength multiplexing an optical signal having a wavelength interval Δλu (optical frequency interval Δfu) inputted from the transmission line on the second input / output end, and transmitting the multiplexed signal to the transmission line on the first input / output end;
A wavelength division multiplexed optical signal corresponding to an optical signal having a wavelength interval Δλu (optical frequency interval Δfu) input from the transmission line on the first input / output end and input from the transmission line on the second input / output end is Demultiplexed and supplied to the transmission lines on the second input / output end side,
The wavelength division multiplexed optical signal inputted from the transmission line on the first input / output end side and having a wavelength interval Δλd (optical frequency interval Δfd) set to be twice or more the wavelength interval Δλu (optical frequency interval Δfu) is demultiplexed. A wavelength branching device for supplying the signals to the transmission lines on the second input / output end side. A wavelength splitter having a first input / output terminal and a second input / output terminal,
Wavelength multiplexing an optical signal having a wavelength interval Δλu (optical frequency interval λfu) input from the transmission line on the second input / output end, and transmitting the multiplexed signal to the transmission line on the first input / output end;
An optical signal input from the transmission line on the first input / output end side and having an optical spectrum width twice or more as large as the wavelength interval Δλu (optical frequency interval Δfu) has an optical spectrum width within the wavelength interval Δλu (optical frequency interval Δfu). The spectrum is sliced into wavelengths (optical frequencies) different from each other and supplied to the transmission lines on the second input / output end side, respectively.
The wavelength division multiplexed optical signal inputted from the transmission line on the first input / output end side and having a wavelength interval Δλd (optical frequency interval Δfd) set to be twice or more the wavelength interval Δλu (optical frequency interval Δfu) is demultiplexed. And transmitting the signals to the transmission paths on the second input / output end side. A wavelength splitter having a first input / output terminal and a second input / output terminal,
An optical signal input from the transmission line on the second input / output end side and having an optical spectrum width set to twice or more of Δλu (optical frequency interval Δfu) or more has an optical spectral width of wavelength interval Δλu (optical frequency interval Δfu). Spectral slicing to wavelengths (optical frequencies) different from each other within a wavelength range, further wavelength multiplexing, and sending out to the transmission line on the first input / output end side,
The wavelength division multiplexed optical signal inputted from the transmission line on the first input / output end side and having a wavelength interval Δλd (optical frequency interval Δfd) set to be twice or more the wavelength interval Δλu (optical frequency interval Δfu) is demultiplexed. To the transmission path on the second input / output end side,
An optical signal having an optical spectrum width input from the transmission line on the first input / output end side and having a wavelength twice or more as large as Δλu (optical frequency interval Δfu) is branched to the transmission line on the second input / output end side. A wavelength splitter characterized by transmitting. The wavelength splitter according to claim 13,
It has one coupling port and (n + 1) branching ports, and converts an optical signal input to the coupling port into an equally-spaced wavelength grid (equally-spaced frequency grid) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). A first wavelength branching unit for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) centered on (n + 1) wavelengths (optical frequencies) selected from the following: When,
It has one coupling port and n branch ports, and converts an optical signal input to the coupling port into an equally-spaced wavelength grid (equally-spaced frequency grid) determined by an equal wavelength interval Δλu (optical frequency interval Δfu). A second wavelength branching unit for separating the light into a wavelength region (optical frequency region) within a transmission width ± Δλu / 2 (± Δfu / 2) centered on n kinds of wavelengths (optical frequencies) selected from:
The coupling port of the first wavelength branching unit is connected to the transmission line on the first input / output end side, and the n branch ports of the first wavelength branching unit are connected to the transmission line on the second input / output end side. Respectively, and one other branch port of the first wavelength branching means is connected to a coupling port of the second wavelength branching means, and n branch ports of the second wavelength branching means are A wavelength splitter which is connected to a transmission line on a second input / output end side. The wavelength splitter according to claim 13,
It has one coupling port and (n + 2) branch ports, and converts an optical signal input to the coupling port into an equally-spaced wavelength grid (equally-spaced frequency grid) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). A first wavelength branching means for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) centered on (n + 2) types of wavelengths (optical frequencies) selected from the following: When,
It has one coupling port and m branch ports, and converts an optical signal input to the coupling port into an equidistant wavelength grid (equidistant frequency grid) determined by an equal wavelength interval Δλu (optical frequency interval Δfu). A second wavelength branching means for separating into a wavelength region (optical frequency region) within a transmission width ± Δλu / 2 (± Δfu / 2) centered on m kinds of wavelengths (optical frequencies) selected from:
A third wavelength branching unit similar to the second wavelength branching unit having one coupling port and (nm) branching ports,
The coupling port of the first wavelength branching unit is connected to the transmission line on the first input / output end side, and the n branch ports of the first wavelength branching unit are connected to the transmission line on the second input / output end side. And the other two branch ports of the first wavelength branching means are respectively connected to the respective coupling ports of the second and third wavelength branching means, and the m number of the second wavelength branching means are And the (nm) branch ports of the third wavelength branching means are respectively connected to the transmission line on the second input / output end side. The wavelength splitter according to claim 13,
Wavelength branching / coupling means having one coupling port and two branching ports, and branching / coupling an optical signal between the coupling port and the branching port;
It has one coupling port and n branch ports, and converts an optical signal input to the coupling port into an equidistant wavelength grid (equidistant frequency grid) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). First wavelength branching means for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) centered on n kinds of wavelengths (optical frequencies) selected from:
It has one coupling port and n branch ports, and converts an optical signal input to the coupling port into an equally-spaced wavelength grid (equally-spaced frequency grid) determined by an equal wavelength interval Δλu (optical frequency interval Δfu). A second wavelength branching means for separating into a wavelength region (optical frequency region) within a transmission width ± Δλu / 2 (± Δfu / 2) centered on n kinds of wavelengths (optical frequency) selected from:
A coupling port of the wavelength branching coupling unit is connected to the transmission line on the first input / output end side, and two branch ports of the wavelength branching coupling unit are connected to respective coupling ports of the first and second wavelength branching units. N wavelength ports of the first wavelength branch means are respectively connected to transmission lines on the second input / output end side, and n number of branch ports of the second wavelength branch means are the 2. A wavelength splitter, which is connected to each of the transmission lines on the input / output end side of (2). The wavelength splitter according to any one of claims 14 to 16,
It has one coupling port and (n + 1) branching ports, and converts an optical signal input to the coupling port into an equally-spaced wavelength grid (equally-spaced frequency grid) determined by an equal wavelength interval Δλd (optical frequency interval Δfd). A first wavelength branching unit for separating into a wavelength region (optical frequency region) within a transmission width ± Δλd / 2 (± Δfd / 2) centered on (n + 1) wavelengths (optical frequencies) selected from the following: When,
It has one coupling port and n branch ports, and converts an optical signal input to the coupling port into an equally-spaced wavelength grid (equally-spaced frequency grid) determined by an equal wavelength interval Δλu (optical frequency interval Δfu). Second and third wavelength branching means for separating into wavelength regions (optical frequency regions) within a transmission width ± Δλu / 2 (± Δfu / 2) centered on n kinds of wavelengths (optical frequencies) selected from ,
N wavelength branching / coupling means for coupling / branching an optical signal,
The coupling port of the first wavelength branching unit is connected to the transmission line on the first input / output end side, and the n branch ports of the first wavelength branching unit are connected to the nth branch port via the wavelength branching coupling unit. 2, the other one of the first wavelength branching means is connected to a coupling port of the second wavelength branching means, and the other one of the first wavelength branching means is connected to a coupling port of the second wavelength branching means. N branch ports are respectively connected to the transmission lines on the second input / output end side through the wavelength branching and coupling means, and the n branch ports of the third wavelength branching means are connected to the second input port. The wavelength splitter is connected to the transmission line on the output end side, and the coupling port of the third wavelength splitting means is connected to the transmission line on the first input / output end side. The wavelength splitter according to any one of claims 17 to 19,
N wavelength branching / coupling means for branching / coupling an optical signal between the n branch ports of each of the wavelength branching means and the transmission line on the second input / output end side. Wavelength splitter. The wavelength splitter according to any one of claims 19 to 21,
At least one of the wavelength branching and coupling means is an optical wavelength filter that reflects an optical signal of a predetermined wavelength and transmits an optical signal of another wavelength. The wavelength splitter according to any one of claims 19 to 21,
At least one of the wavelength branching / coupling means is a three-port optical circulator that outputs an optical signal to one optical fiber transmission line and takes in an optical signal input from the one optical fiber transmission line. Wavelength splitter. The wavelength splitter according to any one of claims 19 to 21,
A wavelength splitter, wherein at least one of the wavelength splitting / coupling means is an optical coupler. An optical transmitting and receiving unit including a broad spectrum light source unit for transmitting an optical signal having an optical spectrum width of a wavelength width Δλ (or a frequency width Δf), and an optical receiver for receiving the optical signal;
An electrical processing unit connected to the optical transmitting and receiving unit and performing a predetermined electrical process;
It is arranged at the input / output end of the optical network unit on the transmission path side, and separates the received optical signal corresponding to the optical network unit from all the optical signals input from the transmission path to the optical receiver, and An optical filter means for spectrally slicing a transmission optical signal from the spectrum light source unit at a wavelength width (frequency width) equal to or less than の of the wavelength width Δλ (frequency width Δf) and transmitting the sliced signal to the transmission line. Characteristic optical network unit.   The optical network unit according to claim 25, further comprising an optical connector for detachably attaching the optical filter unit to the optical transmitting / receiving unit. The optical network unit according to claim 25 or 26,
The optical filter means,
An optical signal having a wavelength λsend ± α (α is a wavelength width (frequency width) of 以下 or less of an optical spectrum width Δλ (frequency width Δf)) obtained by a spectrum slice of the transmission optical signal, and at least the reception optical signal. A first wavelength filter that multiplexes / demultiplexes an optical signal having a wavelength range other than λsend ± α, including a wavelength λreceive,
a second wavelength filter for selecting an optical signal of λreceive ± β (β is an arbitrary wavelength width),
The transmission optical signal is transmitted through the first wavelength filter to the transmission line after being spectrally sliced at a wavelength around λ send and simultaneously directionally multiplexed with the optical signal from the transmission line. ,
After an optical signal other than the optical signal transmitted to the transmission line is separated from the optical signal from the transmission line by the first wavelength filter, the light of λreceive ± β is separated by the second wavelength filter. An optical network unit, wherein a signal is separated from other optical signals not related to the optical network unit and output to the optical receiver. The optical network unit according to claim 25 or 26,
The optical filter means,
a first wavelength filter for selecting an optical signal having λsend ± α (α is a wavelength width (frequency width) of 以下 or less of the optical spectrum width Δλ (frequency width Δf));
A second method for multiplexing / demultiplexing an optical signal of λreceive ± β (λreceive is the wavelength of the received optical signal, β is an arbitrary wavelength width) and an optical signal of a wavelength range other than λreceive ± β including at least λsend ± α. With a wavelength filter,
The transmission optical signal is spectrally sliced at a wavelength around λ send via the first wavelength filter, and then direction-multiplexed with the optical signal from the transmission line via the second wavelength filter. And transmitted to the transmission path,
From the optical signal from the transmission line, the second wavelength filter separates the optical signal of λreceive ± β from other optical signals unrelated to the optical network unit and the optical signal transmitted to the transmission line. The optical network unit is output to the optical receiver. A center device (OSU) and a plurality of n optical network units (ONUs) are connected via an optical power splitter and an optical fiber transmission line, and downstream optical signals having different wavelengths from the OSU to the ONUs. And an optical wavelength division multiplexing access system for bidirectional transmission of upstream optical signals having different wavelengths from each of the ONUs to the OSU,
At least in the optical fiber transmission line between each ONU and the OSU, the center wavelength (center frequency) of each upstream optical signal corresponding to each ONU is an equally-spaced wavelength grid determined by equal wavelength intervals Δλu (optical frequency intervals Δfu). (Equally spaced frequency grids), each of which is arbitrarily selected, and its wavelength error (frequency error) is set within ± Δλu / 2 (± Δfu / 2),
Each of the ONUs
An optical transmitting and receiving unit including a broad spectrum light source unit for transmitting an upstream optical signal having an optical spectrum width twice or more the wavelength interval Δλu (Δfu) and an optical receiver for receiving a downstream optical signal;
An electrical processing unit connected to the optical transmitting and receiving unit and performing a predetermined electrical process,
Each of the ONUs is disposed at the input / output end on the optical fiber transmission line side, and among all the downstream optical signals input from the optical fiber transmission line, a downstream optical signal corresponding to each ONU is separated to the optical receiver. And spectrally slicing the upstream optical signal from the broad spectrum light source unit at a wavelength width (frequency width) within a wavelength interval Δλu (frequency interval Δfu) around the center wavelength (center frequency) set for each ONU. An optical wavelength division multiplexing access system, comprising: an optical filter means for transmitting the signal to the optical fiber transmission line.   30. The optical wavelength division multiplexing access system according to claim 29, wherein each of said ONUs further comprises an optical connector for detachably attaching said optical filter means to said optical transceiver. The optical wavelength division multiplexing access system according to claim 29 or 30,
At least between the OSU and each of the ONUs, the center wavelength (center frequency) of each downstream optical signal corresponding to each ONU has an equally-spaced wavelength grid (equally-spaced frequency grid) determined by equal wavelength intervals Δλd (optical frequency intervals Δfd). ) Is arbitrarily selected, and its wavelength error (frequency error) is set within ± Δλd / 2 (± Δfd / 2).
An optical wavelength division multiplexing access system, wherein a wavelength interval Δλd (optical frequency interval Δfd) of the downstream optical signal is set to be twice or more as large as a wavelength interval Δλu (optical frequency interval Δfu) of the upstream optical signal. The optical wavelength division multiplexing access system according to any one of claims 29 to 31,
The wavelength of the downstream optical signal from the OSU to the kth ONU is set to λdk, the wavelength of the upstream optical signal from the kth ONU to the OSU is set to λuk,
The optical filter means of the k-th ONU is:
a first wavelength filter that multiplexes and separates an optical signal of λuk ± α (α is equal to or less than Δλu / 2) and an optical signal of a wavelength range other than λuk ± α, including at least the wavelength λdk;
a second wavelength filter for selecting λdk ± β (β is not more than Δλd / 2),
The upstream optical signal of the ONU is spectrally sliced from the broad-spectrum light source unit through the first wavelength filter at a wavelength around λuk, and simultaneously direction-multiplexed with the downstream optical signal received by the ONU. After being sent to the optical fiber transmission line,
The downstream optical signal of the ONU is separated from the upstream optical signal of the same ONU to be transmitted to the optical fiber transmission line by the first wavelength filter, and then separated by the second wavelength filter. An optical wavelength division multiplexing access system, which is selectively separated from the optical receiver and output to the optical receiver. The optical wavelength division multiplexing access system according to any one of claims 29 to 31,
The wavelength of the downstream optical signal from the OSU to the kth ONU is set to λdk, the wavelength of the upstream optical signal from the kth ONU to the OSU is set to λuk,
The optical filter means of the k-th ONU is:
a first wavelength filter for selecting an optical signal of λuk ± α (α is not more than Δλu / 2);
a second wavelength filter that multiplexes / demultiplexes an optical signal of λdk ± β (β is Δλd / 2 or less) and an optical signal of a wavelength range other than λdk ± β, including at least λuk ± α,
The upstream optical signal of the ONU is spectrally sliced from the broad-spectrum light source unit through the first wavelength filter at a wavelength centered on λuk, and then the ONU is transmitted through the second wavelength filter. After being directionally multiplexed with the downstream optical signal received by the optical fiber transmission line,
The downstream optical signal of the ONU is selectively separated by the second wavelength filter from another downstream optical signal and the upstream optical signal of the same ONU to be transmitted to the optical fiber transmission line, and transmitted to the optical receiver. An optical wavelength division multiplexing access system characterized by being output.

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