JP5900677B1 - COMMUNICATION DEVICE, OPTICAL NETWORK, AND COMMUNICATION METHOD - Google Patents

Abstract

In an optical network using OFDM, a continuous free bandwidth is secured while ensuring a minimum guaranteed bandwidth for each ONU. A communication transmitting apparatus performs communication using a plurality of optical OFDM bands generated in different frequency bands. The center frequency interval of the optical OFDM band transmitted in the adjacent frequency band is set to ½ of the sum of the minimum guaranteed bands set in the optical OFDM band transmitted in the adjacent frequency band. [Selection] Figure 7

Description

  The present invention relates to a communication device, an optical network including the communication device, and a communication method in an optical network using orthogonal frequency division multiplexing (OFDM).

  As an optical access network, a passive optical network (PON) is known. The PON includes one station terminal (OLT: Optical Line Terminal) provided in the station and a plurality of subscriber terminals (ONU: Optical Network Unit) provided in each subscriber house. The OLT and the ONU are connected by an optical fiber via an optical multiplexer / demultiplexer called an optical splitter.

  In PON, signals transmitted from each ONU to the OLT (hereinafter also referred to as upstream signals) are combined by an optical splitter and transmitted to the OLT. On the other hand, a signal (hereinafter also referred to as a downstream signal) sent from the OLT to each ONU is demultiplexed by the optical splitter and transmitted to each ONU. Note that different wavelengths are assigned to the upstream signal and the downstream signal in order to prevent interference between the upstream signal and the downstream signal.

  In PON, various multiplexing techniques are used. The multiplexing technology used in the PON includes time division multiplexing (TDM) technology in which a short interval on the time axis is assigned to each subscriber, wavelength division multiplexing (WDM) in which different wavelengths are assigned to each subscriber (WDM: Wave Division Division Multiplex). And code division multiplexing (CDM) technology that assigns different codes to each subscriber. Among these multiplexing techniques, TDM-PON using TDM is currently most widely used. In TDM-PON, TDMA (Time Division Multiple Access) is used. TDMA is a technique in which the OLT manages the transmission timing of each ONU so that uplink signals from different ONUs do not collide with each other.

A typical PON is GE-PON using Gigabit (1 × 10 ⁹ bits / sec) Ethernet (registered trademark) technology (see, for example, Non-Patent Document 1). In GE-PON, the OLT allocates a frequency band to be used for communication to each connected ONU.

  In GE-PON, for example, a minimum guaranteed bandwidth can be set for each ONU by making a contract or the like in advance. The OLT allocates a frequency band used for communication so that each ONU satisfies at least the minimum guaranteed band. Further, the OLT can allocate the minimum guaranteed bandwidth to each ONU and then distribute the surplus frequency bandwidth to each ONU. A frequency band to be distributed other than the minimum guaranteed band is called a best effort band. The minimum guaranteed bandwidth and the best effort bandwidth can be set for each individual ONU (see, for example, Non-Patent Document 2).

  By the way, in the present optical access network, in addition to the request | requirement of the capacity | capacitance increase of a network by the increase in mobile traffic, the use expansion of moving image content, etc., construction of a highly efficient network is requested | required.

  As a technique for realizing such a network, attention is focused on a network in which a multi-level modulation technique and an orthogonal frequency division multiplexing (OFDM) technique that are widely used in wireless communication are applied to optical fiber transmission.

  OOK (On Off Keying) modulation is so-called binary modulation in which 1-bit data is transmitted in one symbol. On the other hand, multilevel modulation can transmit data of 2 bits or more in one symbol. As multi-level modulation, QPSK (Quadrature Phase Shift Keying), 16QAM (Quadrature Amplitude Modulation), 64QAM, and the like are known.

  The characteristics of multilevel modulation will be described with reference to FIG. 1A to 1D are schematic diagrams for explaining the characteristics of multilevel modulation. 1A to 1D show the wavelength on the horizontal axis.

FIG. 1A shows OOK including 1-bit data in one symbol. FIG. 1B shows QPSK including 2 bits of data in one symbol. FIG. 1C shows 16QAM including 4-bit data in one symbol. FIG. 1D shows 64QAM including 6-bit data in one symbol. QPSK, 16QAM and 64QAM shown in FIGS. 1B to 1D are so-called multilevel modulation, and the number of modulation multilevels increases in the order of QPSK, 16QAM and 64QAM. Note that multilevel modulation is not limited to these, and can be 2 ⁿ QAM (n is an integer of 2 or more). As shown in FIG. 1, when the modulation multi-level number is increased, the wavelength band utilization efficiency (hereinafter also referred to as band utilization efficiency) increases.

  In OFDM, band utilization efficiency can be improved by multicarrier transmission. Multi-carrier transmission will be described with reference to FIG. FIG. 2 is a schematic diagram for explaining multicarrier transmission. FIG. 2 shows the frequency on the horizontal axis. In multicarrier transmission, a plurality of subcarriers having different frequencies can be transmitted in parallel while partially overlapping. Therefore, a highly efficient network can be realized by combining OFDM and the above-described multilevel modulation technique.

  With reference to FIGS. 3A to 3C, the characteristics of optical OFDM will be described. 3A to 3C are schematic diagrams for explaining the characteristics of optical OFDM. 3A to 3C, the horizontal axis indicates the frequency.

  On the transmission side, a baseband signal including a plurality of subcarriers is generated by modulating a bit string as data in the OFDM modulation unit. The subcarriers included in the baseband signal are orthogonal to each other. Thereafter, the optical transmitter generates the optical OFDM band by converting the frequency of the baseband signal to the optical frequency domain (FIG. 3A). This conversion is called up-conversion. Up-conversion is realized by modulating an optical carrier with a baseband signal.

  In communication using one optical fiber, a plurality of optical OFDM bands are generated in different frequency bands according to destinations. By multiplexing a plurality of optical OFDM bands having different bands, the communication efficiency can be improved (FIG. 3B).

  On the receiving side, the optical receiver generates a baseband signal by converting the frequency of the optical OFDM band to the frequency domain of the baseband signal (FIG. 3C). This conversion is called down-conversion. As a technique for realizing down-conversion, there is coherent detection. In coherent detection, an optical OFDM band and a local oscillation light source (LO: Local Oscillator) light are caused to interfere with each other in an optical reception unit, and an interference signal generated thereby is detected. The LO light is set to the same frequency as the optical carrier used in the up-conversion. Thereafter, the OFDM demodulator demodulates the baseband signal to generate a bit string as data.

  In recent years, research and development of an elastic λ aggregation network (EλAN) has attracted attention as a network using a multilevel modulation technique and OFDM (see, for example, Non-Patent Document 3 and Non-Patent Document 4).

  EλAN includes an aggregated OLT in which a plurality of terminal devices are aggregated as an OLT. As the termination device, a logical OLT (L-OLT) is used. In addition, as an ONU, a logical ONU (L-ONU) is provided. A plurality of L-OLTs and a plurality of L-ONUs are connected via an ODN (Optical Distribution Network). In communication between the L-OLT and the L-ONU, OFDM is used. In this case, an optical OFDM band is transmitted as a downstream signal, and a signal in which the optical OFDM band is TDMAd is transmitted as an upstream signal.

  In L-OLT and L-ONU, the modulation multi-level number, the number of subcarriers, the symbol rate, and the wavelength are variable. These parameters may be collectively referred to as optical signal parameters. As described above, when the modulation multi-level number is set large, the utilization efficiency of the wavelength band increases. Further, if the number of subcarriers is set to be small, the frequency utilization efficiency is increased. Also, if the symbol rate is set low, the frequency utilization efficiency increases. The aggregation OLT sets the optical signal parameter of each L-OLT. Each L-OLT generates an optical OFDM band as a downlink signal with the set optical signal parameter, and transmits it to the L-ONU. The L-ONU generates and transmits an optical OFDM band as an upstream signal with the optical signal parameters specified by the L-OLT. In EλAN, for example, one of QPSK, 16QAM, and 64QAM is selected to generate an optical OFDM band.

“Technology Basic Course GE-PON Technology 2nd IEEE 802.3ah Standard” NTT Technical Journal 2005.9 Hirao Tsuyoshi et al. “Trends in Broadband Optical Access Technology” NTT Technology Journal Satoshi Okamoto “Retractable Optical Metro / Access Fusion Aggregation Network Technology for Realizing Various Services and Network Configurations-Elastic λ Aggregation Network-” IEICE Technical Report CS2012-96 Tetsuhei Yamaguchi et al. “A Study on TDM Network with Multiple OLTs Cooperating in Elastic Optical Aggregation Network” IEICE Technical Report

  In EλAN, the bandwidth of the frequency occupied by the optical OFDM band can be expanded and contracted by optimizing the optical signal parameters according to the traffic situation of the network. Therefore, a bandwidth having a width corresponding to each traffic can be allocated to each L-ONU.

  With reference to FIG. 4 and FIG. 5, bandwidth allocation to the ONU in the conventional communication method will be described. Here, an example in which the OLT (aggregation OLT) registers four ONUs (L-ONU) -1 to 4 will be described. FIG. 4 is a diagram showing the minimum guaranteed bandwidth allocated in advance to each ONU at the bit rate. 5A and 5B are diagrams illustrating optical OFDM bands used by each ONU for communication, and the horizontal axis indicates the frequency.

  The OLT sets four different center frequencies and assigns a band to be used for communication of each ONU. The OLT and each ONU perform communication by generating an optical OFDM band in a band assigned to each ONU.

  Here, in the example shown in FIG. 5A, each ONU is set to be able to communicate at a maximum bit rate of 50 Gbps. In this case, the center frequency interval between the adjacent optical OFDM bands (hereinafter also simply referred to as the center frequency interval) is set to 50 / α [GHz], respectively. Α is a coefficient for converting the bit rate into a frequency, and its unit is [bps / Hz]. When the center frequency interval is set in this way, in the time zone in which the traffic of each ONU has a margin, the minimum guaranteed bandwidth, which is the minimum allocated bandwidth, may be allocated to each ONU. When a bandwidth is allocated to each ONU with a width that satisfies the minimum guaranteed bandwidth, an empty bandwidth is created between the optical OFDM bands as shown in FIG. Therefore, this free bandwidth can be used by other systems.

  However, in the communication method using the conventional band allocation shown in FIG. 5A, the vacant band is divided by the optical OFDM band. Therefore, it is difficult to use a free band for a system that requires a large continuous band.

  Here, in order to secure a large continuous free band, it is conceivable to reduce the center frequency interval. For example, as shown in FIG. 5B, the center frequency interval of the optical OFDM band of each ONU is reduced to 25 / α [GHz]. FIG. 5 is a diagram showing an optical OFDM band when the center frequency interval is set to 25 / α [GHz] in each ONU communication shown in FIG. 4. In FIG. 5B, the horizontal axis indicates the frequency. As shown in FIG. 5B, a continuous free band can be secured on the high frequency side by setting the center frequency interval equally small and packing each optical OFDM band on the low frequency side.

  However, when the center frequency interval is set to be evenly small, ONUs to which the minimum guaranteed bandwidth cannot be assigned may occur. In the example shown in FIG. 5B, the minimum guaranteed bandwidth cannot be assigned to ONU-2 and 4 as a result of setting the center frequency interval to 25 / α [GHz].

  The present invention has been made in view of the above-described problems, and an object of the present invention is to secure a continuous free bandwidth while securing the minimum guaranteed bandwidth of each ONU in an optical network using OFDM. It is to provide a communication apparatus such as a station terminal, an optical network, and a communication method.

  In order to achieve the above object, a communication apparatus used in an optical network using OFDM according to the present invention has the following features.

Communication apparatus of the present invention is produced in different frequency bands, and performs communication using a plurality of optical OFDM band fixed center frequency, respectively Ru is set. For example, the communication apparatus of the present invention performs transmission / reception by WDM the optical OFDM band. The center frequency interval of the optical OFDM band transmitted in the adjacent frequency band is set to ½ of the sum of the minimum guaranteed bands set in the optical OFDM band transmitted in the adjacent frequency band.

  The optical network of the present invention has the following features. In other words, the optical network of the present invention includes the OLT that is the communication device described above and a plurality of ONUs connected to the OLT.

  The communication method in the optical network using OFDM according to the present invention has the following features.

The communication method of the present invention, is generated in different frequency bands, and performs communication using a plurality of optical OFDM band fixed center frequency, respectively Ru is set. For example, in the communication method of the present invention, transmission / reception is performed by WDM the optical OFDM band. The center frequency interval of the optical OFDM band transmitted in the adjacent frequency band is set to ½ of the sum of the minimum guaranteed bands set in the optical OFDM band transmitted in the adjacent frequency band.

  In the communication apparatus, optical network, and communication method of the present invention, the center frequency interval of the optical OFDM bands transmitted in adjacent frequency bands is set to ½ of the sum of the minimum guaranteed bands set in these optical OFDM bands. Is done. Therefore, an ONU that performs communication using each optical OFDM band can reliably secure the minimum guaranteed bandwidth. Then, by arranging the optical OFDM bands so as to be close to the low frequency side, it is possible to secure a continuous free band on the high frequency side. Therefore, in the communication apparatus, the optical network, and the communication method according to the present invention, it is possible to secure a continuous free bandwidth while securing the minimum guaranteed bandwidth of each ONU.

(A)-(D) are the schematic diagrams for demonstrating the characteristic of multi-value modulation. It is a schematic diagram for demonstrating multicarrier transmission. (A)-(C) are the schematic diagrams for demonstrating the characteristic of OFDM. It is a figure explaining the conventional communication method, and is a figure which shows the minimum guarantee zone | band of ONU. (A) And (B) is a figure explaining the conventional communication method, and is a figure which shows the optical OFDM band which ONU uses for communication. It is a schematic diagram for demonstrating an optical access network. It is a figure explaining the communication method by embodiment of this invention, and is a figure which shows the optical OFDM band which ONU uses for communication. It is a figure explaining the communication method by a reference example. (A) is a figure which shows the minimum guarantee band and maximum allocatable band of ONU, (B) and (C) are figures which show the optical OFDM band which ONU uses for communication. It is a figure explaining the communication method by embodiment of this invention. (A) is a figure which shows the minimum guarantee band and maximum allocatable band of ONU, (B) and (C) are figures which show the optical OFDM band which ONU uses for communication. It is a figure explaining the communication method by embodiment of this invention. (A) is a figure which shows the minimum guarantee band and maximum allocatable band of ONU, (B) is a figure which shows the optical OFDM band which ONU uses for communication. It is a figure explaining the communication method by the modification of this invention. (A) is a figure which shows the minimum guarantee band and maximum allocatable band of ONU, (B) is a figure which shows the optical OFDM band which ONU uses for communication.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the drawings are merely schematically shown to the extent that the present invention can be understood. In the following, a preferred configuration example of the present invention will be described. However, numerical conditions and the like are merely preferred examples. Therefore, the present invention is not limited to the following embodiments, and many changes or modifications that can achieve the effects of the present invention can be made without departing from the scope of the configuration of the present invention.

(Optical access network)
The communication device according to this embodiment can be used as a station terminal in an optical access network, for example. Therefore, in this embodiment, a case will be described in which the communication device according to this embodiment is used as a station terminal in an optical access network.

  An optical access network will be described with reference to FIG. FIG. 6 is a schematic diagram for explaining the optical access network. In FIG. 6, EλAN configured similarly to that disclosed in Non-Patent Document 3 is shown as an example of an optical access network.

  The EλAN 10 includes a station terminal (OLT) 20, an ODN 40, and N subscriber terminals (ONUs) 30-1 to 30-N, which are communication apparatuses according to this embodiment. The OLT 20 is configured as an aggregation OLT that aggregates the M terminal devices 22-1 to M-2. The termination devices 22-1 to M and the ONUs 30-1 to N are connected via the ODN 40.

  In EλAN10, L-OLT is used as the terminating devices 22-1 to M and L-ONUs are used as the ONUs 30-1 to N in order to allow the service to be provided to be changed in a programmable manner. In EλAN10, the L-OLT 22 to which the L-ONU 30 is registered, that is, the pair of the L-ONU 30 and the L-OLT 22 is freely changed.

  In EλAN10, a multi-level modulation technique and OFDM are used in combination. That is, as a subcarrier of the OFDM signal, for example, a signal that has been subjected to multilevel modulation using any one of QPSK, 16QAM, and 64QAM is transmitted and received.

  Further, the aggregation OLT 20 includes a management unit 25. The L-OLTs 22-1 to 2 -M communicate with the corresponding L-ONUs 30-1 to 30 -N using optical OFDM bands of different frequency bands. Based on the traffic information sent from the L-OLT 22, the management unit 25 assigns a frequency band of the optical OFDM band to be used in communication with the L-ONUs 30-1 to 30-N corresponding to the L-OLTs 22-1-M. The L-OLTs 22-1 to 2 -M communicate with the corresponding L-ONUs 30-1 to 30 -N using the optical OFDM band of the frequency band specified by the management unit 25.

  The aggregation OLT 20 distributes the downlink data received from the upper network to the L-OLTs 22-1 to M-2 according to the destination. The L-OLTs 22-1 to 2 -M generate an optical OFDM band based on the downlink data and send it to the corresponding L-ONUs 30-1 to 30 -N. On the other hand, the L-ONUs 30-1 to 30-N generate an optical OFDM band based on the uplink data received from the user terminal, and transmit the optical OFDM bands to the registration destination L-OLTs 22-1 to 22-M. The optical OFDM bands generated by the L-ONUs 30-1 to 30-N are generated in different frequency bands for each ONU. The frequency band of the optical OFDM band generated by the L-ONUs 30-1 to 30-N is set based on instructions from the registration destination L-OLTs 22-1 to 22-M.

(Communication method)
The communication method according to this embodiment will be described with reference to FIG. In FIG. 7, the horizontal axis shows the frequency. The communication method according to this embodiment is controlled by, for example, a management unit of an OLT (here, an aggregate OLT).

  In this example, an example in which the OLT communicates with four ONUs (here, L-ONUs) will be described. The optical OFDM band used for communication with ONU-1 is up-converted with an optical carrier having a frequency f1, and the center frequency is set to f1. The optical OFDM band used for communication with ONU-2 is up-converted with an optical carrier having a frequency f2, and the center frequency is set to f2. The optical OFDM band used for communication with ONU-3 is up-converted with an optical carrier having a frequency f3, and the center frequency is set to f3. The optical OFDM band used for communication with ONU-4 is up-converted with an optical carrier having a frequency f4, and the center frequency is set to f4. It is assumed that the minimum guaranteed bandwidth shown in FIG. 4A is set in advance in the ONUs 1 to 4.

  In this embodiment, the center frequency intervals Δfa to Δfc of adjacent optical OFDM bands are set to ½ of the sum of the minimum guaranteed bands set for these adjacent optical OFDM bands. Here, the center frequency interval Δfa between the ONU-1 optical OFDM band whose minimum guaranteed bandwidth is 10 Gbps and the ONU-2 optical OFDM band whose minimum guaranteed bandwidth is 40 Gbps is set to 25 / α [GHz]. The Further, the center frequency interval Δfb between the ONU-2 optical OFDM band whose minimum guaranteed bandwidth is 40 Gbps and the ONU-3 optical OFDM band whose minimum guaranteed bandwidth is 20 Gbps is set to 30 / α [GHz]. . The center frequency interval Δfc between the ONU-3 optical OFDM band with a minimum guaranteed bandwidth of 20 Gbps and the ONU-4 optical OFDM band with a minimum guaranteed bandwidth of 30 Gbps is set to 25 / α [GHz]. . Thus, by setting the center frequency intervals Δfa to Δfc, the minimum guaranteed bandwidth of each ONU can be secured.

  In the example of FIG. 7, all the ONUs 1 to 4 are in the activated state, and each indicates a time zone during which communication is performed. In this case, the minimum guaranteed bandwidth is assigned to each of the ONUs 1 to 4. Therefore, the bandwidths P and Q (P and Q are positive real numbers) of optical OFDM bands transmitted in adjacent frequency bands are set such that P / 2 + Q / 2 is the center frequency interval.

  On the other hand, in a time zone including ONUs 1 to 4 in which the ONUs 1 to 4 do not perform communication and are in the sleep state, only the control band is assigned to the ONU in the sleep state, not the minimum guaranteed bandwidth. Then, a band obtained by subtracting the control band from the minimum guaranteed band of the ONU in the sleep state becomes a free band. Using this vacant bandwidth, it is possible to allocate a best effort bandwidth to an activated ONU that is placed between the sleep ONUs. In this case, bandwidths P and Q (P and Q are positive real numbers) of optical OFDM bands transmitted in adjacent frequency bands are set so that P / 2 + Q / 2 is equal to or less than the center frequency interval. . Accordingly, interference between adjacent optical OFDM bands is prevented.

  In this embodiment, the optical OFDM bands are arranged close to the low frequency side. As a result, a continuous free band can be secured on the high frequency side.

  As described above, in the communication method according to this embodiment, it is possible to secure a continuous free bandwidth while securing the minimum guaranteed bandwidth of each ONU.

(Optical OFDM band arrangement)
In the communication method according to this embodiment described above, the arrangement of optical OFDM bands can be optimized. Hereinafter, the arrangement of the optical OFDM band will be described.

  First, a reference example of the arrangement of optical OFDM bands will be described with reference to FIG. In this reference example, an example will be described in which an OLT (here, an aggregate OLT) communicates with six ONUs (here, L-ONUs). It is assumed that the minimum guaranteed bandwidth indicated by the bit rate in FIG.

  8B and 8C are diagrams for explaining the arrangement of the optical OFDM band of the reference example, and the horizontal axis indicates the frequency. The optical OFDM band used for communication with ONU-1 is up-converted with an optical carrier having a frequency f1, and the center frequency is set to f1. The optical OFDM band used for communication with ONU-2 is up-converted with an optical carrier having a frequency f2, and the center frequency is set to f2. The optical OFDM band used for communication with ONU-3 is up-converted with an optical carrier having a frequency f3, and the center frequency is set to f3. The optical OFDM band used for communication with ONU-4 is up-converted with an optical carrier having a frequency f4, and the center frequency is set to f4. The optical OFDM band used for communication with ONU-5 is up-converted with an optical carrier having a frequency f5, and the center frequency is set to f5. The optical OFDM band used for communication with ONU-6 is up-converted with an optical carrier having a frequency f6, and the center frequency is set to f6. The center frequency interval between adjacent optical OFDM bands is set in the same manner as the communication method according to this embodiment described above.

  In the reference example, the optical OFDM bands are arranged in the order of ONU-1, ONU-2, ONU-3, ONU-4, ONU-5, and ONU-6 from the low frequency side (FIG. 8B).

  Here, consider a time zone in which some of the ONUs 1 to 6 are in the sleep state and are not communicating (FIG. 8C). In the example of FIG. 8C, ONU-1, 3, 4, and 6 are in the sleep state.

  For example, a band of 1 / α [GHz] is assigned to the ONUs 1, 3, 4, and 6 in the sleep state as a control band. A band obtained by subtracting the control band from the minimum guaranteed band remains as an empty band.

  In addition to the minimum guaranteed bandwidth, the best effort bandwidth is allocated to the ONUs 2 and 5 that perform communication using this free bandwidth. A free band between adjacent ONUs 1 and 3 is assigned to ONU-2 as a best effort band. The ONU-5 is assigned a free band between the adjacent ONUs 4 and 6 as the best effort band.

  Assuming that the center frequency of the optical OFDM band of each ONU is constant, there is a free band of 3.5 / α [GHz] between ONU-5 and ONU-4 and 6, respectively. Therefore, in addition to the minimum guaranteed bandwidth of 2 / α [GHz], the best effort bandwidth of 7 / α [GHz] can be allocated to ONU-5. Therefore, the maximum allocatable bandwidth for ONU-5 is 9 / α [GHz].

  On the other hand, there is a free band of 3.5 / α [GHz] between ONU-1 and ONU-2. However, there is only a free band of 0.5 / α [GHz] between ONU-2 and ONU-3. Therefore, in addition to the minimum guaranteed bandwidth of 2 / α [GHz], only the best effort bandwidth of 1 / α [GHz] can be assigned to ONU-2. Therefore, the maximum allocatable bandwidth for ONU-2 is 3 / α [GHz].

  Thus, depending on the arrangement of the optical OFDM band, the assignable best effort band differs for each ONU. Therefore, as shown by the bit rate in FIG. 8A, in the reference example, the maximum allocatable bandwidth varies among the ONUs.

  As described above, when down-converting the optical OFDM band, it is necessary to set the LO light to be used to the same frequency as the optical carrier used in the up-conversion. Therefore, in order to change the center frequency of the optical OFDM band of each ONU, it is necessary to change the frequency of the LO light. Since a certain time is required to change the frequency of the LO light, the communication is stopped during that time, and the communication efficiency is deteriorated. Therefore, it is not preferable to change the center frequency of the optical OFDM band of each ONU.

  Therefore, in this embodiment, the optical OFDM band is arranged so that the assignable best effort band can be set fairly with the center frequency of the optical OFDM band of each ONU being constant.

  With reference to FIG. 9, the arrangement of optical OFDM bands in this embodiment will be described. In this example, an example will be described in which an OLT (here, an aggregate OLT) communicates with six ONUs (here, L-ONUs). It is assumed that the minimum guaranteed bandwidth indicated by the bit rate in FIG.

  FIGS. 9B and 9C are diagrams for explaining the arrangement of the optical OFDM bands in this embodiment, and the horizontal axis indicates the frequency. The optical OFDM band used for communication with ONU-1 is up-converted with an optical carrier having a frequency f1, and the center frequency is set to f1. The optical OFDM band used for communication with ONU-2 is up-converted with an optical carrier having a frequency f2, and the center frequency is set to f2. The optical OFDM band used for communication with ONU-3 is up-converted with an optical carrier having a frequency f3, and the center frequency is set to f3. The optical OFDM band used for communication with ONU-4 is up-converted with an optical carrier having a frequency f4, and the center frequency is set to f4. The optical OFDM band used for communication with ONU-5 is up-converted with an optical carrier having a frequency f5, and the center frequency is set to f5. The optical OFDM band used for communication with ONU-6 is up-converted with an optical carrier having a frequency f6, and the center frequency is set to f6. The center frequency interval between adjacent optical OFDM bands is set in the same manner as the communication method according to this embodiment described above.

  In this embodiment, the optical OFDM band is arranged so that the sum of the bandwidths of two adjacent optical OFDM bands becomes a value close to twice the average of the minimum guaranteed bandwidth set for all optical OFDM bands. . Here, the average of the minimum guaranteed bandwidth of the all-optical OFDM band is 5 / α [Hz] as the frequency band. Therefore, the optical OFDM bands are arranged so that the sum of the bandwidths of the adjacent optical OFDM bands becomes a value close to 10 / α [Hz]. In the example of FIG. 9B, the optical OFDM bands are arranged in the order of ONU-1, ONU-2, ONU-4, ONU-3, ONU-6, and ONU-5 from the low frequency side. As a result, the sum of the bandwidths is 10 / α [Hz]. As a result, the center frequency interval between the adjacent optical OFDM bands becomes equal. By arranging in this way, the best effort band that can be allocated to each ONU can be set fairly.

  For example, as shown in FIG. 9C, in the time zone in which the ONUs 1 and 4 to 6 are in the sleep state, the ONUs 2 and 3 are in addition to the minimum guaranteed bandwidth of 2 / α [GHz]. , 7 / α [GHz] can be allocated. Therefore, the maximum allocatable bandwidth for ONU-2 and 3 is 9 / α [GHz]. Note that a band of 1 / α [GHz] is assigned to the ONUs 1 and 4 to 6 in the sleep state as a control band.

  Thus, in the arrangement of the optical OFDM band in this embodiment, the assignable best effort band is fair in each ONU. Therefore, the maximum allocatable bandwidth of each ONU can be set fairly, as shown by the bit rate in FIG. 9A, while securing a continuous free bandwidth on the high frequency side.

  Here, a case has been described in which the minimum guaranteed bandwidth of the optical OFDM band is two types of 2 Gbps and 8 Gbps. However, even when there are three or more types of minimum guaranteed bandwidths for the optical OFDM band, the maximum allocatable bandwidth for each ONU can be set equally.

  As an example, the arrangement of optical OFDM bands when there are four types of minimum guaranteed bands will be described with reference to FIG. In this example, an example will be described in which an OLT (here, an aggregate OLT) communicates with six ONUs (here, L-ONUs). In the ONUs 1 to 6, it is assumed that the minimum guaranteed bandwidth indicated by the bit rate in FIG.

  In the example of FIG. 10, a value twice the average of the minimum guaranteed bandwidth of the all-optical OFDM band is approximately 10.7 / α [GHz] as the frequency band. Therefore, the optical OFDM bands are arranged so that the sum of the bandwidths of the adjacent optical OFDM bands becomes a value close to 10.7 / α [GHz]. In the example of FIG. 10B, the optical OFDM bands are arranged in the order of ONU-1, ONU-5, ONU-3, ONU-4, ONU-6, and ONU-2 from the low frequency side. As a result, the sum of the bandwidths becomes a neighboring value of 10.7 / α [GHz]. As a result, the center frequency interval between the adjacent optical OFDM bands becomes substantially equal. By arranging in this way, it is possible to set the best effort band that can be allocated to each ONU almost fairly, while ensuring a continuous free band on the high frequency side. Therefore, as shown by the bit rate in FIG. 10A, the maximum allocatable bandwidth of each ONU can be set almost fairly.

(Modification)
In the above-described embodiment, the communication method in which the optical OFDM band is arranged so that the maximum allocatable bandwidth of each ONU is fair has been described. However, the arrangement of the optical OFDM band is not limited to this. Normally, it is considered that the user bears a cost proportional to the size of the minimum guaranteed bandwidth for the minimum guaranteed bandwidth set by a contract or the like. Therefore, it is conceivable to preferentially set the maximum allocatable bandwidth of an ONU having a large minimum guaranteed bandwidth. Therefore, in this modification, the maximum allocatable bandwidth is set corresponding to the size of the minimum guaranteed bandwidth. This example will be described with reference to FIG. In this example, an example will be described in which an OLT (here, an aggregate OLT) communicates with six ONUs (here, L-ONUs). It is assumed that the minimum guaranteed bandwidth indicated by the bit rate in FIG.

  When setting the maximum allocatable bandwidth corresponding to the size of the minimum guaranteed bandwidth, the optical OFDM bands are arranged on the frequency axis in descending order of the minimum guaranteed bandwidth. In the example of FIG. 11B, the optical OFDM bands are arranged in the order of the smallest guaranteed bandwidth from the low frequency side in the order of ONU-1, ONU-3, ONU-4, ONU-6, ONU-2 and ONU-5. It is arranged.

  By arranging the optical OFDM band in this way, while ensuring a continuous free band on the high frequency side, as shown by the bit rate in FIG. 11A, for an ONU in which the minimum guaranteed band is set large. A large maximum allocatable bandwidth can be set.

10: EλAN
20: Station building terminal (aggregation OLT)
22: Termination device (L-OLT)
30: Subscriber terminal (L-ONU)
40: ODN

Claims (11)

A communication device used in an optical network using Orthogonal Frequency Division Multiplexing (OFDM),
It is generated in different frequency bands, and performs communication using a plurality of optical OFDM band fixed center frequency, respectively Ru is set,
The center frequency interval of the optical OFDM band transmitted in the adjacent frequency band is set to ½ of the sum of the minimum guaranteed bands set in the optical OFDM band transmitted in the adjacent frequency band. A communication device. The optical OFDM band is arranged so that the sum of the bandwidths of the optical OFDM bands transmitted in the adjacent frequency bands is close to twice the average of the minimum guaranteed bands set for all optical OFDM bands. The communication apparatus according to claim 1. 2. The communication apparatus according to claim 1, wherein optical OFDM bands are arranged on the frequency axis in descending order of the set minimum guaranteed bandwidth. The bandwidths P and Q (P and Q are positive real numbers) of optical OFDM bands transmitted in the adjacent frequency bands are set such that P / 2 + Q / 2 is equal to or less than the center frequency interval. The communication device according to any one of claims 1 to 3. A station terminal, and a plurality of subscriber terminals connected to the station terminal,
An optical network, wherein the station terminal is the communication device according to any one of claims 1 to 4. In an optical network using Orthogonal Frequency Division Multiplexing (OFDM),
It is generated in different frequency bands, and performs communication using a plurality of optical OFDM band fixed center frequency, respectively Ru is set,
The center frequency interval of the optical OFDM band transmitted in the adjacent frequency band is set to ½ of the sum of the minimum guaranteed bands set in the optical OFDM band transmitted in the adjacent frequency band, Communication method. Arranging the optical OFDM bands so that the sum of the bandwidths of the optical OFDM bands transmitted in the adjacent frequency bands is close to twice the average of the minimum guaranteed bands set for all optical OFDM bands. The communication method according to claim 6. The communication method according to claim 6, wherein the optical OFDM bands are arranged on the frequency axis in descending order of the set minimum guaranteed bandwidth. The bandwidths P and Q (P and Q are positive real numbers) of optical OFDM bands transmitted in the adjacent frequency bands are set so that P / 2 + Q / 2 is equal to or less than the center frequency interval. The communication method as described in any one of Claims 6-8. A communication device used in an optical network using Orthogonal Frequency Division Multiplexing (OFDM),
Wavelength division multiplexing (WDM: Wavelength Division Multiplex) is used to transmit and receive optical OFDM bands.
Each optical OFDM band has a fixed center frequency,
A communication apparatus, wherein a center frequency interval between adjacent optical OFDM bands is set to ½ of a sum of minimum guaranteed bands set in an optical OFDM band transmitted in the adjacent frequency band. In an optical network using Orthogonal Frequency Division Multiplexing (OFDM),
Wavelength division multiplexing (WDM: Wavelength Division Multiplex) is used to transmit and receive optical OFDM bands.
Each optical OFDM band has a fixed center frequency,
A communication method characterized in that the center frequency interval between adjacent optical OFDM bands is set to ½ of the sum of the minimum guaranteed bands set in the optical OFDM bands transmitted in the adjacent frequency bands.

Images