JP2016046646A - Olt, onu, pon system, and transmission method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To implement high band use efficiency in a PON system, in transmitting a digital RoF signal.SOLUTION: An OLT comprises: a CPRI reception unit 102 for receiving, from a BBU, a frame including a control message in which user data presence/absence information showing whether or not user data is included is written; a CPRI queue 106 and a queue control unit 107 for referring to user data presence/absence information in a control message to output a frame including user data without changing the frame or to discard a data part of a frame including no user data before outputting the frame including the control message; and a PON transmission unit 112 for transmitting, to an ONU, a transmission frame obtained by adding queue control information including user data presence/absence information and a frame number of a received frame to a frame output from the CPRI queue 106.SELECTED DRAWING: Figure 4

Description

  The present invention is applied to a passive optical network (PON) system, and an OLT (Optical Line Terminal) dynamically allocates an upstream communication band to at least one ONU (Optical Network Unit). The present invention relates to a technique for transmitting a digital RoF (Radio over Fiber) signal.

  In recent years, a passive optical network (PON) system in which one optical transmission line is shared by a plurality of subscribers is widely used as an access line. In the PON system, one optical transmission line terminal (OLT: Optical Line Terminal) installed at a telecommunications carrier's station connects to multiple subscriber-side terminals (ONU: Optical Network Unit) via an optical splitter. Has been. The OLT achieves high bandwidth utilization efficiency by dynamically allocating an upstream bandwidth to a plurality of ONUs using a time division multiplexing method.

  On the other hand, in recent years, a demand for transmitting a digital RoF (Radio over Fiber) signal obtained by digitizing amplitude information of an analog signal has increased, and it has already been widely used as a line for transmitting the digital RoF signal. PON system is a candidate. As an example of a typical digital RoF signal, a signal that flows between a baseband unit (BBU) and a remote radio head (RRH) in a mobile radio system can be cited. There is a signal format defined by Common Public Radio Interface.

  Patent Document 1 discloses an optical wireless access system in which the function of a base station that transmits and receives wireless signals to and from a wireless terminal is divided into one BBU and a plurality of wireless devices RRU (Remote Radio Unit). This optical wireless access system is connected to a PON system that performs RoF transmission using an optical signal between a BBU and an RRU, an ONU function that transmits and receives an optical signal at a predetermined wavelength, and an RRU that accommodates a mobile terminal. An OLT function that transmits and receives an optical signal to and from the ONU using a wavelength assigned to the ONU is provided. Then, an optical signal is transmitted and received between the OLT function and the plurality of ONU functions using a wavelength multiplexing method.

JP, 2014-110574, A

  A system for transmitting a digital RoF signal using the PON system as described above is shown in FIG. 12, for example. In FIG. 12, the OLT 120 is connected to a digital RoF signal transmission device 121 and the Internet 122. The OLT 120 is connected to a plurality of ONUs 124-1 to 124-n via the optical branching device 123, and constitutes a PON system. For example, a general user 125 who enjoys broadband service and a digital RoF signal transmission device 126 are connected to the plurality of ONUs 124-1 to 124-n.

  In the PON system, each of the ONUs 124-1 to 124-n declares a necessary bandwidth to the OLT 120, and the OLT 120 allocates a bandwidth in the uplink direction based on the declaration, and a dynamic bandwidth allocation (DBA: Dynamic Bandwidth Allocation). Is used. Usually, since the bandwidth required for data communication fluctuates irregularly with time, the PON system achieves high bandwidth utilization efficiency by using DBA.

  On the other hand, since the digital RoF signal is obtained by digitizing the amplitude information of the analog signal, it is transmitted as continuous digital data regardless of whether or not the analog signal includes user data. That is, when transmitting a digital RoF signal on the PON system, it is necessary to always allocate a certain band to the ONU that transmits the digital RoF signal, even when user data is not included. This will reduce the bandwidth utilization efficiency.

  The present invention has been made in view of such circumstances, and in the PON system, when transmitting the digital RoF signal by transferring the digital RoF signal to the PON system only when user data exists, An object of the present invention is to provide an OLT, an ONU, a PON system, and a transmission method that can realize high band utilization efficiency on the PON system.

  (1) In order to achieve the above object, the present invention takes the following measures. That is, the OLT of the present invention is applied to a PON (Passive Optical Network) system, and dynamically allocates an upstream communication band to at least one ONU (Optical Network Unit), thereby providing a digital RoF (Radio over Fiber). An OLT (Optical Line Terminal) that transmits a signal, and an OLT frame receiving unit that receives a frame having a control message in which user data presence / absence information indicating whether or not user data is included is written from a BBU (BaseBand Unit) OLT control unit that refers to the user data presence / absence information in the control message and outputs the frame including the user data as it is, discards the data portion of the frame not including the user data, and outputs the frame having the control message And the frame number of the received frame in the frame output from the control unit. And characterized in that it comprises a OLT transmitting unit that transmits a transmission frame including user data existence information in ONU, the.

  As described above, since the data portion of the frame not including the user data is discarded, it is possible to improve the band use efficiency in the downstream PON section when transmitting the digital RoF signal in the PON system.

  (2) Further, the OLT of the present invention is applied to a PON (Passive Optical Network) system, and dynamically allocates an upstream communication band to at least one ONU (Optical Network Unit), and performs digital RoF (Radio). an OLT (Optical Line Terminal) for transmitting an over fiber signal, and an OLT receiving unit that receives a transmission frame including user data presence / absence information indicating whether or not to include a frame number and user data from the ONU; While referring to the frame number and user data presence / absence information from the received transmission frame, a frame including user data is recreated and output as a frame including user data and a control message, while a predetermined idle is set to a frame not including user data. Insert a pattern and include the default idle pattern and control message And the OLT controller for outputting remake the frame, characterized in that it comprises, and the OLT frame transmitting unit that transmits the recreated frame to BBU (BaseBand Unit).

  As described above, since the data portion of the frame that does not include user data is discarded, it is possible to improve the band utilization efficiency in the upstream PON section when transmitting a digital RoF signal in the PON system.

  (3) Further, the ONU of the present invention is applied to a PON (Passive Optical Network) system, and an upstream communication band is dynamically allocated from an OLT (Optical Line Terminal), and a digital RoF (Radio over Fiber) signal is transmitted. An ONU (Optical Network Unit) for transmitting an ONU receiving unit that receives a transmission frame including user data presence / absence information indicating whether or not to include a frame number and user data from the OLT, and the received transmission unit The frame number and user data presence / absence information are referred to from the frame, and a frame including user data is regenerated into a frame including user data and a control message, while a predetermined idle pattern is inserted into a frame not including user data, Recreate the frame containing the default idle pattern and control message And an ONU controller for outputting Te, characterized in that it comprises, and the ONU a frame transmitting unit for transmitting the recreated frame in RRH (Remote Radio Head).

  As described above, since an idle pattern can be inserted into the data portion of a frame that does not include user data and the frame can be reproduced, in the PON system, when transmitting a digital RoF signal, the bandwidth utilization efficiency in the downstream PON section Can be improved.

  (4) Further, the ONU of the present invention is applied to a PON (Passive Optical Network) system, and an upstream communication band is dynamically assigned from an OLT (Optical Line Terminal), and a digital RoF (Radio over Fiber) signal is transmitted. An ONU (Optical Network Unit) for transmitting an ONU frame receiving unit that receives a frame having a control message in which user data presence / absence information indicating whether or not user data is included is written from an RRH (Remote Radio Head) An OLT control unit that refers to user data presence / absence information in the control message and outputs a frame including the user data as it is, discards a data portion of the frame not including the user data, and outputs a frame having the control message; , The frame number of the received frame and the user in the frame output from the control unit And an ONU transmission unit that transmits a transmission frame including data presence / absence information to the OLT.

  As described above, since the data portion of the frame that does not include user data is discarded, it is possible to improve the band utilization efficiency in the upstream PON section when transmitting a digital RoF signal in the PON system.

  (5) Moreover, the PON system of this invention is provided with OLT as described in said (1), and ONU as described in said (3).

  With this configuration, since the data portion of the frame that does not include user data is discarded, it is possible to improve the bandwidth utilization efficiency in the upstream PON section when transmitting a digital RoF signal in the PON system.

  (6) Further, the PON system of the present invention includes the OLT described in (2) above and the ONU described in (4) above.

  With this configuration, since the data portion of the frame that does not include user data is discarded, it is possible to improve the bandwidth utilization efficiency in the downstream PON section when transmitting a digital RoF signal in the PON system.

  (7) The transmission method of the present invention is a transmission method of a digital RoF (Radio over Fiber) signal in a PON (Passive Optical Network) system, and whether or not user data is included from a BBU (BaseBand Unit). Transmitting a frame having a control message in which user data presence / absence information is written to an OLT (Optical Line Terminal), and referring to the user data presence / absence information in the control message in the OLT, the frame including the user data is left as it is. On the other hand, the data part of the frame that does not include user data is discarded, a frame having a control message is output, and the output frame includes the frame number of the received frame and user data presence / absence information in the output frame To the ONU (Optical Network Unit) and the ONU Receiving a transmission frame including user data presence / absence information indicating whether or not to include a frame number and user data from the OLT, referring to the frame number and user data presence / absence information from the received transmission frame, A frame including user data is re-created into a frame including user data and a control message, and a predetermined idle pattern is inserted into a frame not including user data, and the frame including the predetermined idle pattern and control message is re-created. And outputting at least a step of transmitting the remade frame from the ONU to an RRH (Remote Radio Head).

  As described above, since the data portion of the frame not including the user data is discarded, it is possible to improve the band use efficiency in the downstream PON section when transmitting the digital RoF signal in the PON system.

  (8) In the transmission method of the present invention, the BBU further includes a step of dividing the digital RoF signal into a predetermined length and inserting a control message in which the user data presence / absence information is written between the digital RoF signals. It is characterized by including.

  With this configuration, it is possible to perform processing for determining whether to discard the data portion according to the presence or absence of user data. When there is no user data, the data portion is discarded, so that it is possible to improve the bandwidth utilization efficiency in the PON section.

  (9) The transmission method of the present invention is a method for transmitting a digital RoF (Radio over Fiber) signal in a PON (Passive Optical Network) system, and whether or not user data is included from an RRH (Remote Radio Head). Transmitting a frame having a control message in which user data presence / absence information is written to an ONU (Optical Network Unit), and referring to the user data presence / absence information in the control message in the ONU, While outputting as it is, discarding the data part of the frame that does not include user data, outputting a frame having a control message, and including the frame number of the received frame and user data presence / absence information in the output frame Sending the frame to the OLT (Optical Line Terminal), Receiving a transmission frame including user data presence / absence information indicating whether or not to include a frame number and user data from the ONU, and referring to the frame number and user data presence / absence information from the received transmission frame. A frame including user data is recreated into a frame including user data and a control message, and a predetermined idle pattern is inserted into a frame not including user data, and the frame including the predetermined idle pattern and control message is recreated. And outputting the reconstructed frame from the OLT to a BBU (BaseBand Unit).

  As described above, since the data portion of the frame that does not include user data is discarded, it is possible to improve the band utilization efficiency in the upstream PON section when transmitting a digital RoF signal in the PON system.

  (10) In the transmission method of the present invention, the RRH further includes a step of dividing the digital RoF signal into a predetermined length and inserting a control message in which the user data presence / absence information is written between the digital RoF signals. It is characterized by including.

  With this configuration, it is possible to perform processing for determining whether to discard the data portion according to the presence or absence of user data. When there is no user data, the data portion is discarded, so that it is possible to improve the bandwidth utilization efficiency in the PON section.

  (11) Further, in the transmission method of the present invention, the digital RoF signal conforms to CPRI (Common Public Radio Interface) or ETSI (European Telecommunications Standards Institute) -ORI (Open Radio Equipment Interface) standard. And

  With this configuration, it is possible to construct a PON system that conforms to CPRI or ETSI-ORI.

  According to the present invention, when a digital RoF signal is transmitted in a PON system, it is possible to improve band use efficiency in a downstream PON section.

It is a figure which shows schematic structure of the PON system which concerns on this embodiment. It is a block diagram which shows schematic structure of BBU which concerns on 1st Embodiment. It is a figure which shows an example of the flame | frame transmitted from BBU. It is a block diagram which shows schematic structure of OLT. 4 is a flowchart showing control processing in a queue control unit 107. It is a figure which shows an example of the flame | frame transmitted from OLT. It is a block diagram which shows schematic structure of ONU. 10 is a flowchart showing processing for inserting an idle pattern in the queue control unit 208; It is a figure which shows an example of the flame | frame output from ONU. It is a figure which shows schematic structure of BBU which concerns on 2nd Embodiment. It is a block diagram which shows schematic structure of OLT which concerns on 2nd Embodiment. It is a figure which shows an example of the system which transmits a digital RoF signal.

  The inventors pay attention to the fact that the dynamic bandwidth allocation (DBA) of the PON system and the characteristics of the digital RoF signal are incompatible with each other when transmitting a digital RoF signal in a PON system with high frequency utilization efficiency. In order to increase the affinity of the digital RoF signal, when the user data is not included in the digital RoF signal, it is found that the frequency utilization efficiency in the PON section when transmitting the digital RoF signal can be improved by deleting the data portion. Invented.

  That is, the OLT of the present invention is applied to a PON (Passive Optical Network) system, and dynamically allocates an upstream communication band to at least one ONU (Optical Network Unit), thereby providing a digital RoF (Radio over Fiber). An OLT (Optical Line Terminal) that transmits a signal, and an OLT frame receiving unit that receives a frame having a control message in which user data presence / absence information indicating whether or not user data is included is written from a BBU (BaseBand Unit) OLT control unit that refers to the user data presence / absence information in the control message and outputs the frame including the user data as it is, discards the data portion of the frame not including the user data, and outputs the frame having the control message And the frame number of the received frame in the frame output from the control unit. And characterized in that it comprises a OLT transmitting unit that transmits a transmission frame including user data existence information in ONU, the.

  Accordingly, the present inventors have a high frequency band utilization efficiency in the PON section even when there are a plurality of ONUs connected to the digital RoF signal transmission device or when ONUs connected to general users are mixed. It was possible to realize. Embodiments of the present invention will be specifically described below with reference to the drawings.

  In the embodiments described below, the digital RoF signal is described as a CPRI (Common Public Radio Interface) signal flowing between the BBU and the RRH (Remote Radio Head), but the present invention is not limited to this. Absent.

  FIG. 1 is a diagram showing a schematic configuration of a PON system according to the present embodiment. As shown in FIG. 1, in the PON system 10 according to the present embodiment, the OLT 11 is connected to the BBU 12 and the Internet 13. The OLT 11 is connected to a plurality of ONUs 15-1 to 15-n (n is a natural number) via the optical branching device 14, and constitutes the PON system 10.

  A general user 17 who enjoys RRH 16 and broadband service is connected to the plurality of ONUs 15-1 to 15-n, and a user terminal 18 is connected to the RRH 16 via a wireless analog signal. Yes.

(First embodiment)
Next, a first embodiment according to the present invention will be described with reference to FIGS. First, the process for the downlink CPRI signal transmitted from the BBU toward the RRH will be described. FIG. 2 is a block diagram illustrating a schematic configuration of the BBU according to the first embodiment. In FIG. 2, the functions of the upper layer function 1 and the PHY processing unit 3 are the same as those provided in a general BBU. FIG. 2 shows only the part related to the transmission in the downlink direction among the functional blocks indispensable for the present invention included in the BBU. In FIG. 2, the MAC processing unit 2 that has received data from the upper layer performs MAC processing including band allocation to the user terminal. The MAC processing performed here is the same as the MAC processing in a general BBU except that band allocation information is transferred to the data detection unit 4.

  The data detection unit 4 notified of the band allocation information calculates the presence / absence of user data in each CPRI frame and transfers the information to the CPRI framer 5. The CPRI framer 5 divides the data transferred from the PHY processing unit 3 into a predetermined length, and generates a CPRI frame by inserting a CPRI control message. Furthermore, the transferred user data presence / absence information is written in the CPRI control message.

  As an example of a method for writing user data presence / absence information in the control message of the CPRI frame, the user data presence / absence information is aggregated for every predetermined number of frames, and the usage purpose such as “vendor specific usage” area is not clearly defined. There is a method to write in a batch. The CPRI frame in which the user data presence / absence information is written in the control message portion is transferred to the CPRI transmission portion 6 and is transmitted to the OLT 11 as a CPRI frame sequence as shown in FIG.

  Next, processing for the CPRI frame sequence in the OLT 11 will be described. FIG. 4 is a block diagram showing a schematic configuration of the OLT. However, in FIG. 4, only the part related to the downlink transmission is described among the functional blocks included in the OLT 11 and essential to the present invention. First, the CPRI frame sequence is received by the CPRI receiving unit 102 and sequentially transferred to the data copying unit 103. The data duplicating unit 103 duplicates the control message part of the CPRI frame sequence, transfers it to the data detecting unit 104, and transfers the CPRI frame to the CPRI queue 106. The data detection unit 104 reads the control message and stores it in the memory 105 in an associative array format in which the CPRI frame number and the presence / absence of user data of the frame are linked.

  Thereafter, the queue control unit 107 transfers the CPRI frame including the user data to the PON framer 108, and controls the CPRI queue 106 so as to discard the data portion of the CPRI frame not including the user data. In the CPRI frame in which the data part is discarded, only the control message is transferred to the PON framer 108.

  FIG. 5 is a flowchart showing control processing in the queue control unit 107. First, the queue control unit 107 acquires the frame number X of the CPRI frame stored at the head of the CPRI queue 106 (step S1). Then, the user data presence / absence information of the frame X is acquired from the memory 105 and transferred to the PON framer 108 (step S2). This information is used when the discarded frame is restored on the ONU side. Hereinafter, this information is referred to as “queue control information”.

  Next, it is determined whether or not the frame X includes user data (step S3). In step S3, when user data is not included, only the control message of frame X is transferred to the PON framer 108, and the data part is discarded (step S4). On the other hand, if the frame X includes user data in step S3, the frame X is transferred as it is to the PON framer 108 (step S5). Next, in either case, the element with the number X is deleted from the associative array in the memory (step S6), and the processing for the frame X is ended.

  Thereafter, in FIG. 4, the CPRI frame, control message, and queue control information input to the PON framer 108 are encapsulated in a frame of a format defined by the PON system and transferred to the PON control unit 109. The PON control unit 109 multiplexes the frame with other data frames transferred from the higher-order IF receiving unit 101 and distributes them to the queue 110 and the queue 111 according to the PON bandwidth allocation method so that the type of each frame can be determined by the ONU. Are assigned different logical link identifiers, and the identifiers are stored in the frame. Thereafter, the data is sequentially transferred to the PON transmission unit 112 and transmitted to the PON section as shown in FIG. As shown in FIG. 6, the CPRI frame including the user data, the queue control information frame, and other data frames are received by the ONU 15-1 connected to the RRH 16.

  FIG. 7 is a block diagram showing a schematic configuration of the ONU. In FIG. 7, only the part related to the transmission in the downlink direction is described among the functional blocks indispensable for the present invention included in the ONU. The frame received by the PON receiving unit 201 is sorted by the PON control unit 202 based on the logical link identifier. In this embodiment, it is assumed that a frame including a CPRI frame is distributed to the PON framer 204, and other data frames are distributed to the queue 203. The PON framer 204 extracts the queue control information and the CPRI frame from the received frame, and transfers the former to the data detection unit 205 and the latter to the CPRI queue 207, respectively.

  The data detection unit 205 creates an associative array that associates each CPRI frame number with the presence / absence of user data from the queue control information, and stores it in the memory 206 as in the OLT. In the queue control unit 208, for example, based on a table or the like, a process of inserting an idle pattern at a location deleted by the OLT is performed.

  FIG. 8 is a flowchart showing processing for inserting an idle pattern in the queue control unit 208. First, the queue control unit 208 acquires the frame number X of the CPRI queue head frame (step S101). Subsequently, with reference to the associative array, information on the presence / absence of user data in the frame X is acquired, and it is determined whether or not the frame X includes user data (step S102). In step S102, when the frame X does not include user data, the data portion of the frame X has been deleted by the OLT, so the frame X is in a state of only a control message. The queue control unit 208 inserts a predetermined idle pattern after the control message of the frame X, makes the frame X conform to the CPRI frame format, and transfers it to the CPRI transmission unit 210 (step S103). As for the idle pattern, a state in which no signal is output when converted into an analog signal, or a pattern that is converted into an idle signal is registered in advance in the CPRI signal processing unit of the ONU.

  On the other hand, when the frame X includes user data in step S102, the frame X is transferred to the CPRI transmission unit 210 (step S104). Next, the element of number X is deleted from the associative array (step S105), and the process ends.

  By performing the processing according to the above description, as shown in FIG. 9, the frame sequence conforming to the CPRI frame format is output from the ONU 15-1 with only the data portion replaced and received by the RRH 16. At this time, since the signal as output from the BBU 12 is transmitted for the portion including the user data, data transmission / reception is performed between the BBU 12 and the user terminal 18 as if there was no PON system.

  On the other hand, since it is not necessary to transmit the data portion of the CPRI frame that does not include user data in the PON section, the occupied bandwidth can be significantly reduced. In the CPRI frame, the size of the control message for the CPRI frame including the control message is 1/16. Therefore, when there is no user data, the occupied bandwidth by the CPRI frame can be reduced to 1/16.

  The first embodiment of the present invention for the downlink CPRI signal has been described above. On the other hand, as the first embodiment of the present invention for the upstream CPRI signal, the presence / absence of user data is written in the CPRI control frame by the RRH 16, the frame discard procedure described above is performed by the ONU 15-1, and the idle pattern insertion procedure is performed by the OLT 11. By doing so, the bandwidth utilization efficiency can be improved similarly.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIGS. FIG. 10 is a diagram illustrating a schematic configuration of a BBU according to the second embodiment. Also in the second embodiment, band allocation information is transferred from the MAC processing unit 302 to the user data presence / absence information detecting unit 304 via the upper layer function 301. The user data presence / absence information detection unit 304 calculates the presence / absence of user data in each CPRI frame from the bandwidth allocation information, and transfers the user data presence / absence information to the user data presence / absence information transmission unit 306. The user data presence / absence information transmission unit 306 transfers the information to the OLT using a general transmission method typified by Ethernet (registered trademark).

  FIG. 11 is a block diagram illustrating a schematic configuration of the OLT according to the second embodiment. In the OLT, as shown in FIG. 11, in parallel with the process of receiving the CPRI frame and storing it in the CPRI queue 406, information on the presence / absence of user data in each CPRI frame is received, and the data detection unit 404 converts the information into an associative array format Processing to save in the memory 405 is performed. Subsequent processing is in accordance with the first embodiment.

  The second embodiment of the present invention for the downlink CPRI signal has been described above. As a second embodiment of the present invention for an upstream CPRI signal, RRH 16 transfers user data presence / absence information to ONU 15-1 by a general transmission method, performs frame discarding procedure by ONU 15-1, and idles by OLT 11. Perform pattern insertion procedure.

  As described above, according to the present embodiment, for a CPRI frame having no user data, only the control message is transmitted in the PON section, so that the occupied bandwidth of the CPRI frame in the PON section can be significantly reduced. In the case of the CPRI frame, since the ratio of the control message length to the frame length is 1/16, the occupied bandwidth can be reduced to 1/16 when there is no user data. Although the technique described in Patent Document 1 can reduce the number of fibers, it does not consider reducing the number of optical transceivers, but the present invention reduces the number of optical transceivers on the OLT side. There is an excellent effect of being able to.

DESCRIPTION OF SYMBOLS 1 Upper layer function 2 MAC processing part 3 PHY processing part 4 Data detection part 5 CPRI framer 6 CPRI transmission part 10 PON system 11 OLT
12 BBU
13 Internet 14 Optical splitters 15-1 to 15-n ONU
16 RRH
17 General user 18 User terminal 101 Upper IF receiving unit 102 CPRI receiving unit 103 Data duplicating unit 104 Data detecting unit 105 Memory 106 CPRI queue 107 Queue control unit 108 PON framer 109 PON control unit 110 Queue 111 Queue 112 PON transmission unit 201 PON reception Unit 202 PON control unit 203 queue 204 PON framer 205 data detection unit 206 memory 207 CPRI queue 208 queue control unit 209 user IF transmission unit 210 CPRI transmission unit 301 upper layer function 302 MAC processing unit 303 PHY processing unit 304 user data presence / absence information detection Unit 305 CPRI framer 306 user data presence / absence information transmission unit 307 CPRI transmission unit 401 upper IF reception unit 402 CPRI reception unit 403 user data presence / absence information reception unit 4 04 data detection unit 405 memory 406 CPRI queue 407 queue control unit 408 PON framer 409 PON control unit 410 queue 411 queue 412 PON transmission unit

Claims (11)

Applied to a PON (Passive Optical Network) system, an OLT (Optical Line) that dynamically allocates an upstream communication band to at least one ONU (Optical Network Unit) and transmits a digital RoF (Radio over Fiber) signal. Terminal)
An OLT frame receiving unit that receives a frame having a control message in which user data presence / absence information indicating whether or not to include user data is written from a BBU (BaseBand Unit);
An OLT control unit that refers to user data presence / absence information in the control message and outputs a frame including the user data as it is, discards a data part of the frame not including the user data, and outputs a frame having the control message;
An OLT comprising: an OLT transmission unit that transmits a frame for transmission including a frame number of the received frame and user data presence / absence information to an ONU in a frame output from the control unit. Applied to a PON (Passive Optical Network) system, an OLT (Optical Line) that dynamically allocates an upstream communication band to at least one ONU (Optical Network Unit) and transmits a digital RoF (Radio over Fiber) signal. Terminal)
An OLT receiver that receives a transmission frame including user data presence / absence information indicating whether or not to include a frame number and user data from the ONU;
While referring to the frame number and user data presence / absence information from the received transmission frame, a frame including user data is recreated and output as a frame including user data and a control message, while a predetermined idle is set to a frame not including user data. An OLT control unit that inserts a pattern, regenerates and outputs a frame including the predetermined idle pattern and control message;
An OLT comprising: an OLT frame transmission unit that transmits the recreated frame to a BBU (BaseBand Unit). An ONU (Optical Network Unit) that is applied to a PON (Passive Optical Network) system and that dynamically allocates an upstream communication band from an OLT (Optical Line Terminal) and transmits a digital RoF (Radio over Fiber) signal. ,
An ONU receiving unit for receiving a transmission frame including user data presence / absence information indicating whether or not to include a frame number and user data from the OLT;
While referring to the frame number and user data presence / absence information from the received transmission frame, a frame including user data is recreated and output as a frame including user data and a control message, while a predetermined idle is set to a frame not including user data. An ONU control unit that inserts a pattern, regenerates and outputs a frame including the predetermined idle pattern and control message;
An ONU comprising: an ONU frame transmission unit that transmits the remade frame to an RRH (Remote Radio Head). An ONU (Optical Network Unit) that is applied to a PON (Passive Optical Network) system and that dynamically allocates an upstream communication band from an OLT (Optical Line Terminal) and transmits a digital RoF (Radio over Fiber) signal. ,
An ONU frame receiving unit for receiving a frame having a control message in which user data presence / absence information indicating whether or not to include user data is written from RRH (Remote Radio Head);
An OLT control unit that refers to user data presence / absence information in the control message and outputs a frame including the user data as it is, discards a data part of the frame not including the user data, and outputs a frame having the control message;
An ONU comprising: an ONU transmission unit configured to transmit a transmission frame including a frame number of the received frame and user data presence / absence information to the OLT in a frame output from the control unit.   A PON system comprising the OLT according to claim 1 and the ONU according to claim 3.   A PON system comprising the OLT according to claim 2 and the ONU according to claim 4. A method of transmitting a digital RoF (Radio over Fiber) signal in a PON (Passive Optical Network) system,
Transmitting from the BBU (BaseBand Unit) a frame having a control message in which user data presence / absence information indicating whether or not user data is included is written to an OLT (Optical Line Terminal);
In the OLT, referring to the user data presence / absence information in the control message, the frame including the user data is output as it is, the data portion of the frame not including the user data is discarded, and the frame having the control message is output, Transmitting a frame for transmission including the frame number of the received frame and user data presence / absence information to an output frame to an ONU (Optical Network Unit);
In the ONU, a transmission frame including user data presence / absence information indicating whether or not to include a frame number and user data is received from the OLT, and the frame number and the user data presence / absence information are referred to from the received transmission frame. A frame including user data is recreated into a frame including user data and a control message, and a predetermined idle pattern is inserted into a frame not including user data, and the frame including the predetermined idle pattern and control message is recreated. Output step,
Transmitting from the ONU the recreated frame to an RRH (Remote Radio Head).   8. The transmission according to claim 7, further comprising the step of dividing the digital RoF signal into a predetermined length and inserting a control message in which the user data presence / absence information is written between the digital RoF signals in the BBU. Method. A method of transmitting a digital RoF (Radio over Fiber) signal in a PON (Passive Optical Network) system,
Transmitting a frame having a control message in which user data presence / absence information indicating whether or not user data is included is transmitted from an RRH (Remote Radio Head) to an ONU (Optical Network Unit);
In the ONU, referring to the user data presence / absence information in the control message and outputting the frame including the user data as it is, discarding the data portion of the frame not including the user data, outputting the frame having the control message, Transmitting a transmission frame including a frame number of the received frame and user data presence / absence information to an output frame to an OLT (Optical Line Terminal);
In the OLT, a transmission frame including user data presence / absence information indicating whether or not to include a frame number and user data is received from the ONU, and the frame number and user data presence / absence information are referred to from the received transmission frame. A frame including user data is recreated into a frame including user data and a control message, and a predetermined idle pattern is inserted into a frame not including user data, and the frame including the predetermined idle pattern and control message is recreated. Output step,
Transmitting from the OLT the recreated frame to a BBU (BaseBand Unit).   10. The transmission according to claim 9, further comprising: a step of dividing the digital RoF signal into a predetermined length in the RRH and inserting a control message in which the user data presence / absence information is written between the digital RoF signals. Method. 11. The digital RoF signal conforms to CPRI (Common Public Radio Interface) or ETSI (European Telecommunications Standards Institute) -ORI (Open Radio Equipment Interface) standard. The transmission method described in 1.

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