JP4964105B2 - Communication system and media converter - Google Patents

Description

  The present invention relates to a communication system and a media converter that transmit and receive data frames using a PON control protocol.

  In recent years, an FTTH (Fiber To The Home) system using an access network has attracted attention as an Internet connection service using an optical fiber. One of the FTTH systems is a GE-PON (Gigabit Ethernet (registered trademark) -Passive Optical Network) system using an Ethernet (registered trademark) frame (see, for example, Non-Patent Document 1). The GE-PON system is a system in which a plurality of subscriber side communication devices (slave station devices) and station side communication devices (master station devices) are connected via an optical fiber cable cable via a star coupler. The GE-PON system is an economical communication system because a plurality of subscriber side communication devices share a single station side communication device.

IEEE (Institute of Electrical and Electronics Engineers) 802.3-2005 section 5

  In the conventional technology (GE-PON system), subscriber side communication devices having different connection distances from the station side communication devices are mixed, and these subscriber side communication devices are connected by optical fiber cables. However, in an access network such as the GE-PON system, it is technically expensive to install a new optical fiber in an existing apartment house such as a condominium to accommodate subscribers of the existing apartment house. It is difficult. Furthermore, even when the line speed of the access network can be increased, the fiber plant in the common groove or on the pillar is redesigned to increase the number of subscribers (slave station devices) accommodated in one line. There was a problem that it was difficult to do.

  The present invention has been made in view of the above, and an object of the present invention is to provide a communication system and a media converter that can easily perform additional connection of a communication device that transmits and receives data using a PON control protocol. .

In order to solve the above-described problems and achieve the object, the present invention provides a network between a station-side device connected to a wide area network, an optical fiber network extended from the station-side device, and the station-side device. A wireless communication device that terminates the PON control protocol and wirelessly communicates with a predetermined external device, transmits and receives data frames to and from the station side device via the optical fiber network, and transmits the data frame by wireless communication. A media converter that transmits and receives data frames to and from a wireless communication device, and the media converter transparently transfers an access control frame between the station side device and the wireless communication device with a fixed delay. It is characterized by.

  According to the present invention, the media converter transparently transfers the data frame between the station side device and the wireless communication device with a fixed delay, and the wireless communication device terminates the PON control protocol with the station side device. In addition, since wireless communication with the media converter is performed, it is possible to easily perform additional connection of a wireless communication device that transmits and receives data using the PON control protocol.

  Embodiments of a communication system and a media converter according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram showing a configuration of a communication system according to Embodiment 1 of the present invention. The communication system 100 is a system used for a PON type access network such as a GE-PON system. The communication system 100 according to the present embodiment transparently transfers a frame (data frame) according to an access control protocol on a transmission medium in which a wired communication section and a wireless communication section are combined. And data transfer between the station side device.

  In the present embodiment, the communication system 100 is a media converter (described later) that performs wireless communication with an ONU (described later ONUs a1 to a6) having a wireless communication function, and wireless communication with the ONU (also described later OLT). The media converters C1 and C2) have one feature.

  The communication system 100 includes an OLT (Optical Line Terminal) 1 that is a master station device, wireless ONUs (Optical Network Units) a1 to a6 and ONUs b1 to bn (n is a natural number) that are slave station devices, media converters C1 and C2, and star converters. A coupler 2 and an optical fiber (optical fiber cable) 3 are provided.

  The OLT 1 is a device installed in a network operator's office or the like. The OLT 1 is connected to an upper network (not shown) which is a wide area network, and an optical fiber in a subscriber communication network (PON control protocol terminal 4). 3 is connected. The OLT 1 is a higher-order terminal device in the PON control protocol terminal 4. The OLT 1 includes a network-side interface 12 and a PON-side interface (not shown) that are connected to an upper network. The PON side interface is connected to the star coupler 2 via the optical fiber 3.

  The star coupler 2 branches the optical fiber 3 extended from the OLT 1 to the lower side, thereby connecting the OLT 1 to the media converters C 1 and C 2 and the ONUs b 1 to bn by the optical fiber 3. In the communication system 100, the optical fiber 3 and the star coupler 2 constitute an optical fiber network.

  The ONUs b1 to bn are conventional subscriber side communication devices (slave station devices) arranged in subscriber homes, etc., and include a PON side interface (not shown), a subscriber user side interface 36, and PON access. And a means (not shown) for terminating the control (PON access control protocol). The PON side interface is connected to the OLT 1 via the optical fiber 3 in the PON control protocol termination 4, and the user side interface 36 is connected to a communication terminal (subscriber terminal) such as a PC (Personal Computer). The section where the ONUs b1 to bn and the OLT 1 are connected is an optical section (optical communication section) 6 of the PON control protocol termination 4, and optical communication via the optical fiber 3 is performed between the ONUs b1 to bn and the OLT 1. Done.

  The media converter (optical-wireless media converter) C1 includes a PON side interface (not shown) connected to the OLT 1 side, and a wireless antenna 25 that performs wireless communication with the wireless ONUs a1 to a3. Further, the media converter C2 includes a PON side interface (a PON side interface 26 described later) connected to the OLT 1 side, and a radio antenna 25 that performs radio communication with the radio ONUs a4 to a6. Each of the media converters C1 and C2 transfers a frame signal received from the PON side interface to the wireless interface (an RF interface 21 described later), and transfers a frame signal received from the wireless interface to the PON side interface. Media converters C1 and C2 are arranged, for example, in the vicinity of the subscriber's house.

  The section where the media converters C1, C2 and the OLT 1 are connected is the optical section 6 of the PON control protocol termination 4, and optical communication via the optical fiber 3 is performed between the media converters C1, C2 and the OLT 1. It is. The section in which the media converter C1 communicates with the wireless ONUs a1 to a3, and the section in which the media converter C2 communicates with the wireless ONUs a4 to a6 is a wireless section (wireless communication section) 5 of the PON control protocol end point 4. . Data is transmitted from the media converters C1 and C2 to the wireless ONUs a1 to a3 and the wireless ONUs a4 to a6 via the wireless antennas 25, respectively, and data transmitted from the wireless ONUs a1 to a3 and the wireless ONUs a4 to a6 is transmitted to the wireless antennas 25.

  The wireless ONUs a <b> 1 to a <b> 6 are subscriber-side communication devices (wireless communication devices) according to the present embodiment that are arranged in subscriber homes and the like, and accommodate one to a plurality of subscriber terminals. The wireless ONUs a <b> 1 to a <b> 6 are used, for example, when a new subscriber terminal is additionally connected to the communication system 100. The wireless ONUs a1 to a6 include a wireless antenna 35 that performs wireless communication with the media converters C1 and C2, a means for terminating PON access control (a PON control unit 33 described later), and a user interface 36 for a subscriber. is doing. Data is transmitted from the wireless ONUs a1 to a3 and the wireless ONUs 4 to a6 to the media converters C1 and C2 via the wireless antennas 35, and the data transmitted from the media converters C1 and C2 is received by the wireless antennas 35. The The user side interface 36 is connected to a communication terminal (subscriber terminal) such as a PC.

  In FIG. 1, for convenience of explanation, the network side interface 12 is illustrated outside the OLT 1, but the network side interface 12 is one of the components of the OLT 1. Further, although the user side interface 36 is illustrated outside the wireless ONUs a1 to a6 and the ONUs b1 to bn, the user side interface 36 is one of the components of the wireless ONUs a1 to a6 and the ONUs b1 to bn.

  Next, the detailed configuration of the media converters C1 and C2 will be described. Since media converters C1 and C2 have the same configuration, the configuration of media converter C1 will be described here.

  FIG. 2 is a block diagram showing the configuration of the media converter. The media converter C1 includes an RF (Radio Frequency) interface 21, a frame processing unit 22, a parallel conversion unit 23, an EO / OE conversion unit 24, a wireless antenna 25, and a PON side interface 26.

  Here, the RF interface 21 and the wireless antenna 25 correspond to the wireless communication unit described in the claims, and the frame processing unit 22, the parallel conversion unit 23, and the EO / OE conversion unit 24 here are claimed. It corresponds to the transfer processing unit described in the range. Further, the PON side interface 26 here corresponds to the optical communication unit described in the claims.

  The PON side interface 26 is connected to the OE / EO conversion unit 24, and sends the frame received from the OLT 1 via the optical fiber 3 to the OE / EO conversion unit 24. The PON side interface 26 transmits the frame sent from the OE / EO conversion unit 24 to the OLT 1 via the optical fiber 3.

  The OE / EO conversion unit (optical / electrical conversion unit) 24 converts the downstream optical signal (frame) received from the OLT 1 into an electrical signal to the wireless ONUs a1 to a3 and the upstream received from the wireless ONUs a1 to a3. Is converted into an optical signal to the OLT 1.

  The parallel conversion unit 23 is a SerDes (Serializer / Deserializer) and is connected to the OE / EO conversion unit 24 and the frame processing unit 22. The parallel conversion unit 23 performs parallel conversion on the electrical signal serially input from the OE / EO conversion unit 24 and sends the converted signal to the frame processing unit 22. In addition, the parallel conversion unit 23 serially converts the electrical signal input in parallel from the frame processing unit 22 and sends it to the OE / EO conversion unit 24.

  The frame processing unit 22 has a MAC + PHY function for performing wireless communication, and exchanges signals with the RF interface 21. The frame processing unit 22 performs encapsulation of the frame sent from the parallel conversion unit 23 and sends it to the RF interface 21. In addition, the frame processing unit 22 decapsulates the frames received from the wireless ONUs a <b> 1 to a <b> 3 via the RF interface 21 and sends them to the parallel conversion unit 23.

  The RF interface 21 is connected to the frame processing unit 22 and the wireless antenna 25, and transmits a frame transmitted from the frame processing unit 22 to the wireless ONUs a1 to a3 via the wireless antenna 25. Further, the RF interface 21 sends frames received from the wireless ONUs a <b> 1 to a <b> 3 via the wireless antenna 25 to the frame processing unit 22. The wireless antenna 25 transmits and receives data by wireless communication with the wireless antennas 35 of the wireless ONUs a1 to a3.

  Next, a detailed configuration of the wireless ONUs a1 to a6 will be described. Since the wireless ONUs a1 to a6 have the same configuration, the configuration of the wireless ONUa1 will be described here. FIG. 3 is a block diagram showing a configuration of the wireless ONU. The wireless ONUa1 includes an RF interface 31, a frame processing unit 32, a PON control unit 33, a PHY unit 34, a wireless antenna 35, and a user side interface (UNI).

  The wireless antenna 35 is a network-side interface, and transmits and receives data by wireless communication with the wireless antenna 25 of the media converter C1. The RF interface 31 is connected to the frame processing unit 32 and the wireless antenna 35, and sends a frame received from the media converter C 1 via the wireless antenna 35 to the frame processing unit 32. Further, the RF interface 21 transmits the frame transmitted from the frame processing unit 32 to the media converter C1 via the wireless antenna 35.

  The frame processing unit 32 has a MAC + PHY function for performing wireless communication, and exchanges signals with the RF interface 31. The frame processing unit 32 performs encapsulation of the frame sent from the PON control unit 33 and sends it to the RF interface 31. Further, the frame processing unit 32 decapsulates the frame received from the media converter C 1 via the RF interface 31 and sends it to the PON control unit 33.

  The frame processing unit 32 according to the present embodiment transparently transfers a signal sent from the RF interface 31 side to the PON control unit 33 side, and sends a signal sent from the PON control unit 33 side to the RF interface 31 side. It has a function to transfer to transparently.

  The PON control unit 33 is connected to the frame processing unit 32 and the PHY unit. The PON control unit 33 has a function of terminating PON access control with the OLT 1 and bridging a user frame between the frame processing unit 32 and the PHY unit 34.

  The PHY unit 34 is connected to the PON control unit 33 and the user side interface 36. The PHY unit 34 has a conventional Ethernet (registered trademark) PHY function having a physical layer function necessary for transmitting and receiving an Ethernet (registered trademark) frame (hereinafter referred to as a frame) to and from the user-side interface 36. It has.

  Next, the operation of the communication system 100 will be described. In the communication system 100, the OLT 1 and the ONUs b1 to bn execute access control and frame transmission based on the conventional PON access control protocol and frame transmission format. Specifically, a logical link is established between the OLT 1 and the ONUs b1 to bn, and data is transmitted and received by a MAC (Media Access Control) frame using a logical link identifier (LLID) of the established logical link. To do.

  Next, access control and frame transmission performed between the OLT 1 and the wireless ONUs a1 to a6 will be described. The wireless ONUs a1 to a3 and the wireless ONUs a4 to a6 transmit and receive signals to and from the media converter C1 and C2, respectively, and terminate the PON control protocol similarly to the conventional ONU.

  For example, when GE-PON based on the IEEE (Institute of Electrical and Electronics Engineers) 802.3ah specification is applied to the PON access control method of the communication system 100, the wireless ONUs a1 to a6 are based on the standard. It is connected to OLT1 by the protocol, and LLID is assigned from OLT1.

  For example, when the OLT 1 performs unicast transfer, when the OLT 1 receives a frame from the upper network, the OLT 1 adds an LLID indicating the destination to the frame based on the destination MAC address and VID information. Then, the OLT 1 broadcasts the frame to which the LLID is assigned to all the wireless ONUs a1 to a6 and ONUs b1 to bn.

  Next, access control will be described. The access control frame is a frame generated by the OLT and terminated by the ONU. The MPCP protocol used in the GE-PON is applied, and the media converter C1 is connected to all the wireless ONUs a1 to a6 and ONUs b1 to bn from the OLT1, for example. By assigning a radio frequency dedicated to access control, congestion due to the buffer in the media converter C1 can be avoided, and a function of transmitting with a fixed delay is provided.

  Hereinafter, since the media converter C1 and the media converter C2 perform the same operation, the operation of the media converter C1 will be described here. Since the wireless ONUs a1 to a3 perform the same operation, the operation of the wireless ONUa1 will be described here.

  When the media converter C1 receives the frame from the OLT 1 via the PON side interface, the EO / OE conversion unit 24 converts the received frame into an electric signal and serially inputs the parallel signal to the parallel conversion unit 23. The parallel conversion unit 23 performs parallel conversion on the electrical signal serially input from the OE / EO conversion unit 24 and sends the converted signal to the frame processing unit 22.

  The frame processing unit 22 performs encapsulation of the frame sent from the parallel conversion unit 23 and sends it to the RF interface 21. The RF interface 21 wirelessly propagates the frame transmitted from the frame processing unit 22 via the wireless antenna 25.

  As a result, the media converter C1 transparently transfers the PON frame format frame transferred from the OLT 1 to the wireless ONUa1. Further, in the wireless section 5 of the present embodiment, the media converter C1 performs data communication using a wireless system capable of full-duplex communication in which an access control frame is transmitted with a fixed delay.

  The wireless ONUa 1 receives the frame from the media converter C 1 through the wireless antenna 35. The RF interface 31 of the wireless ONU a 1 sends the frame received from the media converter C 1 via the wireless antenna 35 to the frame processing unit 32.

  The frame processing unit 32 decapsulates the frame received from the media converter C <b> 1 via the RF interface 31 and sends it to the PON control unit 33. At this time, the frame processing unit 32 transparently transfers the signal transmitted from the RF interface 31 side to the PON control unit 33 side.

  The PON control unit 33 terminates PON access control with the OLT 1. Specifically, the PON control unit 33 confirms the value of the LLID given to the received frame. The PON control unit 33 discards the received frame if the LLID value is not the LLID value indicating itself or the LLID indicating broadcast transmission. On the other hand, if the LLID value is the LLID value indicating itself or the LLID value indicating broadcast transmission (broadcast) (= 0xFFFF), the PON control unit 33 determines whether the received frame is a PON access control signal. Is determined based on the value of TPID (Tag Protocol ID).

  If the received frame is a PON access control signal, the PON control unit 33 performs PON access control with the OLT 1 using the received frame. On the other hand, if the received frame is user data, the PON control unit 33 bridges (transfers) the user data to the PHY unit 34. The PHY unit 34 transmits a frame to a terminal such as a PC via the user side interface 36. Thereafter, PON access control using LLID and transmission / reception of user data are performed between the wireless ONUa1 and the OLT1.

  Next, uplink control of the communication system 100 will be described. When the PON control unit 33 of the wireless ONUa 1 receives the Gate frame addressed to the LLID transmitted from the OLT 1, the PON control unit 33 transmits an uplink signal in the time slot specified by the Gate frame. The signal from the PON control unit 33 is encapsulated by the frame processing unit 32 and sent to the RF interface 31. At this time, the frame processing unit 32 transparently transfers the signal transmitted from the PON control unit 33 side to the RF interface 31 side. The signal transferred to the RF interface 31 side is sent to the media converter C1 via the wireless antenna 35.

  The media converter C1 receives the frame from the wireless ONUa1 through the wireless antenna 25. The RF interface 21 of the media converter C1 sends the frame received from the wireless ONUa1 via the wireless antenna 25 to the frame processing unit 22. The frame processing unit 22 decapsulates the frame received from the wireless ONU a 1 via the RF interface 21 and sends it to the parallel conversion unit 23.

  The parallel conversion unit 23 serially converts the electric signal input in parallel from the frame processing unit 22 and sends the electric signal to the OE / EO conversion unit 24. The OE / EO conversion unit 24 converts the upstream electrical signal received from the wireless ONUa1 into an optical signal to the OLT1. The media converter C1 transmits the frame converted into the optical signal by the OE / EO conversion unit 24 to the OLT 1 via the PON side interface. As a result, the media converter C1 transparently transfers user data in the PON frame format to be transferred from the wireless ONUa1 to the OLT1 with a fixed delay.

  When a new subscriber is added to the communication system 100, the optical fiber 3 is extended from the star coupler 2, and a new media converter is disposed at the tip (the user side end of the optical section 6). . Then, a new wireless ONU that performs wireless communication with the new media converter is disposed at the PON control protocol terminal 4. When a new wireless ONU can be wirelessly connected to an already installed media converter, a new wireless ONU that performs wireless communication with the existing media converter is disposed at the PON control protocol terminal 4.

  In the OLT 1, information on the connection distances of the wireless ONUs a1 to a6 and ONUs b1 to bn is managed, so that no frame collision occurs between the wireless ONUs a1 to a6 and the existing b1 to bn. In the present embodiment, PON access control is performed across the optical section 6 and the wireless section 5 in this way, so that CSMA / CA (Carrier Sense Multiple Access with the conventional wireless access control in the upstream direction) is required. A function for collision avoidance such as Collision Avoidance is not necessary in the communication system 100. Further, since full-duplex communication is performed so that uplink and downlink communication do not collide in the wireless section 5, the wireless ONUs a1 to a6 can be mixed with existing OLTs and ONUs. Further, by interposing the media converters C1 and C2 in the communication system 100, it becomes possible to easily accommodate a plurality of subscribers per media converter.

  In this embodiment, a case has been described in which there are two media converters connected to the OLT 1, the media converter C1 and the media converter C2. However, even if there is only one media converter connected to the OLT 1. It may be three or more.

  In the present embodiment, the case where there are three wireless ONUs a wireless ONU a1 to a3 and wireless ONUs a4 to a6 has been described, but the media converter C1 and the media converter C2 are described. The number of wireless ONUs connected to may be two or less, or may be four or more.

  As described above, according to the first embodiment, since wireless communication is performed between the wireless ONUs a1 to a6 and the media converters C1 and C2, communication is possible between the OLT 1 and the wireless ONUs a1 to a6, and the number of branches of the optical fiber 3 is increased. Therefore, it is possible to freely add wireless ONUs (terminals) at low cost without being restricted by the above.

  In addition, since the access control protocol is transparently transferred on a transmission medium that combines wired and wireless technologies, it is possible to mix with existing systems while minimizing changes from existing networks It is possible to flexibly increase the number of subscribers per line and increase the number of subscribers per line.

Embodiment 2. FIG.
Next, a second embodiment of the present invention will be described with reference to FIG. In the first embodiment, a case has been described in which an ONU such as GE-PON has a wireless function and a subscriber terminal connects to this ONU. However, in the second embodiment, a subscriber network is a mobile terminal. The mobile terminal is accommodated and connected to the communication system 100.

  FIG. 4 is a diagram illustrating a configuration of the mobile terminal according to Embodiment 2. In FIG. The mobile terminal 40 is a wireless communication device such as a mobile phone, and includes an RF interface 41, a PON protocol termination unit 42, a telephone communication unit 43, a voice processing unit 44, a data processing unit 45, an application unit 46, and a wireless antenna 47. is doing.

  The mobile terminal 40 performs wireless communication with the media converter C1 or the media converter C2. Here, a case where the mobile terminal 40 performs wireless communication with the media converter C1 will be described.

  The wireless antenna 47 transmits and receives data by wireless communication with the wireless antenna 25 of the media converter C1. The RF interface 41 is a wireless interface, and is connected to the PON protocol termination unit 42, the telephone communication unit 43, and the wireless antenna 47. The RF interface 41 sends the audio data and application data received from the media converter C 1 via the wireless antenna 47 to the PON protocol termination unit 42. Further, the RF interface 41 transmits voice data and application data transmitted from the PON protocol termination unit 42 to the media converter C1 via the wireless antenna 47. Further, the RF interface 41 sends a voice signal for a call sent via a base station of a mobile phone network to the telephone communication unit 43.

  The PON protocol termination unit 42 terminates PON access control with the OLT 1. The PON protocol termination unit 42 according to the present embodiment establishes a PON protocol-based link with the OLT 1 via the media converter C1 according to the procedure specified by the PON protocol when it can be connected to the OLT 1. Execute data communication.

  The telephone communication unit 43 includes a communication unit for telephone (for voice call) and a communication unit for data communication, which are included in a conventional mobile phone. The voice processing unit 44, the data processing unit 45, and the application unit 46 are functions that a conventional portable terminal has, and each performs voice processing related to voice calls, data processing related to e-mails, application processing related to e-mails, and the like. Do. The voice processing unit 44, the data processing unit 45, and the application unit 46 according to the present embodiment perform various data processing using the frame received from the OLT 1.

  Next, communication processing between the portable terminal 40 and the OLT 1 will be described. Note that the OLT 1 and the media converters C1 and C2 transmit and receive frames by the same processing as in the first embodiment, and thus description thereof is omitted.

  The portable terminal 40 receives the frame from the media converter C1 through the wireless antenna 47. The RF interface 41 of the portable terminal 40 sends the frame received from the media converter C 1 via the wireless antenna 47 to the PON protocol termination unit 42.

  The PON protocol termination unit 42 establishes a PON protocol-based link with the OLT 1 via the media converter C1 according to a procedure defined by the PON protocol. The PON protocol termination unit 42 terminates PON access control with the OLT 1. Specifically, the PON protocol termination unit 42 confirms the value of the LLID assigned to the received frame. The PON protocol termination unit 42 discards the received frame if the LLID value is not the LLID value indicating itself or the LLID indicating broadcast transmission. On the other hand, when the value of LLID is the value of LLID indicating itself or the value of LLID indicating broadcast transmission, the PON protocol termination unit 42 determines whether or not the received frame is a PON access control signal. Judgment based on.

  If the received frame is a PON access control signal, the PON protocol termination unit 42 executes PON access control with the OLT 1 using the received frame. On the other hand, if the received frame is user data, the PON protocol termination unit 42 transfers the user data to the voice processing unit 44 and the data processing unit 45. The voice processing unit 44, the data processing unit 45, and the application unit 46 execute processing according to the received user data. Thereafter, PON access control using LLID and transmission / reception of user data are performed between the portable terminal 40 and the OLT 1.

  Next, uplink control of the communication system 100 will be described. When the PON protocol termination unit 42 of the mobile terminal 40 receives the Gate frame addressed to the LLID transmitted from the OLT 1, the PON protocol termination unit 42 transmits an uplink signal in the time slot specified by the Gate frame. The signal from the PON protocol termination unit 42 is sent to the RF interface 41 and sent to the media converter C 1 via the wireless antenna 47.

  When a new portable terminal 40 is added to the communication system 100, the optical fiber 3 is extended from the star coupler 2, and a new media converter is disposed at the tip (the user side end of the optical section 6). To do. Then, the new portable terminal 40 and the new media converter are set so that the new portable terminal 40 and the new media converter can perform wireless communication. In addition, when a new portable terminal can be wirelessly connected to the already installed media converter, the new portable terminal is configured so that the new portable terminal 40 and the already installed media converter can perform wireless communication. 40 and media converters already installed are set.

  In the present embodiment, media converters C1 and C2 are interposed in communication system 100, so that a plurality of portable terminals 40 can be easily accommodated per media converter.

  In the portable terminal 40 of the present embodiment, a PON protocol termination function (PON protocol termination unit 42) is connected to the RF interface 41 together with a conventional telephone communication function (telephone communication unit 43). In the portable terminal 40, the telephone communication unit 43 and the PON protocol termination unit 42 interface with the voice processing unit 44 and the data processing unit 45, respectively. Therefore, according to the second embodiment, when the portable terminal 40 can establish a PON protocol-based link with the OLT 1, the voice data and other application data are transmitted and received between the portable terminal 40 and the OLT 1. Since it can be performed using a transmission path faster than the conventional telephone communication function, it is possible to provide the mobile terminal 40 with a high-speed and high-quality service. In addition, the cellular phone network can be wound by the existing optical access network.

Embodiment 3 FIG.
Next, a second embodiment of the present invention will be described with reference to FIG. In the second embodiment, the case where the subscriber terminal connected to the communication system 100 is a mobile terminal such as a mobile phone has been described. However, in the third embodiment, the subscriber terminal connected to the communication system 100 is a laptop type, for example. A wireless card that can be inserted into an information processing apparatus such as a PC or a household electric appliance (hereinafter referred to as a home appliance) is used.

  FIG. 5 is a diagram illustrating a configuration of a wireless card according to the third embodiment. The wireless card 50 is a wireless communication device that is directly inserted into the communication system 100 via wireless communication by being inserted into the information processing device such as a PC or a home appliance.

  The wireless card 50 includes an RF interface 51, a frame processing unit 52, a PON protocol termination unit 53, a bus connector 54, and a wireless antenna 55. The wireless card 50 performs wireless communication with the media converter C1 or the media converter C2. Here, a case where the wireless card 50 performs wireless communication with the media converter C1 will be described.

  The wireless antenna 55 is a network-side interface, and transmits and receives data by wireless communication with the wireless antenna 25 of the media converter C1. The RF interface 51 is a wireless interface, and is connected to the frame processing unit 52 and the wireless antenna 55. The RF interface 51 sends the frame received from the media converter C <b> 1 via the wireless antenna 55 to the frame processing unit 52. Further, the RF interface 51 transmits the frame transmitted from the frame processing unit 32 to the media converter C1 via the wireless antenna 55.

  The frame processing unit 52 has a MAC + PHY function for performing wireless communication, and exchanges signals with the RF interface 51. The frame processing unit 52 performs encapsulation of the frame sent from the PON protocol termination unit 42 and sends it to the RF interface 51. Further, the frame processing unit 32 decapsulates the frame received from the media converter C 1 via the RF interface 31 and sends it to the PON protocol termination unit 53.

  The frame processing unit 52 according to the present embodiment transparently transfers a signal transmitted from the RF interface 51 side to the PON protocol termination unit 53 side, and transmits a signal transmitted from the PON protocol termination unit 53 side to the RF interface. It has a function of transparently transferring to the 51 side.

  The PON protocol termination unit 53 terminates PON access control with the OLT 1. The PON protocol termination unit 53 of the present embodiment establishes a PON protocol-based link with the OLT 1 via the media converter C1 according to the procedure specified by the PON protocol when it can be connected to the OLT 1. Execute data communication. The PON protocol termination unit 53 has a function of terminating PON access control with the OLT 1 when performing PON control, and a function of bridging a user frame between the frame processing unit 52 and the bus connector 54. is doing.

  The bus-type connector 54 is a conventional interface connector with high versatility, such as a PCI (Peripheral Components Interconnect) bus. In this embodiment, by using a highly versatile bus-type connector 54 for the user-side interface, an existing information processing device such as a home appliance or a home router is converted into a conventional optical access network via a wireless section. It becomes possible to connect.

  Next, communication processing between the wireless card 50 and the OLT 1 will be described. Note that the OLT 1 and the media converters C1 and C2 transmit and receive frames by the same processing as in the first and second embodiments, and thus description thereof is omitted.

  The wireless card 50 receives the frame from the media converter C1 through the wireless antenna 55. The RF interface 51 of the wireless card 50 sends the frame received from the media converter C <b> 1 via the wireless antenna 55 to the PON protocol termination unit 53. The PON protocol termination unit 53 establishes a PON protocol-based link with the OLT 1 via the media converter C1 according to a procedure defined by the PON protocol. The PON protocol termination unit 53 terminates PON access control with the OLT 1. Specifically, the PON protocol termination unit 53 checks the value of the LLID given to the received frame. The PON protocol termination unit 53 discards the received frame unless the LLID value is the LLID value indicating itself or the LLID indicating broadcast transmission. On the other hand, when the value of LLID is the value of LLID indicating itself or the value of LLID indicating broadcast transmission, the PON protocol terminator 53 determines whether the received frame is a PON access control signal or not. Judgment based on.

  If the received frame is a PON access control signal, the PON protocol termination unit 53 executes PON access control with the OLT 1 using the received frame. On the other hand, if the received frame is user data, the PON protocol termination unit 53 transfers the user data to the bus connector 54. The bus-type connector 54 transfers user data from the PON protocol termination unit 53 to the information processing apparatus in which the wireless card 50 is inserted. Thereafter, PON access control using LLID and transmission / reception of user data are performed between the wireless card 50 and the OLT 1.

  Next, uplink control of the communication system 100 will be described. When the PON protocol termination unit 53 of the wireless card 50 receives the Gate frame addressed to the LLID transmitted from the OLT 1, the PON protocol termination unit 53 transmits an uplink signal in the time slot specified by the Gate frame. The signal from the PON protocol termination unit 53 is sent to the RF interface 41 and sent to the media converter C1 via the wireless antenna 55.

  When a new wireless card 50 is added to the communication system 100, the optical fiber 3 is extended from the star coupler 2, and a new media converter is provided at the tip (the user side end of the optical section 6). To do. Then, the new wireless card 50 and the new media converter are set so that the new wireless card 50 and the new media converter can perform wireless communication. If the new wireless card 50 can be wirelessly connected to the already installed media converter, a new wireless card 50 and the already installed media converter can be wirelessly communicated with each other. Settings are made for the card 50 and the already installed media converter.

  In the present embodiment, media converters C1 and C2 are interposed in communication system 100, so that a plurality of wireless cards 50 can be easily accommodated per media converter.

  Thus, according to the third embodiment, since the wireless card 50 includes the PON protocol termination unit 53, the information processing apparatus can be efficiently accommodated in the conventional optical access network via the wireless section. It becomes.

  As described above, the communication system and the media converter according to the present invention are suitable for data frame transmission / reception using the PON control protocol.

It is a figure which shows the structure of the communication system which concerns on Embodiment 1 of this invention. It is a block diagram which shows the structure of a media converter. It is a block diagram which shows the structure of radio | wireless ONU. 6 is a diagram showing a configuration of a mobile terminal according to Embodiment 2. FIG. FIG. 10 is a diagram illustrating a configuration of a wireless card according to a third embodiment.

Explanation of symbols

1 OLT
2 Star coupler 3 Optical fiber 4 PON control protocol termination 5 Wireless section 6 Optical section 12 Network side interface 21, 31, 41, 51 RF interface 22, 32, 52 Frame processing section 23 Parallel conversion section 24 EO / OE conversion section 25, 35, 47, 55 Wireless antenna 26 PON side interface 33 PON control unit 34 PHY unit 36 User side interface 40 Mobile terminal 42 PON protocol termination unit 43 Telephone communication unit 44 Voice processing unit 45 Data processing unit 46 Application unit 50 Wireless card 53 Protocol termination 54 Bus-type connector 100 Communication system C1, C2 Media converter a1-a6 Wireless ONU
b1-bn ONU

Claims (6)

A station side device connected to the wide area network;
An optical fiber network extending from the station side device;
A wireless communication device that performs wireless communication with a predetermined external device with terminating P ON control protocol between the station-side apparatus,
A media converter that performs transmission and reception of data frames with the station side device via the optical fiber network, and that transmits and receives data frames with the wireless communication device by wireless communication,
With
The communication system, wherein the media converter transparently transfers an access control frame between the station side device and the wireless communication device with a fixed delay.   The communication system according to claim 1, wherein the media converter performs wireless communication with a plurality of the wireless communication devices.   The said wireless communication apparatus is a subscriber side communication apparatus which accommodates a subscriber terminal and transfers a data frame to the subscriber terminal from the media converter to the subscriber terminal. The communication system according to 1.   The communication system according to claim 1, wherein the wireless communication device is a portable terminal that performs data processing using the data frame.   3. The wireless communication device according to claim 1, wherein the wireless communication device has a bus connector and transfers a data frame from the media converter to an information processing device connected via the bus connector. Communications system. In media converters that convert optical signals and electrical signals to each other,
An optical communication unit for transmitting and receiving data frames by optical communication with the station side device via an optical fiber network extended from the station side device connected to the wide area network;
A wireless communication unit for transmitting and receiving data frames by the wireless communication with the wireless communication device for terminating a P ON control protocol between the station-side apparatus,
It converts the optical signal of the data frame received from the station-side device to an electric signal, and the wireless electrical signals of the data frame received from the communication device into a light signal, and the station side device the data frame A transfer processing unit for transparently transferring with a fixed delay to and from the wireless communication device;
A media converter comprising:

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