JP2006109357A - Synchronous clock information transfer method, transmission apparatus and communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To establish clock frequency synchronism and clock timing synchronism between a transmission apparatus and a reception apparatus without individually transmitting, for each reception apparatus, an asynchronous data packet containing synchronous clock information. <P>SOLUTION: In the synchronous clock information transfer method, a transmission apparatus and a plurality of reception apparatuses are connected over an asynchronous network, synchronous clock information of the transmission apparatus is transmitted over the asynchronous network and each of the reception apparatus is synchronized with the transmission apparatus based on the synchronous clock information. The transmission apparatus generates a packet containing synchronous clock information for establishing clock frequency synchronism and clock timing synchronism between the transmission apparatus and the plurality of reception apparatuses and performs multi-address transfer of the packet through the asynchronous network to the plurality of reception apparatuses at fixed intervals. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a synchronous clock information transfer method, a transmission device, and a communication for transferring synchronous clock information for clock frequency synchronization and clock timing synchronization between a transmission device and a plurality of reception devices connected via an asynchronous network. About the system.

  In the prior art, when the synchronous clock information is to be transferred using an asynchronous communication frame such as LAN defined in IEEE802.3, the transmission device and the reception device are logically or physically 1 as shown in FIG. In the form of being connected in a one-to-one manner, synchronous clock information is transferred by being superimposed on an asynchronous data packet (Non-Patent Document 1). In such a form, when the synchronous clock information is distributed to a plurality of receiving apparatuses, the transmitting apparatus generates and transmits asynchronous data packets including the synchronous clock information by the number of receiving apparatuses.

  Also, when transferring asynchronous data packets to a single receiving device through a plurality of channels, the conventional technology transfers asynchronous data packets including synchronous clock information for each channel. However, the synchronous clock information transferred to one receiving device on each channel is usually the same except when the clock frequency is different for each channel, so the synchronous clock information is transferred on one of the channels. It is enough.

  Furthermore, as shown in FIG. 8, when a transmitting device and a plurality of receiving devices that operate in synchronization with a single clock frequency share a medium, specifically, a repeater hub that replicates asynchronous data packets on a LAN, When an asynchronous data packet is passively duplicated by an optical splitter used in optical fiber communication, an asynchronous data packet including synchronous clock information may be duplicated redundantly.

In addition, when asynchronous data packets that do not include synchronous clock information and asynchronous data packets that include synchronous clock information coexist, if the asynchronous data packet that includes synchronous clock information is lost, clock synchronization between the transmitting device and the receiving device is established. It may not be possible. In order to solve such a problem, a method of performing priority control (QoS) in which asynchronous data packets including synchronous clock information are preferentially transferred is used. When the amount of asynchronous data packets including the synchronous clock information is small, the clock synchronization between the transmission device and the reception device can be stably established by this priority control. However, when the bandwidth occupied by the asynchronous data packet including the synchronous clock information approaches the total bandwidth of the transmission path, priority control becomes difficult, and the asynchronous data packet including the synchronous clock information may be lost. In such a case, clock synchronization between the transmission device and the reception device may become unstable, and further, clock synchronization may not be established.
XiPeng Xiao, Danny McPherson, Prayson Pate, "Requirements for Pseudo-Wire Emulation Edge-to-Edge (PWE3)" draft-ietf-pwe3-requirements-08.txt, 2003

  Since the transmitting device needs to generate asynchronous data packets including the synchronous clock information as many as the number of receiving devices as described above, there is a problem that the generation amount of asynchronous data packets including the synchronous clock information increases with the number of receiving devices. there were. Further, when asynchronous data packets including synchronous clock information are transferred redundantly through a plurality of channels, or when redundantly replicated by a repeater hub or the like, effective use of the band is hindered.

  FIG. 9 shows a frame format of a conventional asynchronous data packet. Here, a frame format addressed to a home device applied to a passive transmission system (PON) is shown. Clock frequency synchronization is established between the transmitting device and the receiving device based on packet intervals and synchronous clock information TS1, TS2,. However, clock timing information that is an element of clock synchronization (for example, information for inserting timing information at an interval of 8 kHz into a 64 kHz base clock to obtain timing synchronization instead of frequency synchronization) cannot be transmitted.

  The present invention pays attention to the fact that the synchronous clock information does not necessarily have to be different for each receiving device, and without transmitting an asynchronous data packet including the synchronous clock information for each receiving device, between the transmitting device and the receiving device. It is an object of the present invention to provide a synchronous clock information transfer method, a transmission apparatus, and a communication system that can achieve clock frequency synchronization and clock timing synchronization.

  In the first aspect of the present invention, the transmitting device and the plurality of receiving devices are connected via an asynchronous network, and the synchronous clock information of the transmitting device is transmitted via the asynchronous network, and the receiving device is based on the synchronous clock information. In the synchronous clock information transfer method that synchronizes with the transmitting device, the transmitting device includes a packet including synchronous clock information for synchronizing clock frequency and clock timing between the transmitting device and a plurality of receiving devices, in addition to the asynchronous data packet. And broadcast-transmitted to a plurality of receiving devices at regular intervals via an asynchronous network.

  Here, the transmitting device and the plurality of receiving devices are connected via a passive transmission system using an optical fiber and an optical splitter, so that packets including synchronous clock information are broadcasted to the plurality of receiving devices at regular intervals. (Claim 2). In addition, the transmitting device and the plurality of receiving devices are connected via a hub type transmission system using a repeater hub or a switching hub, so that packets including synchronization clock information are broadcasted to the plurality of receiving devices at regular intervals. (Claim 3). Furthermore, the receiving device may have the function of a transmitting device, and packets including synchronous clock information may be broadcasted at regular intervals via the transmitting device and the receiving device connected in multiple stages.

  According to a fifth aspect of the present invention, there is provided a transmitting device that transmits synchronous clock information to a plurality of receiving devices connected via an asynchronous network via the asynchronous network. And a means for generating a packet including synchronous clock information for clock frequency synchronization and clock timing synchronization of the plurality of receiving apparatuses, and broadcast-transmitting the packets to the plurality of receiving apparatuses at regular intervals via an asynchronous network.

  According to the sixth aspect of the present invention, the transmission device and the plurality of reception devices are connected via an asynchronous network, and the synchronous clock information of the transmission device is transmitted via the asynchronous network, and the reception device is based on the synchronous clock information. In the communication system that synchronizes with the transmission device, the transmission device is configured to generate a packet including synchronous clock information separately from the asynchronous data packet, and to broadcast to multiple reception devices via the asynchronous network, The receiving apparatus is configured to perform clock frequency synchronization and clock timing synchronization with the transmitting apparatus based on the synchronous clock information.

  The present invention solves the problem of the prior art in which data packets including the same number of synchronous clock information as the receiving device are generated and transferred to all receiving devices, and broadcasts packets containing the same synchronous clock information at a fixed interval. Thus, clock frequency synchronization and clock timing synchronization can be achieved between the transmission device and the plurality of reception devices with a smaller amount of data transfer.

(First embodiment)
FIG. 1 shows a first embodiment of the present invention. Here, a passive transmission system (GE-PON) defined by IEEE802.3ah will be described as an example.

  In the figure, a transmitting apparatus (intra-station apparatus) 11 and a plurality of receiving apparatuses (in-house apparatuses) 12-1 to 12-3 are connected via an optical fiber 13 and an optical splitter 14. The transmitter 11 is supplied with the same synchronous clock signal as the synchronous clock signal supplied from the synchronous clock source 15 to the exchange or the like. The transmission device 11 processes the synchronous multiplexed signal transferred from the exchange or the like based on the synchronous clock signal. Further, the transmission device 11 generates a packet including synchronization clock information (hereinafter referred to as “clock synchronization packet”) based on the synchronization clock signal, and broadcasts the packet to the reception device 12 at regular intervals. The clock synchronization packet transmitted from the transmission device 11 is broadcast to all the reception devices 12-1 to 12-3 connected to the optical splitter 14.

  FIG. 2 shows the frame format of the clock synchronization packet of the first embodiment. The broadcast LLID is used for broadcasting the LLID to all receiving apparatuses 12. As a destination address, a broadcast address addressed to all receiving apparatuses 12 is used. A clock identifier and a delay time correction value are set in the payload. The receiving device 12 identifies the clock synchronization packet by the clock identifier. A receiving apparatus that does not require clock synchronization confirms the clock identifier and discards the clock synchronization packet. Note that a plurality of types of synchronous clock information can be transmitted by dividing the value of the clock identifier. The delay time correction value is an in-device delay in the transmission device 11, and the reception device 12 calculates the correct clock timing (time) by subtracting the delay time correction value from the reception time of the clock synchronization packet, and reproduces the timing. .

  The transmission device 11 broadcasts such a clock synchronization packet at a fixed interval separately from the data packet, thereby synchronizing the clock frequency as the average arrival interval of the packets in all the reception devices 12, and further delay time correction value Can be used for clock timing synchronization. The relationship between each timing is shown in FIG.

  As long as clock synchronization is established between the transmission device 11 and the reception device 12, the transmission device 11 divides the synchronous multiplexed signal from the exchange or the like into asynchronous data packets, and unicasts the reception device 12 as a destination. . In addition, the receiving device 12 divides the synchronous multiplex signal in the own device and the synchronous multiplex signal input from the terminal side into asynchronous data packets, and transmits the data to the transmission device 11 as a destination. Since the receiving device 12 connected to the optical splitter 14 can receive the same clock synchronization packet and establish clock synchronization with the transmitting device 11, the synchronization multiplexed signal can be packetized and transferred immediately after the synchronization is established. .

  Note that the receiving device 12 may have the function of the transmitting device 11 and may transmit the packet including the synchronous clock information at a fixed interval via the transmitting device 11 and the receiving device 12 connected in multiple stages. The same applies to the embodiments described below.

(Second Embodiment)
FIG. 4 shows a second embodiment of the present invention. Here, a hub type transmission system (LAN) defined by IEEE802.3 will be described as an example.

  In the figure, a transmitting apparatus (intra-station apparatus) 11 and a plurality of receiving apparatuses (in-house apparatuses) 12-1 to 12-3 are connected to each other via an electrical wiring 16 and a repeater hub 17 or a switching hub (L2SW). The transmitter 11 is supplied with the same synchronous clock signal as the synchronous clock signal supplied from the synchronous clock source 15 to the exchange or the like. The transmission device 11 processes the synchronous multiplexed signal transferred from the exchange or the like based on the synchronous clock signal. Further, the transmission device 11 generates a clock synchronization packet based on the synchronization clock signal, and broadcasts the packet to the reception device 12 at regular intervals. The clock synchronization packet transmitted from the transmission device 11 is duplicated by the repeater hub 17 and broadcast to all the reception devices 12-1 to 12-3.

  FIG. 5 shows a frame format of the clock synchronization packet of the second embodiment. A clock identifier and a delay time correction value are set in the payload. The transmission device 11 broadcasts such a clock synchronization packet at a fixed interval separately from the data packet, so that, as in the first embodiment, all the reception devices 12 use the clock frequency as the average packet arrival interval. Synchronization can be achieved and clock timing synchronization can be achieved using the delay time correction value.

  As long as clock synchronization is established between the transmission device 11 and the reception device 12, the transmission device 11 divides the synchronous multiplexed signal from the exchange or the like into asynchronous data packets, and unicasts the reception device 12 as a destination. . In addition, the receiving device 12 divides the synchronous multiplex signal in the own device and the synchronous multiplex signal input from the terminal side into asynchronous data packets, and transmits the data to the transmission device 11 as a destination. Since the receiving device 12 connected to the LAN via the repeater hub 17 or the L2SW can receive the same clock synchronization packet and establish clock synchronization with the transmitting device 11, the synchronization multiplexed signal is packetized immediately after the synchronization is established. Can be transferred.

(Third embodiment)
FIG. 6 shows a third embodiment of the present invention. The present embodiment shows a case where a plurality of synchronous multiplexed signals are handled by a plurality of receiving apparatuses in the PON connection mode of the first embodiment.

  In the figure, an exchange 22 is connected to the transmission apparatus 11 via a synchronous multiplex line 21, and a synchronous multiplex line 23 is connected to each of the receiving apparatuses 12-1 to 12-3. Other configurations are the same as those of the first embodiment.

  After establishing clock synchronization as in the first embodiment, the transmission device 11 divides the synchronous multiplexed signal from the exchange 22 into asynchronous data packets, and unicasts the reception device 12 as a destination. In addition, the receiving device 12 divides the synchronous multiplex signal in the own device and the synchronous multiplex signal input from the terminal side into asynchronous data packets, and transmits the data to the transmission device 11 as a destination.

The figure explaining the 1st Embodiment of this invention. The figure which shows the example of the frame format of the clock synchronization packet of 1st Embodiment. The figure which shows the relationship of each timing of 1st Embodiment. The figure explaining the 2nd Embodiment of this invention. The figure which shows the example of the frame format of the clock synchronization packet of 2nd Embodiment. The figure explaining the 3rd Embodiment of this invention. The figure explaining the transfer form of the conventional synchronous clock information. The figure explaining the transfer form of the conventional synchronous clock information. The figure which shows the example of the frame format of the conventional asynchronous data packet.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 Transmitter 12 Receiver 13 Optical fiber 14 Optical splitter 15 Synchronous clock source 16 Electric wiring 17 Repeater hub 21, 23 Synchronous multiplex line 22 Switch

Claims (6)

A synchronization clock in which a transmission device and a plurality of reception devices are connected via an asynchronous network, and the synchronous clock information of the transmission device is transmitted via the asynchronous network, and the reception device synchronizes with the transmission device based on the synchronous clock information In the information transfer method,
The transmitting device generates a packet including synchronous clock information for clock frequency synchronization and clock timing synchronization between the transmitting device and the plurality of receiving devices separately from the asynchronous data packet, and a plurality of packets are transmitted via the asynchronous network. Synchronous clock information transfer method, wherein broadcast transmission is performed at regular intervals to a receiver. In the synchronous clock information transfer method according to claim 1,
The transmitting apparatus and the plurality of receiving apparatuses are connected via a passive transmission system using an optical fiber and an optical splitter, and broadcast transmission of packets including the synchronous clock information to the plurality of receiving apparatuses at regular intervals. A method for transferring synchronous clock information. In the synchronous clock information transfer method according to claim 1,
The transmitting device and the plurality of receiving devices are connected via a hub type transmission system using a repeater hub or a switching hub, and broadcast transmission of packets including the synchronous clock information to the plurality of receiving devices at regular intervals. A method for transferring synchronous clock information. In the synchronous clock information transfer method according to claim 2 or 3,
Synchronous clock information transfer method characterized in that the receiver has the function of the transmitter, and the packet including the synchronous clock information is broadcasted at regular intervals via the transmitter and receiver connected in multiple stages. . In a transmitting device that transmits synchronous clock information via the asynchronous network to a plurality of receiving devices connected via the asynchronous network,
Separately from the asynchronous data packet, a packet including synchronous clock information for clock frequency synchronization and clock timing synchronization of the transmission device and the plurality of reception devices is generated, and the packet is transmitted to the plurality of reception devices via the asynchronous network at regular intervals. A transmission device comprising means for performing broadcast transmission using A communication system in which a transmission device and a plurality of reception devices are connected via an asynchronous network, and synchronous clock information of the transmission device is transmitted via the asynchronous network, and the reception device synchronizes with the transmission device based on the synchronous clock information In
The transmitting device is configured to generate a packet including synchronous clock information separately from an asynchronous data packet, and to broadcast to a plurality of receiving devices via the asynchronous network,
The communication system, wherein the reception device is configured to perform clock frequency synchronization and clock timing synchronization with the transmission device based on the synchronous clock information.

Images