JP3906920B2 - Internet access method - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an Internet access method in which an LSP (Label Switched Path) is set in an Internet network to perform information communication between computers.
[0002]
[Prior art]
[Patent Document 1]
    JP 2002-314487 A
[Patent Document 2]
    JP 2002-223235 A
[Patent Document 3]
    JP 2001-358777 A
  As shown in FIG. 10, in today's Internet configuration, in order to realize information communication between the terminal computers 10, a network in which a plurality of routers 14 are interposed is provided in the Internet 12, and each router 14 in the network is provided. The basic function is to detect a destination accompanying the input information and deliver the packet as the information to the destination. In the Internet 12, between the plurality of terminal computers 10, the transport layer of the fourth layer of the OSI 7 hierarchical model in the data format in TCP (Transmission Control Protocol) / IP (Internet Protocol) shown in FIG. Information transfer control is performed using the TCP protocol, which is a protocol, and each router 14 performs routing based on an IP address using a layer 3 Internet protocol in the network layer.
[0003]
  Each router 14 identifies the route based on the IP address present in the header attached to the packet, and sends the received packet to the identified route. Each router 14 pays attention only to the header of the packet and performs routing by looking at the header of the packet sent from the adjacent router.
[0004]
  More specifically, in communication on the Internet 12, data to be sent is first divided into a plurality of pieces, and each is attached with address information (header) to form a packet as shown in FIG. Data is transmitted and received between the terminal computers 10 based on this packet. As shown in FIG. 12, each packet is transferred from terminal A with packets A1, A2,... Destined for terminal B, and from terminal C with packets B1, B2,. , E send packets C1, C2,. This information reaches the router R1 and is sent to the transmission line 1 on the outgoing side. On the transmission line 1, packets with different destinations are packet-multiplexed and transmitted. A packet input to the router R2 having a plurality of outgoing side transmission paths is routed to a required path according to destination information in the header H. In this case, the packets C1, C2,... Having the destination D are routed to the transmission line 3 by the router R2 and reach the target terminal. Similarly, packets A1, A2,... With destination B are routed by router R3 and reach target terminal B, and packets B1, B2,... With destination F reach terminal F by router R3. To do.
[0005]
  On the other hand, data transfer control between the terminal computers 10 is performed by a TCP flow control procedure as shown in FIG. Connections in the TCP protocol are logically set between the terminal computers 10, and according to a control method defined by the TCP protocol, data transmission / reception is performed between terminals while confirming transmission / reception of each packet. FIG. 14 shows the entire data transmission system using the Internet 12 described above.
[0006]
  As described above, the router 14 is not aware of any TCP connection. The router 14 does not see when the TCP connection is set and when it is released, and a plurality of connections are confused and set, and the management of each TCP connection makes the function of the router 14 extremely complicated. Therefore, the router 14 does not perform any management related to setting / release of the TCP connection as indicated by the thin line arrow in FIG.
[0007]
  However, in recent years, various problems have occurred in the above-described Internet configuration method using the router method. In the Internet configuration method described above, all routers 14 interpret the IP header and perform routing based on the interpretation. Therefore, there are many variations in time delay, packet loss, etc., ensuring communication quality, and traffic engineering. It was difficult to implement. In order to solve the problem, a network configuration called MPLS (Multi Protocol Label Switching) has been devised. In MPLS, a new label is added to a packet, and routing is performed by paying attention only to the label, thereby performing high-speed routing and traffic engineering. In order to realize this, MPLS divides the router into the following two functions.
[0008]
  (1) Edge function having a function as a conventional IP router and having label generation and label erasing functions for realizing label switching (this function router is referred to as an edge label switch router, hereinafter simply referred to as an edge router LER (Edge Label Switching Router))
  (2) Core function for routing a packet based on a label added by an edge router (a router having this function is referred to as a core switch router, hereinafter simply referred to as a core router LSR (Label Switching Router))
The MPLS network 16 shown in FIGS. 16 and 17 (showing the MPLS concept) is configured.
[0009]
  Between the edge router LER and the edge router LER, the core router LSR simply looks at the label attached to the packet and routes to the port corresponding to the label, so the label is added to the packet input to the edge router LER. After that, the path through which the packet passes is uniquely determined. That is, in MPLS, a logically unique data path is formed between the edge router LER and the edge router LER. This is called LSP (Label Switched Path) and is an important concept in MPLS.
[0010]
  Next, the generation and erase timings of this LSP will be described. The LSP is generated in accordance with FEC (Forwarding Equivalence Class) in MPLS. The FEC is basically created based on the destination information, but is generated corresponding to the service class requested by the packet entering the router. Once generated, the FEC is not permanently erased. If it is erased, it will be forcibly reset. However, making an LSP is not particularly burdensome for the edge router LER, and it can be used even when it comes only by chance. It is only necessary to generate a label as a process for the corresponding packet. The LSP is logically created corresponding to the FEC associated therewith, and corresponds to one LSP for each packet. Therefore, in MPLS, it is not assumed that the LSP dynamically generates and disappears.
[0011]
  Furthermore, in recent years, the concept of LSP has been expanded to make it possible to materialize the LSP, and at the same time, the control plane is separated from the data plane so that control information can be sent and received in a separate network. ) Appeared. In GMPLS, control information transfer is performed using an architecture based on MPLS, and not only the Internet but also a network in a conventional telecommunications network can be used as a data path. That is, a time slot or LSP in TDM (Time Division Multi Plexing) can be assigned to the optical wavelength of optical communication, or the fiber itself can be used as an LCP. With this technology, a data path configured using a communication path using circuit switching technology such as a conventional space division switch, time division switch, or optical space division switch can be used as an LSP in the core router. It became so. In other words, it has become possible to use, as a core router, a device called a cross-connect that performs wavelength switching using wavelengths and optical switches in a wavelength division multiplexing transmission system.
[0012]
  An outline of GMPLS is shown in FIG. 18 by taking as an example the configuration of an optical router using an optical switch. In this case, each wavelength itself passing through the optical switch unit constitutes one LSP. In order to configure this LSP, MPLS only needed to create a label correspondence table (ILM) on the storage device using LDP (Label Distribution Protocol). In order to do this, it is necessary to distribute information (switch control command) for actually executing switch control by LDP and control the switch. As long as the LSP is present, this switch must continue to semi-fixedly connect the specific optical switch terminals to each other "semi-fixedly". In that sense, the data path in the GMPLS router using an optical switch is considered to be functionally similar to a conventional cross-connect.
[0013]
[Problems to be solved by the invention]
  In this way, it is necessary to keep the switch fixedly connected in the case of an LSP that is not used so much, because there is a substance called “wavelength”, which requires a cost for that. This will use more wavelengths than necessary, increasing system costs. On the other hand, as described above, the TCP connection is basically set at the start of data transmission and is released when the data transmission is completed. In other words, it is set as needed and is designed to be opened when it is no longer needed. In the method of configuring an LSP by setting a line using a switch, a path actually physically exists. Therefore, when a path is not actually used, it is opened, that is, a TCP connection setting is released. Therefore, if the LSP can be set to be released, it is not necessary to continue using a useless path, which is effective.
[0014]
  However, even in GMPLS, it is difficult to set the LSP according to the TCP connection. This is because the network targeted by GMPLS is premised on a network composed of routers, and there is no substitute for MPLS and its points. That is, GMPLS, like MPLS, can only be used in a form in which a plurality of connections are bundled at one wavelength. This relationship is shown in FIG. The wavelength LSP1 is one LSP set between LER1 and LER2. Further, when packet A is a packet going from router R1 to router R4 and packet B is going from router R2 to router R3, a certain FEC that has already been set.
When the wavelength LSP1 corresponding to is set, packet A and packet B have different destinations, but the same FEC is used between LER1 and LER2, so that packets with different destinations are classified into the same FEC and multiplexed. Therefore, the wavelength LSP is effectively used without waste even if the setting is semi-fixed without setting the LSP for each TCP connection. That is, the LSP can be used sufficiently effectively without corresponding to the TCP connection. Conversely, unless such an LSP setting is performed (the LSP setting considering the traffic situation must be performed), the wavelength usage rate is poor, resulting in a high-cost network.
[0015]
  In GMPLS, the LSP has been expanded to include various types of LSP, but the character of the LSP is left as it is, is generated for the FEC, and the connection state is held semi-fixed. For example, when a fiber is set as LSP and set using a switch, it is necessary to keep the switch semi-fixed. This means that the technology previously developed as a cross-connect can be used as it is, so that the conventional cross-connect is used as a core router by GMPLS on the Internet.
[0016]
  However, in this case, the semi-fixed connection is basically used, and the path setting is not performed in accordance with the setting / release of the TCP connection. If an incoming packet is examined and an LSP corresponding to a specific FEC is clearly established, the packet will be sent even if it is sufficiently fast in time. Since it cannot be identified, it is difficult to finely set and release the LSP according to the reception and transmission of the packet.
[0017]
  On the other hand, if the setting is not finely opened, the usage rate for that wavelength will be poor and the efficiency will be poor. However, in the current cross-connect, such fine setting is difficult for the above reasons. Furthermore, in the current method, it is difficult to set and release the LSP in accordance with the setting and release of the TCP connection. When the router is used, it is necessary to perform the following.
[0018]
  First, it is necessary to see the information of the TCP header in the router. That is, it is necessary to terminate the TCP header, look at the TCP header, look at the connection setting information in the header, and exchange label information using LDP based on the information. After that, it is necessary to carry out a process for finding TCP connection release information by looking at all TCP headers for each packet. Furthermore, if the TCP connection release is found as a result, it is necessary to perform LSP release processing using LDP. A packet from a plurality of terminals is input to one router, and it is necessary to examine all the TCP headers of the input information. This greatly increases the load on the router, and it is practically difficult to implement it.
[0019]
  The present invention has been made in view of the above-mentioned problems of the prior art. By realizing the setting / release of the LSP in accordance with the setting / opening of the TCP connection, the LSP usage rate is improved and the economical Internet is established. The purpose is to provide an access method.
[0020]
[Means for Solving the Problems]
  In the present invention, each terminal computer on the Internet has the function of an edge router in the MPLS network. In each terminal computer, in accordance with the setting / release processing of the TCP connection formed by the Internet transport layer protocol, This is an Internet access method for performing LSP setting / release processing. That is, as shown in FIG. 1, an LSP is set or released in correspondence with setting / release of a TCP connection between terminal computers.
[0021]
  In the edge router function, the FEC is determined by looking at the header of the input packet, and a set of labels corresponding to the FEC is created (implemented using the LDP protocol). If the processing is brought to the terminal computer as it is, the input of the FEC classification can be made into an application program existing in the terminal computer, the LSP setting can be released in correspondence with the application, and the TCP connection release setting. Can be synchronized with LSP setting / release.
[0022]
  The TCP connection is required when the application needs to send data to the partner terminal, and disappears when the necessary data has been sent. The LSP usage efficiency can be increased by setting and releasing the LSP accordingly.
[0023]
  In addition to the transport layer protocol of TCP, the method of the present invention can be applied to UDP (User Datagram Protocol) which is the same transport layer protocol. That is, since the application software can know the timing for starting the data transfer process, the LSP can be set in accordance with this.
[0024]
DETAILED DESCRIPTION OF THE INVENTION
  Embodiments of the Internet access system of the present invention will be described below with reference to the drawings. Here, the symbols and alphabetical symbols used in the following are the same as those in the above-described conventional technology. FIG. 2 shows a first embodiment showing a basic configuration by MPLS of this system. A plurality of terminal computer groups T1 to Tn are connected to the router R1 through 100BASE-T or 1-Gigabit Ethernet cables, respectively, and other terminal computer groups S1 to Sn are accommodated in the router R2 by their own cables. Furthermore, each terminal computer 10 of the terminal computer groups Tn and Sn is equipped with a function (LER) as an edge router in MLPS, and a function (LSR) as an MPLS core router is implemented in the routers R1 and R2. . In this embodiment, the function as the edge router provided in the terminal computer 10 is displayed as CLER. An MPLS network 16 is formed including the terminal computer groups Sn and Tn.
[0025]
  When one terminal computer T1 transmits data to the terminal computer S1, the LSP is set for the pair S1 before executing the TCP connection. Since the data transmission request is classified into a specific FEC, the FEC information is set in the LSP setting.Using the control path needed toThis is done by making a label setting request to each of the core routers R1 and R2. As a result, the label correspondence is created in the label correspondence table ILM of the storage device of the terminal computer 10. Upon completion of the setting, a packet is transmitted and a TCP connection is established. When the data transmission is completed, the TCP connection is released, and the LSP release processing is performed based on the TCP connection.
[0026]
  The configuration of the terminal computer 10 of this embodiment is shown in FIG. The terminal computer 10 is mounted with a terminal communication board 24 connected to the LAN card 20 through an Ethernet interface, for example, in order to realize communication in this patent. The terminal communication board 24 turns on an LD (laser diode) corresponding to the wavelength specified by the control signal passed through the RS232C, and sends data to be sent to the subscriber optical fiber 26. An optical path formed through the optical fiber 26 and an optical switch fabric (not shown) in the optical label switch router is an LSP. That is, a data plane based on the GMPLS architecture is configured by this path.
[0027]
  In this embodiment, when the application program of the terminal computer 10 requests a TCP connection by the MPLS architecture configured by the CLER function of the terminal computer 10 and the LSRs of the routers R1 and R2, the LSP is set before the TCP connection is set. Set. In this embodiment, a necessary wavelength is transmitted by the terminal communication board 24, a path for reaching the wavelength to the partner terminal computer 10 is set, and this is used as an LSP, and then a TCP connection is set and necessary data is transmitted and received. After the data transmission / reception is completed, the TCP connection is first released, and then the LSP is released. In this embodiment, the wavelength can be effectively used by making the wavelength correspond to the LSP.
[0028]
  FIG. 4 shows a second embodiment of the Internet access system of the present invention. The terminal computer groups T1 to Tn are aggregated into one cable by, for example, a hub (hereinafter referred to as HUB) in an Ethernet (registered trademark) work and connected to one port of the router R1. Similarly, the terminal computer groups Y1 to Yn are connected to one port of R1 via a HUB, and the terminal computer groups S1 to Sn and X1 to Xn are similarly connected to the R2 port via a HUB. Yes. The router R1 is connected to the router R2 through a transmission line. However, logically, each terminal computer 10 is controlled so as to be connected to each router R1, R2 on a one-to-one basis. That is, the logical configuration is the same as in FIG.
[0029]
  Each terminal computer 10 of this terminal computer group Tn, Yn, Sn, Xn has an edge router function (LER) in MPLS, and the routers R1 and R2 have a function as a core router (LSR). It is assumed that an MPLS network including the terminal computer 10 is formed, and the setting release of the LSP is performed in accordance with the setting / release of the TCP connection in the same manner as described in the first embodiment.
[0030]
  FIG. 5 shows a third embodiment of the Internet access system of the present invention. In FIG. 5, the GMPLS architecture is composed of terminal computer groups Tn and Sn and a wavelength router OLSR connected by an optical fiber 28. The wavelength router OLSR includes an optical switch fabric 30 including wavelength multiplexing, wavelength separation circuits, and optical switches for routing each wavelength. Further, the wavelength router OLSR includes a control device LSR-C for controlling the optical switch, and implements a core router function in MPLS. The connection state of the input port and the output port in the optical switch fabric 30 can be controlled by the control information from the control device LSR-C. An edge function CLER in the MPLS architecture is implemented in the terminal computer groups Tn and Sn. Also in this embodiment, a control plane in the MPLS architecture is formed by CLER and LSR-C.
[0031]
  FIG. 6 shows a fourth embodiment of the Internet access system according to the present invention, in which a plurality of LSPs can be set from one terminal computer 10 by allowing a plurality of wavelengths to be transmitted and received simultaneously. Indicates. That is, by independently controlling the laser diode LD in the terminal communication board 24 so as to be able to transmit and receive arbitrary plural wavelengths and having a plurality of ether interfaces, a plurality of information can be simultaneously transmitted to the terminal communication board 24. Can send and receive. By this method, TCP connections can be set simultaneously for the number of wavelengths independently, and more services can be realized.
[0032]
  In the embodiment of FIGS. 2 and 4, all are configured by an electric system, and it is appropriate that data and control information are transmitted on the same transmission path and the same medium. In the GMPLS architecture, it is basically assumed that the data plane and the control plane are physically different. Therefore, the control information does not need to be transmitted on the data path configured by the wavelength configured in FIG. 3 of the first embodiment, and there is no problem even if it is transmitted on the Internet configured by the conventional electric technology.
[0033]
  FIG. 7 shows a fifth embodiment of the Internet access system of the present invention. In this embodiment, in FIG. 6 of the fourth embodiment, a wavelength λ 0 different from the wavelength for setting the LSP is prepared, and the data Is configured to transmit on the same fiber 26 and is configured to physically share a transmission path although it is a logically different path. Wavelength multiplexing is possible on the fiber prepared for the LSP, and information is not mixed if the wavelengths are different, so that a separate medium for the control plane is not required and an economical configuration is possible. The same concept can be applied to FIG. 3 of the first embodiment.
[0034]
  FIG. 8 shows a sixth embodiment of the Internet access system of the present invention. An optical coupler 32 is introduced into a fiber 26 connecting the terminal computer 10 and the wavelength router OLSR, and a plurality of terminals are connected to one port of the wavelength router OLSR. In this embodiment, the computer 10 can be connected. As shown in FIG. 9, for example, the number of wavelengths of 8 can be shared by 32 terminal computers, and the 32 terminal computers 10 can use any free wavelength. is there. This means that four terminals use one wavelength on average, and the use efficiency of the wavelength can be improved. This is an effective method for system economy although it is necessary to determine the average number of terminal computers per wavelength depending on the frequency of use of each terminal.
[0035]
  For this embodiment as well as for the one shown in FIG.
      (1) Integrate with the data path of the control path.
      (2) A plurality of wavelengths LSP can be set simultaneously by allowing one terminal computer to simultaneously transmit and receive a plurality of wavelengths.
There is an example.
[0036]
【The invention's effect】
  The present invention provides a TCP connection setting in communication between terminal computers connected on the Internet.Since the LSP is set, the TCP connection is released when the packet transmission is completed, and then the LSP is released., Improve the LSP usage rate, high-speed and large-capacity communication with an economical and simple configurationsafelyIt can be achieved.Similarly, in UDP communication of the transport layer protocol of the layered communication standard, high-speed and high-quality communication by LSP can be safely performed.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing a process (a) in a terminal computer and a process (b) in a terminal computer according to the present invention in TCP / IP of the prior art.
FIG. 2 is a conceptual diagram of a basic configuration of an Internet access method based on an MPLS architecture according to the first embodiment of this invention.
FIG. 3 is a schematic diagram showing the configuration of a terminal computer according to the first embodiment of the present invention.
FIG. 4 is a conceptual diagram of a basic configuration of an Internet access method based on an MPLS architecture according to a second embodiment of the present invention.
FIG. 5 is a conceptual diagram of a basic configuration of an Internet access system based on an MPLS architecture according to a third embodiment of the present invention.
FIG. 6 is a schematic diagram showing the configuration of a terminal computer according to a fourth embodiment of the present invention.
FIG. 7 is a schematic diagram showing the configuration of a terminal computer according to a fifth embodiment of the present invention.
FIG. 8 is a conceptual diagram of a basic configuration of an Internet access system based on an MPLS architecture according to a sixth embodiment of the present invention.
FIG. 9 is a schematic diagram showing a connection example of a terminal computer according to a sixth embodiment of the present invention.
FIG. 10 is a schematic diagram showing a basic configuration of the Internet.
FIG. 11 is a schematic diagram showing a data format in TCP / IP.
FIG. 12 is a conceptual diagram showing a packet transfer method.
FIG. 13 is a schematic diagram illustrating a TCP flow control function;
FIG. 14 is a schematic diagram showing an Internet information transfer method.
FIG. 15 is a conceptual diagram illustrating a processing hierarchy of a router.
FIG. 16 is a conceptual diagram showing an MPLS architecture.
FIG. 17 is a conceptual diagram showing packet transfer in MPLS.
FIG. 18 is a conceptual diagram of a GMPLS router.
FIG. 19 is a conceptual diagram showing a packet transfer method in a GMPLS network using a wavelength LSP.
[Explanation of symbols]
  10 Terminal computer
  12 Internet
  14 routers
  16 MPLS network

Claims (6)

Each terminal computer on the Internet is provided with a label generation / deletion function for realizing label switching, which is an edge router function in MPLS (Multi Protocol Label Switching) architecture. When a TCP (Transmission Control Protocol) connection formed by a transport layer protocol that is a hierarchical communication standard is requested, before setting the TCP connection, an LSP (Label Switched Path) is processed by a processing method based on the MPLS architecture. ) , And after confirming the setting, the TCP connection is set, the packet is transmitted by TCP / IP (Internet Protocol) communication, and when the packet transmission by TCP / IP communication is completed, the TCP connection is first set. An Internet access system characterized in that, based on this, the LSP is released by a processing system based on the MPLS architecture . A plurality of terminal computers connected via an optical coupler to one optical fiber connected to a wavelength router that performs wavelength switching using an optical switch are formed by the transport layer protocol of the hierarchical communication standard. In the Internet access method for TCP / IP communication , the wavelength router has a core router function in the GMPLS (Generalized Multi Protocol Label Switching) architecture, but has a function to route packets based on the label added by the edge router. and, where the terminal computer is an edge router functionality in GMPLS architecture implements the label generation label erase function for realizing label switching, wherein each terminal computer is the application program, the Doo When a TCP connection formed by the transport layer protocol is requested, before setting the TCP connection, an LSP is set by a processing method based on the MPLS architecture, and after confirming the setting, the TCP connection is set. The packet is transmitted by TCP / IP communication, and when the packet transmission by TCP / IP communication is completed, the TCP connection is first released, and based on this, the LSP is released by the processing method based on the MPLS architecture. Internet access method characterized by processing . 3. The Internet access system according to claim 2 , wherein an optical coupler and an optical fiber that connect the terminal computer and the wavelength router are used as a control information transmission path in a control plane of a GMPLS architecture . 4. The Internet access system according to claim 2, wherein said terminal computer is provided with means for simultaneously oscillating a plurality of different wavelengths so that a plurality of TCP connections can be simultaneously formed . Each terminal computer on the Internet is provided with a label generation / deletion function for realizing label switching, which is a function of an edge router in the MPLS architecture, and the application program of the terminal computer is a hierarchical communication standard. When performing communication using UDP (User Datagram Protocol) of a certain transport layer protocol, before sending a packet by the UDP communication, an LSP is set by a processing method based on the MPLS architecture, and after confirming the setting, the UDP communication The Internet access system characterized in that the LSP is released by the processing system based on the MPLS architecture based on completion of packet transmission by the UDP communication . A plurality of terminal computers connected via an optical coupler to one optical fiber connected to a wavelength router that performs wavelength switching using an optical switch are connected to each other by means of a transport layer protocol UDP (User Datagram Protocol) In the Internet access method for performing communication, the wavelength router has a function of routing a packet based on a label added by an edge router, which is a core router function in the GMPLS architecture. where the edge router functionality in GMPLS architecture implements the label generation label erase function for realizing label switching, wherein each terminal computer is the application program, when performing the UDP communication, the UDP communication In Before sending the packet, the LSP is set by the processing method based on the MPLS architecture, and after confirming the setting, the packet is sent by the UDP communication. Further, based on the end of sending the packet by the UDP communication, An Internet access system characterized in that the LSP release processing is performed by a processing system based on an MPLS architecture .

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