1. Field of the Invention
The present invention relates to a line access termination system, an access device and a line accommodation method used therefor and, more particularly, a ring-type asymmetric access line termination system in which a ring is formed of up and down asymmetric access devices.
2. Description of the Related Art
With the spread of ADSL (Asymmetric Digital Subscriber Line) and the like, broadband system has been rapidly adopted for access lines in our country and other foreign countries.
On the side of a central office, disposed is an access multiplexer (AM) 806 which terminates these plurality of access lines and integrate them into one high-speed signal. The access multiplexer 806 is internally provided with an integrated gateway unit (IGU) 807 and a line termination unit (LTU) 808.
At the integrated gateway unit 807, signal protocol conversion is executed as required as well as multiplexing. Disposed farther to the access multiplexer 806 is a switch/router 804 through which a signal goes out to an internet 803. Farther to the internet 803, connection is made to an ISP (Internet Service Provider) server 801 and the like again through a switch/router 802.
The access multiplexer 806, which has been conventionally disposed in many cases in a central office of a carrier [GC (Group Unit Center) etc.], is recently demanded to locate extending far away from a central office in order to accommodate users at remote places. In this case, optical fibers extend from a central office to a remote place and ordinarily disposed, at the remote place, is a small-sized access line termination device taking economical efficiency and space-saving into consideration.
For such a small-sized access line termination device, realization of a highly reliable device is required which has a function of monitoring control at a remote place, in particular, a function of giving a notification and recovering a failure when a failure occurs, and as a solution, proposed is a method of, in a network structure in which with a central office at the center, pipelines radially extend to a remote office having a small capacity, causing signals go around by connecting devices at remote offices in a ring.
In the above-described conventional access line termination system in which signals go around in a ring with devices at remote offices connected, however, an increase in ring transmission capacity requires modification/ expansion of hardware such as new introduction of an optical interface. Under these circumstances, transmission efficiency of already set up optical fibers should be further improved to increase economical efficiency of the system as a whole.
An object of the present invention is to solve the above-described problem and provide an access line termination system, an access line termination device and a transmission control method which realize expansion of a down transmission capacity in a normal state without changing/expanding a transmission path interface.
More specifically, the access line termination system according to the present invention is premised on a network structure in which a telephone exchange is located at the center (hereinafter referred to as a central office), from which pipelines radially extend to an office at a remote place whose capacity is small (hereinafter referred to as a remote office).
In such a network structure, at the time of realizing a line accommodation method which enables an access line termination device with a small capacity disposed extending to a remote office to be efficiently accommodated at a central office and which has high reliability as a whole, adapting a ring structure to an up and down asymmetric access lines enables more efficient use of optical fibers and expansion of a transmission capacity.
According to one aspect of the invention, an access line termination system with an access line termination device which terminates asymmetric up signal and down signal connected in a ring for causing the up signal and the down signal to travel, wherein the down signal is separated to travel rightward and leftward on the ring, and the access line termination device includes a multiplexing unit which multiplexes either one of the rightward and leftward down signals with the up signal to transmit the multiplexed signal on the same signal line.
In other words, the access line termination system according to the present invention enables expansion of a transmission capacity in a normal state without involving change or expansion of hardware by assigning a part of a down signal to a free band of an up signal flowing on the ring.
In addition, by giving two priorities, high priority and low priority, to a down signal, the access line termination system according to the present invention enables a down signal having high priority to be remedied at the time of switching a direction of a signal going around on the ring in an emergency.
Furthermore, the access line termination system according to the present invention enables rapid control operation by giving a warning notification or executing switching control by using overhead of a main signal going around in the ring.
The present invention attains the effect of realizing expansion of a down transmission capacity in a normal state without change/expansion of a transmission line interface by the structure and operation set forth in the following.
Other objects, features and advantages of the present invention will become clear from the detailed description given herebelow.
The present invention will be understood more fully from the detailed description given herebelow and from the accompanying drawings of the preferred embodiment of the invention, which, however, should not be taken to be limitative to the invention, but are for explanation and understanding only.
In the drawings:
The preferred embodiment of the present invention will be discussed hereinafter in detail with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. It will be obvious, however, to those skilled in the art that the present invention may be practiced without these specific details. In other instance, well-known structures are not shown in detail in order to unnecessary obscure the present invention.
In
The parent device 1 includes a first optical expansion unit (OEU) 11, an integrated gateway unit (IGU) 12, line termination units (LTU) 13-1 to 13-n and a second optical expansion unit (OEU) 14.
The remote devices 2-1 to 2-6 include third optical expansion units (OEU) 21-1 to 21-6 (the third optical expansion units 21-2 to 21-5 are not shown), interface units (INF) 22-1 to 22-6 (the interface units 22-2 to 22-5 are not shown) and line termination units (LTU) 23-1 to 23-6 and 24-1 to 24-6 (the line termination units 23-2 to 23-5 and 24-2 to 24-5 are not shown), respectively.
The remote devices 2-1 to 2-6 terminate such an asymmetric access line in which a volume of data of an up signal is small as compared with that of a down signal as ADSL (Asymmetric Digital Subscriber Line).
A down signal 103 applied to the parent device 1 from the Internet through the switch/router 3 or the like is branched at the first optical expansion unit 11 into a signal to be processed within the device and a signal directed to the downstream remote devices 2-1 to 2-6. Executed here is simple branching into two (copying of an original signal).
The signal directed to the parent device 1 is applied to the integrated gateway unit (IGU) 12 and output to an access line further through the line termination units (LTU) 13-1 to 13-n.
On the other hand, a signal directed to the downstream remote devices 2-1 to 2-6 is divided into two directions at the second optical expansion unit 14 to hereafter generate a clockwise signal 107 and a counterclockwise signal 106. In this case, separation is made such that an original signal is logical multiplexing of the counterclockwise signal 106 and the clockwise signal 107.
Upper limit of a capacity of the counterclockwise signal 106 is a transmission capacity of a signal line (optical fiber and the like) forming the ring, while an upper limit of a capacity of the clockwise signal 107 is set to be a value obtained by subtracting a total sum of up signal capacities (which will be described later) of the respective remote devices 2-1 to 2-6 from a transmission capacity of a signal line (optical fiber and the like) forming the ring.
The counterclockwise signal 106 is applied to its first remote device 2-1 shown in
The counterclockwise signal 106 goes around counterclockwise through the remote devices 2-1 to 2-6 connected in the ring as described above and is branched and distributed by the respective remote devices 2-1 to 2-6.
The clockwise signal 107, similarly to the above-described counterclockwise signal 106, is also applied to its first remote device 2-6 and goes clockwise around the ring to be branched and distributed at the respective remote devices 2-6 to 2-1.
Next, operation of the present embodiment will be described along a flow of an up signal with reference to
An up signal on an access line 126 accommodated in the remote device 2-6 is applied to the interface unit 22-6 through the line termination units 23-6 and 24-6 and multiplexed. The up signal multiplexed at the interface unit 22-6 is further applied to the third optical expansion unit 21-6 and multiplexed with the clockwise down signal 107 from the parent device 1 and sent out as a signal 125 directed to the adjacent remote device 2-5 (see
Thus, in the present embodiment, up signals of the remote devices 2-1 to 2-6 connected in a ring are sequentially collected and multiplexed to ultimately input a multiplexed signal 111 to the parent device 1 from the last remote device 2-1.
The parent device 1 multiplexes the up signal 111 collected (multiplexed) while traveling around the ring and an up signal on an access line 105 accommodated in the parent device I itself, and after separating and abandoning the clockwise down signal 107 which has been transmitted by the parent device 1 by itself to go around the ring, outputs the obtained signal to the switch/router 3 at the succeeding stage or the like.
As described above, down signals are traveled in two directions, counterclockwise and clockwise, on the ring, which are delivered by broadcasting to the respective remote devices 2-1 to 2-6 and up signals are traveled clockwise on the ring, which are collected and multiplexed.
Here, determine assignment of signals such that a total sum of clockwise down signals and up signals fails to exceed a transmission capacity of a signal line (optical fiber or the like).
Although a signal format should be selected to meet a system of an access device, in a case of an ADSL, for example, the access line termination device according to the present embodiment can be structured, with optical ATM (Asynchronous Transfer Mode) signals going around on a ring, by executing optical branching or cell copying for a down signal and executing cell multiplexing for an up signal.
At the time of separating the clockwise down signal 107 and the counterclockwise down signal 106 in the parent device 1, a cell flow is separated by using a virtual path (VP) number, a virtual channel (VC) number of an ATM or the like to assign a VP number or VC number varying with each direction as identification information. Since a clockwise signal is a signal obtained by multiplexing the down signal 107 from the parent device 1 and an up signal, a VP number or a VC number varying with the up direction and the down direction is assigned as identification information for separating a down signal at the respective remote devices 2-1 to 2-6.
Although illustrated in
In
In
In
In this case, the clockwise down signal has its transmission from the parent device 1 stopped. Accordingly, a down signal having high priority is assigned to a counterclockwise down signal and on the assumption that a clockwise down signal might be cut off in an emergency, a signal having low priority is assigned to the signal.
In
For an input/output interface of the first optical expansion unit 11, an optical signal, more specifically, an ATM over SDH is assumed. In other words, the input/output unit is mounted with the optical/electrical conversion units 31, 38 and 43, the electrical/optical conversion units 34, 40 and 41 and the SDH termination units 32, 35, 37, 39, 42 and 44. 306 in
A down signal 303 from the higher-order device is branched into two by the signal branching unit 36, one of which will be sent out as a down signal 307 in its own device and the other of which will be sent out as a down signal 301 to the second optical expansion unit 14.
305 in
In
These ATM cell selection units 67, 68 and 69 identify a signal on an ATM cell level to transmit only a signal having a specific VP number or VC number (identification number) according to an instruction of the clock selection/pulse generation control unit 65.
The ATM cell selection unit 67 selectively transmits only a counterclockwise down signal 507 out of a down signal 503 received from the first optical expansion unit 11.
While the ATM cell selection unit 68 selects and transmits only a clockwise down signal 501 out of the down signal 503 received from the optical expansion unit 11 in a normal state, when a failure occurs in the remote devices 2-1 to 2-6 to execute recovering by the ring, it selectively transmits the same down signal as the counterclockwise down signal 507 according to an instruction of the clock selection/pulse generation control unit 65 (see
The ATM cell selection unit 69 selectively transmits only an up signal 504 out of signals 502 and 506 received from the remote office (see
The third optical expansion units 21-1 to 21-6 include ATM cell multiplexing units 71 and 73, signal branching units 72, 75 and 91 to 93, an ATM cell selection unit 74, SDH termination units 76, 78, 81 and 83, optical/electrical conversion units 77 and 82, electrical/optical conversion units 79 and 80, a clock selection/pulse generation control unit 84, an internal oscillator 85, selection units 86 to 90 and ATM cell extraction units 94 to 97.
In other words, the third optical expansion units 21-1 to 21-6, whose basic structure is that of the second optical expansion unit 14 of the parent device 1 illustrated in
Disposing the selection units 86 to 90 and the signal branching units 72, 75 and 91 to 93 in a manner as described in
The ATM cell extraction circuits 94 to 97 are circuits for extracting a main signal cell when necessary in order to avoid meaningless signal multiplexing. The clock selection/pulse generation control unit 84 is mounted with, in addition to the clock selection and pulse generation function, the control function of controlling the selection units 86 to 90 and the ATM cell extraction circuits 94 to 97 based on overhead information (F1, K1/K2) received from the SDH termination units 76, 78, 81 and 83.
The signal branching unit 72, similarly to the signal branching units 75 and 91 to 93, is a circuit for simply branching a signal into two (copying). The ATM cell selection unit 74 operates to transmit only a signal designated as a down signal based on identification information set in advance, for example, a VP number or a VC number of an ATM cell or the like.
Accordingly, it is necessary in the present embodiment to assign different identification information (VP number or VC number, etc.) to an up signal and a down signal in advance. The ATM cell multiplexing unit 71 multiplexes a clockwise down signal and a counterclockwise down signal and transmits the obtained signal to the interface units 22-1 to 22-6 in the devices. For multiplexing on an ATM level, simple cell multiplexing is executed. The interface units 22-1 to 22-6 are assumed to have sufficient performance for processing a down signal thus multiplexed and restored.
In the present embodiment, a down signal is transmitted to the respective remote devices 2-1 to 2-6 bidirectionally, clockwise and counterclockwise, in a normal state as shown in
In
In the following, description will be specifically made of operation of the first optical expansion unit 11, the second optical expansion unit 14 and the third optical expansion units 21-1 to 21-6.
As a method of making a down signal which travels counterclockwise in a normal state go clockwise in an emergency, executed are notifying a warning and switching control by using overhead information of a main signal. Each device discriminates a signal traveling direction by information included in the overhead information to operate a signal selection circuit.
The parent device 1 transmits a down signal in two directions, clockwise and counterclockwise in a normal state, while it stops a clockwise signal and broadcasts a counterclockwise signal rightward and leftward in an emergency. This ensures a path for a down signal having high priority to reach the respective remote devices 2-1 to 2-6.
More specifically, at the parent device 1, the ATM cell selection unit operates with a warning notification of a failure from the remote devices 2-1 to 2-6 as a trigger to cause the same down signal (down signal having the same identification information) to flow in both right and left directions. While this can be realized by a CPU control circuit, realization all by a hardware circuit enables high-speed failure evaluation and switching operation to be realized.
The down signal 503 received from the first optical expansion unit 11 is separated into the counterclockwise signal 507 and the clockwise signal 501 by the signal branching unit 56 and the ATM cell selection units 67 and 68. To the counterclockwise signal 507 and the clockwise signal 501, different identification information is assigned.
The counterclockwise signal 502 having made the round of the ring is the same as the transmitted counterclockwise signal 507. The clockwise signal 506 having made the round of the ring is a signal obtained by multiplexing the transmitted clockwise signal 501 with the up signals of the respective remote devices 2-1 to 2-6.
The counterclockwise signal 502 and the clockwise signal 506 are multiplexed by the ATM cell multiplexing unit 53 and then only an up signal is selected by the ATM cell selection unit 69 and transmitted as the signal 504 to the first optical expansion unit 11.
In
At that time, the clockwise signal 501 will be the same signal as the counterclockwise signal 507. The counterclockwise signal 502 and the clockwise signal 506 to be received are both signals obtained by multiplexing an up signal of the respective remote devices 2-1 to 2-6.
The received counterclockwise signal 502 and clockwise signal 506, after being multiplexed by the ATM cell multiplexing unit 53 to pass through the ATM cell selection unit 69, are transmitted to the first optical expansion unit 11. At that time, the ATM cell selection unit 69 transmits all the applied signals.
Out of a received clockwise signal 702 (a signal obtained by multiplexing a down signal and an up signal), only a down signal is transmitted through the ATM cell selection unit 74 and applied to the ATM cell multiplexing unit 71. Here, the signal is multiplexed with a counterclockwise down signal 703 to restore a down signal in the parent device 1, which signal is applied to the interface units 22-1 to 22-6.
The clockwise signal 702 to be received is multiplexed at the ATM cell multiplexing unit 73 with an up signal 706 of the device in question and transmitted as a clockwise signal 704 to the remote device at the subsequent stage.
By bringing the respective selection units 86 to 90 into a state as shown in
At the third optical expansion units 21-5 and 21-6 of the remote offices #5 and #6, for example, the received clockwise signal 702 is multiplexed with the up signal 706 at the ATM cell multiplexing unit 73 and the multiplexed signal is branched by the signal branching unit 92, so that one is transmitted as the down signal 704 to the adjacent remote device and the other is sent to the selection unit 88 and transmitted as a counterclockwise signal 701 (up signal).
In addition, at the third optical expansion units 21-1, 21-2 and 21-3 of the remote offices #1, #2 and #3, the received counterclockwise signal 703 is branched by the signal branching unit 75, so that one is transmitted as the counterclockwise signal 701 and the other is multiplexed with an up signal at the ATM cell multiplexing unit 73 through the selection unit 89 and transmitted as the clockwise signal 704 (up signal).
At that time, the ATM cell selection unit 74 prevents a signal from transmitting such that both the rightward and leftward received signals 702 and 703 are not multiplexed by the ATM cell multiplexing unit 71.
Thus, by assigning a part of a down signal to a free band of an up signal flowing on the ring, the present embodiment enables a transmission capacity in a normal state to be increased without involving change or expansion of hardware.
In addition, by giving a down signal two priorities, high priority and low priority, the present embodiment enables a down signal having high priority to be remedied at the time of switching a direction of a signal traveling on the ring in an emergency.
Furthermore, the present embodiment realizes rapid control operation by using overhead information of a main signal which travels in the ring to give a warning notification or execute switching control.
Although the present invention is premised on an ADSL as an asymmetric access line and an optical ATM signal as an integration signal as described above with respect to the embodiment, it does not define a signal transmission system. As an access line, applicable are, for example, other DSL (Digital Subscriber Line) system [e.g. VDSL (Very High Bit Rate Digital Subscriber Line)], electric or optical Ethernet (Registered Trademark), and a case where up and down PON (Passive Optical Network) signal capacities are asymmetric.
The present invention also allows other systems to be adopted as an integration signal such as optical Ethernet (Registered Trademark), PON, and SONET/SDH (Synchronous Optical Network/Synchronous Digital Hierarchy) line multiplexing. Signal traveling directions in a normal state and at a time of a failure can be reversely set to those in the above-described embodiment.
Furthermore, while the above-described embodiment illustrates an example in which provided as a separate unit is the integrated gateway unit, or are the interface unit and the optical expansion unit, it is also possible to form these into one unit, to realize the first optical expansion unit and the second optical expansion unit as one unit and to wavelength-multiplex up and down integration signals and transmit the obtained signal by one optical fiber.
Although the invention has been illustrated and described with respect to exemplary embodiment thereof, it should be understood by those skilled in the art that the foregoing and various other changes, omissions and additions may be made therein and thereto, without departing from the spirit and scope of the present invention. Therefore, the present invention should not be understood as limited to the specific embodiment set out above but to include all possible embodiments which can be embodies within a scope encompassed and equivalents thereof with respect to the feature set out in the appended claims.
Number | Date | Country | Kind |
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2005-074190 | Mar 2005 | JP | national |