JP4042607B2 - Transmission apparatus and transmission system having transmission path delay adjustment function - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a transmission apparatus having a function of adjusting a delay of a transmission line signal in order to realize an uninterruptible switching function, and more particularly, a plurality of the transmission apparatuses are configured in a ring shape, and BLSR (bi-directional line switched ring) In a ring network having a redundant configuration of transmission path signals by a protection function such as), a transmission path signal with a small delay is absorbed in order to absorb a phase difference of the redundant transmission path signals caused by a difference in transmission path length. The present invention relates to a transmission apparatus and a transmission system that adjust a delay difference of a transmission path signal by making one round of a ring network.
[0002]
In the regional ring networks in today's information sharing society, the demand for communications such as the Internet is anticipated, and in order to widen the ring network, transmission speed is increased and transmission line WDM (wavelength division multiplexing) is made. The transmission capacity is increasing due to In addition, there is a need for an uninterruptible switching function of a transmission line that is required for construction such as trouble relocation due to the high reliability of the ring network.
[0003]
[Prior art]
The non-instantaneous switching function adds a delay with a memory or the like to a transmission line signal having a small transmission line delay among the two transmission line signals in a redundant configuration to equalize the phase of the two transmission line signals. Is realized.
A technique for minimizing the signal delay in the apparatus when adding a delay to the transmission line signal by using a memory as a difference in the transmission line delay amount is considered (for example, see Patent Document 1).
[0004]
FIG. 10 is a system configuration diagram for explaining conventional transmission path delay control. The transmission apparatuses 100, 200, 300, 400, 500, and 600 are connected in a ring shape by a transmission path having a delay time between the transmission apparatuses. ing. The transmission line delay between the transmission apparatuses is a transmission line delay R1T connected to the transmission apparatus 200 clockwise from the transmission apparatus 100, a transmission line delay R2T connected to the transmission apparatus 300 clockwise from the transmission apparatus 200, and the transmission line similarly. Delays R3T, R4T, R5T, a transmission line delay R6T connected to the transmission apparatus 100 clockwise from the transmission apparatus 600, a transmission line delay L6T connected to the transmission apparatus 600 counterclockwise from the transmission apparatus 100, and the transmission apparatus 600 , The transmission line delay L5T connected to the transmission apparatus 500 counterclockwise, similarly transmission line delays L4T, L3T, and L2T, and the transmission line delay L1T connected counterclockwise from the transmission apparatus 200 to the transmission apparatus 100.
[0005]
In FIG. 10, the signal A is transmitted from the transmission device 100 to the path from the transmission device 500, and the transmission device 500 transmits the transmission device 100 to R1T to the transmission device 200 to R2T to the transmission device 300 to R3T to the transmission device 400 to R4T. The delay adjustment unit 501 includes a transmission path signal from a clockwise line serving as a path of the transmission apparatus 500 and a transmission path signal from a counterclockwise line serving as a path of the transmission apparatuses 100 to L6T to the transmission apparatuses 600 to L5T to the transmission apparatus 500. Thus, the signal phase is matched, and the SW unit 502 switches the path between the transmission device 100 and the transmission device 500, thereby realizing the instantaneous switching of the path.
[0006]
FIG. 11 is a functional configuration diagram of a transmission apparatus for explaining conventional transmission path delay control. The clockwise circuit passes through the transmission device (hereinafter referred to as THR). The path is transmitted through the O / E unit 130, the DMUX unit 140, the ADM unit 110, the MUX unit 150, and the E / O unit 160 through the counterclockwise circuit. A path for THR of the apparatus passes through the O / E unit 131, the DMUX unit 141, the ADM unit 110, the MUX unit 151, and the E / O unit 161.
[0007]
The clockwise line falls to the transmission device (hereinafter referred to as DROP). The path is photoelectrically converted by the O / E unit 130, separated into channels by the DMUX unit 140, dropped by the ADM unit 110, and dropped by the delay adjustment unit 120. And the MF synchronization unit 121 performs multi-frame synchronization. Similarly, the path through which the counterclockwise line DROPs to the transmission apparatus is DROP by the ADM unit 110 via the O / E unit 131 and the DMUX unit 141 and is input to the delay adjustment unit 120, and multiframe synchronization is performed by the MF synchronization unit 122. It is done. Based on the multiframe phase detected by the MF synchronization units 121 and 122, the delay difference detection unit 123 detects the difference between the multiframe phases. In the case of FIG. 10, the transmission line delay amount of the clockwise circuit is R1T + R2T + R3T + R4T, and the transmission line delay amount of the counterclockwise line is L6T + L5T. By detecting the transmission line delay difference (R1T + R2T + R3T + R4T) − (L6T + L5T), the delay difference detection unit 123 adds a delay corresponding to the transmission line delay difference to the line having a small transmission line delay. Thus, the multiframe phase is matched, and the path switching is performed by the SW unit 125, thereby realizing the pathless switching of the path.
[0008]
A path accommodated in the ring transmission path received by the transmission apparatus in the ADM unit 110 in FIG. 11 is referred to as a THR path, and the path received by the transmission apparatus is referred to as a THR path. A path in which a path accommodated in a transmission path falls on a line under the transmission apparatus is referred to as a DROP path.
As described above, in order to realize non-instantaneous switching, the transmission apparatus needs to have a memory for absorbing a transmission line delay difference for each DROP path, and this memory has the worst case for one path. Assuming a memory capacity to absorb the transmission path delay for one round of the ring is required. In the worst case, the DROP path is extended between the transmission apparatus 100 and the transmission apparatus 600, and L6T is very small. Relationship.
[0009]
[Patent Document 1]
Japanese Patent No. 2735437 “Uninterruptible Switching Device”
[0010]
[Problems to be solved by the invention]
As described above, as the transmission capacity of the ring network increases, the total capacity of the paths handled by the transmission equipment with the transmission path delay adjustment function also increases. Therefore, an increasingly larger memory capacity is required to realize instantaneous switching. It is necessary to provide this, which induces an increase in the hardware scale and power consumption of the transmission apparatus.
[0011]
In order to absorb a phase difference between redundant transmission path signals caused by a difference in transmission path length, the present invention delays the transmission path signal by circulating a transmission path signal with a small transmission path delay on the ring network. An object of the present invention is to provide a transmission apparatus and a transmission system that adjust the difference.
[0012]
[Means for Solving the Problems]
In a transmission apparatus having a function of adjusting a delay of a transmission line signal in order to realize an uninterruptible switching function used in a ring network having a redundant configuration of transmission line signals,
Means for measuring a transmission time for one round of the ring network, and a plurality of redundant configurations when a difference in transmission delay times of a plurality of transmission path signals of the redundant configuration is greater than half of the transmission time for one round of the ring network. Means that circulates the ring network using a channel that is pre-assigned a transmission line signal having a small transmission delay time, a transmission line signal that circulates the ring network using the pre-assigned channel, and A transmission apparatus comprising: a means for performing non-instantaneous switching between a plurality of redundantly configured transmission line signals and a transmission line signal having a long transmission delay time.
[0013]
According to the first invention, when the transmission delay time difference between the plurality of redundantly configured transmission line signals is larger than one half of the transmission time that makes one round of the ring network, the transmission line signal that circulates the pre-assigned channel and the transmission signal A channel for circulating a transmission path signal that is circulated in advance in a ring network system, in which a plurality of transmission path signals in a redundant configuration are switched instantaneously with a transmission path signal having a large transmission delay time. By using this, the memory capacity for adjusting the transmission line delay difference provided in the transmission apparatus becomes half of the conventional one, and it becomes possible to provide a transmission apparatus capable of reducing the hardware scale.
[0014]
A second invention is the transmission apparatus according to the first invention,
A transmission line signal having a small transmission delay time in the plurality of transmission line signals in the redundant configuration when a difference in transmission delay time between the transmission line signals in the redundant configuration is larger than one half of a transmission time for one round of the ring network. Means for circulating the ring network using an empty channel of the ring network, a transmission path signal that circulates the ring network using the empty channel, and a plurality of transmission path signals of the redundant configuration. And a means for switching without interruption with a large transmission line signal.
[0015]
According to the second invention, when the transmission delay time difference between a plurality of transmission path signals in a redundant configuration is larger than one half of the transmission time that goes around the ring network, the transmission path signal that goes around an empty channel and the redundant configuration The transmission device can perform switching without interruption with a transmission line signal having a long transmission delay time among the plurality of transmission line signals, and by using the idle channel in the ring network system for the circulating transmission line signal. The memory capacity for adjusting the transmission line delay difference included in the transmission line becomes one-half that of the prior art, and it is possible to provide a transmission apparatus capable of reducing the hardware scale.
[0016]
A third invention is a transmission system characterized in that a ring network is constituted by the transmission device according to either the first invention or the second invention.
According to the third aspect of the invention, in order to realize a non-instantaneous switching function used in a ring network having a redundant configuration of transmission line signals, a delay around the ring network is used as means for adjusting the delay of the transmission line signals. A transmission system can be provided.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the details of the present invention will be described with reference to the drawings.
FIG. 1 is a system configuration diagram illustrating delay control according to the present invention. First, an outline of the present invention will be described.
The signal A transmitted by the transmission apparatus 1 is received by the transmission apparatus 5 through the clockwise path and the counterclockwise path, and is transmitted from the transmission path signal from the clockwise path and the counterclockwise path by the delay adjustment unit 51. The transmission path delay difference of the transmission path signal is adjusted, and the SW section 52 switches the transmission path signal from the clockwise path and the transmission path signal from the counterclockwise path to become the signal B.
[0018]
The signal A is branched and inserted in the clockwise path and the counterclockwise path in the transmission apparatus 1, and in the clockwise path, the transmission apparatuses 2, 3, and 4 are THR to reach the transmission apparatus 5, and the counterclockwise path Then, the transmission device 6 is THRed to reach the transmission device 5, but when the conditional expression described later is satisfied, the signal A of the counterclockwise path that has reached the small transmission path delay is directed to the transmission device 4. THR is performed, and the transmission apparatuses 3, 2, 1 and 6 are THR to reach the transmission apparatus 5 again.
[0019]
The transmission path delay from the transmission apparatus 1 to the transmission apparatus 2 in the clockwise path is R1T, the transmission path delay from the transmission apparatus 2 to the transmission apparatus 3 is R2T, and similarly, R3T, R4T, R5T, and transmission from the transmission apparatus 6 The transmission line delay to the apparatus 1 is R6T. Further, the transmission path delay from the transmission apparatus 1 to the transmission apparatus 6 in the counterclockwise path is L6T, the transmission path delay from the transmission apparatus 6 to the transmission apparatus 5 is L5T, similarly L4T, L3T, L2T, and the transmission apparatus 2 The transmission line delay from the transmission device 1 to the transmission device 1 is L1T.
[0020]
In the transmission apparatus 5, if the transmission path delay of the signal A that has been THRed in the clockwise path is dly1, dly1 = (R1T + R2T + R3T + R4T), and the transmission path delay of the signal A that has passed through the counterclockwise path is dly2. Assuming that the transmission path delay of the circulating signal A is dly21, dly2 = (L6T + L5T), dly21 = (dly2 + dly2 + dly1).
[0021]
When dly1> dly2, the delay adjusting unit 51 conventionally adjusts the phase by adding a delay corresponding to (dly1-dly2) to the signal of the counterclockwise path. A delay corresponding to (dly21-dly1) frames is added to the signal of the path.
FIG. 2 is a diagram for explaining the correlation of delay. DLY1 is the transmission path delay amount dly1 of the clockwise path, DLY2 is the transmission path delay amount dly2 of the counterclockwise path, DLY21 is the transmission path delay amount dly21 of one more round of the counterclockwise path, and Total represents a transmission time total for one round of the ring network.
[0022]
In the transmission apparatus having the transmission line delay adjustment function of the present invention, the total and transmission line delay difference diff1 can be measured, total = (dly1 + dly2), diff1 = (dly1-dly2), and dly1 = 1/2 × ( total + diff1), dly2 = 1/2 × (total−diff1) ((3), (4)). Then, the transmission line delay difference diff11 = (dly21−dly1) in the case of one more round, and diff11 = 2 × dly2 from (dly21 = (dly2 ++ dly1 + dly2)) (5).
[0023]
In the present invention, if diff1> dif11 holds, the transmission device 5 in FIG. 1 causes the transmission device 5 in FIG. When diff1> dif11 is satisfied, dly1> 3 × dly2 is satisfied (7), and diff1> 1/2 × total is satisfied. That is, when the transmission line delay difference diff1 is equal to or more than half of the transmission time total for one round of the ring network, the transmission line signal with a small delay is THRed in the transmission device 5 and the transmission line of the dly 21 that has made one round of the ring network. If the phase is adjusted between the signal and the transmission line signal of dly1, the transmission line delay adjustment amount (memory capacity) becomes smaller.
[0024]
FIG. 3 is a functional block diagram of the transmission apparatus for explaining the first invention. The clockwise in signal is separated into channels by the DMUX unit 21. In the ADM unit 10, the ADM processing unit 12 performs DROP or THR for each channel under the control of the ADM control unit (not shown) and the THR control unit 11. Further, the signal inserted (hereinafter referred to as ADD) by the ADM control unit (not shown) and the THR signal are multiplexed by the MUX unit 22 to become a clockwise out signal. Similarly, the counterclockwise in signal is separated into channels by the DMUX unit 23. In the ADM unit 10, the ADM processing unit 13 performs DROP or THR for each channel under the control of the ADM control unit (not shown) and the THR control unit 11. To do. The signal ADDed by the ADM control unit (not shown) and the THR signal are multiplexed by the MUX unit 24 to become a counterclockwise out signal.
[0025]
Next, a description will be given of means for further making one round of a transmission line signal having a small transmission line delay based on the result of the transmission line delay difference.
Signals to be DROP by an ADM control unit (not shown) are CH1 of clockwise in signal and CH1 of counterclockwise in signal, and CHOP and CH2 are DROP channel numbers.
[0026]
The DROP signals CH1 and CH2 are subjected to multiframe synchronization by the MF synchronization units 31 and 32, and the delay difference detection unit 33 transmits a transmission line delay difference known from the difference between the respective multiframe phases and a cyclic time frame described later. Whether the conditional expression diff1> 1/2 × total described above is satisfied is determined from the number.
If the conditional expression diff1> 1/2 × total is not satisfied, the multi-frame is matched by delaying the number of frames equivalent to the diff1 for the transmission path signal with a small transmission path delay by the memory control unit, By switching the path in the SW unit 40, switching of the path without interruption is realized.
[0027]
When the conditional expression diff1> 1/2 × total is satisfied, the ADM processing unit 12 or the ADM processing unit 13 executes THR on a channel with a small transmission path delay under the control of the THR control unit 11. At this time, a pre-assigned channel is used for a signal to be THRed. Then, the transmission path signal that has made one round is DROP from a pre-assigned channel, multi-frame synchronization is performed by the MF synchronization units 31 and 32 in the same manner as described above, diff11 is detected by the delay difference detection unit 33, and a frame corresponding to the diff11 By delaying the number by the memory control unit, the multi-frame phases are made to coincide with each other, and the path is switched by the SW unit 40 to realize the instantaneous switching of the path.
[0028]
FIG. 9 is a diagram for explaining a multi-frame configuration of POH. As means for recognizing the phase of the transmission path signal described above, the frame is converted into multi-frames and the phase of the transmission path signal is recognized in units of frames. In FIG. 9, SONET (synchronous optical network) or SDH (synchronous digital hierarchy) is used as a frame format, and a POH (path) in an STS (synchronous transport signal) -m signal frame of a band of 2.4 Gbit / s, 10 Gbit / s, etc. The STS-n signal frame in which the J1 byte, the H4 byte, etc. of the overhead) are converted into a multiframe is shown.
[0029]
One frame is 125 μsec. For example, by making 64 multiframes, one multiframe is 8 msec. In general, one frame length of 125 µsec is converted to 25 km as the transmission line length, so 64 multiframe signals are equivalent to 1,600 km, and half the 800 km transmission is used to recognize the phase relationship of redundant transmission line signals. The road delay can be tolerated. That is, in a ring network system using a 64-multiframe SONET or SDH frame signal, the transmission line delay can be adjusted up to a maximum of 800 km of the ring transmission line length.
[0030]
In the above description, DROP, THR, and ADD are realized by the ADM unit 10 for the clockwise signal and the counterclockwise signal for each channel, but DROP, THR, and ADD are converted by the cross-connect function for converting the channel position for each channel. THR and ADD can also be realized.
Next, the number of circulating time frames serving as a transmission time for one round of the ring network measured by the transmission apparatus having the transmission path delay adjusting function of the present invention in the above description will be described.
[0031]
FIG. 4 is a system configuration diagram illustrating the number of lap time frames, which is the same as the system configuration described in FIG. In order to measure the transmission time for one round of the ring network using a pre-assigned channel, the transmission device 5 sends out a frame signal that has been made into a multiframe on the clockwise transmission path, and the multiframe that has made one round The delay difference detection unit 53 receives the converted frame signal, detects the lap time from the transmitted multiframe position and the received multiframe position, and outputs the number of frames corresponding to the lap time as the lap time frame number. The detected transmission path delay difference is R5T + R6T + R1T + R2T + R3T + R4T.
[0032]
FIG. 5 is a sequence diagram for explaining the measurement of the number of lap time frames. Although the system configuration is the same as that of FIG. 4, the transmission devices 3 and 4 operate in the same manner as the transmission devices 1, 2, and 6. Omitted.
As described above with reference to FIG. 4, the transmission device 5 sends a frame signal that has been converted into multi-frames to the transmission device 6. (A-1)
The transmission device 6 that has received the multi-frame signal performs THR processing on the multi-frame signal. (B-1)
Similarly, the transmission apparatuses 1 and 2 perform THR processing on the received frame signal. (C-1, d-1)
The transmission device 5 that has received the frame signal that has been converted into multiframes detects the lap time from the transmitted multiframe position and the received multiframe position, and outputs the number of frames corresponding to the lap time as the number of lap time frames. . At the same time, the number of round time frames is stored in a pre-assigned time slot of the multi-framed frame signal, and the multi-framed frame signal is transmitted to the transmission device 6. (A-2)
The transmission apparatus 6 that has received the frame signal in which the number of round time frames is stored and converted into a multiframe monitors the number of round trip time frames, and performs THR processing on the frame signal in which the number of round trip time frames is stored. To do. (B-2)
Similarly, the transmission apparatuses 1 and 2 monitor the number of round time frames and perform THR processing on the frame signal in which the round time frames are stored and converted into multi-frames. (C-2, d-2)
Note that the measurement of the number of circulating time frames is performed on a clockwise transmission line or a counterclockwise transmission path by a preset transmission apparatus constituting the ring network.
[0033]
FIG. 6 is a functional configuration diagram (1) of the transmission apparatus for explaining the second invention. The clockwise in signal is separated into channels by the DMUX unit 21, and the signal of the operation channel to be dropped (hereinafter referred to as operation CH) is subjected to multiframe by the MF synchronization unit 51, and the counterclockwise in signal Are separated into channels by the DMUX unit 23, and DROP operation CH signals are multiframed by the MF synchronization unit 52, and the delay difference detection unit 56 detects the transmission path delay difference from each multiframe phase. The THR / DROP determination unit 57 is notified of whether or not the conditional expression diff1> 1/2 × total described above holds from the relationship with the number of round time frames from the MF synchronization unit 53.
[0034]
Here, the MF synchronization unit 53 recognizes the multi-frame phase for measuring the number of circulation time frames described with reference to FIGS. 4 and 5, which is measured using the circulation CH assigned in advance. .
If the conditional expression diff1> 1/2 × total does not hold, the THR / DROP determination unit 57 sends a DROP-N signal for delay adjustment to the DROP selection unit 59 for the signals dropped by the ADM processing units 61 and 62. Notice. The DROP selection unit 59 that has received the DROP-N signal selects the signal that has been dropped by the ADM processing units 61 and 62, and outputs the selected signal to the delay adjustment unit 70.
[0035]
On the other hand, when the conditional expression diff1> 1/2 × total is satisfied, the THR / DROP determination unit 57 generates a control signal for making one more turn in the direction in which the transmission line delay is small, that is, a clockwise transmission line delay. When it is small, THR-R is notified to the control information adding unit 58 when the counterclockwise transmission path delay is small, and a signal of an empty channel (hereinafter referred to as an empty CH) is sent to the DROP selection unit 59. Is notified of a DROP-C signal for delay adjustment. When notifying the DROP-C signal, the THR / DROP determining unit 57 receives control information from the control information monitoring units 54 and 55 that monitor the control information of the free CH (described later in the control information adding unit 58). Recognizing the information detected that the signal that has made one round has arrived, the DROP selection unit 59 is notified of the DROP-C signal.
[0036]
The control information adding unit 58 that has received the THR-R and THR-L from the THR / DROP judging unit 57 makes one-round request information (RQ), one-round request information (RQ), Control information composed of the circulation request device number (ND), the applicable path number (TS), and the used channel bandwidth (CB) is notified to the ADM processing units 61 and 62 in the corresponding direction.
[0037]
The ADM processing units 61 and 62 that have received the control information ADD the control information, THR a transmission path signal known from the applicable path number (TS), and transmit it to an empty CH.
When the conditional expression diff1> 1/2 × total is satisfied, the DROP selection unit 59 selects a signal that has been circulated once using an empty CH, and outputs the selected signal to the delay adjustment unit 70.
[0038]
The memory control unit 71 of the delay adjustment unit 70 has a small delay of the transmission path signal from the DROP selection unit 59 based on the multiframe phase from the MF synchronization units 51 and 52 and the control information monitoring units 54 and 55. The phase is adjusted by adding a delay equivalent to the diff11 to the transmission line signal so that the multiframes are matched.
The SW unit 72 realizes uninterruptible path switching by switching path signals having the same multi-frame phase, and outputs it as a DROPout signal.
[0039]
FIG. 7 is a functional configuration diagram (2) of the transmission apparatus for explaining the second invention. In the description of FIG. 6, the transmission apparatus that adjusts the transmission path delay by DROPing the transmission path signal in the ring network has been described. However, in FIG. 7, the transmission apparatus described in FIG. A transmission apparatus when THR processing is performed on a transmission line signal to be performed will be described. Therefore, the transmission apparatus shown in FIG. 7 has the same functional configuration as that of the transmission apparatus shown in FIG. 6, but FIG. 7 shows functions necessary for performing THR processing on a transmission line signal that goes around once using the empty CH. Is described and explained.
[0040]
The clockwise in signal is separated into channels by the DMUX unit 21, and the operating CH is subjected to THR processing by the ADM processing unit 61 under the control of the ADM control unit (not shown), multiplexed by the MUX unit 22, and clockwise out Output as a signal. Similarly, the counterclockwise in signal is output as a counterclockwise out signal via the ADM processing unit 62 and the MUX unit 24.
[0041]
When the transmission path signal that makes one round using the empty CH described in FIG. 6 is a clockwise signal, the transmission path signal that makes one round using the empty CH is separated into channels by the DMUX unit 21 and controlled. Monitored by the information monitoring unit 54.
The control information monitoring unit 54 performs multi-frame synchronization of a transmission channel signal of an empty CH, and the one-round request information (RQ), one-round request device number (ND), applicable path number (TS), used channel band The control information composed of (CB) is monitored, and if the one-round request information (RQ) is present, the control information is notified to the THR / DROP determination unit 57. Similarly, in the case of a counterclockwise signal, the control information monitoring unit 55 performs multiframe synchronization to monitor the control information, and notifies the THR / DROP determination unit 57 of the control information.
[0042]
The THR / DROP determination unit 57 confirms that the one-round requesting device number (ND) of the control signal is different from its own device number, and makes one round known from the applied path number (TS) and the used channel bandwidth (CB). The signal to be determined is determined. When there is a signal that goes around once in the empty channel of the clockwise transmission path signal, the control information adding unit 58 is notified of the control information via the THR-R signal. Similarly, when there is a signal that makes a round in the empty channel of the counterclockwise transmission line signal, the control information adding unit 58 is notified of the control information via the THR-L signal.
[0043]
The control information adding unit 58 receives the THR-R signal and the THR-L signal, and controls the corresponding ADM processing units 61 and 62 to THR empty channels known from the control information.
When the system to which the present invention is applied is a system using WDM, it is possible to use the free CH used in the second invention by securing the free optical wavelength at the wavelength used by the WDM system. is there.
[0044]
FIG. 8 is a system sequence diagram for explaining delay control according to the third aspect of the invention, which has the same system configuration as that of FIG. The system is configured by.
It is assumed that the transmission apparatuses 1, 2, 5, and 6 recognize the number of circulatory time frames described with reference to FIGS.
[0045]
The transmission device 1 transmits the multi-frame transmission path signal to the transmission device 5 to the transmission device 2 as a clockwise signal. (E)
At the same time, the transmission device 1 sends a multi-frame transmission path signal to the transmission device 5 to the transmission device 6 as a counterclockwise signal. (G)
As described with reference to FIG. 7, the transmission apparatuses 2 and 6 monitor the free CH and determine whether or not the free CH is used based on the control information. Here, it is assumed that no free CH is used. Therefore, the ADM control unit (not shown) THRs the transmission channel signal of the operation CH and sends it to the transmission device 5. (F) (h)
The transmission apparatus 5 receives the clockwise transmission path signal from the transmission apparatus 2 and the counterclockwise transmission path signal from the transmission apparatus 6, and detects a delay difference between the transmission path signals. Whether or not the conditional expression diff1> 1/2 × total is satisfied is determined from the number of round time frames and the number of frames corresponding to the delay difference between the transmission path signals. In this case, since the conditional expression diff1> 1/2 × total is satisfied, the transmission apparatus 5 THRs the counterclockwise transmission path signal with a small transmission path delay. (I)
In the case of the first invention, the previously assigned CH is used as the transmission line signal for THR. In the case of the second invention, the unused CH is used and the control information described in FIG. 6 is added to the transmission line signal to be THRed.
[0046]
The transmission apparatus 2 receives the counterclockwise transmission path signal (i). In the case of the first invention, the received transmission path signal is THRed by an ADM control unit (not shown). In the case of the second invention, the empty channel is monitored, and the received transmission line signal is THRed by the control information. (J)
Similarly, the transmission apparatuses 1 and 6 perform THR on the received transmission path signal. (K) (l)
In the case of the first invention, the transmission device 5 has a small transmission line delay so as to match the multi-frame phase between the clockwise transmission line signal and the counterclockwise transmission line signal of the pre-assigned CH once. The path is switched by adjusting the transmission line delay of the clockwise transmission line signal, and output as a DROPout signal. In the case of the second invention, the empty channel is monitored, and it is confirmed that the one-round requesting device number (ND) of the control information matches the own device number. In order to match the multiframe phase with the counterclockwise transmission path signal, the transmission path delay of the clockwise transmission path signal with a small transmission path delay is adjusted to switch the transmission path signal and output as a DROPout signal.
[0047]
(Supplementary note 1) In a transmission apparatus having a function of adjusting a delay of a transmission line signal in order to realize a non-instantaneous switching function used in a ring network having a redundant configuration of transmission line signals, transmission that makes one round of the ring network Means for measuring the time, and when the transmission delay time difference between the plurality of transmission line signals of the redundant configuration is larger than one half of the transmission time of going around the ring network, the transmission delay is caused by the transmission line signals of the redundant configuration Means for circulating the ring network using a channel pre-assigned a transmission line signal having a small time; a transmission line signal circulating around the ring network using the pre-assigned channel; and a plurality of redundantly configured transmission lines A transmission device comprising: a means for performing uninterrupted switching with a transmission line signal having a long transmission delay time by a signal.
[0048]
(Supplementary note 2) In the transmission apparatus according to supplementary note 1, when a difference in transmission delay time between the plurality of transmission path signals in the redundant configuration is larger than half of the transmission time for one round of the ring network, the plurality of redundant configurations A transmission line signal having a small transmission delay time using the free CH of the ring network, a transmission line signal that circulates the ring network using the free CH, and A transmission apparatus comprising: a means for performing uninterrupted switching between a plurality of redundantly configured transmission line signals and a transmission line signal having a long transmission delay time.
[0049]
(Supplementary note 3) A transmission system comprising a ring network by the transmission device according to either Supplementary note 1 or Supplementary note 2.
(Additional remark 4) In the transmission apparatus of Additional remark 2, when using empty CH of the ring network as a transmission band which a transmission line signal circulates, in order to monitor the transmission line signal which this empty CH circulates, 1 A transmission apparatus characterized in that control information composed of circulatory request information, circulatory request apparatus number, applicable path number, and used channel band circulates through an empty channel of the ring network together with the circulated transmission path signal.
[0050]
【The invention's effect】
As described above, in the function of adjusting the delay of the transmission line signal in order to realize the uninterruptible switching function, the transmission line signal is obtained by adding a delay to the transmission line signal having a small delay using a memory or the like. However, in the present invention, it is used for a ring network having a redundant configuration of transmission path signals, and a transmission path signal with a small delay is assumed on the assumption that an empty CH exists in the transmission bandwidth of the ring network. By adjusting the loop transmission path delay time, it is possible to reduce the memory capacity for adjusting the transmission path delay.
[0051]
According to the first invention, when the transmission delay time difference of the plurality of transmission line signals in the redundant configuration is larger than one half of the transmission time for making one round of the ring network, the looped transmission line signal and the plurality of redundant configuration signals By using a channel for circulating the transmission path signal that has been allocated in advance in the ring network system, the transmission path signal will be switched without interruption with a transmission path signal having a large transmission delay time. The memory capacity for adjusting the transmission path delay difference included in the transmission apparatus is halved compared to the conventional one, and it is possible to provide a transmission apparatus capable of reducing the hardware scale.
[0052]
According to the second invention, when the transmission delay time difference of the plurality of transmission line signals in the redundant configuration is larger than one half of the transmission time for making one round in the ring network, the looped transmission line signal and the plurality of redundant configuration signals A transmission line signal is switched without instantaneously switching to a transmission line signal having a long transmission delay time, and the circulatory transmission line signal is used in a ring network system so that a transmission channel is provided. The memory capacity for adjusting the path delay difference becomes one-half that of the prior art, and it is possible to provide a transmission apparatus that can reduce the hardware scale.
[0053]
According to the third invention, in order to realize a non-instantaneous switching function used in a ring network having a redundant configuration of transmission lines, transmission using a delay around the ring network as means for adjusting the delay of the transmission line signal A system can be provided.
[Brief description of the drawings]
FIG. 1 is a system configuration diagram illustrating delay control according to the present invention.
FIG. 2 is a diagram for explaining delay correlation
FIG. 3 is a functional configuration diagram of a transmission apparatus for explaining the first invention.
FIG. 4 is a system configuration diagram for explaining the measurement of the number of lap time frames.
FIG. 5 is a sequence diagram for explaining the measurement of the number of lap time frames.
FIG. 6 is a functional configuration diagram (1) of the transmission apparatus for explaining the second invention.
FIG. 7 is a functional configuration diagram (2) of the transmission apparatus illustrating the second invention.
FIG. 8 is a sequence diagram for explaining the third invention.
FIG. 9 is a diagram illustrating a multi-frame configuration of POH
FIG. 10 is a system configuration diagram illustrating conventional transmission path delay control.
FIG. 11 is a functional configuration diagram of a transmission apparatus for explaining conventional transmission path delay control;
[Explanation of symbols]
1,2,3,4,5,6,100,200,300,400,500,600 transmission device
30, 51, 70, 120, 501 Delay adjustment unit
40, 52, 72, 125, 502 SW section
10, 50, 110 ADM
11 THR control unit
12, 13, 61, 62 ADM processing unit
21, 23, 140, 141 DMUX section
22, 24, 150, 151 MUX section
31, 32, 51, 52, 53, 121, 122 MF synchronization unit
33, 56, 123 Delay difference detector
34, 71, 124 Memory control unit
54,55 Control information monitoring unit
57 THR / DROP decision section
58 Control information adding part
59 DROP selector
130, 131 O / E section
160,161 E / O section

Claims (3)

In a transmission device having a function of adjusting a delay of a transmission line signal in order to realize a non-instantaneous switching function used in a ring network having a redundant configuration of transmission line signals,
Means for measuring the transmission time for one round of the ring network;
When a transmission delay time difference between a plurality of redundant configuration transmission line signals is larger than one half of a transmission time for one round of the ring network, a transmission line signal having a small transmission delay time among the plurality of redundant configuration transmission line signals is obtained. Means for circling the ring network using pre-assigned channels;
Means for performing uninterrupted switching between a transmission line signal that circulates in a ring network using the pre-assigned channel and a transmission line signal having a large transmission delay time in the plurality of redundant transmission line signals;
A transmission apparatus comprising: The transmission apparatus according to claim 1,
A transmission line signal having a small transmission delay time in the plurality of transmission line signals in the redundant configuration when a difference in transmission delay time between the transmission line signals in the redundant configuration is larger than one half of a transmission time for one round of the ring network. Means for circling the ring network using an empty channel of the ring network;
Means for performing uninterrupted switching between a transmission line signal that circulates in a ring network using the empty channel and a transmission line signal having a large transmission delay time among the plurality of transmission line signals of the redundant configuration;
A transmission apparatus comprising: A transmission system comprising a ring network by the transmission device according to claim 1.

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