JP3712633B2 - Packet communication circuit, packet communication device, power-off notification method, program, and recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
In the packet communication system that communicates packet signals, the present invention determines whether or not a remote node is powered off when a signal from the remote node is stopped as one of maintenance operation monitoring of the remote node. A packet communication circuit, a packet communication device, a power-off notification method, a packet communication circuit, a program executed by a computer in the device, and a recording medium storing the program It is about.
[0002]
[Prior art]
As a conventional technique, an SDH (Synchronous Digital Hierarchy) communication system will be described here with reference to FIGS.
FIG. 12 shows the structure of the SDH frame, and a part of the overhead of the SDH frame (Z2 b7 & b8) is used as the power-off information.
[0003]
In the communication system for transmitting the SDH signal from the node 1 to the node 2 through the transmission line as shown in FIG. 13A, the power-off information is transmitted from the node 1 to the node at a cycle of 125 μs as shown in FIG. 2 is transmitted. The node 1 normally transmits b7 & b8 of Z2 as “00”. When the power switch of the node 1 changes from ON to OFF, or when the original power supply is cut off when the power switch is ON, Z2 b7 & b8 is set to “01” and transmitted for 12 cycles (1500 μs) or more.
Then, as illustrated in FIG. 13C, the node 2 determines that the power of the node 1 is off when the value of b7 & b8 of Z2 received is “01” continuously for 6 cycles (750 μs).
[0004]
FIG. 14 is a block diagram showing a configuration of a conventional packet communication apparatus as the node 1.
In FIG. 14, a payload output unit 500 outputs a signal of the payload portion of SDH. The overhead transmission processing unit 200 generates overhead information to be transmitted. The overhead writing unit 300 writes overhead and sets b2 & b8 of Z2 according to the presence / absence of input of a power-off detection signal. The optical transmission unit 400 converts the electrical signal from the overhead writing unit 300 into an optical signal and transmits it.
[0005]
The power supply unit 600 supplies power to the entire apparatus and outputs a power-off detection signal. In addition, the power storage unit 601 continues to supply the power stored in the power storage unit 601 over a period of at least 1500 μs to each unit as a node power source after outputting the power-off detection signal. The power-off detection signal is output upon detecting that the power SW (switch) is turned ON → OFF or that the original power is cut off.
[0006]
In a packet communication system that communicates packet signals, unlike SDH, there is no frame structure or overhead byte with a period of 125 μs. In the packet communication system, the power-off information can be notified to the receiving side in the same manner as in the SDH communication system.
[0007]
15 to 17 show the embodiment shown in the prior invention.
In the present embodiment, the same mechanism as the communication by the frame of the existing synchronous communication system is virtualized by sharing the control information and matching the communication speed of the control information in a communication method different from the communication method of the existing synchronous communication system. Is realized. Accordingly, by communicating overhead information of a synchronous communication system using frames at a frame period (virtual frame), it is possible to realize a communication system having no difference when viewed from the operation.
[0008]
FIG. 15 shows an embodiment of an integrated network A1 in which an existing synchronous communication system 7 and a new communication system 7 ′ of a new protocol having a different communication method are connected.
The integrated network A1 includes a synchronous communication system 7, a new communication system 7 ′, and a communication system conversion node A2 that connects them.
[0009]
The synchronous communication system 7 and the new communication system 7 ′ are each provided with a network operation unit 100. As will be described later, the network operation unit 100 processes the control information 3 and the control information 3 ′ according to the control information processing method 6 conforming to the SDH frame overhead processing method.
[0010]
The synchronous communication system 7 uses the communication unit 50 to communicate the communication data 2 and the control information 3 for operation and maintenance of the communication system according to the synchronous frame communication method 5 which is a communication method using an SDH frame.
[0011]
FIG. 16A shows a configuration of a signal communicated by the synchronous frame communication method 5, and FIG. 16B shows a frame structure of the synchronous frame communication method 5.
As shown in FIG. 16A, in the synchronous frame method 5, the communication data 2 and the control information 3 are transmitted and received using a frame having the frame structure 1 compliant with SDH continuously at an interval of a frame time 4 of 125 μs. .
[0012]
As shown in FIG. 16 (b), the control information 3 is m that is all or part of each byte of the repeater section overhead, each byte of the terminal section overhead, and each byte of the high-order path overhead. It consists of control information bytes 8-1 to 8-m of bytes (m is a natural number). A control information processing method 6 which is a processing method of the control information 3 for performing operation and maintenance conforms to the overhead processing method of the SDH frame.
[0013]
FIG. 17 is an example of a timing chart of signals to be communicated in the new communication system 7 ′.
The new communication system 7 ′ uses the communication unit 50 ′ to communicate data 2 ′ and one block as control information 3 ′ during a frame time 4 of 125 μs by a communication method 5 ′ different from the synchronous frame communication method 5. Communicate with m control information blocks 8B-1 ′ to 8B-m ′ composed of K codes (K is a natural number). The control information block 8B-i ′ (i is 1 to m) includes a code representing a control information byte 8-i ′ corresponding to the control information byte 8-i. Each block includes control information identification bits C1 and C2 composed of one bit or a plurality of bits for identifying the type of the control information byte included therein.
[0014]
In the transmission of the control information block 8B-i ′, m control information blocks 8B-1 ′ to 8B-m ′ are transmitted during the frame time 4 (125 μs) using a period in which the communication data 2 ′ is not transmitted. Finish sending. Frame timing is generated at intervals of 125 μs, and transmission is started in order from the control information block 8B-1 ′ according to the timing. The transmission of the control information block corresponding to the next frame is not started from the time when transmission is completed up to 8B-m ′ to the next frame timing.
[0015]
Upon reception of the control information block 8B-i ′, the control information block including the control information identification bit indicating the control information byte 8-1 ′ is detected, and the frame timing is reproduced by removing the jitter component from the detection timing.
[0016]
When the control information identification bit of the received control information block indicates the control information byte 8-i ′, the control information byte 8-i ′ is obtained from the block. If control information block 8B-j 'is not received among control information blocks 8B-2' to 8B-m 'to be received, a code error has occurred in control information byte 8-j' during transmission Judgment is made and predetermined error processing is performed.
[0017]
The control information processing method 6 of the synchronous communication system 7 is applied as the control information processing method for the control information byte 8-i ′ for performing operation and maintenance of the new communication system 7 ′.
[0018]
Therefore, according to the new communication system 7 ′ to which the communication method according to the present embodiment is applied, the control information of the existing synchronous communication system 7 is shared, and the communication speed of the control information is matched, so that the existing synchronous communication system 7 A virtual frame equivalent to the frame is realized.
[0019]
As a result, the control information processing method 6 of the existing synchronous communication system 7 can be adopted as it is in the new communication system 7 ′ to which the communication method according to the present embodiment is applied.
Further, in the integrated network in which the existing synchronous communication system 7 and the new communication system 7 ′ to which the communication method according to this embodiment is applied can be mixed, the control information processing method 6 can be unified, so that the operation of the integrated network can be performed. This can be realized in the same way as the case where only the synchronous communication system 7 is configured.
Further, this embodiment is suitable for use in packet communication such as Ethernet (registered trademark).
[0020]
In the transmission of the control information 3 ′ of the new communication system 7 ′, among the m control information blocks 8B-1 ′ to 8B-M ′, the control information block 8B-i ′ that matches the default value is It is also possible not to transmit. In that case, in the reception of the control information 3 ′, it is detected that the control information block 8B-i ′ has not been received at a predetermined time, and when this is detected, the control information block 8B-1 ′ that matches the default value is detected. It is processed in the same way as when received.
[0021]
[Problems to be solved by the invention]
As described above, the node 1 in FIGS. 12 and 13 needs to continue to transmit the power-off detection signal at a period of 125 μs for 1500 μs or more after the original power supply is cut off. In order to obtain power for transmitting the power-off detection signal, the node 1 includes a power storage unit 601 capable of supplying power instead of the original power source for 1500 μs or longer as shown in FIG. Conventionally, there has been a problem that downsizing of the apparatus is hindered by the volume of the power storage unit.
[0022]
The present invention has been made to solve the above-described problems, and aims to enable downsizing of the apparatus.
[0023]
[Means for Solving the Problems]
To achieve the above objective, The present invention In the packet communication circuit according to the above, the power interruption detecting means for detecting the power interruption, the power accumulation means for accumulating the power of the power supply, the power supplied from the power supply, the packet signal is inputted and transmitted, When the power-off detection means detects a power-off, there is provided a transmission processing means that operates by being supplied with the power stored in the power storage means and continuously outputs a power-off signal for a predetermined time.
[0024]
Also according to the present invention, The power-off detection unit may monitor the voltage of the power source and determine that the power is off when the voltage becomes lower than a predetermined voltage.
[0025]
The present invention In the power-off notification method using the first packet communication device, the encoded packet signal is transmitted from the first packet communication device to the second packet communication device via the transmission path, and the transmission is stopped due to the power failure in the first packet communication device. In the power-off notification method of the packet communication system for notifying the second packet communication device of the power-off before the first packet communication device detects the power-off, the first packet communication device continues p power-off code sets. The second packet communication apparatus performs power-off detection processing when q (q ≦ p) continuous power-off code sets are received.
[0026]
In the present invention, When the first packet communication device detects a power interruption, the first packet communication apparatus repeats transmission processing at the time of power interruption in which p 'idle code sets are continuously transmitted after continuously transmitting p power interruption code sets. You may do it.
[0027]
In the present invention, The code rule of the packet signal is an mb / nb code rule (n> m), the power cutoff code set is composed of a plurality of n-bit codes, and at least one code is an mb / nb code. The code may have a bit pattern that does not follow the rules.
[0028]
The present invention In the packet communication device according to the above, in the packet communication device that transmits the encoded packet signal to the packet communication device on the receiving side, the power-off detection unit that detects power-off, and the power-off detection unit detects the power-off And a power-off processing means for continuously transmitting p power-off code sets.
[0029]
Also in the present invention The power-off processing means may repeatedly transmit p ′ idle code sets after transmitting p power-off code sets continuously.
[0030]
In the present invention, The code rule of the packet signal is an mb / nb code rule (n> m), the power cutoff code set is composed of a plurality of n-bit codes, and at least one code is an mb / nb code. The code may have a bit pattern that does not follow the rules.
[0031]
Also according to the present invention In the packet communication apparatus, in the packet communication apparatus that receives the encoded packet signal from the transmission-side packet communication apparatus, p power supplies that are continuously transmitted when the transmission-side packet communication apparatus detects a power interruption. A power-off detection processing means is provided for detecting power-off when q (q ≦ p) consecutive power-off code sets are received among the code-off sets.
[0032]
The present invention In the program used in the packet communication circuit according to, the power-off detection process for detecting the power-off, the power storage process for accumulating the power of the power supply, the power supplied from the power supply, the operation is performed, and the packet signal is input and transmitted In addition, when the power-off detection means detects a power-off, a transmission process is provided that operates by being supplied with the power stored by the power storage process and outputs a power-off signal continuously for a predetermined time.
[0033]
In the present invention, In the power-off detection process, the power-supply voltage may be monitored, and when the voltage becomes lower than a predetermined voltage, the power-off may be determined.
[0034]
The present invention In the program used in the packet communication device on the transmission side according to, when the power interruption is detected by the power interruption detection process for detecting the power interruption and the power interruption detection process, p power interruption code sets are continuously transmitted. Power-off processing is provided.
[0035]
In the present invention, The power-off process may be such that p ′ idle code sets are continuously transmitted after p power-off code sets are continuously transmitted.
[0036]
In the present invention, The code rule of the packet signal is an mb / nb code rule (n> m), the power cutoff code set is composed of a plurality of n-bit codes, and at least one code is an mb / nb code. The code may have a bit pattern that does not follow the rules.
[0037]
Also according to the present invention, In the program used in the packet communication device on the reception side, q (q ≦ p) consecutive out of the p power-off code sets that are transmitted continuously when the packet communication device on the transmission side detects power-off. A power-off detection process for detecting power-off when a power-off code set is received is provided.
[0038]
Also according to the present invention, In computer-readable recording media, Above The program is recorded.
[0039]
[Action]
In the present invention, Since the power-off signal is continuously transmitted when the operation power-off is detected, the receiving side can know the power-off on the transmitting side in a short time. As a result, the period during which the power-off signal is to be transmitted can be shortened, so that the amount of energy that the power storage unit should store can be reduced, and the volume of the power storage unit can be reduced. Further, since the power storage unit can supply power to only the packet communication circuit, which is the minimum circuit necessary for transmitting the power-off signal, the amount of energy that the power storage unit should store is limited. This can be reduced, and the volume of the power storage unit can be reduced. Since the volume of the power storage unit can be reduced, the packet communication circuit can be reduced in size. In addition, Of the present invention In the program, Above Processing based on the action is performed.
[0040]
In the present invention, Since the operating power supply voltage is monitored and it is determined that the power supply is cut off when the power supply voltage falls below a certain value, it is possible to detect the power supply interruption with a simple circuit, contributing to downsizing and cost reduction of the packet communication circuit. In addition, it is possible to reliably detect power interruptions caused by various factors. That is, when the packet communication circuit is detachable from the device body of the packet communication node, it can be detected not only when the device body is powered off but also when the packet communication circuit is removed from the device body. it can. In addition, Of the present invention In the program, Above Processing based on the action is performed.
[0041]
In the present invention, Since a power-off code set that combines codes that are basic units of working communication is used as a signal for notifying power-off, it is easy to generate and detect in a packet communication device that performs processing in units of codes. . Further, the first packet communication device continuously transmits p (p is a natural number) power-off code sets, and the second packet communication device has q (q is a natural number equal to or less than p) power-off code sets. Since the power-off of the first packet communication device is detected when the packet is continuously received, the reliability of the power-off notification can be easily increased by increasing the values of p and q. Further, when the power failure of the first packet communication device is detected in the second packet communication device, it can be used for elucidating the cause of the reception failure by performing a power failure detection process such as recording the time. .
[0042]
Also In the present invention The operation of the first packet communication device can be obtained. Also, The present invention In the program of this Processing based on the action is performed.
[0043]
In the present invention, When the power failure is detected in the first packet communication device, not only the power loss code set but also the idle code set is transmitted, so that the idle code set is inserted into and removed from the transmission path to the second packet communication device. A network configuration in which a relay node exists is possible. The relay node can suppress the jitter of the relayed signal by inserting and extracting the idle code set included in the packet signal to be relayed. Therefore, the relay node can be arranged on the transmission path, and the transmission distance from the first packet communication device to the second packet communication device can be extended without degrading the signal.
[0044]
In addition, In the present invention The operation of the first packet communication device can be obtained. Also, The present invention In the program of this Processing based on the action is performed.
[0045]
In the present invention The second packet communication device can know the power-off of the first packet communication device by receiving the power-off code set, and can process the power-off signal separately from the normal packet information. is there. When the second packet communication apparatus that does not have the power-off code set reception mechanism and receives a signal that conforms to the mb / nb code rule frequently receives a bit pattern that does not conform to the mb / nb code rule, a reception error state This makes it possible to detect a power-off on the transmission side even on the reception side. That is, at least one Ci (i is a natural number equal to or less than s) among power cut-off code sets composed of s (s is a natural number) n-bit long codes of C1, C2,. By setting the bit pattern not to be generated according to the mb / nb coding rule, the receiving side is in a reception error state when receiving this power-off code set, so the receiving side is notified of the power-off on the transmitting side as an alarm. can do.
[0046]
In addition, The present invention In this case, the operation of the first packet communication device can be obtained. , The present invention In the program of this Processing based on the action is performed. Also, The present invention In the above, the operation of the second packet communication device can be obtained. , The present invention In the program of this Processing based on the action is performed.
[0047]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, first to eighth embodiments of the present invention will be described with reference to the drawings.
FIG. 1 shows the configuration and operation of a packet communication apparatus according to a first embodiment of the present invention, and corresponds to claim 1.
In FIG. 1A, the packet communication apparatus supplies power to each part of the apparatus based on the packet output unit 10 that outputs a packet signal, the packet communication circuit 20, the original power supply, and the power switch (switch) ON. The power supply unit 30 is configured.
The packet communication circuit 20 includes a packet signal transmission processing unit 21, a transmission unit 22, a power interruption detection unit 23, and a power storage unit 24.
[0048]
The packet signal transmission processing unit 21 outputs the packet signal as a packet transmission signal when the power-off detection signal is not input from the power detection unit 23, and stops outputting the packet transmission signal when the power-off detection signal is input. At the same time, a power-off signal is continuously output during a predetermined time T. The transmission unit 22 transmits a signal output from the packet signal transmission processing unit 21.
[0049]
The power interruption detection unit 23 detects the power interruption of the packet communication circuit 20 and outputs a power interruption detection signal to the packet signal transmission processing unit 21. The power storage unit 24 stores the power of the power supplied from the power supply unit 30 to the packet communication circuit 20, and the packet signal transmission processing unit 21 detects the time T after the power-off detection unit 23 detects the power-off. In the meantime, a power-off signal is output continuously, and power for transmitting the signal is transmitted to each part of the packet communication circuit 20.
[0050]
Next, the operation will be described.
FIGS. 1B and 1C are timing charts showing output signals of the packet signal transmission processing unit 21.
When the power-off detection signal is not input, the encoded packet information and the inter-packet gap filled with the idle code set are alternately transmitted as shown in (b). In this state, when a power-off detection signal is input as shown in (c), transmission is stopped and a power-off signal is continuously output during time T to notify the receiving side of power-off. The power for outputting the power-off signal can be obtained from the power storage unit 24.
[0051]
Therefore, according to the present embodiment, the power-off signal is conventionally periodically transmitted (for example, transmitted at a period of 125 μs in a period of 1500 μs), whereas the power-off signal is continuously transmitted during the time T. Therefore, the receiving side can know that the power has been cut off in a short time. Therefore, it is possible to reduce the time for transmitting the power-off signal as compared with the prior art. For this reason, it is possible to reduce the amount of energy that should be stored in the power storage unit 24 and to reduce the volume of the power storage unit 24 compared to the conventional case. Can be small.
[0052]
FIG. 2 shows a packet communication apparatus according to the second embodiment of the present invention. The parts corresponding to those in FIG.
In this embodiment, a reception function is added to the transmission function of the packet communication circuit 20 of FIG. That is, a packet signal input / output unit 40 is provided instead of the packet signal output unit 10 of FIG. 1, and the packet communication circuit 20 includes a receiving unit 25 that receives a signal, and a packet signal input by processing the received signal. A packet signal reception processing unit 26 to be output to the output unit 40 is added.
[0053]
Also with the above configuration, the same effect can be obtained by performing the same operation as in the first embodiment. At the same time, when the packet communication device of FIG. 2 is used as the reception side, it is possible to detect and process a power-off signal from the packet communication device on the transmission side.
[0054]
FIG. 3 shows a packet communication apparatus according to the third embodiment of the present invention. The parts corresponding to those in FIG. This embodiment corresponds to claim 2.
In FIG. 3, the power storage unit 24 includes a diode 241, a capacitor 242, and a regulator 243 as illustrated.
[0055]
The capacitor 242 accumulates electric charges due to the power supply voltage Vs. The diode 241 prevents the current from the capacitor 242 from flowing backward to the power supply side when the power supply is cut off. The regulator 243 is operable when the input voltage from the capacitor 242 is equal to or higher than Vi, and stabilizes and outputs the input voltage to the constant voltage Vr. Further, the power-off detection unit 23 outputs a power-off detection signal when the power supply voltage Vs becomes lower than the predetermined voltage Vt.
[0056]
The capacitor 242 can supply each part of the packet communication circuit 20 with the power necessary for the packet signal transmission processing unit 21 to continuously output the power-off signal during the time T after the power-off detection signal is output. It has the following capacity C.
C> (2 · T · I · Vr) / [a · {(Vt−Vd) ² -Vi ² }] …… (1)
However,
Vd: Voltage drop when diode 241 is ON
a: Conversion efficiency of regulator 243
I: Total current that flows through each of these parts when the constant voltage Vr from the regulator 243 is supplied to the power-off detection unit 23, the packet signal transmission processing unit 21, and the transmission unit 22.
[0057]
FIG. 4 shows a packet communication apparatus according to the fourth embodiment of the present invention. The parts corresponding to those in FIG.
In this embodiment, a reception function is added to the packet communication circuit 20 of FIG. 3, and a reception unit 25 and a packet signal reception processing unit 26 of FIG. 2 are added.
Therefore, I in the above formula (1) in this case indicates the total current flowing from the regulator 243 to the power interruption detection unit 23, the packet signal transmission processing unit 21, the transmission unit 22, the reception unit 25, and the packet signal reception processing unit 26. ing.
Also with the above configuration, the same operation as in the first to third embodiments is performed, and the same effect can be obtained.
[0058]
FIG. 5 shows a packet communication apparatus according to a fifth embodiment of the present invention. The parts corresponding to those in FIG.
The present embodiment is a packet communication device in which a plurality of packet communication circuits # 1 to #N are detachably connected to the packet communication device main body 60.
In this case, each of the packet communication circuits # 1 to #N can be attached and detached while receiving a voltage from the power supply unit 30 of the apparatus main body 60, that is, can be hot swapped.
[0059]
According to the present embodiment, not only power interruption but also power interruption due to removal of each of the packet communication circuits # 1 to #N from the apparatus main body 60 can be notified to the receiving side with a simple circuit configuration.
[0060]
FIG. 6 shows the configuration and operation of a packet communication system according to the sixth embodiment of the present invention. This embodiment corresponds to claim 3.
FIG. 6A shows a packet communication system in which a signal from a packet communication node 1 as a packet communication device is transmitted through a transmission line having a transmission line delay d and received by the packet communication node 2.
FIG. 2B shows the operation of the packet communication node 1 and the transmission signal. FIG. 2C shows the operation of the packet communication node 2 and the received signal. This reception signal is processed in the reception unit 25 and the packet signal reception processing unit 26 in the packet communication node 2.
[0061]
In (b), the transmission signal is started to be transmitted from time t, and the encoded packet signal and the inter-packet gap filled with the idle code set are alternately transmitted. Reception of this signal is started by the packet communication node 2 from time t + d as shown in (c).
[0062]
When power-off of the packet communication node 1 is detected at a certain time t1 in (b), a power-off signal is output. In the present embodiment, this power-off signal is constituted by a plurality of power-off code sets 70 as shown in the figure. Each power code set 70 includes s n-bit codes C1, C2,... Cs. After p power-off code sets 70 have been transmitted, the packet communication node 1 stops transmitting.
[0063]
In (c), the receiving side receives the power-off code set 70 at time t1 + d. At the time t ′ when q (q ≦ p) pieces of the power-off code set 70 have been received continuously, it is determined that the power supply on the transmitting side is off. Therefore, it is possible to determine the power interruption before stopping transmission on the transmission side. At this time, by recording the time t ′ in the power-off detection process, it can be used for elucidating the cause of reception interruption.
[0064]
7 shows a transmission flow of the power-off code set 70 of the packet communication node 1, and FIG. 8 shows a power-off detection flow of the packet communication node 2.
In FIG. 7, after initialization by power-on reset, the presence / absence of power-off is detected. If the power is not off, one packet signal code is transmitted, and then the presence / absence of power-off is detected again (steps S1, S2,. Hereinafter, steps are omitted). When the power interruption occurs, the number of transmissions of the power interruption code set 70 is set to 0 (S3), and then the power interruption code set 70 is transmitted one by one, and the number of transmissions is incremented by 1 every time it is transmitted (S4, S5). ). When p pieces are transmitted continuously, the transmission is stopped (S6).
[0065]
In FIG. 8, after initialization, the number of times of power-off code set reception is set to 0, and the power-off detection state is set to 0 (state where power is not off) (S11). Next, the presence / absence of reception interruption is detected (S12). If reception interruption occurs, one of the codes of the power interruption code set 70 is received (S13), and it is sequentially confirmed whether the codes are C1, C2,. (S14 to S18). If all the confirmations have been made, the number of times of reception of the power-off code set is incremented by 1 (S19). (S22). If the reception is actually cut off, the reception cut-off state is recovered and then the process returns to the original state (S23).
[0066]
FIG. 9 shows the configuration and operation of a packet communication system according to the seventh embodiment of the present invention. This embodiment corresponds to claim 4.
FIG. 9A shows a packet communication system in which a signal from a packet communication node 1 as a packet communication device is transmitted through the relay node 1 and the relay node 2 and received by the packet communication node 2.
FIG. 2B shows the operation of the packet communication node 1 and the transmission signal.
[0067]
In (b), the transmission signal is started to be transmitted from time t, and the encoded packet signal and the inter-packet gap filled with the idle code set are alternately transmitted. This transmission signal is sequentially relayed by the relay nodes 1 and 2 and received by the packet communication node 2. At this time, in each of the relay nodes 1 and 2, the idle code set included in the packet signal to be relayed is removed and the idle code set generated by itself is inserted. That is, since each relay node performs transmission in synchronization with a clock generated by itself rather than a clock regenerated from the received signal, jitter of the signal to be relayed can be suppressed.
[0068]
On the other hand, in the packet communication node 1, after detecting power-off, p power-off code sets 70 are transmitted, and then p ′ idle code sets 80 are transmitted. Since the idle code set 80 is inserted / removed as described above at the relay node, normal relay can be performed even after the power-off is detected as in the packet signal relay.
[0069]
FIG. 10 shows a transmission flow of the power disconnection code set 70 of the packet communication node 1. Note that the power-off detection flow of the packet communication node 2 is the same as that in FIG.
In FIG. 10, the presence / absence of power-off is detected. If the power is not off, the presence / absence of power-off is detected every time one code of the packet signal is transmitted (S31, S32). When power-off is detected, the number of transmissions of the power-off code set 70 is set to 0 (S33), transmission of the power-off code set 70 is started, and when p pieces are transmitted (S34, S35), the idle code set 80 Is set to 0 (S36). Next, transmission of the idle code set 80 is started, and when p ′ pieces are transmitted, the number of times of power-off code set transmission is set to 0 (S37, S38, S33).
[0070]
FIG. 11 shows the configuration and operation of a Gigabit LAN communication system according to the eighth embodiment of the present invention. In this example, Ethernet (registered trademark) is used as the LAN. This embodiment corresponds to claim 5.
FIG. 11A shows a packet communication system in which a signal from a Gigabit Ethernet (registered trademark) communication node 1 as a packet communication device is transmitted through a relay node 1 and a relay node 2 and received by the Gigabit Ethernet (registered trademark) communication node 2. It is.
FIG. 4B shows the operation and transmission signal of the Gigabit Ethernet (registered trademark) communication node 1. Note that the power-off code set transmission flow of the Gigabit Ethernet (registered trademark) communication node 1 is the same as in FIG. 7, and the power-off detection flow of the Gigabit Ethernet (registered trademark) communication node 2 is the same as in FIG.
[0071]
In (b), the transmission signal is started to be transmitted from time t, and an Ethernet (registered trademark) frame and an interframe gap which are mb / nb encoded (m = 8, n = 10 in the illustrated example) are alternately transmitted. Is done. This transmission signal is sequentially relayed by the relay nodes 1 and 2 and received by the Gigabit Ethernet (registered trademark) communication node 2.
[0072]
After detecting power-off, the Gigabit Ethernet (registered trademark) communication node 1 transmits p = 16 power-off code sets 70 and then transmits p ′ = 16 idle code sets 80. In this case, it is assumed that the power-off code set 70 includes two codes C1 and C2 having the following bit patterns.
C1 = K28.5 (00111111010)
C2 = 0100100011 (It is a bit pattern that deviates from the 8b / 10b code rule. 0000100011 is also possible as a bit pattern)
[0073]
The idle code set 80 includes two codes K28.5 and D16.2 having the following bit patterns.
K28.5 = 00111111010
D16.2 = 1001000101
[0074]
According to the present embodiment, the gigabit Ethernet (registered trademark) communication node 2 that does not have the reception function of the power-off code set 70 and receives a signal that complies with the mb / nb code rule has the mb / nb code rule. Utilizing the fact that a reception error state occurs when a bit pattern that does not follow is frequently received makes it possible for the node 2 on the reception side to detect a power failure on the transmission side. That is, in the power cut-off code set 60 composed of codes of C1 and C2 of n-bit length, at least one code Ci is set as a bit pattern that is not generated by the mb / nb coding rule, so that the node 2 Can receive a power-off on the transmission side as an alarm since a reception error state occurs when this power-off code set 70 is received.
[0075]
Next, a program and a computer-readable recording medium according to the embodiment of the present invention will be described.
The program for the CPU of the computer system in the packet communication circuit and the packet communication apparatus to execute the processing based on the operations described in the above-described embodiments and the processing shown in the flowcharts constitutes a program according to the present invention. The recording medium on which the program is recorded constitutes a computer-readable recording medium according to the present invention.
[0076]
As a recording medium for recording this program, a magneto-optical disk, an optical disk, a semiconductor memory, a magnetic recording medium, and the like can be used. These are configured as a ROM, a RAM, a CD-ROM, a flexible disk, a memory card, and the like. May be used.
[0077]
In addition, this recording medium can store a program for a certain period of time such as a volatile memory such as a RAM in a computer system as a server or a client when the program is transmitted via a network such as the Internet or a communication line such as a telephone line. The thing to hold is also included.
[0078]
The program may be transmitted from a computer system storing the program in a storage device or the like to another computer system via a transmission medium or by a transmission wave in the transmission medium. The transmission medium refers to a medium having a function of transmitting information, such as a network (communication network) such as the Internet or a communication line (communication line) such as a telephone line.
[0079]
The program may be for realizing a part of the functions described above. Furthermore, what can implement | achieve the function mentioned above in combination with the program already recorded on the computer system, what is called a difference file (difference program) may be sufficient.
[0080]
Therefore, the recording medium is used in a system or apparatus different from the system or apparatus of each embodiment, and the computer of the system or apparatus executes the program recorded in the recording medium. Functions and effects equivalent to the functions and effects described can be obtained, and the object of the present invention can be achieved.
[0081]
【The invention's effect】
As described above, according to the present invention, the power-off signal is continuously transmitted when the power-off is detected, so that the receiving side can know the power-off on the transmitting side in a short time. As a result, the period during which the power-off signal is to be transmitted can be shortened, so that the amount of energy that the power storage unit should store can be reduced, and the volume of the power storage unit can be reduced. Further, since the power storage unit can supply power to only the packet communication circuit, which is the minimum circuit necessary for transmitting the power-off signal, the amount of energy that the power storage unit should store is limited. This can be reduced, and the volume of the power storage unit can be reduced. Since the volume of the power storage unit can be reduced, the packet communication circuit can be reduced in size.
[0082]
Further, since it is determined that the power supply is cut off when the power supply voltage becomes a certain value or less, it is possible to realize the power interruption detection with a simple circuit, and to realize a reduction in size and cost of the packet communication circuit. In addition, it is possible to reliably detect power interruptions caused by various factors. That is, when the packet communication circuit is detachable from the packet communication device main body, it can be detected not only when the power of the device main body is turned off but also when the packet communication circuit is removed from the device main body.
[0083]
In addition, since a power-off code set that combines codes that are basic units of communication is used as a signal to notify power-off, it is easy to generate and detect in a packet communication device that performs processing in units of codes. Become. Further, the first packet communication device on the transmission side continuously transmits p power-off code sets, and the second packet communication device on the reception side continuously receives q power-off code sets. In this case, since the power-off of the first packet communication device is detected, it is possible to easily increase the reliability of the power-off notification by increasing the values of p and q. Further, when the power failure of the first packet communication device is detected in the second packet communication device, it can be used for elucidating the cause of the reception failure by performing a power failure detection process such as recording the time. .
[0084]
In addition, when the first packet communication apparatus detects a power interruption, not only the power interruption code set but also the idle code set is transmitted, so the function of inserting and removing the idle code set on the transmission path leading to the second packet communication apparatus is provided. A network configuration in which there are relay nodes is possible. The relay node can suppress the jitter of the relayed signal by inserting and extracting the idle code set included in the packet signal to be relayed. Therefore, the relay node can be arranged on the transmission path, and the transmission distance from the first packet communication device to the second packet communication device can be extended without degrading the signal.
[0085]
In addition, the second packet communication device can know the power-off of the first packet communication device by receiving the power-off code set, and processes the power-off signal separately from the normal packet information. Is possible. When the second packet communication apparatus that does not have the power-off code set reception mechanism and receives a signal that conforms to the mb / nb code rule frequently receives a bit pattern that does not conform to the mb / nb code rule, a reception error state This makes it possible to detect a power-off on the transmission side even on the reception side. That is, at least one Ci among the power cut-off code sets composed of s (s is a natural number) n-bit codes of C1, C2,..., Cs is determined by the mb / nb coding rule. By using a bit pattern that is not generated, the reception side is in a reception error state when receiving this power-off code set, and therefore can notify the reception side of power-off on the transmission side.
[Brief description of the drawings]
FIG. 1 is a block diagram and a timing chart showing a packet communication apparatus and its operation according to a first embodiment of the present invention.
FIG. 2 is a block diagram and a timing chart showing a packet communication device and its operation according to a second embodiment of the present invention.
FIG. 3 is a block diagram and timing chart showing a packet communication circuit and its operation according to a third embodiment of the present invention.
FIG. 4 is a block diagram and timing chart showing a packet communication circuit and its operation according to a fourth embodiment of the present invention.
FIG. 5 is a block diagram and timing chart showing a packet communication apparatus and its operation according to a fifth embodiment of the present invention.
FIG. 6 is a block diagram and timing chart showing a packet communication system and its operation according to a sixth embodiment of the present invention.
FIG. 7 is a flowchart showing the operation of the transmission side packet communication apparatus.
FIG. 8 is a flowchart showing the operation of the receiving side packet communication apparatus.
FIG. 9 is a block diagram and timing chart showing a packet communication system and its operation according to a seventh embodiment of the present invention.
FIG. 10 is a flowchart showing a power-off code set transmission operation of the transmission side packet communication apparatus.
FIG. 11 is a block diagram and timing chart showing a Gigabit Ethernet (registered trademark) communication system as a packet communication system according to an eighth embodiment of the present invention and its operation.
FIG. 12 is a block diagram showing the structure of a conventional SDH frame.
FIG. 13 is a block diagram and timing chart showing a conventional SDH communication system and its operation.
FIG. 14 is a block diagram showing a configuration of a conventional transmitting side node.
FIG. 15 is a block diagram showing a configuration of a conventional integrated network to which the present invention can be applied.
16 is a configuration diagram showing a signal configuration and a frame structure according to the SDH scheme in the synchronous communication system 7 of FIG. 15;
FIG. 17 is a timing chart showing an example of signals to be communicated in the new communication system 7 ′ of FIG.
[Explanation of symbols]
10 Packet signal output section
20 Packet communication circuit
21 Packet signal transmission processor
22 Transmitter
23 Power-off detector
24 Power storage unit
25 Receiver
26 Packet signal reception processor
30 Power supply unit
40 Packet signal input / output section
60 Packet communication device body
70 Power off sign set
80 idle code set

Claims (7)

The encoded packet signal is transmitted from the first packet communication device to the second packet communication device via the transmission path, and the second packet communication is performed before the transmission is stopped due to power failure in the first packet communication device. In the power-off notification method of the packet communication system for notifying the apparatus of power-off,
When the first packet communication device detects a power-off, it continuously transmits p power-off code sets,
The first packet communication device repeats a power-off transmission process of continuously transmitting p 'idle code sets after continuously transmitting the p power disconnection code sets,
A power-off notification method for a packet communication system, wherein the second packet communication device performs a power-off detection process when q (q ≦ p) consecutive power-off codes are received. The encoded packet signal is transmitted from the first packet communication device to the second packet communication device via the transmission path, and the second packet communication is performed before the transmission is stopped due to power failure in the first packet communication device. In the power-off notification method of the packet communication system for notifying the apparatus of power-off,
When the first packet communication device detects a power-off, it continuously transmits p power-off code sets,
The first packet communication device repeats a power-off transmission process of continuously transmitting p 'idle code sets after continuously transmitting the p power disconnection code sets,
A relay node installed on a transmission path between the first packet communication device and the second packet communication device removes the idle code set transmitted from the first packet communication device, Inserting the idle code set generated in synchronization with the clock generated in step ii and relaying it to the second packet communication device,
The second packet communication apparatus performs a power-off detection process when q (q ≦ p) continuous power-off code sets are received. A power-off notification method for a packet communication system, comprising: The code rule of the packet signal is an mb / nb code rule (n> m), the power cutoff code set is composed of a plurality of n-bit codes, and at least one code is an mb / nb code. 3. The power-off notification method for a packet communication system according to claim 1 , wherein the code has a bit pattern that does not follow a rule. In a packet communication device that transmits an encoded packet signal to a packet communication device on the receiving side,
Power-off detection means for detecting power-off,
When the power-off detection means detects a power-off, the p power-off code sets are continuously transmitted , and the p power-off code sets are continuously transmitted, and then the p ′ idle code sets are transmitted. And a power-off processing means for repeating the continuous transmission of the packet communication device. In a packet communication circuit that transmits an encoded packet signal to a packet communication device on the receiving side,
  Power-off detection means for detecting power-off,
  When the power-off detection means detects a power-off, the p power-off code sets are continuously transmitted, and the p power-off code sets are continuously transmitted, and then the p ′ idle code sets are transmitted. And a power-off processing means that repeatedly transmits
  And a packet communication circuit. A program for causing a computer of a packet communication device to transmit an encoded packet signal to a packet communication device on the receiving side,
  Power-off detection processing for detecting power-off,
  When the power-off detection means detects a power-off, the p power-off code sets are continuously transmitted, and the p power-off code sets are continuously transmitted, and then the p ′ idle code sets are transmitted. Power-off process that repeats sending
  A program that causes a computer to execute. A recording medium for storing a program to be executed by a computer of a packet communication device that transmits an encoded packet signal to a packet communication device on a receiving side,
  Power-off detection processing for detecting power-off,
  When the power-off detection means detects a power-off, the p power-off code sets are continuously transmitted, and the p power-off code sets are continuously transmitted, and then the p ′ idle code sets are transmitted. Power-off process that repeats sending
  Medium for storing a program for causing a computer to execute the program.

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