CA2053734C - Supervision control system - Google Patents
Supervision control system Download PDFInfo
- Publication number
- CA2053734C CA2053734C CA 2053734 CA2053734A CA2053734C CA 2053734 C CA2053734 C CA 2053734C CA 2053734 CA2053734 CA 2053734 CA 2053734 A CA2053734 A CA 2053734A CA 2053734 C CA2053734 C CA 2053734C
- Authority
- CA
- Canada
- Prior art keywords
- cell
- cells
- received
- identified virtual
- virtual connection
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired - Lifetime
Links
Classifications
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/54—Store-and-forward switching systems
- H04L12/56—Packet switching systems
- H04L12/5601—Transfer mode dependent, e.g. ATM
- H04L12/5602—Bandwidth control in ATM Networks, e.g. leaky bucket
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L49/00—Packet switching elements
- H04L49/30—Peripheral units, e.g. input or output ports
- H04L49/3081—ATM peripheral units, e.g. policing, insertion or extraction
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/54—Store-and-forward switching systems
- H04L12/56—Packet switching systems
- H04L12/5601—Transfer mode dependent, e.g. ATM
- H04L2012/5629—Admission control
- H04L2012/5631—Resource management and allocation
- H04L2012/5636—Monitoring or policing, e.g. compliance with allocated rate, corrective actions
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/54—Store-and-forward switching systems
- H04L12/56—Packet switching systems
- H04L12/5601—Transfer mode dependent, e.g. ATM
- H04L2012/5638—Services, e.g. multimedia, GOS, QOS
- H04L2012/5646—Cell characteristics, e.g. loss, delay, jitter, sequence integrity
- H04L2012/5651—Priority, marking, classes
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/54—Store-and-forward switching systems
- H04L12/56—Packet switching systems
- H04L12/5601—Transfer mode dependent, e.g. ATM
- H04L2012/5638—Services, e.g. multimedia, GOS, QOS
- H04L2012/5646—Cell characteristics, e.g. loss, delay, jitter, sequence integrity
- H04L2012/5652—Cell construction, e.g. including header, packetisation, depacketisation, assembly, reassembly
Abstract
A supervision control system for an ATM cell switching system counts the number of cells transmit-ted from a subscriber in a predetermined duration unit, attaches a sign to the cells when the counted value exceeds a predetermined value, and discards the cells to which the sign is attached when a buffer does not have enough capacity during a cell multi-plexation.
Description
A SUPERVISION CONTROL SYSTEM
Background of the Invention 5 This invention pertains to a supervision control system for supervising the inflow of cells to an ATM
switching system.
The ATM switching system switches cells having fifty-four (54) bytes split from various data, such as voice data, image data and other numerical data, and transmits in a multiplexed form the various data at different transmission speed. Of the fifty-four (54) bytes in a cell, forty-eight (48) bytes form an information field and six (6) bytes form a header 15 part. Of the four (4) bytes, i.e. thirty-two (32) bits, in the header part excluding two (2) bytes forming a tag, twenty-eight (28) bits indicate a VPI/VCI (virtual path identifier/virtual channel identifier), two (2) bits indicate a PT (payload 20 type), one (1) indicates a CLP (cell loss priority) and one (1) bit is for a RES (reserve).
A buffer in a multiplexer for these cells can experience an overflow when an unexpected number of cells flow in. Since overflowing cells are dis-25 carded, the communications quality is deteriorated.
2t~~3'~~4 Although such a problem can be avoided by using a buffer having a larger capacity, a larger delay results, which is critical in transmitting voice data, image data, and so forth.
Therefore, a buffer is required in which the occurrence of an overflow and its effect are mini-mized.
Description of the Related Art Figure 1 is a block diagram of an ATM switching system.
As shown in Figure 1 , a plurality of terminals (TE) 10 are connected through respective terminal 15 adapters (TA) 9 to one of plural network terminators (NT) 8 in an ATM switching system.
The network terminators (NT) 8 are connected through respective interoffice trunks 6 to one (1) of plural broadband remote switching units (BRSU) 7.
20 The broadband remote switching units (BRSU) 7 are connected to one ( 1 ) of a plurality of central of-fices (CO) 5.
The interoffice trunks 6 interconnect the central offices (CO) 5. The interoffice trunks 6 and 25 subscriber lines are high speed transmission paths, ":i.'.ix',:
20~~'~34 such as an optical transmission path e.g. comprising a SONET (Synchronous Optical Network), having bands of one hundred fifty-five mega-herts (155 MHz), six hundred twenty-two mega-herts (622 MHz) or higher.
Figure 2 shows a cell configuration.
As described earlier, voice data, image data, numerical data, etc. from the terminals (TE) 10 are split into cells having fifty-four (54) bytes.
Because one ( 1 ) word is defined to comprise two ( 2 ) 10 bytes, a cell has twenty-seven (27) words. As shown in Figure 2, of the fifty-four (54) bytes in a cell, forty-eight (48) bytes form an information field and six (6) bytes form a header part. Of the six (6) bytes, i.e. forty-eight (48) bits, in the 15 header part, two (2) bytes, i.e. sixteen (16) bits, form a tag, twenty-eight (28) bits indicate a VPI/VCI
(virtual path identifier/virtual channel identifier), two (2) bits indicate a PT (payload type), one (1) bit indicates a CLP (cell loss priority) and one (1) 20 bit is for a RES (reserve).
The network terminators (NT) 8 send the cells to the broadband remote switching units (BRSU) 7.
The terminal adapters (TA) 9 receive cells from corresponding terminals (TE) 10 through the network 25 terminators (NT) 8 and send the decelled voice data, 20~3~~4 image data, numerical data, etc. to the terminals (TE) 1 0.
Figure 3 is a block diagram of one (1) of the broadband remote switching units (BRSU) 7.
Background of the Invention 5 This invention pertains to a supervision control system for supervising the inflow of cells to an ATM
switching system.
The ATM switching system switches cells having fifty-four (54) bytes split from various data, such as voice data, image data and other numerical data, and transmits in a multiplexed form the various data at different transmission speed. Of the fifty-four (54) bytes in a cell, forty-eight (48) bytes form an information field and six (6) bytes form a header 15 part. Of the four (4) bytes, i.e. thirty-two (32) bits, in the header part excluding two (2) bytes forming a tag, twenty-eight (28) bits indicate a VPI/VCI (virtual path identifier/virtual channel identifier), two (2) bits indicate a PT (payload 20 type), one (1) indicates a CLP (cell loss priority) and one (1) bit is for a RES (reserve).
A buffer in a multiplexer for these cells can experience an overflow when an unexpected number of cells flow in. Since overflowing cells are dis-25 carded, the communications quality is deteriorated.
2t~~3'~~4 Although such a problem can be avoided by using a buffer having a larger capacity, a larger delay results, which is critical in transmitting voice data, image data, and so forth.
Therefore, a buffer is required in which the occurrence of an overflow and its effect are mini-mized.
Description of the Related Art Figure 1 is a block diagram of an ATM switching system.
As shown in Figure 1 , a plurality of terminals (TE) 10 are connected through respective terminal 15 adapters (TA) 9 to one of plural network terminators (NT) 8 in an ATM switching system.
The network terminators (NT) 8 are connected through respective interoffice trunks 6 to one (1) of plural broadband remote switching units (BRSU) 7.
20 The broadband remote switching units (BRSU) 7 are connected to one ( 1 ) of a plurality of central of-fices (CO) 5.
The interoffice trunks 6 interconnect the central offices (CO) 5. The interoffice trunks 6 and 25 subscriber lines are high speed transmission paths, ":i.'.ix',:
20~~'~34 such as an optical transmission path e.g. comprising a SONET (Synchronous Optical Network), having bands of one hundred fifty-five mega-herts (155 MHz), six hundred twenty-two mega-herts (622 MHz) or higher.
Figure 2 shows a cell configuration.
As described earlier, voice data, image data, numerical data, etc. from the terminals (TE) 10 are split into cells having fifty-four (54) bytes.
Because one ( 1 ) word is defined to comprise two ( 2 ) 10 bytes, a cell has twenty-seven (27) words. As shown in Figure 2, of the fifty-four (54) bytes in a cell, forty-eight (48) bytes form an information field and six (6) bytes form a header part. Of the six (6) bytes, i.e. forty-eight (48) bits, in the 15 header part, two (2) bytes, i.e. sixteen (16) bits, form a tag, twenty-eight (28) bits indicate a VPI/VCI
(virtual path identifier/virtual channel identifier), two (2) bits indicate a PT (payload type), one (1) bit indicates a CLP (cell loss priority) and one (1) 20 bit is for a RES (reserve).
The network terminators (NT) 8 send the cells to the broadband remote switching units (BRSU) 7.
The terminal adapters (TA) 9 receive cells from corresponding terminals (TE) 10 through the network 25 terminators (NT) 8 and send the decelled voice data, 20~3~~4 image data, numerical data, etc. to the terminals (TE) 1 0.
Figure 3 is a block diagram of one (1) of the broadband remote switching units (BRSU) 7.
5 A multiplexer/demultiplexer (MDX) 12 multiplexes cells asynchronously inputted from subscribers through a buffer and transmitted over a plurality of subscriber line trunks 11, which are connected to respective subscriber lines. A concentrator switch 10 (CSW) 13 switches the multiplexed cells. A multi-plexer/demultiplexer (MDX) 14 demultiplexes the switched cells over to an appropriate one (for the predetermined central office) of a plurality of interoffice trunks 15, which form interoffice cell 15 transmission paths.
The multiplexer/demultiplexer (MDX) 14 multiplex-es cells asynchronously inputted from correspondent subscribers through a buffer and transmitted over the interoffice trunks 15. The concentrator switch 20 (CSW) 13 switches the multiplexed cells. The multiplexer/demultiplexer (MDX) 12 demultiplexes the switched cells over to an appropriate one (for the predetermined subscriber) of a plurality of subscrib-er line trunks 11.
25 A local processor interface (LPIF) 16 connects a 2053"~~4 local processor (LPR) 17 with the concentrator switch (CSW) 13 and multiplexers/demultiplexers (MDXs) 12 and 1 4 .
When a larger number of cells flow into the 5 multiplexer/demultiplexer (MDX) 12, its buffer causes some cells to overflow. Therefore, a virtual path is set at a call-up by having a subscriber declare his cell transmission band and by judging whether or not the cells can be multiplexed in the declared band.
In this case, if this subscriber sends cells over the declared band, cells from other subscribers who share the same buffer with this subscriber are also discarded.
15 That is, if any subscriber sends cells over the declared band, a large ill-effect occurs such that cells from other subscribers are also discarded.
2 0 Summary of the Invention This invention pertains to a supervision control system for supervising the inflow of cells to an ATM
switching system.
It aims at avoiding a congestion state caused by 25 a cell inflow over a band declared by a subscriber.
The multiplexer/demultiplexer (MDX) 14 multiplex-es cells asynchronously inputted from correspondent subscribers through a buffer and transmitted over the interoffice trunks 15. The concentrator switch 20 (CSW) 13 switches the multiplexed cells. The multiplexer/demultiplexer (MDX) 12 demultiplexes the switched cells over to an appropriate one (for the predetermined subscriber) of a plurality of subscrib-er line trunks 11.
25 A local processor interface (LPIF) 16 connects a 2053"~~4 local processor (LPR) 17 with the concentrator switch (CSW) 13 and multiplexers/demultiplexers (MDXs) 12 and 1 4 .
When a larger number of cells flow into the 5 multiplexer/demultiplexer (MDX) 12, its buffer causes some cells to overflow. Therefore, a virtual path is set at a call-up by having a subscriber declare his cell transmission band and by judging whether or not the cells can be multiplexed in the declared band.
In this case, if this subscriber sends cells over the declared band, cells from other subscribers who share the same buffer with this subscriber are also discarded.
15 That is, if any subscriber sends cells over the declared band, a large ill-effect occurs such that cells from other subscribers are also discarded.
2 0 Summary of the Invention This invention pertains to a supervision control system for supervising the inflow of cells to an ATM
switching system.
It aims at avoiding a congestion state caused by 25 a cell inflow over a band declared by a subscriber.
It configures a supervision control apparatus for an ATM (Asynchronous Transmission Mode) cell switching system comprising a supervisor and a multiplexer. The supervisor further comprises a cell counter and a judge. The cell counter counts cells transmitted from a subscriber in a predetermined duration unit. The judge attaches a sign to the cells when the value counted by the cell counter exceeds a predetermined value. The multiplexer discards the cells to which the sign is attached when a buffer does not have enough capacity during a cell multiplexation.
In accordance with the present invention there is provided a supervision control method for an asynchronous transmission mode cell switching system comprising the steps of: (a) storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored in memory regions at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; (b) counting cells having one of the plurality of identified virtual connections formed by a particular virtual channel identifier and a particular virtual path identifier transmitted from a subscriber in a predetermined duration unit, by incrementing a count value stored in one of the memory regions having an address uniquely accessed with said particular virtual channel identifier and said particular virtual path identifier; (c) attaching a sign to the cells when the count value incremented in said step (b) exceeds a predetermined value; and (d) discarding the cells to which said sign is attached when a buffer does not have enough capacity to multiplex the cells.
In accordance with the present invention there is also provided a supervision control method for an asynchronous transmission mode cell switching system comprising the steps of: (a) counting cells having a particular virtual channel 6a identifier and a particular virtual path identifier received from a subscriber in a predetermined unit by incrementing a count value stored in a memory region having an address uniquely accessed with said particularly virtual path identifier; (b) attaching a sign to the cells when the count value incremented in said step (a) exceeds a first predetermined value; (c) discarding the excess cells over a second predetermined value when the count value incremented in said step (a) exceeds the second predetermined value; and (d) discarding the excess cells over the first predetermined value, to which the sign is attached in said step (b), when a buffer does not have enough capacity to multiplex the cells.
In accordance with the present invention there is further provided a supervision control apparatus for an asynchronous transmission mode cell switching system comprising: a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, the bandwidth data being stored at address thereof, each address being operatively accessed based on one of a plurality of identified virtual connections; a cell counter including a memory to store a count value at an address uniquely accessed with one of the plurality of identified virtual connections formed by a particular virtual channel identifier and a particular virtual path identifier, for counting cells having said particular virtual channel identifier and said particular virtual path identifier transmitted from a subscriber in a predetermined duration unit by incrementing the count value; a judge circuit for attaching a sign to the cells when the count value incremented by said cell counter exceeds a predetermined value; and a multiplexer for discarding the cells to which the sigh is attached when a buffer does not have enough capacity to multiplex the cells.
In accordance with the present invention there is also provided a supervision control apparatus for a cell 6b switching system comprising: a cell counter including a memory to store a count value at an address uniquely accessed with a particular virtual channel identifier and a particular virtual path identifier, for counting cells having said particular virtual channel identifier and said particular virtual path identifier transmitted from a subscriber in a predetermined duration unit; a judge circuit for attaching a sign to the cells when the count value incremented by said cell counter exceeds a first predetermined value; a selector for discarding the excess cells over a second predetermined value when the count value incremented by said cell counter exceeds the second predetermined value; and a multiplexer for discarding the excess cells over the first predetermined value, to which said sign is attached by said judge circuit, when a buffer does not have enough capacity to multiplex the cells.
In accordance with the present invention there is further provided a supervision control method in which cells, each including a header field with an identified virtual connection, are received from a plurality of sources, comprising: storing a plurality of bandwidth data which are pre-assigned to the sources of the cells and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; monitoring a transmission rate on the identified virtual connection of a received cell; comparing the transmission rate with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and marking the received cell to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a supervision control apparatus in which 6c cells, each including a header field with an identified virtual connection, are received from a plurality of sources, comprising: a memory to store a plurality of bandwidth data which are pre-assigned to the sources of the cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections; a cell counter to monitor a transmission rate on the identified virtual connection of a received cell; a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a supervision control apparatus, comprising: a receiver to receive a cell including a header field with an identified virtual connection; a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections; a cell counter to monitor a transmission rate on the identified virtual connection of a received cell; a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a supervision control method, comprising:
6d receiving a cell including a header field with an identified virtual connection; storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; monitoring a transmission rate on the identified virtual connection of a received cell; comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the received cell to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a supervision control method in which cells, each including a header field with an identified virtual connection and a bit indicating a cell loss priority, are received, comprising: storing a plurality of bandwidth data which are pre-assigned to sources of the cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; monitoring a transmission rate on the identified virtual connection of a received cell; comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the bit to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a switching system which receives a cell including a header field with an identified virtual connection, comprising: a supervisor, including; a memory to store a 6e plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; a cell counter to monitor a transmission rate on the identified virtual connection specified by a received cell; a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to the identified virtual connection.
In accordance with the present invention there is further provided a supervision control method in which a cell having a header field with an identified virtual connection, is received from a source, comprising: storing a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; and marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the stored bandwidth data for the received cell.
In accordance with the present invention there is further provided a supervision control apparatus in which a cell having a header field with an identified virtual connection, is received from a source, comprising a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual 6f connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at an address of the memory corresponding to the identified virtual connection of the received cell.
In accordance with the present invention there is further provided a switching system which receives a cell including a header field with an identified virtual connection, comprising: a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at the address of the memory corresponding to the identified virtual connection of the received cell; and a switch to direct the cell from said supervisor to the identified virtual connection.
In accordance with the present invention there is further provided a switching system located along an identified virtual connection, comprising: an interface to receive a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority; a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the bit to indicate a higher cell loss priority when the monitored transmission rate corresponding to the bandwidth data stored at an address of the memory corresponding to the identified virtual connection in the header field of the received cell; and a switch, to direct 6g the cell from said supervisor to an output of the identified virtual connection.
Brief Description of the Drawinas Figure 1 is a block diagram of an ATM switching system;
Figure 2 shows a cell configuration;
Figure 3 is a block diagram of one (1) of the broadband remote switching units (BRSU) 7;
Figure 4 is a block diagram of this invention;
Figure 5A is a block diagram of parts pertinent to a first embodiment of this invention;
Figure 5B illustrates an example of cell discarding;
Figure 6 is a block diagram of a subscriber line 20 i3~~~4 trunk pertinent to a second embodiment of this inven-tion;
Figure 7 is a block diagram of the supervisor and the selection control processor pertinent to the second embodiment of this invention; and Figure 8 illustrates the input interface of a multiplexer.
Description of the Preferred Embodiments A supervision control system of this invention prioritizes discarding of cells overflowing from a buffer by attaching a high cell-loss-priority sign to cells flowing in over a band declared by a subscrib-er, thereby minimizing ill-effects to other subscrib-ers.
Figure 4 is a block diagram of this invention, The supervision control apparatus for an ATM
(Asynchronous Transmission Mode) cell switching system comprises a supervisor 23 and a multiplexer 24. A supervisor 23 further comprises a cell counter 21 and a judge 22. The cell counter 21 counts cells transmitted from a subscriber in a predetermined duration unit. The judge 22 attaches a sign to the cells when the value counted by the ... "...........,...~..».,...»...»...a...w....~....~."~.~..,.... ..
.......".""".~;.'"",~~,~".~.w~.~"
2~~3~~~
cell counter 21 exceeds a predetermined value. The multiplexer 24 discards the cells to which the sign is attached when a buffer does not have enough capac-ity during a cell multiplexation.
That is, the cell counter 21 in the supervisor 23 counts cells flowing in from a subscriber in a prede-termined duration unit. The judge 22 in the super-visor 23 judges whether or not the cells are flowing in over the band declared by the subscriber and attaches a sign to a predetermined bit in the excess cells flowing in over the declared band. The multiplexer 24 multiplexes the cells having the sign for their transmission when its buffer has the capac-ity to handle them. However, the multiplexer 24 discards them with high priority, when neither the buffer in the multiplexer 24 itself nor the buffer in a concentrator switch, or in a demultiplexer, con-nected to the multiplexer 24 has a capacity to handle the cells, thereby ensuring the multiplexation and transmission of cells having no such sign input-ted from other subscribers.
Alternatively, the judge 22 in the supervisor 23 can set a first judging threshold and a second judg-ing threshold. The first judging threshold corre-sponds to a band declared by a subscriber. The 2t~~~'~ ~~
second judging threshold is set higher than the first judging threshold. The judge 22 attaches a sign to the inflowing cells from a subscriber in excess of the first judging threshold, and discards the i nflowing cells from the subscriber in excess of the second judging threshold.
That is, the judge 22 sets the first and second judging thresholds in correspondence with a band declared by a subscriber. The judge 22 attaches a sign to the excess inflowing cells over the first judging threshold by appropriately marking the CLP
(cell loss priority) bit or the RES (reserve) bit of the cell, thereby prioritizing the discarding of such cells, when neither the buffer in the multiplexer 24 itself nor the buffer in a concentrator switch, or in a demultiplexer, connected to the multiplexer 24 has a capacity to handle the cells. The judge 22 always discards the inflowing cells in excess of the second judging threshold, because they are likely to cause an overflow in the buffer.
Embodiments of this invention are explained in further detail by referring to some of the attached drawings.
First Embodiment 20~3'~~4 Figure 5A is a block diagram of parts pertinent to a first embodiment of this invention.
Subscriber line terminators 31-1 through 31-m each paired with the corresponding one of interfacers 5 32-1 through 32-m are equivalent to subscriber line trunks connecting subscribers to the ATM cell switch-ing system. A multiplexer 34 receives cells from subscribers by way of the subscriber line terminators 31-1 through 31-m and the interfacers 32-1 through 10 32-m. Supervisors 33-1 through 33-m respectively supervise cell inflows to the multiplexer 34 via the subscriber line terminators 31-1 through 31-m and the interfacers 32-1 through 32-m.
When a subscriber calls up, he declares the band to be occupied. A processor 37 reads from a cell its VCI (virtual channel identifier) for specifying the switchers and the subscriber and its VPI (virtual path identifier? for specifying the paths among the switchers, and notifies the supervisors 33-1 through 33-m of the VCI/VPI and the maximum number of cells, set in correspondence with the subscriber declared band, passing through in a predetermined duration unit.
The supervisors 33-1 through 33-m count the number of cells having particular VCIs/VPIs in the 2~53~~~
predetermined duration units, and attach a sign to the cells in excess of the maximum number of cells, set in correspondence with the subscriber declared band, passing through in a predetermined duration unit, for example, by marking the CLP (cell loss priority) bit in those cells.
Figure 5B illustrates an example of cell discard-ing.
Alternatively, the supervisors 33-1 through 33-m can attach a sign to the cells in excess of the maximum number of cells, set in correspondence with the subscriber declared band, passing through in a predetermined duration unit, by marking the RES
(reserve) bit in those cells, as shown in Figure 5B.
The multiplexer 34 has a buffer. It multiplexes cells from subscribers and supplies the multiplexed cells to a concentrator switch 35. However, it multiplexes cells having the sign marked in their CLP
bit or in their RES bit only when the buffer has enough capacity, and discards them with high priority when the buffer does not have enough capacity.
This ensures the multiplexation of cells from sub-scribers transmitted within the declared bands.
Also, even when the buffer in the multiplexer 34 has enough capacity to handle the cells, the buffer at an input terminal or at an output terminal of a device connected in a later stage, such as the con-centrator switch 35 and a demultiplexer on the re-ceiving side, discards the cells, if it does not have enough capacity.
Also, the supervisors 33-1 through 33-m can attach a sign to the cells in excess of a first judging threshold equivalent to the maximum number of cells, set in correspondence with the subscriber declared band, passing through in a predetermined duration unit, by marking either the CLP bit or the RES bit in those cells. The multiplexer 34 priori-tizes the discarding of those cells having the sign, when its buffer lacks enough capacity. Other devices connected in later stages discard cells similarly, when their respective buffers lack enough capacity. When the number of cells passing through in a predetermined duration unit further increases and reaches a second judging threshold, the multi-plexer 34 can be made to perform a control such that the excess cells over the second judging threshold are discarded regardless of the available capacity of the buffer in the multiplexer 34. The local proc-essor interface 36 notifies the local processor 37 of the results of processing by the supervisors 33-1 ~....-~~.._.:. ._... .. . _~~-.~.- '.~w..~.;,~..~.~,.
,.m:~~:~~:...~.:..~~,~...~. _ .._._.._ . _.~. ..r.:.~..-.....J..._ ~.__._n__...~ _~ .-_. .._...
through 33-m.
Second Embodiment Figure 6 is a block diagram of a subscriber line trunk pertinent to a second embodiment of this inven-tion.
A subscriber line 41 such as a SOVIET based opti-cal transmission path transmits cells in light sig-nals. A light-electricity (electro-optic/opto-electric) converter (EO/OE) 42 converts the cells in light signals to cells in electric signals and sup-plies the converted cells through a terminator 43 and an interfacer 44 to a selection control processor 46.
A local processor 52 notifies a supervisor 45 through a local processor interface 51 of a VCI/VPI and first and second judging thresholds set correspondingly to a subscriber declared band. An alternative ar-rangement can be made such that the processor noti-fies the supervisor 45 of a subscriber declared band and the supervisor 45 sets first and second judging thresholds accordingly.
The supervisor 45 counts the number of cells having a particular VCI/VPI passing through the interfacer 44 in a predetermined duration unit for a comparison with the first and second judging thresh-14 2Q~3'~3~
olds. The supervisor 45 has the selection control processor 46 turn on e.g. the CLP bit in the header part of the cells exceeding the first judging thresh-old, so that discarding of those cells is prioritized when the buffer of a multiplexer 49, or the buffer of a device connected in a later stage, lacks enough capacity. Also, the supervisor 45 has the selec-tion control processor 46 turn on e.g. the RES bit in the header part of the cells exceeding the second judging threshold, so that those cells are supplied to the multiplexer 49 as empty cells, thereby causing those cells to be discarded anyway regardless of the available capacity in the buffer of the multiplexer 49. This is because the multiplexer 49 does not send empty cells to a concentrator switch 50.
Figure 7 is a block diagram of the supervisor 45 and the selection control processor 46 pertinent to the second embodiment of this invention.
A buffer 55 delays cells in correspondence with the delays caused by respective supervisions.
A memory 56 counts the number of cells passing through in a predetermined duration unit.
Memories 57 and 58 respectively store first and second judging thresholds.
A memory 59 measures an elapse of the predeter-15 2~~3'~~4 mined duration unit.
A memory 60 stores duration unit data.
When the supervisor 45 commences its operations, a processor CC instructs selectors 65, 66 and 69 to select their "b" side inputs and to output them to respective address terminals of memories 57, 58 and 60, which receive data from the processor CC as respective data inputs. The processor CC supplies to "b" side inputs of selectors 65, 66 and 69 an address by which memories 57, 58 and 60 are accessed.
The processor CC accesses memories 57, 58 and 60 to have them respectively store the first judging threshold, the second judging threshold and the duration unit data.
When the supervisor 45 commences its operations, the processor CC also instructs selectors 67 and 68 to select their "a" side inputs and to output, so that memory 59 receives an address and data from the processor CC. Memory 59 stores as its initial data duration unit data similar to those stored in memory 60. The processor stores data to be stored in memories 57, 58, 59 and 60 at respective addresses corresponding to VPIs/VCIs.
When the supervisor 45 commences its operations, memory 60 is reset and its stored data are initial-ized to zero (0).
That~is, the processor CC supplies the first and second judging thresholds set correspondingly to the subscriber declared band, the duration unit data indicating the supervision cycle and the addresses corresponding to the subscriber assigned VPIs/VCIs.
Memory 57 stores the first judging threshold.
Memory 58 stores the second judging threshold.
Memory 60 stores the duration unit data. Although all the duration unit data can be set the same, they can be set in correspondence with the subscriber characteristics. This is because pass-through cells sent from a subscriber in a burst need to be counted over a comparatively long period of time, whereas those sent from another in a more or less constant speed can be counted over a relatively short period of time.
Meanwhile, when the supervisor 45 commences its operation, selectors 63, 65 and 66 select their "a"
side inputs, so that the memories 56, 57 and 58 are accessed by using the VPIs/VCIs in the header part of cells as addresses. Selector 64 has memory 56 count the number of cells passing through by having an incrementer 70 increment the value by one ( 1 ) in an address region of memory 56 corresponding to the ~~.~....~..,...~... ~.~..,,~.._.. ....._ .._...~...~..d..~~,...m.q...~~.~...~.._..~_...,W..~ ~u..~.~....4.
~.~~.~..,~_~~......N._.~.~_.
20~~'~~4 VPIs/VCIs.
Selector 68 has memory 59 store duration unit data stored in memory 60, each time the value stored in memory 59 becomes zero (0). A decrementer 71 decrements the value stored in memory 59 by one (1).
When the value stored in memory 59 reaches zero (0), memory 56 clears its address regions corresponding to the VPIs/VCIs set in correspondence with the duration unit data. That is, memory 56 counts cells passing through in predetermined units in the address fields corresponding to their VPIs/VCIs. Then, memory 59 again stores duration unit data stored in memory 60, again.
A counter 72 generates respective addresses for managing duration units e.g. up to the maximum value of the VPIs/VCIs. Although this is not shown in the drawings, the counter 72 receives a clock signal, accesses memory 59, each time its own value is incre-mented by one (1), by using the incremented value as the address, and decrements the value stored in memory 59 by one (1). At this time, selector 67 selects its "b" side input and selector 68 selects its "c" side input.
A count cycle [from zero (0) to next zero (0)] in the counter 72 becomes the basis of the duration unit 18 2~3'~ ~
data stored in the memory 60. The values obtained by multiplying the count cycle by the duration unit data become duration units corresponding to the VPIs/VCIs.
When the value stored in memory 59 accessed by value of the counter 72 becomes zero (0), selector 68 switches its selection from "c" side input to "b"
side input, thereby loading the duration unit data in memory 60, again.
The counting by the counter 72 enables the ad-dresses corresponding to all the VPIs/VCIs to be specified, thereby realizing duration units to be managed.
Ordinarily, selectors 63, 65, and 66 select their "a" side inputs, access the corresponding address each time a cell passes through, and perform the following operations.
The count value of the cells passing through stored in memory 56 is supplied to the comparator 61 through the incrementer 70. The comparator 61 receives the first judging threshold stored in memory 57 and the second judging threshold stored in memory 58. When the number of cells passing through is less than the first and second thresholds, the compa-rator 61 does not control the selector 62 and cells passing through the buffer 55 also pass through selec-for 62 without any obstruction. Also, when the number of cells passing through is more than the first threshold but less than the second threshold, the excess cells over the first judging threshold are transmitted after selector 62 turns on the CLP bit in the header part of those cells. Finally, when the number of cells passing through is more than the second judging threshold, selector 62 converts the excess cells over the second judging threshold to empty cells, where all the bits are zero (0). The comparator 61 notifies the processor CC of the result of respective processings.
Because selector 62 supplies cells to the multi plexer for cell multiplexation, cells with the CLP
bit on are discarded when the buffer lacks the capac ity. Since cells from other subscribers are within their declared bands, even if a subscriber sends cells in excess of his declared band, ill-effects on other subscribers are minimized. When the numbers of cells from other subscribers are small, i.e. when the buffer has enough capacity, the multiplexer multiplexes even the cells with their CLP bit on.
Cells far exceeding the declared band are dis-Carded, e.g. through an empty cell conversion, to 20 ~~~3'~~4 avoid discarding of cells from other subscribers within their declared bands.
In the first and second embodiments of this invention, the supervisors 23, 33-1 through 33-m, and 45 output cells in which all the bits are zero (0) to 5 multiplexers 24, 34 and 49, where these cells are actually discarded. However, this invention is not limited to such a configuration.
Figure 8 illustrates the input interface of a multiplexer.
10 As shown in Figure 8, the multiplexers 24, 34 and 49 can use an input interface such that a "Data Line"
comprises sixteen (16) bits, a "Cell Frame" comprises one (1) bit, an "Enable" comprises one (1) bit and a "Parity" comprises one (1) bit. The "Data Line" is 15 a signal line for transmitting the cell width.
"Cell Frame" is a signal line specifying the head end of each cell by a pulse indicating a "Cell Slot".
"Enable" is a signal line specifying the cells' effectiveness. "Parity" is a data error scanning 20 line.
When the numbers of cells are more than the second threshold, the supervisors 23, 33-1 through 33-m and 45 turn off "Enable" without performing any data control. The multiplexers 23, 34 and 49 discard cells without multiplexing them when their "Enable" is off.
This invention is not limited to those embodi-ments, but instead can be applied in various deriva-tive forms. For instance, it goes without saying that counting of the number of cells passing through by memory 56 can be substituted by counting by an ordinary counter.
Further, this invention can be applied also to any cell switching system, in addition to an ATM cell switching system.
As explained earlier, this invention causes an ATM switching system to have its cell counter 21 in its supervisor 23 to count the cells inputted from respective subscribers. When the judge 22 discov-ers that the number of cells inputted from a particu-lar subscriber exceeds his declared band, the judge 22 attaches a sign to the excess cells to be sent to the multiplexer 24 e.g. by turning on their CLP bit.
When its buffer has enough capacity, the multiplexer 24 ordinarily multiplexes the cells. However, when its buffer lacks it, the multiplexer 24 prioritizes the discarding of these cells. Thus, even if its buffer lacks enough capacity, the multiplexer 24 prioritizes the multiplexation of cells from other 22 20~37~4 subscribers, as long as such cells are within their declared bands. Hence, this invention produces a distinct advantage of eliminating a possible ill-effect on others when a particular subscriber sends his cells beyond his declared band, while maintaining the best communications quality by avoiding unneces-sary cell discarding.
Alternatively, this invention can be structured such that first and second judging thresholds are used for an even finer cell discarding control.
That is, a sign is attached to excess cells over the first judging threshold e.g. by turning on the CLP
bit, and excess cells over the second judging thresh-old are converted to empty cells and discarded. As a result, cells exceeding a declared band by a narrow margin can be multiplexed ordinarily depending on the availability of buffering capacity, while cells exceeding a declared band by a wide band are discard-ed to minimize the ill-effect on other subscribers.
Thus, this invention is effective in reduction of discarding cells within declared bands and in pre-venting a deterioration in communications quality by supervising cells flowing in an ATM cell switching system.
In accordance with the present invention there is provided a supervision control method for an asynchronous transmission mode cell switching system comprising the steps of: (a) storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored in memory regions at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; (b) counting cells having one of the plurality of identified virtual connections formed by a particular virtual channel identifier and a particular virtual path identifier transmitted from a subscriber in a predetermined duration unit, by incrementing a count value stored in one of the memory regions having an address uniquely accessed with said particular virtual channel identifier and said particular virtual path identifier; (c) attaching a sign to the cells when the count value incremented in said step (b) exceeds a predetermined value; and (d) discarding the cells to which said sign is attached when a buffer does not have enough capacity to multiplex the cells.
In accordance with the present invention there is also provided a supervision control method for an asynchronous transmission mode cell switching system comprising the steps of: (a) counting cells having a particular virtual channel 6a identifier and a particular virtual path identifier received from a subscriber in a predetermined unit by incrementing a count value stored in a memory region having an address uniquely accessed with said particularly virtual path identifier; (b) attaching a sign to the cells when the count value incremented in said step (a) exceeds a first predetermined value; (c) discarding the excess cells over a second predetermined value when the count value incremented in said step (a) exceeds the second predetermined value; and (d) discarding the excess cells over the first predetermined value, to which the sign is attached in said step (b), when a buffer does not have enough capacity to multiplex the cells.
In accordance with the present invention there is further provided a supervision control apparatus for an asynchronous transmission mode cell switching system comprising: a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, the bandwidth data being stored at address thereof, each address being operatively accessed based on one of a plurality of identified virtual connections; a cell counter including a memory to store a count value at an address uniquely accessed with one of the plurality of identified virtual connections formed by a particular virtual channel identifier and a particular virtual path identifier, for counting cells having said particular virtual channel identifier and said particular virtual path identifier transmitted from a subscriber in a predetermined duration unit by incrementing the count value; a judge circuit for attaching a sign to the cells when the count value incremented by said cell counter exceeds a predetermined value; and a multiplexer for discarding the cells to which the sigh is attached when a buffer does not have enough capacity to multiplex the cells.
In accordance with the present invention there is also provided a supervision control apparatus for a cell 6b switching system comprising: a cell counter including a memory to store a count value at an address uniquely accessed with a particular virtual channel identifier and a particular virtual path identifier, for counting cells having said particular virtual channel identifier and said particular virtual path identifier transmitted from a subscriber in a predetermined duration unit; a judge circuit for attaching a sign to the cells when the count value incremented by said cell counter exceeds a first predetermined value; a selector for discarding the excess cells over a second predetermined value when the count value incremented by said cell counter exceeds the second predetermined value; and a multiplexer for discarding the excess cells over the first predetermined value, to which said sign is attached by said judge circuit, when a buffer does not have enough capacity to multiplex the cells.
In accordance with the present invention there is further provided a supervision control method in which cells, each including a header field with an identified virtual connection, are received from a plurality of sources, comprising: storing a plurality of bandwidth data which are pre-assigned to the sources of the cells and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; monitoring a transmission rate on the identified virtual connection of a received cell; comparing the transmission rate with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and marking the received cell to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a supervision control apparatus in which 6c cells, each including a header field with an identified virtual connection, are received from a plurality of sources, comprising: a memory to store a plurality of bandwidth data which are pre-assigned to the sources of the cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections; a cell counter to monitor a transmission rate on the identified virtual connection of a received cell; a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a supervision control apparatus, comprising: a receiver to receive a cell including a header field with an identified virtual connection; a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections; a cell counter to monitor a transmission rate on the identified virtual connection of a received cell; a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a supervision control method, comprising:
6d receiving a cell including a header field with an identified virtual connection; storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; monitoring a transmission rate on the identified virtual connection of a received cell; comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the received cell to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a supervision control method in which cells, each including a header field with an identified virtual connection and a bit indicating a cell loss priority, are received, comprising: storing a plurality of bandwidth data which are pre-assigned to sources of the cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; monitoring a transmission rate on the identified virtual connection of a received cell; comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the bit to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
In accordance with the present invention there is further provided a switching system which receives a cell including a header field with an identified virtual connection, comprising: a supervisor, including; a memory to store a 6e plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; a cell counter to monitor a transmission rate on the identified virtual connection specified by a received cell; a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to the identified virtual connection.
In accordance with the present invention there is further provided a supervision control method in which a cell having a header field with an identified virtual connection, is received from a source, comprising: storing a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; and marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the stored bandwidth data for the received cell.
In accordance with the present invention there is further provided a supervision control apparatus in which a cell having a header field with an identified virtual connection, is received from a source, comprising a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual 6f connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at an address of the memory corresponding to the identified virtual connection of the received cell.
In accordance with the present invention there is further provided a switching system which receives a cell including a header field with an identified virtual connection, comprising: a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at the address of the memory corresponding to the identified virtual connection of the received cell; and a switch to direct the cell from said supervisor to the identified virtual connection.
In accordance with the present invention there is further provided a switching system located along an identified virtual connection, comprising: an interface to receive a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority; a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the bit to indicate a higher cell loss priority when the monitored transmission rate corresponding to the bandwidth data stored at an address of the memory corresponding to the identified virtual connection in the header field of the received cell; and a switch, to direct 6g the cell from said supervisor to an output of the identified virtual connection.
Brief Description of the Drawinas Figure 1 is a block diagram of an ATM switching system;
Figure 2 shows a cell configuration;
Figure 3 is a block diagram of one (1) of the broadband remote switching units (BRSU) 7;
Figure 4 is a block diagram of this invention;
Figure 5A is a block diagram of parts pertinent to a first embodiment of this invention;
Figure 5B illustrates an example of cell discarding;
Figure 6 is a block diagram of a subscriber line 20 i3~~~4 trunk pertinent to a second embodiment of this inven-tion;
Figure 7 is a block diagram of the supervisor and the selection control processor pertinent to the second embodiment of this invention; and Figure 8 illustrates the input interface of a multiplexer.
Description of the Preferred Embodiments A supervision control system of this invention prioritizes discarding of cells overflowing from a buffer by attaching a high cell-loss-priority sign to cells flowing in over a band declared by a subscrib-er, thereby minimizing ill-effects to other subscrib-ers.
Figure 4 is a block diagram of this invention, The supervision control apparatus for an ATM
(Asynchronous Transmission Mode) cell switching system comprises a supervisor 23 and a multiplexer 24. A supervisor 23 further comprises a cell counter 21 and a judge 22. The cell counter 21 counts cells transmitted from a subscriber in a predetermined duration unit. The judge 22 attaches a sign to the cells when the value counted by the ... "...........,...~..».,...»...»...a...w....~....~."~.~..,.... ..
.......".""".~;.'"",~~,~".~.w~.~"
2~~3~~~
cell counter 21 exceeds a predetermined value. The multiplexer 24 discards the cells to which the sign is attached when a buffer does not have enough capac-ity during a cell multiplexation.
That is, the cell counter 21 in the supervisor 23 counts cells flowing in from a subscriber in a prede-termined duration unit. The judge 22 in the super-visor 23 judges whether or not the cells are flowing in over the band declared by the subscriber and attaches a sign to a predetermined bit in the excess cells flowing in over the declared band. The multiplexer 24 multiplexes the cells having the sign for their transmission when its buffer has the capac-ity to handle them. However, the multiplexer 24 discards them with high priority, when neither the buffer in the multiplexer 24 itself nor the buffer in a concentrator switch, or in a demultiplexer, con-nected to the multiplexer 24 has a capacity to handle the cells, thereby ensuring the multiplexation and transmission of cells having no such sign input-ted from other subscribers.
Alternatively, the judge 22 in the supervisor 23 can set a first judging threshold and a second judg-ing threshold. The first judging threshold corre-sponds to a band declared by a subscriber. The 2t~~~'~ ~~
second judging threshold is set higher than the first judging threshold. The judge 22 attaches a sign to the inflowing cells from a subscriber in excess of the first judging threshold, and discards the i nflowing cells from the subscriber in excess of the second judging threshold.
That is, the judge 22 sets the first and second judging thresholds in correspondence with a band declared by a subscriber. The judge 22 attaches a sign to the excess inflowing cells over the first judging threshold by appropriately marking the CLP
(cell loss priority) bit or the RES (reserve) bit of the cell, thereby prioritizing the discarding of such cells, when neither the buffer in the multiplexer 24 itself nor the buffer in a concentrator switch, or in a demultiplexer, connected to the multiplexer 24 has a capacity to handle the cells. The judge 22 always discards the inflowing cells in excess of the second judging threshold, because they are likely to cause an overflow in the buffer.
Embodiments of this invention are explained in further detail by referring to some of the attached drawings.
First Embodiment 20~3'~~4 Figure 5A is a block diagram of parts pertinent to a first embodiment of this invention.
Subscriber line terminators 31-1 through 31-m each paired with the corresponding one of interfacers 5 32-1 through 32-m are equivalent to subscriber line trunks connecting subscribers to the ATM cell switch-ing system. A multiplexer 34 receives cells from subscribers by way of the subscriber line terminators 31-1 through 31-m and the interfacers 32-1 through 10 32-m. Supervisors 33-1 through 33-m respectively supervise cell inflows to the multiplexer 34 via the subscriber line terminators 31-1 through 31-m and the interfacers 32-1 through 32-m.
When a subscriber calls up, he declares the band to be occupied. A processor 37 reads from a cell its VCI (virtual channel identifier) for specifying the switchers and the subscriber and its VPI (virtual path identifier? for specifying the paths among the switchers, and notifies the supervisors 33-1 through 33-m of the VCI/VPI and the maximum number of cells, set in correspondence with the subscriber declared band, passing through in a predetermined duration unit.
The supervisors 33-1 through 33-m count the number of cells having particular VCIs/VPIs in the 2~53~~~
predetermined duration units, and attach a sign to the cells in excess of the maximum number of cells, set in correspondence with the subscriber declared band, passing through in a predetermined duration unit, for example, by marking the CLP (cell loss priority) bit in those cells.
Figure 5B illustrates an example of cell discard-ing.
Alternatively, the supervisors 33-1 through 33-m can attach a sign to the cells in excess of the maximum number of cells, set in correspondence with the subscriber declared band, passing through in a predetermined duration unit, by marking the RES
(reserve) bit in those cells, as shown in Figure 5B.
The multiplexer 34 has a buffer. It multiplexes cells from subscribers and supplies the multiplexed cells to a concentrator switch 35. However, it multiplexes cells having the sign marked in their CLP
bit or in their RES bit only when the buffer has enough capacity, and discards them with high priority when the buffer does not have enough capacity.
This ensures the multiplexation of cells from sub-scribers transmitted within the declared bands.
Also, even when the buffer in the multiplexer 34 has enough capacity to handle the cells, the buffer at an input terminal or at an output terminal of a device connected in a later stage, such as the con-centrator switch 35 and a demultiplexer on the re-ceiving side, discards the cells, if it does not have enough capacity.
Also, the supervisors 33-1 through 33-m can attach a sign to the cells in excess of a first judging threshold equivalent to the maximum number of cells, set in correspondence with the subscriber declared band, passing through in a predetermined duration unit, by marking either the CLP bit or the RES bit in those cells. The multiplexer 34 priori-tizes the discarding of those cells having the sign, when its buffer lacks enough capacity. Other devices connected in later stages discard cells similarly, when their respective buffers lack enough capacity. When the number of cells passing through in a predetermined duration unit further increases and reaches a second judging threshold, the multi-plexer 34 can be made to perform a control such that the excess cells over the second judging threshold are discarded regardless of the available capacity of the buffer in the multiplexer 34. The local proc-essor interface 36 notifies the local processor 37 of the results of processing by the supervisors 33-1 ~....-~~.._.:. ._... .. . _~~-.~.- '.~w..~.;,~..~.~,.
,.m:~~:~~:...~.:..~~,~...~. _ .._._.._ . _.~. ..r.:.~..-.....J..._ ~.__._n__...~ _~ .-_. .._...
through 33-m.
Second Embodiment Figure 6 is a block diagram of a subscriber line trunk pertinent to a second embodiment of this inven-tion.
A subscriber line 41 such as a SOVIET based opti-cal transmission path transmits cells in light sig-nals. A light-electricity (electro-optic/opto-electric) converter (EO/OE) 42 converts the cells in light signals to cells in electric signals and sup-plies the converted cells through a terminator 43 and an interfacer 44 to a selection control processor 46.
A local processor 52 notifies a supervisor 45 through a local processor interface 51 of a VCI/VPI and first and second judging thresholds set correspondingly to a subscriber declared band. An alternative ar-rangement can be made such that the processor noti-fies the supervisor 45 of a subscriber declared band and the supervisor 45 sets first and second judging thresholds accordingly.
The supervisor 45 counts the number of cells having a particular VCI/VPI passing through the interfacer 44 in a predetermined duration unit for a comparison with the first and second judging thresh-14 2Q~3'~3~
olds. The supervisor 45 has the selection control processor 46 turn on e.g. the CLP bit in the header part of the cells exceeding the first judging thresh-old, so that discarding of those cells is prioritized when the buffer of a multiplexer 49, or the buffer of a device connected in a later stage, lacks enough capacity. Also, the supervisor 45 has the selec-tion control processor 46 turn on e.g. the RES bit in the header part of the cells exceeding the second judging threshold, so that those cells are supplied to the multiplexer 49 as empty cells, thereby causing those cells to be discarded anyway regardless of the available capacity in the buffer of the multiplexer 49. This is because the multiplexer 49 does not send empty cells to a concentrator switch 50.
Figure 7 is a block diagram of the supervisor 45 and the selection control processor 46 pertinent to the second embodiment of this invention.
A buffer 55 delays cells in correspondence with the delays caused by respective supervisions.
A memory 56 counts the number of cells passing through in a predetermined duration unit.
Memories 57 and 58 respectively store first and second judging thresholds.
A memory 59 measures an elapse of the predeter-15 2~~3'~~4 mined duration unit.
A memory 60 stores duration unit data.
When the supervisor 45 commences its operations, a processor CC instructs selectors 65, 66 and 69 to select their "b" side inputs and to output them to respective address terminals of memories 57, 58 and 60, which receive data from the processor CC as respective data inputs. The processor CC supplies to "b" side inputs of selectors 65, 66 and 69 an address by which memories 57, 58 and 60 are accessed.
The processor CC accesses memories 57, 58 and 60 to have them respectively store the first judging threshold, the second judging threshold and the duration unit data.
When the supervisor 45 commences its operations, the processor CC also instructs selectors 67 and 68 to select their "a" side inputs and to output, so that memory 59 receives an address and data from the processor CC. Memory 59 stores as its initial data duration unit data similar to those stored in memory 60. The processor stores data to be stored in memories 57, 58, 59 and 60 at respective addresses corresponding to VPIs/VCIs.
When the supervisor 45 commences its operations, memory 60 is reset and its stored data are initial-ized to zero (0).
That~is, the processor CC supplies the first and second judging thresholds set correspondingly to the subscriber declared band, the duration unit data indicating the supervision cycle and the addresses corresponding to the subscriber assigned VPIs/VCIs.
Memory 57 stores the first judging threshold.
Memory 58 stores the second judging threshold.
Memory 60 stores the duration unit data. Although all the duration unit data can be set the same, they can be set in correspondence with the subscriber characteristics. This is because pass-through cells sent from a subscriber in a burst need to be counted over a comparatively long period of time, whereas those sent from another in a more or less constant speed can be counted over a relatively short period of time.
Meanwhile, when the supervisor 45 commences its operation, selectors 63, 65 and 66 select their "a"
side inputs, so that the memories 56, 57 and 58 are accessed by using the VPIs/VCIs in the header part of cells as addresses. Selector 64 has memory 56 count the number of cells passing through by having an incrementer 70 increment the value by one ( 1 ) in an address region of memory 56 corresponding to the ~~.~....~..,...~... ~.~..,,~.._.. ....._ .._...~...~..d..~~,...m.q...~~.~...~.._..~_...,W..~ ~u..~.~....4.
~.~~.~..,~_~~......N._.~.~_.
20~~'~~4 VPIs/VCIs.
Selector 68 has memory 59 store duration unit data stored in memory 60, each time the value stored in memory 59 becomes zero (0). A decrementer 71 decrements the value stored in memory 59 by one (1).
When the value stored in memory 59 reaches zero (0), memory 56 clears its address regions corresponding to the VPIs/VCIs set in correspondence with the duration unit data. That is, memory 56 counts cells passing through in predetermined units in the address fields corresponding to their VPIs/VCIs. Then, memory 59 again stores duration unit data stored in memory 60, again.
A counter 72 generates respective addresses for managing duration units e.g. up to the maximum value of the VPIs/VCIs. Although this is not shown in the drawings, the counter 72 receives a clock signal, accesses memory 59, each time its own value is incre-mented by one (1), by using the incremented value as the address, and decrements the value stored in memory 59 by one (1). At this time, selector 67 selects its "b" side input and selector 68 selects its "c" side input.
A count cycle [from zero (0) to next zero (0)] in the counter 72 becomes the basis of the duration unit 18 2~3'~ ~
data stored in the memory 60. The values obtained by multiplying the count cycle by the duration unit data become duration units corresponding to the VPIs/VCIs.
When the value stored in memory 59 accessed by value of the counter 72 becomes zero (0), selector 68 switches its selection from "c" side input to "b"
side input, thereby loading the duration unit data in memory 60, again.
The counting by the counter 72 enables the ad-dresses corresponding to all the VPIs/VCIs to be specified, thereby realizing duration units to be managed.
Ordinarily, selectors 63, 65, and 66 select their "a" side inputs, access the corresponding address each time a cell passes through, and perform the following operations.
The count value of the cells passing through stored in memory 56 is supplied to the comparator 61 through the incrementer 70. The comparator 61 receives the first judging threshold stored in memory 57 and the second judging threshold stored in memory 58. When the number of cells passing through is less than the first and second thresholds, the compa-rator 61 does not control the selector 62 and cells passing through the buffer 55 also pass through selec-for 62 without any obstruction. Also, when the number of cells passing through is more than the first threshold but less than the second threshold, the excess cells over the first judging threshold are transmitted after selector 62 turns on the CLP bit in the header part of those cells. Finally, when the number of cells passing through is more than the second judging threshold, selector 62 converts the excess cells over the second judging threshold to empty cells, where all the bits are zero (0). The comparator 61 notifies the processor CC of the result of respective processings.
Because selector 62 supplies cells to the multi plexer for cell multiplexation, cells with the CLP
bit on are discarded when the buffer lacks the capac ity. Since cells from other subscribers are within their declared bands, even if a subscriber sends cells in excess of his declared band, ill-effects on other subscribers are minimized. When the numbers of cells from other subscribers are small, i.e. when the buffer has enough capacity, the multiplexer multiplexes even the cells with their CLP bit on.
Cells far exceeding the declared band are dis-Carded, e.g. through an empty cell conversion, to 20 ~~~3'~~4 avoid discarding of cells from other subscribers within their declared bands.
In the first and second embodiments of this invention, the supervisors 23, 33-1 through 33-m, and 45 output cells in which all the bits are zero (0) to 5 multiplexers 24, 34 and 49, where these cells are actually discarded. However, this invention is not limited to such a configuration.
Figure 8 illustrates the input interface of a multiplexer.
10 As shown in Figure 8, the multiplexers 24, 34 and 49 can use an input interface such that a "Data Line"
comprises sixteen (16) bits, a "Cell Frame" comprises one (1) bit, an "Enable" comprises one (1) bit and a "Parity" comprises one (1) bit. The "Data Line" is 15 a signal line for transmitting the cell width.
"Cell Frame" is a signal line specifying the head end of each cell by a pulse indicating a "Cell Slot".
"Enable" is a signal line specifying the cells' effectiveness. "Parity" is a data error scanning 20 line.
When the numbers of cells are more than the second threshold, the supervisors 23, 33-1 through 33-m and 45 turn off "Enable" without performing any data control. The multiplexers 23, 34 and 49 discard cells without multiplexing them when their "Enable" is off.
This invention is not limited to those embodi-ments, but instead can be applied in various deriva-tive forms. For instance, it goes without saying that counting of the number of cells passing through by memory 56 can be substituted by counting by an ordinary counter.
Further, this invention can be applied also to any cell switching system, in addition to an ATM cell switching system.
As explained earlier, this invention causes an ATM switching system to have its cell counter 21 in its supervisor 23 to count the cells inputted from respective subscribers. When the judge 22 discov-ers that the number of cells inputted from a particu-lar subscriber exceeds his declared band, the judge 22 attaches a sign to the excess cells to be sent to the multiplexer 24 e.g. by turning on their CLP bit.
When its buffer has enough capacity, the multiplexer 24 ordinarily multiplexes the cells. However, when its buffer lacks it, the multiplexer 24 prioritizes the discarding of these cells. Thus, even if its buffer lacks enough capacity, the multiplexer 24 prioritizes the multiplexation of cells from other 22 20~37~4 subscribers, as long as such cells are within their declared bands. Hence, this invention produces a distinct advantage of eliminating a possible ill-effect on others when a particular subscriber sends his cells beyond his declared band, while maintaining the best communications quality by avoiding unneces-sary cell discarding.
Alternatively, this invention can be structured such that first and second judging thresholds are used for an even finer cell discarding control.
That is, a sign is attached to excess cells over the first judging threshold e.g. by turning on the CLP
bit, and excess cells over the second judging thresh-old are converted to empty cells and discarded. As a result, cells exceeding a declared band by a narrow margin can be multiplexed ordinarily depending on the availability of buffering capacity, while cells exceeding a declared band by a wide band are discard-ed to minimize the ill-effect on other subscribers.
Thus, this invention is effective in reduction of discarding cells within declared bands and in pre-venting a deterioration in communications quality by supervising cells flowing in an ATM cell switching system.
Claims (98)
1. A supervision control method for an asynchronous transmission mode cell switching system comprising the steps of:
(a) storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored in memory regions at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
(b) counting cells having one of the plurality of identified virtual connections formed by a particular virtual channel identifier and a particular virtual path identifier transmitted from a subscriber in a predetermined duration unit, by incrementing a count value stored in one of the memory regions having an address uniquely accessed with said particular virtual channel identifier and said particular virtual path identifier;
(c) attaching a sign to the cells when the count value incremented in said step (b) exceeds a predetermined value; and (d) discarding the cells to which said sign is attached when a buffer does not have enough capacity to multiplex the cells.
(a) storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored in memory regions at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
(b) counting cells having one of the plurality of identified virtual connections formed by a particular virtual channel identifier and a particular virtual path identifier transmitted from a subscriber in a predetermined duration unit, by incrementing a count value stored in one of the memory regions having an address uniquely accessed with said particular virtual channel identifier and said particular virtual path identifier;
(c) attaching a sign to the cells when the count value incremented in said step (b) exceeds a predetermined value; and (d) discarding the cells to which said sign is attached when a buffer does not have enough capacity to multiplex the cells.
2. A supervision control method for an asynchronous transmission mode cell switching system comprising the steps of:
(a) counting cells having a particular virtual channel identifier and a particular virtual path identifier received from a subscriber in a predetermined unit by incrementing a count value stored in a memory region having an address uniquely accessed with said particularly virtual path identifier;
(b) attaching a sign to the cells when the count value incremented in said step (a) exceeds a first predetermined value;
(c) discarding the excess cells over a second predetermined value when the count value incremented in said step (a) exceeds the second predetermined value; and (d) discarding the excess cells over the first predetermined value, to which the sign is attached in said step (b), when a buffer does not have enough capacity to multiplex the cells.
(a) counting cells having a particular virtual channel identifier and a particular virtual path identifier received from a subscriber in a predetermined unit by incrementing a count value stored in a memory region having an address uniquely accessed with said particularly virtual path identifier;
(b) attaching a sign to the cells when the count value incremented in said step (a) exceeds a first predetermined value;
(c) discarding the excess cells over a second predetermined value when the count value incremented in said step (a) exceeds the second predetermined value; and (d) discarding the excess cells over the first predetermined value, to which the sign is attached in said step (b), when a buffer does not have enough capacity to multiplex the cells.
3. The supervision control method according to claim 2, wherein said step (b) attaches based on the first predetermined value as a number of peak cells in the predetermined duration unit; and wherein said step (a) comprises the substep of designating the first and second predetermined values based on a designation received from the subscriber.
4. A supervision control apparatus for an asynchronous transmission mode cell switching system comprising:
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, the bandwidth data being stored at address thereof, each address being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter including a memory to store a count value at an address uniquely accessed with one of the plurality of identified virtual connections formed by a particular virtual channel identifier and a particular virtual path identifier, for counting cells having said particular virtual channel identifier and said particular virtual path identifier transmitted from a subscriber in a predetermined duration unit by incrementing the count value;
a judge circuit for attaching a sign to the cells when the count value incremented by said cell counter exceeds a predetermined value; and a multiplexer for discarding the cells to which the sigh is attached when a buffer does not have enough capacity to multiplex the cells.
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, the bandwidth data being stored at address thereof, each address being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter including a memory to store a count value at an address uniquely accessed with one of the plurality of identified virtual connections formed by a particular virtual channel identifier and a particular virtual path identifier, for counting cells having said particular virtual channel identifier and said particular virtual path identifier transmitted from a subscriber in a predetermined duration unit by incrementing the count value;
a judge circuit for attaching a sign to the cells when the count value incremented by said cell counter exceeds a predetermined value; and a multiplexer for discarding the cells to which the sigh is attached when a buffer does not have enough capacity to multiplex the cells.
5. The supervision control apparatus according to claim 4, wherein said judge circuit comprises a selector to switch when said sign is attached to a cell.
6. A supervision control apparatus for a cell switching system comprising:
a cell counter including a memory to store a count value at an address uniquely accessed with a particular virtual channel identifier and a particular virtual path identifier, for counting cells having said particular virtual channel identifier and said particular virtual path identifier transmitted from a subscriber in a predetermined duration unit;
a judge circuit for attaching a sign to the cells when the count value incremented by said cell counter exceeds a first predetermined value;
a selector for discarding the excess cells over a second predetermined value when the count value incremented by said cell counter exceeds the second predetermined value; and a multiplexer for discarding the excess cells over the first predetermined value, to which said sign is attached by said judge circuit, when a buffer does not have enough capacity to multiplex the cells.
a cell counter including a memory to store a count value at an address uniquely accessed with a particular virtual channel identifier and a particular virtual path identifier, for counting cells having said particular virtual channel identifier and said particular virtual path identifier transmitted from a subscriber in a predetermined duration unit;
a judge circuit for attaching a sign to the cells when the count value incremented by said cell counter exceeds a first predetermined value;
a selector for discarding the excess cells over a second predetermined value when the count value incremented by said cell counter exceeds the second predetermined value; and a multiplexer for discarding the excess cells over the first predetermined value, to which said sign is attached by said judge circuit, when a buffer does not have enough capacity to multiplex the cells.
7. The supervision control apparatus according to claim 6, wherein said first predetermined value is a number of average cells in said predetermined duration unit and said second predetermined value is a number of peak cells in said predetermined duration unit; and wherein said system further comprises a receiver for receiving a designation from the subscriber to designate the first and second predetermined values.
8. The supervision control apparatus for an asynchronous transmission mode cell switching system according to claim 6, wherein said selector outputs "0" upon discarding the cells.
9. A supervision control method in which cells, each including a header field with an identified virtual connection, are received from a plurality of sources, comprising:
storing a plurality of bandwidth data which are pre-assigned to the sources of the cells and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
monitoring a transmission rate on the identified virtual connection of a received cell;
comparing the transmission rate with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and marking the received cell to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
storing a plurality of bandwidth data which are pre-assigned to the sources of the cells and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
monitoring a transmission rate on the identified virtual connection of a received cell;
comparing the transmission rate with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and marking the received cell to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
10. A supervision control method according to claim 9, wherein said monitoring comprises counting a number of the received cells having the same identified virtual connection in a predetermined duration unit.
11. A supervision control method, according to claim 9, further comprising discarding the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity for buffering the received cell.
12. A supervision control apparatus in which cells, each including a header field with an identified virtual connection, are received from a plurality of sources, comprising:
a memory to store a plurality of bandwidth data which are pre-assigned to the sources of the cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
a memory to store a plurality of bandwidth data which are pre-assigned to the sources of the cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
13. A supervision control apparatus according to claim 12, wherein said cell counter counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
14. A supervision control apparatus according to claim 12, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
15. A supervision control apparatus in which cells, each including a header field with an identified virtual connection, are received from a plurality of sources, comprising:
memory means for storing a plurality of bandwidth data which are pre-assigned to the sources of the cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
monitor means for monitoring a transmission rate on the identified virtual connection of a received cell;
comparing means for comparing the monitored transmission rate of said monitor means with the bandwidth data stored at an address of said memory means corresponding to the identified virtual connection of the received cell; and mark means for marking the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
memory means for storing a plurality of bandwidth data which are pre-assigned to the sources of the cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
monitor means for monitoring a transmission rate on the identified virtual connection of a received cell;
comparing means for comparing the monitored transmission rate of said monitor means with the bandwidth data stored at an address of said memory means corresponding to the identified virtual connection of the received cell; and mark means for marking the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
16. A supervision control apparatus according to claim 15, wherein said monitor means counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
17. ~A supervision control apparatus according to claim 15, further comprising discard means for discarding the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity for buffering the received cell.
18. ~A supervision control apparatus, comprising:
a buffer memory to received and store a cell including a header field with an identified virtual connection;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
a buffer memory to received and store a cell including a header field with an identified virtual connection;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
19. ~A supervision control apparatus according to claim 18, wherein said cell counter counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
20. ~A supervision control apparatus according to claim 18, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when said buffer memory has less capacity than an operative capacity to store the received cell.
21. ~A supervision control apparatus, comprising:
a receiver to receive a cell including a header field with an identified virtual connection;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
a receiver to receive a cell including a header field with an identified virtual connection;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
22. ~A supervision control apparatus according to claim 21, wherein said cell counter counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
23. ~A supervision control apparatus according to claim 21, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
24. ~A supervision control apparatus, comprising:
a receiver to receive a cell including a header field with an identified virtual connection and a cell loss priority bit indicating a cell loss priority;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the cell loss priority bit to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
a receiver to receive a cell including a header field with an identified virtual connection and a cell loss priority bit indicating a cell loss priority;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the cell loss priority bit to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
25. ~A supervision control apparatus according to claim 24, wherein said cell counter counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
26. ~A supervision control apparatus according to claim 24, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
27. ~A supervision control apparatus in which a cell including a header field with an identified virtual connection and a cell loss priority bit indicating a cell loss priority, is received from a source, comprising:
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of the received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the cell loss priority bit to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of the received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at an address of said memory corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the cell loss priority bit to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
28. ~A supervision control apparatus according to claim 27, wherein said cell counter counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
29. ~A supervision control apparatus according to claim 27, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
30. ~A supervision control method, comprising:
receiving a cell including a header field with an identified virtual connection;
storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
monitoring a transmission rate on the identified virtual connection of a received cell;
comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the received cell to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
receiving a cell including a header field with an identified virtual connection;
storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
monitoring a transmission rate on the identified virtual connection of a received cell;
comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the received cell to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
31. ~A supervision control method according to claim 30, wherein said monitoring step comprises counting a number of the received cells having the same identified virtual connection in a predetermined duration unit.
32. ~A supervision control method according to claim 30, further comprising discarding the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity for buffering the received cell.
33. ~A supervision control method, comprising:
receiving a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority;
storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored at
receiving a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority;
storing a plurality of bandwidth data which are pre-assigned to a plurality of sources of cells, and are stored at
34 memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
monitoring a transmission rate on the identified virtual connection of a received cell;
comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the bit to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
34. A supervision control method according to claim 33, wherein said monitoring step comprises counting a number of the received cells having the same identified virtual connection in a predetermined duration unit.
monitoring a transmission rate on the identified virtual connection of a received cell;
comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the bit to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
34. A supervision control method according to claim 33, wherein said monitoring step comprises counting a number of the received cells having the same identified virtual connection in a predetermined duration unit.
35. A supervision control method according to claim 33, further comprising discarding the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity for buffering the received cell.
36. A supervision control method in which cells, each including a header field with an identified virtual connection and a bit indicating a cell loss priority, are received, comprising:
storing a plurality of bandwidth data which are pre-assigned to sources of the cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
monitoring a transmission rate on the identified virtual connection of a received cell;
comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the bit to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
storing a plurality of bandwidth data which are pre-assigned to sources of the cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
monitoring a transmission rate on the identified virtual connection of a received cell;
comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the identified virtual connection of the received cell; and marking the bit to indicate a higher cell loss priority when the monitored transmission rate of the received cell exceeds a rate corresponding to the bandwidth data.
37. ~A supervision control method according to claim 36, wherein said monitoring comprises counting a number of the received cells having the same identified virtual connection in a predetermined duration unit.
38. ~A supervision control method according to claim 36, further comprising discarding the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity for buffering the received cell.
39. ~A switching system which receives a cell including a header field with an identified virtual connection, comprising:
a supervisor, including;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection specified by a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to the identified virtual connection.
a supervisor, including;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection specified by a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to the identified virtual connection.
40. ~A switching system according to claim 39, wherein said cell counter counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
41. ~A switching system according to claim 39, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a puffer has less capacity than an operative capacity to store she received cell.
42. ~A switching system which receives a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority comprising:
a supervisor, including:
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the bit to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to the identified virtual connection.
a supervisor, including:
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the bit to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to the identified virtual connection.
43. ~A switching system according to claim 42, wherein said cell counter counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
44. ~A switching system according to claim 42, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
45. ~A switching system, comprising:
an interface to receive a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority;
a supervisor, including;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the bit to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to an output of the identified virtual connection.
an interface to receive a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority;
a supervisor, including;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the bit to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to an output of the identified virtual connection.
46. ~A switching system according to claim 45, wherein said cell counter counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
47. ~A switching system according to claim 45, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
48. ~A switching system, comprising:
an interface to receive a cell including a header field with an identified virtual connection:
a supervisor, including;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to an output of the identified virtual connection.
an interface to receive a cell including a header field with an identified virtual connection:
a supervisor, including;
a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections;
a cell counter to monitor a transmission rate on the identified virtual connection of a received cell;
a comparator to compare the monitored transmission rate of said cell counter with the bandwidth data stored at a memory address corresponding to the identified virtual connection of the received cell; and a judge circuit to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data; and a switch to direct the cell from said supervisor to an output of the identified virtual connection.
49. ~A switching system according to claim 48, wherein said cell counter counts a number of the received cells having the same identified virtual connection in a predetermined duration unit.
50. ~A switching system according to claim 48, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
51. ~A supervision control method in which a cell having a header field with an identified virtual connection, is received from a source, comprising:
storing a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; and marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the stored bandwidth data for the received cell.
storing a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at memory addresses, each of the memory addresses being operatively accessed based on one of a plurality of identified virtual connections; and marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the stored bandwidth data for the received cell.
52. ~A supervision control method according to claim 51, wherein said marking comprises counting the number of the received cells having the same identified virtual connection in a predetermined duration unit.
53. ~A supervision control method according to claim 51, further comprising discarding the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity for buffering the received cell.
54. ~A supervision control method according to claim 51, wherein said marking comprises:
monitoring a transmission rate on the identified virtual connection specified by a received cell; and comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the specified identified virtual connection.
monitoring a transmission rate on the identified virtual connection specified by a received cell; and comparing the transmission rate with the bandwidth data stored at the memory address corresponding to the specified identified virtual connection.
55. ~A supervision control apparatus in which a cell having a header field with an identified virtual connection, is received from a source, comprising a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at an address of the memory corresponding to the identified virtual connection of the received cell.
56. A supervision control apparatus according to claim 55, wherein said supervisor includes a cell counter to count a number of the received cells having the same identified virtual connection in a predetermined duration unit.
57. ~A supervision control apparatus according to claim 55, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
58. ~A supervision control apparatus according to claim 55, wherein said supervisor further includes:
a cell counter to monitor a transmission rate on the identified virtual connection specified by a received cell;
a comparator, coupled to said memory and said cell counter, to compare the monitored transmission rate of said cell counter with the bandwidth data stored in said memory at the address corresponding to the identified virtual connection in the header field of the received cell; and a judge circuit, coupled to said comparator, to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
a cell counter to monitor a transmission rate on the identified virtual connection specified by a received cell;
a comparator, coupled to said memory and said cell counter, to compare the monitored transmission rate of said cell counter with the bandwidth data stored in said memory at the address corresponding to the identified virtual connection in the header field of the received cell; and a judge circuit, coupled to said comparator, to mark the received cell to indicate a higher cell loss priority when the monitored transmission rate exceeds a rate corresponding to the bandwidth data.
59. ~A switching system which receives a cell including a header field with an identified virtual connection, comprising:
a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at the address of the memory corresponding to the identified virtual connection of the received cell; and a switch to direct the cell from said supervisor to the identified virtual connection.
a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at the address of the memory corresponding to the identified virtual connection of the received cell; and a switch to direct the cell from said supervisor to the identified virtual connection.
60. ~A switching system according to claim 59, wherein said supervisor includes a cell counter to count a number of received cells having the same identified virtual connection in a predetermined duration unit.
61. ~A switching system according to claim 59, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
62. ~A switching system which receives a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority, comprising:
a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at the address of the memory corresponding to the identified virtual connection of the received cell; and a switch to direct the cell from said supervisor to the identified virtual connection.
a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at the address of the memory corresponding to the identified virtual connection of the received cell; and a switch to direct the cell from said supervisor to the identified virtual connection.
63. ~A switching system according to claim 62, wherein said supervisor includes a cell counter to count a number of the received cells having the same identified virtual connection in a predetermined duration unit.
64. ~A switching system according to claim 62, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
65. ~A switching system located along an identified virtual connection, comprising:
an interface to receive a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority;
a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the bit to indicate a higher cell loss priority when the monitored transmission rate corresponding to the bandwidth data stored at an address of the memory corresponding to the identified virtual connection in the header field of the received cell;
and a switch, to direct the cell from said supervisor to an output of the identified virtual connection.
an interface to receive a cell including a header field with an identified virtual connection and a bit indicating a cell loss priority;
a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the bit to indicate a higher cell loss priority when the monitored transmission rate corresponding to the bandwidth data stored at an address of the memory corresponding to the identified virtual connection in the header field of the received cell;
and a switch, to direct the cell from said supervisor to an output of the identified virtual connection.
66. ~A switching system according to claim 65, wherein said supervisor includes a cell counter to count a number of the received cells having the same identified virtual connection in a predetermined duration unit.
67. ~A switching system according to claim 65, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
68. ~A switching system, comprising:
an interface to receive a cell including a header field with an identified virtual connection;
a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at an address of the memory corresponding to the identified virtual connection of the received cell; and a switch to direct the cell from said supervisor to an output of the identified virtual connection.
an interface to receive a cell including a header field with an identified virtual connection;
a supervisor including a memory to store a plurality of bandwidth data which are pre-assigned to sources of cells, and are stored at addresses thereof, each of the addresses being operatively accessed based on one of a plurality of identified virtual connections, said supervisor marking the received cell to indicate a higher cell loss priority when a transmission rate of the received cell exceeds a rate corresponding to the bandwidth data stored at an address of the memory corresponding to the identified virtual connection of the received cell; and a switch to direct the cell from said supervisor to an output of the identified virtual connection.
69. A switching system according to claim 68, wherein said supervisor includes a cell counter to count a number of the received cells having the same identified virtual connection in a predetermined duration unit.
70. A switching system according to claim 68, further comprising a discard circuit to discard the received cell which has been marked to indicate a higher cell loss priority when a buffer has less capacity than an operative capacity to store the received cell.
71. ~A supervision control method, according to claim 1, wherein each of the cells is of fixed length.
72. ~A supervision control apparatus according to claim 4, wherein each of the cells is of fixed length.
73. ~A supervision control method, according to claim 9, wherein each of the cells is of fixed length.
74. ~A supervision control apparatus, according to claim 12, wherein each of the cells is of fixed length.
75. ~A supervision control apparatus, according to claim 15, wherein each of the cells is of fixed length.
76. ~A supervision control apparatus, according to claim 18, wherein each of the cells is of fixed length.
77. ~A supervision control apparatus, according to claim 21, wherein each of the cells is of fixed length.
78.~A supervision control apparatus, according to claim 24, wherein each of the cells is of fixed length.
79. ~A supervision control apparatus, according to claim 27, wherein each of the cells is of fixed length.
80. ~A supervision control method, according to claim 30, wherein each of the cells is of fixed length.
81. A supervision control method, according to claim 33, wherein each of the cells is of fixed length.
82. A supervision control method, according to claim 36, wherein each of the cells is of fixed length.
83. A switching system, according to claim 39, wherein each of the cells is of fixed length.
84. A switching system, according to claim 42, wherein each of the cells is of fixed length.
85. A switching system, according to claim 45, wherein each of the cells is of fixed length.
86. A switching system, according to claim 48, wherein each of the cells is of fixed length.
87. A supervision control method, according to claim 51, wherein each of the cells is of fixed length.
88. A supervision control apparatus, according to claim 55, wherein each of the cells is of fixed length.
89. A switching system, according to claim 59, wherein each of the cells is of fixed length.
90. A switching system, according to claim 62, wherein each of the cells is of fixed length.
91. A switching system, according to claim 65, wherein each of the cells is of fixed length.
92. A switching system, according to claim 68, wherein each of the cells is of fixed length.
93. A supervision control method according to claim 9, wherein said storing comprises storing bandwidth data which is declared from the source of the received cell prior to transmitting the received cell from the source.
94. A supervision control apparatus according to claim 12, wherein said memory stores bandwidth data which is declared from the source of the received cell prior to transmitting the received cell from the source.
95. A supervision control apparatus according to claim 15, wherein said memory means stores bandwidth data which is declared from the source of the received cell prior to transmitting the received cell from the source.
96. A supervision control method according to claim 51, wherein said storing comprises storing bandwidth data which is declared from the source of the received cell prior to transmitting the received cell from the source.
97. A supervision control method according to claim 55, wherein said memory stores bandwidth data which is declared from the source of the received cell prior to transmitting the received cell from the source.
98. A switching system, according to claim 59, wherein said memory stores bandwidth data which is declared from the source of the received cell prior to transmitting the received cell from the source.
Applications Claiming Priority (2)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| JP27915390A JP3128654B2 (en) | 1990-10-19 | 1990-10-19 | Supervisory control method, supervisory control device and switching system |
| JP2-279153 | 1990-10-19 |
Publications (2)
| Publication Number | Publication Date |
|---|---|
| CA2053734A1 CA2053734A1 (en) | 1992-04-20 |
| CA2053734C true CA2053734C (en) | 2002-08-27 |
Family
ID=17607190
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA 2053734 Expired - Lifetime CA2053734C (en) | 1990-10-19 | 1991-10-18 | Supervision control system |
Country Status (5)
| Country | Link |
|---|---|
| US (2) | US5394396A (en) |
| EP (1) | EP0481505B1 (en) |
| JP (1) | JP3128654B2 (en) |
| CA (1) | CA2053734C (en) |
| DE (1) | DE69129887T2 (en) |
Families Citing this family (41)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| JPH04257145A (en) * | 1991-02-12 | 1992-09-11 | Hitachi Ltd | Method and device for packet flow rate control |
| JPH05122238A (en) * | 1991-10-28 | 1993-05-18 | Fujitsu Ltd | Police system in atm exchange |
| AU661155B2 (en) * | 1992-06-18 | 1995-07-13 | Telstra Corporation Limited | A method for controlling congestion in packet switched telecommunications networks |
| JP3211833B2 (en) * | 1993-07-21 | 2001-09-25 | 富士通株式会社 | ATM switch |
| US5528763A (en) * | 1993-09-14 | 1996-06-18 | International Business Machines Corporation | System for admitting cells of packets from communication network into buffer of attachment of communication adapter |
| US5448564A (en) * | 1994-01-31 | 1995-09-05 | Advanced Micro Devices, Inc. | Modular architecture for fast-packet network |
| US6134218A (en) * | 1994-04-28 | 2000-10-17 | Pmc-Sierra (Maryland), Inc. | Many dimensional congestion detection system and method |
| JP2757779B2 (en) * | 1994-06-21 | 1998-05-25 | 日本電気株式会社 | Buffer priority control method |
| EP0700229B1 (en) | 1994-08-22 | 2006-06-28 | Fujitsu Limited | Connectionless communications system, test method, and intra-station control system |
| DE69533353T2 (en) * | 1995-05-01 | 2005-09-01 | Koninklijke Kpn N.V. | Communication system with marking system |
| US5956342A (en) | 1995-07-19 | 1999-09-21 | Fujitsu Network Communications, Inc. | Priority arbitration for point-to-point and multipoint transmission |
| WO1997004567A1 (en) * | 1995-07-19 | 1997-02-06 | Fujitsu Network Communications, Inc. | Method and apparatus for discarding frames in a communications device |
| JPH0974420A (en) * | 1995-09-06 | 1997-03-18 | Fujitsu Ltd | Band control system |
| US5898671A (en) | 1995-09-14 | 1999-04-27 | Fujitsu Network Communications, Inc. | Transmitter controlled flow control for buffer allocation in wide area ATM networks |
| JP3652759B2 (en) * | 1995-11-27 | 2005-05-25 | 富士通株式会社 | Packet flow monitoring and control method |
| KR100318956B1 (en) | 1995-12-26 | 2002-04-22 | 윤종용 | Apparatus and method for multiplexing cells in asynchronous transmission mode |
| US5991298A (en) | 1996-01-16 | 1999-11-23 | Fujitsu Network Communications, Inc. | Reliable and flexible multicast mechanism for ATM networks |
| DE19602337A1 (en) * | 1996-01-23 | 1997-07-24 | Siemens Ag | Method for handling overload situations in ATM networks |
| JPH09224034A (en) * | 1996-02-19 | 1997-08-26 | Fujitsu Ltd | Overflow processing system for counter value and cell flow-in control system |
| US5838661A (en) * | 1996-03-27 | 1998-11-17 | Cirrus Logic, Inc. | Method and arrangement for shutting off a receive channel in a data communications system |
| JPH09266484A (en) * | 1996-03-28 | 1997-10-07 | Mitsubishi Electric Corp | Atm exchange |
| US5828653A (en) * | 1996-04-26 | 1998-10-27 | Cascade Communications Corp. | Quality of service priority subclasses |
| US5748905A (en) | 1996-08-30 | 1998-05-05 | Fujitsu Network Communications, Inc. | Frame classification using classification keys |
| JPH10150445A (en) * | 1996-11-19 | 1998-06-02 | Fujitsu Ltd | Cell loss detection method |
| US6097698A (en) | 1996-12-16 | 2000-08-01 | Cascade Communications Corporation | Cell loss balance system and method for digital network |
| EP0957588A1 (en) * | 1996-12-18 | 1999-11-17 | Aiwa Co., Ltd. | Radio receiver, radio receiving method, and audio transmitter |
| JP3077647B2 (en) * | 1997-11-04 | 2000-08-14 | 日本電気株式会社 | Concentrator type ATM switch system |
| US6426943B1 (en) * | 1998-04-10 | 2002-07-30 | Top Layer Networks, Inc. | Application-level data communication switching system and process for automatic detection of and quality of service adjustment for bulk data transfers |
| JP3045150B2 (en) * | 1998-07-22 | 2000-05-29 | 日本電気株式会社 | ATM communication quality monitoring device, quality monitoring method, and ATM switching device |
| FI106504B (en) * | 1998-10-06 | 2001-02-15 | Nokia Networks Oy | Data segmentation method in a communication system |
| JP2000196621A (en) * | 1998-12-28 | 2000-07-14 | Nec Corp | Asynchronous transfer mode multiplexer and cell rejecting method |
| US7142507B1 (en) | 1999-02-25 | 2006-11-28 | Nippon Telegraph And Telephone Corporation | Traffic monitoring equipment and system and method for datagram transfer |
| JP3471276B2 (en) * | 1999-02-25 | 2003-12-02 | 日本電信電話株式会社 | Datagram transfer system and datagram transfer device |
| WO2001001634A1 (en) * | 1999-06-24 | 2001-01-04 | Fujitsu Limited | Dynamic virtual channel manager |
| US6574195B2 (en) * | 2000-04-19 | 2003-06-03 | Caspian Networks, Inc. | Micro-flow management |
| US6968392B1 (en) * | 2000-06-29 | 2005-11-22 | Cisco Technology, Inc. | Method and apparatus providing improved statistics collection for high bandwidth interfaces supporting multiple connections |
| US6831891B2 (en) * | 2001-03-06 | 2004-12-14 | Pluris, Inc. | System for fabric packet control |
| JP3896879B2 (en) * | 2002-03-22 | 2007-03-22 | 日本電気株式会社 | Traffic monitoring system |
| US7142513B2 (en) | 2002-05-23 | 2006-11-28 | Yea-Li Sun | Method and multi-queue packet scheduling system for managing network packet traffic with minimum performance guarantees and maximum service rate control |
| US7558200B2 (en) * | 2005-09-01 | 2009-07-07 | Microsoft Corporation | Router congestion management |
| US8547843B2 (en) | 2006-01-20 | 2013-10-01 | Saisei Networks Pte Ltd | System, method, and computer program product for controlling output port utilization |
Family Cites Families (42)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| US4734907A (en) * | 1985-09-06 | 1988-03-29 | Washington University | Broadcast packet switching network |
| US4769810A (en) * | 1986-12-31 | 1988-09-06 | American Telephone And Telegraph Company, At&T Bell Laboratories | Packet switching system arranged for congestion control through bandwidth management |
| US4769811A (en) * | 1986-12-31 | 1988-09-06 | American Telephone And Telegraph Company, At&T Bell Laboratories | Packet switching system arranged for congestion control |
| FR2616024B1 (en) | 1987-05-26 | 1989-07-21 | Quinquis Jean Paul | SYSTEM AND METHOD FOR PACKET FLOW CONTROL |
| FR2616025B1 (en) | 1987-05-26 | 1989-07-21 | Lespagnol Albert | METHOD AND SYSTEM FOR PACKET FLOW CONTROL |
| EP0308565B1 (en) | 1987-09-23 | 1993-02-10 | International Business Machines Corporation | Improvement to digital packet switching networks |
| DE3732937A1 (en) | 1987-09-30 | 1989-04-20 | Philips Patentverwaltung | CIRCUIT ARRANGEMENT FOR AVOIDING OVERLOAD IN A BROADBAND SWITCHING SYSTEM |
| JPH01221042A (en) | 1988-02-29 | 1989-09-04 | Toshiba Corp | Congestion control method for packet exchange |
| JPH021671A (en) | 1988-03-17 | 1990-01-05 | Toshiba Corp | Load control system for packet switchboard |
| JP2753254B2 (en) | 1988-04-06 | 1998-05-18 | 株式会社日立製作所 | Packet exchange system |
| JPH0290834A (en) * | 1988-09-28 | 1990-03-30 | Hitachi Ltd | Atm channel equipment and atm line terminal equipment |
| DE68929523T2 (en) | 1988-07-22 | 2005-12-15 | Hitachi, Ltd. | ATM switching system |
| SE462360B (en) | 1988-10-28 | 1990-06-11 | Ellemtel Utvecklings Ab | PROCEDURE AND DEVICE TO PREVENT IT TO BE SENDED ON A COMMON TRANSFER LINK HIGH-INTENSITY DATA PACKAGE WITH A PREDICTED VALUE DETERMINED AT A PREDICTED VALUE |
| US5130985A (en) | 1988-11-25 | 1992-07-14 | Hitachi, Ltd. | Speech packet communication system and method |
| NL8900269A (en) | 1989-02-03 | 1990-09-03 | Nederland Ptt | METHOD FOR TRANSMISSION OF TIME-DISTRIBUTED TRANSMISSION CHANNELS OVER A STAGE OF DATA CELLS THROUGH A MULTIPLE OF ASYNCHRONOUS Maintaining a counter reading per transmission channel, which depends on the number of data cells per time. |
| FR2643532B1 (en) | 1989-02-17 | 1991-05-10 | France Etat | METHOD FOR RESERVING RATES AND TIME SWITCHES OF ASYNCHRONOUS PACKETS |
| JPH02220531A (en) | 1989-02-22 | 1990-09-03 | Toshiba Corp | Call connection control system and flow monitor system |
| US5140584A (en) | 1989-03-01 | 1992-08-18 | Kabushiki Kaisha Toshiba | Packet communication system and method of controlling same |
| JP2860661B2 (en) * | 1989-03-14 | 1999-02-24 | 国際電信電話 株式会社 | ATM switch |
| NL8900640A (en) | 1989-03-16 | 1990-10-16 | At & T & Philips Telecomm | METHOD FOR TRANSMITTING DATA PACKAGES IN ATD (ASYNCHRONOUS TIME DIVISION) AND AN APPARATUS FOR APPLYING THIS METHOD |
| CA2012868C (en) | 1989-03-23 | 1994-03-22 | Shin-Ichiro Hayano | Call control with transmission priority in a packet communication network of an atm type |
| FR2648648B1 (en) * | 1989-06-20 | 1991-08-23 | Cit Alcatel | METHOD AND DEVICE FOR EVALUATING THE FLOW RATE OF CIRCUITS EMPLOYING AN ASYNCHRONOUS TIMED MULTIPLEXED TRANSMISSION CHANNEL |
| US5179557A (en) | 1989-07-04 | 1993-01-12 | Kabushiki Kaisha Toshiba | Data packet communication system in which data packet transmittal is prioritized with queues having respective assigned priorities and frequency weighted counting of queue wait time |
| JPH03104451A (en) * | 1989-09-19 | 1991-05-01 | Fujitsu Ltd | Route changeover system for multi-stage link exchange system |
| EP0419958B1 (en) * | 1989-09-29 | 1997-02-19 | Siemens Aktiengesellschaft | Circuit arrangement for detecting the data quantity transmitted in an ATM-switching system and for checking compliance with specified bit rates |
| US5038345A (en) | 1989-10-30 | 1991-08-06 | Amp Incorporated | Traffic pattern information for a local area network |
| JP2701507B2 (en) | 1990-02-13 | 1998-01-21 | 日本電信電話株式会社 | Cell loss rate estimation method, and call admission control device and buffer link design device using the same |
| US5029164A (en) | 1990-04-13 | 1991-07-02 | Digital Equipment Corporation | Congestion avoidance in high-speed network carrying bursty traffic |
| ATE149070T1 (en) * | 1990-08-08 | 1997-03-15 | Siemens Ag | METHOD AND CIRCUIT ARRANGEMENT FOR DETERMINING THE QUALITY OF VIRTUAL CONNECTIONS OVER AN ATM SWITCHING DEVICE |
| US5280483A (en) | 1990-08-09 | 1994-01-18 | Fujitsu Limited | Traffic control system for asynchronous transfer mode exchange |
| JP3241716B2 (en) | 1990-08-31 | 2001-12-25 | 株式会社東芝 | ATM exchange method |
| JP3420763B2 (en) | 1991-04-10 | 2003-06-30 | コーニンクレッカ フィリップス エレクトロニクス エヌ ヴィ | Low delay or low loss switch for ATM |
| US5233606A (en) | 1991-08-02 | 1993-08-03 | At&T Bell Laboratories | Arrangement for controlling shared-buffer-memory overflow in a multi-priority environment |
| US5850385A (en) | 1991-09-24 | 1998-12-15 | Kabushiki Kaisha Toshiba | Cell loss rate sensitive routing and call admission control method |
| GB2261798B (en) | 1991-11-23 | 1995-09-06 | Dowty Communications Ltd | Packet switching networks |
| US5448567A (en) | 1993-07-27 | 1995-09-05 | Nec Research Institute, Inc. | Control architecture for ATM networks |
| US5784358A (en) | 1994-03-09 | 1998-07-21 | Oxford Brookes University | Broadband switching network with automatic bandwidth allocation in response to data cell detection |
| US5504744A (en) | 1994-03-09 | 1996-04-02 | British Telecommunications Public Limited Company | Broadband switching network |
| US5392280A (en) | 1994-04-07 | 1995-02-21 | Mitsubishi Electric Research Laboratories, Inc. | Data transmission system and scheduling protocol for connection-oriented packet or cell switching networks |
| US5706288A (en) | 1996-03-27 | 1998-01-06 | Pmc-Sierra, Inc. | Available bit rate scheduler |
| US5867494A (en) | 1996-11-18 | 1999-02-02 | Mci Communication Corporation | System, method and article of manufacture with integrated video conferencing billing in a communication system architecture |
| US5956340A (en) | 1997-08-05 | 1999-09-21 | Ramot University Authority For Applied Research And Industrial Development Ltd. | Space efficient fair queuing by stochastic Memory multiplexing |
-
1990
- 1990-10-19 JP JP27915390A patent/JP3128654B2/en not_active Expired - Lifetime
-
1991
- 1991-10-18 CA CA 2053734 patent/CA2053734C/en not_active Expired - Lifetime
- 1991-10-18 DE DE1991629887 patent/DE69129887T2/en not_active Expired - Lifetime
- 1991-10-18 EP EP19910117814 patent/EP0481505B1/en not_active Expired - Lifetime
-
1994
- 1994-06-17 US US08/261,890 patent/US5394396A/en not_active Expired - Lifetime
-
1997
- 1997-02-27 US US08/810,977 patent/USRE37435E1/en not_active Expired - Lifetime
Also Published As
| Publication number | Publication date |
|---|---|
| USRE37435E1 (en) | 2001-11-06 |
| DE69129887D1 (en) | 1998-09-03 |
| JP3128654B2 (en) | 2001-01-29 |
| EP0481505A3 (en) | 1992-10-28 |
| EP0481505A2 (en) | 1992-04-22 |
| US5394396A (en) | 1995-02-28 |
| CA2053734A1 (en) | 1992-04-20 |
| EP0481505B1 (en) | 1998-07-29 |
| JPH04156026A (en) | 1992-05-28 |
| DE69129887T2 (en) | 1999-01-14 |
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| CA2053734C (en) | Supervision control system | |
| US5295135A (en) | Arrangement for monitoring the bit rate in ATM networks | |
| US5339332A (en) | Arrangement for monitoring the bit rate in ATM networks | |
| US5453981A (en) | Method of controlling communication network incorporating virtual channels exchange nodes and virtual paths exchange nodes | |
| US5150358A (en) | Serving constant bit rate traffic in a broadband data switch | |
| JP3545110B2 (en) | Communication service quality control method | |
| EP0533900B1 (en) | Low delay or low loss cell switch for atm | |
| US6041038A (en) | Packet switching device and cell transfer control method | |
| CA2130403C (en) | Atm switching system and cell control method | |
| US6067298A (en) | ATM switching system which separates services classes and uses a code switching section and back pressure signals | |
| US5287347A (en) | Arrangement for bounding jitter in a priority-based switching system | |
| EP0788288A2 (en) | Flow control in a cell switched communication system | |
| JP3632229B2 (en) | ATM switching equipment | |
| US6169727B1 (en) | Device and method of notifying and controlling congestion in asynchronous transfer mode network | |
| EP0481447B1 (en) | Method of controlling communication network incorporating virtual channels exchange nodes and virtual paths exchange nodes, and the said communication network | |
| JP3644404B2 (en) | Optical subscriber line terminal station apparatus, APON system, and cell delay fluctuation suppressing method | |
| Cooper et al. | A reasonable solution to the broadband congestion control problem | |
| Cisco | ATM Connections | |
| Cisco | ATM Connections | |
| JP3097549B2 (en) | ATM switch | |
| US6982981B1 (en) | Method for configuring a network termination unit | |
| EP1443703A1 (en) | Method and apparatus for generating test packets in a data network | |
| KR100191257B1 (en) | Apparatus for real-time queue service discipline using virtual clock algorithm in atm networks | |
| KR19990039236A (en) | Multiplexing Method in Asynchronous Transmission Mode Network | |
| JPH08237262A (en) | Atm communication network and transmission terminal equipment |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| EEER | Examination request | ||
| MKEX | Expiry |