JP2001500323A - Method and apparatus for reducing information loss in a communication network - Google Patents

Abstract

(57) [Summary] The present invention reduces information loss in a communication network (10). The plurality of virtual connections are transmitted from a first node of a communication network (10) to a second node via a first link. A node is comprised of a plurality of input queues coupled to a switching network, and the switching network is coupled to a plurality of output queues. Each virtual connection is associated with a first output queue of a first node, a second input queue of a second node, and a second output queue of a second node. A connection feedback signal is provided from the second node to the first node along with the state of the second input queue to control the flow of information between the nodes. An exchange feedback signal is provided between the second output queue and the second input queue with the state of the second output queue to control the flow of information through the exchange at the second node.

Description

DETAILED DESCRIPTION OF THE INVENTION                 Method and apparatus for reducing information loss in a communication networkTECHNICAL FIELD OF THE INVENTION   The present invention relates generally to communication networks, and more particularly to a method for reducing information loss in a communication network. Laws and systems.Background of the Invention   Communication networks, such as Asynchronous Transfer Mode ("ATM") networks, provide audio, video, and other Used for data transfer. ATM networks are data units like ATM cells Data by routing from the source to the destination via a switch I do. The switch (or node) has an input / output port and is connected via the input / output port. Then, the ATM cell is received and transmitted. The exchanges in the communication network are connected by continuous links. Connected.   One problem associated with ATM networks is cell loss due to congestion. Cell Buffered in each switch before being routed and transmitted from the switch . More specifically, switches typically store cells temporarily before transmission. The switch has a buffer at one or both of the input and output (or both). network Improper buffer space and loss of data as traffic increases The possibilities increase. If the buffer size is insufficient, cells will be lost. Cell loss May cause unwanted interference with audio and video data transmissions and cause more serious damage. This type of data transmission may occur. Therefore, avoid cell loss Is desirable. The cell may be due to congestion on the link between the nodes or the nodes themselves. Can be lost due to internal congestion.   Cell loss is particularly problematic for certain types of network traffic. Effectiveness Bit rate services allow applications to tolerate multiple times of delay variation. Used when low cost service is required. Low cost sir Bandwidth and buffering resources between multiple connections to achieve Shared by The service is low cost. Bandwidth is reserved for each connection Bandwidth that is not used by the delay-sensitive connection Can be used by connection.   The most important quality of service for effective bitrate service is cell loss. You. The main reasons for using effective bitrate services are burst size and This is because the periodicity is unpredictable and an economical service is desired. Typically, The burst size requires a group of cells. A cell reaches its destination If not, from the point of view of receiving information, a cell loss triggers a cell retransmission, which As a result, a larger delay occurs. From the sender's point of view, the cell is If not, all cells in the frame will be lost when cells from the group are lost. Used to make cells in other frames reach the destination Resources are wasted. Therefore, because of the unpredictable effective bit rate service Delay and resource utilization are minimized by achieving cell-free loss. for The term "cell-free" refers to cells lost due to network congestion.Summary of the Invention   The present invention comprises a method and apparatus for reducing information loss in a communication network. The present invention According to the law, a plurality of virtual connections are connected to a communication network via a first link. Sent from the first node to the second node of the communication network. First and second nodes Consists of a plurality of input queues coupled to the switching network, and the switching network Is bound to an output queue. Each virtual connection is One output queue and the second output queue of the second node.   The connection feedback signal is the second signal associated with the virtual connection. From the second node for each virtual connection that reflects the state of the input queue of Provided to the first node. The flow of information between the first node and the second node is For a particular virtual connection or group of virtual connections Is controlled according to the connection feedback signal. Exchange feedback A signal is a specific virtual connection or a group of virtual connections. Each virtual connector consisting of data reflecting the state of the second output queue associated with The data is supplied from the second output queue to the second input queue for each action. Each virtual Of information between the second input queue and the second output queue for each connection Is controlled according to the exchange feedback signal related to the virtual connection Is done.   The present invention has several important technical effects. The present invention uses each link Per connection, per node passing through each node, and via links or nodes Enable flow control for each group of connections. Thus, the present invention provides Minimize both cell loss through the switch and across each link of the cell-based network It is possible to suppress. More efficient network resources by minimizing cell loss And the delay through the network is minimized. In practice, The present invention achieves cell-free loss due to congestion.   In controlling the flow of cells through the switch, the invention provides a virtual connection. It implements flow control for each application. Virtual connections can be dedicated or shared buffers Resource may be used. Shared buffer resources are connection traffic type But may be realized based on traffic subtypes. May be. Flow control for each virtual connection depends on the status of dedicated and shared resources Consider. The present invention realizes flow control for each connection. Is a valid point-to-multipoint within the node Enables operation and multipoint-to-point operation.   The present invention provides for flow over a link at both link level and connection based. Allow control. Therefore, link flow control is only available for connections over links. Since the present invention can be realized with a smaller bandwidth than per-unit flow control, the present invention is useful. The update frequency of the network used is high in the case of link flow control, and the flow of each connection Low for control. Since link level flow control exists only once per link In the end, a low and efficient update frequency is obtained, while links are typically It has a number of connections inside that require row control. Thus, the present invention To minimize the link bandwidth consumption for transmitting flow control update information.   However, the entire link is a link, i.e., all connections within the link. The buffer has a flow control mechanism that ensures lossless transmission The connection shares access to the available buffer space. You. Sharing of buffer space is required for links at well-defined and known time intervals. The projected buffer is active for all connections in the link during the same time interval. Less than the projected buffer required when calculated together and independently. This means that fewer buffers are needed. In addition, link bandwidth High update frequency used in link-level flow control without excessive consumption of width The degree allows for a further minimization of the buffer to be allocated to the link. Receiving Minimizing the number of cell buffers in the transmitter significantly increases the net receiver cost Lower.   The present invention relates to a connector that uses both link flow control and switch flow control. Make it possible to create options. Link flow control, exchange flow control, Or other connections that do not use both use the same link or the same switch. May coexist. These connections are linked flow control accounting The system has Not included. For example, a constant bit rate connection uses link flow control. It may or may not be used. In addition, the present invention provides that the connection Allows to be multiplexed with the effective bit rate connection using control.BRIEF DESCRIPTION OF THE FIGURES   By referring to the following description in conjunction with the accompanying drawings, the present invention and the effects of the present invention are described. Is more fully understood. In the drawing,   FIG. 1 is a diagram showing a communication network configured according to the present invention;   FIG. 2 is a block diagram of a node of the communication network of FIG.   FIG. 3 is a portion of the communication network of FIG. 1 that implements the use of flow control over a communication link. FIG.Detailed description of the invention   Preferred embodiments of the present invention and the advantages of the present invention are identified by the same reference numerals in the various figures. Very well understood by referring to FIGS. 1 to 3 which are used for the minutes and corresponding parts. Understood.   FIG. 1 is a diagram illustrating a communication network configured in accordance with the teachings of the present invention. Communication network 10 Is composed of a plurality of nodes 12 connected by a plurality of links 14. Each node 12 comprises a communication device called an exchange. In the case of this embodiment, the communication network Reference numeral 10 denotes a cell-based communication network in which information is transmitted in cells. Each cell has a header and And a data section. In the case of this embodiment, the communication network 10 uses the asynchronous transfer mode (AT M) Network. The present invention may be applied to cell-based networks without departing from the scope of the present invention. It can be used in external communication networks.   The communication network 10 includes a number of flows between and within the nodes 12 of the communication network 10. Use a control mechanism. In the case of the above embodiment, the flow control is performed through the note 12, And between the nodes 12 via the communication link 14. Within node 12, Flow control is a connection This is performed for each connection or each connection group. Flow between nodes 12 Control is performed for each connection and for each link via the link 14. You. Flow control through exchanges can be exchange flow control or exchange per connection. Called flow control. Flow control over one of the link-level links 14 Control is referred to as link flow control. Flow through each connection link The control is called link flow control for each connection.   FIG. 2 shows the method used to control the flow through each node 12 (exchange FIG. 1 is a block diagram of a node of a communication network 10 used for explaining a machine flow control. Have been. Each node 12 includes a plurality of input queues 16, a switch body 18, Number of output queues 20. The input queue 16 is coupled to the switch body 18, Next, the switch body is connected to the output queue 20. Information from input queue 16 The information flows to the output queue 20 through the switch body 18. In the case of this embodiment, The input queue 16 is uniquely assigned to a specific connection, and each output queue 20 is uniquely assigned to a particular connection through node 12. Each birch Providing a unique input queue 16 and output queue 20 for each connection Thus, the flow control through the node 12 is simplified. Each connection is a connection The bandwidth type is assigned based on the traffic type associated with the application. There are two types of bandwidth to be allocated in the switch, an allocation type and a dynamic type. Percent The attached bandwidth is the bandwidth of the exchange body 18 and the connection to which the bandwidth is allocated. Reserved for use by the application. Generally speaking, the allocated bandwidth is The accompanying connection has access to all of the bandwidth allocated to that connection. The cell is guaranteed. In this way, traffic that requires deterministic control of delay The network type is assigned an allocated bandwidth. Dynamic bandwidth can be different for different competitive connections. Bandwidth that is "shared" by any of the options. Dynamic bandwidth is shared Because it is a source There is no guarantee that a particular connection will access a particular amount of bandwidth. For this reason, Dynamic bandwidth is typically allocated to connections with wider delay bounds. You. Other connections are assigned a combination of dynamic and allocated bandwidth .   In the present invention, the first and second bits are added to facilitate the flow control of the switch body. Utilize digital feedback messages. This feedback message Messages are sent to the input queue 16 from the output queue 20 associated with a particular connection. Contains an acknowledgment message ACCEPT that can be trusted. More specifically, the feedback By using the first bit of the ACK message, the first bit that matches zero is The acknowledgment message ACCEPT in the input queue transfers the cell to the output queue 20. To request that you The input key for which the message ACCEPT is When received by the queue, the cell is transferred to the output queue 20. Feedback The lock message further includes a reject message REJECT. Message REJ When an ECT is received by the requesting input queue 16, no cells are transferred. However, further transfer requests are sent to the input queue 16.   The feedback message temporarily interrupts the transmission of a transfer request with dynamic bandwidth. XOFF (dynamic) message to stop. XOFF from specific output queue 20 Each input queue 16 that receives (dynamic) messages will have a specified event Until then, it does not issue a transmission request to a particular output queue 10 via the dynamic bandwidth. Designation The event that has occurred is a predetermined amount of time elapses, or X that permits transmission of a further transfer request. An ON signal may be received. The input queue 16 uses the XON signal regularly to immediately That is, regardless of when each specific input queue 16 is moved to the XOFF (dynamic) state. May be allowed. The rule of such regularity is, for example, even in 100 milliseconds. Good. When the second bit of the two-bit message matches zero, no operation NO-O P signal. Each input queue 16 receiving a non-operation NO-OP signal is in a disabled state. I will not be.   The feedback message is an XOFF (assignment type) feedback message including. Each input queue receiving XOFF (assignment type) from a specific output queue 20 16 is a specific output queue with allocated bandwidth until a specified event occurs. A transfer request to 20 is not issued temporarily. The specified event is typically Request to send an XON signal. Input queue 16 is a rule Specifically, when each specific input queue 16 is moved to the XOFF (assignment type) state Irrespective of this, it may be permitted by the XON signal. Such regular criteria, for example, For example, it may be every 100 milliseconds. If the second bit of the two-bit message is zero or one When matched, indicates a no-operation NO-OP signal. (No operation) Receiving NO-OP signal Are not disabled.   In this embodiment, the XON signal indicates that the input queue 1 is in any XOFF state. 6 to enable. Receiving XON from specific output queue 20 Each of the input queues 16 can transmit a transmission request to the output queue 20 It is. More specifically, XON is an XOFF (dynamic) state and an XOFF (allocation type). ) Reset both states. XON signal reduces unnecessary switch traffic In order to prevent flow disruption due to errors. Can be used for   Various combinatorial responses to transmission requests are received by the input queue 16 in the request. Be trusted. XON reception and ACCEPT message or REJECT message Reception of any of the messages is performed as described above. XOFF (dynamic) and A CCEPT message or XOFF (assignment type) and ACCEPT message Receive any further transfer requests via the specified bandwidth type. This indicates that the transfer of one cell is stopped. XOFF (Dynamic) and REJECT Messe Page or XOFF (assignment type) and REJECT Receipt of a message will immediately prompt for further transfer requests with the specified bandwidth type. Means that the cell is no longer transmitted. Thus, the XOFF command Affects further requests, and the REJECT command rejects the current request.   An inactive NO-OP / XOFF (dynamic) message is an unnecessary Used to reduce feedback signaling. Switch bandwidth, cell switched When the REJECT message appears repeatedly when it cannot be transmitted through the device Lost to. XOFF (dynamic) is thus performed on a full output queue 20 Used to reduce the number of requests made.   Flow control with the above feedback message is highly reliable in the exchange. Point-to-multipoint transmission, i.e., multiple outputs from a single input queue 16. Provides transmission to force queue 20. For point-to-multipoint operation, Feedback messages from multiple output queues 20 to a single input queue 16 Is a single XOF from any one of the plurality of output queues 20. F (dynamic) or REJECT message is OR'ed to prevent transmission . Thus, the point-to-multipoint cell has the lowest output queue 20 rate. Transmitted by   The flow control with the 2-bit feedback message described above Reliable multipoint-to-point transmission, i.e. multiple input queues 16 Provide transmission to a single output queue 20. Each output queue 20 has a threshold, An XON message is transmitted when the output queue 20 has reached the threshold. Mar In the case of a one-point-to-point operation, the XON threshold of the output queue 20 is It is set dynamically to ensure sufficient space for transmission to the queue 20. For example , When there are eight input queues 16, the output queues 20 are all The threshold is set to 8 to free up enough space to receive all cells .   Thus, the feedback mechanism of the present invention prevents cell loss in node 12. When the output queue 20 is filled to a predetermined threshold level, Feedback message is entered to prevent cell transmission to force queue 20 It is supplied to the queue 16. The number of cells transmitted to the output queue 20 is the output queue 2 If there are more than the number of available locations in 0, the cell is lost. However, the output key Block transmission of cells from input queue 16 when queue is full to threshold level Feedback message is transmitted to the input queue 16. Threshold level Have more cells than can be handled by the available space in the output queue 20. Is set to a value that prevents the transmission of files. However, the input queue 16 and the output queue 20 Cell loss between is prevented by the flow control message.   In this embodiment, the input queue 16 and the output queue 20 are shared resources. Traffic type group to provide traffic flow control when Assigned. By assigning a unique queue for each connection, -Control is realized for each connection. Flow control for each traffic type Can be realized. In addition, flow control for each connection of the type for each traffic A nested queue may be used to provide it. As above Each connection is based on the traffic type associated with the connection. Bandwidth is allocated.   At node 12, a connection using dynamic bandwidth, allocated bandwidth, or both. Each cell is labeled to identify the cell associated with the action. More details In other words, a transfer request for a connection using dynamic bandwidth is sent to a bit in the first state. Request for a connection that uses the allocated bandwidth A status bit is marked. The cell rate at which the connection was allocated If so, the cell is marked as dynamic. Connection-allocated cell If the cell operates below the rate, the cell is labeled Be killed.                                   Table 1                         Feedback message  Referring to Table 1, The feedback message is a request message from the input queue 16. Provided according to the message. Transmit cells from input queue 16 to output queue 20 Before you do To determine whether sufficient space is available in the output queue 20 , A request message is sent from the input queue 16 to the output queue 20. Fee The back message is Give an indication of the state of the output queue 20; Transmission follows it Begin. The request message is Cells are now transferred only under selected conditions Proceed with cell transfer in the exchange.   To provide effective flow control, The flow from the output queue 20 to the input queue 16 The feedback message is Includes several subtype messages. For example, H The feedback message is ACCEPT message sent in response to the request message Including messages. By using a 1-bit digital signal, Matches zero The first bit is Input queue request to transfer a cell to a specific output queue 20 ACCEPT (acceptance). ACCEPT by requesting input queue 16 When a message is received, The cell is transferred to the output queue 20.   Also, The feedback message is REJECT message Including sage. More specifically, The response to the request message is ACCEP Contains either a T message or a REJECT message. 1-bit data By using digital signals, The first bit that matches 1 is Output cell REJECT (rejection) of the request to be transferred to the queue 20. Input key during request When a REJECT message is received by queue 16, Cell is the output queue Not transferred to 20. But, Further request messages output from input queue 16 It is transmitted to the queue 20.   To reduce the likelihood of lockups in switch flow control, Poe Regardless of the failure of internal elements like Time to enable continued operation It is desirable to use out-type functions. For example, XOFF (dynamic) message Following receipt of the sage, Transmission of a request message to a specific output queue 20 The stopped input queue 16 XON message is output within a predetermined time interval. If not received from queue 20, Propagate further request message to output queue 20 Send. Or, The input queue 16 Request message regardless of XOFF (dynamic) state Send messages periodically.   Thus, The present invention If a cell is lost in the output queue 20, -16 so as not to be transferred via the switch body 18 between the output queue 20 and By providing a feedback signal from the output queue 20 to the input queue 16 Enables flow control within node 12. Also, The present invention Over each communication link Provide flow control. More specifically, The present invention Link level flow system Control and per-connection link flow control.   In FIG. An upstream transmission node 12a; Connection between the downstream (receiving) node 12b Action is shown. Connection 22 Upstream node 12a and downstream node 12b. In this case, Upstream node 12a and below The flow node 12b It is constituted by an exchange node of the communication network 10. Or, Submit Node 12a Alternatively, one of the receiving nodes 12b may be a terminal station connected to the communication network 10. No.   The link flow control mechanism for each connection will be described first. Illustrated connectors In the case of The data cell is With the upstream node 12a via the connection 22 The data is transferred to and from the downstream node 12b. In this example, Connection 22 The cell associated with An input queue related to the connection 22 in the downstream node 12b. Stored in the The data cell is Switch to another link beyond the downstream node 12b By sending Or By using cells in the downstream node 12b, Connection From the input queue in the downstream node 12b associated with the node 22. The latter event Is If the downstream component 12b is in a terminal node such as a workstation, If Includes data frame configuration.   Buffer state control Buffer status counter BS_Cou of the upstream node 12a inter 24 and a buffer state limit BS_Limit 26. This fruit In the case of the example, Each counter is a 14-bit counter, Connection is 16, 383 Allows you to have multiple buffers. This number is For example, 139 megabits per second 10 (Mbps) Support 000km round trip service. Buffer status Counter 24, 26 is If the connection 22 in question is in the flow control permission state Only used when That is, Connections that are each connection descriptor A bit in the queue descriptor associated with 22 is set; Connection 22 -Indicates that control is permitted.   The buffer status counter 24 The data cell is connected from the upstream node 12a. When transferred to the downstream node 12b via the Will be increased. Explained below Periodically as This counter 24 stores information received from the downstream node 12b. Coordinated during update events based on The buffer status counter 24 Like this hand, Upstream configuration Currently transferred to connection 22 between element 12a and downstream component 12b Or Or Data that has not yet been transmitted from the buffer in the downstream node 12b. Give an indication of the number of data cells.   The buffer state limit 26 is Downstream due to input queue associated with connection 22 When configuring a connection to reflect the number of buffers available in node 12b Is set to In other words, Buffer state 26 is Related to connection 22 This reflects the capacity of the input queue of the downstream node 12b. For example, This connection 2 2, the buffer status counter 24 Indicates that the data cell has been transferred, And, The buffer state limit 26 indicates that this connection 22 To indicate that you are limited to 20 cells in the power queue, Downstream node 12b An indication that additional buffer space is available for connection 22 from Until is received Further transfer from the upstream node 12a to the downstream node 12b is prevented. Is stopped.   The transmission counter Tx_Counter 28 is Connect by upstream node 12a It is used to count the total number of data cells transmitted via option 22. this In the case of the embodiment, The transmission counter is a circulating 28-bit counter. The theory below As we will show, The transmission counter 28 Erroneous cell for connection 22 Used during inspection events to determine the cause of   At the downstream node 12b, Counter settings are retained for each connection . The buffer limit BUFFER_Limit32 is To prevent transmitter malfunction The management function is executed in the downstream node 12b. In particular, The buffer limit 32 is Connection Cells that can be used by the input queue in downstream node 12b by action 22 Indicates the maximum number of buffers. In most cases, Buffer state limit 26 is buffer limit Matches 32. But, At some point, Up or down connection 22 Need to adjust the maximum number of cell buffers available. It is necessary. This feature Network management software to avoid "missing" of data cells during transmission Adjusted by software, The increase in buffers per connection is buffer The state limit 26 is first reflected in the buffer limit 32. Conversely, Ko The reduction in the number of receiver buffers per connection 22 is First buffer state limit 26, next, This is reflected in the buffer limit 32.   The buffer counter Buffer_Counter31 is Connection at the moment In the downstream node 12b being used for storage of data cells for 22 Gives an indication of the number of As explained below, This value is It gives the upstream node 12a a more accurate concept of buffer utilization. Buffer limit B buffer_Limit32 and buffer counter Buffer_Counter 31 is In this embodiment, the width is 14 bits.   N2_Limit 34 is Connection flow rate notification to upstream node 12a Determine the frequency of communication. Cells holding such flow rate information Downstream node 1 2b transfers a large number of cells matching N2_Limit 34 from the downstream node 12b Each time it is sent, it is transmitted upstream. Next, the update operation will be described. Of this embodiment In case, N2_Limit 34 is 6 bits wide.   N2_Counter36 is After reaching N2_Limit 34 last It is used to track the number of cells transferred from the downstream node 12b. This fruit In the case of the example, N2_Counter 36 is 6 bits wide.   The transfer counter Fwd_Counter 38 is Transfer through downstream node 12b It is used to keep a running count of the total number of cells made. This includes Day Opened when the tassels are used for data frame configuration in end nodes Includes buffer. When the maximum count of the counter 38 is reached, Coun Ta loops to zero, continue. The total number of cells received by the downstream node 12b is , It is obtained by adding the buffer counter 31 to the transfer counter 38. the latter The transfer counter of As explained below, Error of the upstream node 12a during the inspection event It is used when correcting a cell with a defect. The transfer counter 38 is used in this embodiment. Is 28 bits wide.   The reception counter Rx_Counter30 is No connection downstream for connection 22 Is maintained by the node 12b. This counter is The downstream node 12b is connected When a data cell is received via the It is incremented by one. Receive counter 3 The value of 0 is Response to the test cell described below, And When an update cell occurs Available directly to: Like the transfer counter 38, The reception counter 30 In the case of the embodiment, the width is 28 bits.   The link flow control protocol for each connection includes two Event, That is, Updates and checks exist. In a stable state, Data cells are upstream From the node 12a to the downstream node 12b. When updating, Buffer occupancy information Is Upstream by the downstream node 12b to correct the counter value of the upstream node 12a Returned to the flow. Inspection mode is The transmission between the upstream node 12a and the downstream node 12b Used for inspection of cells damaged or mixed due to transmission errors.   Before any action, The counters of the upstream node 12a and the downstream node 12b are the first Be initialized. For initialization, Zeroing the counter, Buffer state limit 26, buffer Supplying initial values to limit registers such as limit 32 and N2_Limit32 included. The buffer limit 32 is Round trip time × virtual connection Initialized to (RTT × BW + N2), which represents the bandwidth of the   The buffer status counter 24 and the transmission counter 28 With flow control enabled If there is The upstream node 12a transmits a data cell via the connection 22 When it is incremented by one. After receiving the data cell, The downstream node 12b Buff Buffer 31 The limit is 32 or more, No buffer available for receiving data cells Check whether or not. If this test is negative, Data cells are discarded You. If not, The buffer counter 31 and the reception counter 30 are incremented by one. , The data cells are stored in buffer cells associated with the input queue. Transmission counter 28 and the reception counter 30 It patrols when it reaches the maximum value. Flow control allowed When not None of the above functions are activated.   When the data cell is transferred from the downstream node 12b, The buffer counter 31 Decremented by one. The buffer counter 31 Connection-level flow control When the protocol is approved, The buffer state limit 26 is reduced, Downstream node 12b is not enough to make the buffer counter 31 smaller than the buffer limit 32. Unless you need to transfer extra cells, The buffer limit 32 must not be exceeded. Ba If the buffer counter 31 is greater than or equal to the buffer limit 31, a data cell is received. When Cells are discarded, An error situation is notified to the connection 22. .   Buffer status update The downstream node 12b Matches N2_Limit34 This is performed when a large number of data cells are transferred from the downstream node 12b. Transfer counsel In one embodiment of the present invention that maintains the Updates are Downstream node in update cell 12b, the transfer of the value of the transfer counter 38 returning to the upstream node 12a. Downstream In one embodiment of the present invention utilizing the reception counter 30 in the mode 12b, Receiver The value obtained by subtracting the buffer counter 31 from the counter 30 is transmitted by the update cell. update At node 12a, The update cell is used to update the value of the buffer status counter 24 Is done. The buffer status counter 24 Independent of buffer allocation algorithm Because Buffer allocation is Performance in terms of link flow control per connection Can be changed without affecting.   The updated cells utilize the allocated bandwidth to guarantee delay within limits. This delay is To determine the buffer allocation for each connection, Raun It must be taken into account as a component of chip tip time.   The amount of bandwidth allocated to the update cell is a function of the counter. This counter Is An update cell; Forcibly perform scheduling with the test cell described below . There is a corresponding counter that controls the interval between update cells. Normal cell filling The filling is 7 records per cell, The minimum update interval is also set to 7. It is. In the above embodiment, Since you can only update once per cell time, Upstream The densely and completely packed update cells on the side of the node 12a are: Some record Causes missing.   The update event is performed as follows. The downstream node 12b has transferred (released) the cell. When The buffer counter 31 is decremented by one, N2_Counter36 and Fwd_Counter 38 is incremented by one. N2_Counter36 When it matches N2_Limit34, The downstream node 12b Upstream node 12b Prepare update cells for transfer back to N2_Counter 36 is set to 0 . The transmitter on the downstream node 12b side Identify the connection 22 to be updated Therefore, the connection indication is received from the cell transferred by the downstream node 12b. One fruit In the example, The transfer counter Fwd_Counter 38 is an update record payload. Inserted into the code. In another embodiment, Receive counter Rx_Counter3 The value obtained by subtracting the buffer counter 31 from 0 is inserted into the update record. Update cell Is completely filled with records, Or The minimum bandwidth stuffing interval has been reached Come The update cell is transmitted to the upstream node 12a, N2_Counter36 becomes 0 Reset.   The upstream node 12a Copy from update record to identify transmitter connection Receiving the negation sign, From the update record, the value of the transfer counter 38, Or Receiving The value obtained by subtracting the buffer counter 31 from the counter 30 is obtained. Buffer status Unta 24, Sending counsel Is reset to the value obtained by subtracting the updated record value from the data 28. Connection is buffered Transmission prohibited state due to buffer status counter 24 which is greater than When This condition should be reversed, If inverted Connection The action is again set to the transmission permission state.   In summary, Update events are: First transmitted by the upstream node 12a, next An indication of the number of cells released from the buffer in the downstream node 12b is displayed on the upstream node 1 2a, This allows Buffer of downstream node 12b for connection 22 A more accurate indication of the operating rate is given to the upstream node 12a.   The buffer status check event serves two purposes: That is, (1) Transmission error Calculation of cell loss or cell contamination caused by Provide a compensation mechanism, (2) Update center When lost Or Enough data that N2_Limit34 never reaches When the tassels are lost, Start (or restart) the flow.   One timer (not specified) works for all connections. The connection is Transmits a test cell from the upstream node 12a to the downstream node 12b It is allowed or prohibited one by one as to whether or not. Inspection process in the upstream node 12a Is All connection descriptors to detect connections allowed to be inspected Searching. After the minimum pacing interval (inspection interval) has elapsed, Inspection The cell is transferred to the downstream node 12b, The next test-permitted connection is identified. The gap between test cells of the same connection is Active flow controlled connectors Of the commanded gap between test cells for all connections multiplied by the number of applications. Is a number. The test cell has a higher priority than the update cell.   The inspection events are performed as follows. The connection of each upstream node 12a is is there Inspect after a time interval. The connection is allowed flow control, Connection If valid, Inspection event is downstream no A schedule for transmission to the node 12b is set. The buffer status check cell is Inspection Generated using the value of the transmission counter 28 for the connection in the cell payload. And It is transmitted using the connection indication from each connection descriptor.   In one embodiment, The calculation of the erroneous cell is Transfer counter Fwd_Count ter38 buffer counter 31, and The test cell record that sent this value The contents of the That is, By subtracting from the value of the transmission counter 28, the downstream node 12 b. The value of the transfer counter 38 is incremented by the number of erroneous cells. Turn Update record with new value for send counter Fwd_Counter38 Is generated next. The updated transfer counter Fwd_Counter 38 value is, next, The value of the buffer status counter 24 in the transmitter element 12 is updated.   In a second embodiment, The reception counter 30 is set to the inspection cell payload value (transmission count). The same is done by resetting to a value that matches the counter 28). Next update The new record uses the difference between the reception counter 30 and the buffer counter 31. Is determined by   Thus, Inspection events are: Via the connection 22 by the upstream node 12a Sent, Missing, Or, A message not received by the downstream node 12b It is possible to determine the cause of the problem.   The downstream node 12a In the downstream node 12b available for receiving data cells The latest number of buffers in Buffer available for data cell transmission downstream With a sign when it must be discontinued due to lack of “No cell loss "Guarantees are enabled using connection-level buffer state management.   To enhance the above protocol with a receiver element buffer sharing mechanism, Link Link level flow control known as level buffer status management is performed for each connection Is added to the flow control. Such link level flow control is performed for each connection. Use link flow control It can be realized without. But, Link flow system for each connection If not, No limit on the number of buffers used by a single connection It will be It is preferable to combine both.   For the following reasons: Link level buffer status management in addition to connection level It is desirable to perform Link-level flow control Resources for each connection Receiver element security that successfully maintains the "cell-free" guarantee obtained by link flow control. Enable the use of shared buffers. By sharing the buffer, Limited number of buffs Key is used most efficiently. Not all connections need to be Because not all quantities are required, RT multiplied by bandwidth for each connection Rather than providing a large number of buffers matching T (round trip time), insect Oh, A small number of buffers are made available at downstream node 12b.   A further advantage of link-level flow control is that Reverse direction increased for each connection Without the need for bandwidth Accurate downstream buffer availability for each connection Is given. Frequent link-level updates Overall connection Does not significantly affect per-action bandwidth.   Referring again to FIG. Link buffer status counter Link_BS_Cou inter40, A cell moving between the upstream node 12a and the downstream node 12b, And Including cells stored in the input buffer in the downstream node 12b, No upstream All cells passing between the node 12a and the element downstream of the downstream node 12b. It is to trace. The above update events related to link flow control for each connection both, The link buffer status counter Link_BS_Counter 40 is Re Link transfer counter Link_Fwd_Counter 56, Or Receive link Communication counter Link_Rx_Counter 46 and link buffer counter Li nk_Buffer_Co link_Tx_Count to the link transmission counter Link_Tx_Count. It is changed during the link update event by subtracting from the value of r44.   The link buffer state limit Link_BS_Limit 42 is Flow control allowed Downstream node 12b to be shared between all of the allowed flow control connections Limit the number of downstream cell buffers shared within In one embodiment, Link bar Buffer status counter 40 and link buffer status limit 42 Both are 20 bits wide It is.   The link transmission counter Link_Tx_Counter 4444 is: Link 14 Keep track of all cells transmitted above. this is, Link buffer status counter L To calculate a new value for the ink_BS_Counter40, Link level Used during update events.   At the downstream node 12b, A set of counters is maintained for each link 14. Re Link buffer limit Link_Buffer_Limit48 is All connections Indicates the maximum number of cell buffers in the downstream node 12b available for use by By doing Link buffer status limit Link_BS_L of upstream node 12a Executes the function of the downstream node 12b similar to the function of the "imit42". In most cases, Re Link buffer status limit Link_BS_Limit 42 is Link buffer limit Matches with Link_Buffer_Limit48. Up based on link width Or the effect of adjusting the number of buffers available below, Specific connection 22 As described above for adjusting the number of available buffers for . The link buffer limit Link_Buffer_Limit48 is This example Is 20 bits wide.   The link buffer counter Link_Buffer_Counter50 is De Downstream node 1 currently used by all connections for storage of data cells Give an indication of the number of buffers in 2b. This value is set to phosphorus (as described below). Transfer counter Link_ Used in test events to correct Fwd_Counter56. Link bag The face counter Link_Buffer_Counter 50 is used in this embodiment. 20 bits wide.   In this embodiment, Link_N2_Limit 52 and Lin having an 8-bit width are used. k_N2_Counter54 is Mixed with connection level update record Used to generate a linked update record. Link_N2_Limit 52 is Determine the threshold number that triggers the generation of link level update records, Link _N2_Counter 54 and Link_Fwd Counter 56 are C Is released from the buffer cell at the downstream node 12b, It is incremented by one. In this example, Link_N2_Limit52 is After first configured , It is static. But, Both are dynamically adjustable based on measured bandwidth. is there.   The link transfer counter Link_Fwd_Counter 56 is Problem link 14 and all cells released from the input queue in the downstream node 12b generated from Trace. that is, In the case of this embodiment, it is 28 bits wide, Link buffer status Used in update event to recalculate counter Link_BS_Counter40 Is done.   The link reception counter Link_Rx_Counter 46 is Link_Fw Used in other embodiments where d_Counter 56 is not used. Link receiver The counter is 28 bits wide, Received over all connections on link 14 Track the number of cells.   Normal data transfer by the upstream node 12a to the downstream node 12b is as follows. Link bar As long as the buffer status counter 40 is below the link buffer limit 42, Link 14 Is allowed over all connections. This exam is The upstream node 12a is More data cells than are believed to be available in the mode 12b. Prevent transmission. This trust will be maintained during the update and inspection events described below. Will be retained.   The data cell is Set both connection-level and link-level buffer limits If not exceeded, it is received by the downstream node 12b. When the limit is exceeded, Cell is Discarded. Link-level update events are: Link_N2_Counter54 When the value of (reaches or exceeds) the value of Link_N2_Limit52, Rin Includes update records. In this example, Link_N2_Limi t52 is set to 40.   Link update report, which is the value obtained from Link_Fwd_Counter 56 The code is Update record for each connection (Fwd_Counter38 value) And the updated cell transferred to the upstream node 12a. In one embodiment, Link_Rx_Counter 46 to Link_Buffer_Count The value obtained by subtracting er50 is It is mixed with the update record for each connection. No update When the node 12a receives an update cell having a link update record, Link_B Update S_Counter40 from the value of Link_Tx_Counter44. Set to the same value as the value obtained by subtracting the code value. Thus, L of the upstream node 12a Ink_BS_Counter40 is Sent by the upstream node 12a, under Set to reflect the number of data cells that have not yet been released at the flow node 12b. Is   Link-level inspection events are: Upstream node 12a for every "W" test cells Including the transmission of a test cell having a value of Link_Tx_Counter44. First In the embodiment of W is equal to 4. The above connection at the downstream node 12b The level inspection function In one embodiment, Inspection record contents Link_Tx_C Link_Buffer_Counter50 and Link from counter44 _Fwd_Counter 56 Link_ by an amount corresponding to the amount obtained by subtracting the sum with 56 This is performed with an increase in the value of Fwd_Counter56. In another embodiment, Link_Rx_Counter46 is Reset to the contents of the inspection record (Link_Tx_Counter44) . Updated Link_Fwd_Counter56 or Link_Rx_Co An update record having a value derived from the value of unter46 is then generated.   Inspection events are: In case of severe transient link failure, Link_Fwd_count Quickly readjust the value of er56 or the value of Link_Rx_Counter46 For, This is performed at the link level in addition to the connection level.   Less than, In an embodiment having 100 connections in one cell, Exemplified An example of the initial value for the counter will be described. The buffer state limit BS_Limit is 20 and The buffer limit Buffer_Limit is 20, N2_Li mit is 3, Link buffer status limit Link_BS_Limit is 10 00, Link_N2_Counter is 40. BS_Limit value is, Match Buffer_Limit value for both connection and link You. BS_Limit and Buffer_Limit are both 20, This phosphorus There are 100 connections in the In the downstream node 12b, Link_BS_ Represented by Limit42 and Link_Nuffer_Limit48 There are only 1000 buffers. The reason is, Buffer pool sharing is phosphorus This is because it is permitted by level feedback.   The above invention, further, N2_Limit34 and Link_N2_Limi Augmenting with a dynamic buffer allocation scheme as described above for t52 It is possible. This scheme is BS_Limit26, Link_BS_Lim it42, Buffer_Limit32 and Link_Buffer_Lim limit parameters like it48, N2_Limit34 and Link_N2 _Limit 52 includes the ability to adjust dynamically. Such adjustments In one embodiment hand, Key characteristics of an individual connection or of an entire link Responds to It is established according to the defined priority scheme of other embodiments. dynamic Buffer allocation is Thus, If buffer resources are limited, One or more Provides the ability to prioritize a connection or link.   Based on all links, As the number of connections in the link increases, Many Since accurate buffer sharing between connections is desirable, Increase the number of connections It is desirable to reduce the Link_N2_Limit 52 in consideration of the above. Conversely And If the number of connections in the link decreases, Relatively small number of connectors The critical state of sharing limited resources between applications is reduced, Link_N 2_Limit 52 may be decreased.   In addition to adjusting the limits for each link, Maximum maintenance bandwidth for connection It is desirable to adjust the limits for each connection to change the width. Dynamic above The assignment scheme is Implemented during link operation based on the performance goals described above.   Having provided a detailed description of the invention, Of the present invention as described in the claims. Without departing from the spirit and scope Various changes, What substitutions and substitutions can be made You need to be careful.

[Procedure of Amendment] Article 184-8, Paragraph 1 of the Patent Act [Submission date] July 21, 1997 (July 21, 1997) [Correction contents]                                The scope of the claims 1. In a method for reducing information loss in a communication network,   A first link coupled to a plurality of output queues from a first node of the network; To a second node of a communication network comprising a plurality of input queues coupled to a switched network. Establishing multiple virtual connections,   Each virtual connection is routed to a first output queue in a first node and to a second node. Associating with a second input queue and a second output queue in the code;   The connection feedback signal of a specific virtual connection Composed of data reflecting the status of the second input queue related to the connection Connected connection feedback signal for each virtual connection. Supplying from the second node to the first node;   Responds to the connection feedback signal related to the virtual connection. Then, for each virtual connection, the first node and the second node Controlling the flow of information between them;   Switch feedback signal for a specific virtual connection Composed of data reflecting the status of the second output queue related to the connection The exchange feedback signal that has been Feeding from the second output queue to the second input queue;   In response to the exchange feedback signal associated with the virtual connection, The second input queue and the second output queue for each virtual connection Controlling the flow of information between. 2. The first link generates a connection feedback signal. The method of claim 1, wherein the additional virtual connection that is not created is communicated. 3. The first link is an additional bar on which no switch feedback signal is generated. The method according to claim 1, wherein the communication is performed. 4. Buffer space shared between at least some of the second input queues Creating at least one pool of   Link feedback signal for a specific buffer space pool is buffer empty Link feedback composed of data reflecting the state of the pool between A signal is sent from the second node to the first node for each pool in the created buffer space. Supplying to the nodes of   Buffer space where the second input queue is associated with a particular link feedback signal The first node and the second node for each virtual connection that shares A specific link by controlling the flow of the first information with the other node. Information is sent between the first node and the second node in response to the feedback signal. Controlling the flow of information. 5. The virtual connection consists of a series of asynchronous transfer mode cells. 5. The method of claim 4, wherein the method is performed. 6. In a communication device for reducing information loss of a communication network,   Receives multiple virtual connections from a signal source, coupled to the network An input link that is operable as   A plurality of input queues associated with one of the virtual connections,   Multiple outputs related to one of the above virtual connections Queue and   Coupled to the input link, the plurality of input queues, and the plurality of output queues Flow control circuit that is The above where the connection feedback signal is associated with a particular virtual connection A first connection buffer composed of data reflecting the state of the input queue. Feedback signal from the communication device for each virtual connection. Data that reflects the state of the output queue for each particular virtual connection. The switch feedback signal configured by the The virtual queue is supplied from the output queue to the input queue for each connection. Each virtual connection depends on the exchange feedback signal associated with the connection. Each time to operate to control the flow of information between the input queue and the output queue. A communication device comprising a operable flow control circuit. 7. Further comprising an output link coupled to at least some of the plurality of output queues. Have   The flow control circuit includes, for each output queue coupled to the output link, a second Receives a connection feedback signal and associates it with the above virtual connection Specific virtual connection according to the second connection feedback signal Controls the flow of information between the output queue and the output link for each application. The communication device according to claim 6, which is operable to operate. 8. Less buffer space shared between at least some of the input queues Has at least one more pool,   The above-mentioned flow control circuit is generated for each pool in the buffer space, and a specific buffer is generated. For the pool in the buffer space, the data reflecting the status of the pool in the buffer space is used. Configured link feedback signal Signal from each of the virtual connectors sharing the pool of buffer space from the communication device. 7. The communication device of claim 6, operable to supply the signal source of the communication device. 9. The virtual connection comprises a series of asynchronous transfer mode cells. Item 9. The communication device according to item 8. 10. A link consists of multiple nodes and links that interconnect nodes. In a communication network operable to reduce information loss,   Each node includes a communication device, and the communication device includes:   (a) coupled to the communication network, comprising one of the plurality of links, Operable to receive a plurality of virtual connections from a first node. Input links,   (b) a plurality of input queues associated with one of the virtual connections,   (C) a plurality of output queues associated with one of the virtual connections,   (d) The input link, the plurality of input queues, and the plurality of output queues A flow control circuit that is coupled to a specific virtual connection Connection feedback signal related to a particular virtual connection A first connection composed of data reflecting the state of the input queue Feedback signal from the communication device for each virtual connection. Supply to the first node and output queue status for each specific virtual connection The exchange feedback signal composed of the reflected data is From the output queue to the input queue for each connection   Exchange feedback signal associated with the virtual connection The input queue and the output queue for each virtual connection And a flow control circuit operable to control the flow of information between the Communication network. 11. Coupled to at least some of the plurality of output queues, and Further comprising an output link consisting of one link of   The flow control circuit includes, for each output queue coupled to the output link, a second Receives a connection feedback signal and associates it with the above virtual connection Specific virtual connection according to the second connection feedback signal Controls the flow of information between the output queue and the output link for each application. 11. The communication network of claim 10, wherein the communication network is operable. 12. A small amount of buffer space shared between at least some of the input queues At least one more pool,   The flow control circuit controls the buffer space for a particular buffer space pool. Link feedback signal composed of data reflecting the state of the pool From the communication device to the first node for each pool in the buffer space. The communication network of claim 10 operable to: 13. The virtual connection is a contract consisting of a series of asynchronous transfer mode cells. The communication network according to claim 12. 14． The communication device comprises one of the links, and Further comprising an output link coupled to at least some of the output queues;   The flow control circuit includes a second control for each output queue coupled to the output link. Receiving the connection feedback signal, In response to the second connection feedback signal related to the For a particular virtual connection, the output queue and the output link 14. A communication network according to claim 13, operable to control the flow of information between. 15. At least some of the above virtual connections have an effective bit rate The communication network according to claim 14, wherein the communication network comprises a connection. 16. At least one pool of buffer space is allocated for the effective bit rate connection. Buffer space shared between all input queues associated with the The communication network according to claim 15, which is configured. 17． In a method for reducing information loss in a communication network,   At least one output key from a first node of the communication network via a first link. At least one second input queue coupled to a switch network coupled to the queue Establishing a virtual connection to a second node of a communication network consisting of:   Each virtual connection is routed to a first output queue in a first node and to a second node. Associated with a second input queue and at least one second output queue in the code And   The connection feedback signal of a specific virtual connection Composed of data reflecting the status of the second input queue related to the connection Connected connection feedback signal for each virtual connection. Supplying from the second node to the first node;   Up on virtual connection in response to connection feedback signal Controlling the flow of information between the first node and the second node;   Data reflecting the status of the second output queue related to the virtual connection The exchange feedback signal composed of Supplying the second output queue to the second input queue each time;   In response to the exchange feedback signal, the virtual connection Information flows between a second input queue and the at least one second output queue. Controlling the key. 18. No connection feedback signal is generated for the first link The method according to claim 17, wherein the additional virtual connection is transmitted. 19. Each of the at least one third node in the communication network from the second node Connection to at least one input queue via at least one second link Establishing a   At least one third node input key associated with the virtual connection; At least one second connector constituted by data reflecting the status of the menu. Application feedback signal for the virtual connection. Supply from each of the third nodes in the one third node to the second node To do,   Responsive to the at least one second connection feedback signal, The second node and the at least one third Controlling the flow of information to and from the node. Law. 20. The at least one third node associated with the virtual connection; Shared between at least one third node input queue that includes a Creating a pool of buffer space to be   The third node buffer space is configured by data reflecting the state of the pool. The link feedback signal from the third node buffer space created. From the at least one third node to the second node Stages and   In response to a particular link feedback signal, the second node and the at least Controlling the flow of information to and from each of the third nodes. 20. The method of claim 19, further comprising: 21. Buffer empty shared between at least some of the second input queues Creating at least one pool between;   The link feedback signal for a pool in a particular buffer space Link feedback composed of data reflecting the state of the pool of space The lock signal is sent from the second node to the second node for each pool in the created buffer space. Supplying to one node;   Buffer space where the second input queue is associated with a particular link feedback signal The first node and the second node for each virtual connection that shares A specific link by controlling the flow of the first information with the other node. Information is sent between the first node and the second node in response to the feedback signal. Controlling the flow of information. 22. In a communication device for reducing information loss of a communication network,   Coupled to the network and operable to receive a virtual connection from a signal source. An input link that can be created,   If the virtual connection described above has multiple input keys related to one input queue, And   A plurality of output queues, wherein said virtual connection is associated with a subset;   Coupled to the input link, the plurality of input queues, and the plurality of output queues Flow control circuit that is The first connection field is composed of data reflecting the status of the power queue. A feedback signal from the communication device to the signal source for each virtual connection. , An exchange consisting of data that reflects the state of each output queue Device feedback signal for the virtual connection From the switch to the input queue and associated with the virtual connection Between the input queue and the output queue subset according to the feedback signal Communication comprising a flow control circuit operable to control the flow of information at the apparatus. 23. An output link coupled to at least one subset of the output queues Have more,   The flow control circuit includes an output cube subset coupled to the output link. A second connection feedback signal is received for each output queue, and the second connection feedback signal is received. The output coupled to the output link in response to a connection feedback signal. Controls the flow of information between each output queue in the power queue subset and the above output links 23. The communication device of claim 22, operable to: 24. Has an input queue, communicates with an output link, and has at least some A destination device having a pool of buffer space shared between input queues. Have   The flow control circuit receives the destination call from the destination device via the output link. A link buffer consisting of data reflecting the status of the destination device buffer pool The communication device of claim 23, operable to receive a feedback signal. 25. At least some, including the input queue associated with the virtual connection Further comprising a pool of buffer space shared between input queues of   The flow control circuit is generated for each pool in the buffer space, Link feedback composed of data reflecting the state of the pool of space From the communication device to the signal source of the virtual connection. 23. The communication device of claim 22, wherein the communication device is operable. 26. In a method for reducing information loss in a communication network,   Via at least one first link, at least one first node of the communication network; From the network to a switch network coupled to at least one output queue A virtual connection to a second node of the communication network comprising a plurality of input queues; Establishing, and   Each virtual connection is connected to a respective node in at least one first node. A first output queue in the second node, a second input queue and a second output in the second node. Relating to each queue in the queue;   Reflected the state of the second respective input queue associated with the virtual connection The connection feedback signal composed of data is Connection to the at least one first node from the second node. Paying,   Up on virtual connection in response to connection feedback signal Controlling the flow of information between at least one first node and said second node; Controlling,   Data reflecting the status of the second output queue related to the virtual connection The exchange feedback signal composed of Supplying the second output queue to the second input queue;   In response to the exchange feedback signal, the virtual connection Controlling the flow of information between a second input queue and the second output queue. A method consisting of 27. The at least one first link includes a connection feedback signal. 27. The method according to claim 26, further comprising transmitting an additional virtual connection in which no signal is generated. . 28. At least one of the second input keys associated with a virtual connection; At least one of the buffer spaces shared between the second input queues Creating a pool,   Link feedback signal for a specific buffer space pool is buffer empty Link feedback composed of data reflecting the state of the pool between The signal is transmitted to the at least one first link and each of the created buffer spaces. Providing from the second node to one of the first nodes for each pool; ,   The one first node and the second node are responsive to the link feedback signal. Controlling the flow of information to and from the other nodes. Method. 29. In a communication device for reducing information loss of a communication network,   Is connected to the communication network and transmits at least one At least one input link through which to receive from the source,   A plurality of subsets of the input queue associated with the virtual connection An input queue,   A plurality of output queues having an output queue associated with the virtual connection When,   The at least one input link, the plurality of input queues, A flow control circuit coupled to the plurality of output queues,   A connector consisting of data reflecting the status of the input queue subset Communication feedback signal from the communication device to the virtual connection. The data supplied to the at least one signal source reflects the status of the output queue. The configured switch feedback signal to the virtual connection. Feeds from the output queue to a subset of the input queues and In response to a traffic signal, the virtual queue A flow control operable to control the flow of information to and from the output queue. A communication device consisting of a control circuit. 30. Further comprising an output link coupled to the output queue;   The flow control circuit includes a second one for an output queue coupled to the output link. Receiving the connection feedback signal of the second connection Information flow between the output queue and the output link in response to the feedback signal. 30. The communication device of claim 29, operable to control 31. At least some of the above, including at least one subset of the input queue Further comprising at least one pool of buffer space shared between input queues ,   The flow control circuit is generated for each pool in the buffer space, Link feedback composed of data reflecting the state of the pool of space The communication signal from the communication device to at least one subset of the input queue. 30. The communication device according to claim 29, operable to supply the signal source.

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), OA (BF, BJ, CF) , CG, CI, CM, GA, GN, ML, MR, NE, SN, TD, TG), AP (KE, LS, MW, SD, S Z, UG), EA (AM, AZ, BY, KG, KZ, MD , RU, TJ, TM), AL, AM, AT, AU, AZ , BB, BG, BR, BY, CA, CH, CN, CU, CZ, DE, DK, EE, ES, FI, GB, GE, H U, IL, IS, JP, KE, KG, KP, KR, KZ , LK, LR, LS, LT, LU, LV, MD, MG, MK, MN, MX, NO, NZ, PL, PT, RO, R U, SD, SE, SG, SI, SK, TJ, TM, TR , TT, UA, UG, UZ, VN (72) Inventor Caldara, Stephen A             Massachusetts, United States             01776, Sudbury, Horse Pond Low             C 220 (72) Inventor Hauser, Stephen A             Massachusetts, United States             01803, Burlington, Farms Dora             Eve 106 (72) Inventors Manning, Thomas A             Massachusetts, United States             01532, Northborough, Summer Street               26th

Claims (1)

[Claims] 1. In a method for reducing information loss in a communication network,   Multiple ingress queues coupled to a switch network coupled to multiple egress queues Via a first link from a first node of the communication network to a second node of the communication network. Transmitting a plurality of virtual connections by using   Each virtual connection is routed to a first output queue in a first node and to a second node. Associating with a second input queue and a second output queue in the code;   The connection feedback signal of a specific virtual connection Composed of data reflecting the status of the second input queue related to the connection Connected connection feedback signal for each virtual connection. Supplying from the second node to the first node;   Responds to the connection feedback signal related to the virtual connection. Then, for each virtual connection, the first node and the second node Controlling the flow of information between them;   Switch feedback signal for a specific virtual connection Composed of data reflecting the status of the second output queue related to the connection The feedback signal of the exchange that has been Feeding from the second output queue to the second input queue;   In response to the exchange feedback signal associated with the virtual connection, The second input queue and the second output queue for each virtual connection Controlling the flow of information between. 2. The first link generates a connection feedback signal. The method of claim 1, wherein the additional virtual connection that is not created is communicated. 3. The first link is an additional bar on which no switch feedback signal is generated. The method according to claim 1, wherein the communication is performed. 4. Buffer space shared between at least some of the second input queues Creating at least one pool of   The link feedback signal for a pool in a particular buffer space Link feedback composed of data reflecting the state of the pool of space The lock signal is sent from the second node to the second node for each pool in the created buffer space. Supplying to one node;   Buffer space where the second input queue is associated with a particular link feedback signal The first node and the second node for each virtual connection that shares A specific link by controlling the flow of the first information with the other node. Information is sent between the first node and the second node in response to the feedback signal. Controlling the flow of information. 5. The virtual connection consists of a series of asynchronous transfer mode cells. 5. The method of claim 4, wherein the method is performed. 6. In a communication device for reducing information loss of a communication network,   Receives multiple virtual connections from a signal source, coupled to the network An input link that is operable as   Multiple input queues associated with the virtual connection,   Multiple output queues associated with the virtual connection,   The input link, the plurality of input queues, and the plurality of outputs A flow control circuit that is coupled to a queue and Connection feedback signal for a particular virtual connection The first is constituted by data reflecting the state of the input queue related to The connection feedback signal is transmitted to the communication device for each virtual connection. Device to the above signal source and output queue status for each specific virtual connection. The exchange feedback signal composed of data reflecting the status For each channel connection, supply from the output queue to the input queue and Depending on the exchange feedback signal associated with the channel connection, each virtual Control the flow of information between the input queue and the output queue for each connection. And a flow control circuit operable to control the communication device. 7. Further comprising an output link coupled to at least some of the plurality of output queues. Have   The flow control circuit includes, for each output queue coupled to the output link, a second Receives a connection feedback signal and associates it with the above virtual connection Specific virtual connection according to the second connection feedback signal Controls the flow of information between the output queue and the output link for each application. The communication device according to claim 6, which is operable to operate. 8. Less buffer space shared between at least some of the input queues Has at least one more pool,   The above-mentioned flow control circuit is generated for each pool in the buffer space, and a specific buffer is The data that reflects the status of the buffer space pool for the buffer space pool The configured link feedback signal is transmitted from the communication device to the buffer space. Operable to supply the above signal source for each virtual connection sharing the pool Noh The communication device according to claim 6. 9. The virtual connection comprises a series of asynchronous transfer mode cells. Item 9. The communication device according to item 8. 10. A link consists of multiple nodes and links that interconnect nodes. In a communication network operable to reduce information loss,   Each node includes a communication device, and the communication device includes:   (a) coupled to the communication network, comprising one of the links, An input resource operable to receive multiple virtual connections from a node. And   (b) a plurality of input queues associated with the virtual connection;   (C) a plurality of output queues related to the virtual connection,   (d) The input link, the plurality of input queues, and the plurality of output queues A flow control circuit that is coupled to a specific virtual connection Connection feedback signal related to a particular virtual connection A first connection composed of data reflecting the state of the input queue; Feedback signal from the communication device for each virtual connection. Supply to the first node and output queue status for each specific virtual connection The exchange feedback signal composed of the reflected data is From the output queue to the input queue for each connection   In response to the exchange feedback signal associated with the virtual connection, Information is exchanged between the input queue and the output queue for each virtual connection. A communication network comprising a flow control circuit operable to control a flow. 11. Coupled to at least some of the plurality of output queues, and Further comprising an output link consisting of one link of   The flow control circuit includes, for each output queue coupled to the output link, a second Receives a connection feedback signal and associates it with the above virtual connection Specific virtual connection according to the second connection feedback signal Controls the flow of information between the output queue and the output link for each application. 11. The communication network of claim 10, wherein the communication network is operable. 12. A small amount of buffer space shared between at least some of the input queues At least one more pool,   The flow control circuit controls the buffer space for a particular buffer space pool. Link feedback signal composed of data reflecting the state of the pool From the communication device to the first node for each pool in the buffer space. The communication network of claim 10 operable to: 13. The virtual connection is a contract consisting of a series of asynchronous transfer mode cells. The communication network according to claim 12. 14． The communication device comprises one of the links, and Further comprising an output link coupled to at least some of the output queues;   The flow control circuit includes a second control for each output queue coupled to the output link. Receiving the connection feedback signal, and A specific virtual connection according to the second connection feedback signal. Controls the flow of information between the output queue and the output link for the 14. The communication network of claim 13, operable to: 15. At least some of the above virtual connections have an effective bit rate The communication network according to claim 14, wherein the communication network comprises a connection. 16. At least one pool of buffer space is allocated for the effective bit rate connection. Buffer space shared between all input queues associated with the 16. The communication network according to claim 15, further comprising: