EP1078482A1 - Noeud central de reseau en boucle a insertion d'initialisation de boucle - Google Patents

Noeud central de reseau en boucle a insertion d'initialisation de boucle

Info

Publication number
EP1078482A1
EP1078482A1 EP99922729A EP99922729A EP1078482A1 EP 1078482 A1 EP1078482 A1 EP 1078482A1 EP 99922729 A EP99922729 A EP 99922729A EP 99922729 A EP99922729 A EP 99922729A EP 1078482 A1 EP1078482 A1 EP 1078482A1
Authority
EP
European Patent Office
Prior art keywords
hub
port
loop
node
data
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.)
Withdrawn
Application number
EP99922729A
Other languages
German (de)
English (en)
Other versions
EP1078482A4 (fr
Inventor
David Brewer
Karl M. Henson
Hossein Hashemi
Greg Scherer
David Baldwin
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Emulex Corp
Original Assignee
Emulex Corp
Priority date (The priority date 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 date listed.)
Filing date
Publication date
Priority claimed from US09/069,765 external-priority patent/US6934546B1/en
Priority claimed from US09/071,275 external-priority patent/US6560205B1/en
Application filed by Emulex Corp filed Critical Emulex Corp
Publication of EP1078482A1 publication Critical patent/EP1078482A1/fr
Publication of EP1078482A4 publication Critical patent/EP1078482A4/fr
Withdrawn legal-status Critical Current

Links

Classifications

    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L12/00Data switching networks
    • H04L12/28Data switching networks characterised by path configuration, e.g. LAN [Local Area Networks] or WAN [Wide Area Networks]
    • H04L12/42Loop networks
    • H04L12/437Ring fault isolation or reconfiguration
    • HELECTRICITY
    • H04ELECTRIC COMMUNICATION TECHNIQUE
    • H04LTRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
    • H04L12/00Data switching networks
    • H04L12/28Data switching networks characterised by path configuration, e.g. LAN [Local Area Networks] or WAN [Wide Area Networks]
    • H04L12/42Loop networks
    • H04L12/427Loop networks with decentralised control
    • H04L12/433Loop networks with decentralised control with asynchronous transmission, e.g. token ring, register insertion

Definitions

  • the present invention relates to electronic network systems, and more specifically to a loop network hub designed such that loop address conflicts are reduced by forcing initialization of the loop upon insertion of a new node port into the loop.
  • Network communication systems are frequently interconnected using network communication systems.
  • Area- wide networks and channels are two approaches that have been developed for computer network architectures.
  • Traditional networks e.g., LAN's and WAN's
  • Channels such as the Enterprise System Connection (ESCON) and the Small Computer System Interface (SCSI), have been developed for high performance and reliability.
  • ESCON Enterprise System Connection
  • SCSI Small Computer System Interface
  • Fibre Channel a new network standard known as "Fibre Channel”.
  • Fibre Channel systems combine the speed and reliability of channels with the flexibility and connectivity of networks.
  • Fibre Channel products currently can run at very high data rates, such as 266 Mbps or 1062 Mbps. These speeds are sufficient to handle quite demanding applications, such as uncompressed, full motion, high-quality video.
  • ANSI specifications such as X3.230-1994, define the Fibre Channel network. This specification distributes Fibre Channel functions among five layers.
  • FC-0 the physical media layer
  • FC-1 the coding and encoding layer
  • FC-2 the actual transport mechanism, including the framing protocol and flow control between nodes
  • FC-3 the common services layer
  • FC-4 the upper layer protocol.
  • Fibre Channel network There are generally three ways to deploy a Fibre Channel network: simple point-to-point connections; arbitrated loops; and switched fabrics.
  • the simplest topology is the point-to-point configuration, which simply connects any two Fibre - 2 -
  • Arbitrated loops are Fibre Channel ring connections that provide shared access to bandwidth via arbitration.
  • Switched Fibre Channel networks are a form of cross-point switching.
  • FC-AL Fibre Channel Arbitrated Loop
  • FIG. 1 A illustrates a conventional loop configuration 100.
  • Four node ports 101, 102, 104, 106 are shown joined together node port to node port. Each node port represents a connection to a device or to another loop.
  • Node port 101 is connected to node port 102 such that data is transmitted from node port 101 to node port 102.
  • Node port 102 is in turn connected to node port 104 which is in turn connected to node port 106.
  • Node port 106 is connected to the first node port, node port 101. In this manner, a loop datapath is established; from node port 100 to node port 102 to node port 104 to node port 106 back to node port 100.
  • FIG. IB illustrates a loop 107 where node ports 108, 110, 112, 114 are organized in a physical star topology with a hub 116 in the center.
  • Node port 108 is connected to a hub port 118 in hub 116 as are node ports 110, 112 and 114 to their own respective hub ports 120, 122, and 124.
  • Internal to hub 116 is a loop, where hub ports 118 - 124 of hub 116 form a loop datapath similar to the conventional loop configuration shown in FIG. 1 A.
  • a hub as a central component to a loop network allows for operation when one or more hub ports are not connected to node ports, or one or more hub ports are connected to node ports which have failed, by bypassing such hub ports.
  • Each hub port typically contains circuitry which provides a bypass mode for the hub - J port. When a hub port is in bypass mode, data received by the hub port from the previous hub port in the loop is passed directly to the next hub port in the loop.
  • node ports may be hot insertable.
  • Hot insertable functionality allows the insertion and removal of node ports from a loop without powering down the entire loop or the hub and then restarting again.
  • the addresses of node ports attached to a loop are not always properly maintained.
  • Loop initialization is invoked under FC-AL protocols by generating a sequence of Loop Initialization Primitive ("LIP") ordered sets.
  • LIP Loop Initialization Primitive
  • a hub port may be connected to a hub port on another hub.
  • hubs When hubs are linked one hub to another through hub ports, sometimes hubs do not properly initiate an initialization routine upon insertion, especially in the case of quiescent hubs (/. e. , no loop traffic at the time of insertion). At this point there is a possibility of address conflicts between the node ports on the first hub and the node ports on the second hub.
  • FIGS. 2 A and 2B Such an address conflict problem is illustrated in FIGS. 2 A and 2B.
  • four node ports Al, Bl, Cl, Dl are linked to a hub 200.
  • Three node ports A2, B2, C2, are connected to a hub 202.
  • the numbers 1 and 2 are illustrative only and in fact the addresses for each node port are still represented by the letter A, B, C, or D.
  • each node port has a unique address within its own loop.
  • the addresses for the node ports are no longer necessarily unique, h the single loop shown in FIG.
  • node ports have address A
  • two node ports have address B
  • two node ports - 4 - have address C.
  • an error is generated which starts an initialization sequence, ultimately resulting in unique addresses for each node port.
  • messages may still continue to pass which are received by incorrect node ports resulting in possible data corruption.
  • FIG. 2 A when node port Bl sends data to node port Al , the hub ports are adjacent and node port Al receives the data from node port B 1 possibly without an error.
  • the connection from node port Bl to node port Al may begin without generating an address conflict because messages from Bl successfully pass along the loop to node port Al, the intended destination, as long as node port B2 was not arbitrating.
  • node port Al attempts to send data to node port Bl
  • data corruption may result.
  • the data is sent from node port A 1 , past node port C 1 , past node port D 1 , and then to node port B 1 , the intended destination.
  • data passes from node port A 1 , past node port C 1 , past node port D 1 , through the hub ports connecting hub 200 and hub 202, past node port C2 and is received by node port B2.
  • the numerals indicate only the difference between node ports from hub 200 and node ports from hub 202.
  • node port B2 is indistinguishable from node port Bl .
  • Node port Al sends data addressed to node port B.
  • node port B2 accepts data which is addressed to node port B.
  • node port B2 receives data addressed to node port B, though node port Al intended the data to be received by node port Bl .
  • "B" is not a unique address.
  • Neither node port Al nor node port B2 is aware of the existence of either node port B2 or node port Al . As a result, depending on the nature of the transaction entered into, data corruption may result. At some point, a proper error may be generated resulting in the initialization sequence. That may be too late, however, to prevent or recover from unwanted data corruption.
  • the inventors have determined that it would be desirable to provide a loop network hub which can provide unique addresses upon insertion of a new node port or a new hub into a loop by forcing the loop to initialize before data corruption occurs. - 5 -
  • a loop network hub of the preferred embodiment includes a hub port with a loop initialization insertion mechanism.
  • the loop initialization insertion mechanism causes a hub port which detects a new connection to automatically begin generating loop initialization data.
  • a hub port continues to generate loop initialization data until that hub port receives a loop initialization sequence.
  • the loop initialization data propagates around the loop of the hub, halting ordinary processing. In this way, the entire loop is cleared.
  • the hub port originating the loop initialization data stops sending the loop initialization data and inserts the new node port into the loop. At this point, loop initialization begins and each node port in the loop network obtains a unique loop network address.
  • a hub of the preferred embodiment includes a hub port with a LIP insertion mechanism.
  • the loop initialization insertion mechanism causes a hub port which detects a new connection to automatically begin generating LIP (F7, F7) ordered sets.
  • the hub port continues to generate LIP (F7, F7) ordered sets until that hub port receives a LIP primitive sequence, where a LIP primitive sequence includes three consecutive identical LIP ordered sets.
  • the LIP (F7, F7) ordered sets propagate around the loop of the hub, halting ordinary processing. In this way, the entire loop is cleared.
  • the hub port originating the LIP (F7, F7) ordered sets stops inserting LIP (F7, F7) ordered sets and inserts the new node port into the loop.
  • LIP Arbitrated Loop Physical Address
  • FIG. 1 A shows a prior art node port to node port loop.
  • FIG. IB shows a prior art loop including a hub.
  • FIG. 2A shows two separate prior art loops.
  • FIG. 2B shows two prior art loops connected to form a single loop.
  • FIG. 3 shows a loop including a hub.
  • FIG. 4 shows a block diagram of a hub port according to the preferred embodiment.
  • FIG. 5A shows a hub with two node ports.
  • FIG. 5B shows a hub with three node ports.
  • FIG. 6A shows two separate loops including hubs.
  • FIG. 6B shows two loops including hubs connected by hub ports.
  • the preferred embodiment provides a mechanism to force loop initialization upon insertion of a node port into a loop network.
  • FC-AL Fibre Channel Arbitrated Loop
  • FIG. 3 shows a hub 300 with six hub ports 302, 304, 306, 308, 310, and 312.
  • Each hub port is connected to another hub port with a unidirectional internal hub link forming an internal hub loop.
  • data flows from hub port 302 to hub port 304 and so on in a counter clockwise manner.
  • hub ports may be connected such that data flows in a clockwise direction so long as the loop topology is maintained.
  • Attached to three hub ports 302, 310, 312, are three node ports 314, 316, 318.
  • Node port 314 is attached to hub port 302
  • node port 316 is attached to hub port 312
  • node port 318 is attached to hub port 310.
  • Each node port is preferably attached to a hub port by two data channels: one data channel sends data from the - 7 - hub port to the node port, one data channel sends data from the node port to the hub port.
  • a data channel carries data from hub port 302 to node port 314 and another data channel carries data from node port 314 to hub port 302.
  • Data from node port 314 to be received by node port 316 passes from node port 314 through a data channel to hub port 302, then from hub port 302 to hub port 306, then to hub port 306, to hub port 308, to hub port 310. If node port 318 is operating in the loop, the data passes through a data channel to node port 318 and back through a data channel to hub port 310, and then passes to hub port 312. The data passes through a data channel from hub port 312 and is received at node port 316. In the preferred embodiment, incoming data entering a hub port from the previous hub port in the loop is sent to the node port connected to the hub port, if present.
  • the hub port is in bypass mode, the incoming data is sent directly from the hub port to the next hub port in the loop without including any data from the node port in response to the incoming data.
  • the preferred embodiment uses a switching device such as a multiplexer to accomplish this bypass, as described below with reference to FIG. 4.
  • the attached node port recognizes whether the data received from the hub port is addressed to that node port or not and responds appropriately.
  • the bypass is accomplished in the hub port, however, not in the node port. Thus the loop is protected from node port failures.
  • a hub port which has no attached node port, such as hub ports 304, 306 or 308 shown in FIG. 3, is always in bypass mode and passes any data directly to the next hub port.
  • hub port 302 received by hub port 304 is passed directly to hub port 306.
  • hub port 306 When a hub port with an attached node port, such as hub port 310, 312, or 302 as shown in FIG. 3, receives data from the previous hub port on the loop, the hub port passes the data to the attached node port. The node port responds appropriately and passes the data back to the hub port.
  • hub port 312 passes the data to node port 316, if node port 316 is not bypassed. Node port 316 recognizes that the data is not addressed to node port 316 and so passes the data back to hub port - 8 -
  • Hub port 312 passes the data to hub port 302.
  • Hub port 302 passes the data to node port 314, if node port 314 is not bypassed. Node port 314 recognizes the data is addressed to node port 314 and responds appropriately.
  • FIG. 4 illustrates internal components of a hub port according to the preferred embodiment.
  • a hub port 400 as shown in FIG. 4 is equivalent to hub ports 302, 304, 306, 308, 310, and 312 shown in FIG. 3.
  • An incoming internal hub link 402 enters hub port 400 from a previous hub port in the loop (not shown).
  • Incoming internal hub link 402 is connected to a hub port transmit circuit 404.
  • Hub port transmit circuit 404 sends the data received through a data channel 406 out to a node port 408 after converting the data into a form usable by node port 408.
  • data channel 406 may be connected to a hub port in a different hub, allowing interconnection hub to hub.
  • Node port 408 outputs data to hub port 400 via a data channel 410.
  • Data channel 410 is connected to a hub port receive circuit 412.
  • Hub port receive circuit 412 converts data received from node port 408 into a form usable inside the hub.
  • hub port receive circuit 412 converts data from serial to parallel and decodes the data.
  • Hub port receive circuit 412 also includes a loop initialization data detect circuit 414 and a hub port output control circuit 416.
  • the loop initialization data detect circuit 414 is a LIP detect circuit.
  • Hub port receive circuit 412 outputs data via a hub port output line 418.
  • Hub port output control circuit 416 outputs control signals via a hub port output control line 420.
  • Hub port output line 418 is connected to a first input A of a switching device 422, such as a multiplexer. Incoming internal hub link 402 is connected to a second input B of switching device 422.
  • a loop initialization data generator 424 generates loop initialization data and outputs those ordered sets to a loop initialization data line 426.
  • loop initialization data generator 424 is a LIP generator and generates LIP (F7, F7) ordered sets.
  • Loop initialization data line 426 is connected to a third input C of switching device 422.
  • Hub port output control line 420 is connected to a control input of switching device 422.
  • switching - 9 - device 422 selects a single input A, B, or C to be output depending upon the control signal generated by hub port output control circuit 416.
  • the output of switching device 422 is sent to outgoing internal hub link 428.
  • Outgoing internal hub link 428 passes data to the next hub port in the hub in the same manner that internal hub link 402 passes into hub port 400, forming a loop as shown in FIG. 3.
  • hub port output control circuit 416 holds hub port 400 in bypass mode.
  • data received from the previous hub port on incoming internal hub link 402 is output to outgoing internal hub link 428.
  • bypass mode data on incoming internal hub link 402 enters input B of switching device 422 and is output unchanged onto outgoing internal hub link 428 to be passed to the next hub port in the loop (not shown).
  • hub port 400 If, however, an operational device, such as an FC-AL NL_Port or loop segment, is attached to hub port 400, represented by node port 408, data received from node port 408 by hub port receive circuit 412 is sent to the next hub port along outgoing internal hub link 428.
  • hub port output control circuit 416 selects input A of switching device 422 via hub port output control line 420.
  • hub port receive circuit 412 detects the reception of data from node port 408 and ends bypass mode (where input B of switching device 422 is selected). Data received from node port 408 is inserted onto the loop by selecting input A of switching device 422. The data received by hub port receive circuit 412 from node port 408 is immediately passed along to the next hub port via outgoing internal hub link 428.
  • this immediate insertion into the loop of a new device or hub may generate address conflicts and lead to undesirable data corruption.
  • the preferred embodiment provides a loop initialization insertion mechanism.
  • hub port receive circuit 412 detects that new device or hub by detecting the reception of formatted data along data channel 410 where previously - 10 - there was no data.
  • hub port output control circuit 416 selects input C of switching device 422.
  • Loop initialization data generator 424 generates a constant stream of loop initialization data which indicates to other hub ports in the loop that a new device or hub has been attached. Other hub ports in the loop upon receiving a loop initialization sequence pass the sequence along.
  • a loop initialization sequence is a specified combination of loop initialization data.
  • a LIP primitive sequence consists of three consecutive identical LIP ordered sets of the same type. In this way, the processing of transactions on the loop stops and each hub port begins to pass along or generate loop initialization data.
  • Loop initialization data generator 424 repeatedly generates loop initialization data, preferably in coordination with the frame sequence appropriate to the loop network.
  • Hub port output control circuit 416 continues to select input C of the hub port switching device 422 until loop initialization data detect circuit 414 detects a loop initialization sequence received from node port 408.
  • Node port 408, as described above, receives signals from incoming internal hub link 402 via hub port transmit circuit 404. The selection of inputs on switching device 422 does not affect the reception of data by node port 408 because switching device 422 controls the output of hub port 400 onto the loop, not the input from the loop.
  • the loop initialization data is LIP (F7, F7) ordered sets.
  • LIP (F7, F7) ordered sets are preferably in the form (K28.5 D21.0 D23.7 D23.7), compliant with FC-AL protocols.
  • a loop initialization sequence generated from a previous port in the loop enters hub port 400 on incoming internal hub link 402 and is sent to node port 408 through hub port transmit circuit 404.
  • Node port 408 sends the loop initialization sequence to hub port receive circuit 412.
  • Loop initialization data detect circuit 414 detects the loop initialization sequence.
  • hub port output control circuit 416 switches from selecting input C of switching device 422 to selecting input A of switching device - 1 1 -
  • a LIP detect circuit 414 generates an affirmative detection signal upon detecting any LIP primitive sequence, not necessarily the same LIP (F7, F7) primitive sequence.
  • the detected LIP primitive sequence does not need to be from the same hub port as originally began the LIP (F7, F7) ordered set generation from detecting a new device or hub.
  • the node port passes some of the loop initialization data back to the hub port.
  • the hub port passes along data from the node port (by selecting input A of the switching device as shown in FIG. 4)
  • loop initialization is forced upon attachment of a new operational device or a new hub to an existing hub.
  • the generation and propagation of loop initialization sequences halts ordinary loop operation and begins loop initialization.
  • loop initialization is desirable upon connection of a new device or upon connection of a second loop to a first loop because the loop initialization process is an assured way under network protocols such as FC-AL protocols to assign each device on the newly established loop a unique physical address.
  • FIG. 5 A and 5B illustrate an example of inserting an operational device in a loop according to a preferred embodiment.
  • FIG. 5 A illustrates a loop and components before the new device is inserted.
  • a hub 500 has four hub ports 502, 504, 506, 508. As shown in FIG. 5A, hub 500 has only four hub ports, however, hubs may have more or less hub ports. The number of hub ports shown in FIG. 5 A is for illustrative purposes only. Hub ports 502, 504, 506, 508, are connected to one another by internal hub links to form a loop. Two node ports 510, 512 are attached to hub ports 502, 508, respectively. Data from node port 510 to node port 512 flows through a data channel into hub port 502.
  • Hub port 502 outputs the data along the internal hub link to hub port 504.
  • Hub port 504 does not have an attached operational device and - 12 - so is in bypass mode.
  • hub port 504 passes the data from hub port 502 along the internal hub link to hub port 506.
  • Hub port 506 is also in bypass mode and so passes the data along the internal hub link to hub port 508.
  • Hub port 508 has an operational device attached at node port 512 and so is not in bypass mode.
  • data from node port 512 to be sent to node port 510 passes through a data channel to hub port 508 and passes along the internal hub link to hub port 502.
  • Hub port 502 sends the data along a data channel to node port 510. In this way, hub ports 502 - 508 and hub 500 operate to maintain a loop topology.
  • Node port 514 is attached to hub port 504.
  • Hub port 504 detects the new node port 514 from the presence of data incoming to hub port 504 in a particular formation of data. Upon detecting node port 514, hub port 504 does not immediately pass along data from node port 514. Hub port 504 synchronizes timing and frames with data from node port 514 and validates the proper operation of the node port 514.
  • hub port 504 begins to send loop initialization data (e.g., LIP (F7, F7) ordered sets) along the internal hub link by selecting an input of a switching device inside of hub port 504 which corresponds to a loop initialization data generator.
  • the loop initialization data passes along the internal hub link to hub port 506.
  • Hub port 506 is in bypass mode because no node port is attached to hub port 506. Hence, the loop initialization data passes along the internal hub link to hub port 508.
  • Hub port 508 passes the loop initialization data to node port 512, if node port 512 is not already bypassed.
  • the operational device attached to node port 512 preferably responds to the loop initialization data and node port 512 passes the loop initialization data back to hub port 508. Because the operational device attached to node port 512 generates a proper response to the loop initialization data, in the preferred embodiment hub port 508 selects the signal received from node port 512 to pass along the internal hub link of hub 500.
  • a hub port such as hub port 508, which is attached to an operational device through a node port, passes along the loop - 13 - initialization data received from the node port by selecting input A of the hub port switching device as shown in FIG. 4.
  • the loop initialization data is preferably passed along the internal hub link to the next hub port.
  • hub port 508 passes the loop initialization data to hub port 502.
  • Hub port 502 follows a similar process as hub port 508 because hub port 502 also has an operational device attached, represented by node port 510. Accordingly, the loop initialization data passes from hub port 502 to hub port 504.
  • Hub port 504 receives the loop initialization data and transmits the loop initialization data to node port 514, if node port 514 is not already bypassed.
  • Node port 514 passes the loop initialization data back to hub port 504, similar to node ports 512 and 510.
  • the loop initialization data detect circuit (414 as shown in FIG. 4) in the hub port receive circuit of hub port 504 detects the loop initialization data.
  • Hub port 504 stops outputting loop initialization data when a loop initialization sequence has been received.
  • hub port 504 may have received the loop initialization sequence which originated at hub port 504.
  • hub port 504 ceases outputting loop initialization data upon detecting a loop initialization sequence from any source.
  • a hub port stops outputting LIP (F7, F7) ordered sets upon detecting a LIP primitive sequence of any type.
  • the hub port transmit logic detects a loop initialization sequence received along the internal hub link and does not necessarily wait for a response from the connected node port. In either case, hub port 504 switches from outputting loop initialization data (through selecting input C of the switching device as shown in FIG.
  • FIG. 6A and 6B illustrate the connection of one hub loop to a second hub loop. In general, the process is similar to that illustrated in FIG. 5A and 5B for the insertion of a new operational device to a single hub loop.
  • FIG. 6 A shows a first hub 600 with six hub ports 602, 604, 606, 608, 610, 612. Three node ports 614, 616, and 618 are connected to hub ports 602, 604, and 606, respectively.
  • a second hub 620 also has six hub ports 622, 624, 626, 628, 630, - 14 -
  • Three node ports 634, 636, and 638 are connected to three hub ports 622, 624, and 626, respectively.
  • the hub ports of each hub are connected in a loop.
  • FIG. 6B illustrates the connection of hub 600 to hub 620.
  • a pair of data channels connect hub port 608 to hub port 632.
  • One data channel carries data from hub port 608 to hub port 632.
  • One data channel carries data from hub port 632 to hub port 608.
  • the new circular datapath among hub ports has the following pattern: hub port 608 to 610 to 612 to 602 to 604 to 606 back to 608, then to hub port 632 to 622 to 624 to 626 to 628 to 630 back to 632, then back to hub port 608, completing the circle.
  • hub port 608 When data enters hub port 608 from hub port 606, the data passes through a transmit circuit of hub port 608 (recall FIG. 4) and then out through the data channel to hub port 632. The data has not yet entered a receive circuit of hub port 608, and does not until the data returns from hub port 632. In this way, data flows in a circular pattern through two hubs and the two previously physically distinct loops operate as one virtual loop.
  • Hub port 608 detects the connection to hub port 632 of hub 620 through the new reception of properly formatted data. Upon detection of hub port 632, hub port 608 follows the procedure as defined above for detection of a new device. Hub port 608 selects a loop initialization data generator internal to hub port 608 and outputs loop initialization data along the hub loop. Accordingly, loop initialization data passes from hub port 608 to hub port 610. Hub port 610 is in bypass mode because there is no node port attached to hub port 610.
  • Hub port 610 passes the loop initialization data along to the next hub port, and the process continues as described above with respect to FIG. 5B.
  • hub port 632 detects the connection to hub port 608 of hub 600.
  • hub port 632 selects a loop initialization data generator internal to hub port 632 and outputs loop initialization data onto the hub loop of hub 620. - 15 -
  • each of hub ports 608 and 632 are generating loop initialization data which is being passed along the loop.
  • the loop initialization data from hub port 608 passes from hub port 608, to 610, to 612, to 602, to node port 614 (if node port 614 is not bypassed), to hub port 602, to 604, to node port 616 (if node port 616 is not bypassed), to hub port 604, to 606, to node port 618 (if node port 618 is not bypassed), to hub port 606, and back to 608.
  • hub port 608 does not detect the loop initialization data because the loop initialization data detection circuit of hub port 608 is in the hub port receiving circuit of hub port 608.
  • the loop initialization data received along the internal hub link from hub port 606 is in the hub port transmit circuit of hub port 608. Accordingly, the loop initialization data passes to hub port 632.
  • Hub port 632 receives the loop initialization data in its hub port receiving circuit and detects the loop initialization data using its loop initialization data detection circuit.
  • hub port 632 changes the selection of input on the internal switching device of hub port 632 so that loop initialization proceeds.
  • hub port 608 receives the loop initialization data generated by hub port 632 which passed along the internal hub link of hub 620 and eventually from hub port 632 to hub port 608.
  • the loop initialization data detect circuit in the hub port receiving circuit of hub port 608 detects the loop initialization sequence, ends the bypass, and begins loop initialization processing according to standard FC-AL protocols.
  • both hub ports 608, 632 begin loop initialization processing.
  • the handling of loop initialization is conventionally understood and defined according to network protocols, such as FC-AL protocols.
  • the technique is still effective if one of the interconnected hubs is a conventional hub, so long as at least one hub in the loop operates according to the present invention. - 16 -

Abstract

L'invention concerne un noeud central (400) de réseau en boucle comprenant un accès de noeud central équipé d'un mécanisme d'insertion d'initialisation de boucle. Par ce mécanisme, un accès de noeud central (400) décelant une nouvelle connexion d'accès de noeud central fournit automatiquement des données d'initialisation de boucle. L'accès en question (400) continue à fournir les données considérées jusqu'au moment où il (400) reçoit une séquence d'initialisation de boucle. Les données d'initialisation de boucle sont transmises le long de la boucle du noeud central, interrompant le traitement normal. Ainsi, la boucle entière est libérée. A la réception d'une séquence d'initialisation de boucle, l'accès de noeud central qui est à l'origine des données d'initialisation de boucle insère le nouvel accès de noeud dans la boucle. Dès lors, l'initialisation de boucle est lancée et chaque accès de noeud (408) dans le réseau en boucle dispose d'une adresse de réseau en boucle unique.
EP99922729A 1998-04-30 1999-04-26 Noeud central de reseau en boucle a insertion d'initialisation de boucle Withdrawn EP1078482A4 (fr)

Applications Claiming Priority (4)

Application Number Priority Date Filing Date Title
US09/069,765 US6934546B1 (en) 1998-04-30 1998-04-30 Method and apparatus for control of soft handoff usage in radiocommunication systems
US69765 1998-05-01
US09/071,275 US6560205B1 (en) 1998-05-01 1998-05-01 Method and apparatus for control of soft handoff usage in radiocommunication
PCT/US1999/008986 WO1999057827A1 (fr) 1998-04-30 1999-04-26 Noeud central de reseau en boucle a insertion d'initialisation de boucle

Publications (2)

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US7242941B2 (en) * 2003-05-16 2007-07-10 Motorola, Inc. Method and apparatus for performing soft-handoff in a wireless communication system
US7460855B2 (en) * 2003-06-03 2008-12-02 Microsoft Corporation Selective pre-authentication to anticipated primary wireless access points
FR2897499A1 (fr) * 2006-02-13 2007-08-17 France Telecom Procede d'allocation d'au moins d'un point d'acces a un terminal mobile, dans un reseau cellulaire, terminal, serveur de mobilite et programme correspondants
CN101184325B (zh) * 2006-11-14 2011-08-24 联想(北京)有限公司 通信系统中的切换方法及终端
CN110198183B (zh) * 2019-06-25 2022-05-17 Oppo广东移动通信有限公司 天线切换方法及相关设备

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CA2329950C (fr) 2004-11-02
CN1153499C (zh) 2004-06-09
CA2329950A1 (fr) 1999-11-11
EP1078482A4 (fr) 2005-05-04
CN1298619A (zh) 2001-06-06

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