RU2360377C2 - Double connection method - Google Patents

Abstract

FIELD: communications.

SUBSTANCE: technical outcome is achieved due to realisation of double connection, which involves: setting up each of the two sets of main control equipment as reserve for each other and connecting a network object, belonging to one of the two sets of main control equipment, to two sets of main control equipment through a main channel and a standby channel, respectively; setting up the main channel, connected to the main control equipment, as active, and setting up the standby channel, connected to the main control equipment, as inactive; determination of whether the main control equipment, corresponding to the main channel, is out of service; if the main control equipment, corresponding to the main channel, is out of service, the standby channel is activated.

EFFECT: increased reliability of the network.

65 cl, 15 dwg

Description

The text of the description is given in facsimile form.

Claims (70)

1. A method for implementing dual connectivity, comprising the steps of:
configure each of the two elements of the main control equipment as a backup for the other main control equipment and connect the network object belonging to one of the two sets of the main control equipment with two sets of the main control equipment, respectively, the main channel and the backup channel;
configure the main channel connected to the main control equipment as active, and turn off the backup channel connected to the main control equipment;
determining whether the main control equipment corresponding to the main channel is out of service; if the main control equipment corresponding to the main channel is out of service, the backup channel is activated, and then it is established whether the out-of-service main control equipment is restored; if the out-of-service main control equipment is restored, the backup channel is turned off and the main channel is activated;
return to determine if the main control equipment corresponding to the main channel is out of service. 2. The method according to claim 1, in which additionally: configure the main channel as inactive when the backup channel is activated. 3. The method according to claim 1, additionally containing steps:
configure the main alarm point and the backup alarm point in each set of the main control equipment, as backup for each other, respectively, and the main alarm point of one main control equipment corresponds to the backup signaling point of the other main control equipment; moreover
the step of activating the backup channel when it is established that the main control equipment corresponding to the main channel is taken out of service, includes activating the backup alarm point and turning off the main alarm point when the backup channel is activated. 4. The method according to claim 1, additionally containing steps:
configure the main alarm point and the backup alarm point in each set of the main control equipment, as backup for each other, respectively, and the main alarm point of one main control equipment corresponds to the backup signaling point of the other main control equipment; moreover, the step of transferring the backup channel to the inactive state, when it is established that the main control equipment located outside the service is restored, contains:
setting up the backup alarm point as inactive and activating the main alarm point when the backup channel is switched to inactive. 5. The method according to any one of claims 1 to 4, in which the main control equipment is a server of the Mobile Switching Center (MSC); and the network object is any equipment from the following list: Base Station Controller (BSC), Radio Network Controller (RNC), Home Location Register (HLR), Public Switched Telephone Network (PSTN)) , Service Management Point (TUU (SCP) and CCMS (MSC). 6. The method according to any one of claims 1 to 4, in which the main control equipment is a MSC server (MSC), the network object is a BSC (BSC), further comprising a step: connecting the BSC (BSC) with two MSC servers, respectively via Media Gateway (МШ (MGW)). 7. The method according to claim 6, in which the MG (MGW) is configured with a signaling gateway, the MSC server (MSC) serves as the Application Service Station (SOP) associated with the signaling point of the signaling gateway through an agent mode or a transmission mode using a protocol Adaptation of user level 3 of the messaging subsystem. 8. The method according to any one of claims 1 to 4, in which two elements of the main control equipment are software switches, and the network object includes a media resource server, application server, PSTN (PSTN), integrated home location register, TUU (SCP). 9. The method according to any one of claims 1 to 4, in which the main control equipment is a software switch, the network object is PSTN (PSTN), and the method further comprises: connecting the PSTN (PSTN), respectively, with two program switches through the MG (MGW). 10. The method according to claim 9, in which the MG (MGW) is configured with a signaling gateway, the software switch serves as one SOP (ASP) associated with the signaling point of the signaling gateway through agent mode or transfer mode using a subsystem level 3 user adaptation protocol messaging. 11. The method according to claim 1, in which the network object is a signaling gateway, further comprising steps:
configure the first code of the outgoing point (instrumentation (OPC)), respectively, in the first and second main control equipment, backup for each other;
connect all the signal gateways that will interact with the first instrumentation (OPC), respectively, with the first instrumentation (OPC) of the first and second main control equipment, and for each signal gateway, the priority of the first connection connecting the signal gateway with the first instrumentation (OPC) of the first main control equipment higher than the priority of the second connection connecting the signaling gateway to the first instrumentation (OPC) of the second main control equipment;
upon receipt of a signal message whose destination is the first instrumentation (OPC), each signaling gateway determines whether the first connection with a higher priority can be used; if the first connection with a higher priority can be used, then an alarm is exchanged with the first instrumentation (OPC) of the first main control equipment through the first connection; otherwise, exchange the alarm with the first instrumentation (OPC) of the second main control equipment through the second connection. 12. The method according to claim 11, further comprising steps:
install the second instrumentation (OPC), respectively, in the first and second main control equipment, backup for each other, and configure the first and second instrumentation (OPC) of each main control equipment as equipment mutual assistance;
moreover, the first connection is a direct route between the signaling point of the signaling gateway and the first instrumentation (OPC) of the first main control equipment;
and the second connection is an indirect route between the signaling point of the signaling gateway and the first instrumentation (OPC) of the second main control equipment through the transit of the second instrumentation (OPC) of the second main control equipment. 13. The method according to item 12, in which the exchange of alarm with the first instrumentation (OPC) of the second main control equipment through the second connection contains the steps:
the signaling gateway sends upward signaling messages to the second instrumentation (OPC) of the second main control equipment on an indirect route with lower priority; the second instrumentation (OPC) sends upward signaling messages to the first instrumentation (OPC) of the second main control equipment;
the first instrumentation (OPC) of the second main control equipment sends downlink signaling messages to the second instrumentation (OPC) of the second main control equipment, the second instrumentation (OPC) sends downlink signaling messages to the signaling gateway. 14. The method according to claim 11, further comprising steps: while receiving signal messages from the first instrumentation (OPC) of the first and second main control equipment, the signal gateway receives a signal message from the first connection with a higher priority and rejects the signal message from the second connection with a lower priority according to connection priorities. 15. The method according to claim 1 or 11, in which two elements of the main control equipment are the first main control equipment and the second main control equipment, and a method further comprising steps:
the first main control equipment receives data and the state of the second main control equipment;
the first main control equipment processes the services of the second main control equipment using the data of the second main control equipment according to the state of the second main control equipment. 16. The method according to clause 15, in which the first main control equipment receives the state of the second main control equipment through the acknowledgment mechanism. 17. The method according to clause 15, in which the state of the second main control equipment contains a normal state and a state outside of service; and the step of processing the first main control equipment of the services of the second main control equipment using the data of the second main control equipment according to the state of the second main control equipment further comprises the steps:
if the second main control equipment is in a normal state, then the first main control equipment receives data of the second main control equipment;
if the second main control equipment is out of service, the first main control equipment takes over the services of the second main control equipment according to the data of the second main control equipment. 18. The method according to 17, in which:
the step of taking over the services of the second main control equipment by the first main control equipment according to the data of the second main control equipment contains the steps:
the first main control equipment configures the services associated with the second main control equipment according to the data of the second main control equipment;
performance of established services in the first main control equipment. 19. The method according to 17, in which the processing step of the first main control equipment of the services of the second main control equipment using the data of the second main control equipment according to the state of the second main control equipment further comprises:
if the second main control equipment changes from an out-of-service state to a normal state, then the first main control equipment returns the services of the second main control equipment to the second main control equipment. 20. The method according to claim 19, in which the step of returning the first main control equipment services of the second main control equipment to the second main control equipment contains the steps:
the first main control equipment disconnects the connections for services associated with the second main control equipment according to the second main control equipment;
the first main control equipment receives data of the second main control equipment. 21. The method according to clause 15, in which:
data with the identification of other equipment is left unprocessed when the first main control equipment is connected. 22. A method for implementing dual connectivity, comprising the steps of:
configure each of the two Media Gateway Control Function (MGCF) objects as a backup for another Media Gateway (MGCF), with each MGCF managing at least one Media Gateway (MGW);
establish whether the MSH (MGW) should be registered in the standby FMSh (MGCF),
if the MGW is to be registered in the standby FMSh (MGCF), then upon detecting the registration of a new MSH (MGW), the standby FMSH (MGCF) activates or sets all signaling channels associated with the MG (MGW) and updates the called party route information;
if the MSh (MGW) should not be registered in the standby FMSh (MGCF), they again return to the step of establishing whether the MSh (MGW) should be registered in the standby FMSh (MGCF). 23. The method according to item 22, which before the standby FUMS (MGCF) detects the registration of a new MSH (MGW), further comprises the steps: the main FUMS (MGCF) again turns off or blocks the signaling channels associated with the MS (MGW) requiring Registration
and while the standby FUMS (MGCF) updates the called party route information, the main FMS (MGCF) updates the called party route information. 24. The method according to item 23, in which the step of updating the information about the route of the called party contains the steps:
the main FMMS (MGCF) changes the inter-office call associated with the newly registered MS (MGW), in the route information of the called party to the inter-office call;
the standby MFCH (MGCF) changes the call between the MGs (MGWs), with the exception of the newly registered MHs (MGWs) and the newly registered Msgs (MGWs) in the called party’s routing information to the in-house call. 25. The method according to item 23, in which the signaling channels that are associated with the MG (MGW), requiring a new registration, and are turned off or blocked by the main FMSh (MGCF) - this is the connection of signaling channels associated with the MS (MGW), or signaling channels Associated only with the MG (MGW). 26. The method according to item 22, in which the step of activating or establishing a backup FMSh (MGCF) of all signaling channels associated with the MS (MGW), upon detecting the registration of a new MS (MGW) contains the steps:
for channels routed to the standby FUMS (MGCF) from other equipment, the standby FUMS (MGCF) activates or actively establishes the signaling channels associated with the MG (MGW), after successfully registering the control interface of the MG (MGW) gateway MS (MGW). 27. The method according to item 22, in which the step of activating or establishing a backup FMSh (MGCF) of all signaling channels associated with the MS (MGW), upon detecting the registration of a new MS (MGW) contains the steps:
for inter-station signaling, the standby FMSh (MGCF) interacts directly with the external standby FMSh (MGCF), actively opening the signaling channels associated with the MG (MGW), after successfully registering the control interface of the MS (MGW) of the gateway MS (MGW). 28. The method according to paragraphs 22 and 23 or 26, in which the signaling channels are channels directed to the standby FMSh (MGCF) from the MS (MGW) or the signaling gateway, the signaling channel may be one of the following:
channel of the protocol for adapting users of level 2 of the subsystem for transmitting messages, channel of the protocol for adapting users of version 5 of the channel access protocol, channel of the protocol for adapting users of version 5 of the channel access protocol, channel of the protocol for adapting users of Q.921 digital network with integration of services, channel of the subsystem of applications for the wireless access network base station application subsystem channel. 29. The method according to paragraphs 22 and 23 or 27, in which the signaling channels are inter-station signaling, which FUMSH (MGCF) directly exchanges with the outside world; inter-station signaling is either call control signaling independent of the transmission channel, or signaling of the session initiation protocol, or signaling No. 7. 30. The method according to item 22, in which each FMSh (MGCF) corresponds to KMSh (MGC), further comprising steps:
configure the MGS (MGW) gateways so that they can be controlled by each LMS (MGC), configure the LMS (MGC) that controls the LMS (MGW) as the local LMS gateway (MGC) of the MGW and configure each of the two LMS (MGC) which control different MSs (MGWs) as backup KMSs (MGCs) for each other;
The MSH (MGW) periodically sends a clock pilot to the current local CMC (MGC) while in a normal operating state, and monitors the heartbeat that returns the local CMC (MGC); if the local LMS (MGC) returns a normal clock pilot, then the LMS (MGW) constantly periodically sends a clock to the current local LMS (MGC), in the normal operating state, and monitors the clock signal returned by the local LMS (MGC); if the local LMS (MGC) does not return a normal clock pilot, then initiates a dual-connect switch to the local LMS (MGC) standby LMS (MGC) and sets the standby LMS (MGC) as the current local LMS (MGC) after switching carried out as part of a dual connection, while the MG (MGW) periodically constantly sends a clock control signal to the current local LMS (MGC), while in normal operating condition. 31. The method of claim 30, further comprising: each CMS (MGC), upon initialization, sets up an MS list (MGW), this list being used to record all the CMS (MGCs) managed by the CMS (MGC);
The switching performed as part of the dual connection contains:
MSH (MGW), requiring a switch performed as part of a dual connection, transmits a registration request to the CMC (MGC) of the destination of this switch as part of a dual connection;
upon receipt of the registration request sent by the MSH (MGW), the MSH (MGC) of the destination determines whether the MSH (MGW) is in its list of MSs (MGW), if the MSH (MGW) is in the list of MSHs (MGW) organized by the MSH ( MGC) then accepts the registration request and establishes a connection with the MG (MGW); otherwise, rejects the registration request. 32. The method according to clause 30, further comprising the steps of: KMSh (MGC) sends a clock pilot to the backup KMSH (MGC) according to the schedule and monitors the clock pilot sent by the backup KMSh (MGC); at the same time KMSh (MGC) has two types of normal operating states:
an inactive state of mutual assistance and an activated state of mutual assistance;
when it detects an interruption in the clock of the pilot signal sent by the MSC (MGC) of mutual assistance, the MSC (MGC) in an inactive state of mutual assistance switches to an activated state of mutual assistance from an inactive state of mutual assistance;
upon detecting a normal clock pilot sent by the mutual assistance CMS (MGC), the MGC in the activated mutual assistance state switches to the inactive mutual assistance state from the activated mutual assistance state. 33. The method according to p, optionally containing steps:
if upon recovering from an out-of-service state, it is found that the clock pilot sent from the mutual assistance LMS (MGC) is normal, then the MGC is directly switched to the inactive mutual assistance state; otherwise, it directly switches to the activated state of mutual assistance. 34. The method according to p, in which the normal operating state of the KMSh (MGC) further comprises:
unoccupied condition subject to mutual assistance;
when recovering from an out-of-service state, the CMS (MGC) directly switches to an idle state subject to mutual assistance;
The MGC, which is in an idle state under the condition of mutual assistance, switches to the activated state of mutual assistance or to the inactive state of mutual assistance according to the control command for changing the state, which is sent by the network control center of the system. 35. The method according to any one of claims 32-34, further comprising steps:
configure the MS (MGW), managed by each KMSh (MGC), as the main MS (MGW), configure the MS (MGW), managed by its mutual assistance KSH (MGC), as a backup MS (MGW); and save the result of the settings in the database of the network control center of the system to which the KMSh belongs (MGC);
for each MCW (MGW), an AMC (MGC) is configured, which controls an MCM (MGW) as the primary AMC (MGC) of an MS gateway (MGW), an MSC (MGC) of mutual assistance of an MCC (MGC) is configured as a backup AMC (MGC) of a gateway MS (MGW); and save the result of the settings in the database of the MSH (MGW). 36. The method according to clause 35, in which the KMSh (MGC) in the inactive state of mutual assistance performs the following actions:
supports the established main channel connected to its own main MS (MGW), controls the main MS (MGW) on the main channel;
responds on the main channel to the clock control signal periodically sent by its own main MS (MGW);
maintains its own list of MS (MGW) and processes the registration requests that the MS sends (MGW), according to his list of MS (MGW). 37. The method according to clause 35, in which KMSh (MGC) in the activated state of mutual assistance performs the following operations:
maintains the installed primary channel connecting the KMSh (MGC) with its own primary MS (MGW), and establishes a backup channel connecting the KMSh (MGC) with its backup MS (MGW), and controls the main MS (MGW) and the backup MS (MGW), respectively on the main and backup channel;
periodically responds to a clock control signal that sends the main MBH (MGW) on the main channel, and periodically responds to the clock control signal that sends the backup MSH (MGW) on the backup channel;
maintains its own list of MS (MGW) and processes the registration requests that the MS sends (MGW), according to its list of MS (MGW). 38. The method according to clause 35, further comprising steps:
The MGC (MGC), before switching from the non-activated state of mutual assistance to the activated state of mutual assistance, reads the information of the MG (MGW) from the database of the network control center of the system, adds its backup MS (MGW) to the list of MG (MGW) managed by it. 39. The method according to clause 35, in which before the transition from the activated state of mutual assistance in the inactive state of mutual assistance KMSh (MGC) performs the following steps:
it searches for the list of MGs (MGWs) managed by it; it obtains information about the reserve MSs (MGWs) from the list of MSs (MGWs) at the request of the database of the system network control center;
sends a cessation of service message to the standby MSH (MGW), informing the standby MSH (MGW) that the KMSH (MGC) no longer provides services, and sends a command to the standby MSH (MGW) to immediately disconnect the standby channel;
turns off the communication port connected to the backup MB (MGW) and disconnects the backup channel;
deletes all information about the backup MB (MGW) from the list of MB (MGW) managed by the KMS (MGC). 40. The method according to clause 35, further comprising steps:
Before switching from an out-of-service or unoccupied state, under the condition of mutual assistance to the non-activated state of mutual assistance, the KMG (MGC) reads information about the MG (MGW) from the database of the network control center of the system, adds its main MS (MGW) to the list of MG (MGW) supported by the KMS itself (MGC);
Before switching from an out-of-service or unoccupied state, under the condition of mutual assistance to the activated state of mutual assistance, the CMS (MGC) reads the information about the MSC (MGW) from the database of the network control center of the system, adds its main MSC (MGW) and the backup MSC (MGW) to the list of MSH (MGW), supported by the KMSh (MGC). 41. The method according to clause 35, which after switching the MSH (MGW) to the backup KMSh (MGC) further comprises the steps:
The MSH (MGW) periodically sends a clock pilot to its primary CMC (MGC) and monitors a clock pilot returned from the main CMC (MGC); if the clock is returned from the primary LMS (MGC), it configures the primary LMS (MGC) as the current local LMS (MGC) of the MSS (MGW) and initiates a switch from the backup LMS (MGC) to the primary LMS (MGC). 42. The method according to clause 30, further comprising the step of setting a threshold for detecting a broken clock reference signal;
The normal heartbeat signals returned by the local LMS (MGC) contain:
heartbeats continuously returned by the local LMS (MGC), or the interruption period of the returned heartbeats is less than a predetermined threshold for detecting a broken heartbeat. 43. The method according to item 22 or 30, in which two objects of the media gateway control function (MGCF) are the first main control equipment and the second main control equipment, and the method further comprises the steps:
the first main control equipment receives data and the state of the second main control equipment;
the first main control equipment processes the services of the second main control equipment using the data of the second main control equipment according to the state of the second main control equipment. 44. The method according to item 43, in which the first main control equipment receives the state of the second main control equipment through the acknowledgment mechanism. 45. The method according to item 43, in which the state of the second main control equipment includes a normal state and an out-of-service state; and the step of processing the first main control equipment of the services of the second main control equipment using the data of the second main control equipment according to the state of the second main control equipment further comprises the steps:
if the second main control equipment is in a normal state, then the first main control equipment receives data of the second main control equipment;
if the second main control equipment is out of service, the step further comprises:
the first main control equipment assumes the services of the second main control equipment according to the data of the second main control equipment. 46. The method according to item 45, in which the step of taking the first main control equipment services of the second main control equipment according to the second main control equipment further comprises the steps:
the first main control equipment establishes services associated with the second main control equipment according to the second main control equipment;
perform established services in the first primary control equipment. 47. The method according to item 45, in which, when the second main control equipment switches from a state outside the service to a normal state; the processing step of the first main control equipment for the services of the second main control equipment using the data of the second main control equipment according to the state of the second main control equipment further comprises the steps:
the first main control equipment returns the services of the second main control equipment to the second main control equipment. 48. The method according to clause 47, in which the step of returning the first main control equipment services of the second main control equipment to the second main control equipment further comprises:
the first main control equipment disconnects the connections for services associated with the second main control equipment according to the second main control equipment; the first main control equipment receives data of the second main control equipment. 49. The method according to item 43 further comprises:
data with the identification of other equipment is left unprocessed at the start of the first main control equipment. 50. An element of local equipment with dual connection, containing:
a data acquisition unit connected to mutual assistance equipment of the local equipment and a data storage unit used to receive data on the mutual assistance equipment and store the received data in the data storage unit; moreover, the data storage unit is designed to store data received by the data receiving unit from the mutual assistance equipment;
a heartbeat detection unit connected to the mutual assistance equipment, the service switching unit and the service disconnection control unit for detecting the status of the mutual assistance equipment and sending a notification about the detected state of the mutual assistance equipment to the service switching control unit and the service disconnection control unit;
a service switching control unit connected to the clock detection unit and the data storage unit, which is intended for receiving data on mutual assistance equipment stored in the data storage unit for receiving services of mutual assistance equipment and control equipment originally controlled by mutual assistance equipment, if a heartbeat detection unit has detected that the state of the mutual assistance equipment is inoperative;
a service disconnection control unit connected to the clock detection unit and the data storage unit, which is intended for receiving data on the mutual assistance equipment stored in the data storage unit, for disconnecting the services received from the mutual assistance equipment, and returning the services back to the mutual assistance equipment if the heartbeat detection unit has detected that the state of the mutual assistance equipment has changed from a non-working state to a normal state. 51. An item of local equipment with dual connection according to item 50, in which the local equipment further contains a list for recording all equipment controlled by local equipment, and
local equipment is additionally designed to determine whether the managed equipment that sent the registration request is on the list when receiving a registration request to initiate a switchover, carried out as part of a double connection, from the controlled equipment; if the managed equipment that sent the registration request is on the list, then the local equipment accepts the registration request and connects to the managed equipment; otherwise, local equipment rejects the registration request. 52. The item of local equipment with double connection according to item 50, in which the element of local equipment with double connection is additionally designed to send a normal clock control signal to the equipment of mutual assistance and to the controlled equipment of the element of local equipment with double connection, if the element of local equipment with double The connection is in normal condition. 53. The item of local equipment with double connection according to item 50, in which the element of local equipment with double connection is additionally designed to determine that the mutual assistance equipment is inoperative if the item of local equipment with double connection for a predetermined time does not receive from mutual assistance clock control signal or if the period of interruption of the returned clock control signal from mutual assistance equipment pain e than the predetermined threshold; after it is established that the mutual assistance equipment is inoperative, the local equipment element with double connection is additionally designed to switch from the inactive mutual assistance state to the activated mutual assistance state, add equipment controlled by the mutual assistance equipment to the list managed by the local equipment element when dual connection, for active establishment of a connection with controlled equipment, initial on mutual assistance control equipment, and making management of the controlled equipment. 54. The dual-connect local equipment item according to claim 50, wherein the dual-connect local equipment item is further adapted to determine the switching of the mutual assistance equipment from an idle state to a normal state when it is detected that the clock control signal from the mutual assistance equipment is normal;
after it is established that the mutual assistance device has switched from an inoperative state to a normal state, the element of local equipment with double connection is additionally designed to remove from its list of controlled equipment originally controlled by mutual assistance equipment, notify the controlled equipment that no service will be provided, and disconnect the connection with controlled equipment. 55. The controlled equipment of the communication network according to claim 51, wherein the controlled equipment is designed to periodically send a clock control signal to its own local equipment in normal condition, to detect a clock control signal returned from its own local equipment;
the controlled equipment is additionally designed to periodically send a clock control signal to local equipment upon receipt of a normal clock control signal returned from local equipment;
the controlled equipment is additionally intended to initiate a switchover, carried out as part of a double connection, to mutual assistance equipment of their own local equipment, to accept mutual assistance equipment of their own local equipment as new local equipment and to send a clock control signal to new local equipment, if within a predetermined period the controlled equipment does not receive a normal clock control signal from the local ore or if the interruption period of the returned control clock signal from the local equipment is longer than the specified threshold. 56. The equipment of claim 55, wherein the managed equipment is further configured to configure the local equipment controlling it as the first local equipment, configure the mutual assistance equipment of the local equipment as the second local equipment, and save the tuning result in a database managed by the controlled equipment. 57. The equipment according to item 55, in which the managed equipment is additionally designed to send a registration request to the second local equipment when determining the need to initiate a switchover carried out as part of a double connection. 58. A system for implementing dual connectivity, comprising:
first local equipment and second local equipment configured as backup for each other;
an item of controllable equipment related to the first local equipment or to the second local equipment, sets its local equipment as the main local equipment, sets the equipment for mutual assistance of its local equipment as the backup local equipment, connects the main local equipment and the backup local equipment respectively with the main channel and backup channel; if the main local equipment is in normal condition, then the main channel is activated, and the backup channel remains inactive; if the main equipment is in an idle state, the backup channel is activated and the main channel remains inactive, and if the main equipment returns from an idle state, the main channel is activated and the backup channel is taken out of activity. 59. The system of claim 58, wherein:
the first Outgoing Point Code (OPC) is set respectively in the first local equipment and in the second local equipment;
the controlled equipment that will interact with the first instrumentation (OPC) is connected to the first local equipment and the second local equipment, and the priority of the main channel connecting the controlled equipment to the first instrumentation (OPC) of the first local equipment is higher than the priority of the backup channel connecting the managed equipment with the first instrumentation (OPC) of the second local equipment;
controlled equipment is designed to determine whether it is possible to use the main channel with a higher priority when receiving a signal message, the destination of which is the first instrumentation (OPC);
the controlled equipment is additionally designed to perform signaling exchange with the first instrumentation (OPC) of the first local equipment on the main channel, if the main channel with a higher priority can be used;
the controlled equipment is additionally designed to perform signaling exchange with the first instrumentation (OPC) of the second local equipment via the backup channel, if it is impossible to use the main channel with a higher priority. 60. The system of claim 58, wherein:
the second instrumentation (OPC) is installed respectively in the first local equipment and in the second local equipment, and the second instrumentation (OPC) and the first instrumentation (OPC) installed in each local equipment are installed as backup for each other;
the main channel connecting the signaling point of the controlled equipment to the first instrumentation (OPC) of the first local equipment is a direct route;
the backup channel connecting the signaling point of the controlled equipment to the first instrumentation (OPC) of the second local equipment is an indirect route passing the second instrumentation (OPC) of the second local equipment. 61. The system of claim 58, wherein the controllable equipment is designed to exchange alarms with the first instrumentation (OPC) of the second local equipment via the backup channel if the main channel cannot be used or if the first local equipment is inoperative;
the controlled equipment is additionally designed to send an upward signaling message to the second instrumentation (OPC) of the second local equipment on an indirect route with lower priority if the main channel cannot be used or if the first local equipment is inoperative; and the second checkpoint (OPC) of the second local equipment is intended to send an upward signaling message / messages received from the managed equipment to the first instrumentation (OPC) of the second local equipment;
the first instrument (OPC) of the second local equipment is designed to send a downlink signal message to the second instrument (OPC) of the second local equipment if the main channel cannot be used or if the first local equipment is inoperative, and the second instrument (OPC) of the second local equipment is additionally designed to send a downstream alarm message / messages to the managed equipment. 62. The system of claim 58, wherein the first local equipment is for receiving data and the state of the second local equipment, processing the services of the second local equipment using the data of the second local equipment according to the state of the second local equipment. 63. The system of claim 58, wherein the state of the second local equipment comprises a normal state and an inoperative state; and
the first local equipment is intended to receive data of the second local equipment when the second local equipment is in normal condition; and
the first local equipment is additionally intended to accept the services of the second local equipment according to the second local equipment when the second local equipment is inoperative. 64. The system according to § 58, in which the first local equipment is additionally designed to accept services related to the second local equipment according to the second local equipment, when the state of the second local equipment changes from an idle state to a normal state; and the second local equipment is intended to receive controlled equipment and data that it manages in good condition. 65. The system of claim 58, wherein when the state of the second local equipment changes from a non-working state to a normal state, the first local equipment is further designed to continuously manage the services of the second local equipment until the state of the first local equipment changes to non-working, and when the state of the first local equipment changes to non-working, the second local equipment is additionally designed to accept all the services managed by the first local equipment located in in good condition, which includes services related to the first local equipment and services received from the second local equipment.
Priority on points: 08/29/2004 according to claims 1-10, 58; 06/17/2005 according to claims 11-14, 59-61; 06/21/2005 according to claims 22-29; 04/18/2005 according to claims 30-42, 51-57; 07/26/2005 according to claims 15-21, 43-49, 50, 62-65.

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