Abstract:
An access node (e.g., Digital Subscriber Line Access Multiplexer) and a method are described herein that proactively monitor the connectivity of one or more end devices (e.g., residential gateways). In one embodiment, the access node performs the following: (a) receives continuity check messages from at least one of the end devices; (b) polls the received continuity check messages to ascertain the connectivity of each end device; and (c) if at least one continuity check message is detected as missing from one of the end devices during the polling step, then an alarm message is sent indicating a loss of connectivity to the one end device. Thereafter, an edge router (e.g., Broadband Network Gateway) would receive the alarm message and know there is no longer a connection to the one end device.

Description:
TECHNICAL FIELD 
       [0001]    The present invention relates to an access node (e.g., Digital Subscriber Line Access Multiplexer) and method for proactively monitoring the connectivity of one or more end devices (e.g., residential gateways). 
       BACKGROUND 
       [0002]    The following abbreviations are herewith defined, at least some of which are referred to in the following description associated with the prior art and the present invention. 
       AIS Alarm Indication Signaling 
     ANCP Access Node Control Protocol 
     BRAS Broadband Remote Access Server 
     BNG Broadband Network Gateway 
     BTV Broadcast Television 
     CC Continuity Check 
     CFM Connectivity Fault Management 
     DSL Digital Subscriber Line 
     DSLAM Digital Subscriber Line Access Multiplexer 
     FTTN Fiber to the Node 
     FTTU Fiber to the User 
     IEEE Institute of Electrical and Electronics Engineers 
     IP Internet Protocol 
     IPTV Internet Protocol Television 
     IWF Interworking Function 
     L2CP Layer 2 Control Protocol 
     LB Loopback 
     LBR Loopback Reply 
       [0003]    LT Line Termination (customer-side of a DSLAM)
 
NT Network Termination (network-side of a DSLAM)
 
       MA Maintenance Association 
     MAC Media Access Control 
     MEP Maintenance End Point 
     OLT Optical Line Termination 
     ONT Optical Network Termination 
     PON Passive Optical Network 
     RGW Residential Gateway 
     SNMP Simple Network Management Protocol 
     TV Television 
       [0004]    Referring to  FIGS. 1-2  (PRIOR ART), there are two block diagrams of a traditional access network  100  with Ethernet-based DSL aggregation (e.g., see DSL Forum TR-101). The traditional access network  100  (e.g., IPTV network  100 ) includes a regional network  102  which is coupled to an edge router  104  (e.g., BNG  104  with ports  105 ) which is coupled to one or more aggregation nodes  106  (with ports  106   a  and  106   b ). The aggregation node(s)  106  are connected by an Ethernet access network  108  to multiple access nodes  110  (e.g., DSLAMs  110  each of which include a bridge-on-network-interface card  113  which has exterior-facing ports  113   a  and interior-facing ports  113   b  and a bridge-on-line card  115  which has interior-facing ports  115   a  and exterior facing ports  115   b ). The DSLAMs  110  are connected to multiple RGWs  112  (CPEs  112 ) which in turn are associated with multiple customers  114  where there is normally one customer  114  associated with one RGW  112 . In one application, the BNG  104  transmits BTV traffic  118  (multiple TV channels  118 ) at the Ethernet level (level 2) downstream via the aggregation node(s)  106 , the Ethernet access network  108 , the DSLAMs  110 , and the RGWs  112  to the customers  114 . The basic architecture and functionality of the traditional access network  100  is well known to those skilled in the art but for additional details about this type of architecture reference is made to DSL Forum TR-101 Ethernet-based DSL aggregation dated April 2006 (the contents of which are hereby incorporated by reference herein). 
         [0005]    In this broadband access network  100 , a provider wants to know if anyone of the RGWs  112  is unreachable before one of the customers  114  calls in with a complaint. Thus, the BNG  104  proactively monitors the connectivity to all of the RGWs  112  so that disconnection problems can be detected before the provider receives a call from a customer  114 . This proactive connectivity monitoring is achieved through the use of continuity check (CC) messages which are defined in the IEEE 802.1ag standard entitled “Virtual Bridged Local Area Networks-Amendment 5: Connectivity Fault Management” Feb. 8, 2007 (the contents of which are incorporated by reference herein). Basically, the BNG  104  proactively monitors the connectivity to each of the RGWs  112  by having CC messages  126  flowing on a MA  128  between each of the RGWs  112  and the BNG  104 . However, in many applications like the IPTV application there can be a few thousand RGWs  112  connected to a single BNG  104 . Thus, the BNG  104  has to process and store the corresponding state information for each of the CC messages  126  that are received from all of the RGWs  112 . This scheme causes memory and processing scalability problems at the BNG  104 . Accordingly, there has been a need and still is a need for addressing this shortcoming and other shortcomings which are associated with the traditional access network  100 . This need and other needs are satisfied by the present invention. 
       SUMMARY 
       [0006]    In one aspect, the present invention provides a method that could be implemented by an access node (e.g., DSLAM, ONT) to proactively monitor the connectivity of a plurality of end devices (e.g., RGWs, CPEs). The method comprises the steps of: (a) receiving continuity check messages from at least one of the plurality of end devices; (b) polling the received continuity check messages to ascertain the connectivity of each end device; and (c) if at least one continuity check message is detected as missing from one of the end devices during the polling step, then sending an alarm message indicating a loss of connectivity to the one end device. Thereafter, an edge router (e.g., BNG) would receive the alarm message and know there is no longer a connection to the one end device. 
         [0007]    In another aspect, the present invention provides an access node (e.g., DSLAM, ONT) with a processor that retrieves instructions from a memory and processes those instructions to enable an interworking function to perform the following operations: (a) receive continuity check messages from at least one of the plurality of end devices (e.g., RGWs, CPEs); (b) poll the received continuity check messages to ascertain the connectivity of each end device; and (c) if at least one continuity check message is detected as missing from one of the end devices during the polling step, then sending an alarm message indicating a loss of connectivity to the one end device. Thereafter, an edge router (e.g., BNG) would receive the alarm message and know there is no longer a connection to the one end device. 
         [0008]    In yet another aspect, the present invention provides a method for proactively monitoring the connectivity of a plurality of end devices within an access system which also includes an edge router and an access node. The method comprising the steps of: (a) receiving continuity check messages at the access node, where the continuity check messages are sent from at least one of the plurality of end devices; (b) polling the received continuity check messages at the access node to ascertain the connectivity of each end device; and (c) if at least one continuity check message is detected as missing from one of the end devices during the polling step, then sending an alarm message from the access node to the edge router, where the alarm message indicates a loss of connectivity to the one end device. 
         [0009]    Additional aspects of the invention will be set forth, in part, in the detailed description, figures and any claims which follow, and in part will be derived from the detailed description, or can be learned by practice of the invention. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the invention as disclosed. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0010]    A more complete understanding of the present invention may be obtained by reference to the following detailed description when taken in conjunction with the accompanying drawings wherein: 
           [0011]      FIGS. 1-2  (PRIOR ART) are two diagrams of a traditional access network (e.g., IPTV network) which are used to help explain several problems that are solved by the present invention; 
           [0012]      FIGS. 3-4  are two diagrams of an access network (with an Ethernet-based DSL aggregation) which has access nodes (e.g., DSLAMs) that implement a method for proactively monitoring the connectivity of end devices (e.g., RGWs, CPEs) in accordance with the present invention; 
           [0013]      FIG. 5  is a flowchart illustrating the basic steps of the method for proactively monitoring the connectivity of end devices (e.g., RGWs, CPEs) in accordance with the present invention; 
           [0014]      FIG. 6  is a diagram of an exemplary access network which is used to help explain how the proactive monitoring method can be implemented in accordance with one embodiment of the present invention; and 
           [0015]      FIG. 7  is a diagram which illustrates the CFM header of an exemplary Ethernet AIS that was configured to be an alarm message which is discussed with respect to the access network shown in  FIG. 6  in accordance with the present invention. 
       
    
    
     DETAILED DESCRIPTION 
       [0016]    Referring to  FIGS. 3-4 , there are two block diagrams of an access network  300  (with an Ethernet-based DSL aggregation) which has access nodes  310  (e.g., DSLAMs  310 ) that implement a method  350  for proactively monitoring the connectivity of end devices  312  (e.g., RGWs  312 , CPEs  312 ) in accordance with the present invention. The access network  300  (e.g., IPTV network  300 ) includes a regional network  302  which is coupled to an edge router  304  (e.g., BNG  304  with ports  305 ) which is coupled to one or more aggregation nodes  306  (with ports  306   a  and  306   b ). The aggregation node(s)  306  are connected by an Ethernet access network  308  to multiple access nodes  310  (e.g., DSLAMs  310  each of which include a bridge-on-network-interface card  313  which has exterior-facing ports  313   a  and interior-facing ports  313   b  and a bridge-on-line card  315  which has interior-facing ports  315   a  and exterior facing ports  315   b ). The DSLAMs  310  are connected to multiple RGWs  312  (CPEs  312 ) which in turn are associated with multiple customers  314  where there is normally one customer  314  associated with one RGW  312 . In one application, the BNG  304  transmits BTV traffic  318  (multiple TV channels  318 ) at the Ethernet level (level 2) downstream via the aggregation node(s)  306 , the Ethernet access network  308 , the DSLAMs  310 , and the RGWs  312  to the customers  314 . 
         [0017]    Each DSLAM  310  is shown to have a processor  320  that retrieves instructions from a memory  322  and processes those instructions to enable an interworking function  324  to implement a proactive connectivity monitoring method  350  (see flowchart in  FIG. 5 ) in accordance with the present invention. In one embodiment, each DSLAM  310  and in particular their interworking function  324  implements method  350  to proactively monitor the connectivity of their corresponding end devices  312  (e.g., RGWs  312 , CPEs  312 ) by receiving CC messages  326  from one or more of the corresponding end devices  312  (see step  502 ). In this example, assume all of the corresponding end devices  312  are sending the CC messages  326  except for one end device  312 ′. Then, each DSLAM  310  and in particular their interworking function  324  polls the received CC messages  326  to ascertain the connectivity of all of their corresponding end devices  312  (see step  504 ). If at least one CC message  326  is detected as missing from one of the end devices  312  during the polling step, then the respective DSLAM  310  and in particular their interworking function  324  sends an alarm message  328  to the BNG  304  where the alarm message  328  indicates a loss of connectivity to the one end device  312 ′ (see step  506 ). 
         [0018]    Referring to  FIG. 6 , there is a block diagram of an exemplary access network  300   a  which is used to help explain how the proactive connectivity monitoring method  350  can be implemented in accordance with one embodiment of the present invention. The steps of how this particular embodiment of the proactive connectivity monitoring method  350  can be implemented are as follows: 
         [0019]    1. The RGWs  312  send periodic CC messages  326  over an access link MA  602  to their corresponding bridge-on-network-interface cards  313  in the DSLAMs  310 . The CC message  326  is described in the IEEE 802.1 ag/D8 standard entitled “Virtual Bridged Local Area Networks-Amendment 5: Connectivity Fault Management” Feb. 8, 2007 (the contents of which are hereby incorporated by reference herein). 
         [0020]    2. Each bridge-on-network-interface card  313  polls the received CC messages  326  to ensure the reception of at least one CC message  326  from all of the corresponding RGWs  312  (see steps  502  and  504 ). In one embodiment, the polling is achieved by the IWF  324  that polls the respective access link MA  602  between the corresponding bridge-on-network-interface card  313  and each of the corresponding RGWs  312 . How the IWF  324  performs the polling operation is application specific and would depend on the total number of corresponding RGWs  312 . In one case, the IWF  324  may have a polling rate=1/n (rate of CC messages  326  coming in) where n=number of user facing ports  315   b.    
         [0021]    3. If the required number of CC messages  326  from each of the corresponding RGWs  312  are received at the bridge-on-network-interface card  313 , then the IWF  324  will do nothing and will not send any alarm message  328  to the BNG  304 . 
         [0022]    4. If the required CC messages  326  from any of the corresponding RGWs  312  are not received at the bridge-on-network-interface card  313 , then the IWF  324  will send an alarm message  328  on an intra carrier MA  604  to the BNG  304  (see step  506 )(note: the DSLAM  310  will not expect a response back from the BNG  304 ). In this example, assume the IWF  324  sends the alarm message  328  after three consecutive CC messages  326  fail to be received from the corresponding RGW  312 ′. The alarm message  328  identifies the particular RGW  312 ′ that failed to send the required number of CC messages  326 . If there are multiple non-connected RGWs  312 ′, then the IWF  324  would send multiple alarm signals  328  to the BNG  304 . Typically, the alarm message  328  would contain the MAC address or the RGW port ID  315   b ′ that is associated with the non-connected RGW  312 ′. If desired, the alarm message  328  could be an Ethernet AIS (which would identify the MAC address of the non-connected RGW  312 ′), an ANCP/L2CP message (which would identify the MAC address of the non-connected RGW  312 ′) or a SNMP trap (which would identify the RGW port ID  315   b ′ of the non-connected RGW  312 ′).  FIG. 7  is a diagram which illustrates the basic CFM header of an exemplary Ethernet AIS  328  configured to be an alarm message  328  which has a SA with an identifier  702  (e.g., MAC address) that is used to identify the non-connected RGW  312 ′. 
         [0023]    5. The BNG  304  upon receiving the alarm message  328  knows that connectivity was lost to the identified non-connected RGW  312 ′. As can be seen, this method  350  enables scalability processing because the bridge-on-network-interface cards  313  send an alarm message  328  to the BNG  304  only when there happens to be a non-connected RGW  312 ′. Plus, the bridge-on-network-interface cards  313  send an alarm message  328  as soon as they detect the loss of a certain number of CC message(s)  326  from anyone of their corresponding RGWs  312 . Thus, there is no need for the BNG  304  to continuously monitor the loss of CC messages  326  for each of their corresponding RGWs  312  as was required in the prior art. 
         [0000]    Note 1: If desired the IWF  324  and the proactive connectivity monitoring method  350  can be implemented in the bridge-on-line card  315  instead of the bridge-on-network-interface card  313 . This alternate location of the IWF  324  may be used if one wanted to help alleviate the processing on the bridge-on-network-interface card  313 .
 
Note 2: The present invention can be implemented as well in an access network that is based on a PON model in which case the DSLAM  310  would be replaced by both an OLT and an ONT. Typically, the OLT-ONT can be used in a FTTU architecture while the DSLAM would be used in a FTTN architecture.
 
         [0024]    From the foregoing, it can be seen that each DSLAM  310  effectively acts as a proxy to collect CC messages  326  received from their corresponding RGWs  312  and sends an alarm message  328  to the BNG  304  only when there is a loss of connectivity detected with any of their corresponding RGWs  312 . Thus, there is a local termination of Ethernet CC messages  32  at the DSLAMs  310 , combined with some protocol that indicates loss of connectivity to the BNG  304  such as an Ethernet AIS message  328 , an ANCP/L2CP message  328 , or a SNMP trap  328 . This is a marked-improvement over the prior art in which all of the RGWs  312  would have had to send periodic CC messages  326  directly to the BNG  304  so that the BNG  304  could proactively monitor the connectivity to the corresponding RGWs  312 . There are several other advantages associated with the present invention some of which are listed below: 
         [0025]    1. The present invention described here applies not only to IPTV architectures but to other similar architectures. 
         [0026]    2. The IWF  324  need not be standardized since it is implemented internal to the access node  310 . 
         [0027]    3. The connectivity monitoring method  350  is scalable, proactive, and relatively simple to implement in current access nodes  301 . 
         [0028]    4. The BNG  304  is aware of the loss of RGW  312  connectivity without the need to store state information nor the need to perform processing for each RGW  312 . This significantly reduces memory and processing requirements on the BNG  304 . 
         [0029]    5. There is no need to change the IEEE CFM standard behaviors to implement the proactive connectivity monitoring method  350 . However, there may be a need to standardize the message format between the access node  310  and the edge router  304  to enable the exchange of the alarm message  328 . However, the Ethernet AIS message, an ANCP/L2CP message, or a SNMP trap are excellent candidates for the alarm message  328  because they provide the required semantics including the message type and the header plus the message layout has already been defined. 
         [0030]    Although one embodiment of the present invention has been illustrated in the accompanying Drawings and described in the foregoing Detailed Description, it should be understood that the present invention is not limited to the disclosed embodiment, but is capable of numerous rearrangements, modifications and substitutions without departing from the spirit of the invention as set forth and defined by the following claims.