Abstract:
A method of delaying or blocking new bus resets from propagating while a previous bus initialization (bus reset, tree-id or self-id) is in process during the performance of a IEEE-1394 serial bus. The method provides for more robust Beta only bus operation during high frequency bus resets. The bus resets are caused by noise events, power-up and power-down sequences and other bus reset causing events.

Description:
BACKGROUND OF THE INVENTION 
     (a) Field on Invention 
     This invention relates to the performance of a IEEE-1394 serial bus, and more particularly, but not by way of limitation, to a method of delaying or blocking new bus resets from propagating while a previous bus initialization (bus reset, tree-id or self-id) is in process. The method provides for more robust Beta only bus operation during high frequency bus resets. The bus resets are caused by noise events, power-up and power-down sequences and other bus reset causing events. 
     (b) Discussion of Prior Art 
     IEEE-1394-2008 defines Legacy or Alpha nodes and Beta nodes. Legacy nodes are based on earlier versions of the IEEE-1394 standard (IEEE-1394-1995 and IEEE-1394a-2000), while Beta nodes are based on IEEE-1394b-2002. There are many differences between Legacy node and Beta node implementations. But, for the purposes of this application, Legacy nodes do not support loops in a topology while Beta nodes do support loops in the topology. By definition, a loop in a topology is where a node port connects back to the same node through 0 to N nodes in a node cloud. 
     Heretofore, there have been a number of IEEE 1394-coupled communication system and method patents. For example, they are U.S. Pat. No. 7,681,051 to Liu et al., U.S. Pat. No. 7,036,031 to Takeuchi, U.S. Pat. No. 6,912,596 to Skidmore, U.S. Pat. No. 6,523,073 to Kammer et al., and U.S. Pat. No. 6,412,076 to Honda et al. 
     None of these patents describe the unique features and method for specific improved robustness of Beta only bus topologies by delaying or blocking new bus resets from propagating during bus initialization. 
     SUMMARY OF THE INVENTION 
     In view of the foregoing, it is a primary object of the subject invention to reduce the occurrence of disconnects in a Beta only bus topology as caused by Legacy loop detection during bus initialization caused by noise events, power-up and power-down sequencing or other bus reset causing events. The noise events can be caused by lightning strikes, a strobe light, static electricity and the like. 
     Another object of the invention is reduce the occurrence of disconnects caused by devices not implementing this method or a method that disables a Legacy loop detection logic when devices implementing this method are present in the same topology. 
     These and other objects of the present invention will become apparent to those familiar with different versions of Legacy node and Beta node IEEE-1394 technology when reviewing the following detailed description, showing novel construction, combination, and elements as described herein 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The accompanying drawings illustrate complete preferred embodiments in the present invention according to the best modes presently devised for the practical application of the subject method for blocking bus resets, and in which: 
         FIG. 1  illustrates a Node A and a Node B connected in a single topology. 
         FIG. 2  illustrates Nodes A and B connected to Nodes C and D in a single topology. 
         FIG. 3  illustrates the decision process a node uses to determine if a bus reset should be blocked or not. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     In  FIG. 1 , Nodes A and B are shown connected in a single topology. In this drawing, if Node A generates four (4) consecutive bus resets spaced close enough together that when Node B doesn&#39;t transition into S1: Self-ID Grant or S2: Self-ID Receive state between bus resets then Node B&#39;s resetCount variable will become greater than three (3) which will cause Node B to disconnect from Node A. 
     In  FIG. 2 , Nodes A, B, C and D are shown connected in a single topology. In this drawing, if Node A generates four (4) consecutive bus resets that when repeated by Node B becomes spaced close enough together that when Node C doesn&#39;t transition to S1: Self-ID Grant or S2: Self-ID Receive state between bus resets then Node C&#39;s resetCount variable will become greater than three (3) which will cause Node C to disconnect from Node B thus temporarily creating two separate node topologies, such as Nodes A and B and Nodes C and D. 
     In  FIG. 3 , a Node implementing this invention tests each connected port of its PHY and if a bus reset is detected, portRArb[i]==BUS_RESET, and busInitializeActive, the PHY is currently in a bus initialize state (R1|T0|T1|T2|T3|S0|S1|S2|S3|S4), the PHY will block the propagation, repeat_Bus_Reset=FALSE, the received bus reset to its other active ports. The PHY port receiving the bus reset responds with bus reset, return_Bus_Reset[i]=TRUE. When the other ports transition out of a bus initialize state, busInitializeActive=FALSE, the received bus reset is then repeated to its other active ports, repeat_Bus_Reset=TRUE. 
     This behavior was designed into the IEEE-1394-2008 standard to detect a loop between Alpha nodes during bus initialization as described in the IEEE-1394-2008 section “14.7.13 Loop detection during bus initialization”: 
     Some loop conditions may be detected during bus initialization. They are:
     a) Configuration timeout (in the T0: Tree ID Start state), which can occur if the node is on a loop and either that loop includes one or more Alpha nodes or the loop is formed as a result of a connection on the bus being resumed.   b) Arbitration state timeout, which can occur up to the time when the port enters the S1: Self-ID Grant or S2: Self-ID Receive state if the node is connected to a network of Alpha nodes that are in a loop.   c) Repeated resets, which can occur in similar circumstances to condition b with a loop on a network that includes IEEE 1394 nodes that use a shorter arbitration state timeout.”   

     While in most cases this functionality is desirable. Also, some applications can guarantee either Alpha nodes are not preset, Beta nodes only, or Alpha nodes cannot be connected in a loop. Furthermore, in some environments, it is possible that bus resets can be generated quickly enough to cause a Beta node PHY ports to incorrectly disable a connection between two different nodes for reasons other than a loop between Alpha nodes. 
     It should be noted that Texas Instruments (TI) TSB41BA3 and TSB81BA3 PHYs do not behave exactly as the IEEE-1394 standard defines. In fact, it appears these PHYs do not clear the resetCount variable until the PHY transitions from the Self-id to normal arbitration state AO. This creates, especially in large topologies, a much larger timing window in which four (4) consecutive bus resets could cause resetCount to be greater than three (3) and cause a port to disconnect. 
     The method described below provides a programmable implementation that provides both backward compatibility and software/hardware programmable means to enable this new functionality. In addition, to the method described below, other methods may be implemented that provide the same desired results. 
     The Block Bus Reset Propagation Method determines that if a bus reset signal (portRArb[i]==BUS_RESET) is received while the PHY is currently in the R1, T0, T1, T2, T3, S0, S1, S2, S3 or S4 states (busInitializeActive==TRUE) the PHY won&#39;t propagate (repeat_Bus_Reset=FALSE) the bus reset until the other connected port(s) transition to the AO (Arbitration state zero) state. The port receiving the bus reset responds by returning bus reset, return_Bus_Reset[i]=TRUE. This guarantees the PHY receiving the new bus reset will block the propagation of bus reset until the bus reset, tree-id and self-id processes complete. Additionally, the method prohibits the PHY from initiating consecutive bus resets until its ports transition through the Bus Reset, Tree-ID and Self-ID states to the Arbitration zero state. 
     Also referring to  FIG. 2 , if Node A generates four (4) consecutive bus resets and Node B implements the Block Bus Reset Propagation Method and the method is enabled, Node B won&#39;t propagate subsequent bus resets until the topology comprised of Nodes B, C and D transition out of the Bus Reset, Tree-ID or Self-ID state to the Arbitration zero state. This will allow the resetCount variable to be cleared in nodes B, C and D thereby not causing any of those nodes to experience a legacy loop detect event during bus initialization as described in the IEEE-1394-2008 section “14.7.13 Loop detection during bus initialization”. 
     When one or more PHY&#39;s implementing the Block Bus Reset Propagation Method are connected to an IEEE-1394 bus with PHY&#39;s allowing legacy loop detect, the probability the resetCount value will exceed there (3) is reduces. Of course the more nodes that implement this method and are directly connected to PHYs with the legacy loop detect logic enabled, the lower the probability a port will be disabled due to resetCount being greater than 3.