Abstract:
In a railroad locomotive having a plurality of systems which collectively are used for locomotive operations, a method of self-healing a system of the plurality of systems comprising monitoring operational conditions of the system, detecting at least one of a pending and a current failure, determining a self-healing procedure to correct the failure, and applying the self-healing procedure comprising at least one of a safe mode technique, a redundancy technique, and an automatic configuration technique.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS  
       [0001]     This application is a continuation of and claims the benefit of the Feb. 20, 2003 filing date of U.S. patent application Ser. No. 10/370,824. 
     
    
     BACKGROUND OF THE INVENTION  
       [0002]     This invention generally relates to diagnostics and repair, and more particularly to a method and system for correcting a malfunction or breakdown of a machine, such as a locomotive, a system, and/or a process.  
         [0003]     The diagnosis, repair, maintenance and/or other servicing of generally complex equipment, such as mobile assets that may include on-road and off-road vehicles, ships, airplanes, railroad locomotives, trucks, and other forms of complex equipment including industrial equipment, consumer appliance equipment, medical imaging equipment, equipment used in industrial processes, telecommunications, aerospace applications, power generation, etc. involves extremely complex and time consuming processes. In the case of transportation equipment, such as a locomotive and a fleet of locomotives, the efficient and cost-effect operation of a vehicle or fleet of vehicles demands minimization of the number of vehicle failures while in use, minimization of vehicle downtime and the expeditious and accurate performance of diagnostic, repair, maintenance and/or other services to the vehicles.  
         [0004]     A locomotive is one example of a complex electromechanical system comprising a plurality of complex systems and subsystems. Many if not all of these systems and subsystems are manufactured from components that will fail over time. The operational parameters of a locomotive system or subsystem are frequently monitored with on-board sensors that may continually monitor on-board operational parameters of systems, subsystems, and/or other components during operation of the locomotive to detect potential or actual failures. The on-board system may also log fault data or other fault indicators when anomalous operating conditions arise. If a failure condition or a set of failure conditions is detected then a service technician may study the fault log and/or indicator after a locomotive has arrived in a service yard to identify the nature of the problem and determine whether a repair and/or maintenance service is necessary. Conducting the diagnostics at the service yard for all faults detected may extend the overall amount of time the vehicle is out of service, especially when considering the complexity of locomotive systems and subsystems, it is sometimes difficult to precisely identify a failed component or other cause of the failure conditions.  
         [0005]     This may be because the effects or problems that the failure has on the system or subsystem are often neither readily apparent in terms of their source nor unique. Sometimes the recommended fix for a problem may not resolve the problem due to the complexity of the problem and/or diagnostic efforts. With some components, this is not a significant issue. For example, if a component has binary functional properties in that it either works properly or it doesn&#39;t, such as a mechanical or electrical switch, then diagnosing, recommending a fix and determining that the fix was correct is typically not too difficult. However, with more complex problems these efforts may be more difficult and may lead to the inefficient operation or underutilization of a locomotive or fleet of locomotives.  
         [0006]     Diagnosing failure conditions associated with complex machines such as systems and subsystems of a locomotive may be performed by experienced personnel who have in-depth training and experience in working with a particular type of machine. Typically, these experienced individuals may use current and historical information associated with a problem that has been recorded in a written or electronic log. Using this information, the technicians apply their accumulated experience, knowledge and training, in mapping incidents occurring in a complex system and/or subsystem to problems that may be causing the incidents.  
         [0007]     Computer-based systems are also used to automatically diagnose problems in a machine to overcome some of the disadvantages associated with relying completely on experienced personnel. This may increase the speed and consistency of the diagnosis. Computer-based systems are becoming more popular and may utilize a mapping between the observed failure conditions and the equipment problems using techniques such as table look-ups, symptom-problem matrices, and production rules, for example. These techniques work well for simplified systems having simple mappings between symptoms and problems. However, more complex equipment and process diagnostics seldom have such simple correspondences. Consequently, recommended fixes may be made that do not solve a problem immediately or completely. This may not be determined for sometime after the fix was executed, leading to the potential for recommending the same improper fix when that problem is next identified.  
         [0008]     Accordingly, it is desirable to provide a method and system for monitoring the resolution of problems associated with a machine, such as a locomotive, and verifying that an executed fix instruction has resolved that problem. The ability to monitor and verify the resolution of problems with a locomotive&#39;s systems and/or subsystems is advantageous because this ability may minimize overall locomotive downtime, leading to a cost savings for the operator of the locomotive or a fleet of locomotives.  
       BRIEF SUMMARY OF THE INVENTION  
       [0009]     This invention is directed to a method and system for providing a self-healing technique to correct a fault encountered during operation of a machine, system, and/or process, such as a locomotive. A preferred method comprises monitoring operational conditions of a component and/or a subsystem of the remote asset. Sensors are used to detect an impending failure associated with at least the component and/or the subsystem. After the failure is isolated, a self-healing procedure is selected to correct the failure. The self-healing procedure is applied wherein the self-healing procedure is a safe mode technique, a redundancy technique, and/or an automatic configuration technique. Verification as to whether the self-healing technique corrected the failure is then made.  
         [0010]     In a preferred embodiment, a system for autonomously correcting a failure is disclosed comprising a sensor connected to a machine, such as a locomotive, system, and/or a process to monitor and collect operating conditions data. A method of self-healing a locomotive is provided wherein either a pending or current failure is detected or identified. Once a current or pending failure is detected, a determination is made as to a self-healing technique to use to correct the pending and/or current failure. The self-healing technique is then implemented.  
         [0011]     A diagnostics system is also provided that receives the data from the sensor and isolates a pending and/or occurring failure. A processor is connected to the diagnostics system to determine a self-healing technique for the failure. The self-healing technique comprises a self-healing control technique, a redundancy technique, and/or an automatic fix technique.  
         [0012]     In another preferred embodiment, a method comprises identifying a fault. A level of confidence as to a cause of the fault is determined. If the level of confidence is above a desired threshold, a self-healing procedure is selected. A determination is made as to whether the mobile asset is in a safe mode to accept the self-healing procedure before using the self-healing procedure. The mobile asset is placed in a safe mode to accept the self-healing procedure, and then the self-healing technique is executed. Next, a validation is made as to whether the self-healing procedure corrected the fault. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0013]     The invention itself, both as to organization and method of operation, may best be understood by reference to the following description in conjunction with the accompanying drawings in which like numbers represent like parts throughout the drawings and in which:  
         [0014]      FIG. 1  is an illustration of an exemplary locomotive;  
         [0015]      FIG. 2  is a block diagram of exemplary elements of the present invention;  
         [0016]      FIG. 3  is a chart illustrating exemplary elements of the present invention; and  
         [0017]      FIG. 4  is an exemplary flow chart of steps taken when implementing the self-healing technique.  
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0018]     With reference to the figures, exemplary embodiments of the invention will now be described. The scope of the invention disclosed is applicable to a plurality of systems, machines, and/or processes. Thus, even though embodiments are described specific to a mobile asset, in this case a locomotive, this invention is also applicable to other systems, machines, and/or processes, which comprise components and subsystems which may fail over time. Thus the terms system, machine, process, component, and subsystem can be used interchangeably. Likewise, even though the present invention is disclosed towards fixing pending faults, it is also applicable to correcting current faults.  
         [0019]      FIG. 1  is an illustration of an exemplary locomotive. The locomotive  10  may be either an AC or DC locomotive. The locomotive  10  is comprised of several complex systems, such as, but not limited to, an air brake system  12 , an auxiliary alternator system  14 , an intra-consist communications systems  18 , a cable signal system  19 , a distributed power control system  26 , an engine cooling system  20 , an equipment ventilation system  22 , and a propulsion system  24 . Some of these systems, or subsystems, work independent of the other systems, whereas others interact with other systems. The subsystems are monitored by an on-board monitor system  28 , which tracks any incidents or faults occurring in any of the systems with an incident or fault log. In one embodiment, an on-board diagnostics system is also on-board to diagnose the incidents or faults. In another embodiment, the diagnostics system is at a remote monitoring facility. Though the present invention is described with respect to fixing a locomotive  10  where all necessary elements are on-board, one skilled in the art will recognize that this invention is applicable to off-board diagnostics systems and tools, as well, wherein a fix may be reached off-board and then communicated to the locomotive  10 .  
         [0020]      FIG. 2  is a block diagram of exemplary elements of the present invention and  FIG. 3  is a chart illustrating exemplary elements of the present invention. Sensors  30  are provided on the locomotive  10 , which collect data about performance of a plurality of subsystems. The data collected is either in the form of data packs, raw data, and/or custom data. The data is then processed in a diagnostics system  32 , or process, to determine faults and impending faults  40 . After a fault is detected, the diagnostics system  32  is used to isolate the fault. Such diagnostics processes may include, but are not limited to, applying rule-based systems, Case-Based Reasoning, and Belief Networks to accomplish this task. In a preferred embodiment, the diagnostics process relates a specific combination of anomalies to individual problems to isolate the fault. Once a fault is isolated  42 , a decision  44  is made as to whether the fault is a candidate for self-healing or whether a regular, traditional, or existing repair process should be implemented  46 . In a preferred embodiment, a processor  34  is used to determine whether self-healing will be used. In another preferred embodiment, a processor in the diagnostics system  32  is used to make the self-healing decision. If self-healing is the selected option  47 , then one or a combination of self-healing techniques is utilized. One skilled in the art will recognize that no precise order for implementing a self-healing technique is required and that the following techniques may be used in any order, dependent of the failure detected, and/or the component affected.  
         [0021]     One self-healing technique, or procedure, that may be implemented is a self-healing control technique  50 . A self-healing control technique  50  employs various control strategies to prevent or stop a failure by utilizing alternate control strategies to bypass the effects of the failure. For example, in one embodiment, referred to as safe mode control  51 , a failure can be avoided by operating in a safe mode. With respect to a locomotive  10 , when a failure is detected, a locomotive controller can switch the subsystem or component experiencing the problem into a safe mode operation. Though the safe mode operation may be different for various subsystems, in one embodiment the safe mode would comprise disabling certain functions of the subsystem and/or turning off or shutting down the subsystem.  
         [0022]     In another safe mode control technique embodiment referred to as reprogrammable control  52 , the locomotive would reset the subsystem to operate in less than optimal operating conditions to mitigate the effects of the failure. For example, instead of operating a subsystem at its peak conditions (e.g., optimum speed, best voltage), the locomotive control operates the subsystem at a lower operating condition (such as at much lower speed or voltage). Another reprogrammable control technique also comprises operating the locomotive controller at less than optimal gains, and using alternate models/equations to perform the required control.  
         [0023]     Another embodiment of self-healing control is using an alternate control algorithm  53 , such as Proportional-Integral-Derivative (PID). PID is a typical algorithm used in industrial control system designed to eliminate a need for continuous operator attention. This is a type of feedback controller whose output, a control variable, is generally based on an error between some user-defined set point and some measured process variable where each element of the PID controller refers to a particular action taken based on the error.  
         [0024]     In a system due to component or sensor failure, an error signal may change, pushing the controller beyond its optimal operating region. These failures can potentially drive the controller into an unstable region. In the self-healing version of PID control, an increase in controller error will automatically initiate a self-detection algorithm, which shall identify the root cause for the error increase and subsequently initiate the tuning of the PID controller to compensate for the failure. The tuning algorithm is usually dependent on the failure and the desired direction of compensation. In the present invention, the locomotive controller can also use similar approaches, such as, but not limited to, Proportional-Integral (PI), Proportional-Derivative (PD), and/or sliding mode control. The alternate algorithm used depends on the subsystem and its associated failure.  
         [0025]     Another self-healing technique that may be utilized is a hardware and software redundancy technique  55 . This technique employs the use of built-in redundancy in hardware and/or software to mitigate the effects of the failure. Thus, with respect to hardware redundancy  57 , when a failure occurs in a locomotive&#39;s subsystems, an alternate, or secondary, redundant subsystem or component within the subsystem, component, and/or locomotive is used in place of the failed subsystem or component to deliver the same function. Similarly, the software redundancy  58  operates in a similar fashion whereas in a preferred embodiment, alternate copies of the same software reside in a computer or processor on the locomotive  10 . If the present software fails due to corruption, the alternate copy of the software is used in its place. Another strategy is hardware polymorphism  59 . A piece of hardware or component is polymorphic if the hardware can deliver multiple alternate functionality through automatic reprogramming. Thus, as an example, when a circuit inverter on a locomotive axle fails, its function may be picked up by the inverter on the next axle, or by a controller chip which has the necessary calculation cycles and hardware connection and capacity to execute the function. Another technique is analytical redundancy  60 . In this strategy, redundancy between sensors is derived through analytical models. For example, if a locomotive&#39;s speed sensor fails, models may be employed to use the motor current signals to estimate values that would normally be provided by the speed sensor.  
         [0026]     A third self-healing technique is an automatic-fix technique  65 . One automatic-fix technique is an automatic reset  67 . Locomotives encounter some faults while in transient that are not reliably reproducible when at a repair depot since they may occur due to external conditions. For example, a locomotive  10  may experience overheating when climbing a steep slope while carrying a full load, or may have sensors stop operating when passing a microwave tower. Such faults may immediately interfere with the operation of the locomotive  10 . When detected, the system  5  will automatically reset the subsystem with the fault, such as switching the subsystem or component off and then back on, which then automatically corrects the fault. Another automatic-fix technique is an automatic software upgrade  68 . When certain software and/or hardware is upgraded, other pieces of hardware and/or software may not function properly in combination with the upgrade. In an automatic software upgrade technique  68 , a repository of various versions of software and a compatibility matrix are maintained in a database connected to a processor. In one embodiment the database and processor are remote from the locomotive  10 . In another embodiment these components are on-board the locomotive. When a software-related fault is identified, the locomotive  10  would communicate with the processor, which evaluates the fault using the compatibility matrix. If an incompatibility in software is detected, a software upgrade is automatically loaded to the specific processor or subsystem on the locomotive  10 .  
         [0027]      FIG. 4  is an exemplary flow chart of steps taken when implementing the self-healing technique. Sensors  30  transmit data, including fault data to a diagnostics system  32 . Based on the analysis performed by the diagnostics system  32 , a fault, or problem, is identified, Step  70 . In identifying the fault, a determination is made by the diagnostics system as to the level of confidence the diagnostics system has making the identification of the fault, Step  72 . In a preferred embodiment, if the diagnostics system is ninety percent (90%) or more confident in its identification of the fault, the system will progress to a self-healing technique, Step  74 . As one skilled in the art will recognize, the confidence level of the diagnostics system  32  can be a plurality of levels, preferably over 50%, and not just 90%. If the diagnostics system&#39;s  32  confidence is lower than the threshold level, such as 90% in the illustrated embodiment, the diagnostics system  32  will ask a plurality of questions of a user, Step  76 . Such questions may include, but are not limited to asking questions about track conditions, environmental conditions, switch settings, etc. Based on the responses of the user, Step  78 , this information is provided to the diagnostics system  32  and the confidence level in the detected fault is recalculated  72 . In one embodiment, this process can continue a plurality of times until the diagnostics system has obtained enough information to raise its confidence level above the threshold. In another embodiment, after a defined number of attempts to raise its confidence level, the diagnostics systems will cease trying, and log the fault as an alarm or an alert, Step  80  and wait for more information to be gathered, generally with the sensors  30 .  
         [0028]     To determine a confidence level, a diagnostics system can use a plurality of paradigms. Though not limited to these examples, a Case-Based Reasoning system and/or a Rule-Based system may be used to compute a confidence matrix, where rule based probabilistic theory techniques are used.  
         [0029]     Once the confidence threshold is met, the system moves to the self-healing techniques, Step  74 . First, the system will determine if the fault is one that is possible to cure with one of the self-healing techniques, Step  82 . To make this determination, in a preferred embodiment, a database contains a table or matrix comprising a list of events and identifications identifying whether the fault is a self-healing fault or not. If the fault is not a self-healing candidate, then the normal or regular fix to the fault is used  46 .  
         [0030]     In a preferred embodiment, if after the system  5  determines the self-healing-technique to use, a safety check, Step  84  is performed to determine whether the locomotive  10  is in a safe mode to accept the procedures that the specific self-healing technique will perform and/or to place subsystems or components in operational conditions to accept the self-healing technique. For example, if a fuel pump needs to be shut down to implement a self-healing technique, such as the hardware redundancy technique, the locomotive must modify control parameters so that the horse power of the fuel pump distribute more load across the remaining fuel pumps, bypassing the one that has failed. After the safety checks are completed, Step  84 , the self-healing technique is executed, Step  86 . Then, if any functions were shut down or modified to execute the self-healing technique, the functions are restarted or returned to acceptable operational conditions, Step  88 . The system  5  then validates that the self-healing technique fixed the fault, Step  90 . If the fault was fixed, then the locomotive  10  considers the fix a success, Step  92 . If the fault was not corrected, the system will cycle through the identified fix, in a preferred embodiment, three additional times, Step  94 . If the fault is still not fixed, Step  96 , the fault is logged as an alert, Step  80 . In some situations, such as when a fuel pump is bypassed, this fix is only a temporary fix. Eventually the bypassed fuel pump must be manually inspected and/or replaced, Step  98 .  
         [0031]     While the invention has been described in what is presently considered to be a preferred embodiment, many variations and modifications will become apparent to those skilled in the art. Accordingly, it is intended that the invention not be limited to the specific illustrative embodiment, but be interpreted within the full spirit and scope of the appended claims.