The present invention relates to rail systems in general, and, more particularly, to methods for controlling the movement of trains through a rail system.
Vital train movements include the required enforceable “movement authority” for a train operating on controlled track. This movement authority (data) must be transmitted from a controlling entity to the train, both at the trip origin and while the train is en route. Since this is critical train control data, the exchange of the data must be performed in a vital manner. Furthermore, the data onboard must be verified as being current at a frequent rate to avoid operating with stale or missing data.
Communications between the train and a controlling entity is expected to be over a wireless communications path where bandwidth considerations are paramount. Often, the available communications channels offer relatively low bandwidth and high-latency. Yet, this bandwidth is required to support data exchanges between the controlling entity and all the operating locomotives as well as all equipped wayside devices. Minimal communications latency is a key design consideration to deliver and maintain the vital data and react quickly to changes in the operating environment, such as loss of communications.
For movement authority vitality, there are two areas of primary concern:
Concern no. 1 is handled by checking that no vital movement authorities have already been granted over any section of track that overlaps the proposed authority (except as rules permit) and also validating with the vital switch data that no switches are aligned improperly. Any conflict that is discovered causes, at a minimum, the movement authority to be rejected and potentially causes all conflicting authorities to be truncated at the point of requested overlap. The reason for rejection is returned to the non-vital components. The non-vital components may then attempt to propose a new authority with smaller limits, facilitating stacking of authorities.
Concern no. 2, reducing movement authorities, can also create an unsafe condition. In particular, if a train is still occupying the limits of the authority it was granted, the track must still be protected. If not, a new authority might be granted to a different train which puts it on the same track as the original train. This is especially true if automatic rollup of movement authorities is being performed on a leading train and given to the following train immediately in a moving block operation.
Updating the full movement authority for either case can be problematic with low-bandwidth/high-latency communications between a centralized server responsible for generating/modifying the movement authorities and the locomotive system, which must enforce the movement authorities.
In accordance with the illustrative embodiment of the present invention, the full movement authority that a train is expected to be granted (based upon the dispatcher's Track Authority) is transmitted to the train in advance, ideally under the high-bandwidth condition of a train yard. In accordance with the present invention, the definition of the movement authority includes a partitioning or segmenting of the full movement authority into much smaller “partial movement authorities” or “PMAs.” These partial movement authorities represent smaller segments within the movement authority.
The controlling entity provides, through regular messages, such as the Health Monitoring message (which contains information related to the vital data maintained by both the train and the controlling entity), the current limits of authority by including PMA information periodically. A train's onboard system would update the current limits of authority based upon this information.
This method therefore enables the current authority to be truncated or rolled up in a timely manner. Since only PMAs have to be sent upon authority update, rather than the full movement authority as in the prior art, the effects of low bandwidth or high latency networks are substantially reduced.
Also, since roll-up of authority occurs timely and on a regular basis, the separation between adjacent trains can be reduced, relative to the prior art. That is, once a first train has exceeded some of the authority it was granted, that portion of the authority is no longer required for the train. Since, in accordance with the illustrative embodiment, movement authority is segmented into a plurality of discrete or “partial” movement authorities, the partial authorities that are no longer necessary can be rolled-up (i.e., withdrawn) and granted to a second train that follows the first train.
Furthermore, if communication is lost, the train will not have true permission onboard to move across the entire movement authority limits. Rather, it will only have the permissions in the smaller set (i.e., the particular PMA) given in the last Health Monitoring message before the communications loss. At that point, railroad-specific rules for how to proceed over the limits of a movement authority without vital PMA confirmation will take effect (e.g., enforced move at a reduced speed, stop at limit of PMA, etc.).
In accordance with the illustrative embodiment, full movement authority 110 that train 104 is expected to be granted (i.e., based on a dispatcher's Track Authority) is sent to the train in advance over communications channel 108, advantageously under the high-bandwidth conditions in train yard 112.
In accordance with the present invention, movement authority 110 is partitioned into much smaller “partial movement authorities” or “PMAs.” These partial movement authorities represent smaller segments of full movement authority 110. Each partial movement authority provides permission for the train to proceed over a specific portion of track.
In the illustrative embodiment, movement authority 110 is sub-divided into eight partial movement authorities: PMA-1 through PMA-8. The division of movement authority 110 into eight partial movement authorities is strictly for illustrative purposes. In conjunction with the present disclosure, those skilled in the art will know how to subdivide movement authority into any convenient number of partial movement authorities.
In accordance with operation 202 of method 200, the expected full movement authority is partitioned into a plurality of partial movement authorities. Each partial movement authority represents the authorization for the train to movement over a portion of track.
Operation 204 recites transmitting, at a first time, at least one, but not all of the partial movement authorities to the train. As the train proceeds, partial movement authority information is periodically transmitted to the train from the controlling entity (i.e., a network control center). This is the process of updating the movement authority. In the prior art, this process involves transmitting the full movement authority, as updated to include any changes. By contrast, in the illustrative embodiment of the present invention, only a relevant and much smaller portion of the movement authority—namely, one or more partial movement authorities, are transmitted to the train.
The information pertaining to the partial movement authorities can be transmitted in conjunction with the routinely-transmitted “health monitoring message.” The health monitoring message nominally contains information pertaining to the vital data maintained by the train and the controlling entity. In accordance with the illustrative embodiment, the health monitoring message will also provide information pertaining to the current limits of authority per the included partial-movement-authority information.
As per operation 206, as the train proceeds, subsequent transmissions (e.g., health monitoring messages, etc.) will include further updates pertaining to then relevant partial movement authorities.
As depicted in
In the time period t10 through t14, train 104 is granted partial movement authorities PMA-2 through PMA-5. During that time, updates concerning those partial movement authorities may be received by train 104 over communications channel 308. Note that partial movement authority PMA-2 has not yet been rolled-up.
Between times t15 to t17, partial movement authority PMA-2 is rolled up. Train 104 is operating under partial movement authorities PMA-3 through PMA-5. Updates pertaining to those partial movement authorities will be received by the train during this period of time.
Beginning at time t18, partial movement authorities PMA-3 and PMA-4 are rolled-up and the train is operating under partial movement authorities PMA-5 through PMA-7 through time t25. Train 104 will receive updates over communications channel 308 pertaining to partial movement authorities PMA-5 through PMA-7.
Between time t26 through t27, train 104 is granted additional partial movement authority PMA-8. During this time period, train 104 will receive updates over communications channel 308 pertaining to partial movement authorities PMA-5 through PMA-8.
At time t28, partial movement authority PMA-5 is rolled-up. Between time t28 and t30, train 104 operates under partial movement authorities PMA-6 through PMA-8. During this period of time, the train will receive updates over communications channel 308 pertaining to partial movement authorities PMA-6 through PMA-8.
In this fashion, partial movement authorities are sequentially granted and rolled-up as the train proceeds along the track.
It is to be understood that the disclosure teaches just one example of the illustrative embodiment and that many variations of the invention can easily be devised by those skilled in the art after reading this disclosure and that the scope of the present invention is to be determined by the following claims.
This case claims priority of U.S. Provisional Patent Application Ser. No. 61/021,856, which was filed on Jan. 17, 2008 and which is incorporated herein by reference.
Number | Date | Country | |
---|---|---|---|
61021856 | Jan 2008 | US |