Braking systems and methods for determining dynamic braking data for a braking model for a train

What is claimed is: 1. A braking system including dynamic braking for a train having at least one locomotive with at least one on-board computer configured or programmed to: (a) before or during at least one braking event, determine predicted acceleration or deceleration of the train based at least partially upon an on-board braking model; (b) during the at least one braking event, determine actual train acceleration or deceleration of the train based at least partially upon sensed, measured, and/or calculated operating conditions; and (c) adjust at least one variable of the on-board braking model based at least partially on a specified difference between the predicted acceleration or deceleration and the actual acceleration or deceleration, wherein the on-board braking model is generated or modified based at least partially on a determined retarding force provided by each equipped or applicable axle of the train, and wherein the at least one on-board computer is further configured or programmed to determine the retarding force based at least partially on determining, sensing, and/or measuring the operating status, performance, available force, and/or condition of at least one of the following: (i) the at least one locomotive; (ii) at least one locomotive consist; (iii) at least one component of a dynamic brake system, or any combination thereof. 2. The braking sytem of claim 1 , wherein at least one of steps (a)-(c) is implemented or occurs substantially in real-time. 3. The braking system of claim 1 , further comprising determining the retarding force based at least partially on the level of dynamic brake excitation and/or measured dynamic brake energy. 4. The braking system of claim 1 , further comprising determining retarding force based at least partially on railroad operating rules and/or cut-out axles. 5. A braking system including dynamic braking for a train having at least one locomotive with at least one on-board computer configured or programmed to: (a) before or during at least one braking event, determine predicted acceleration or deceleration of the train based at least partially upon an on-board braking model; (b) during the at least one braking event, determine actual train acceleration or deceleration of the train based at least partially upon sensed, measured, and/or calculated operating conditions; and (c) adjust at least one variable of the on-board braking model based at least partially on a specified difference between the predicted acceleration or deceleration and the actual acceleration or deceleration, wherein the on-board braking model is generated or modified based at least partially on a determined retarding force provided by each equipped or applicable axle of the train, wherein dynamic brake-generated retarding force is determined using the following formulae: total axle count=(number of cut-in locomotives)*(axles per locomotive) if (total axle count>max DB axle count per rule) then (total axle count=max axle count) retarding force=(total axle count−de-rated axle count)*(DB force per axle). 6. The braking system of claim 1 , further comprising accumulating or analyzing the predicted train acceleration or deceleration and the actual train acceleration or deceleration over a period of time, and optionally, normalizing the accumulated data. 7. A braking system including dynamic braking for a train having at least one locomotive with at least one on-board computer configured or programmed to: (a) before or during at least one braking event, determine predicted acceleration or deceleration of the train based at least partially upon an on-board braking model; (b) during the at least one braking event, determine actual train acceleration or deceleration of the train based at least artially upon sensed, measured, and/or calculated operating conditions; and (c) adjust at least one variable of the on-board braking model based at least partially on a specified difference between the predicted acceleration or deceleration and the actual acceleration or deceleration, wherein the on-board braking model is generated or modified based at least partially on a determined retarding force provided by each equipped or applicable axle of the train, wherein: (a) if the actual train deceleration is less than the predicted train deceleration by a specified amount, the adjustment step (c) comprises: (i) removing one axle's worth of force; or (ii) de-rating one axle's worth of force, in subsequent brake model calculations; or (b) if the actual train deceleration is greater than the predicted train deceleration by a specified amount, the adjustment step (b) comprises at least one of: (i) adding one axle's worth of force; or (ii) rating one axle's worth of force, in subsequent brake model calculations. 8. The braking system of claim 7 , further comprising repeating adjustment step (b) for the predicted train acceleration or deceleration and the actual train acceleration or deceleration over a subsequent period of time. 9. The braking system of claim 8 , wherein, upon reducing the difference between the predicted train acceleration or deceleration and the actual train acceleration or deceleration to a specified level, adjusting the braking model for subsequent braking events. 10. The braking system of claim 1 , wherein at least one safety factor of the on-board braking model is generated by: (a) receiving or determining at least one initial safety factor; (b) receiving or determining at least one dynamic braking adjustment factor based at least partially on (i) the expected dynamic braking force, and (ii) specified retarding forces of the train; and (c) determining at least one new safety factor based at least partially on the initial safety factor and the dynamic braking adjustment factor. 11. The braking system of claim 1 , wherein the at least one variable comprises dynamic braking force data.