Patent Grant
7312590
Model train systems have been in existence for many years. In the typical system, the model train engine is an electrical engine which receives power from a voltage which is applied to the tracks and picked up by the train motor. A transformer is used to apply the power to the tracks. The transformer controls both the amplitude and polarity of the voltage, thereby controlling the speed and direction of the train. In HO systems, the voltage is typically a DC voltage. In other systems, the voltage may be an AC voltage transformed from the 60 Hz line voltage available in a standard wall socket.
A variety of mechanisms are used to control velocity of model trains. In the traditional approach shown in
When wiper 702 is located at zero position 703, no connection is made on the secondary side of the transformer, and thus no voltage is available to operate the locomotive. This comprises the stopped condition.
When wiper 702 is located at full power position 704, the largest number of turns on the secondary winding is the connection point, and thus all available voltage is supplied to model train. This constitutes the fastest velocity the train can travel.
At any position lying between the no connection point and the maximum number of connected windings, a portion of the maximum voltage will be output of the secondary side. The resolution of this control is determined by the number of secondary winding connections. In a typical transformer, the number of secondary winding connections is between about forty and eighty, over an angular range of knob positions of about 90°.
Conventionally, the power applied by transformer 4 to track 2 is increased as knob 6 is turned in the clockwise direction, and decreased as knob 6 is turned in the counter-clockwise direction. As illustrated in
In another type of control system, a coded signal is sent along the track, and addressed to the desired train, conveying a speed and direction. The train itself controls its speed, by converting the AC voltage on the track into the desired DC motor voltage for the train according to the received instructions.
These instructions can convey commands relating to other than train speed, including for example signals instructing the train to activate or deactivate its lights, or to sound its horn. U.S. Pat. Nos. 5,441,223 and 5,749,547 issued to Neil Young et al. show such a system and are incorporated by reference herein for all purposes. Due to this increase in complexity of model railroading layouts and equipment, it is desired to exercise more precise control over the velocity of locomotives.
For example, the above-incorporated control system utilizes a rotating control wheel to achieve higher resolution of train velocity. Such a control wheel allows continuous rotation in either direction with no fixed starting or stopping point. Such a rotating control wheel typically generates approximately fifty signals per revolution. Thus a particular system featuring a total resolution of two hundred speed steps would require four complete revolutions of the control wheel by the user to move from zero to full speed.
This conventional command control approach to regulating train velocity offers the advantage of conferring greater granularity over the control of velocity. This approach, however, requires that more physical effort be exerted by the user to turn the knob multiple times, in order to produce the same speed resulting from less than one twist of the knob of the device shown in
This enhanced physical effort offers at least two disadvantages. First, the extra time required to rotate the knob an additional distance may delay responsiveness between train speed and the controller. Second, the required physical manipulation of the control knob over greater distances may strain the wrist tendons/ligaments of a user.
Accordingly, there is a need in the art for a model train velocity controller which allows the user to rapidly exercise precise control over a wide range of speeds.
Control over velocity of a model train may be determined based upon the speed of rotation of a control knob. A processor receives an electronic pulse indicating rotation of the knob beyond a predetermined increment of angular distance. The processor calculates the amount of power ultimately conveyed to the model train based not only upon the number of pulses received, but also upon the elapsed time between these pulses. The shorter the elapsed time between pulses, the greater the change in power communicated to the train. Initially, a user can rapidly rotate the knob to attain coarse control over a wide range of velocities, and then rotate the knob more slowly to achieve fine-grained control over the coarse velocity. Utilizing the control scheme in accordance with embodiments of the present invention, in a compact and uninterrupted physical motion, a user can thus rapidly exercise both coarse and fine control over velocity of a model train.
An embodiment of a method in accordance with the present invention for controlling velocity of a model vehicle, comprises, providing a control wheel configured to rotate within a range of positions, and determining a speed of rotation of the control wheel. The magnitude of power provided to the model vehicle is correlated with a speed of rotation of the wheel.
An embodiment of an apparatus in accordance with the present invention for providing power to a model vehicle, comprises, a control wheel rotatable over a range of positions, a sensing element in communication with the control wheel and configured to detect a speed of rotation of the wheel, and a processor in electrical communication with the sensing element, the processor configured to correlate wheel rotational speed with a magnitude of power provided from a source to a model vehicle.
For further understanding of the nature and advantages of the invention, reference should be made to the following description taken in conjunction with the accompanying drawings.
Transformer 300 includes control knob 312. Control knob 312 controls the magnitude of the power applied to rails 304, and may occupy a range of positions corresponding to a complete rotation of knob 312. Movement of knob 312 in a clockwise direction results in application of power resulting in forward movement of the model train. Movement of knob 312 in a counterclockwise direction results in application of power resulting in backward movement of the model train.
Processor 359 receives input from first optical detector 804 and from second optical detector 805. Control knob 312 is in rotatable communication with disk 802 having slots 803. Depending upon the rotational orientation of disk 802, slots 803 are spaced to selectively permit light transmitted from source 351 to reach one of detectors 804 and 805. Successful transmission of the light through a slot 803 results in the respective optical detector 804 and/or 805 generating a voltage pulse for receipt by processor 359.
Conventionally, a processor receiving such an electronic pulse changes the applied power based only upon the number of pulses. For example,
Waveforms 600 and 601 exhibit 90° degree phase shift 616 relative to each other. This phase shift allows the direction of turning of the wheel and disk to be recovered from the pulses transmitted from the detectors to the processor.
In a conventional control scheme, an edge generates a signal for a single step velocity increase or decrease, based on the direction of rotation to the regulator, which is relayed to the model train. The velocity signal generated is limited to the number of edges comprising one complete revolution of the optical disk.
In order to provide for more fine-grained control over velocity control, it is possible to create an optical disk having more slots and therefore exhibiting a larger number of edges per revolution. Such a modified controller device, however, would exhibit a small angular distance between individual markings. This would cause difficulty in manipulating the device in order to accomplish a fine adjustment of train velocity.
Conversely, where angular distance between slots is increased to avoid this problem, a user would be forced to rotate the wheel more than one revolution in order to complete the entire speed range. In order to adjust speed to the same velocity over the same time, a user would be forced to rotate the wheel and disk more rapidly.
This is shown in
In accordance with embodiments of the present invention, control over velocity of a model train may be determined based upon the speed of rotation of a control knob. Specifically, processor 359 receives electronic pulses from optical detectors 804 and 805 that are in selective communication with optical source 351 through gaps 803 in an intervening optical disk 802. The gaps 803 in optical disk 802 are regularly spaced in predetermined increments 806 of angular distance.
Processor 359 receives the pulsed signals from elements 804 and 805, calculating therefrom the amount of power ultimately conveyed to the model train. This velocity calculation is based not only upon the number of pulses received, but also upon the elapsed time between these pulses. The shorter the elapsed time between pulses, the greater the power communicated to the train.
Unlike the conventional approaches shown in
Later during time T, however, the edges of the electrical pulses communicated from detectors 804 and 805 are spaced by a shorter time interval T2 between edges at 612. Processor 359 receives these signals, and applies a multiplier factoring in knob speed, to in order produce the changed velocity. Thus the correlation between pulse edges received and changes in velocity steps will exceed a 1:1 ratio for the time interval T2. This time is shorter in duration, indicating the operator requires faster acceleration or deceleration of the train. The second example could evaluated as one pulse multiplied by a rotational speed factor of two, resulting in a change of two. This would allow the same number of slots to exist on the wheel, without requiring twice the movement.
Application of a multiplier to govern train velocity can occur over a range of control wheel rotation speeds. For example, in accordance with one embodiment of the present invention, rotation of the wheel at speeds corresponding to one full rotation in greater than 200 ms could result in a multiplication factor of one. Rotation of a full turn over a time of between about 100-200 ms could result in a multiplication factor of two, rotation of a full turn over a time of between about 50-100 ms could result in a multiplication factor of three, rotation of a full turn over a time of between about 25-50 ms could result in a multiplication factor of four, and rotation of a full turn over a time less than 25 ms could result in a multiplication factor of eight.
Still later during time T, the edges of the electrical pulses communicated from detectors 804 and 805 are spaced by an even shorter time interval T3 between edges at 613, T3<T2<T1. Processor 359 receives these signals, and applies an even greater multiplier to produce the changed velocity. Thus the correlation between pulse edges received and changes in velocity steps will exceed the ratio for the time interval T2.
In a third example, times 612 and 613 would could have a speed multiple factor of four and eight, respectively. Utilizing the former speed factor of four, a wheel conventionally generating fifty edges per revolution could output one hundred speed step changes within a wheel rotational arc of only 180°, or two hundred speed step changes within a wheel rotational arc of 360°. Utilizing the latter speed factor of eight would require only a half a complete turn of the control knob to complete the two hundred speed step command.
Initially, a user can rapidly rotate the knob to attain coarse control over a wide range of velocities, and then rotate the knob more slowly to achieve fine-grained control over the coarse velocity. Utilizing the control scheme in accordance with embodiments of the present invention, in a compact and uninterrupted physical motion, a user can rapidly exercise both coarse and fine control over velocity of a model train.
It is important to note that velocity adjustment in accordance with the present invention is operable both to achieve both acceleration and deceleration of a moving train. Thus movement of the control wheel in an opposite direction can rapidly and effectively reduce the amount of power provided to the locomotive, causing it to stop, and even accelerate in the reverse direction if necessary.
Although one specific embodiment has been described above, the present invention can be embodied in other specific ways without departing from the essential characteristics of the invention. Thus while
For example, rotation of a control knob over an angular distance could be detected through selective reflection, rather than transmission, of a light beam. In one such alternative embodiment shown in the simplified schematic drawing of
And while the above-referenced embodiments have focused on the use of optical principles to generate electronic pulses correlating to movement of the disk, this is also not required by the present invention. In accordance with still other alternative embodiment shown in the simplified schematic drawing of
While
Moreover, the control knob and processor need not be housed in the same structure as the power regulator. In addition, the processor need not be in wired communication with the power regulator. In accordance with certain embodiments, the processor may be in wireless communication with the power regulator, as depicted in
And while the specific embodiment described above causes greater power to be delivered by knob rotation beyond a threshold speed, this is not required by the present invention. In accordance with alternative embodiments, knob rotation below a recognized threshold speed may result in the application of greater or less power.
Moreover, while the specific embodiment of
In addition, the increasing complexity of track layouts and equipment utilized by model railroading hobbyists may feature more than one locomotive running on the same track. In such settings, it may be desired to independently exercise control over the velocity of each train. Accordingly, more advanced model railroading systems may include wireless interface devices allowing selective communication with different engines running along the same track.
Example Train Layout
Power master unit 150 modulates AC track power to the track 16 and also superimposes DC control signals on the track to control special effects and locomotive 24′. Locomotive 24′ is, e.g., a standard Lionel locomotive powered by AC track power and receptive to DC control signals for, e.g., sound effects.
Base unit 14 transmits an RF signal between the track and earth ground, which generates an electromagnetic field indicated by lines 22 which propagates along the track. This field will pass through a locomotive 24 and will be received by a receiver 26 inside the locomotive an inch or two above the track. Locomotive 24 may be, e.g., a standard locomotive retrofitted or designed to carry a special receiver 26.
The electromagnetic field generated by base unit 14 will also propagate along a line 28 to a switch controller 30. Switch controller 30 also has a receiver in it, and will itself transmit control signals to various devices, such as the track switching module 32 or a moving flag 34.
The use of both base unit 14 and power master unit 150 allows operation and control of several types of locomotives on a single track layout. Locomotives 24 which have been retrofitted or designed to carry receiver 26 are receptive to control signals delivered via base unit 14. Standard locomotives 24′ which have not been retrofitted may be controlled using DC offset signals produced by power master unit 150.
The remote unit can transmit commands wirelessly to base unit 14, power master unit 150, accessories such as accessory 31, and could also transmit directly to train engines instead of through the tracks. Such transmission directly to the train engine could be used for newer engines possessing a wireless receiver, while older train engines would continue to receive commands through the tracks.
Remote unit 12 includes control knob 12a that is actuable in accordance with the present invention. Remote unit 12 also includes mechanism 19 for determining both the position and speed of rotation of control knob 12a, for example a wheel having spokes configured to selectively permit transmission of light along a pathway, as described above in connection with the Embodiment of
When knob 12a of wireless interface device 12 is turned slowly, the location of the knob dictates the velocity of the selected locomotive. When, however, knob 12a of the wireless interface 12 is turned more rapidly, this rotational speed may dictate velocity of the selected locomotive.
While the specific embodiments described above relate to methods and apparatuses for controlling the velocity of model trains moving on a track, the present invention is not limited to this particular application. In accordance with alternative embodiments, the velocities of other types of model vehicles moving on a track could also be controlled, for example the speed of a slot car. The control mechanism in accordance with embodiments of the present invention is also not limited to controlling the velocities of tracked vehicles, but could also be utilized to exercise remote control over model vehicles such as boats and aircraft.
Accordingly, the foregoing description is intended to be illustrative, but not limiting, of the scope of the invention which is set forth in the following claims.
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