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Description  |
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FIELD OF THE INVENTION
The present invention relates to positioning systems for rail vehicles and
more particularly, concerns rail vehicle positioning systems which utilize
a combination of positioning sources such a global positioning systems
(GPS) technology, trackside transponders, track circuits and wheel
tachometer inputs.
BACKGROUND OF THE INVENTION
In the past, rail vehicle positioning has been accomplished in two
predominant manners. The traditional vehicle positioning system has used
embedded track circuits which are insulated or electrically isolated
sections of track with a voltage applied at one end, which are shunted by
a vehicle and indicate that a vehicle is located at a certain segment of
the track. Such a system is described in U.S. Pat. No. 4,361,301 entitled,
"Vehicle Train Tracking apparatus and Method" and was issued to Donald G.
Rush on Nov. 30, 1982, which is incorporated herein by this reference.
Another improved system, has included dead reckoning with wheel tachometer
readings which are corrected by trackside transponder units. Such a system
is described in U.S. Pat. No. 4,027,840 entitled, "Vehicle Position
Indicator with Radar Interrogation Each of Spaced Transponders Disposed
Along Pathway for the Vehicle", which was issued to Peter Kenneth Blair on
June 7, 1977, which is incorporated herein by this reference.
While these systems, or variations of them, have enjoyed use in the past,
they each have several serious drawbacks. The traditional embedded track
circuit method as a weakness, because it provides low resolution of
position typically one or more miles. Also, there is no way to distinguish
whether one or more trains are occupying the same track segment. The
trackside transponder (or indicator) and wheel tachometer dead reckoning
method has problems, because the wheel slip, between the locomotive wheel
and the rail, causes uncertainty in the accuracy of the wheel tachometer.
The ability to provide accurate position is also a function of the number
of the expensive trackside transponders that are used.
The inability to continuously ascertain the precise location of a train on
a rail network results in an inefficient use of the track resources
because the dispatching, routing, or authorization of trains on a
particular track is often delayed until all uncertainties of train
locations about the network are resolved.
Consequently, there exists a need for improvement in rail vehicle
positioning systems which have a high degree of accuracy while
concomitantly reducing the need for trackside transponders.
SUMMARY OF THE INVENTION
It is an object of the present invention to provide a highly accurate rail
vehicle positioning system.
It is a feature of the present invention to use a combination of sources
including GPS technology, trackside transponders, track circuits and wheel
tachometer readings to perform position determination.
It is an advantage of the present invention to provide position information
over a wide geographic area without requiring trackside transponders over
the entire length of track.
The present invention provides a rail vehicle positioning system which is
designed to fulfill the aforementioned needs, satisfy the earlier
propounded objects, contain the above described features and produce the
previously stated advantages. The invention is carried out in a "trackside
transponder-less" fashion, in the sense that the large numbers of
trackside transponders which would be necessary if they were the sole
source of position determination are substantially reduced along a large
majority of the track length. Instead, the rail vehicle positioning
system, utilizes a multiplicity of sources including track circuits,
transponders, and GPS data to update the wheel tachometer and further uses
GPS data to affect wheel tachometer calibrations.
Accordingly, the present invention relates to a rail vehicle positioning
system which includes a GPS receiver, a reduced number of trackside
transponders (or no trackside transponders), track circuits, a wheel
tachometer and a computer which calibrates the wheel tachometer where
available using GPS data and further performs a dead reckoning function.
BRIEF DESCRIPTION OF THE DRAWINGS
The invention may be more fully understood by reading the following
description of the preferred embodiments of the invention in conjunction
with the appended drawings wherein:
FIG. 1 is a schematic representation of the rail vehicle positioning system
in its intended environment.
FIG. 2 is a diagram of the apparatus and method in which information is
utilized, on and off board the rail vehicle, in its position determining
function.
DETAILED DESCRIPTION
Now referring to the drawings, and more particularly to FIG. 1, there is
shown a first locomotive, generally designated 100, on a first rack 101.
Locomotive 100 is shown having a Train Control Computer (TCC) 102 which is
coupled with train/base radio 103 having antenna 105. TCC 102 is
preferably a microprocessor controlled digital computer, capable of
performing numerous variable functions, which are necessarily variable to
accommodate different locomotive types, radio systems, trackside
transponders and etc., all of which are to some extent a matter of the
system designer preference. Train/Base Radio 103 is preferably a
communication system that is capable of transmitting and receiving data
signals at a relatively high data rate. Train Control Computer (TCC) 102
is also coupled with wheel tachometer 104, or the like, and the
combination of GPS antenna 106 and receiver 107. GPS satellite 108 is
schematically shown transmitting a signal. (Note--several GPS satellites
would typically be transmitting signals to a covered area at any given
time)
Train Situation Indicator (TSI) 109 is coupled with TCC 102 and is
preferably an interactive display device for both receiving information
from and displaying information to a train crew member. TSI 109 may be
either a touch screen display device for both displaying information and
receiving information or it may be bifurcated into separate components
including one means for displaying and another means for receiving manual
input of information, both of which are well known in the art. OS circuit
122 and switch position detector 124 are preferably RF coupled through
antenna 105 and radio 103 to TCC 102 and through base antenna 113 and base
radio 114 to base control computer (ROCS) 116, which is preferably coupled
with dispatchers console 118. Transponder 120 is coupled by transponder
interrogator 121 to TCC 102. OS Circuit 122 and detector 124 may also be
only coupled indirectly to TCC 102 and directly to only base radio 114 and
ROCS 116. ROCS 116 is preferably a computer, similar to TCC 102 which is
capable of performing numerous variable functions, which are necessarily
variable to accommodate different locomotive types radio systems,
trackside indicators and etc., all of which are to some extent a matter of
the system designers preference.
In operation, the rail vehicle positioning system operates by the TCC 102
receiving GPS signals, from satellite 108, together with wheel tachometer
signals, from wheel tachometer 104, and transmitting this information by
train/base radio 103, back to the base antenna 113 at the base station 112
where the data is manipulated by ROCS 116 in a manner similar to that
discussed below, and retransmitted back to radio 103 and possibly, if
desired to any other radio on any other locomotives, (not shown). However,
the data manipulation can also be performed in the TCC 102. It is
understood that through this description, that all functions performed by
ROCS 116 or TCC 102 may be performed by either ROCS 116 or TCC 102. The
degree of duplication between functions performed by the ROCS 116 and TCC
102 and the and the degree of separation of such functions is a matter of
designers choice for the particular needs and wants of any particular
customer.
A more detailed understanding of the position determining function of the
present invention can be achieved by referring to FIG. 2, where like
numbers and matter refer to like numbers and matter of FIG. 1 and their
accompanying text.
FIG. 2 depicts a system and method, of the present invention, which results
in a position report, which is preferably divided into a GPS data block
and a dead reckoning data block. Exterior dashed line 200 represents the
equipment on board the locomotive 100 (FIG. 1). The interior dashed line
represents equipment and functions which could all be performed by TCC
102. Wheel tachometer 104 generates pulses which are used by the dead
reckoning filter 202 to determine speed. Dead reckoning filter 202 is
preferably a process performed by TCC 102 which compares velocity and
position data, and rejects inconsistent data. GPS receiver 107 also
generates a speed and position signal which is input to the TCC 102 to
indicate position and speed, and also to calibrate the wheel tachometer
104. GPS receiver 107 also inputs a speed signal into TCC 102. The TCC 102
determines the best source of speed signal. In making such determinations
the GPS speed is generally preferred when it is greater than 10 miles per
hour or when wheel slip is detected; otherwise, CPS calibrated wheel tach
104 speed is used. TCC 102 routes this best speed signal to integrator
204, differentiator 206 and to bus 210. The integrator 204 determines
distance traveled by integrating the speed signal output from TCC 102.
Integrator 204 outputs a distance signal which can be compared in TCC 102,
with a distance signal input from the locomotive engineer at the TSI 109
or with distance signals from an OS circuit 122 or a transponder 120 to
provide a more accurate distance signal. The differentiator 206 determines
acceleration by differentiating the speed signal output from the TCC 102.
Integrator 204 and differentiator 206 can be performed by numerous devices
and methods which are generally known and are commercially available. The
values of speed, distance and acceleration constitute the dead reckoning
data block of the position report. The sign of the speed indicates
direction of travel with respect to the train route as defined by the
origin and destination of the train. The GPS block of the position report
contains position, velocity, speed, heading, and time. The position report
generated by the TCC 102 is transmitted by train/base radio 103 to base
station 112. Base station 112 is preferably where a dispatcher has direct
access to dispatcher's console 118 and train/base radio 103.
In operation, the rail vehicle positioning system, of the present
invention, is initialized as follows. The dead reckoning data block,
discussed above, represents distance from a defined point in the ROCS 116
or TCC 102 database constituting the trains route. When initializing the
train position at the start of a trip, the ROCS 116 or TCC 102 determines
the initial location of the train, either automatically or manually, i.e.
from input by the locomotive engineer at the TSI 109 in terms of distance
on the first segment of the route. Segment distance refers to the method
of representing location on a track. The segment is a section of
unbranched track (not including sidings). Points on a segment are
preferably measured in distance from the east end starting with zero. This
initial distance is received by the TCC 102 and subsequent TCC 102
generated distances are directly related to route distance from that
point. Route distance herein refers to the ever increasing distance
accrued on a single trip, i.e., since the initialization of the TCC 102.
After initializing the train position at the start of a trip, two methods
are used to correct the TCC's calculation of position. First of all, ROCS
116 or TCC 102 has accurate train position when the GPS data block is
being received in the position report. GPS derived position is translated
in ROCS 116 or TCC 102 to route distance. At periodic intervals, ROCS 116
may send a time tagged distance value corresponding to GPS derived
position to the TCC 102. Alternately, the TCC 102 can independently
generate such a time tagged distance value corresponding to GPS derived
position. The TCC 102 uses this input as a correction to its next dead
reckoned data block report and flags it as corrected. Because GPS speed is
being simultaneously sued by the TCC 102 as a basis of its calculations,
these corrections are expected to be of small magnitude.
In the absence of GPS, ROCS 116 or TCC 102 uses the well known central
train control (CTC) generated OS passage indications to determine known
positions of the train in sections of track so equipped. ROCS 116 or TCC
102 similarly translate this to route distance. Because in this case,
wheel tach 104 is the only source of speed for the TCC 102, with its
attendant problems of slip and calibration, and because OS reports are
relatively infrequent, these corrections may be of significant magnitude.
Secondly, the TSI 109 provides a mechanism by which the locomotive engineer
can input current location in terms of mile post. The TSI 109 preferably
contains a database which allows it to translate the mile post location to
distance along the train's route and then sends it to the TCC 102 which
uses it to correct the next dead reckoning data block.
The onboard display, TSI 109, is driven by the TCC 102 distance output. To
display train position, the TSI 109 uses a database to translate route
distance to location on the route and can therefore show the train moving
along in reference to geographical features and mile posts stored in the
data base. The database is uploaded from ROCS 116 or TCC 102 and defines
the route, which is a concatenation of track segments over which the train
is expected to travel. In a case where the entire route is unknown at
initialization, the TSI 109 can still support the display of train
movement if it receives from ROCS 116 or TCC 102, an indication of
direction of travel on the first segment. In this case, ROCS 116 or TCC
102 must send a timely message later which includes additional route
information.
In ROCS 116, vehicle position reports are being received at a rate
preferably based upon the speed of the vehicle. Also, ROCS 116 can
determine when to expect the next report by looking at the speed value in
the current report. ROCS 116 and TCC 102 evaluates each input for
reasonable consistency with previous reports and other applicable reports,
and accepts or rejects it as appropriate. Additionally, trackside
transponders are showing progressive movement along tracks. It is in ROCS
116 or TCC 102 that the various sources of information are integrated to
create a unified, consistent picture of traffic and traffic flow.
A necessary and crucial step in creating the consistent picture of traffic
flow is resolving ambiguities between the information from the various
sources. An early component of this resolution of ambiguities is
validation of the information from the several sources. Another step is
correction of the sources when possible. Finally, it is necessary to have
a prioritization of sources.
For example, GPS data reports, once determined to have arrived over the
datalink uncorrupted, undergo the following tests:
1. The three dimensional position is mapped on a tangent plane defined for
the region.
2. The database is searched for a track segment, the end points of which,
bracket the GPS position and for which the cross-track error is less than
some maximum which depends on figure of merit (FOM) and depth of curve. If
no track segment is found which meets these conditions, then the position
report is rejected.
3. Distance along the track is determined by interpolating between points
stored and the database for the track segment.
4. The new train location is checked for reasonableness against the
previously accepted position, taking into account reported velocity,
maximum velocity and physical acceleration limits. Any report rejected at
this point is saved for future reference.
5. The direction of travel is established or confirmed by using the
velocity vector in the tangent plane. A report passing all tests is
accepted and stored as a position fix for the vehicle. Position fix refers
to the location a vehicle is known to have achieved according tot he last
position report which was accepted as uncorrupted and reasonable, and was
unambiguously assigned to a vehicle. When the train length is known, an
end of train position is also stored at this time.
When a train position report is received in ROCS 116 with no valid GPS
block in it, then the distance is taken from the dead reckoning data block
portion of the position report. Reasonableness checks similar to the above
checks for GPS data reports are performed, and if accepted, the report is
stored as a position fix for the vehicle.
Dead reckoning data blocks, of the position reports, which are flagged to
indicate corrected data, may fall the reasonableness test but are stored
for further reference in subsequent reasonableness tests.
Train position reports, including both GPS data block and dead reckoning
data block, provide an acceptable and precise along-the-track position,
but neither one can indicate which of parallel tracks the train is on.
Transponder indicators, track occupancies, switch positions train crew
entries and manual dispatcher entries are also used to resolved these
ambiguities.
While GPS is available, it is preferred that no other source of position
information is used to generate a position fix, though they may be used to
resolved ambiguities. In the absence of GPS and for non-reporting
vehicles, any of the other sources (dead reckoning, transponder, OS
circuits, dispatcher entry, etc.), once accepted as reasonable and
assigned to a vehicle, are stored as a position fix for that vehicle. When
a vehicle is reporting dead reckoning position only, successive track
occupancy indications are used to validate the direction of travel
indicated by the dead reckoning data blocks. This reduces the time to
recognize an error in locomotive switch settings which drive the TCCs
sense of direction. The correction sent to the TCC, when a direction error
is noted, causes the TCC to reverse its directional logic.
When transponders are available, but GPS is not, transponders are preferred
for the fix.
When GPS is not available and the train is in a territory where no track
circuits and no transponders are present to aid in confirmation of
direction, ROCS 116 shall prompt the dispatcher to confirm manually, or
preferably TCC 102 shall prompt the locomotive engineer to confirm
manually.
Also track occupancies and OS reports are used to track non-equipped
vehicles, and OS reports are used to correct dead reckoning distance and
OS entries when GPS is unavailable. Additionally, track circuits around a
switch are used to verify that a train has cleared the main at a turnout.
When no train generated reports are available, best estimate of speed is
derived by averaging time between OS reports.
Manual entry of position made by the dispatcher is required in dark
territory for non-reporting trains, for correcting dead reckoning distance
when GPS is unavailable, and for resolving ambiguities where switch
position is unknown. The entry is assumed to be correct, although, it is
subjected to gross reasonable tests and the dispatcher is prompted to
verify the entry if it fails these tests.
ROCS 116 maintains current best estimate of position for all trains through
a dead reckoning calculation based on last reported speed and direction,
known speed restrictions, train acceleration parameters, and commanded
pacing speeds. The best estimate of position (BEOP) is preferably updated
at a minimum of once every two minutes and is preferably set to agree to
new position fixes. This allows the display function to show both the last
known position of the end of the train and the estimated (probable)
position of the front of the train at any time.
The position of track maintenance forces is preferably based on GPS reports
from the vehicle or manual dispatcher entry (or possible track circuit
transponders). Special consideration is made for those vehicles which can
be off the track. The threshold for off-track error may be greater than
for trains so as to assume the worst case (on track causes potential
hazard). When dealing with nearby train traffic, the dispatcher will
confirm verbally with track maintenance forces whether they are on or off
track. Those reports which are not accepted as on track are mapped to a
locally referenced grid but are not displayed on the track charts.
The foregoing description has essentially described the rail vehicle
positioning system of the present invention. The operation and
construction of the rail vehicle positioning system of the present
invention is performed by the rail vehicle tracking computer algorithm
which is implemented either by ROCS 116 or TCC 102 and is individually
prepared for the peculiar needs of a particular railroad customer. The
purpose of the vehicle tracking algorithm is to provide a best estimate of
position for all vehicles. The algorithm will accept inputs entered by
dispatchers for vehicle I.D. and location, special moves definition and
train length. The algorithm also accepts GPS, dead reckoning, position
transponder and OS position reports from equipment on board locomotives
and also accepts track vehicle type inputs.
While particular embodiments of the present invention have been shown and
described, it should be clear that changes and modifications may be made
to such embodiments without departing from the true scope and spirit of
the invention. It is intended that the appended claims cover all such
changes and modifications.
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