KR101487521B1 - System for controlling automatically a train using smart signal - Google Patents

Abstract

A train control system using a smart signal according to a preferred embodiment of the present invention includes a laser module for emitting laser light forward of a train and emitting light at a width of a pair of rails, A control unit for receiving the returned laser light to calculate a distance to the object in real time and determining whether the train is braked according to the calculated distance; and a warning for warning when the control unit determines that the train is required to be braked And the controller determines that the distance is shorter than the initially set laser emission distance of the laser emitted from the laser module. As a result, it is possible to determine whether the object is present on the trail front side of the train by the laser module, and it is possible to calculate the distance between the determined object and the train, so that the traveling speed and the separation distance of the current train are compared So that the train accident can be prevented in advance.

Description

TECHNICAL FIELD [0001] The present invention relates to a train control system using a smart signal,

The present invention relates to a train control system using a smart signal such as a laser sensor, and more particularly, to a train control system using a smart sensor, such as a laser sensor, by installing a laser emitting light in front of a train without installing other complicated terrestrial signals and on- The present invention relates to a train control system using a smart signal that can automatically control a traveling speed of a train in accordance with a distance between the train and a preceding train traveling forward.

In general, trains are able to carry many passengers as well as carry a lot of cargo compared to ordinary cars, so they are being illuminated again as transportation vehicles not only in transportation and logistics but also in environmental pollution problems. In recent years, the use of trains has been gradually increasing with the increase in the quantity of goods and the appearance of high-speed trains.

These trains are designed to run at high speeds on a railway car by connecting a number of trains to a power train in front of the train, which can cause many casualties and material damage in the event of an accident. have.

In this way, trains are operated with limited number of trains, which limits the use of trains and thus the speed of trains. In addition, due to the nature of the train 's operation, it is necessary to prevent the occurrence of a collision by coordinating the service between the preceding train and the trailing train.

Accordingly, there have been proposed various methods of controlling the trains of the trains by determining the occupancy of the trains of the preceding trains. Among these measures, the ATS system (Automatic Train Stop System) and the ATP system System: Automatic Train Protect System).

The ATS system is a system that divides a railway line that a train travels into a certain section and causes the train to decelerate at a limited speed and forcibly stops the train if it is not decelerated within a predetermined time. The stop signal (R), the boundary signal (YY) caution signal (Y), the deceleration signal (YG) and the progress signal (G) are displayed for each section in the case of the five-system system based on the section occupied by the occupied unit , The stop signal (R), the caution signal (Y) and the progress signal (G) are displayed for each section in the case of the three-time system.

At this time, the generated signal for each section is transmitted from the ATS receiver box installed in each section to the ATS receiver box of the train, which is a well known technique. In brief description, it is assumed that a predetermined section (hereinafter referred to as' The ATS ground is oscillated according to the present signal. When the ATS car box is passed by the ATS interference masturbation, the resonance frequency of the ATS ground is detected by the frequency induction phenomenon, It is decelerated at a limited speed according to the frequency.

However, in the ATS system, there is no information on the distance between the preceding train and the trailing train, the installation position of the ATS ground, and the separation distance between the ATS ground and the ATS, so that the system simply decelerates to the predetermined speed before entering the corresponding section, There is a problem in that a limited line is inefficiently used due to an unconditionally mechanically decelerating operation even if the train in operation is separated from the preceding train by more than a braking distance sufficiently or the train is operated inefficiently.

On the other hand, the ATP system is equipped with a ground ballis for each section of the line, and receives information on the distance from the ground floor balise to the preceding train, the position where the ground ballis is installed, So that it is possible to increase the efficiency of train operation by using the line more efficiently.

However, in the case of the ATS system or the ATP system for efficiently using the limited line as described above, when the trajectory is occupied by the preceding train, the corresponding signal is transmitted to the trailing train through the ATS ground or through the ground ballis, In case of an abnormal situation such as an abnormal obstacle in the railway track, there is a problem that it can not cope with this situation.

Further, since the ATS ground box and the ground balisse are installed so as to be spaced apart from each other, there is a problem that it is difficult to acquire train line information between them (such as where the preceding train is located therebetween).

In addition, the ATS system and the ATP system require a ground box or balise to be installed at a predetermined interval on the ground of the train line, and a signal system for transmitting these signals must be established. In addition, The overall system construction cost and maintenance cost increase.

In addition, these ATS systems and ATP systems can not be exchanged in parallel, and only trains of ATS system trains or ATP systems can be operated.

In order to compensate for or solve the problem that the interval between the trains is limited by the length of the blockage period, the motion blocking method that does not use the track circuit has been proposed.

The mobile closure system is divided into a system using an inductive loop and a system using a wireless communication. The next train obtains the position and speed of the preceding train, calculates a braking curve proportional to the target speed, calculates the minimum distance in real time It is an occlusion system that operates.

However, in the case of the system using the induction loop, the induction loops are installed in the entire line at regular intervals (approximately 25 m) in the middle of the rail, and when the train passes through the induction loop, It is necessary to detect the position of the train. Due to the low density of the communication band, there is a limit to display various train conditions in the control facility because the information can not be exchanged much. The maintenance cost of the induction loop is increased.

Also, in the case of a system using wireless communication, a ground is not used such as an induction loop for detecting the position of a train within a block, and a radio is used to communicate with the ground. The position of the train is set at a constant interval In order to recognize the absolute position of a train by using a pond, wireless communication may cause confusion, interference and hacking of communication, and it may be difficult to secure the stability of the radio communication. In addition, There is a problem that the cost increases.

In addition, an obstacle device is installed in front of the train in order to determine whether there is an obstacle in front of the train line. This obstacle device is similar to a bumper of a general automobile. There is a problem that the collision with the obstacle can not be prevented originally.

In addition, although a line manager is installed to visually check the presence of obstacles, there is a limit to the manual control, and it is impossible to manage the entire line.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a system capable of automatically detecting whether an obstacle is present in front of a train by a train, have.

In addition, the present invention is not limited to the signal system of a train, but it is also an object of the present invention to provide a system which can newly transmit a train to a line in which a signal system is built.

According to a preferred embodiment of the present invention, there is provided a train control system using a smart signal, comprising: a laser module emitting laser light in front of a train and radiating light with a width of a pair of rails; A control unit for receiving the laser light returned by the object after being emitted from the laser module to calculate a distance from the object in real time and determining whether the train is braked according to the calculated distance; And a warning unit for warning when the control unit determines that the train is required to be braked. The control unit may control the laser beam emitting unit .

As a result, it is possible to determine whether the object is present on the trail front side of the train by the laser module, and it is possible to calculate the distance between the determined object and the train, so that the traveling speed and the separation distance of the current train are compared So that the train accident can be prevented in advance.

Further, it is preferable that the train is automatically braked when the train is not braked after the warning section is activated.

It is preferable that the control unit judges the traveling speed of the vehicle and the traveling speed of the preceding vehicle to determine the relative speed between the vehicle and the preceding vehicle and controls the running speed of the train.

This makes it possible to automatically brak down the train if the command to brake the train is not executed after a certain period of time has elapsed after warning that the object is present in front of the train running, thereby preventing double accidental train accidents .

In addition, it can be judged that this object in front is not an obstacle falling on a train line but a preceding train traveling forward, so that it is possible to determine the distance from the preceding train, the speed of the current train, It is possible to control the safety distance to the front preceding train.

In addition, the installation of complicated ground signal systems and onboard signal systems such as conventional automatic train stop (ATS), automatic train protection (ATP) or automatic train operation (ATO) It is possible to automatically operate the train by installing a laser module that emits and receives the laser light forward in a simple manner.

Further, it is possible to effectively operate the line as in the conventional mobile occlusion method without constructing a complicated infrastructure such as a track circuit, a loop circuit, or a ground wireless communication device with respect to the ground line, and to greatly reduce the maintenance, .

At least one ground laser module that emits a laser beam forward in a train traveling direction in a gradient section or a curved section; And a terrestrial transmission / reception unit for transmitting the measured data signal from the terrestrial laser module to a traveling train.

The control unit may determine a data signal transmitted from the terrestrial laser module, a position of the terrestrial laser module, and a position of the subject vehicle, and judges that the signal is a foreign object when a signal shorter than the initially set emission distance of the terrestrial laser module is received , It is preferable to determine the distance between the object and the ground laser module, and then determine the distance between the train and the object based on the distance.

Thus, even if the line traveled by the train is a curved section or a gradient section, even if the laser module emitting light forward is a foreign object in a blind spot that can not be captured, the data can be obtained from the terrestrial laser module on the train. It is possible to obtain the same effect as determining the distance between the ground laser module and the ground laser module and the distance between the object and the laser module, It is possible to determine the object stably and control the traveling speed of the train appropriately.

It is preferable that the above-mentioned terrestrial laser module emits plane light with a width of a pair of rails.

This makes it possible to detect not only the object located on the rail but also the object lying or present between the pair of rails.

Further, it is preferable that the terrestrial laser module emits laser light when a trailing train is sensed.

At this time, a vibration sensing unit for sensing vibration generated when a train is traveling on the rear side rail of the terrestrial laser module is provided, and when the vibration is sensed, the terrestrial laser module is driven.

Further, when a signal is detected from the transceiver of the train in the terrestrial transceiver, the terrestrial laser module may be driven.

In this case, when the laser module emits and receives laser light for 24 hours, it takes time and expense to process, maintain and manage the laser module. Therefore, when the train enters the terrestrial laser module, So that data processing, maintenance, and management can be facilitated.

Meanwhile, the control unit receives the train running signal from the ground apparatus of the existing railway signal system, compares the determined distance with the object and determines whether or not to brak the train, and brakes the train in accordance with the signal to be braked more quickly .

This allows the train to be operated automatically using the laser module, as well as to operate in parallel with existing signaling systems, such as ATS, ATP or ATO, so that if there is a malfunction of the existing signaling system, In addition, in the case of the existing signal system, there is a limit that can only receive the ground information of the line only at the place where the ground box, ground device or ballis is installed. By supplementing this, it is possible to acquire the ground information of the line over the entire running track of the train So that a more stable train operation system can be constructed.

Preferably, the control unit adjusts the output of the laser module according to the traveling speed of the train.

Accordingly, when the running speed of the train is high, the braking distance is increased. Accordingly, it is necessary to detect the obstacle ahead or the preceding train farther ahead so that the emission range of the laser module is increased. When the running speed of the train is slow, The distance can be shortened so that the forward light emission range can be reduced so that the front obstacle or the preceding train can be more spaciously and precisely detected, so that the forward surveillance can be effectively performed according to the traveling speed of the train.

According to the train control system using the smart signal according to the preferred embodiment of the present invention as described above, it is possible to judge whether the object is present on the running front side of the train by the laser module, It is possible to calculate the distance between the trains, so that the traveling speed and the distance of the current train can be compared with each other to warn the train, thereby preventing a train accident from occurring.

In addition, if the command to brake the train is not executed after a predetermined time has elapsed after warning that the object is present in the front of the train, the train can be automatically braked and the train accident can be prevented in advance .

In addition, it can be judged that this object in front is not an obstacle falling on a train line but a preceding train traveling forward, so that it is possible to determine the distance from the preceding train, the speed of the current train, It is possible to control the safety distance to the front preceding train.

In addition, the installation of complicated ground signal systems and onboard signal systems such as conventional automatic train stop (ATS), automatic train protection (ATP) or automatic train operation (ATO) It is possible to automatically operate the train by installing a laser module that emits and receives the laser light forward in a simple manner.

Further, it is possible to effectively operate the line as in the conventional mobile occlusion method without constructing a complicated infrastructure such as a track circuit, a loop circuit, or a ground wireless communication device with respect to the ground line, and to greatly reduce the maintenance, .

In addition, when the line traveled by the train is a curved section or a gradient section, data can be obtained from the terrestrial laser module even in the case of a foreign object in a blind spot where the laser module emitting light forward can not be captured. It is possible to obtain the same effect as determining the distance between the ground laser module and the ground laser module and the distance between the object and the laser module, It is possible to determine the object stably and control the traveling speed of the train appropriately.

It is also possible to detect not only this object located on the rail but also this object lying or present between a pair of rails.

In addition, when the laser module emits and receives the laser light for 24 hours, it takes time and cost to process, maintain and manage the laser module. Therefore, when the train enters the terrestrial laser module, So that data processing, maintenance, and management can be facilitated.

In addition, not only can the train be operated automatically by using the laser module, but it also operates in parallel with the existing signal system such as ATS, ATP or ATO, so that if there is a malfunction of the existing signal system, In addition, in the case of the existing signal system, there is a limit that can only receive the ground information of the line only at the place where the ground box, ground device or ballis is installed. By supplementing this, it is possible to acquire the ground information of the line over the entire running track of the train So that a more stable train operation system can be constructed.

In addition, when the running speed of the train is high, the braking distance is increased. Accordingly, it is necessary to detect the obstacle ahead or the preceding train in the farther advance, so that the emission range of the laser module is increased. In the case where the running speed of the train is slow, The distance can be shortened so that the forward light emission range can be reduced so that the front obstacle or the preceding train can be more spaciously and precisely detected, so that the forward surveillance can be effectively performed according to the traveling speed of the train.

1 is a block diagram schematically illustrating a train control system using a smart signal according to a preferred embodiment of the present invention.
FIGS. 2 and 3 are diagrams for explaining a laser module installed in a train,
FIG. 4 is a view for explaining a method of controlling the traveling of a train by determining a distance between the train and another train in front of the train;
5 is a diagram for explaining a method of controlling the running of a train in a curve section,
6 is a diagram for explaining a method of controlling the running of a train in a gradient section,
7 is a flowchart illustrating a method of controlling a train using a smart signal according to a preferred embodiment of the present invention.

Hereinafter, a train control system using a smart signal according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

In addition, a method using the laser sensor of the present invention which does not use these signal infrastructures in contrast to the conventional ATS, APT, fixed occlusion method, and mobile occlusion method is defined as a smart signal.

1 to 7 show an automatic train control system using a smart signal such as a laser according to a preferred embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a system for automatically operating a train using a smart signal according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a schematic block diagram of an automatic train control system using a smart signal, such as a laser, according to a preferred embodiment of the present invention, and FIGS. 2 and 3 are views for explaining a state in which a laser module is installed on a train.

Referring to FIG. 1, the system includes a laser-based automatic train driving system 100, a laser module 120, a control unit 110, a warning unit 130, and a braking unit 140 according to a preferred embodiment of the present invention .

The laser module 120 is composed of a laser emitting portion and a laser receiving portion, and the laser emitted from the laser emitting portion is reflected by the forward object or the like and enters the light receiving portion.

At this time, as shown in FIG. 2, it is preferable that the laser modules 120 are installed on the front of the train so as to be spaced apart from each other by a rail width, or may be provided to be flush with the rail width.

As a result, this object or the like outside the rail can be filtered and prevented from being mistaken for an obstacle or a preceding train.

The control unit 110 counts the time taken for the light emitted from the light emitting unit of the laser module 120 to be reflected by the object and received by the light receiving unit to determine the distance from the object.

Thereafter, the control unit 110 determines the braking distance according to the traveling speed of the current train, compares the distances from the identified objects with the braking distances, i.e., determines whether a sufficient braking distance can be secured, Determine if braking is necessary.

At this time, when it is determined that deceleration or braking of the train is necessary, it is preferable to output a voice or a warning sound through the warning unit 130 so that the engineer takes necessary measures.

More specifically, after the controller 110 determines that deceleration or braking is necessary, the control unit 110 warns the driver through the warning unit 130 and then receives an input signal for braking from the braking unit 140 If it is not input, the control unit 140 automatically controls the braking unit 140 to decelerate or brake the train.

According to the preferred embodiment of the present invention configured as described above, the braking distance is calculated according to the distance between the obstacle and the current running speed of the train when the obstacle is detected in front of the line of the running train, The train can be decelerated or braked so that a safety accident against an obstacle can be prevented without a complicated mechanical device. In addition, if the object is a preceding train as shown in FIG. 4, The speed of the train can be increased, decelerated or braked according to the distance from the preceding train, so that it is possible to efficiently use the limited train line without the need to install a complicated ground device or an onboard device .

In addition, even if the train to be operated on the line where the existing ATS system or ATP system is installed is a train for which the corresponding system is not installed, any line or any line can be used to operate the train and the existing old infrastructure is established Even when the train is deployed effectively, the train can be operated.

If the traveling speed of the train is high, the braking distance must be long. Therefore, it is necessary to brak down the traveling speed of the train even if the distance from the object is long. The output of the laser module 120 is increased or decreased in proportion to the traveling speed of the train because it is necessary to braking the traveling speed to decelerate when the distance to the object is close to the distance.

With this configuration, when the traveling speed of the train is slow, the emission distance of the laser module 120 is short, so that the power consumption can be minimized and the train can be operated while observing the front side in more detail. The light emitting distance of the laser module 120 is long, so that it is possible to control the traveling speed of the train to be reduced more quickly by detecting a farther object.

Therefore, when the emission distance of the laser module 120 is fixed, it can not follow the running speed of the train and can be fixedly set to the maximum emission distance. In this case, power consumption may be unnecessarily consumed, The maintenance and repair costs increase.

At this time, the controller 110 recognizes data on the front emission distance of the laser module 120 according to the traveling speed of the train, and calculates the distance to the object from the distance.

More preferably, the light emitting angle of the laser module 120 is changed according to the running speed of the train. When the running speed of the train is high, the laser module 120 is tilted so as to emit a long distance.

According to a preferred embodiment of the present invention, as shown in FIG. 5, when the line is a curved section or when the line is a gradient section as shown in FIG. 6, the laser module senses the object of the train line The ground laser module 160 is installed on the ground so as to emit laser light in the traveling direction of the train in the curved section or the gradient section.

The terrestrial laser module 160 emits light in a forward direction like the laser module 120 installed on the train so that an object is detected ahead.

The data signal sensed by the terrestrial laser module 120 is transmitted to a train that enters the terrestrial laser module 160 side.

At this time, the terrestrial transceiver unit 170 is provided to transmit the data signal sensed by the terrestrial laser module 160 to the incoming train.

The trailing trains sense the object as if the data signal transmitted from the terrestrial transceiver unit 170 is determined by the distance from the object to the laser module 120. When the object is determined, the separation distance between the terrestrial laser module 160 and the foreign object and the distance between the train and the ground laser module 160 are summed up to finally calculate the distance between the train and the foreign object.

To this end, the terrestrial transceiver unit 170 transmits the position data provided with the terrestrial laser module 160 and the time data received and emitted by the following trains. At this time, it is desirable to transmit data on the set emission distance of the terrestrial laser module 120. Alternatively, the controller 110 may determine the installation position data of the terrestrial laser module 160, The light emitting distance of the module 120 may be read and used.

That is, the control unit 110 determines the installation position data of the terrestrial laser module 160 transmitted from the terrestrial transceiver unit 170 and the position data of the current train from the GPS module 280, Determines the separation distance, and determines a separation distance between the terrestrial laser module 160 and the foreign object by analyzing the data signal transmitted from the terrestrial laser module 160 to finally determine the separation distance between the train and the foreign object.

Thereafter, it is determined whether deceleration or braking control is necessary by calculating the braking distance according to the distance between the train and the object and the running speed of the train that is currently running. If deceleration or braking control is required, And notifies the warning message, and if the input signal to the braking unit 140 does not exist even after a predetermined time has elapsed, the train is automatically decelerated or braked.

Accordingly, even when the laser module 120 of the train can not detect the curved section and the gradient section, the object can be grasped in advance to control the deceleration or braking of the train.

At this time, it is also possible to install at least one ground laser module in the curved section and the gradient section according to the turning radius or the gradient of the gradient.

In the above description, the data signal is transmitted from the terrestrial laser module 160 to the train, and the control unit 110 analyzes the data signal to analyze the separation distance. However, in the terrestrial laser module 160, It is also possible to calculate the distance from this object and transmit it to the train.

In addition, the train laser module 120 emits light in real time, and in the case of the terrestrial laser module 160, the terrestrial laser module 160 is caused to emit light only when a trailing train is detected, thereby facilitating maintenance of the terrestrial laser module 160 .

Alternatively, a vibration sensing unit S may be provided to sense the vibration generated when the train is traveling on the rear side rail from a position where the ground laser module 160 is installed. When vibration exceeding a predetermined size is detected from the vibration sensing unit S It may be determined that there is a trailing train and the terrestrial laser module 160 is driven to emit light.

Alternatively, if the signal transmitted from the onboard transceiver unit 150 of the trailing train is received by the terrestrial transceiver unit 170, the terrestrial laser module 160 may be driven to emit light.

Thus, the terrestrial laser module 170 can emit light only when a trailing train is sensed in a standby mode without emitting light in the absence of trailing trains, thereby substantially extending the operating life of the terrestrial laser module 160 And the cost and time for maintenance or management thereof can be shortened.

In this way, conventionally, it is inconvenient to establish a separate obstacle judging device and to construct a separate historical stationary system even if the signal system and infrastructure are built according to the signal system (ATS or ATP, etc.) of the railway track However, it is possible to judge obstacles and determine the distance between the trains and the foreign object by using one system, that is, the laser, to control the train operation considering the correlation with the preceding train, It is possible to drastically reduce the cost of installation and construction as well as drastically reduce the time and cost of maintaining and managing the conventional complicated and large number of ground apparatuses and onboard apparatuses and greatly simplifying the operation of the system do.

Meanwhile, it is also possible to control the traveling speed of the train by using the laser module in parallel with the existing signal system infrastructure according to the preferred embodiment of the present invention, that is, in parallel with the ATS system or the ATP system.

That is, in the case of the ATS system, when the determination of deceleration or braking of the traveling speed is made using the traveling speed of the train by the ATS signal or the ATP signal and the data of the laser module, So that the train can be decelerated or braked to follow the signal.

For example, even when the progress signal (G) of the train is received in the ATS signal, the object is judged by the laser, and the distance between the object and the train is compared with the braking distance according to the train traveling speed, If a deceleration is required, braking or decelerating control is performed by ignoring the progress signal (G) of the ATS signal.

As a result, it is possible to control the train operation more stably, so that it is possible to utilize the railway line more efficiently, and the stability of the train operation can be remarkably increased.

Hereinafter, the operation of the automatic laser train operating system according to the preferred embodiment of the present invention will be described with reference to FIG.

The laser module 120 emits a laser toward the front of the train (S110), receives the laser returning to the light receiving unit (S115), judges whether or not the object is in consideration of the time from emission to light reception, The separation distance is calculated (S120).

Thereafter, when it is determined that there is an obstacle in the control unit 110, it is necessary to determine whether the distance between the train and the obstacle is a distance, determine the braking distance by calculating the running speed of the current train, decelerate the traveling speed of the train, (S125).

If it is determined in step S125 that braking or deceleration is required, the control unit 110 notifies the driver of the necessity of deceleration or braking because there is an obstacle ahead through the warning unit 130 (S130) If the braking signal is not detected at step S135, the control unit 110 automatically decelerates or brakes the train at step S140.

If vibration of a predetermined magnitude or more is sensed by the vibration sensor S installed on the ground while emitting light toward the front of the train with the laser module 120 in step S110 or when a vibration is detected from the onboard transceiver 150 to the ground transceiver When the terrestrial laser module 160 emits a laser beam forward and receives a light signal, the terrestrial laser module 160 transmits the data signal to the on-train transceiver unit 150.

The control unit 110 analyzes the data of the laser module 120 and the terrestrial laser module 160 of the train to determine an obstacle or a preceding train and if it is analyzed that there is an obstacle or a preceding train, The distance from the obstacle or the preceding train is finally determined in real time by analyzing the position of the train, the installation position of the ground laser module 160, the distance of light emission, It is determined whether deceleration or braking is necessary, and the process proceeds to the next step.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the present invention as defined by the appended claims. You will understand. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. The scope of the present invention is defined by the appended claims rather than the above detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be interpreted as being included in the scope of the present invention .

100: automatic train control system 110: control unit
120: Laser module 130: Warning part
140: Braking unit 150: Onboard transmission / reception unit
160: ground laser module 170: ground transmission / reception unit
180: GPS module S:

Claims (11)

A laser module which emits a laser beam in front of a train and emits light with a width of a pair of rails;
A control unit for receiving the laser light returned by the object after being emitted from the laser module to calculate a distance from the object in real time and determining whether the train is braked according to the calculated distance;
And a warning unit for warning when the control unit determines that train braking is necessary,
At least one ground laser module positioned in a gradient section or a curved section line where it is difficult to sense the object of the train line by the laser module and emitting laser light forward in the train traveling direction;
And a terrestrial transmission / reception unit for transmitting the measured data signal from the terrestrial laser module to a traveling train,
Wherein,
Wherein when the distance is shorter than the initially set laser emission distance of the laser emitted from the laser module, the determination is made as a foreign object. The method according to claim 1,
Wherein when the train is not braked after the warning unit is activated, the train is automatically braked. 3. The apparatus of claim 2,
Wherein the driving speed of the train is controlled by determining a distance between the subject vehicle and the preceding object through the subject vehicle and the moving speed and the relative speed of the preceding object. delete The apparatus of claim 1,
The position of the ground laser module, and the position of the child vehicle, which are transmitted from the terrestrial laser module,
Wherein when the signal is shorter than the initially set emission distance of the ground laser module, it is judged to be a foreign object, and the distance between the object and the ground laser module is determined and then the distance between the train and the foreign object is determined based on the distance. Automatic train operation system using. 6. The method of claim 5,
Wherein the terrestrial laser module emits light at a width of a pair of rails. 6. The method of claim 5,
Wherein the terrestrial laser module emits laser light when a trailing train is sensed. 6. The method of claim 5,
Wherein the ground laser module is driven when a vibration is sensed by detecting a vibration generated when a train runs on a rear side rail of the ground laser module. 6. The method of claim 5,
Wherein the terrestrial laser module is driven when a signal is detected by the terrestrial transmission / reception unit from the transmission / reception unit of the train. The method according to any one of claims 1 to 3 and 5 to 9,
Wherein,
And a braking unit for braking the train in accordance with a signal to be braked more quickly by comparing the determined distance and the braking distance with the determined object, Automated train operating system. The method according to any one of claims 1 to 3 and 5 to 9,
Wherein,
Wherein the output of the laser module is adjusted according to the running speed of the train.

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