CN112631273A - Remote intelligent one-key forced stop control system for public passenger vehicles - Google Patents

Remote intelligent one-key forced stop control system for public passenger vehicles Download PDF

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Publication number
CN112631273A
CN112631273A CN202011219598.5A CN202011219598A CN112631273A CN 112631273 A CN112631273 A CN 112631273A CN 202011219598 A CN202011219598 A CN 202011219598A CN 112631273 A CN112631273 A CN 112631273A
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vehicle
remote
mounted terminal
forced stop
instruction
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CN112631273B (en
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何忠贺
李健诚
刘世达
邢更力
王力
张海波
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North China University of Technology
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North China University of Technology
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    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/02Control of position or course in two dimensions
    • G05D1/021Control of position or course in two dimensions specially adapted to land vehicles
    • G05D1/0231Control of position or course in two dimensions specially adapted to land vehicles using optical position detecting means
    • G05D1/0246Control of position or course in two dimensions specially adapted to land vehicles using optical position detecting means using a video camera in combination with image processing means
    • G05D1/0253Control of position or course in two dimensions specially adapted to land vehicles using optical position detecting means using a video camera in combination with image processing means extracting relative motion information from a plurality of images taken successively, e.g. visual odometry, optical flow
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/02Control of position or course in two dimensions
    • G05D1/021Control of position or course in two dimensions specially adapted to land vehicles
    • G05D1/0212Control of position or course in two dimensions specially adapted to land vehicles with means for defining a desired trajectory
    • G05D1/0214Control of position or course in two dimensions specially adapted to land vehicles with means for defining a desired trajectory in accordance with safety or protection criteria, e.g. avoiding hazardous areas
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/02Control of position or course in two dimensions
    • G05D1/021Control of position or course in two dimensions specially adapted to land vehicles
    • G05D1/0212Control of position or course in two dimensions specially adapted to land vehicles with means for defining a desired trajectory
    • G05D1/0221Control of position or course in two dimensions specially adapted to land vehicles with means for defining a desired trajectory involving a learning process
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/02Control of position or course in two dimensions
    • G05D1/021Control of position or course in two dimensions specially adapted to land vehicles
    • G05D1/0212Control of position or course in two dimensions specially adapted to land vehicles with means for defining a desired trajectory
    • G05D1/0223Control of position or course in two dimensions specially adapted to land vehicles with means for defining a desired trajectory involving speed control of the vehicle
    • GPHYSICS
    • G05CONTROLLING; REGULATING
    • G05DSYSTEMS FOR CONTROLLING OR REGULATING NON-ELECTRIC VARIABLES
    • G05D1/00Control of position, course, altitude or attitude of land, water, air or space vehicles, e.g. using automatic pilots
    • G05D1/02Control of position or course in two dimensions
    • G05D1/021Control of position or course in two dimensions specially adapted to land vehicles
    • G05D1/0276Control of position or course in two dimensions specially adapted to land vehicles using signals provided by a source external to the vehicle

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  • General Physics & Mathematics (AREA)
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Abstract

The invention provides a remote intelligent one-key forced stop control system for public passenger vehicles, which comprises a remote command platform, an interactive server, an intelligent gateway module, a vehicle-mounted terminal, a controller and an actuator, wherein if the remote command platform confirms that an emergency situation occurs, the remote command platform issues a one-key forced stop instruction to remotely control the speed of the vehicle; the interactive server is connected with the vehicle-mounted terminal and the remote command platform and is used for transmitting data information and instructions between the vehicle-mounted terminal and the remote command platform; and the vehicle-mounted terminal is used for receiving the data information and the instruction of the remote command platform, communicating with the background data processing center according to the data information and the instruction, and outputting a video monitoring signal and an emergency forced stop signal. And the controller is respectively connected with the remote command platform, the interactive server and the vehicle-mounted terminal, and signals output by the controller are sent to the actuator to realize remote speed control and forced stop control.

Description

Remote intelligent one-key forced stop control system for public passenger vehicles
Technical Field
The invention relates to a remote intelligent one-key forced stop control system for public passenger vehicles, belonging to the technical field of remote intelligent control.
Background
At present, the speed limitation in the running process of a vehicle is realized by mainly setting the upper limit of the rotating speed of an engine, and most of the speed limitation is realized by adopting manual braking or based on the vehicle. Remote speed limit is less applicable, and remote forced stop technology is not applied to vehicles.
However, for the prevention and control requirements of the emergency in the vehicle, according to different road conditions and environments, the vehicle running state and other information, a vehicle remote speed limiting and forced stopping control method needs to be designed, the safety of passengers is guaranteed, and the influence range of the casualty event is reduced.
Disclosure of Invention
The invention aims to solve the problem of providing a remote intelligent one-key forced stop control system for public passenger vehicles, which can perform emergency braking and forced stop on the vehicles under special emergency conditions and can effectively control the vehicles through a remote command platform.
In order to achieve the purpose, the invention adopts the following technical scheme:
a remote intelligent one-key forced stop control system for public passenger vehicles comprises a remote command platform, an interactive server, an intelligent gateway module, a vehicle-mounted terminal, a controller and an actuator, wherein the remote command platform is used for monitoring video data transmitted from the vehicle-mounted terminal, and issuing a one-key forced stop instruction to remotely control the vehicle speed if an emergency situation is confirmed; the interactive server is connected with the vehicle-mounted terminal and the remote command platform and is used for transmitting data information and instructions between the vehicle-mounted terminal and the remote command platform; and the vehicle-mounted terminal is used for receiving the data information and the instruction of the remote command platform, communicating with the background data processing center according to the data information and the instruction, and outputting a video monitoring signal and an emergency forced stop signal. And the controller is respectively connected with the remote command platform, the interactive server, the vehicle-mounted terminal and the actuator, and outputs signals to the actuator to realize remote speed control and forced stop control.
Preferably, the in-vehicle terminal includes: the data access and standardization module is used for accessing detection data of vehicle-mounted inflammable volatile matters, explosives, navigation positioning and the like in real time; the video processing and analyzing module is used for supporting intelligent analysis of vehicle-mounted video images and early warning of abnormal behaviors; the large-capacity storage module is used for supporting the local storage of detection data such as pictures, inflammable volatile matters, explosives, navigation and positioning and the like; the wireless communication module is used for supporting real-time transmission and retrieval of video images, and real-time transmission of early warning information such as abnormal behaviors, inflammable volatile matters, explosives, navigation positioning, abnormal tracks and the like and vehicle remote control instructions; the emergency communication module is used for supporting the real-time transmission of early warning information such as abnormal behaviors, inflammable volatile matters and explosives, navigation positioning and abnormal tracks under the conditions of wireless communication abnormity or interruption and the like; the vehicle remote speed limiting and forced stopping module is wirelessly accessed to a vehicle speed limiting or forced stopping instruction, and transmits the control instruction to the vehicle speed control unit through a vehicle CAN bus to realize vehicle speed limiting or forced stopping; the emergency power supply module is used for supporting emergency power supply under the condition that the vehicle-mounted power supply system is damaged, ensuring normal operation of vehicle-mounted terminal equipment and effectively acquiring key data of an incident time period; the safety protection module is used for protecting the outside of the equipment and ensuring the vibration resistance, the collision resistance, the high temperature resistance and the like of the equipment.
Preferably, the controller adopts a remote forced stop control method that:
a. define a remote forced-stop SIS0 discrete-time nonlinear system:
y(k+1)=f(y(k),...,y(k-ny),u(k),...,u(k-nu)
wherein y (k) and u (k) represent the output and input of the remote forced-stop SISO discrete-time nonlinear system at the time k, respectively; f (..) represents a nonlinear function of the system; the output y is the running speed of the passenger car at the moment;
b. the vehicle speed is defined as 60km/h, and the emergency acceleration is-8 m/s2U represents the opening degree of the valve of the brake device,
Figure RE-GDA0002944291270000031
p (k) representing it as a non-emergency situation; q (k) represent it as a general emergency; z (k) represent it as an emergency;
c. defining that the passenger vehicle runs at a constant speed V, wherein the output y is Vm/s, the opening of a valve of a brake device is0, and the expected input speed is yd
Figure RE-GDA0002944291270000032
d. When braking measures need to be taken, an error e is generated between an actually output y value and an expected value, then the speed deviation value is changed into an acceleration deviation value through an integrator, the acceleration deviation value acts on a control object through a controller, and finally the acceleration is adjusted by adjusting the opening degree of a braking device, so that remote intelligent one-key forced stop is realized.
Preferably, when the vehicle is disturbed by the external environment during the running process, the signal is replaced by a pulse signal if the signal is a transient signal, and is replaced by a step signal if the signal exists for a certain time.
Preferably, the actuator performs one-key forced stop after receiving the forced stop instruction, and then feeds back the result to the vehicle-mounted terminal, the vehicle-mounted terminal feeds back the result to the interactive server after confirming with the in-vehicle terminal and the actuator, and the interactive server feeds back the result to the remote command platform after confirming with the in-vehicle terminal and the vehicle-mounted terminal.
Advantageous effects
After the technical scheme is adopted, the vehicle can be braked and stopped urgently under special emergency conditions, and the vehicle can be effectively controlled through the remote command platform.
Drawings
FIG. 1 is a joint debugging diagram of the one-key forced stop system of the present invention;
FIG. 2 is a control diagram of the one-key forced stop system of the present invention;
FIG. 3 is a schematic diagram of a vehicle mounted terminal assembly of the remote push-to-stop system of the present invention;
FIG. 4 is a flow chart of the one-touch forced stop system of the present invention;
FIG. 5 is a block diagram of the algorithm system of the one-key forced stop method of the present invention;
FIG. 6 is a block diagram of an interference system for the one-touch forced stop method of the present invention.
Detailed Description
The following detailed description of the embodiments of the present invention is provided in conjunction with the accompanying drawings, so that how to implement the embodiments of the present invention by using technical means to solve the technical problems and achieve the technical effects can be fully understood and implemented.
It will be understood by those skilled in the art that, unless otherwise defined, all terms (including technical and scientific terms) used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. It will be further understood that terms, such as those defined in commonly used dictionaries, should be interpreted as having a meaning that is consistent with their meaning in the context of the prior art and will not be interpreted in an idealized or overly formal sense unless expressly so defined herein.
Referring to fig. 1 to 6, the invention relates to a public passenger vehicle-oriented remote intelligent one-key forced stop control device, which mainly comprises a remote command platform, an interactive server, an intelligent gateway module, a vehicle-mounted terminal and an actuator, wherein the command priority order among the remote command platform, the interactive server, the intelligent gateway module, the vehicle-mounted terminal and the actuator is that the remote command platform > the interactive server > the vehicle-mounted terminal > the actuator, and the device brakes the vehicle by a message which is actually sent through a gateway and is converted into a corresponding acceleration value.
In this embodiment, the remote command platform, also called platform, and the background data processing center have the highest priority in such remote intelligent one-key forced stopping method, and have a decisive role. It is the highest level of issued commands and is responsible for all vehicle operations.
When the remote command platform monitors that video data transmitted from the vehicle-mounted terminal has an emergency situation, the video data is communicated with the interior of the vehicle, the situation is confirmed to occur, a one-key forced stop instruction is issued, the vehicle speed can be remotely controlled, and vehicle remote forced stop is implemented under an extreme situation. Some data transmission protocol exists between the instruction issued by the platform and the interactive server.
And the interaction server is used for converting data into data required by the remote command platform. The interactive server is a bridge connecting the vehicle-mounted terminal and the remote command platform, receives the downlink instruction and forwards the downlink instruction to the vehicle-mounted terminal, and receives the uplink service data and forwards the uplink service data to the remote command platform. The execution flow is as follows:
1. the interactive server starts and monitors the appointed service port, and provides service through SOCKET.
2. The vehicle-mounted terminal is powered on and started to be connected to the interactive server through the SOCKET, the interactive server identifies the equipment according to the ID of the transmitted equipment end, the channel information is stored in the interactive server, and the equipment end maintains long connection between the server and the equipment through a timing heartbeat mechanism.
3. The remote command platform initiates a downlink instruction, including an ID with an operating device and the like, the interactive server finds a connecting channel of the device to be operated according to the device identification issued by the remote command platform, and sends data to the device to be operated through the channel.
And the vehicle-mounted terminal is a pivot of the whole remote control system and is used for uploading data and issuing instructions. The vehicle-mounted electronic information input interface is used for being connected with a vehicle bus to acquire vehicle-mounted electronic information. And the command instruction input interface is used for receiving command instructions. Meanwhile, the vehicle-mounted terminal is provided with a central processing unit which receives the command instruction input by the command instruction input interface, and the central processing unit is also communicated with the background data processing center correspondingly according to the inflammable and explosive detection data, the vehicle-mounted electronic information, the command instruction, the positioning data and the navigation data, and outputs a video monitoring signal and an emergency stop signal.
The intelligent Gateway module, Gateway (Gateway) is also called Gateway connector and protocol converter, the Gateway is on the transmission layer to realize network interconnection, it is the most complex network interconnection equipment, only used for two different network interconnections of high layer protocol. The gateway is also similar in structure to a router, except for the interconnect layer. The gateway can be used for interconnection of both wide area networks and local area networks.
In this embodiment, the instruction sent by the vehicle-mounted terminal is converted into a message form through the intelligent gateway module, and is broadcasted in the communication local area network, and the instruction is transmitted to the vehicle control unit, i.e., the actuator, in the form of a message, so as to realize the remote control function.
The actuator is a brake control device of an Ebs of a brake in the remote one-key forced stop intelligent system, so as to execute forced stop tasks. Assuming that the straight-line running speed of a bus (tourist bus) is less than or equal to 40Km/h and the acceleration is-0.5 m/s2 when encountering terrorist hijacking and other emergency situations: the vehicle-mounted terminal receives the platform wireless speed limit or forced stop instruction and forwards the instruction to the vehicle control unit through the vehicle CAN communication network, so that the remote control of the vehicle speed is realized. Wherein the forced stop is braked by a request brake message XBR 3. On an electric brake system, an XBR message checksum is used to validate the signal path from the requesting device to the brake controller. If not, the brake system does not accept external requests.
The power drive control of the pure electric vehicle, namely the vehicle speed control of the whole vehicle controller and the motor controller is realized together; hybrid vehicle power drive control-the vehicle controller and the motor controller together realize vehicle speed control; the traditional energy vehicle-CAN instrument and engine ECU realize the speed control together;
meanwhile, the invention provides a control algorithm of remote forced stop, which can effectively realize remote one-key forced stop, has small steady-state error after response and can well track the expected error value. The overshoot generated by the control algorithm is small, and when a random interference signal is given to the whole control system, the system can be quickly recovered to a balanced and stable state, so that the designed controller is proved to have strong robustness and anti-interference performance.
The controller is respectively connected with the remote command platform, the interactive server and the vehicle-mounted terminal. The signal output by the controller is sent to the actuator to realize remote speed control and forced stop control. The control algorithm is as follows:
a remote forced-stop SISO discrete-time nonlinear system is now defined:
y(k+1)=f(y(k),...,y(k-ny),u(k),...,u(k-nu)
wherein y (k) and u (k) represent the output and input of the remote forced stop system at time k, respectively. f. -) represents a nonlinear function of the system. The output y is the speed at which the passenger vehicle is traveling at that time. In this system, the influence of the friction coefficient, weather, etc. on the passenger car is not considered for the moment.
The vehicle speed is defined as 60km/h, and the emergency acceleration is-8 m/s2And u represents the opening degree of the valve of the brake device, and the larger the value is, the larger the opening degree of the valve of the brake is, namely the more urgent the brake is stepped on. The definition for u is as follows:
Figure RE-GDA0002944291270000071
as shown in the above formula, p (k) represents it as a non-emergency; q (k) represent it as a general emergency; z (k) represents this as an emergency.
The desired input signal is an acceleration value requiring braking. The passenger vehicle runs at a constant speed V, the output y is Vm/s, and the opening degree of a valve of the brake device is 0. Let the desired input speed be ydTo y fordIs represented as follows:
Figure RE-GDA0002944291270000081
when the passenger car meets an emergency, braking measures need to be taken. There are several different ways for the speed from V to 0. As shown by the above equation, to apply the emergency braking, the speed needs to be reduced to 0 in a very short time.
As shown in fig. 5, when a situation occurs, a braking measure needs to be taken, at this time, an error e is generated between a y value actually output by the system and an expected value, then the y value is changed into an acceleration deviation value through an integrator, an instruction is issued through a controller, namely, a remote command platform, data of an interaction server is converted, the instruction is transmitted to a vehicle-mounted terminal, the vehicle-mounted terminal converts the instruction into a message through a gateway and acts on a control object, and finally the acceleration is adjusted by adjusting the opening degree of a braking device, so that the acceleration is adjusted to the fastest and optimal degree, and the remote intelligent one-key forced stop is realized.
During the running process of the vehicle, the vehicle is easily disturbed by the external environment, such as environmental factors, the change of the friction coefficient and the occurrence of special conditions. This interference signal is defined as d (k) and acts on the output of the controller. The external interference can be treated as follows according to different conditions: if the external force acts, the signal is often an instantaneous signal, the acting time is short, and the signal can be replaced by a pulse signal with a certain width; if there is a signal for a certain time, a step signal may be used instead, as shown in fig. 6. After verification, the control system can be quickly restored to a stable state after being interfered by the outside, and the anti-interference and strong robustness of the designed controller are proved.
Fig. 1 is a joint debugging diagram of the present invention, which includes the main components of the system, namely, the remote control platform, the interactive server, the vehicle-mounted terminal, the gateway and the actuator. The arrow direction represents the direction of instruction transfer. The transfer of information may be bidirectional. The background data processing center always monitors video data transmitted from the vehicle-mounted terminal. If dangerous conditions such as hijacking of gangsters occur, the command can be issued and transmitted to the interactive server, and the interactive server converts the data and transmits the data to the vehicle-mounted terminal. The vehicle-mounted terminal converts the instruction into a message, and the controller executes the forced stopping task after receiving the instruction information. The communication protocol between the gateway and the vehicle-mounted terminal comprises the following three parts:
1. the communication mode is as follows:
a communication interface: vehicle CAN interface
Communication baud rate: 250kbps
Data frame type: extended frame
A data uploading period: the vehicle-mounted device sends the command of platform forced stop when receiving the command
2. Communication protocol analysis:
CAN interface ID 0x0C040B2C
Eight bytes of data: 0000000000000000
3. Description of related Art:
after receiving the forced stop instruction issued by the platform, the vehicle-mounted equipment sends forced stop CAN data to the gateway equipment once, and the gateway starts to send forced stop messages to the broken stop equipment after receiving the forced stop CAN data.
The data transmission protocol between the interaction server and the vehicle-mounted terminal is as follows:
the method comprises the steps that execution instructions such as one-key forced stop and one-key window breaking are transmitted between a data interaction server and a vehicle-mounted terminal through a 4G network, after the vehicle-mounted terminal is connected to a remote command platform (a TCP server 65004 port) through a TCP Socket, an identification instruction is sent at first for maintaining a long connection mapping relation between terminal equipment and the data interaction server, after the vehicle-mounted terminal is connected to the interaction server (a TCP server 65004 port) through the TCP Socket, the platform sends the execution instructions to the vehicle-mounted terminal through a client Socket of the TCP server. The remote command platform is connected to a data interaction server (TCP server 8090 port) through a TCP Socket to send data.
Referring to fig. 2, when the remote control timing is determined:
under the state of the internet of vehicles, when the vehicles are hijacked, collided and in other emergency situations, the speed of the vehicles can be remotely controlled, and the vehicles can be remotely forced to stop in extreme situations.
The vehicle remote speed control mainly comprises two stages: firstly, remote control opportunity judgment: comprehensively analyzing the vehicle sensing data to determine the vehicle running state, and determining the conditions and the time for implementing vehicle remote control by considering the vehicle running road conditions, environment, emergency types and the like; secondly, remote control is implemented: the remote control instruction can be decided by a central platform or a vehicle operation enterprise, a vehicle-mounted terminal developed by a subject receives the remote control instruction, and the rotating speed of a vehicle engine is controlled through a vehicle bus, so that the aim of controlling the vehicle speed is fulfilled.
The specific control operation is as follows:
1) a commander issues a wireless instruction through a remote command platform;
2) the vehicle-mounted terminal receives the wireless instruction, converts the instruction into a CAN message and broadcasts the CAN message in a communication area network CANA;
3) the gateway module receives the instruction information in the CANA and forwards the instruction information to the CANB;
4) and the vehicle control unit acquires the instruction information in the CANB, issues the instruction and realizes the remote control function. Finally realizing one-key forced stop.
Referring to fig. 3, the in-vehicle terminal includes:
(1) data access and standardization module: the real-time access of detection data such as vehicle-mounted inflammable volatile matters, explosives, navigation positioning and the like is mainly realized;
(2) the video processing and analyzing module: the intelligent analysis and the abnormal behavior early warning of the vehicle-mounted video image are mainly supported;
(3) a mass storage module: local storage of detection data such as pictures, inflammable volatile matters, explosives, navigation positioning and the like is supported;
(4) a wireless communication module: the real-time transmission and retrieval of video images are supported, and the real-time transmission of early warning information such as abnormal behaviors, inflammable volatile matters, explosives, navigation positioning, abnormal tracks and the like and vehicle remote control instructions is supported;
(5) an emergency communication module: the real-time transmission of early warning information such as abnormal behaviors, inflammable volatile matters, explosives, navigation positioning, abnormal tracks and the like is supported under the conditions of abnormal or interrupted wireless communication and the like;
(6) the vehicle remote speed limiting and forced stopping module comprises: based on a wireless access vehicle speed limit or forced stop instruction, transmitting a control instruction to a vehicle speed control unit through a vehicle CAN bus to realize vehicle speed limit or forced stop;
(7) the emergency power supply module: the emergency power supply under the condition that the vehicle-mounted power supply system is damaged due to typical emergencies such as fire and explosion or other types of events is supported, normal operation of vehicle-mounted terminal equipment is ensured, and key data of an incident time period are effectively acquired;
(8) the safety protection module: through scientific hardware design, structural optimization and material selection, through the outside protection of equipment, ensure the performance such as shock resistance, resistant clashing, high temperature resistant of equipment. And under the emergency conditions of explosion, fire, collision and the like, the stability and reliability of data storage are ensured.
The vehicle-mounted terminal is connected with the data access and standardization module and the vehicle remote speed limit and forced stop module. In the system, the vehicle-mounted terminal can be combined with a background data center to upload generated video data to a remote command platform in real time, and the remote command platform issues an instruction to the vehicle-mounted terminal to complete a forced stop task in case of emergency.
Referring to fig. 4, the detailed operation of the remote vehicle control system is as follows:
the method comprises the following steps that firstly, the vehicle-mounted terminal and the interactive server automatically transmit data to the remote command platform, and when abnormal behaviors and abnormal tracks of a vehicle are detected or inflammable and explosive articles and the like are detected, the remote command platform is in contact with a driver in the vehicle. If the communication is not problematic, the communication is static; and if the communication is problematic, the remote command platform issues an instruction to the interactive server.
Secondly, the interactive server firstly confirms with the remote command console, and if no instruction is confirmed, the interactive server is static; if the issued command is confirmed, confirming with the interior of the vehicle, and if the interior of the vehicle is not in a condition, stopping; and if the condition exists in the vehicle, the instruction is issued to the vehicle-mounted terminal.
And thirdly, the vehicle-mounted terminal firstly confirms with the interactive server and then confirms with the interior of the vehicle, and if the conditions of the vehicle-mounted terminal and the interactive server are confirmed, the vehicle-mounted terminal issues an instruction to the actuator. If there is no case, then the system is static.
Fourthly, after the actuator receives the instruction, corresponding operations are carried out: one key is used for forced stop.
And fifthly, after the actuator executes the corresponding task, feeding the result back to the vehicle-mounted terminal.
And sixthly, after the vehicle-mounted terminal confirms with the in-vehicle and the actuator, feeding the result back to the interactive server.
And seventhly, after the interactive server is confirmed with the in-vehicle terminal and the vehicle-mounted terminal, feeding back a result to the remote command platform.
And eighthly, after the command platform confirms with the in-vehicle and interactive server, the platform completes the task after receiving the successful execution, and the remote vehicle control is successful.
The method for calculating the checksum of the request braking message and the debugging comprises the following steps: the control Mode signal XBR _ Ctrl _ Mode, the endurance brake integrated signal XBR _ EBI _ Mode, the external acceleration demand signal XBR _ ExternalAccelementDemand, the Priority signal XBR _ Priority, and the emergency signal XBR _ Unrgency. An information counter signal XBR _ message _ counter, and a checksum signal XBR _ checksum.
The XBR is an external braking request. The method for realizing remote one-key forced stop is realized by issuing messages among several signals, and the following describes the several signals in detail.
(1) The external acceleration demand signal XBR _ external accelerationdemand, whose specification criteria are: the parameters are provided to the brake system from an external source. This is the acceleration that the brake system is expected to achieve. It is designated as the absolute acceleration of the reference r. Positive values result in increased vehicle speed, and negative values result in decreased vehicle speed. The numerical ranges are: +15.687m/s 15.6872The operable range is-10.0 to +10.0m/s2. The following functions are described next: external braking request: the acceleration that the braking system is expected to achieve. Used in BM by EXVGX algorithm. The requested operating range for the XBR external brake deactivation is absolutely necessary: 0m/s 2. A request to exit this range will be entered. If an error or unavailability exists, the XBR request is not executed. Byte and bit are 1.1, data length is 16.
(2) The durable brake integration signal XBR _ EBI _ Mode is used as an input to the brake system to provide for the use of a durable brake, such as a retarder or an engine brake. 00-acceleration required for non-durable brake integration must be achieved by the brake system using only the foundation brakes. During the activation of the XBR request, the brake system must not actively demand the braking torque of other braking devices, such as a retarder or an engine brake. 01-only the acceleration required for permanent braking allowance must be achieved by the braking system, requiring braking torque from other braking devices such as a retarder or an engine brake. The foundation brake itself must not be used. 10-durable braking integration allows the required acceleration by implementing the braking system by using the foundation brake or requiring the braking torque of other braking devices such as a retarder or an engine brake. 11-not defined. Simply put, 00 — allows for non-durable brake integration; 01-only durable braking is allowed; 10-allowing durable brake integration; 11-undefined. Its function is described as: external braking request: durable brake integration mode. Used in BM by EXVGX algorithm. It is absolutely necessary to activate the XBR external braking request, which, if undefined, will be disregarded. Byte and bit are 3.1, data length is 2.
(3) Priority signal XBR _ Priority, whose specification criteria are: the XBR priority is used as an input to the braking system to manage the priority of overlapping external and internal requests. 00-highest priority-for emergency situations, for example. For future collision avoidance systems. This mode covers any braking protection measures of the braking system. 01-high priority-undefined, 10-medium priority-for ACC systems. This mode does not cover the brake protection measures of the brake system. Low priority-for "override disabled" XBR control mode. For its functional description: XBR: managing the priority of requests of overlapping priority of external and internal requests. Used in BM by EXVGX algorithm. The absolutely necessary activation of the XBR external brake requests high priority (01b), and low priority requests are not supported. In this case, the EBS does not accept any external requests. Byte and bit are 3.3, data length is 2.
(4) The control Mode signal XBR _ Ctrl _ Mode, which is described as follows: the XBR control mode is used as an input to the braking system and defines how the external acceleration demand is achieved. 00-inhibit overwrite-inhibit any external control requirements by this instruction source. 01-additional mode acceleration control-adding the XBR acceleration demand to the driver's acceleration demand. 10-maximum mode acceleration control-if the external brake request acceleration demand is greater than the driver's acceleration demand, the XBR acceleration demand is executed. 11-not defined. For its functional description: the XBR control mode, which defines how the external acceleration requirements are implemented. Used in BM by EXVGX algorithm. It is absolutely necessary to activate the XBR external braking request. If not, then no external request is accepted by the EBS. Its byte and bit are 3.5 and data length is 2.
(5) Emergency signal XBR _ argency, whose specification criteria are: the idea of the emergency value is to adapt the durable brake integration behavior in the EBS system according to the traffic situation. At low emergency values (0%, e.g. downhill cruise control or the front vehicle is far ahead) the brake system should mainly use durable brakes to reduce lining wear. With high emergency values (100%, e.g. vehicle stopped or vehicle cut into the traffic line before the host vehicle), the brake system is expected to achieve the required deceleration (acceleration) as soon as possible. Numerical values: 0% -the situation is not critical; allowing low retarder dynamics. If the retarder performance is not sufficient, the foundation brake is activated after a period of time. y% -the foundation brake is activated faster to compensate the performance of the retarder, the linear interpolation is between 0 and 100%. 100% -low retarder dynamics should be adequately compensated by the foundation brake. Note that: this parameter is only set when the XBREBI switch is set to \ 10: durable braking integration will be allowed. The urgency of the XBR is only significant when the XBR request is processed in one device, such as the EBS controller, which also sends TSC1 to the retarder. Its byte and bit are 4.1 and data length is 8.
(6) The message counter signal XBR _ message _ counter, which describes the criteria: the XBR message counter is used to verify the signal path on the electric brake system from the demand device to the brake controller. Support for this parameter is mandatory. Note: the initial value of the 4-bit information counter of the first message in the drive cycle is arbitrary. In each following message, the counter is incremented by 1(0 to 15). Its function is described as XBR: for verifying the signal path from the desired device to the brake controller. If a discontinuous count occurs, the brake system does not accept external requests. Byte and bit 8.1, data length 4.
(7) The checksum signal XBR _ checksum is highlighted, and its specification criteria are: the XBR message checksum is used to validate the signal path from the demand device to the brake controller on the electric brake system. The calculation method comprises the following steps: (Byte1+ Byte2+ Byte3+ Byte4+ Byte5+ Byte6+ Byte7+ message counter &0X0F + message ID low Byte + message ID mid high Byte + message ID high Byte) Checksum ((Checksum > >4) + Checksum) &0X0F, i.e. Checksum equal to the sum of bytes 1 to 7 plus the message counter and 0X0F bitwise and operation, plus a low Byte in the message ID, a high Byte in the message ID, and a high Byte in the message ID. The resulting checksum is right shifted by 4 bits and the sum of the values added to the original checksum 0X0F is bit-wise and, ultimately, the value of the new checksum is obtained. Its byte and bit number is 8.5, and data length is 4. Its function is described as: the checksum is used to verify the signal path from the demand device to the brake controller. If not, the brake system does not accept external requests. This is specifically described below by way of an example. According to the algorithm, the gateway writes a message, wherein the message is 7E 7D 0E FF 0000000D, the ID number is 0C040B2B, the bytes 1-7 are 7E 7D 0E FF 000000, and the counter value is the last value of the message and is D, and the value is converted into hexadecimal. It is calculated that the sum of four bytes of ID is 46, the sum is 208+ D + 46-25B, 25B right-shifted four bits is 25, 25+ 25B-280, 280&0X 0F-O for 1-7 byte additions. And after calculation, if the value of the checksum is0 and is the same as the value of the second last digit of the message, the calculation is proved to be correct, and the brake system receives an external request and executes remote one-key forced stop.
If the existing input signal and its value are:
Signal Standby Request
Ctrl_Mode[bit] 0 2
EBI_Mode[bit] 0 0
ExternalAccelerationDemand[m/s2] 16.312... -5.9902..
XBR_Priority[bit] 3 0
XBR_Urgency[%] 102 102
firstly, transmitting the Standby data on the whole vehicle.
And a second step of sending Request data when requesting (note: ExternalAccelerationDemand is sent according to the actual deceleration required value).
And thirdly, circularly transmitting the Counter (8 th byte 1-4 bit) according to 0-15.
And the fourth step of Checksum (8 th byte 5-8 bit) sending is executed according to the algorithm.
And finally, the remote one-key forced stop program is executed to the executor according to the message converted by the instruction.
The above are merely embodiments of the present invention, which are described in detail and with particularity, and therefore should not be construed as limiting the scope of the invention. It should be noted that, for those skilled in the art, various changes and modifications can be made without departing from the spirit of the present invention, and these changes and modifications are within the scope of the present invention.

Claims (5)

1. A remote intelligent one-key forced stop control system for public passenger vehicles comprises a remote command platform, an interactive server, an intelligent gateway module, a vehicle-mounted terminal, a controller and an actuator, and is characterized in that,
the remote command platform is used for monitoring video data transmitted from the vehicle-mounted terminal, and issuing a one-key forced stop instruction to remotely control the vehicle speed if an emergency situation is confirmed;
the interactive server is connected with the vehicle-mounted terminal and the remote command platform and is used for transmitting data information and instructions between the vehicle-mounted terminal and the remote command platform;
and the vehicle-mounted terminal is used for receiving the data information and the instruction of the remote command platform, communicating with the background data processing center according to the data information and the instruction, and outputting a video monitoring signal and an emergency forced stop signal.
And the controller is respectively connected with the remote command platform, the interactive server, the vehicle-mounted terminal and the actuator, and outputs signals to the actuator to realize remote speed control and forced stop control.
2. The public passenger vehicle-oriented remote intelligent one-touch forced stop control system as claimed in claim 1, wherein the vehicle-mounted terminal comprises:
the data access and standardization module is used for accessing detection data of vehicle-mounted inflammable volatile matters, explosives, navigation positioning and the like in real time;
the video processing and analyzing module is used for supporting intelligent analysis of vehicle-mounted video images and early warning of abnormal behaviors;
the large-capacity storage module is used for supporting the local storage of detection data such as pictures, inflammable volatile matters, explosives, navigation and positioning and the like;
the wireless communication module is used for supporting real-time transmission and retrieval of video images, and real-time transmission of early warning information such as abnormal behaviors, inflammable volatile matters, explosives, navigation positioning, abnormal tracks and the like and vehicle remote control instructions;
the emergency communication module is used for supporting the real-time transmission of early warning information such as abnormal behaviors, inflammable volatile matters and explosives, navigation positioning and abnormal tracks under the conditions of wireless communication abnormity or interruption and the like;
the vehicle remote speed limiting and forced stopping module is wirelessly accessed to a vehicle speed limiting or forced stopping instruction, and transmits the control instruction to the vehicle speed control unit through a vehicle CAN bus to realize vehicle speed limiting or forced stopping;
the emergency power supply module is used for supporting emergency power supply under the condition that the vehicle-mounted power supply system is damaged, ensuring normal operation of vehicle-mounted terminal equipment and effectively acquiring key data of an incident time period;
the safety protection module is used for protecting the outside of the equipment and ensuring the vibration resistance, the collision resistance, the high temperature resistance and the like of the equipment.
3. The remote intelligent one-key forced stop control system for the public passenger vehicles as claimed in claim 1, wherein the controller adopts a remote forced stop control method comprising:
a. define remote forced-stop SISO discrete-time nonlinear system:
y(k+1)=f(y(k),...,y(k-ny),u(k),...,u(k-nu)
wherein y (k) and u (k) represent the output and input of the remote forced-stop SISO discrete-time nonlinear system at the time k, respectively; f (..) represents a nonlinear function of the system; the output y is the running speed of the passenger car at the moment;
b. the vehicle speed is defined as 60km/h, and the emergency acceleration is-8 m/s2U represents the opening degree of the valve of the brake device,
Figure FDA0002761588350000021
p (k) representing it as a non-emergency situation; q (k) represent it as a general emergency; z (k) represent it as an emergency;
c. defining that the passenger vehicle runs at a constant speed V, wherein the output y is Vm/s, the opening of a valve of a brake device is0, and the expected input speed is yd
Figure FDA0002761588350000022
d. When braking measures need to be taken, an error e is generated between an actually output y value and an expected value, then the speed deviation value is changed into an acceleration deviation value through an integrator, the acceleration deviation value acts on a control object through a controller, and finally the acceleration is adjusted by adjusting the opening degree of a braking device, so that remote intelligent one-key forced stop is realized.
4. The remote intelligent one-key forced stop control system for the public passenger vehicles according to claim 1, wherein when the vehicles are disturbed by the external environment during the driving process, if the signals are instantaneous signals, the signals are replaced by pulse signals, and if the signals exist for a certain time, the signals are replaced by step signals.
5. The remote intelligent one-key forced stop control system for the public passenger vehicles according to claim 1, wherein the actuator performs one-key forced stop after receiving a forced stop instruction, then feeds back a result to the vehicle-mounted terminal, feeds back the result to the interaction server after the vehicle-mounted terminal confirms with the vehicle-mounted terminal and the actuator, and feeds back the result to the remote command platform after the interaction server confirms with the vehicle-mounted terminal and the vehicle-mounted terminal.
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