DE102021204481A1 - Method for warning a vehicle operator of an imminent collision in a parking environment - Google Patents

Abstract

According to a first aspect of the invention, a method for warning a vehicle driver of an impending collision of the vehicle he is driving manually with a driverless, automated vehicle in a parking environment in which there are both driverless, automated vehicles and vehicles manually driven by human drivers Move vehicles, suggested. An infrastructure device detects impending collisions between an automatically guided vehicle and the manually guided vehicle using an infrastructure sensor system that has at least one infrastructure sensor. If an impending collision is detected, a warning signal is output as a result, so that the driver of the vehicle he is driving manually is warned of the impending collision with the driverless, automated vehicle and can react, for example by stopping or taking evasive action depending on the situation .

Description

The invention describes a method for warning a vehicle driver of an impending collision between the vehicle he is driving and an automated vehicle in a parking environment in which both driverless vehicles, in particular guided by an infrastructure facility, and vehicles manually guided by human vehicle drivers are on the road. It is provided that the infrastructure device recognizes imminent collisions between, in particular, stationary automatically guided vehicles and manually guided vehicles and, as a result, causes the automatically guided vehicle to emit a warning signal. The invention also relates to a parking environment. The invention also relates to a computer program.

State of the art

the DE 102016215468 A1 describes a method for warning a person located within a parking space. Provision is made here for the traffic within the parking lot to be recorded by means of sensors surrounding the parking lot. In a variant of the method, a server predicts the respective trajectories of the objects that are located within the parking lot, where the objects can be driverless vehicles, manually operated vehicles, cyclists and pedestrians in particular.

the DE 102018215008 A1 describes a method for operating a motor vehicle, in which data about the driving situation of a second vehicle is received. Furthermore, data about a third vehicle are determined with sensors of the motor vehicle.

the DE 102013200398 A1 discloses a method for warning of a collision of a motor vehicle. In the method, objects in the area surrounding one's own motor vehicle are detected using a detection device in one's own vehicle, and a probability of a collision with a detected object is determined. If a hazard is detected, a warning signal is issued to potential road users.

The driving corridor of a parking environment in which automated parking (so-called “automated valet parking”) is possible is monitored by infrastructure sensors, for example. Using the infrastructure sensors, automated guided vehicles (so-called "AVP vehicles") as well as all other vehicles and obstacles can be detected and localized. By determining relative object positions using the infrastructure sensors, for example, it is recognized when an object is approaching the AVP vehicle. This information can be used to warn of a collision. "AVP" is understood in particular as an automated, driverless parking process in which a vehicle is handed over to a so-called drop zone and then drives automatically and driverless within the parking area to an assigned parking space and parks there. For example, upon request or after a predetermined parking time has elapsed, the AVP vehicle automatically drives to a specific pick-up position (also referred to as a pick-up zone), where the driver can pick up the vehicle.

For example, if an AVP vehicle moves along a path while maintaining a defined minimum distance behind a manually guided vehicle in front, the AVP vehicle can stop in the event that the vehicle in front stops and/or reverses, e.g. to park backwards to prevent a collision.

However, if the vehicle in front has moved too far forward and the AVP vehicle driving behind automatically obstructs or prevents the parking space or the maneuvering process, a human vehicle driver would assume that the vehicle behind would free up the necessary space. Due to technical limitations on the AVP vehicle or due to direction of travel regulations that the AVP vehicle cannot break (or reversing may not be permitted due to one-way street regulations in multi-storey car parks only in the case of maneuvering for parking; but not to make room for a person driving ahead) however, this may be impossible. If the driver of the vehicle in front does not notice this fact, a collision can occur from the manually controlled vehicle. In this case, the automated vehicle is not able to avoid the collision.

Disclosure of Invention

The object on which the invention is based is to be seen as providing a concept for efficiently warning a vehicle driver of a vehicle traveling within a parking environment of an impending collision with a driverless vehicle.

This object is solved by means of the respective subject matter of the independent claims. Advantageous configurations of the invention are the subject matter of the dependent subclaims.

According to a first aspect of the invention, a method for warning a vehicle driver of an impending collision of the vehicle he is driving manually with a driverless, automated vehicle in a parking environment in which there are both driverless, automated vehicles and vehicles manually driven by human drivers Move vehicles, suggested. An infrastructure device detects impending collisions between an automatically guided vehicle and the manually guided vehicle using an infrastructure sensor system that has at least one infrastructure sensor. If an impending collision is detected, a warning signal is output as a result, so that the driver of the vehicle he is driving manually is warned of the impending collision with the driverless, automated vehicle and can react, for example by stopping or taking evasive action depending on the situation .

The invention is based on the finding that the above object can be achieved in that an infrastructure device, which can be designed in particular as a parking lot management server, based on monitoring the manually controlled and automatically guided vehicles moving within the parking environment, i.e. to decide determine whether a vehicle driver needs to be warned of an imminent collision of the vehicle he is manually guided with a driverless, automated vehicle and, if so, then issue a warning signal. The warning signal can, for example, control one or more signal transmitters in order to warn the driver of the driverless, automated vehicle. A central decision-making body, here the infrastructure facility, is therefore provided.

In particular, this brings about the technical advantage that vehicle drivers of manually controlled vehicles can be efficiently warned of an impending collision with a driverless vehicle. In particular, a collision probability between manually operated vehicles and driverless, automatically operated vehicles can be reduced.

A vehicle can be understood here in particular as a motor vehicle, for example a passenger car.

A parking environment within the meaning of the present invention can also be referred to as a parking area or a parking lot and serves as a parking area for vehicles, in particular motor vehicles. The parking environment thus forms an area, in particular a contiguous area, which has a number of parking spaces (in the case of a parking lot on private property) or parking lots (in the case of a parking lot on public property). According to one embodiment, the parking environment is designed as a multi-storey car park. According to one embodiment, the parking area is designed as a parking garage.

A driverless, automated vehicle refers in particular to an autonomous, i.e. independently, driving vehicle. An automated guided vehicle refers in particular to a vehicle that is remotely controlled, for example by means of the infrastructure facility of the parking area. Such a vehicle can also be referred to as an AVP vehicle, where AVP stands for "Automated Valet Parking", see above

That is, according to one embodiment, the driverless vehicle is a vehicle that is controlled remotely, for example by means of the infrastructure facility of the parking environment.
An impending collision is understood in particular as a situation in which the manually operated vehicle has a high probability of colliding with the driverless, automated vehicle when the manually operated vehicle and/or the driverless, automated vehicle maintain their current course.

In particular, the driverless, automatically guided vehicle drives behind the manually guided vehicle, with a specific direction of travel being specified for the driverless, automatically guided vehicle. For example, in the case of narrow access routes within the parking area, it can be provided for safety reasons that automated vehicles may only move in a certain direction, in the sense of a one-way street, in order in particular not to impede or endanger following traffic. The driverless, driverless, automated guided vehicle can therefore stop, but it cannot reverse to avoid an imminent collision. In this embodiment, it is provided that the driverless, automatically guided vehicle maintains a predetermined distance from the manually guided vehicle. An impending collision can now be recognized by detecting that the manually operated vehicle stops and then starts to reverse, e.g. to park in a parking space. If the distance between the driverless, automatically guided vehicle and the manually guided vehicle falls below the predetermined distance, the driverless, automatically guided vehicle can be stopped preferentially. If the distance decreases further, this can be recognized as an impending collision and a corresponding warning signal can be output to the vehicle driver of the vehicle that he is driving manually.

This can advantageously avoid a dangerous situation that arises, for example, when a human driver first drives past a parking space while looking for a parking space and then reverses and finally parks while a driverless, automated vehicle is following him, which can stop if the manually guided vehicle reverses, but not, as the human driver might expect, reverses to give way to the manually guided vehicle.

In another embodiment, the driverless, automatically guided vehicle drives ahead of the manually guided vehicle, with a specific direction of travel also being specified here for the driverless, automatically guided vehicle, so that it cannot reverse. A warning signal is output when a distance between the driverless, automatically guided vehicle and the manually guided vehicle falls below a predetermined minimum distance.

This advantageously avoids the dangerous situation that arises when the driverless, automatically guided vehicle has to carry out emergency braking, for example due to an obstacle that suddenly appears. A warning signal is output if, for example, a distance between the driverless, automatically guided vehicle and the manually guided vehicle falls below a predetermined minimum distance. By outputting a warning signal, the human vehicle driver of the manually operated vehicle can be made aware in good time that the driverless, automated vehicle has stopped and can initiate emergency braking or an evasive maneuver himself.

In a preferred embodiment of the invention, a warning signal is issued by one or more signal transmitters.

The signal transmitter is, for example, included in the driverless, automated vehicle itself, for example by a lighting system and/or a horn and/or a loudspeaker and/or interior lighting and/or underbody lighting of the driverless, automated vehicle. This has the advantage that the driver of the manually operated vehicle can directly identify the source of the impending collision and thus intuitively react correctly. This can increase the probability that the driver of the manually guided vehicle will react in such a way that a collision is avoided. In addition, no additional signal transmitters or warning systems are required within the parking area.

Alternatively or additionally, one or more signal transmitters can be included in the parking environment, ie belong to the infrastructure of the parking environment. A signal transmitter is designed, for example, as a signal light or floor lighting marking or loudspeaker or screen display.

Alternatively or additionally, the warning signal can be transmitted to the manually operated vehicle and/or to other manually operated vehicles moving within the parking area by means of a communication network, in particular by V2X communication. A warning display or an acoustic warning signal, for example, can then be generated directly in a manually operated vehicle from the received warning signal. Additional information such as status reports or error messages from the automated guided vehicle can also be transmitted and displayed.

In this way, in particular, the technical advantage can be brought about that the driver of the vehicle can be warned efficiently. The security can be further increased by the transmission to other, in particular other manually guided vehicles. For example, the situation can arise that a driver of a second manually-guided vehicle waiting behind the driverless, automatically-guided vehicle that is waiting becomes impatient and prepares to overtake, resulting in an additional risk of collision. If the driver of this second, manually operated vehicle is also made aware of the situation by means of a warning signal transmitted via V2X communication, the driver of this second vehicle can better assess the situation and may not overtake.

According to one embodiment, a communication network comprises a WLAN communication network and/or a mobile radio communication network and/or a radio network. The use of other wireless communication standards is also conceivable; these are known to those skilled in the art.

According to one embodiment, a communication via the communication network is or is encrypted.

An impending collision between a stationary, automatically guided vehicle and the manually guided vehicle can be detected by the infrastructure device, for example, by detecting and monitoring the absolute and/or relative positions of the vehicles. For this purpose, the parking environment has in particular one or more infrastructure sensors that the absolute and/or detect relative positions of the vehicles and transmit this information to the infrastructure facility. By evaluating the position information, the infrastructure device can detect whether the manually guided vehicle is moving backwards in the direction of the stationary, automatically guided vehicle, for example, and a collision is therefore imminent. For example, the infrastructure device can also detect an impending collision between a stationary, automatically guided vehicle and the manually guided vehicle by detecting that the automatically guided vehicle has suddenly stopped and the manually guided vehicle is approaching the stationary, automatically guided vehicle from behind .

In particular, by evaluating a temporal development of the detected positions of the vehicles, it can be determined whether a collision is actually imminent between an automatically guided vehicle and the manually guided vehicle. If, for example, it is recognized that the predetermined minimum distance has not been reached, but the manually-guided vehicle is already slowing down and will come to a standstill in good time, or that the manually-guided vehicle has changed its direction of travel and, possibly at a small distance, is approaching the, in particular stationary, automatically guided vehicle passes, the output of the warning signal can be stopped or changed. Such an evaluation can be carried out, for example, by evaluating successively recorded camera images using known methods of digital image processing with regard to the positions of vehicles imaged thereon.

This achieves the advantage in particular that the driver of the vehicle is not warned unnecessarily.

According to a second aspect of the invention, an infrastructure device that is designed to carry out a method according to one of the preceding claims. For this purpose, the infrastructure unit can have one or more corresponding computing units which, for example, evaluate position and/or movement data received from infrastructure sensors from manually and automatically guided vehicles within a parking environment and detect impending collisions.

According to one embodiment, the infrastructure device includes at least one processor.

For example, the processor is configured to determine, based on monitoring, whether a driver of a manually controlled vehicle needs to be warned of an unmanned vehicle.

According to one embodiment, the processor is designed, if the determination has shown that a vehicle driver of a manually controlled vehicle must be warned of a driverless vehicle, to issue a warning signal that controls in particular one or more signal transmitters, so that the vehicle driver of the manually controlled vehicle can be warned by means of one of the plurality of signal generators before the driverless vehicle.

In one embodiment, the infrastructure device includes a communication interface that is designed to communicate via a communication network. In particular, the communication interface is designed to send a control command via a communication network to a signal transmitter in the parking area or to a signal transmitter in a vehicle. In particular, the communication interface is designed to receive environment data from infrastructure sensors via the communication network.

According to one embodiment, the communication interface is designed to send a stop command to an automated guided vehicle via the communication network in order to stop it remotely.

According to one embodiment, the infrastructure device is designed to remotely control a vehicle within the parking environment.

The infrastructure device is preferably also set up to determine a path for a driverless, automatically guided vehicle, which the driverless, automatically guided vehicle follows within the parking environment and to generate corresponding control commands and to transmit them to the driverless, automatically guided vehicle using a communication network. For example, the infrastructure facility can assign a parking space to an automated guided vehicle and calculate a path that the automated guided vehicle has to follow in order to get to the parking space in order to be parked there. The infrastructure device can, for example, generate corresponding control signals and transmit them to the automated guided vehicle. The infrastructure device can be set up to transmit a digital map of a parking environment to the automated guided vehicle based on which the automated guided vehicle can be automatically guided within the parking environment. The infrastructure facility calculates a path that the automated guided vehicle has to follow in order to get from the parking space where it is parked to an exit from the parking area or to a pick-up area.

According to a third aspect of the invention, a parking environment for both driverless, automatically guided vehicles and vehicles guided manually by human vehicle drivers is proposed which has an infrastructure device according to the second aspect of the invention and at least one infrastructure sensor which is designed to determine the relative position of the driverless, automatically guided vehicle and the vehicle controlled manually by the vehicle driver and to make the infrastructure facility available.

At least one infrastructure sensor can be designed as a camera sensor, radar sensor and/or lidar sensor, for example. A number of infrastructures can be provided which are designed in the same way or differently.

According to a fourth aspect of the invention, a computer program comprising program code for carrying out a method according to the invention when the computer program is executed on a computer.

character list

• 1a)-d) zeigt schematisch vier aufeinanderfolgende Szenen einer Fahrsituation innerhalb einer Parkumgebung, bei der eine drohende Kollision eines manuell geführten Fahrzeugs mit einem führerlosen, automatisiert geführten Fahrzeug auftritt.
• 2 zeigt ein schematisches Ablaufdiagramm eines Verfahrens gemäß einem Ausführungsbeispiel der Erfindung
• 3 zeigt schematisch eine Parkumgebung nach einem Ausführungsbeispiel der Erfindung umfassend eine Infrastruktureinrichtung nach einem Ausführungsbeispiel der Erfindung.

Embodiments of the invention are described in detail with reference to the attached figures.

• 1a)-d ) schematically shows four consecutive scenes of a driving situation within a parking environment, in which an impending collision of a manually operated vehicle with a driverless, automated vehicle occurs.
• 2 shows a schematic flowchart of a method according to an embodiment of the invention
• 3 shows schematically a parking environment according to an embodiment of the invention comprising an infrastructure facility according to an embodiment of the invention.

Preferred Embodiments of the Invention

In the following description of the exemplary embodiments of the invention, the same elements are denoted by the same reference symbols, with a repeated description of these elements being dispensed with if necessary. The figures represent the subject matter of the invention only schematically.

1 a)-d ) shows the course of a possible driving situation within a parking environment 301 in which both driverless, automated vehicles and vehicles manually controlled by human vehicle drivers are moving, with a method implemented according to the invention for warning a vehicle driver of an imminent collision of the vehicle 12 is carried out with a driverless, automated guided vehicle 10.

As in 1 a) shown drives the manually guided vehicle 12 within the parking area 301. The parking area 301 has a plurality of parking spaces 30, 32 on which vehicles can be parked. The manually guided vehicle 12 moves along a lane 17 in a predefined direction of travel 18. A driverless, automatically guided vehicle 10 drives behind the manually guided vehicle 12. The driverless, automatically guided vehicle 10 follows the manually guided vehicle 12 at a predetermined distance 14 , which is 3 meters, for example. In this example, the movement of driverless, automated vehicle 10 is controlled by a (not shown, see 3 ) Infrastructure unit 201 controls the parking environment 301, which sends appropriate control commands to the driverless, automated guided vehicle 10 by means of a wireless communication link.

The movement of the vehicles 10, 12 is monitored by an infrastructure sensor 20, which is arranged within the parking environment 301. In this example, the infrastructure sensor 20 is designed as a camera sensor, in particular as a stereo camera. The parking environment 301 may include additional infrastructure sensors. The infrastructure sensors can be in the form of camera sensors, lidar sensors or radar sensors or ultrasonic sensors, for example.

The driver of the manually operated vehicle 12 recognizes that the parking space 32 is free and decides to back the vehicle 12 into the parking space 32 . To this end he holds, as in 1 b) shown, the vehicle 12 and activates the direction indicator 15 right. The driverless, automatically guided vehicle 10 then receives the command to also stop, since this is the only way to maintain the specified distance 14 . The driver of the manually guided vehicle 12 has driven a little too far past the parking space 32, so that he has to back up a little for the parking maneuver provided, as in FIG 1 c) is shown. The driver of the manually controlled vehicle 12 initially does not know that the vehicle 10 behind him is a driverless, automatically controlled vehicle 10 . In a human-driven vehicle, the driver of the manually-guided vehicle 12 might assume that it is backing up to make room. The driverless, automated guided vehicle 10 has However, in this example, a predetermined direction of travel 18 and can therefore not perform a corresponding maneuver. Furthermore, the driverless, automated guided vehicle 10 has no way of recognizing the intention of the driver of the manually guided vehicle 12 . So it stays put.

By reversing the manually guided vehicle 12, the distance between the two vehicles 10 and 12 decreases further, so that the distance is now smaller than the predetermined distance 14. This is detected by the infrastructure sensor 20. For this purpose, the infrastructure sensor 20, for example, continuously captures image data of the scene, including information about the positions of the vehicles 10 and 12, and sends this to the infrastructure device. The image data is evaluated there and analyzed with regard to an impending collision between vehicles 10 and 12 . At the latest at the in 1d) illustrated situation in which the manually guided vehicle was backed even further, the analysis of the image data shows that a collision between the automatically guided vehicle 10 and the manually guided vehicle 12 is imminent if the manually guided vehicle continues its maneuver. As a result, the infrastructure device 201 sends a warning signal to the automatically guided vehicle 10, whereupon the hazard warning system 13 of the automatically guided vehicle 10 is activated as a signal transmitter. Alternatively or additionally, further signal generators, for example a horn of the automatically guided vehicle 10 and/or the front and/or rear headlights and/or a signal system of the parking area 301 (not shown) can be activated. For example, as the distance between vehicles 10 and 12 decreases, the intensity of the warning can be increased, for example by successively activating more and more different signal generators at shorter distances and/or increasing the light intensity or volume or repetition rate (frequency) of the warning signals issued, the smaller the distance. Other ways of changing the warning signals are conceivable, e.g. B. a color change and / or the display of different warning symbols and / or voice output of a warning message. In this case, additional information about the automatically guided vehicle 10 and/or the imminent collision can also be transmitted to the driver of the manually guided vehicle 12 .

By outputting the warning signal, the driver of the manually operated vehicle 12 is informed of the impending collision and can stop the parking maneuver in good time. In an alternative embodiment, a V2X signal can be sent to the manually operated vehicle 10 as a warning signal, whereby z. B. a warning can be issued directly in the manually guided vehicle, z. B. on a display and / or via a speaker system within the vehicle 10.

2 shows a flowchart of a method for warning a vehicle driver of an impending collision of the vehicle he is driving manually with a driverless, automated vehicle in a parking environment in which both driverless, automated vehicles and vehicles driven manually by human vehicle drivers are moving.

In a step 101, traffic within the parking lot is monitored. According to a step 103, based on the monitoring, it is determined whether a vehicle driver of a manually controlled vehicle needs to be warned of an imminent collision with a driverless, automated vehicle, since a collision of the vehicles is imminent. The determination is carried out by means of an infrastructure unit, which is comprised of a parking lot management server, for example, by analyzing data recorded by an infrastructure sensor system.

If determination 103 has shown that a vehicle driver of a manually controlled vehicle does not need to be warned of an imminent collision with a driverless, automatically controlled vehicle, then the method is continued in step 101 .

If the determination according to step 103 has shown that the driver of a manually operated vehicle must be warned of an impending collision with a driverless, automated vehicle, the infrastructure unit outputs a warning signal according to step 105, with one or more signal generators be controlled so that the driver of the manually guided vehicle can be warned of an impending collision with a driverless, automated guided vehicle.

3 shows a parking environment 301 for motor vehicles, the parking environment 301 including an infrastructure facility 201 .

At this point it is noted that 3 only shows a schematic block diagram without showing details of a parking environment or an infrastructure device in detail.

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102016215468 A1 [0002]
• DE 102018215008 A1 [0003]
• DE 102013200398 A1 [0004]

Claims (13)

Method for warning a vehicle driver of an impending collision between the vehicle (12) being manually guided by him and a driverless, automatically guided vehicle (10) in a parking environment (301) in which both driverless, automatically guided vehicles (10) and manually vehicles driven by human drivers move (12), with an infrastructure device (201) detecting imminent collisions between an automatically driven vehicle (10), in particular a stationary one, and the manually driven vehicle (12) by means of an infrastructure sensor system which has at least one infrastructure sensor (20). , and as a result a warning signal is output. procedure after claim 1 , wherein the driverless, automatically guided vehicle (10) drives behind the manually guided vehicle (12), wherein a certain direction of travel (18) is specified for the driverless, automatically guided vehicle (10) and wherein the driverless, automatically guided vehicle (10 ) maintains a predetermined distance (14) from the manually guided vehicle (12). procedure after claim 2 , wherein the driverless, automated guided vehicle (10) is stopped when the predetermined distance (14) is undershot. procedure after claim 1 , wherein the driverless, automatically guided vehicle (10) drives ahead of the manually guided vehicle (12), wherein a specific direction of travel (18) is specified for the driverless, automatically guided vehicle (10) and wherein the warning signal is output when a distance between the driverless, automatically guided vehicle (10) falls below a predetermined minimum distance from the manually guided vehicle. Method according to one of the preceding claims, wherein the warning signal is emitted by the driverless, automated vehicle (10), in particular by a lighting system (13) and/or a horn and/or a loudspeaker of the driverless, automated vehicle (10). Method according to one of the preceding claims, wherein the warning signal is transmitted to the manually operated vehicle (12) and/or to other manually operated vehicles moving within the parking environment by means of a communication network, in particular by V2X communication. Method according to one of the preceding claims, wherein the infrastructure device (201) detects an imminent collision between a stationary, automatically guided vehicle (10) and the manually guided vehicle (12) by detecting that the manually guided vehicle (12) is reversing moves in the direction of the stationary, automatically guided vehicle (10). Method according to one of the preceding claims, wherein the infrastructure device (201) detects an impending collision between a stationary, automatically guided vehicle (10) and the manually guided vehicle (12) by detecting that the automatically guided vehicle (10) suddenly stopped and the manually guided vehicle (12) approaches the stationary, automatically guided vehicle (10) from behind. Infrastructure device (201) which is designed to carry out a method according to one of the preceding claims. Infrastructure device (201) after claim 9 which is also set up to determine a path for a driverless, automated guided vehicle (10) along which the driverless, automated guided vehicle (10) travels within the parking environment (301) and to generate corresponding control commands and to the driverless, automated guided vehicle To transmit vehicle (10) by means of a communication network. Parking environment (301) for both driverless, automatically guided vehicles (10) and vehicles (12) manually guided by human vehicle drivers, comprising an infrastructure device (201) according to one of claims 9 or 10 and an infrastructure sensor system with at least one infrastructure sensor (20), which is designed to detect the relative position of a driverless, automated vehicle (10) and a vehicle (12) controlled manually by the vehicle driver and to make the infrastructure device (201) available . parking environment after claim 11 , wherein the at least one infrastructure sensor (20) is designed as a camera sensor and/or radar sensor and/or lidar sensor. Computer program comprising program code for carrying out the method according to one of Claims 1 until 8th , if the computer program runs on a computer.

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