EP2648171A1 - System and method for managing parking space occupancy - Google Patents

Abstract

The method involves detecting a user (301) requesting actuation of regulating access to a parking space. A determination is made (302) if the user is previously authorized to access the parking space by a parking management system. A command for actuating a barrier unit is transmitted (305) in case of positive verification so as to allow a user to pass through the parking space. A state of occupation of the parking space is modified (307) on determining that the vehicle is passed (306) through the barrier unit to the parking space. Independent claims are also included for the following: (1) a method for managing parking space occupancy (2) a computer program comprising instructions for performing the method for managing parking space occupancy (3) a storage unit with instructions for performing the method for managing parking space occupancy.

Description

The present invention relates to the management of parking spaces.

Any vehicle movement requires a parking solution at the destination. The problem facing any agglomeration is the shortage of parking supply. Users are in fact more and more numerous whereas the urban space is not very extensible. The construction of underground or overground car parks is also particularly expensive.

There are many unused parking spaces for hours ranging from a few hours to several days of rank. These include the parking places of private homes when they are at their place of work or vacation and the places of government or business during their hours of closure. These places are often difficult to reach for third parties, even on foot, because they have doors or automatic gates. Access to these parking spaces must, however, remain under control in order to ensure that they will actually be released during slots not made available to their owners. Access to these parking spaces must also be secured to prevent malicious third parties that are difficult to identify to access these spaces. car parks, in particular for parking during slots not made available to their owners.

It is desirable to overcome these various disadvantages of the state of the art.

The invention relates to a system for managing the occupancy of at least one parking space in at least one access parking area regulated by means of a barrier device, comprising means for detecting a user requiring an actuation of the dam device regulating access to a said parking lot; verification means that the user has been previously authorized to access said parking lot by the management system; means for transmitting an actuation command of said barrier device, in the event of positive verification by said verification means, so as to allow the user to pass via the access controlled by said barrier device; means for modifying a state of occupancy of a parking space of said car park, in the event of detection of a vehicle passage via the access regulated by said barrier device. Thus, the system can control the actual entries and exits of the vehicles, and take measures in the event that time constraints of occupation of the parking spaces are not respected. Such measures are for example the sending of a vehicle to remove the vehicle from a user exceeding the parking period granted to him, or sending a warning to the user.

According to a particular embodiment, the user's detection means comprise means for receiving a remote control signal and means for obtaining an identifier associated with the user from the received remote control signal. Thus, the user can access various car parks by means of the same remote control that can identify it. In addition, the use of this remote control provides access to covered car parks, for which the radiotelephone network coverage is low or non-existent.

According to a particular embodiment, said system comprising a remote control intended to be assigned to the user, the remote control is adapted to select an identifier from a set of identifiers stored in said remote control, and the verification by said verification means is positive when the identifier obtained from the received remote control signal is distinct from an identifier obtained from a previously received remote control signal. Thus, by the use of such a remote control, access to the car park is secure.

According to a particular embodiment, the system comprising a server and at least one control point intended to be located near a said barrier device, each identifier transmitted by a remote control signal comprising a part transmitted in clear and a part transmitted in encrypted form, the control point comprises means for detecting a cut of a communication link connecting the checkpoint and the server. The verification that the user has been previously authorized to access the parking is implemented by the control point on the basis of the transmitted part in clear of the identifier, when a break of the communication link is detected; the verification that the user has previously been authorized to access the parking is implemented by the server at least on the basis of the portion transmitted in encrypted form of the identifier, when no break in the communication link is detected . Thus, access to the car park is secure, while allowing the user to recover his vehicle parked in the car park.

According to a particular embodiment, the checkpoint comprises means for recording in a local log of changes in the state of occupancy of parking spaces, when a break in the communication link is detected; means for detecting a restoration of the communication link; means for transmission to the server of the local log, when a restoration of the communication link is detected. Thus, the occupancy states of the parking spaces are up to date at the server level despite the cutting of the communication link.

According to a particular embodiment, the means for detecting the user comprise means for receiving a call from the user on a voice server. Thus, the user can benefit from the system simply through a mobile phone.

According to a particular embodiment, in the case of a positive verification by said verification means, the management system implements means for obtaining the user's coordinates, and transmission means intended for the user. a message including an identifier of an assigned parking space. Thus, each parking space of a car park can be managed independently of the other parking spaces of this car park.

According to a particular embodiment, the management system comprises: means for receiving, from a terminal associated with a user, a parking request in a given geographical area; means for determining, in the given geographical area, a list of car parks comprising parking available; means for transmitting to said terminal of the determined list; means for receiving, from the terminal, a validation of a car park among the list; means for reserving, for said user, a parking space in the validated parking lot. Thus, the user can find a parking solution close to its destination, and ensure availability.

The invention also relates to a method for managing the occupancy of at least one parking space in at least one regulated access car park by means of a barrier device. A management system performs the following steps: detection of a user requiring an actuation of the barrier device regulating access to said parking; verification that the user has been previously authorized to access said parking lot by the management system; transmitting an actuation command of said barrier device, in the case of positive verification, so as to allow the user to pass via the access regulated by said barrier device; modification of a state of occupancy of a parking space of said car park, in the event of detection of a vehicle passage via the access regulated by said barrier device.

The invention also relates to software, which can be stored on a medium and / or downloaded from a communication network, in order to be read by a processor. This software includes instructions for implementing the method mentioned above, when said software is executed by the processor. The invention also relates to storage means comprising such software.

• la Fig. 1 illustre schématiquement un système de gestion d'occupation de places de stationnement ;
• la Fig. 2 illustre schématiquement une architecture de serveur ou de point de contrôle du système de gestion d'occupation de places de stationnement ;
• la Fig. 3 illustre schématiquement un algorithme de gestion d'occupation de places de stationnement ;
• les Figs. 4, 5 et 6 illustrent schématiquement des algorithmes de gestion d'occupation de telles places, mis en oeuvre par un serveur dudit système ;
• les Figs. 7 et 8 illustrent schématiquement des algorithmes de gestion d'occupation de telles places, mis en oeuvre par un point de contrôle dudit système.

The characteristics of the invention mentioned above, as well as others, will appear more clearly on reading the following description of an exemplary embodiment, said description being given in relation to the attached drawings, among which:

• the Fig. 1 schematically illustrates a parking occupancy management system;
• the Fig. 2 schematically illustrates a server or control point architecture of the parking occupancy management system;
• the Fig. 3 schematically illustrates an occupancy management algorithm of parking spaces;
• the Figs. 4 , 5 and 6 schematically illustrate algorithms for occupancy management of such places, implemented by a server of said system;
• the Figs. 7 and 8 schematically illustrate algorithms for occupancy management of such places, implemented by a control point of said system.

The Fig. 1 illustrates a parking space management system. The system comprises a server 100 and at least one control point 101 connected by a communication network 120, for example the Internet. The control point 101 and the server 100 may also be connected by an additional network, serving as a fallback in the case where the connection via the communication network 120 would be disturbed or interrupted. For example, the control point 101 and the server 100 preferentially communicate via GPRS ("General Packet Radio Service" in English), and when the GPRS connection is interrupted, they communicate by SMS ( "Short Message Service" on the network). GSM (" Global System for Mobile Communications" ).

The server 100 is in charge of managing a schedule of reservation and occupation of the parking spaces and to authenticate the users accessing the parking spaces. The reservations can be made to the server 100 via a communication network 121. The user wishing to reserve a parking space accesses through a user equipment 130, such as a computer or a mobile phone, to a reservation service exported by the server 100, for example in the form of a website. Users can also access the car park by presenting themselves without a reservation at a checkpoint 101. In order to maintain the reservation and occupancy schedule of the parking spaces, the server 100 manages occupancy states of parking spaces indicating whether places are free or occupied by passenger vehicles. The occupancy states of parking spaces may further indicate whether the places are made available by their holder, or whether they are reserved. The reservation and occupancy schedule indicates the occupation status of the parking spaces according to slots.

Each control point 101 is in charge of controlling the access to a car park of at least one parking space. Each car park at least one parking space is managed by the system has a control point 101. The control point 101 deals with parking access commands issued by a control member 102, which is for example a remote control provided to a system user by a system operator. Each control point 101 is connected to a control box 110, controlling the opening and closing of a barrier device, for example a door, a barrier or retractable studs, restricting access to the parking. This control box 110 can also be directly controlled by means of a remote control or a badge 111 by the holders of parking spaces in the parking lot. They can continue to access the parking as usual. The control point 101 may for example control the control unit 110 by reproducing the control signals emitted by the remote control 111, which requires no modification of the barrier devices and their automatisms, or be electrically connected to the control unit 110. The control point 101 is furthermore connected to at least one sensor 103, such as a sensor for passing a vehicle via the access regulated by said barrier device, and to signaling means 104, such as horns. bright and / or sound. According to a first example, such a vehicle passage sensor is a detector of variations of the earth's magnetic field. The sensor is placed at ground level, and the arrival of a vehicle, which contains ferromagnetic materials, deforms this magnetic field locally. According to a second example, such a passage sensor is a pneumatic pipe placed on the ground perpendicular to the axis of circulation. The passage of a vehicle causes a crushing of the pipe, causing inside the pipe a pressure variation detectable by a piezoelectric sensor.

The Fig. 2 illustrates schematically an example architecture of the server 100. The server 100 then comprises, connected by a communication bus 210: a processor or CPU ("Central Processing Unit" in English) 200; a Random Access Memory (RAM) 201; a ROM ( Read Only Memory ) 202; a communication interface 204 with the communication network 120; optionally a communication interface 205 with the communication network 121; and a storage unit 203, such as a HDD ( "Hard Disk Drive" ), or a storage medium reader.

It should be noted that each control point 101 can be implemented according to the same architecture example, replacing the communication interface 205 with an interaction management interface with the control member 102, the control box 110, the sensor (s) 103 and the signaling means 104.

The processor 200 is capable of executing instructions loaded into the RAM 201 from the ROM 202, an external memory (not shown), a storage medium, such as the HDD 203, or a communication network. When the server 100 or the control point 101 is turned on, the processor 200 is able to read instructions 201 from the RAM and execute them. These instructions form a computer program causing the implementation, by the processor 200, all or some of the algorithms described below in connection with the Fig. 3 , the Figs. 4 to 6 where the Figs. 7 and 8 . All or part of the algorithms described below can be implemented in software form by executing a set of instructions by a programmable machine, such as a DSP ( "Digital Signal Processor" in English), or be implemented in hardware form. by a machine or a dedicated component, such as a FPGA ( Field-Programmable Gate Array ).

The Fig. 3 schematically illustrates an occupancy management algorithm of parking spaces, as it can be implemented by the system of the Fig. 1 .

In a step 301, the system detects a user requiring an actuation of the barrier device regulating access to a parking lot. In a step 302, the system verifies that the user has been previously authorized to access the parking lot by the system. For example, this user has registered with the server via the website, and presents himself with his vehicle at the entrance of the car park. In another example, the user was parked in the parking lot, so known from the system, and is at the exit of the car park. In a step 303, the system tests whether the user has actually been authorized; if it is the case, it performs a step 305, otherwise it performs a step 304 in which it reports an error, for example by means of warning lights and / or sound. In step 305, the system issues an actuation command so as to allow the user to pass via the access controlled by the barrier device, such as a barrier opening control. In a step 306, the system checks whether it detects a vehicle passage via the access controlled by the barrier device. If it is, it performs a step 307, otherwise it ends the algorithm in a step 308. In step 307, the system modifies a state of occupancy of a parking space of the parking.

Thus, authorized users can freely enter and leave the car park without their vehicle despite the barrier. The occupation of the parking spaces is however managed according to the actual entries / exits of the vehicles of the authorized uses.

The Fig. 8 schematically illustrates an algorithm implemented by the control point 101, located in the vicinity of a barrier device regulating access to a parking lot, when a user requires an actuation of the barrier device.

In a step 801, the control point 101 receives an identifier associated with the user from the control member 102. In a preferred embodiment, the control member 102 is a remote control point 101 is adapted to receive signals transmitted by this remote control and to obtain an identifier associated with the user from the received remote control signal. This obtaining can be performed by the server 101 from the remote control signal propagated by the control point 101, especially when the remote control transmits signals in encrypted form.

In a step 802, the checkpoint 101 tests whether the connection with the server 100 is working. If it is interrupted, it performs a step 804, otherwise it performs a step 803. In step 803, the control point 101 sends the server 100 the identifier received in step 801. In a step 805, it receives from the server 100 a notification authorizing or not the actuation of the barrier device. If this is the case, the checkpoint 101 performs a step 811, otherwise it performs a step 806 in which it reports an error via the signaling means 104.

In step 811, the control point 101 orders the control box 110 to open the barrier device, so as to allow the user to pass via the access controlled by the barrier device. In a step 812, the checkpoint 101 tests whether the sensors 103 detect a vehicle passage via the access controlled by the barrier device. This step aims to determine if the user crosses the access on foot or with his vehicle, whether entering or leaving the car park. If a vehicle is detected, a step 813 is performed, otherwise a step 815 is performed. In step 813, the checkpoint 101 sends the server 100 a vehicle transit notification, and then performs a step 814 in which it receives from the server 100 an update order of the data relating to the user. If the user enters the car park, the control point 101 stores in an internal memory all or part of the identifier received in step 801, and if the user leaves the car park, the control point 101 clears his internal memory all or part of the identifier received in step 801 and previously stored. In a particular embodiment, the control point 101 can determine whether the user exits or enters the parking, by determining whether the identifier received in step 801 is present, or not, in its internal memory. The control point 101 then performs step 815, in which it orders the control box 110 to close the barrier device. The management of any closure of the barrier device can also be left to the control unit 110 without intervention of the control point 101. The control unit 110 orders for example the closure of the barrier device after the expiration of a predefined time.

In a particular mode, the remote control member 102 being a remote control, each identifier transmitted by a remote control signal comprises a portion transmitted in clear and a portion transmitted in encrypted form. The checkpoint 101 stores in step 814 the clear part, and provides the server 100 at step 803 at least the encrypted part, and possibly the clear part.

In step 804, checkpoint 101 tests whether all or part of the identifier received in step 801 is stored in its internal memory. If this is the case, it performs a step 807, otherwise it performs step 806. Thus, the opening of the barrier device is not ordered if the vehicle of the user is not parked in the parking lot, when the connection between the control point 101 and the server 100 is broken. In step 807, the control point 101 orders the control box 110 the opening of the barrier device, so as to allow the user to pass via the access controlled by the barrier device. In a step 808, the checkpoint 101 tests whether the sensors 103 detect a vehicle passage via the access controlled by the barrier device. If a vehicle is detected, a step 809 is performed, otherwise a step 810 is performed. In step 809, the checkpoint 101 records, in an event log, a vehicle output event in association with the identifier received at step 801. In other words, the checkpoint 101 records changes in the occupancy status of the parking spaces of the car park, when a break of the communication link with the server 100 is detected. The control point 101 then performs step 810, in which it orders the control box 110 to close the barrier device.

The Fig. 7 schematically illustrates an algorithm implemented by the control point 101, during disconnections and reconnections of the communication link with the server 100.

In a step 701, the checkpoint 101 detects a disconnect with the server 100. In a step 702, it activates the event log, and in a step 703, it records the events that are related to state changes. occupancy of the parking spaces of the car park, during the duration of the disconnection. In a step 704, the checkpoint 101 detects a reconnection with the server 100. In a step 705, it transmits to the server 100 the contents of the event log. Thus, the server 100 can update its data relating to the occupancy states of the parking spaces of the car park. In a step 706, the checkpoint 101 receives from the server 100 an order for updating the data relating to the users who have left the parking during the link break with the server 100. The checkpoint 101 erases from its internal memory the previously stored identifiers for these users.

The Fig. 6 schematically illustrates an algorithm implemented by the server 100, during reconnections of the communication link with the control point 101.

In a step 601, the server 100 detects a reconnection with the control point 101. In a step 602, the server 100 receives from the control point 101 the contents of the event log that the control point 101 has activated, and maintained, during the break of the link. In a step 603, the server 100 scans and analyzes the contents of the event log and then updates the occupancy states of the parking spaces of the car park to which the control point 101 is associated. In a step 604, the server 100 orders the control point 101 to update the data relating to the users and stored in its internal memory, by erasing the previously stored identifiers for users who have left the car park during the link break. with the server 100.

The Fig. 4 schematically illustrates an algorithm implemented by the server 100 to obtain a representation of the occupation of the parking spaces.

In a step 401, the server 100 receives from the control point 101 a vehicle passage notification via the access controlled by the barrier device near which the control point 101 is installed. In a step 402, the server 100 modifies the state of occupation of at least one parking space of the car park which this barrier device regulates access. The server 100 can manage the occupation of the parking spaces as a whole, that is to say by determining a number of free and occupied parking spaces. The server 100 can manage the occupation of the parking spaces on a per seat basis, that is to say by determining the actual occupation of each parking space. The server 100 can furthermore draw up the list of the users whose vehicle is actually parked in the car park, which makes it possible to verify that these users respect a reservation schedule and / or a schedule of provision of the parking spaces by their usual holder. . This makes it possible to warn the user in question, for example by SMS, when the time slot during which the parking space has been allocated to him is exceeded or about to be exceeded. The user being previously registered with the server 100, the server 100 can have coordinates, for example telephone number or email address, to contact the user. In a step 403, the server 100 orders the checkpoint 101 to update the data relating to the user, as already described in connection with step 814.

The Fig. 5 schematically illustrates an algorithm implemented by the server 100 to allow, or not, the actuation of a barrier device to a user, when it is presented to the barrier device.

In a step 501, the server 100 receives from the checkpoint 101 an identifier to check, and in a step 502, checks whether it corresponds to a user previously registered and allowed to enter / exit the parking.

In one embodiment, a remote control is provided by the system operator to the user when registering the user with the system. This remote control transmits an identifier, in response to pressing a button on the remote control or other user command, which is captured by the control device 101. This identifier is associated with the user and allows identification.

According to an improvement, the remote control is adapted to select an identifier from a set of identifiers stored in said remote control. This set of identifiers is associated with the user. The server 100 verifies that the identifier obtained in step 501 is distinct from an identifier obtained from a previously received remote control signal. In other words, for the same user, the identifiers vary in a predefined list between two supports and the server verifies that the same identifier is not used twice in a row. This makes it possible to secure the use of remotes, so that a third party can not pick up the signal emitted by one of these remotes and use it to freely enter the car parks managed by the system. The security is also enhanced if the remote control selects the identifier from the set of identifiers stored in a predefined sequence, and the server 100 verifies compliance with this predefined sequence.

According to another improvement, each identifier transmitted by the remote control is encrypted at least in part, and the server 100 decrypts the received identifier to check whether it corresponds to a user authorized to enter / exit the parking. The server 100 may additionally use a portion of the identifier transmitted in clear by the remote control for this verification.

In addition, in step 502, the server 100 can check the availability of at least one parking space in the car park to which the control point is associated. This operation is carried out on the basis of the occupancy states of the parking maintained by the server 100. This operation is performed if the user is not indicated in the server data 100 as parked in the parking.

In addition, in step 502, the server 100 can check whether the registration of the user with the server 100 gives him the right of access to this parking. Indeed, the users can be classified according to different profiles allowing, according to the profile in which the user is classified, to allow access to only certain car parks.

Also, in step 502, the server 100 can check whether the user has previously reserved a parking space in the car park to which the control point is associated, for the time slot at which the user has presented himself to the device. dam.

Also, in step 502, the server 100 can check whether the user is registered in a blacklist, grouping the users having for example made fraudulent maneuvers by accessing the car parks. Such fraudulent maneuvers are for example detected by the control point 101 when the barrier device has been opened by the system to let in the user and that several vehicles are successively detected by the sensor 103 during the opening time of the device when the barrier device has been opened by the system to allow the user to retrieve his vehicle and at least one other vehicle is detected by the sensor 103 during the opening time of the device dam.

In a step 503, the server 100 tests the result of the check. If the user is authorized, a step 505 is performed, otherwise a step 504 is performed in which the server 100 transmits to the control point 101 a notification that does not authorize the actuation of the barrier device, or because the identifier is not validated by the server 100, or because no place is currently available or previously reserved by the user; then the algorithm is terminated. In step 505, the server 100 optionally allocates a parking space to the user, if the latter has come to the barrier device to park his vehicle in the parking lot. In a step 506, the server 100 transmits to the control point 101 a notification authorizing the actuation of the barrier device. The server 100 may further transmit to the user a message including an identifier of an assigned parking space.

In a particular mode, the server 100 is adapted to allow the user to previously reserve a parking space. The server 100 receives from the user equipment 130 associated with the user, possibly via a identification system of the user, a parking request in a given geographical area. The request may indicate a reservation time slot. The server 100 determines, on the basis of the occupancy states of the parking spaces and in the given geographical area, a list of car parks with parking spaces currently available, or available in the reservation time slot. The server 100 can also transmit the list of all the car parks of the given geographical area and mark those with available parking spaces. The server 100 then transmits this list to the user equipment 130, and receives in response a validation of a car park from the list. The server 100 then reserves, for the user, a parking space in the parking validated. Such a reservation may be canceled if the user has not presented himself to the barrier device corresponding to a given moment, for example the beginning of the reservation time slot, or after a predetermined duration after the reservation has been made, by example to allow 10 minutes for the user to go to the car park.

In another particular mode, the user does not use a remote control to require the actuation of the barrier device, but uses the user equipment 130 to call a voice server implemented by the server 100. The server 100 is then adapted to receive this call, and to identify the user on the basis of this call.

In yet another particular mode, the user uses a smartphone application (" smartphone " in English) to identify the user and access the services of the server 100. The application can obtain geolocation information from the user through a GPS module ( Global Positioning System in English) of the smartphone. The application can transmit this geolocation information to the server 100, which allows the server 100 to identify the checkpoint 101 with which the user has visited, or to list the car parks near the geo-localized location of the user.

In yet another particular mode, the user uses a keypad associated with each control point 101 and enters a code provided to it by the server 100. Such a keypad can be used only to exit the parking lot, including because the network coverage may not allow the user to use the user equipment 130 in the parking enclosure to contact the server 100. The code to be entered is then transmitted by the server 100 to the user equipment 130 before the user has entered the car park. A code reading to bars, possibly two-dimensional ( QR code ) can be implemented in place of the numeric keypad. The bar code is then transmitted by the server 100 to the user equipment 130 before the user has entered the parking.

Claims (11)

System for managing the occupancy of at least one parking space in at least one regulated access parking area by means of a barrier device, the system comprising: detection means (301) of a user requiring an actuation of the barrier device regulating access to a said parking lot; - Verification means (302) that the user has been previously authorized to access said parking lot by the management system; means for transmitting (305) an actuation command of said barrier device, in the event of positive verification by said verification means, so as to allow the user to pass via the access controlled by said device barrage ; - Means for modifying (307) a state of occupancy of a parking space of said parking
characterized in that the means for modifying the state of occupancy are adapted to modify said occupation state in the event of detection (306) of a vehicle passage via the access regulated by said barrier device. Management system according to claim 1, characterized in that the means for detecting the user comprise means for receiving a remote control signal and means for obtaining an identifier associated with the user from the signal remote control received. Management system according to claim 2, characterized in that , said system comprising a remote control intended to be assigned to the user, the remote control is adapted to select an identifier from a set of identifiers stored in said remote control, and in that verification by said verification means is positive when the identifier obtained from the received remote control signal is distinct from an identifier obtained from a previously received remote control signal. Management system according to any one of claims 2 and 3, characterized in that , said system comprising a server (100) and at least one point control unit (101) intended to be located near a said barrier device, each identifier transmitted by a remote control signal comprising a portion transmitted in clear and a portion transmitted in encrypted form, the control point comprises: - Detection means (701) of a cut of a communication link connecting the control point and the server;
and in that the verification (804) that the user has been previously authorized to access the parking lot is implemented by the control point on the basis of the transmitted part in clear of the identifier, when a break in the link communication is detected; and
the verification (502) that the user has been previously authorized to access the parking is implemented by the server at least on the basis of the portion transmitted in encrypted form of the identifier, when no break in the communication link n 'is detected. A management system according to claim 4, characterized in that the control point comprises: means for recording (703,809) in a local log of the changes in the state of occupancy of parking spaces, when a break in the communication link is detected; detection means (704) for reestablishing the communication link; - Transmission means (705) to the local log server, when a restoration of the communication link is detected. Management system according to claim 1, characterized in that the means for detecting the user comprise means for receiving a call from the user on a voice server. Management system according to any one of claims 1 to 6, characterized in that , in the case of a positive verification by said verification means, the management system implements means for obtaining the user's coordinates, and transmission means for the user of a message including an identifier of an assigned parking space. Management system according to any one of claims 1 to 7, characterized in that it comprises: means for receiving, from a terminal associated with a user, a parking request in a given geographical area; means for determining, in the given geographical area, a list of car parks with available parking spaces; means of transmission to said terminal of the determined list; means for receiving, from the terminal, a validation of a parking lot from the list; means for reserving, for said user, a parking space in the validated parking lot. Method for managing the occupancy of at least one parking space in at least one regulated access parking area by means of a barrier device, a management system performing the following steps: detection (301) of a user requiring an actuation of the barrier device regulating access to a said parking lot; - verification (302) that the user has been previously authorized to access said parking lot by the management system; - Transmission (305) of an actuating command of said barrier device, in the case of positive verification, so as to allow the user to pass via the access controlled by said barrier device; - modification (307) of a state of occupation of a parking space of said parking
characterized in that the step of changing the state of occupancy is performed in case of detection (306) of a vehicle passage via the access regulated by said barrier device. Computer program, characterized in that it comprises instructions for implementing, by a parking management system of at least one parking space in at least one regulated access car park by means of a device method, according to claim 9, when said program is executed by at least one processor of said management system. Storage means, characterized in that they store a computer program comprising instructions for implementing, by a system for managing occupancy of at least one parking space in at least one regulated access car park at the means of a barrier device, the method of claim 9, when said program is executed by at least one processor of said management system.

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