CN102637306A - Parking lot management system and management method thereof in different contextual models - Google Patents

Abstract

The invention discloses a parking lot management system and a management method thereof in different contextual models. The parking lot management system comprises a server, a sentry box computer, a ticket box control panel and passage equipment, wherein the ticket box control panel comprises an off-line judgment module, a ticket box control panel transmission module and a ticket box control panel incident processing module; and the sentry box computer comprises a sentry box computer receiving module, an off-line judgment module and a sentry box computer incident processing module. According to the management system and the management method, a parameter set corresponding to a current contextual model is loaded according to a result of judging whether the ticket box control panel is off line and the sentry box computer is off line or not, a passage equipment incident is processed according to the parameter set, and the parameter of the running mode of the parking lot management system can be automatically changed according to changes of the contextual models under a condition that no specialized person is on the spot, so that the parking lot can be correctly and effectively managed when the contextual model changes.

Description

Parking lot management system and management method thereof under different contextual models

Technical Field

The invention relates to a parking lot management system, in particular to a management method for the parking lot management system in different contextual models and a parking lot management system.

Background

In order to ensure that a parking lot management system manages and charges a parking lot according to requirements, a professional is usually required to set parameter sets such as an inlet/outlet channel and a charging rule for the parking lot management system so as to ensure that the system effectively manages the parking lot according to the requirements of customers. In addition, the values of these parameter sets should not be static, and different values need to be applied in different situations. For example, the parking lot passageway is different to the condition of passing and the mode of passing of vehicle under the manned condition and the unmanned condition, if pass card verification and license plate verification simultaneously for the condition of passing, when certain car card verification passed and license plate verification could not pass, under the manned condition, the value of the mode of passing can be for artifical affirmation, forbid the pass and allow the pass etc. and under the unmanned condition, the value of the mode of passing can only be for forbidding the pass and allowing the pass. It can be seen that, as the scene changes, the value of the corresponding parameter set should change.

However, most of the existing parking lot management systems can only use one operation mode, the value of the parameter set is usually preset and cannot be changed at will, if the value of the parameter set is to be changed, the parameter set can be changed only by quite complicated operations of professionals, and if the value of the parameter set is not changed in time, an error which cannot be made up can be caused, and even the system is broken down.

Disclosure of Invention

The invention aims to: the management method for the parking lot management system under different contextual models and the parking lot management system are provided, so that the parking lot management system can flexibly and effectively manage the parking lot according to different contextual models.

In one aspect, the present invention provides a management method for a parking lot management system in different contextual models, where the parking lot management system includes a server, a sentry box computer, a ticket box control board, and a channel device, where the method includes:

the ticket box control board judges whether the ticket box control board is offline or not,

when the ticket box control board is offline, the corresponding parameter set is loaded according to the current scene mode of the ticket box control board, and the channel equipment event is processed according to the loaded parameter set,

when the ticket box control board is not off-line, the channel equipment event is sent to the sentry box computer;

the sentry box computer judges whether the computer is off line,

when the sentry box computer is off-line, loading a parameter set corresponding to the sentry box computer according to the current scene mode of the sentry box computer, and processing the channel equipment event through interaction with the ticket box control panel according to the loaded parameter set,

and when the sentry box computer is not off-line, loading a parameter set corresponding to the sentry box computer according to the current scene mode of the sentry box computer, and processing the channel equipment event through interaction with the server and the ticket box control panel according to the loaded parameter set.

Correspondingly, the invention also provides a parking lot management system, which comprises a server, a sentry box computer, a ticket box control panel and channel equipment, wherein,

the ballot box control panel includes:

the offline judging module is used for judging whether the ticket box control panel is offline or not;

the ticket box control board sending module is used for sending the channel equipment event to the sentry box computer when the ticket box control board is not offline;

the ticket box control board event processing module is used for processing the channel equipment event according to the current contextual model of the ticket box control board when the ticket box control board is offline;

the sentry box computer comprises:

the sentry box computer receiving module is used for receiving the channel equipment event from the ticket box control panel;

the off-line judgment module is used for judging whether the sentry box computer is off-line or not;

and the sentry box computer event processing module is used for processing the channel equipment event according to the judgment result of the off-line judgment module and the current scene mode of the sentry box computer.

The parking lot management system and the management method thereof under different contextual models have the following beneficial effects: the method comprises the steps of setting different contextual models and values of parameter sets of the contextual models for the parking lot management system in advance, judging whether a ticket box control board is offline and whether a sentry box computer is offline, correspondingly processing channel equipment events in different contextual models according to the judgment result, and automatically changing the parameter values of the operating modes of the parking lot management system under the condition that no professional is present so that the parking lot can be managed correctly and effectively under the condition that the contextual models are changed.

Drawings

FIGS. 1 a-1 d are diagrams of four networking modes of the parking lot management system of the present invention;

fig. 2 is a flowchart of a management method of the present invention for a parking lot management system in different contextual models;

FIG. 3 is a flow chart of the kiosk computer processing a channel device event from the ticket box control board through interaction with the ticket box control board according to the loaded set of parameters in step S205;

FIG. 4 is a flow chart of the kiosk computer processing a channel device event from the ticket box control board through interaction with the server and the ticket box control board according to the loaded set of parameters in step S206;

fig. 5 is embodiment 1 of the parking lot management system 1 of the present invention;

fig. 6 is embodiment 2 of the parking lot management system 1 of the present invention.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present invention more apparent, the present invention is further described in detail below with reference to the accompanying drawings.

Fig. 1 a-1 d are diagrams of four networking modes of the parking lot management system of the present invention. As shown in fig. 1a, the parking lot management system includes a server, a sentry box computer, a ticket box control board (an entrance ticket box control board and an exit ticket box control board) and a channel device (a vehicle detector, a gateway, a card reader, a display screen, etc.), which are connected via a network, so as to complete transmission and processing of information and control instructions of channel events. In the networking mode 2 shown in FIG. 1b, the ticket box control board is incorporated into the kiosk computer, and in the networking mode 3 shown in FIG. 1c, the kiosk computer is incorporated into the server. The main function of the server is centralized storage and processing of control logics such as data and pictures, the main function of the sentry box computer is monitoring, controlling and charging of a plurality of channels, and the main function of the ticket box control board is driving of channel equipment, controlling and charging under special conditions and the like. If the communication from the ticket box control board to the sentry box computer fails, the communication is called offline, under the offline condition, the ticket box control board can independently process channel events, and at the moment, managers cannot monitor the channel through the sentry box computer; if the communication from the sentry box computer to the server fails, the sentry box computer is called off-line, under the off-line condition, the sentry box computer independently processes channel events through interaction with the ticket box control panel, and at the moment, managers cannot monitor the channel through the server. It should be further noted that in the four networking modes shown in fig. 1a to 1d, the channels are not limited to four channels including the inlet and the outlet, each networking mode may have multiple channels, each ticket box control board corresponds to one channel, each kiosk computer may control one or more ticket box control boards, and each server may control one or more kiosk computers.

After understanding the networking mode and structure of the parking lot management system of the present invention, the following describes in detail the management method for the parking lot management system in different contextual modes.

Referring first to fig. 2, fig. 2 is a flowchart of a management method for a parking lot management system in different contextual models, the method comprising:

s201, the ticket box control board judges whether the ticket box control board is offline, if so, S202 is executed, and if not, S203 is executed.

S202, the ticket box control board loads the corresponding parameter set according to the current scene mode of the ticket box control board, and processes the channel equipment event according to the loaded parameter set. The event of the channel equipment is an event captured by the ticket box control board through the channel equipment when a vehicle enters or exits.

S203, the ticket box control board sends the channel equipment event to a sentry box computer.

S204, the sentry box computer judges whether the computer is off-line, if so, S205 is executed, and if not, S206 is executed.

S205, the sentry box computer loads the corresponding parameter set according to the current scene mode of the sentry box computer, and processes the channel equipment event from the ticket box control board through interaction with the ticket box control board according to the loaded parameter set.

S206, the sentry box computer loads the corresponding parameter set according to the current scene mode, and processes the channel equipment event from the ticket box control board through interaction with the server and the ticket box control board according to the loaded parameter set.

When the method is implemented, technicians need to store the preset contextual model and the parameter set thereof in the server, and then the server sends the contextual model and the parameter set thereof to the sentry box computer and the ticket box control panel through the network. The server can detect whether the stored scene mode and the parameter set thereof are updated in real time (namely whether the scene mode and the parameter set thereof exist or whether the existing scene mode and the parameter set thereof are changed), and when the situation mode and the parameter set thereof are detected to be updated, the updated scene mode and the parameter set thereof are sent to the sentry box computer and the ticket box control board.

The scene modes comprise a manned mode, an unmanned mode, an offline manned mode, an offline unmanned mode, an offline manned mode and an offline unmanned mode. In the embodiment of the invention, a manager can set an initial contextual model, such as a manned mode or an unmanned mode, for the ticket box control panel in advance through the server. The manned mode is a processing mode of a sentry box computer for realizing a monitoring channel through interaction with a server and a ticket box control panel under the conditions of online, networking and manned; the unmanned mode is a processing mode of realizing a monitoring channel by the interaction of a sentry box computer with a server and a ticket box control panel under the conditions of online, networking and unmanned; the offline and manned mode refers to a processing mode of the ticket box control panel monitoring channel under the offline and manned conditions; the offline unmanned mode refers to a processing mode of a ticket box control panel monitoring channel under the offline and unmanned conditions; the off-line and on-person mode is a processing mode of realizing a monitoring channel by the interaction of a sentry box computer and a ticket box control panel under the conditions of on-line, off-line and on-person; the off-line unmanned mode is a processing mode of realizing a monitoring channel by the interaction of a sentry box computer and a ticket box control panel under the conditions of on-line, off-line and unmanned. Of course, the contextual model of the parking lot management system is not limited to this, and the technician may configure the system according to the actual situation, for example, in the networking mode 4 shown in fig. 1d, since the server is directly connected to the kiosk computer and the ticket box control board, in addition to the above contextual model, the system may also include a server model, that is: under the on-line and off-line conditions, the server takes over the sentry box computer to monitor the channel.

By setting different contextual models and enabling the parking lot management system to change the specific operation of processing the channel equipment event according to the change of the contextual models, the aim of flexibly managing the parking lot can be achieved. In the embodiment of the present invention, the change of the profile is mainly determined by two factors: offline, offline and someone. The presence and absence of people are switched by the manager through login and logout on the sentry box computer and the ticket box control panel, so that whether people are present or not can be judged by checking the login state, and whether the people are offline or not is judged by sending heartbeat packets.

Specifically, in order to determine whether the ticket box control board is offline, the management method for the parking lot management system in different contextual models further includes:

the ticket box control board sends a heartbeat packet to the sentry box computer according to a preset frequency, and the sentry box computer returns a confirmation message to the ticket box control board after receiving the heartbeat packet; or

The sentry box computer sends a heartbeat package to the ticket box control panel according to a preset frequency. Wherein, predetermine the frequency and can be set up by technical staff according to actual conditions, for example can set up to 1 second, and in the system operation period, no matter whether take place the channel equipment incident, all will send the heartbeat package according to predetermineeing the frequency ceaselessly, the sentry box computer in addition in time returns the acknowledgement message to the ballot box control panel after receiving the heartbeat package.

Then, in step S201 shown in fig. 2, the box control board determining whether or not it is offline includes:

the ticket box control board judges whether a confirmation message from the sentry box computer is received within a first preset time period, and if not, the ticket box control board is judged to be offline; or

And the ticket box control board judges whether a heartbeat packet from the sentry box computer is received within a first preset time period, and if not, the ticket box control board is judged to be offline. The first preset time period is a time period which is elapsed since the last time the confirmation message or the heartbeat packet is received from the sentry box computer, and the duration of the time period can be set by a technician according to actual conditions, for example, can be set to 3 seconds.

Correspondingly, in order to judge whether the sentry box computer is off-line or not, the management method for the parking lot management system under different contextual models further comprises the following steps:

the sentry box computer sends a heartbeat packet to the server according to a preset frequency, and the server returns a confirmation message to the sentry box computer after receiving the heartbeat packet; or

And the server sends a heartbeat packet to the sentry box computer according to a preset frequency.

Then, in step S204 shown in fig. 2, the determining, by the kiosk computer, whether the kiosk computer is offline includes:

the sentry box computer judges whether a confirmation message from the server is received within a second preset time period, and when the confirmation message is not received, the sentry box computer is judged to be off-line; or

And the sentry box computer judges whether the heartbeat packet from the server is received within a second preset time period, and when the heartbeat packet is judged not to be received, the sentry box computer is judged to be off-line. The second preset time period is a time period that is elapsed since the last time the acknowledgement message or the heartbeat packet is received from the server, and the duration of the time period may be set by a technician according to an actual situation, for example, may be set to 3 seconds.

Reference is next made to fig. 2. In step S202 shown in fig. 2, after knowing that the ticket box control board has been offline, the loading of the parameter set corresponding to the ticket box control board according to its current scene mode includes: the ticket box control board confirms whether the current scene mode is an offline manned mode or an offline unmanned mode, and loads the parameter set corresponding to the confirmed scene mode.

In step S205, after learning that the kiosk computer has disconnected from the network, the loading, by the kiosk computer according to the current scene mode, the parameter set corresponding to the current scene mode includes: the sentry box computer confirms whether the current scene mode is the offline manned mode or the offline unmanned mode, and loads a parameter set corresponding to the current scene mode according to the confirmed scene mode.

In step S206, after learning that the kiosk computer is not off-line, the loading, by the kiosk computer according to the current scene mode, the parameter set corresponding to the current scene mode includes: the sentry box computer confirms whether the current scene mode is a manned mode or an unmanned mode, and loads a parameter set corresponding to the confirmed scene mode.

The parameter set refers to a data set according to three dimensions of pass types, events and passing directions in each contextual model, and the classification and the value of the parameter set are different according to different contextual models. In general, a scene mode corresponds to a set of parameter sets, but for a large parking lot with multiple channels, multiple sets of parameter sets may be set in a scene mode, each set corresponding to one or more channels, that is, when a channel equipment event occurs, no matter in which scene mode, the device responsible for monitoring the channel may load the set corresponding to the channel to process the channel equipment event. Table 1 is an example of a parameter set.

Table 1 example of parameter sets

The parameter set values in table 1 are not listed one by one, and specifically how to take the values can be set by a technician, and the three dimensions and parameters thereof referred to in table 1 can also be set by the technician. For example, the classification of the parameter set may include a release mode, voice, display, and charging rules, and the like, where the value of the release mode may include confirmation release, no pass, pass release, license plate release, and pass + license plate release. This is not exemplified here.

What has been described above in conjunction with fig. 2 is how to determine whether to go offline, offline and how to load the parameter set corresponding thereto according to the current scene mode, and the specific process of processing the channel device event according to the loaded parameter set in steps S202, S205 and S206 shown in fig. 2 is described in detail next. In step S202, the ticket box control board processes the channel device event according to the loaded parameter set, that is, controls the channel device event according to the value of the loaded parameter set, and determines whether to release and how to charge, and the like, which is not described herein again. And for steps S205 and S206, how to process the channel device event according to the loaded parameter set will be described in detail below in conjunction with fig. 3 and 4, respectively.

First, fig. 3 is a flow chart of the kiosk computer processing a channel device event from the ticket box control board through interaction with the ticket box control board according to the loaded parameter set in step S205, as shown in fig. 3, the flow chart includes the following steps:

s301, the sentry box computer generates a control instruction for the channel equipment event according to the loaded parameter set and sends the control instruction to the ticket box control board.

S302, the ticket box control board judges whether timing is started when the ticket box control board sends the channel equipment event to the sentry box computer, whether the control instruction is received in a third preset time period or not, if yes, S303 is executed, and if not, S304 is executed. Wherein, the step of sending the channel device event to the sentry box computer is S203 in fig. 2. The third preset time period may be set by a technician according to actual conditions.

And S303, the ticket box control board processes the channel equipment event according to the control instruction.

S304, the ticket box control board confirms whether the current scene mode is an offline manned mode or an offline unmanned mode, loads the corresponding parameter set according to the confirmed scene mode, and processes the channel equipment event according to the loaded parameter set. When the step S302 determines that the ticket box control board does not receive the control instruction, it indicates that the communication from the ticket box control board to the sentry box computer is failed, i.e. offline, and then the ticket box control board processes the channel device event by itself, and the processing procedure is the same as that of the step S202 in fig. 2.

Through the process shown in fig. 3, system failure due to sudden offline in the case of online offline can be avoided.

Fig. 4 is a flow chart of the kiosk computer processing a channel equipment event from the ticket box control board through interaction with the server and the ticket box control board according to the loaded parameter set in step S206, as shown in fig. 4, the flow chart comprising the steps of:

s401, the sentry box computer sends a control logic query instruction to the server, and judges whether to start timing when the query instruction is sent, whether to receive the control logic from the server in a fourth preset time period or not, if so, S402 is executed, otherwise, S406 is executed. Wherein, the fourth preset time period can be set by a technician according to the actual situation. The control logic refers to a whole set of information required for controlling the channel device event, and the information includes information such as whether the parking card is cancelled, whether recharge delay information is not written into the parking card, whether the current day has charged fees and pictures of vehicles entering the field.

S402, the sentry box computer generates a control instruction for the channel equipment event according to the control logic and the loaded parameter set, and sends the control instruction to the ticket box control board.

And S403, the ticket box control board judges whether timing is started when the ticket box control board sends the channel equipment event to the sentry box computer, whether the control instruction is received within a third preset time period or not, if so, S404 is executed, and if not, S405 is executed. Wherein, the step of sending the channel device event to the sentry box computer is S203 in fig. 2.

S404, the ticket box control board processes the channel equipment event according to the control instruction. The flow ends.

S405, the ticket box control board confirms whether the current scene mode is an offline manned mode or an offline unmanned mode, loads the corresponding parameter set according to the confirmed scene mode, and processes the channel equipment event according to the loaded parameter set. The flow ends.

S406, the sentry box computer confirms whether the current scene mode is the offline manned mode or the offline unmanned mode, and loads the corresponding parameter set according to the confirmed scene mode.

And S407, the sentry box computer generates a control instruction for the channel equipment event according to the loaded parameter set, sends the control instruction to the ticket box control board, and then skips to execute S403.

Through the process described in fig. 4, system failures due to sudden offline and/or offline in the case of online networking can be avoided.

The above is a detailed description of the process of the present invention. It should be noted that, in the embodiment of the present invention, after the ticket box control board and the sentry box computer process the channel device event, the processed result may be temporarily stored in their respective storage devices, so that the processed result may be uploaded to the server for storage when the communication is clear.

The parking lot management system of the present invention will be described in detail below.

Fig. 5 is embodiment 1 of the parking lot management system 1 of the present invention. In embodiment 1, the parking lot management system 1 includes a server 10, a kiosk computer 11, a ticket box control board 12, and a passage device 13. Wherein,

the sentry box computer 11 includes:

the kiosk computer receiving module 110 is used to receive channel equipment events from the ticket box control panel 12.

And the off-line judgment module 111 is used for judging whether the sentry box computer 11 is off-line.

And the sentry box computer event processing module 112 is configured to process the channel device event according to the judgment result of the off-line judgment module 111 and the current contextual model of the sentry box computer 11.

The ticket box control panel 12 includes:

and an offline judging module 120, which is used for judging whether the ticket box control panel 12 is offline.

And the ticket box control board sending module 121 is used for sending the channel equipment event to the sentry box computer 11 when the ticket box control board 10 is not offline.

The ticket box control board event processing module 122 is configured to process the channel device event according to the current contextual model of the ticket box control board 10 when the ticket box control board 10 is offline.

The above-mentioned contextual models include manned mode, unmanned mode, offline manned mode, offline unmanned mode, offline manned mode and offline unmanned mode, and the detailed contents of various contextual models are the same as the corresponding descriptions of the method of the present invention, and therefore, the detailed descriptions thereof are omitted here. The technician needs to set the profile through the server 10 in advance, and therefore, the server 10 includes:

a contextual model setting module, configured to store the contextual model and the parameter set thereof in the server 10 in advance;

a contextual model sending module for sending the contextual model and the parameter set thereof to the sentry box computer 11 and the ticket box control board 12, the module specifically comprises a detecting unit and a sending unit, wherein,

a detecting unit, configured to detect whether the scene mode and the parameter set thereof in the scene mode setting module are updated (i.e., whether the scene mode and the parameter set thereof exist or whether the existing scene mode and the parameter set thereof are changed);

and the sending unit is used for sending the updated scene mode and the parameter set thereof to the sentry box computer 11 and the ticket box control board 12 when the detection unit detects that the updating exists.

The sentry box computer 11 and the ticket box control board 12 further respectively include a sentry box computer contextual model receiving module and a ticket box control board contextual model receiving module, which are respectively connected to the sentry box computer event processing module 112 and the ticket box control board event processing module 122, and are configured to receive the contextual model and the parameter set thereof from the server 10.

With continued reference to fig. 5, in fig. 5, the kiosk computer 11 and the ticket box control board 12 respectively include an offline determination module 111 and an offline determination module 120 for determining whether the kiosk computer 11 is offline and whether the ticket box control board 12 is offline. In the embodiment of the invention, whether the communication from the sentry box computer 11 to the server 10 is smooth or not and whether the communication from the ticket box control board 12 to the sentry box computer 11 is smooth or not can be judged by adopting a heartbeat packet mode, so that whether the sentry box computer 11 is off-line or not and whether the ticket box control board 12 is off-line or not are judged.

Specifically, to determine whether the ticket box control panel 12 is offline, the following two implementation manners are included:

(1) the ticket box control panel 12 further comprises a heartbeat packet sending module of the ticket box control panel, and is used for sending heartbeat packets to the sentry box computer 11 according to a preset frequency. The preset frequency may be set by a technician according to an actual situation, for example, may be set to 1 second, and during the operation of the system, no matter whether a channel device event occurs, the heartbeat packet is sent according to the preset frequency continuously.

The sentry box computer 11 receives the heartbeat packet and returns a confirmation message to the ticket box control board 12.

The ticket box control panel 12 further comprises a heartbeat packet receiving module of the ticket box control panel, which is used for receiving a confirmation message from the sentry box computer 11 for receiving the heartbeat packet.

The offline judging module 120 includes a first judging unit, configured to judge whether the heartbeat packet receiving module of the ticket box control board receives a confirmation message from the sentry box computer 11 within a first preset time period. And when the judgment result is no, judging that the ticket box control panel is offline. The first preset time period is a time period which is elapsed since the last time the confirmation message from the sentry box computer is received, and the duration of the time period can be set by a technician according to actual conditions, for example, can be set to 3 seconds.

(2) The sentry box computer 11 sends heartbeat packets to the ticket box control board 12 according to a preset frequency.

The heartbeat packet receiving module of the ticket box control board is also used for receiving heartbeat packets from the sentry box computer 11.

The offline judging module 120 includes a second judging unit, which is used to judge whether the heartbeat packet receiving module of the ticket box control board receives the heartbeat packet from the sentry box computer 11 within a first preset time period. If not, the control panel 12 is off-line. The first preset time period is a time period which is elapsed since the heartbeat packet from the sentry box computer was last received.

In order to judge whether the sentry box computer is off-line, the method comprises the following two implementation modes:

(1) the sentry box computer 11 further comprises a sentry box computer heartbeat packet sending module, which is used for sending heartbeat packets to the server 10 according to a preset frequency.

The server 10 receives the heartbeat packet and returns a confirmation message to the kiosk computer 11.

The kiosk computer 11 further comprises a kiosk computer heartbeat packet receiving module for receiving a confirmation message from the server 10 of receipt of the heartbeat packet.

The offline judging module 111 includes a third judging unit, configured to judge whether the sentry box computer heartbeat packet receiving module receives the confirmation message from the server 10 within a second preset time period. If not, the sentry box computer 11 is determined to be off-line. The second preset time period is a time period that elapses since the last time the acknowledgement message from the server 10 was received.

(2) The server 10 sends heartbeat packets to the kiosk computer 11 at a preset frequency.

The sentry box computer heartbeat packet receiving module is further configured to receive a heartbeat packet from the server 10.

The offline judgment module 111 includes a fourth judgment unit, configured to judge whether the sentry box computer heartbeat packet receiving module receives a heartbeat packet from the server 10 within a second preset time period. If not, the sentry box computer 11 is determined to be off-line. The second preset time period is a time period which is elapsed since the heartbeat packet from the server was last received.

Reference is now made to fig. 6. Fig. 6 is an embodiment 2 of the parking lot management system 1 of the present invention, and in the embodiment 2, the ticket box control board event processing module 122 and the sentry box computer event processing module 112 will be described in detail. Wherein,

the ticket box control panel event processing module 122 includes:

the ticket box control panel scene mode confirming unit 1220 is configured to confirm whether the current scene mode of the ticket box control panel 12 is the offline manned mode or the offline unmanned mode. When the offline determination module 120 determines that the ticket box control board is offline, it is processed by the ticket box control board scene mode confirmation unit 1220.

A box control board loading unit 1221, configured to load the parameter set corresponding to the scene mode confirmed by the box control board scene mode confirmation unit 1220 according to the scene mode. Here, the scene mode corresponding to the parameter set is an offline manned mode or an offline unmanned mode.

A cassette control board self-processing unit 1222 for processing channel device events according to the parameter sets loaded by the cassette control board loading unit 1221.

The kiosk computer event processing module 112 includes:

a sentry box computer contextual model confirming unit 1120, configured to confirm whether a current contextual model of the sentry box computer 11 is an offline manned mode or an offline unmanned mode; or for confirming whether the current profile of the kiosk computer 11 is manned or unmanned. When the ticket box control board is not offline and the offline judgment module 111 judges that the kiosk computer is offline, or when the ticket box control board is not offline and the kiosk computer is not offline and the inquiry instruction processing unit 1123 judges no, the processing is performed by the kiosk computer scene mode confirmation unit 1120.

The kiosk computer loading unit 1121 is configured to load the parameter set corresponding to the profile confirmed by the kiosk computer profile confirming unit 1120.

The control instruction generating unit 1122 is configured to generate a control instruction for the channel device event according to the parameter set loaded by the kiosk computer loading unit 1121, and send the control instruction to the ticket box control board. Here, the scene mode corresponding to the parameter set is a talk-around mode or a talk-around no-man mode.

And the query instruction processing unit 1123 is configured to send a control logic query instruction to the server 10, and determine whether the control logic from the server 10 is received within a fourth preset time period after the time when the query instruction is sent is started.

And the first control logic processing unit 1124 is configured to, upon receiving the control logic, generate a control instruction for a channel device event according to the control logic and the loaded parameter set, and send the control instruction to the ticket box control board 12. Here, the scene mode corresponding to the parameter set is a manned mode or an unmanned mode.

The second control logic processing unit 1125 is configured to generate a control instruction for the channel device event according to the parameter set loaded by the kiosk computer loading unit 1121 when the control logic is not received, and send the control instruction to the ticket box control board 12. Here, the scene mode corresponding to the parameter set is a talk-around mode or a talk-around no-man mode.

The ticket box control panel event processing module 122 further comprises:

a control instruction receiving and judging unit 1223, configured to implement the following functions:

judging whether a control instruction from the control instruction generating unit 1122 is received within a third preset time period after timing is started when the ticket box control board sending module 121 sends the channel equipment event to the sentry box computer 11; or

And judging whether a control instruction from the first control logic processing unit 1124 or the second control logic processing unit 1125 is received within a third preset time period when the ticket box control board sending module 121 sends the channel equipment event to the sentry box computer 11 to start timing.

The first control instruction processing unit 1224 is configured to, when receiving the control instruction, process a channel device event according to the control instruction.

And a second control instruction processing unit 1225, configured to, when the control instruction is not received, process the channel device event according to the parameter set loaded by the ticket box control board loading unit 1221. Here, the scene mode corresponding to the parameter set is an offline manned mode or an offline unmanned mode.

In addition, the server 10 further includes a server event processing module 100, configured to send the control logic to the kiosk computer 11 according to the control logic query instruction sent by the query instruction processing unit 1123.

In summary, the invention sets different contextual models and values of parameter sets thereof for the parking lot management system in advance, then processes the channel equipment events in different modes according to the judgment result by judging whether the ticket box control board is offline and whether the sentry box computer is offline, can flexibly process the channel equipment events under the condition of changing the contextual models, does not need professionals to perform complicated operations, avoids errors caused by communication faults of the parking lot management system or absence of the managers, and enables the parking lot management system to be used more simply and conveniently.

Through the description of the above embodiments, it is clear to those skilled in the art that the present invention can be implemented by combining software and a hardware platform, and of course, the present invention can also be implemented by hardware entirely. With this understanding in mind, all or part of the technical solutions of the present invention that contribute to the background can be embodied in the form of a software product, which can be stored in a storage medium, such as a ROM/RAM, a magnetic disk, an optical disk, etc., and includes instructions for causing a computer device (which can be a personal computer, a server, or a network device, etc.) to execute the methods according to the embodiments or some parts of the embodiments of the present invention.

The above disclosure is only for the purpose of illustrating the embodiments of the present invention and is not intended to limit the scope of the present invention, and those skilled in the art can make various modifications, changes, or substitutions without departing from the spirit of the present invention.

Claims (24)

1. A management method for a parking lot management system under different contextual models, wherein the parking lot management system comprises a server, a sentry box computer, a ticket box control board and channel equipment, and the method comprises the following steps:

the ticket box control board judges whether the ticket box control board is offline or not,

when the ticket box control board is offline, the corresponding parameter set is loaded according to the current scene mode of the ticket box control board, and the channel equipment event is processed according to the loaded parameter set,

when the ticket box control board is not off-line, the channel equipment event is sent to the sentry box computer;

the sentry box computer judges whether the computer is off line,

when the sentry box computer is off-line, loading a parameter set corresponding to the sentry box computer according to the current scene mode of the sentry box computer, processing a channel equipment event from the ticket box control board through interaction with the ticket box control board according to the loaded parameter set,

and when the sentry box computer is not off-line, loading a parameter set corresponding to the sentry box computer according to the current scene mode of the sentry box computer, and processing a channel equipment event from the ticket box control board through interaction with the server and the ticket box control board according to the loaded parameter set.

2. The method of claim 1, wherein before the hopper control board determines whether it is offline, the method further comprises:

storing preset scene modes and parameter sets thereof in the server, wherein the scene modes comprise a manned mode, an unmanned mode, an offline manned mode, an offline unmanned mode, an offline manned mode and an offline unmanned mode;

and the server sends the contextual model and the parameter set thereof to the sentry box computer and the ticket box control board.

3. The method of claim 2, wherein the step of the server sending the profile and its set of parameters to the kiosk computer and the ticket box control board comprises:

and the server detects whether the scene mode and the parameter set thereof are updated or not, and sends the updated scene mode and the parameter set thereof to the sentry box computer and the ticket box control board when the scene mode and the parameter set thereof are detected to be updated.

4. The method of claim 1, further comprising:

the ticket box control board sends a heartbeat packet to the sentry box computer according to a preset frequency, and the sentry box computer returns a confirmation message to the ticket box control board after receiving the heartbeat packet; or

And the sentry box computer sends a heartbeat packet to the ticket box control board according to a preset frequency.

5. The method of claim 4, wherein the hopper control board determining whether it is offline comprises:

the ticket box control board judges whether a confirmation message from the sentry box computer is received within a first preset time period, and if not, the ticket box control board judges that the ticket box control board is offline; or

The ticket box control board judges whether a heartbeat packet from the sentry box computer is received within a first preset time period, and if not, the ticket box control board judges that the computer is offline.

6. The method of claim 1, further comprising:

the sentry box computer sends a heartbeat packet to the server according to a preset frequency, and the server returns a confirmation message to the sentry box computer after receiving the heartbeat packet; or

And the server sends a heartbeat packet to the sentry box computer according to a preset frequency.

7. The method of claim 6, wherein the kiosk computer determining whether it is off-line comprises:

the sentry box computer judges whether a confirmation message from the server is received within a second preset time period, and if not, the off-line is judged; or

And the sentry box computer judges whether a heartbeat packet from the server is received in a second preset time period, and judges that the sentry box computer is offline if the heartbeat packet is not received in the second preset time period.

8. The method of claim 2, wherein loading the parameter set corresponding to the ticket box control board according to its current contextual model when the ticket box control board is offline comprises:

the ticket box control board confirms whether the current scene mode is an offline manned mode or an offline unmanned mode, and loads a parameter set corresponding to the confirmed scene mode.

9. The method of claim 2, wherein loading the set of parameters corresponding to the kiosk computer according to its current contextual model when the kiosk computer is off-line comprises:

and the sentry box computer confirms whether the current contextual model is the offline manned mode or the offline unmanned mode, and loads a parameter set corresponding to the current contextual model according to the confirmed contextual model.

10. The method of claim 2, wherein loading the set of parameters corresponding to the kiosk computer according to its current contextual model when the kiosk computer is not off-line comprises:

and the sentry box computer confirms whether the current contextual model is the manned mode or the unmanned mode, and loads the parameter set corresponding to the current contextual model according to the confirmed contextual model.

11. The method of claim 2, wherein the kiosk computer processing the channel equipment event from the ticket box control board via interaction with the ticket box control board according to the loaded set of parameters comprises:

the sentry box computer generates a control instruction for the channel equipment event according to the loaded parameter set and sends the control instruction to the ticket box control board;

the ticket box control board judges whether the control instruction is received within a third preset time period or not when the ticket box control board starts timing when the ticket box control board sends the channel equipment event to the sentry box computer,

when the judgment result is yes, the ticket box control board processes the channel equipment event according to the control instruction,

and when the judgment result is no, the ticket box control board confirms whether the current contextual model is an offline manned mode or an offline unmanned mode, loads a parameter set corresponding to the current contextual model according to the confirmed contextual model, and processes the channel equipment event according to the loaded parameter set.

12. The method of claim 2, wherein the kiosk computer processing the channel equipment event from the ticket box control board through interaction with the server and the ticket box control board according to the loaded set of parameters comprises:

a. the sentry box computer sends a control logic query instruction to the server, judges whether timing is started when the sentry box computer sends the query instruction, whether the sentry box computer receives the control logic from the server in a fourth preset time period or not, executes the step b when the sentry box computer judges that the control logic is received, and otherwise, turns to the step f;

b. the sentry box computer generates a control instruction for the channel equipment event according to the control logic and the loaded parameter set and sends the control instruction to the ticket box control board;

c. the ticket box control board judges whether timing is started when the ticket box control board sends the channel equipment event to the sentry box computer, whether the control instruction is received within a third preset time period or not is judged, if yes, the step d is executed, and if not, the step e is executed;

d. the ticket box control board processes the channel equipment event according to the control instruction, and the method is ended;

e. the ticket box control board confirms whether the current scene mode is an offline manned mode or an offline unmanned mode, loads a parameter set corresponding to the confirmed scene mode according to the confirmed scene mode, processes the channel equipment event according to the loaded parameter set, and the method is ended;

f. the sentry box computer confirms whether the current contextual model is the offline manned mode or the offline unmanned mode, and loads a parameter set corresponding to the current contextual model according to the confirmed contextual model;

g. and c, the sentry box computer generates a control instruction for the channel equipment event according to the loaded parameter set, sends the control instruction to the ticket box control board and then goes to the step c.

13. A parking lot management system comprises a server, a sentry box computer, a ticket box control panel and a channel device, and is characterized in that,

the ballot box control panel includes:

the offline judging module is used for judging whether the ticket box control panel is offline or not;

the ticket box control board sending module is used for sending the channel equipment event to the sentry box computer when the ticket box control board is not offline;

the ticket box control board event processing module is used for processing the channel equipment event according to the current contextual model of the ticket box control board when the ticket box control board is offline;

the sentry box computer comprises:

the sentry box computer receiving module is used for receiving the channel equipment event from the ticket box control panel;

the off-line judgment module is used for judging whether the sentry box computer is off-line or not;

and the sentry box computer event processing module is used for processing the channel equipment event according to the judgment result of the off-line judgment module and the current scene mode of the sentry box computer.

14. The system of claim 13, wherein the server comprises:

the contextual model setting module is used for storing contextual models and parameter sets thereof in the server in advance, wherein the contextual models comprise a manned mode, an unmanned mode, an offline manned mode, an offline unmanned mode, an offline manned mode and an offline unmanned mode;

and the contextual model sending module is used for sending the contextual model and the parameter set thereof to the sentry box computer and the ticket box control board.

15. The system of claim 14, wherein the contextual model sending module comprises:

the detection unit is used for detecting whether the scene mode and the parameter set thereof in the scene mode setting module are updated or not;

and the sending unit is used for sending the updated scene mode and the parameter set thereof to the sentry box computer and the ticket box control board when the detection unit detects that the updating exists.

16. The system of claim 14,

the sentry box computer further comprises a sentry box computer contextual model receiving module used for receiving the contextual model and the parameter set thereof from the server;

the ticket box control board further comprises a ticket box control board scene mode receiving module used for receiving the scene mode and the parameter set thereof from the server.

17. The system of claim 13, wherein the ticket box control panel further comprises:

the ticket box control board heartbeat package sending module is used for sending heartbeat packages to the sentry box computer according to a preset frequency;

the heartbeat packet receiving module of the ticket box control panel is used for realizing the following functions:

receiving a confirmation message from the sentry box computer of receiving the heartbeat packet; or

And receiving a heartbeat packet sent to the ticket box control board from the sentry box computer.

18. The system of claim 17, wherein the offline determination module comprises:

the first judgment unit is used for judging whether the heartbeat packet receiving module of the ticket box control board receives a confirmation message from the sentry box computer within a first preset time period; or

And the second judgment unit is used for judging whether the heartbeat packet receiving module of the ticket box control board receives the heartbeat packet from the sentry box computer in a first preset time period.

19. The system of claim 13, wherein the kiosk computer further comprises:

the sentry box computer heartbeat packet sending module is used for sending heartbeat packets to the server according to a preset frequency;

sentry box computer heartbeat package receiving module for realizing the following functions:

receiving an acknowledgement message from the server to the receipt of the heartbeat packet; or

And receiving a heartbeat packet sent to the sentry box computer from the server.

20. The system of claim 19, wherein the offline determination module comprises:

the third judging unit is used for judging whether the sentry box computer heartbeat packet receiving module receives the confirmation message from the server in a second preset time period; or

And the fourth judgment unit is used for judging whether the sentry box computer heartbeat packet receiving module receives the heartbeat packet from the server in a second preset time period.

21. The system of claim 14, wherein the ticket box control board event processing module comprises:

the ticket box control panel contextual model confirming unit is used for confirming whether the current contextual model of the ticket box control panel is an offline manned mode or an offline unmanned mode;

the ticket box control board loading unit is used for loading the parameter set corresponding to the scene mode confirmed by the ticket box control board scene mode confirming unit;

and the ticket box control board self-processing unit is used for processing the channel equipment event according to the parameter set loaded by the ticket box control board loading unit.

22. The system of claim 21, wherein the kiosk computer event processing module comprises:

the system comprises a sentry box computer contextual model confirming unit, a sentry box computer contextual model determining unit and a sentry box computer contextual model determining unit, wherein the sentry box computer contextual model confirming unit is used for confirming whether a current contextual model of the sentry box computer is an offline manned mode or an offline unmanned mode; or the current scene mode of the sentry box computer is determined to be a manned mode or an unmanned mode;

the sentry box computer loading unit is used for loading the parameter set corresponding to the situation mode confirmed by the sentry box computer situation mode confirming unit;

the control instruction generating unit is used for generating a control instruction for the channel equipment event according to the parameter set loaded by the sentry box computer loading unit and sending the control instruction to the ticket box control board;

the query instruction processing unit is used for sending a control logic query instruction to the server, judging whether timing is started when the query instruction is sent, and whether the control logic from the server is received in a fourth preset time period;

the first control logic processing unit is used for generating a control instruction for the channel equipment event according to the control logic and the loaded parameter set when receiving the control logic, and sending the control instruction to the ticket box control board;

and the second control logic processing unit is used for generating a control instruction for the channel equipment event according to the parameter set loaded by the sentry box computer loading unit when the control logic is not received, and sending the control instruction to the ticket box control board.

23. The system of claim 22, wherein the server further comprises:

and the server event processing module is used for sending the control logic to the sentry box computer according to the control logic query instruction.

24. The system of claim 22, wherein the ticket box control board event processing module further comprises:

the control instruction receiving and judging unit is used for realizing the following functions:

judging whether a control instruction from the control instruction generating unit is received within a third preset time period or not when the ticket box control board sending module sends the channel equipment event to the sentry box computer; or

Judging whether a control instruction from the first control logic processing unit or the second control logic processing unit is received within a third preset time period or not when the ticket box control board sending module sends a channel equipment event to a sentry box computer;

the first control instruction processing unit is used for processing the channel equipment event according to the control instruction when the control instruction is received;

and the second control instruction processing unit is used for processing the channel equipment event according to the parameter set loaded by the ticket box control board loading unit when the control instruction is not received.

Images