CN116929389A - Multi-user travel method, system and device based on same terminal - Google Patents

Abstract

The invention provides a multi-user travel method based on the same terminal, which comprises a terminal position determining step, wherein a first user terminal requests a server to acquire map data of a map database of the server, and determines terminal position data from the map data. And the same end position sending step, wherein the user inquires and determines a second user terminal of the end position data through the server, and the server sends the end position data to the second user terminal. And the same end position uses the car service step, the second user terminal receives and analyzes the end position data, the receiving side terminal initiates the corresponding service request to the server according to the end position data. The invention further provides a multi-user travel system and device based on the same terminal point based on the travel method, and the multi-user travel system and the device for operating the system or the method can realize travel demands of a plurality of users based on the same terminal point in one platform and solve the problem of inconvenient travel of the users in the conventional travel.

Description

Multi-user travel method, system and device based on same terminal

Technical Field

The invention relates to the technical field of travel, in particular to a multi-user travel method, system and device based on the same terminal point.

Background

Navigation is a technique of pointing to a critical path of a destination. In the implementation of the prior art, if multiple people need to navigate to the same destination, usually, after one person inputs the destination on the map client to search the route, the sharing instruction (such as a sharing key) is used to invoke the instant messaging software and send the instant messaging software to other people, and the other people clicks the sharing information received in the instant messaging software used by the other people to navigate, but the real-time performance of the navigation route sharing mode based on the sharing instruction is lower.

In a daily multi-person travel scenario, the user has the need to reach the same destination as others. Currently, travel software typically does not provide the ability to share and synchronize selected endpoint information to others. When the user wants to reach the same destination with other people, the user needs to input the destination address again through the third-party map software, then the sharing capability of the third-party map software transmits the destination address information to other people, and the user and the other people input the destination information to the travel software of the first user terminals respectively again, so that the efficiency is low, the accuracy of the destination address cannot be guaranteed, and the travel experience of multiple people is influenced.

Disclosure of Invention

In view of the above drawbacks of the prior art, the present invention is directed to providing a multi-user travel method, system and device based on the same terminal, which are used for solving the problem that terminal data can be shared among multiple users only by means of a third party map software/platform and a third party communication software/platform in the prior art. Meanwhile, data encryption is carried out on the end position selected by the user, so that the safety and privacy of the user data can be ensured.

To achieve the above and other related objects, the present invention provides a multi-user travel method based on the same endpoint, including:

the same end position determining step, wherein a first user requests a server through a first user terminal to acquire map data of a map database of the server, and determines end position data from the map data;

the same end position sending step, wherein the first user inquires and selects a second user through the server, and sends the end position data to the second user through the server;

and in the same terminal position vehicle service step, the first user terminal and at least one second user terminal receive and analyze the terminal position data, and initiate corresponding vehicle service requests to the server according to the terminal position data.

In one embodiment of the present invention, the end position data includes information of a position unique identifier, latitude and longitude, city code, city name, region code, region and location.

In an embodiment of the present invention, the end position data in the end position determining step includes information of a position unique identifier, latitude and longitude, city code, city name, region code, region and location.

In an embodiment of the present invention, the first user terminal or at least one of the second user terminals may optionally display or not display real-time location information and arrival time information of other identical end users.

In an embodiment of the present invention, the first user terminal and at least one of the second users initiate a request for changing destination to the server, and after all the common travel users confirm, the first user terminal and at least one of the second users switch to a new destination location.

In an embodiment of the present invention, the destination location data includes a self-built location unique identifier, and the server generates the destination location data including the location unique identifier according to the destination location corresponding selected and determined by the first user terminal.

In an embodiment of the present invention, a user database is provided in the server for the first user terminal to query and designate the second user terminal, each piece of user data in the user database includes a unique identifier of a receiver, and the server sends the user data corresponding to the designated second user terminal to the first user terminal; the first user terminal directly transmits the end position data and/or distributes the end position data to the second user terminal in a mode of generating a link and transmitting link information.

In an embodiment of the present invention, the link is generated by encryption, the first user terminal generates the link including a unique encrypted string by asymmetric encryption of the destination location data and the user data including the unique recipient identifier of the second user terminal, the second user terminal sends the received link and the unique recipient identifier of the second user terminal to the server, and the server parses and compares and determines whether the unique recipient identifier included in the link is the same as the unique recipient identifier of the second user terminal specified in the user database, and if so, sends the location data included in the link to the second user terminal.

In an embodiment of the present invention, the second user terminal obtains the destination location data, analyzes and analyzes the destination location, and sends a travel request to a vehicle service system module of the server to call the destination location data as destination location data of a receiving party for traveling, where in the destination location determining step, the destination location data includes location, longitude and latitude, city code, city name, region code, region and positioning information.

The invention also provides a multi-user travel system based on the same terminal, which comprises:

the server comprises a database module provided with a user database and a map database, a receiving module for receiving and processing map data and user data and a transmitting module for transmitting terminal position data, wherein each user data in the user database comprises a unique identification code of a receiver;

the first user terminal acquires the user data and the map data stored in the user database and the map database from the database module, determines end position data from the map data, designates a second user terminal in the user database, and sends the determined end position data and a data packet of the user data of the designated second user terminal to the server for data processing;

And the second user terminal is used for analyzing after at least one second user terminal obtains the terminal position data from the sending module and sending a travel request to the server so as to call the terminal position data.

In an embodiment of the present invention, the first user terminal includes an acquisition module, an interaction module, a selection module and a sharing module that are sequentially in communication connection, where the acquisition module is in communication connection with the database module of the server to acquire and parse the map data and the user data, so that the first user terminal performs corresponding selection through the interaction module; the selection module acquires a selection instruction sent by the interaction module and generates the data packet containing the appointed terminal position data and the user data of the second user terminal, and the sharing module sends the data packet to the receiving module of the server so that the server performs data processing.

In an embodiment of the present invention, the second user terminal includes an receiving module, an interaction module and an initiating demand module that are sequentially connected in communication, where the receiving module is connected with the sending module of the server in communication, so as to obtain and parse the end position data, and the interaction module selects the end position data as end position data of a travel end point of the receiving party, and sends a corresponding initiating demand instruction to the initiating demand module; and after the receiving module of the server acquires and analyzes the data packet from the receiving module of the first user terminal, the receiving module sends the end position data to the receiving module.

In an embodiment of the present invention, the first user terminal includes an acquiring module, an interaction module, a selecting module, a generating module and a sharing module that are sequentially in communication connection, where the acquiring module is in communication connection with the database module of the server, acquires and analyzes the map data and the user data, so that a user can make a corresponding selection through the interaction module, the selecting module acquires a selection instruction sent by the interaction module, generates the data packet including the designated end position data and the user data of the second user terminal, the generating module receives the end position data, generates a link including the end position data, and sends the link to the sharing module, and the sharing module sends the link to the first user terminal through a third party public domain.

In an embodiment of the present invention, in the data packet generated by the selecting module, the destination location data includes a location unique identifier, the user data includes a receiver unique identifier specifying the second user terminal, and the generating module compiles the data packet including the specified unique identifier into the link including a unique encrypted string.

In an embodiment of the present invention, the second user terminal includes an import module, an interaction module, and an initiation demand module that are sequentially in communication connection, where the import module obtains the link from the third party public domain and parses the link, the import module sends the end position data obtained by parsing to the interaction module, and the interaction module selects the end position data as end position data of a travel of a receiving party and sends a corresponding initiation demand instruction to the initiation demand module.

In an embodiment of the present invention, the second user terminal includes an import module, a reading module, an interaction module, an initiating request module, and an occurrence module and a receiving module that are sequentially communicatively connected, where the sharing module of the first user terminal sends the link including the unique encrypted string generated by the generation module to the third party public domain, the import module obtains the link including the unique encrypted string from the third party public domain and parses the link, the reading module obtains the unique encrypted string parsed by the import module, sends the unique encrypted string to the server through the sending module to perform identity verification, and the server completes the identity verification and feeds the parsed end position data back to the receiving module, and the receiving module sends the end position data to the reading module to read the end position data, and the interaction module obtains and selects the end position data from the reading module as the end position data of the travel and sends the corresponding instruction to the initiating request module.

In an embodiment of the present invention, the server further includes an parsing module, a verification module, and a sending module, where the receiving module receives the data packet including the unique encrypted string and the unique receiver identifier of the second user terminal from the sending module of the first user terminal, and sends the data packet to the parsing module for parsing and comparing, where the parsing module parses the unique receiver identifier in the data packet, and verifies the unique receiver identifier of the second user terminal specified by the verification module corresponding to the second user terminal in the user database, and when the unique receiver identifier in the data packet is the same as the unique receiver identifier of the second user terminal specified by the second user terminal in the user database, the sending module sends the destination location data to the receiving module.

In an embodiment of the present invention, the server is further provided with a vehicle service system module, the vehicle service system module is used for running a useful vehicle service system, and the request initiating module of the first user terminal is communicatively connected with the vehicle service system module, and sends the request instruction including the end position data to the vehicle service system for execution.

The invention also provides a multi-user travel device based on the same terminal, which comprises: a processor and a storage device. The storage device is used for storing a program, and when the program is executed by the processor, the travel device is enabled to achieve the multi-user travel method based on the same terminal point.

As described above, the multi-user travel method, system and device based on the same terminal point have the following beneficial effects:

according to the multi-user travel method, system and device based on the same terminal, a user selects terminal data in a client program of a first user terminal of the hardware, and then selects user information of a receiver from a built-in or associated user database through unique user identification codes such as a mobile phone number and a user ID or non-unique user identification codes such as a user nickname. Then, the user sends an instruction of transmitting the terminal data to the receiver user to the client program, and the client program transmits the terminal data to the client program of the hardware terminal of the second user terminal through the hardware device, can directly transmit through the hardware device or can transmit through an intermediate server, and finally realizes that multiple users initiate vehicle service requirements in the client program of the terminal based on the terminal data. The user transmits the terminal data without using a third party map software and a third party communication software, so that the operation efficiency of the user is improved intangibly. And the terminal data among multiple users are completely the same, so that deviation cannot exist due to different platforms or databases, and the traveling experience of multiple users is improved. Meanwhile, aiming at the consideration of the public domain transmission end position data used by users, a unique encryption character string is generated in an asymmetric encryption mode, and only specific users analyze and acquire the end position data, so that the safety and privacy of personal information of the users are ensured.

Drawings

Fig. 1 is a flow chart of the multi-user travel method based on the same endpoint of the present invention.

Fig. 2 is a flow chart of the multi-user travel method based on the same destination according to the present invention in a preferred embodiment.

Fig. 3 is a flowchart of a multi-user travel method based on the same endpoint according to another preferred embodiment of the present invention.

Fig. 4 is a flowchart of a multi-user travel method based on the same endpoint according to another preferred embodiment of the present invention.

Fig. 5 is a system architecture diagram of the multi-user travel system based on the same endpoint of the present invention.

Fig. 6 is a system architecture diagram of the multi-user travel system based on the same endpoint according to the present invention in a preferred embodiment.

Fig. 7 is a system architecture diagram of a multi-user travel system based on the same endpoint according to another preferred embodiment of the present invention.

Fig. 8 is a system architecture diagram of a first user terminal and a server of the multi-user travel system based on the same endpoint of the present invention.

Fig. 9 is a system architecture diagram of a multi-user travel system based on the same endpoint according to another preferred embodiment of the present invention.

Fig. 10 is a system architecture diagram of the generation module and the analysis module of fig. 9.

Detailed Description

Other advantages and effects of the present invention will become apparent to those skilled in the art from the following disclosure, which describes the embodiments of the present invention with reference to specific examples. The invention may be practiced or carried out in other embodiments that depart from the specific details, and the details of the present description may be modified or varied from the spirit and scope of the present invention. It should be noted that the following embodiments and features in the embodiments may be combined with each other without conflict. It is also to be understood that the terminology used in the examples of the invention is for the purpose of describing particular embodiments only, and is not intended to limit the scope of the invention. The test methods in the following examples, in which specific conditions are not noted, are generally conducted under conventional conditions or under conditions recommended by the respective manufacturers.

Please refer to fig. 1 to 10. It should be understood that the structures, proportions, sizes, etc. shown in the drawings are for illustration purposes only and should not be construed as limiting the invention to the extent that it can be practiced, since modifications, changes in the proportions, or otherwise, used in the practice of the invention, are not intended to be critical to the essential characteristics of the invention, but are intended to fall within the spirit and scope of the invention. Also, the terms such as "upper," "lower," "left," "right," "middle," and "a" and the like recited in the present specification are merely for descriptive purposes and are not intended to limit the scope of the invention, but are intended to provide relative positional changes or modifications without materially altering the technical context in which the invention may be practiced.

Referring to fig. 1, the present invention provides a multi-user travel method based on the same destination, which includes a same destination location determining step, a same destination location transmitting step, and a same destination location vehicle service step. In the same end position determining step, a first user requests the server through a first user terminal to acquire map data of a map database of the server, and determines end position data from the map data. In the same terminal position sending step, the first user inquires and selects the second user through the server, and sends terminal position data to the terminal of the second user through the server. And finally, in the same terminal position vehicle service step, the first user terminal and at least one second user terminal receive and analyze terminal position data, and initiate corresponding service requests to the server according to the terminal position data.

Referring to fig. 1 and 2, the end position determining step includes a sub-step of acquiring map data and an end position determining sub-step. In the acquire map data sub-step, the user can effectively acquire geographical location (map data) information through a map database in a server or map data in a storage medium. And then selecting specific point positions from the acquired map data as end point data through an end point position determining sub-step. The same terminal position sending step comprises a receiving end user selection sub-step and a terminal position data distribution step, a user database is arranged in a server for a first user terminal to inquire and specify that each piece of user data in a second user terminal user database comprises a receiver unique identification code, and the server sends the user data corresponding to the specified second user terminal to the first user terminal; the first user terminal sends the end position data directly and/or distributes the end position data to the second user terminal in a manner that generates a link and sends the link information. Specifically, the first user terminal sends a query request to the server to acquire user information/data (including but not limited to a unique user identification code or a non-unique user identification code) in the database, and then selects user terminal position data to be sent for distribution. The first user terminal transmits the end position data containing the corresponding position unique identifier and the user data of the appointed terminal to the server so as to request the server to transmit the end position information/data to the corresponding second user terminal directly or through the intermediate server. Finally, in the same terminal position vehicle service step, the network or communication capacity of the user hardware terminal is input, the received terminal position data is analyzed based on the terminal position data, and service requirements are initiated to the server so as to initiate vehicle service requests to the server, and finally the requirements of vehicle travel service are realized.

Referring to fig. 1 and 3, the end position determining step includes a sub-step of acquiring map data and an end position determining sub-step. In the acquire map data sub-step, the user can effectively acquire geographical location (map data) information through a map database in a server or map data in a storage medium. And then selecting specific point positions from the acquired map data as end point data through an end point position determining sub-step. The same destination location transmitting step includes an access link generating sub-step and a destination location data acquiring sub-step. In the access link generation sub-step, the user queries and determines the second user terminal of the end position data through the server, and then generates an access link. The destination location data in the access link includes information of a unique location identifier, longitude and latitude, city code, city name, region code, region and location. The links are sent to the server by the first user terminal, and then sent to the corresponding second user terminal by the server, so that the second user terminal analyzes based on the position data, initiates service requirements to the server, and finally realizes that the second user terminal receives the corresponding position data. In the end position data acquisition sub-step, the second user terminal receives the end position data sent by the server to perform corresponding analysis processing. And finally, in the step of using the vehicle service at the same destination position, the network or communication capacity of the user hardware terminal is input with the received destination data to initiate a vehicle service request to the service end, and finally the vehicle service is realized.

Referring to fig. 1 and 4, the end position determining step includes a sub-step of acquiring map data and an end position determining sub-step. In the sub-step of acquiring map data, the user can effectively acquire the geographical location information through the map database in the server or the map data in the storage medium. In the terminal position determining sub-step, the terminal position data is a self-built position unique identifier, and the server correspondingly generates terminal position data comprising the position unique identifier according to the terminal position selected and determined by the first user terminal. The same end position sending step comprises a receiving end user selection sub-step and an end position data distribution step, a user database is arranged in the server for the first user terminal to inquire and appoint the second user terminal, each user data in the user database comprises a unique identification code of a receiver, and the server sends the user data corresponding to the appointed second user terminal to the first user terminal; the first user terminal sends the end position data directly and/or distributes the end position data to the second user terminal in a manner that generates a link and sends the link information. The first user terminal selects a specific position data receiving end from the acquired map data, and the user selects the second user terminal to send a query request to the server so as to acquire user information (including but not limited to a unique user identifier or a non-unique user identifier) in the database, so as to select a user needing to be transmitted. By means of generating an encrypted link, the first user terminal generates a unique encrypted character string by means of asymmetric encryption of the position data and the unique user identification code, and generates a request of the link end position data taking the unique encrypted character string as a parameter. Because the link is generated by encryption, the first user terminal generates the link comprising the unique encryption character string by asymmetric encryption between the terminal position data and the user data comprising the unique identification code of the receiver of the second user terminal, the second user terminal sends the received link and the unique identification code of the receiver of the second user terminal to the server to analyze and compare and judge whether the unique identification code of the receiver included in the link is the same as the unique identification code of the receiver of the appointed second user terminal in the user database, if so, the position data included in the link is sent to the second user terminal, finally, in the same terminal position vehicle service step, the second user terminal obtains the terminal position data, analyzes and analyzes to obtain the terminal position, and sends a travel request to the vehicle service system module of the server to call the terminal position data as the terminal position data of the receiver travel.

With reference to fig. 1 to fig. 4, the first user terminal and/or at least one second user terminal of the present invention may selectively display or not display real-time location information and arrival time information of other users at the same end point, so that the users may not share related location information and personal data in public domain based on their own needs and privacy security considerations, thereby increasing subjective activity of the users. Meanwhile, when the first user terminal and/or at least one second user terminal need to change the destination (end position), a destination changing request can be initiated to the server, and after confirmation of all the common travel users, a new destination can be sent to the target user terminal through the server, so that the user terminal can be switched to the new end position. Therefore, convenience of user operation can be guaranteed, and experience and dynamic regulation and control capability of a user are enhanced.

With reference to fig. 5, the present invention further provides a multi-user travel system based on the same endpoint, including: the system comprises a server, a first user terminal and a second user terminal. The server comprises a database module provided with a user database and a map database, a receiving module for receiving and processing map data and user data, and a transmitting module for transmitting terminal position data, wherein each user data in the user database comprises a unique identification code of a receiver. The first user terminal acquires user data and map data stored in the user database and the map database from the database module, determines end position data from the map data, designates a second user terminal in the user database, and sends data packets of the determined end position data and the designated user data of the second user terminal to the server for data processing. Finally, at least one second user terminal analyzes after acquiring the end position data from the sending module, and sends a travel request to the server to call the end position data.

Referring to fig. 5 and fig. 6, the first user terminal includes an acquisition module, an interaction module, a selection module and a sharing module which are sequentially connected in communication, where the acquisition module is connected with a database module of the server in a communication manner to acquire and analyze map data and user data, so that the first user terminal can perform corresponding selection through the interaction module; the selection module acquires a selection instruction sent by the interaction module, generates a data packet containing appointed end position data and user data of the second user terminal, and the sharing module sends the data packet to the receiving module of the server so that the server performs data processing. The user can search and select based on unique identification codes, fuzzy search based on non-unique identification codes or recommendation based on the existing friend relation in a database module of a server through an acquisition module, and the user or (a public domain (group chat, square and the like) mode of a plurality of users is determined, wherein the public domain can be a local area network concept, including but not limited to modes based on interest rings or common friends and the like, an image is built for the user, a plurality of groups can be generated, the user can effectively select in the groups, and multidimensional end position sharing can be realized, meanwhile, the acquisition module can acquire data of map data, or can invoke the map data in a storage medium of a user hardware terminal, or invoke a network or communication capacity of the user hardware terminal so as to acquire the map data of the server And the interaction module selects the terminal position data as terminal position data of the travel terminal of the receiver and sends a corresponding initiating demand instruction to the initiating demand module. Specifically, the receiving module of the second user terminal receives and analyzes the endpoint data sent by the server by using the network or communication capability of the user hardware terminal. And then, the user selects and confirms the corresponding terminal data as the required position data through the interaction module, and transmits the network or communication capacity of the user hardware terminal where the initiating demand module is invoked to input the received terminal data and initiate a vehicle service request to the service end. And finally, the position information and the user selection information sent by the first user terminal are sent to the server for corresponding processing, and after the receiving module of the server obtains and analyzes the data packet from the receiving module of the first user terminal, the corresponding second user terminal is determined, and the terminal position data is sent to the receiving module through the sending module, so that the second user terminal and the first user terminal can carry out travel requirements based on the same terminal position.

With reference to fig. 5 and fig. 7, the first user terminal includes an acquisition module, an interaction module, a selection module, a generation module and a sharing module which are sequentially in communication connection, where the acquisition module is in communication connection with a database module of the server, acquires and analyzes map data and user data, so that a user can perform corresponding selection through the interaction module, the selection module acquires a selection instruction sent by the interaction module, generates a data packet containing specified end position data and user data of the second user terminal, the generation module receives the end position data, generates a link containing the end position data and sends the link to the sharing module, and the sharing module sends the link to the first user terminal through a third party public domain. The user can search and select based on the unique identification code, perform fuzzy search based on the non-unique identification code or perform recommendation based on the existing friend relation through the acquisition module, acquire the data of the user, and determine the users to be distributed or the public domain (group chat, square, etc.) modes of a plurality of users, wherein the public domain can be a local area network concept, including but not limited to modes based on interest rings or common friends, etc., to establish portraits for the users, generate a plurality of groups, effectively select the users in the groups, and realize multi-dimensional end position sharing, meanwhile, the acquisition module can acquire the data of map data, namely, can acquire the map data in the storage medium of the user hardware terminal, the user selects a specific point location from the obtained map data as terminal data through an interactive module (including but not limited to a touch screen + GUI interface) of the user hardware terminal, the determined terminal location parameter is sent to a selection module by the interactive module, a data packet of a terminal location is finally realized through analysis of the selection module, then the communication capability of the user hardware terminal is called, and the terminal data/associated unique identification code is transmitted to a server side. And then the analyzed map data and user data are displayed to a user through the interaction module, the user selects and generates corresponding selection instructions by using input equipment (including but not limited to a touch screen and the like) connected with the interaction module, the selection instructions are executed by the selection module, the designated position data are generated by the generation module to be used as links with the position data serving as parameters, and the links are pushed to the second user terminal through a third party public domain (including but not limited to a group or a local area network and the like) by the sharing module. Meanwhile, the second user terminal comprises an import module, an interaction module and an initiation demand module which are sequentially in communication connection, the import module acquires a link from a third party public domain and analyzes the link, the import module sends end position data acquired through analysis to the interaction module, and the interaction module selects the end position data as end position data of a receiver trip and sends a corresponding initiation demand instruction to the initiation demand module. The second user terminal invokes the network or communication capacity of the user hardware terminal, receives the associated unique identification code sent by the server, requests associated terminal data from the server through the associated unique identification code, and finally receives the terminal data sent by the server. The second user terminal obtains a link containing the position data as parameters, analyzes the position data of the corresponding terminal through the importing module, and then presents the position data to the user through the interaction module, so that the user selects and initiates a demand instruction to the demand initiating module through the interaction module, and the final travel demand of the same terminal is achieved. Meanwhile, the selection module of the first user terminal may further generate a data packet, where the end position data in the data packet includes a unique position identifier and a unique identifier of a receiver of the user data packet that includes the specified corresponding second user terminal, and the generation module compiles the data packet including the unique identifier into a link including a unique encrypted string. By means of the encryption character string, the safety and privacy of the terminal position data packet of the user data and the map data in the data transmission process of the third party public domain can be guaranteed.

Referring to fig. 8, in a preferred embodiment of the present invention, a man-machine interaction unit, a memory, a processor and a communication unit are disposed on the first user terminal. The memory is respectively connected with the processor, the communication part and the man-machine interaction part in a communication way, and corresponding computer programs are stored in the memory. The processor may run the computer program, parse the map data and the user data acquired in the server, process the interaction instruction of the man-machine interaction component and the user, and transmit the data to the communication component. The server is also provided with a corresponding memory (database), a processor and a communication part, and data interaction (transmission) is carried out between the communication part of the server and the communication part of the first user terminal. The memory of the server also stores at least one set of computing programs for processing the user database, the map database, and the data parsing of the first user terminal and the second user terminal. The specific analysis execution can be specifically executed by a processor arranged in the server.

In another preferred embodiment of the present invention, referring to fig. 5 and 9, the server further includes an parsing module, a checking module and a transmitting module, the receiving module receives a data packet including a unique encrypted string and a unique identifier of a receiver of the second user terminal from the transmitting module of the first user terminal, and transmits the data packet to the parsing module for parsing and comparing, the parsing module parses the unique identifier of the receiver in the data packet, and checks the unique identifier of the receiver of the second user terminal specified by the checking module corresponding to the user database, and if the unique identifier of the receiver in the data packet is the same as the unique identifier of the receiver of the second user terminal specified by the corresponding user terminal in the user database, the transmitting module transmits the destination location data to the receiving module. Specifically, the acquisition module of the first user terminal acquires and analyzes the map data and the user data from the database module of the server, then the analyzed map data and user data are displayed to the user through the interaction module, the user selects and generates corresponding selection instructions by using input devices (including but not limited to a touch screen and the like) connected with the interaction module, and the selection instructions are transmitted to the selection module to be executed so that the designated position data and the unique identification code of the receiving party of the designated user are generated by the generation module to be used as links with the position data serving as parameters. The generation module sends the link containing the unique encryption character string as the parameter to the sharing module, so that the sharing module sends the link containing the unique encryption character string as the parameter to the import module of the second user terminal through the third party public domain, and the link containing the unique encryption character string as the parameter acquired by the import module is transmitted to the reading module for corresponding analysis. Meanwhile, the server also comprises an analysis module, a verification module and a sending module, wherein the receiving module receives a data packet containing the unique encryption character string and the unique receiver identification code of the second user terminal from the sending module of the first user terminal, and sends the data packet to the analysis module for analysis and comparison, the analysis module analyzes the unique receiver identification code in the data packet, the verification module verifies the unique receiver identification code of the second user terminal corresponding to the verification module in the user database, and the sending module sends the end position data to the receiving module when the unique receiver identification code in the data packet is identical to the unique receiver identification code of the second user terminal corresponding to the verification module in the user database. The reading module of the second user terminal acquires the position data returned by the receiving module, and the position data can be presented to the user by the interaction module so that the user can select and initiate a demand (including but not limited to travel and the like) instruction to the demand initiating module.

Referring to fig. 10, the encrypted string of the generation module of the first user terminal may include, but is not limited to, longitude data, latitude data, POI (Point of Interest information point) data, a receiver unique identification code designating the second user to a receiver unique identification code designating the nth user, generating a process string by sequential concatenation of corresponding programs, and then generating a unique encrypted string by means of asymmetric encryption. The encrypted string may be, for example, "lg" 120.12665988498264, "lt" 30.327991265190974, "poiId" B0I3P7GN8N, "cityCode" 0571

"cityName": data such as "Hangzhou city", "distribution code": "330105", "distribution": "arcade area", "name": "panini", "location": "Duckweed east street 888 number" and the like, and a unique identification code of a user's receiver. The analysis module acquires the process character string from the acquired unique encryption character string through an internal program in an asymmetric decryption mode, and sequentially separates data of a data packet comprising longitude data, latitude data, POI data and a unique identification code of a receiver of a designated second user to a unique identification code of a receiver of a designated Nth user.

The server of the multi-user travel system based on the same destination is also provided with a vehicle service system module, a useful vehicle service system is operated on the vehicle service system module, and the initiating demand module of the first user terminal is in communication connection with the vehicle service system module and sends a demand instruction containing destination position data to the vehicle service system for execution. In the process of searching and searching the user database, the user can search (such as a user nickname and the like) through a non-unique user identification code of the user, and the unique user identification code (such as a user ID, a mobile phone number and the like) is fed back to ensure accuracy; the query accuracy can also be improved by searching for the non-unique user identification code (such as a user nickname, etc.) of the user and displaying more non-unique user identification codes (such as a user head portrait, a user profile, a user gender, etc.). Based on the link (the manner in which the public domain is transmitted), the destination data/the recipient unique identification code (e.g., invitation code, activity ID, etc.) associated with the destination data may be pushed by the user onto the public domain in a manner that sends instructions to the user to select and determine the same destination location. In the communication transmission process, direct communication between the first user terminals can be performed, for example, direct transmission through hardware devices in bluetooth, NFC, wiFI and other modes can be performed, or transmission can be performed through an intermediate server (for example, indirect communication between the first user terminal and the server, and the first user terminal) is usually performed in a cellular network, wiFI and other modes. The user can start from the vehicle demand by using the own map database or calling the third party map, and the service flow is optimized, so that the vehicle scene of the user is more friendly. Meanwhile, based on the own map database, the self-built user database and the user interaction system are used, so that the interaction efficiency (sharing and initiating service) among users is higher, and the accuracy of the end position of the map is higher.

The invention also provides a multi-user travel device based on the same terminal point, which comprises a processor and a storage device. The storage device is used for storing a program, and when the program is executed by the processor, the output device is enabled to realize the multi-user travel method based on the same end point. The user directly retrieves map data in a storage medium of the hardware terminal through the first user terminal and presents the map data to the user through the man-machine interaction module; or calling the network or communication capacity of the hardware terminal to obtain the map data of the server and presenting the map data to the user through the man-machine interaction module. And then, the user selects a specific point position from the presented map data as terminal data through a man-machine interaction module of the hardware terminal. By optimizing the terminal data synchronization mode among multiple users in the program of the server, multiple first user terminals and the server perform data interaction, multiple users can quickly and accurately arrive at a destination based on terminal information, and the traveling experience of multiple users is improved. In particular, a method is used in which the same destination is determined on the basis of a "unique location identifier", which data comprise the received user ID (or check code) when location information is required to occur, only the specified user can receive the corresponding destination location information. Through the improvement, the user experience and the privacy of the position information are optimized. Specifically, the user selects terminal data from the client program of the first user terminal of the hardware, and then selects user information of the receiver from the built-in or associated user database through unique user identification codes such as mobile phone numbers, user IDs and the like or non-unique user identification codes such as user nicknames and the like. Then, the user sends an instruction of transmitting the terminal data to the receiver user to the client program, and the client program transmits the terminal data to the client program of the hardware terminal of the second user terminal through the hardware device, can directly transmit through the hardware device or can transmit through an intermediate server, and finally realizes that multiple users initiate vehicle service requirements in the client program of the terminal based on the terminal data.

In summary, the multi-user traveling method, system and device based on the same terminal point, disclosed by the invention, have the advantages that the operation efficiency is improved without the aid of the third party map software and the third party communication software, the terminal point data among multiple users are completely the same, the deviation caused by different platforms or databases is avoided, and the multi-user traveling experience is improved. The invention also aims at the consideration of the data safety of the end position data transmitted in the public domain range by the user, can select to display or not display the real position information and the arrival time information thereof, and generates a unique encryption character string in an asymmetric encryption mode, and only a specific user analyzes and acquires the end position data, thereby ensuring the safety and privacy of personal information of the user. Meanwhile, aiming at the demand of changing destinations in the use process of users, the users can be switched to a new end position only by confirming all the common travel users. Therefore, the invention effectively overcomes various defects in the prior art and has high industrial utilization value.

The above embodiments are merely illustrative of the principles of the present invention and its effectiveness, and are not intended to limit the invention. Modifications and variations may be made to the above-described embodiments by those skilled in the art without departing from the spirit and scope of the invention. Accordingly, it is intended that all equivalent modifications and variations of the invention be covered by the claims, which are within the ordinary skill of the art, be within the spirit and scope of the present disclosure.

Claims (18)

1. The multi-user travel method based on the same terminal is characterized by comprising the following steps of:

the same end position determining step, wherein a first user requests a server through a first user terminal to acquire map data of a map database of the server, and determines end position data from the map data;

the same end position sending step, wherein the first user inquires and selects a second user through the server, and sends the end position data to the second user through the server;

and in the same terminal position vehicle service step, the first user terminal and at least one second user terminal receive and analyze the terminal position data, and initiate corresponding vehicle service requests to the server according to the terminal position data.

2. The travel method according to claim 1, wherein: the end position data comprises a position unique identifier, longitude and latitude, city codes, city names, region codes, regions and positioning information.

3. The travel method according to claim 1, wherein: the first user terminal or at least one of the second user terminals can select to display or not display the real-time position information and the arrival time information of other identical end users.

4. The travel method according to claim 1, wherein: and the first user terminal and at least one second user initiate a destination changing request to the server, and after all common travel users confirm, the first user terminal and at least one second user switch to a new end position.

5. The travel method according to claim 1, wherein: the terminal position data comprise self-built unique identifiers, and the server generates the terminal position data comprising the unique identifiers according to the terminal position corresponding selected and determined by the user terminal.

6. The travel method of claim 2, 3, 4 or 5, wherein: a user database is arranged in the server for the first user terminal to inquire and appoint the second user terminal, each user data in the user database comprises a unique identification code of a receiver, and the server sends the user data corresponding to the appointed second user terminal to the first user terminal; the first user terminal directly transmits the end position data and/or distributes the end position data to the second user terminal in a mode of generating a link and transmitting link information.

7. The travel method of claim 6, wherein: the link is generated by encryption, the first user terminal generates the link containing unique encryption character strings by asymmetric encryption on the end position data and the user data containing the unique identification code of the receiver of the second user terminal, the second user terminal sends the received link and the unique identification code of the receiver of the second user terminal to the server, the server analyzes and compares and judges whether the unique identification code of the receiver contained in the link is identical to the unique identification code of the receiver of the second user terminal designated in the user database, and if so, the position data contained in the link is sent to the second user terminal.

8. The travel method of claim 6, wherein: and the second user terminal acquires the terminal position data, analyzes and analyzes the terminal position data to obtain the terminal position, and sends a travel request to a vehicle service system module of the server to call the terminal position data as terminal position data of a receiver traveling.

9. A multi-user travel system based on the same endpoint, comprising:

the server comprises a database module provided with a user database and a map database, a receiving module for receiving and processing map data and user data and a transmitting module for transmitting terminal position data, wherein each user data in the user database comprises a unique identification code of a receiver;

the first user terminal acquires the user data and the map data stored in the user database and the map database from the database module, determines end position data from the map data, designates a second user terminal in the user database, and sends the determined end position data and a data packet of the user data of the designated second user terminal to the server for data processing;

and the second user terminal is used for analyzing after at least one second user terminal obtains the terminal position data from the sending module and sending a travel request to the server so as to call the terminal position data.

10. The travel system of claim 9, wherein: the first user terminal comprises an acquisition module, an interaction module, a selection module and a sharing module which are sequentially in communication connection, wherein the acquisition module is in communication connection with the database module of the server so as to acquire and analyze the map data and the user data, and the first user terminal can perform corresponding selection through the interaction module; the selection module acquires a selection instruction sent by the interaction module and generates the data packet containing the appointed terminal position data and the user data of the second user terminal, and the sharing module sends the data packet to the receiving module of the server so that the server performs data processing.

11. The travel system of claim 10, wherein: the second user terminal comprises an accepting module, an interaction module and an initiating demand module which are sequentially in communication connection, wherein the accepting module is in communication connection with the sending module of the server so as to acquire and analyze the terminal position data, and the interaction module selects the terminal position data as terminal position data of a travel terminal of a receiver and sends a corresponding initiating demand instruction to the initiating demand module; and after the receiving module of the server acquires and analyzes the data packet from the receiving module of the first user terminal, the receiving module sends the end position data to the receiving module.

12. The travel system of claim 9, wherein: the first user terminal comprises an acquisition module, an interaction module, a selection module, a generation module and a sharing module which are sequentially in communication connection, wherein the acquisition module is in communication connection with the database module of the server, acquires and analyzes the map data and the user data for a user to select correspondingly through the interaction module, the selection module acquires a selection instruction sent by the interaction module, generates a data packet containing appointed terminal position data and user data of the second user terminal, the generation module receives the terminal position data, generates a link containing the terminal position data and sends the link to the sharing module, and the sharing module sends the link to the first user terminal through a third party public domain.

13. The travel system of claim 12, wherein: and the generation module compiles the data packet containing the appointed unique identifier into the link containing the unique encryption character string.

14. The travel system of claim 13, wherein: the second user terminal comprises an import module, an interaction module and an initiation demand module which are sequentially in communication connection, wherein the import module acquires the link from the third party public domain and analyzes the link, the import module sends the end position data acquired by analysis to the interaction module, and the interaction module selects the end position data as end position data of a receiver trip and sends a corresponding initiation demand instruction to the initiation demand module.

15. The travel system of claim 13, wherein: the second user terminal comprises an import module, a reading module, an interaction module, an initiating demand module, a generation module and a receiving module which are sequentially in communication connection, wherein the generation module and the receiving module are in communication connection with the reading module, the sharing module of the first user terminal sends the link containing the unique encryption character string generated by the generation module to the third party public domain, the import module obtains the link containing the unique encryption character string from the third party public domain and analyzes the link, the reading module obtains the unique encryption character string analyzed by the import module and sends the unique encryption character string to the server through the sending module to perform identity verification, the server completes the identity verification and feeds the analyzed end point position data back to the receiving module, the receiving module sends the end point position data to the reading module to read out the end point position data, and the interaction module obtains and selects the end point position data from the reading module as the end point position data of a receiver and initiates a corresponding demand command to the receiving party.

16. The travel system of claim 15, wherein: the server further comprises an analysis module, a verification module and a sending module, wherein the receiving module receives the data packet containing the unique encryption character string and the unique receiver identification code of the second user terminal from the sending module of the first user terminal, and sends the data packet to the analysis module for analysis and comparison, the analysis module analyzes the unique receiver identification code in the data packet, the verification module verifies the unique receiver identification code of the second user terminal corresponding to the verification module in the user database, and when the unique receiver identification code in the data packet is identical to the unique receiver identification code of the second user terminal corresponding to the verification module in the user database, the sending module sends the end position data to the receiving module.

17. The travel system according to claim 11, 12 or 15, wherein: the server is also provided with a vehicle service system module, a vehicle service system is operated on the vehicle service system module, the demand initiating module of the first user terminal is in communication connection with the vehicle service system module, and the demand instruction containing the end position data is sent to the vehicle service system for execution.

18. A multi-user travel device based on the same endpoint, comprising:

a processor;

storage means for storing a program which, when executed by the processor, causes the travel means to implement the same endpoint-based multi-user travel method of any one of claims 1 to 8.