CN112738771A - TBOX wireless learning device and working method - Google Patents

Abstract

The invention discloses a TBOX wireless learning device and a working method thereof, relates to a vehicle networking device, and aims to solve the problems that the existing mobile phone is connected with a TBOX and always passes through a mobile communication network, the user consumption flow is large, and the use is inconvenient, wherein the device comprises: the processor is used for detecting that the user terminal equipment is positioned in the effective communication distance and sending a mobile network cut-off signal; the second wireless transmission module is used for receiving a mobile network cut-off signal and sending the mobile network cut-off signal to the vehicle TBOX; the mobile network switching-off feedback signal is also used for receiving a mobile network switching-off feedback signal and sending the mobile network switching-off feedback signal to the processor; the vehicle TBOX is used for cutting off the mobile network between the vehicle TBOX and the user terminal equipment after receiving the mobile network cutting off signal and sending a mobile network cutting off feedback signal; the processor is also used for sending a terminal connection signal after receiving the mobile network cut-off feedback signal; and the first wireless transmission module is used for establishing wireless communication connection with the user terminal equipment after receiving the terminal connection signal.

Description

TBOX wireless learning device and working method

Technical Field

The invention relates to a vehicle networking device.

Background

TBOX is called a vehicle-mounted intelligent terminal, and serves as the only control unit capable of being networked with a vehicle body, and plays a role in monitoring and controlling the state of the vehicle body, and the TBOX has the greatest value in the connectivity with a network. The TBOX is mainly used for collecting vehicle-related information including position information, attitude information, vehicle state information (through connection with an on-vehicle CAN bus) and the like, and then transmitting the information to a content Service provider TSP (telematics Service provider) platform in a wireless communication mode. Meanwhile, a user can use the mobile phone APP and the Web client to issue an instruction to the TBOX terminal through the TSP platform, and remote control operation is conducted on the vehicle, such as control over opening and closing of a vehicle window and a vehicle door, adjustment of the angle of a seat, adjustment of the temperature in the vehicle and the like.

As shown in fig. 1, the TBOX communicates with the vehicle through the CAN bus, and uploads the acquired vehicle status information to the server through the 4G network for the mobile terminal to read, and CAN also receive a vehicle control command issued by the mobile terminal and complete control of the vehicle.

However, a mobile communication network (such as a 4G network) is required for information exchange between a user and the TBOX through a mobile phone, the 4G module is embedded in the TBOX, traffic is consumed for data exchange, the user needs to pay corresponding fees according to the amount of the traffic consumed by the TBOX, and even if the user uses the mobile communication network in a vehicle, the traffic is consumed; and TBOX can not identify whether the driver is a real vehicle owner or not, and can not adjust the vehicle to a more customary mode (including a seat angle, a steering wheel angle, a driving mode and the like) for the vehicle owner, so that the vehicle networking experience of a user is influenced.

Disclosure of Invention

The invention aims to solve the problems that the existing mobile phone is always connected with a TBOX through a mobile communication network, the user consumes a large amount of flow and the use is inconvenient, and provides a TBOX wireless learning device and a working method thereof.

The invention discloses a TBOX wireless learning device, which comprises a processor, a first wireless transmission module and a second wireless transmission module;

the processor is simultaneously connected with the first wireless transmission module and the second wireless transmission module and used for detecting whether the user terminal equipment is positioned in the effective communication distance of the first wireless transmission module and sending a mobile network cut-off signal to the second wireless transmission module when the user terminal equipment is detected to be positioned in the effective communication distance of the first wireless transmission module;

the second wireless transmission module is in wireless communication connection with the vehicle TBOX and is used for receiving the mobile network cut-off signal and sending the mobile network cut-off signal to the vehicle TBOX; the mobile network cut-off feedback signal sent by the vehicle TBOX is also received and sent to the processor;

the vehicle TBOX is used for cutting off the mobile network between the vehicle TBOX and the user terminal equipment after receiving the mobile network cutting off signal and sending a mobile network cutting off feedback signal;

the processor is also used for sending a terminal connection signal to the first wireless transmission module after receiving the mobile network cut-off feedback signal;

and the first wireless transmission module is used for establishing wireless communication connection with the user terminal equipment after receiving the terminal connection signal.

The device also comprises a storage module;

the processor is also used for sending a TBOX message interception signal;

the second wireless transmission module is also used for transmitting a TBOX message interception signal to the vehicle TBOX, receiving a TBOX message returned by the vehicle TBOX and sending the TBOX message to the processor;

the vehicle TBOX is also used for returning a corresponding TBOX message after receiving the TBOX message interception signal;

and the processor is also connected with the storage module and used for receiving and analyzing the TBOX message to obtain user vehicle use habit data and storing the user vehicle use habit data into the storage module.

The processor is further used for detecting whether the user terminal equipment is located in the corresponding vehicle, calling the user habit data in the storage module to generate a user habit state adjusting signal when the user terminal equipment is located in the corresponding vehicle, and sending the user habit state adjusting signal to the second wireless transmission module;

the second wireless transmission module is also used for transmitting the user habit state adjusting signal to the vehicle TBOX, so that the vehicle TBOX receives the user habit state adjusting signal and then adjusts the vehicle to be in a corresponding use state according to the user habit data.

The first wireless transmission module is a Bluetooth communication module, and the second wireless transmission module is an infrared communication module.

Based on an operating method of a TBOX wireless learning device, the method is used for changing a communication mode between user terminal equipment and a vehicle TBOX, and the method is embedded in a processor and specifically comprises the following steps:

step one, detecting whether the user terminal equipment is positioned in the effective communication distance of the first wireless transmission module;

if yes, executing step two;

step two, disconnecting a mobile network between user terminal equipment and a vehicle TBOX;

and step three, establishing wireless communication connection between the user terminal equipment and the first wireless transmission module.

The method further comprises a step of obtaining the user car usage habit data, and specifically comprises the following steps:

step two, monitoring and acquiring a TBOX message;

secondly, analyzing to obtain user vehicle using habit data according to the TBOX message;

and step two, storing the user car using habit data.

The method further comprises a step of adjusting the using state of the vehicle according to the using habit data of the user, and specifically comprises the following steps:

step three, detecting whether the user terminal equipment is positioned in the corresponding vehicle;

if yes, executing step two;

and step two, the vehicle TBOX adjusts the vehicle to be in a corresponding use state according to the user vehicle usage habit data.

The invention has the beneficial effects that:

the device adopts an infrared communication method to carry out bidirectional data transmission with the TBOX, achieves the purposes of obtaining vehicle information data and controlling a vehicle, and can carry out data interaction with a mobile phone APP in a Bluetooth communication mode.

The purpose that the vehicle can be controlled through the Bluetooth when the vehicle owner is away from the vehicle in the effective Bluetooth transmission distance is achieved, the use habit of the vehicle owner to the vehicle can be recorded, and when the mobile phone of the vehicle owner is in the vehicle, the vehicle is automatically set to be in the habit state of the vehicle owner. The problem that the TBOX consumes unnecessary flow is solved, and meanwhile, whether the vehicle is used by the vehicle owner or not can be identified by judging whether the mobile phone of the vehicle owner is in the vehicle or not, and the vehicle is automatically adjusted to the habitual state for the vehicle owner. The functions of the TBOX are enriched, and the use experience of the car networking users is improved.

Drawings

FIG. 1 is a flow chart of an existing TBOX communicating with a vehicle over a CAN bus;

fig. 2 is a schematic structural diagram of a TBOX wireless learning apparatus of the present invention in combination with a user terminal device and a vehicle TBOX;

FIG. 3 is a flow chart of the communication mode between the user terminal equipment and the vehicle TBOX in the working method of the invention;

FIG. 4 is a flowchart of steps included in the method of the present invention for obtaining user vehicle usage habit data;

FIG. 5 is a flow chart of steps included in the method of the present invention for adjusting a usage status of a vehicle according to user usage habit data;

fig. 6 is a general flow chart of the working method of the TBOX wireless learning device.

Detailed Description

In a first specific embodiment, the TBOX wireless learning apparatus of the present embodiment includes a processor 1, a first wireless transmission module 2, and a second wireless transmission module 3;

the processor 1 is connected with the first wireless transmission module 2 and the second wireless transmission module 3 at the same time, and is used for detecting whether the user terminal equipment 5 is located within the effective communication distance of the first wireless transmission module 2, and sending a mobile network cut-off signal to the second wireless transmission module 3 when detecting that the user terminal equipment 5 is located within the effective communication distance of the first wireless transmission module 2;

the second wireless transmission module 3 is in wireless communication connection with the vehicle TBOX6 and is used for receiving a mobile network disconnection signal and sending the mobile network disconnection signal to the vehicle TBOX 6; the mobile network cut-off feedback signal sent by the vehicle TBOX6 is also received and sent to the processor 1;

a vehicle TBOX6, for cutting off the mobile network between the user terminal equipment 5 and the vehicle TBOX6 after receiving the mobile network cut-off signal, and sending a mobile network cut-off feedback signal;

the processor 1 is further configured to send a terminal connection signal to the first wireless transmission module 2 after receiving the mobile network disconnection feedback signal;

and the first wireless transmission module 2 is configured to establish a wireless communication connection with the user terminal device 5 after receiving the terminal connection signal.

The TBOX wireless learning device also comprises a storage module 4;

the processor 1 is further configured to send a TBOX message interception signal;

the second wireless transmission module 3 is further configured to transmit a TBOX message interception signal to the vehicle TBOX6, and receive a TBOX message returned by the vehicle TBOX6 and send the TBOX message to the processor 1;

the vehicle TBOX6 is also used for returning a corresponding TBOX message after receiving the TBOX message interception signal;

the processor 1 is also connected with the storage module 4 and is used for receiving and analyzing the TBOX message, obtaining user vehicle usage habit data and storing the user vehicle usage habit data in the storage module 4.

The processor 1 is further configured to detect whether the user terminal device 5 is located inside a corresponding vehicle, and when the user terminal device 5 is located inside the corresponding vehicle, call the user habit data in the storage module 4 to generate a user habit state adjustment signal, and send the user habit state adjustment signal to the second wireless transmission module 3;

the second wireless transmission module 3 is further configured to transmit the user habit state adjustment signal to the vehicle TBOX6, so that the vehicle TBOX6 adjusts the vehicle to a corresponding use state according to the user habit data after receiving the user habit state adjustment signal.

The first wireless transmission module 2 is a bluetooth communication module, and the second wireless transmission module 3 is an infrared communication module.

Specifically, the existing vehicle TBOX is more like a transparent transmission module between a user and a vehicle, and is responsible for collecting and uploading data and analyzing and issuing commands, and functions of saving flow, recording habits of vehicle owners and users and the like are not achieved, and the degree of intellectualization is not achieved.

As shown in fig. 1, the present invention is a device existing between a vehicle TBOX6 and a user terminal device 5, which performs data transmission with a vehicle TBOX6 by means of infrared communication (second wireless transmission module 3), generates user habits by analyzing TBOX data and records them in a storage module 4, and can provide a one-key setting of a vehicle state function of self-preference for the user; in addition, the device provides a Bluetooth communication interface (the first wireless transmission module 2) for the user terminal equipment 5, and when the distance between the user terminal equipment 5 and the device is within the effective Bluetooth range of the first wireless transmission module 2, the vehicle TBOX6 can be controlled to disconnect the 4G network connection, so that the traffic cost is saved for the user.

Fig. 6 is a general flow chart of the operation method of the present apparatus.

Based on an operating method of a TBOX wireless learning device, the operating method is a method for changing a communication mode between a user terminal device 5 and a vehicle TBOX6, as shown in fig. 3, the method specifically comprises the following steps:

step one, detecting whether the user terminal equipment 5 is positioned in the effective communication distance of the first wireless transmission module 2;

if yes, executing step two;

step two, disconnecting the mobile network between the user terminal equipment 5 and the vehicle TBOX 6;

and step three, establishing wireless communication connection between the user terminal equipment 5 and the first wireless transmission module 2.

As shown in fig. 4, further, the method further includes a step of obtaining the user usage habit data, specifically including:

step two, monitoring and acquiring a TBOX message;

secondly, analyzing to obtain user vehicle using habit data according to the TBOX message;

and step two, storing the user car using habit data.

As shown in fig. 5, further, the method further includes a step of adjusting the usage state of the vehicle according to the usage habit data of the user, specifically including:

step three, detecting whether the user terminal equipment 5 is positioned in the corresponding vehicle;

if yes, executing step two;

and step two, the vehicle TBOX6 adjusts the vehicle to be in a corresponding use state according to the user habit data.

Specifically, the work flow of the device is divided into six links: the method comprises the steps of intercepting TBOX messages by using infrared communication, analyzing the TBOX messages by using an MCU (micro control unit) to generate a user habit link, storing user configuration habit data by using an EEPROM (electrically erasable programmable read-only memory), judging whether user terminal equipment is in a link of effective Bluetooth communication distance, cutting off a TBOX4G network link, and starting a Bluetooth communication control link. Through the six links, the device achieves the aims of saving flow cost for users, bringing better use experience to the users and the like.

Claims (7)

1. A TBOX wireless learning device is characterized by comprising a processor (1), a first wireless transmission module (2) and a second wireless transmission module (3);

the processor (1) is connected with the first wireless transmission module (2) and the second wireless transmission module (3) at the same time, and is used for detecting whether the user terminal equipment (5) is located within the effective communication distance of the first wireless transmission module (2) or not, and sending a mobile network cut-off signal to the second wireless transmission module (3) when detecting that the user terminal equipment (5) is located within the effective communication distance of the first wireless transmission module (2);

the second wireless transmission module (3) is in wireless communication connection with the vehicle TBOX (6) and is used for receiving a mobile network cut-off signal and sending the mobile network cut-off signal to the vehicle TBOX (6); the mobile network cut-off feedback signal sent by the vehicle TBOX (6) is also received and sent to the processor (1);

the vehicle TBOX (6) is used for cutting off the mobile network between the vehicle TBOX and the user terminal equipment (5) after receiving the mobile network cutting off signal and sending a mobile network cutting off feedback signal;

the processor (1) is further configured to send a terminal connection signal to the first wireless transmission module (2) after receiving the mobile network disconnection feedback signal;

the first wireless transmission module (2) is used for establishing wireless communication connection with the user terminal equipment (5) after receiving the terminal connection signal.

2. A TBOX wireless learning device according to claim 1, further comprising a memory module (4);

the processor (1) is further configured to send a TBOX message interception signal;

the second wireless transmission module (3) is also used for transmitting a TBOX message interception signal to the vehicle TBOX (6), receiving a TBOX message returned by the vehicle TBOX (6) and sending the TBOX message to the processor (1);

the vehicle TBOX (6) is also used for returning a corresponding TBOX message after receiving the TBOX message interception signal;

the processor (1) is also connected with the storage module (4) and is used for receiving and analyzing the TBOX message, obtaining user vehicle using habit data and storing the user vehicle using habit data in the storage module (4).

3. A TBOX wireless learning apparatus as recited in claim 2,

the processor (1) is further configured to detect whether the user terminal device (5) is located inside a corresponding vehicle, and when the user terminal device (5) is located inside the corresponding vehicle, call the user habit data in the storage module (4) to generate a user habit state adjustment signal, and send the user habit state adjustment signal to the second wireless transmission module (3);

the second wireless transmission module (3) is also used for transmitting the user habit state adjusting signal to the vehicle TBOX (6), so that the vehicle TBOX (6) can adjust the vehicle to be in a corresponding use state according to the user habit data after receiving the user habit state adjusting signal.

4. A TBOX wireless learning device as claimed in claim 1, 2 or 3, characterised by that the first wireless transmission module (2) is a bluetooth communication module and the second wireless transmission module (3) is an infrared communication module.

5. A method of operating a TBOX wireless learning device according to claim 1, characterized in that the method is used to change the communication mode between the user terminal equipment (5) and the vehicle TBOX (6), the method is embedded in the processor, and the method is as follows:

step one, detecting whether the user terminal equipment (5) is positioned in the effective communication distance of the first wireless transmission module (2);

if yes, executing step two;

step two, disconnecting a mobile network between the user terminal equipment (5) and the vehicle TBOX (6);

and step three, establishing wireless communication connection between the user terminal equipment (5) and the first wireless transmission module (2).

6. The working method according to claim 5, wherein the method further comprises a step of obtaining user usage data, specifically comprising:

step two, monitoring and acquiring a TBOX message;

secondly, analyzing to obtain user vehicle using habit data according to the TBOX message;

and step two, storing the user car using habit data.

7. The working method according to claim 6, further comprising a step for adjusting the usage status of the vehicle according to the usage habit data of the user, specifically comprising:

step three, detecting whether the user terminal equipment (5) is positioned in the corresponding vehicle;

if yes, executing step two;

and step two, the vehicle TBOX (6) adjusts the vehicle to be in a corresponding use state according to the user vehicle usage habit data.

Images