Search

US-20260129607-A1 - METHOD AND DEVICE FOR DATA TRANSMISSION AND ATOMIZATION APPARATUS

US20260129607A1US 20260129607 A1US20260129607 A1US 20260129607A1US-20260129607-A1

Abstract

The present application discloses a method and a device for data transmission, and an atomization apparatus; the method for data transmission is applied to a first control module in a first atomization apparatus, the first control module is connected to a first short-range wireless communication module, and the method for data transmission includes: detecting whether a second atomization apparatus exists within a preset distance range through the first short-range wireless communication module; and if the second atomization apparatus is existed within the preset distance range, performing data communication with the second atomization apparatus through the first short-range wireless communication module. By introducing the first short-range wireless communication module into the atomization apparatus, non-contact data transmission between apparatuses is achieved, and the problems of complex connection, vulnerable interface and unstable transmission existing in traditional wired communication methods are addressed.

Inventors

  • Hongxing DUAN
  • Gang Li
  • Mushan Li
  • Huaping LIAO
  • Jinjian XU
  • Linren GU
  • Lin Zhou

Assignees

  • SHENZHEN GEEKVAPE TECHNOLOGY CO., LTD.

Dates

Publication Date
20260507
Application Date
20251104
Priority Date
20241204

Claims (20)

  1. 1 . A method for data transmission, applied to a first control module in a first atomization apparatus, wherein the first control module is connected to a first short-range wireless communication module, and the method for data transmission comprises: detecting whether a second atomization apparatus exists within a preset distance range through the first short-range wireless communication module; and if the second atomization apparatus is existed within the preset distance range, performing data communication with the second atomization apparatus through the first short-range wireless communication module.
  2. 2 . The method for data transmission according to claim 1 , wherein the first control module comprises a dormant state and an activated state, when the first control module is in the dormant state, after if the second atomization apparatus is existed within the preset distance range, the method further comprises: receiving a wake-up signal output by the first short-range wireless communication module and switching from the dormant state to the activated state; and wherein the first control module being in the dormant state comprises: the first control module entering the dormant state when the first control module does not receive data sent by the first short-range wireless communication module within a preset time period.
  3. 3 . The method for data transmission according to claim 1 , wherein the step of detecting whether the second atomization apparatus exists within the preset distance range through the first short-range wireless communication module comprises: periodically sending a first card-seeking signal through the first short-range wireless communication module; determining that the second atomization apparatus exists within the preset distance range when a response signal or a second card-seeking signal sent by the second atomization apparatus is received; and determining that the second atomization apparatus does not exist within the preset distance range when the response signal or the second card-seeking signal sent by the second atomization apparatus is not received.
  4. 4 . The method for data transmission according to claim 1 , wherein the step of performing the data communication with the second atomization apparatus through the first short-range wireless communication module comprises: sending first data to the first short-range wireless communication module, causing the first short-range wireless communication module to encode the first data to obtain a first data packet frame and send the first data packet frame to the second atomization apparatus.
  5. 5 . The method for data transmission according to claim 4 , wherein the atomization apparatus further comprises an user interaction module, and the step of sending the first data to the first short-range wireless communication module comprises: receiving control information output by the user interaction module and sending a first control instruction to the first short-range wireless communication module.
  6. 6 . The method for data transmission according to claim 4 , wherein the step of causing the first short-range wireless communication module to encode the first data to obtain the first data packet frame comprises: causing the first short-range wireless communication module to encode the first data based on a modulation type and an encoding type to obtain the first data packet frame; and wherein the first data packet frame comprises a first frame start segment, a first data segment, and a first frame end segment, and the step of causing the first short-range wireless communication module to encode the first data based on the modulation type and the encoding type to obtain the first data packet frame comprises: causing the first short-range wireless communication module to set the first frame start segment based on the modulation type and the encoding type, to encode the first data according to the modulation type and the encoding type to obtain the first data segment, and to set the first frame end segment according to an encoding violation.
  7. 7 . The method for data transmission according to claim 4 , wherein after sending the first data to the first short-range wireless communication module, the method further comprises: determining that the first short-range wireless communication module has successfully received the data when a response message sent by the first short-range wireless communication module is received; and determining that the first short-range wireless communication module has not successfully received the data when a communication timeout message sent by the first short-range wireless communication module is received.
  8. 8 . The method for data transmission according to claim 1 , wherein the step of performing the data communication with the second atomization apparatus through the first short-range wireless communication module further comprises: decoding a second data packet frame through the first short-range wireless communication module to obtain second data when the first short-range wireless communication module receives the second data packet frame sent by the second atomization apparatus; and wherein the second data packet frame comprises a second frame start segment, a second data segment, and a second frame end segment, and the step of decoding the second data packet frame through the first short-range wireless communication module to obtain the second data comprises: causing the first short-range wireless communication module to obtain a modulation type and an encoding type based on the second frame start segment, to decode the second data segment based on the modulation type and the encoding type to obtain the second data, and to stop decoding based on the second frame end segment.
  9. 9 . The method for data transmission according to claim 8 , wherein after decoding the second data segment based on the modulation type and the encoding type to obtain the second data, the method further comprises: executing a second control instruction when the second data comprises the second control instruction.
  10. 10 . The method for data transmission according to claim 1 , wherein the step of performing the data communication with the second atomization apparatus through the first short-range wireless communication module further comprises: performing a paired connection with the second atomization apparatus through the first short-range wireless communication module, performing data transmission with the second atomization apparatus, and synchronously displaying data with the second atomization apparatus.
  11. 11 . The method for data transmission according to claim 10 , wherein the step of performing the paired connection with the second atomization apparatus through the first short-range wireless communication module comprises: receiving a field signal sent by the second atomization apparatus through the first short-range wireless communication module; receiving an activation signal sent by the first short-range wireless communication module; controlling the first atomization apparatus to enter an activated state from a dormant state based on the activation signal; and sending, in a case where the first atomization apparatus is in the activated state, a response signal to the second atomization apparatus through the first short-range wireless communication module, wherein the response signal is configured to indicate establishing a communication connection between the first atomization apparatus and the second atomization apparatus.
  12. 12 . The method for data transmission according to claim 11 , wherein the first control module is connected to a first display module; and the step of performing data transmission with the second atomization apparatus and the synchronously displaying the data with the second atomization apparatus comprises: receiving second data sent by the second atomization apparatus through the first short-range wireless communication module; synchronously displaying the second data with the second atomization apparatus through the first display module.
  13. 13 . The method for data transmission according to claim 12 , wherein the step of synchronously displaying the second data with the second atomization apparatus through the first display module comprises: comparing a timestamp in the second data with a second local timestamp, and updating displayed data to cause display data of the second atomization apparatus to be consistent with that of the first atomization apparatus when the timestamp in the second data is later than the second local timestamp; wherein the second local timestamp corresponds to a time of a current display content on the first atomization apparatus.
  14. 14 . The method for data transmission according to claim 10 , wherein the first control module is connected to a first display module, and the second atomization apparatus comprises a second control module, a second short-range wireless communication module, and a second display module; the step of performing the data transmission with the second atomization apparatus and synchronously displaying data with the second atomization apparatus comprises: displaying third data through the first display module while simultaneously displaying fourth data sent from the second atomization apparatus; and sending the third data to the second short-range wireless communication module through the first short-range wireless communication module, causing the second control module to simultaneously display both the third data and the fourth data through the second display module.
  15. 15 . The method for data transmission according to claim 14 , wherein the step of simultaneously displaying the fourth data sent from the second atomization apparatus comprises: comparing a timestamp in the fourth data with a second local timestamp, and updating a display data to cause the display data of the first atomization apparatus to be consistent with that of the second atomization apparatus when the timestamp in the fourth data is later than the second local timestamp; wherein the second local timestamp corresponds to a time of a current display content of the first atomization apparatus; and wherein the step of causing the second control module to simultaneously display the third data and the fourth data through the second display module comprises: displaying, through the second control module, the fourth data through the second display module, and comparing a timestamp in the third data with a first local timestamp, updating display data to cause display data of the second atomization apparatus to be consistent with that of the first atomization apparatus when the timestamp in the third data is later than the first local timestamp; wherein the first local timestamp corresponds to a time of a current display content of the second atomization apparatus.
  16. 16 . The method for data transmission according to claim 10 , wherein the step of simultaneously displaying the data with the second atomization apparatus comprises: synchronously displaying flavor parameters, power level information, and usage records with the second atomization apparatus, wherein the flavor parameters refer to a type of atomization liquid currently used, a flavor name, a concentration level, or output power configuration of both the first atomization apparatus and the second atomization apparatus, the power level information refer to the current power level states of both the first atomization apparatus and the second atomization apparatus, and the usage records refer to data related to usage behaviors of both the first atomization apparatus and the second atomization apparatus; and synchronously displaying animation effects with the second atomization apparatus.
  17. 17 . The method for data transmission according to claim 1 , wherein the method further comprises: obtaining an interaction signal output by other electronic apparatuses after establishing a near-field sensing connection between the first atomization apparatus and any one of the other electronic apparatuses; parsing the interaction signal to obtain interaction instruction information; performing a logical judgment based on a local apparatus information of the first atomization apparatus and the interaction instruction information to obtain interaction operation information, wherein the interaction operation information comprises at least one selected from a group consisting of an interaction scene, an interaction mode, an interaction state, an interaction duration, and an interaction prompt; and displaying the interaction operation information in a dynamic effect image style on a human-machine interface of the first atomization apparatus.
  18. 18 . The method for data transmission according to claim 17 , wherein the method further comprises: detecting a sensing distance value between the first atomization apparatus and any one of the other electronic apparatuses, wherein both the first atomization apparatus and the other electronic apparatuses are provided with a near-field communication module and an antenna used in conjunction with the near-field communication module; and establishing the near-field sensing connection between the first atomization apparatus and the other electronic apparatuses in response to detecting that the sensing distance value is less than a preset distance threshold.
  19. 19 . The method for data transmission according to claim 17 , wherein the step of parsing the interaction signal to obtain interaction instruction information comprises: obtaining data content carried in the interaction signal, wherein the data content comprises: a header identifier, instruction content, and a verification portion; and parsing the data content according to a preset interaction protocol and a preset encoding rule to obtain the interaction instruction information, wherein the preset interaction protocol specifies an encoding method for header identifiers corresponding to different types of interaction signals, and the preset encoding rule specifies specific encoding formats for each parameter in the instruction content.
  20. 20 . The method for data transmission according to claim 17 , wherein the method further comprises obtaining local apparatus information of the first atomization apparatus through at least one of followings: obtaining a current power level value of the first atomization apparatus through a power level sensor of the first atomization apparatus; obtaining a current atomization parameter of the first atomization apparatus through a storage configuration module of the first atomization apparatus, wherein the current atomization parameter comprises at least one of followings: an atomization concentration, an atomization flavor, and an atomization duration; and obtaining a current operation state of the first atomization apparatus through a state monitoring module of the first atomization apparatus, wherein the current operation state comprises at least one of followings: a normal operation state, an abnormal operation state, and a firmware upgrade in progress.

Description

CROSS REFERENCE TO RELATED APPLICATIONS The present application claims priorities of a Chinese application, with application No. 202510855768.5, filed on Jun. 24, 2025; a Chinese application, with application No. 202510869140.0, filed on Jun. 24, 2025; a Chinese application, with application No. 202510437750.3, filed on Apr. 8, 2025; a Chinese application, with application No. 202411784810.0, filed on Dec. 4, 2024; and a Chinese application, with application No. 202422685989.6, filed on Nov. 5, 2024; the contents of which are incorporated herein by reference. TECHNICAL FIELD The present application relates to the technical field of atomization apparatuses, and more specifically to a method and a device for data transmission, and an atomization apparatus. BACKGROUND At present, the development of atomization apparatus products in the direction of intelligence is accelerating. The functional linkage and data interaction among different apparatuses have gradually become one of the core demands of users. In the existing technology, data exchange between atomization apparatuses usually relies on wired connection methods, such as communication through UART serial ports. Although this method is simple to implement, it has many limitations, such as the need to lay physical connection cables, vulnerable interfaces, and inconvenient plugging and unplugging. At the same time, in practical applications, if the connection is poor or a circuit break occurs, it is easy to cause data transmission failure, affecting user experience and product stability. SUMMARY The present application provides a method and a device for data transmission, and an atomization apparatus, so as to address above technical problems. A first aspect of embodiments of the present application provides a method for data transmission, applied to a first control module in a first atomization apparatus, the first control module is connected to a first short-range wireless communication module, and the method for data transmission includes: detecting whether a second atomization apparatus exists within a preset distance range through the first short-range wireless communication module; andif the second atomization apparatus is existed within the preset distance range, performing data communication with the second atomization apparatus through the first short-range wireless communication module. Optionally, the first control module includes a dormant state and an activated state, when the first control module is in the dormant state, after if the second atomization apparatus is existed within the preset distance range, the method further includes: receiving a wake-up signal output by the first short-range wireless communication module and switching from the dormant state to the activated state. Optionally, the first control module being in the dormant state includes: the first control module entering the dormant state when the first control module does not receive data sent by the first short-range wireless communication module within a preset time period. Optionally, the step of detecting whether the second atomization apparatus exists within the preset distance range through the first short-range wireless communication module includes: periodically sending a first card-seeking signal through the first short-range wireless communication module;determining that the second atomization apparatus exists within the preset distance range when a response signal or a second card-seeking signal sent by the second atomization apparatus is received; anddetermining that the second atomization apparatus does not exist within the preset distance range when the response signal or the second card-seeking signal sent by the second atomization apparatus is not received. Optionally, the step of performing data communication with the second atomization apparatus through the first short-range wireless communication module includes: sending first data to the first short-range wireless communication module, causing the first short-range wireless communication module to encode the first data to obtain a first data packet frame and send the first data packet frame to the second atomization apparatus. Optionally, the atomization apparatus further includes an user interaction module, and the step of sending the first data to the first short-range wireless communication module includes: receiving control information output by the user interaction module and sending a first control instruction to the first short-range wireless communication module. Optionally, the step of causing the first short-range wireless communication module to encode the first data to obtain the first data packet frame includes: causing the first short-range wireless communication module to encode the first data based on a modulation type and an encoding type to obtain the first data packet frame. Optionally, the first data packet frame includes a first frame start segment, a first data segment, and a first fr