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CN-122018721-A - Multidimensional composite input control method and intelligent watch applying same

CN122018721ACN 122018721 ACN122018721 ACN 122018721ACN-122018721-A

Abstract

The embodiment of the invention provides a multidimensional composite input control method and an intelligent watch applying the same, and the method comprises the following steps of S1, monitoring pulse signals generated by a first input source in real time, monitoring trigger states of a second input source and a third input source, S2, performing time domain analysis on the pulse signals of the first input source, if the duration time of the pulse signals under an effective level is monitored to be smaller than a preset time threshold value, configuring the pulse signals as step signals, and S4, generating a state switching instruction according to the combination states of the resident signals and the second input source or the third input source. Relates to the field of intelligent diving watches. By dividing the pulse signal of the first input source into a stepping signal and a residence signal, the single rotary structure has at least two input modes, the input dimension is improved, and an additional hardware sensor is not required to be added.

Inventors

  • WU GUANGXIONG
  • ZHENG CONG

Assignees

  • 广东多美达智能终端有限公司

Dates

Publication Date
20260512
Application Date
20260129

Claims (10)

  1. 1. The multidimensional composite input control method is characterized by comprising the following steps of: S1, monitoring pulse signals generated by a first input source in real time, and monitoring trigger states of a second input source and a third input source; S2, carrying out time domain analysis on the pulse signal of the first input source, and if the duration time of the pulse signal under the effective level is monitored to be smaller than a preset time threshold value, configuring the pulse signal as a stepping signal; If the duration of the pulse signal under the effective level is monitored to be greater than or equal to the time threshold value, the pulse signal is configured to be a stay signal; S3, performing primary processing on the step signal according to the states of the second input source and the third input source to generate an adjusting instruction with directivity; s4, generating a state switching instruction according to the combination state of the resident signal and the second input source or the third input source.
  2. 2. The method according to claim 1, wherein the primary processing in step S3 specifically includes defining the adjustment command as a forward increment or page up when the second input source is detected to be in a triggered state and the step signal is received at the same time; when the third input source is monitored to be in a triggered state and the stepping signal is received at the same time, defining the regulating instruction as reversely decrement or page down; When the second input source or the third input source is not monitored to be triggered, the regulating instruction is defined as unidirectional cyclic switching.
  3. 3. The multi-dimensional composite input control method of claim 1, wherein in a locked state, none of the step signal, the dwell signal, or the single touch signal triggers a state switch; The unlocking process is that the resident signal is triggered through rotation operation, and when the second input source is detected to be triggered in the period of maintaining the resident signal, an unlocking instruction or an entering instruction is generated.
  4. 4. The multi-dimensional composite input control method according to claim 1, wherein whenever the pulse signal of the first input source is monitored to jump in level to enter an effective state, the vibration unit is immediately driven to generate short navigation vibration, so that a user is prompted to be currently located at a resident position; If the pulse signal is kept unchanged in a preset window period after the navigation vibration is generated, automatic accumulation timing is performed to trigger the resident signal.
  5. 5. The method according to claim 1, wherein the method is further configured to calculate a duty ratio of the pulse signal if the pulse signal is monitored to be dithered between an active level and an inactive level during the determination of the resident signal; if the duty ratio is higher than a preset value, the system forcedly judges that the first input source is still in an effective contact state, and maintains the operation of a timer until an explicit displacement signal is monitored.
  6. 6. The multi-dimensional composite input control method of claim 1, wherein the monitoring of the second input source and the third input source is configured such that the system reads the background conductivity between the two input sources in real time, establishing a dynamic reference value; And only when the monitored change rate of the electric signal exceeds the abrupt change threshold set based on the dynamic reference value, confirming effective human touch triggering so as to filter false touch signals caused by water body conductivity.
  7. 7. The method according to claim 1, wherein when the first input source is monitored to continuously generate more than a preset number of step signals within a preset time period and no resident signal and trigger signals of the second and third input sources are detected during the period, the system automatically triggers a highlight-help mode or resets to a safety default setting when abnormal operation of the user is determined.
  8. 8. A smart watch, characterized in that the smart watch is applied to the multi-dimensional composite input control method of any one of claims 1to 7, and comprises a bottom shell assembly (1), a touch unit (2), a driving ring (3) and a transmission unit (4); the touch unit (2) comprises a touch screen and a shell; the bottom shell assembly (1) is connected with the shell, and the driving ring (3) is arranged on the outer side of the shell and is rotationally connected with the shell; the drive ring (3) is used for triggering the transmission unit (4); The bottom shell assembly (1) comprises a protective shell (11), a first contact end (15), a second contact end (16) and a circuit board (12); the circuit board (12) is connected to the protective shell (11), and the first contact end (15) and the second contact end (16) are connected with the circuit board (12) and are arranged on the side wall of the protective shell (11).
  9. 9. The intelligent watch according to claim 8, characterized in that a gear ring is arranged below the driving ring (3), the transmission unit (4) comprises a first gear (43), a first shell (44) and a first bracket (45), and further comprises a recording unit (5), and the recording unit (5) comprises a wheel body (51), a spring piece (52), a clamping part (53), an extension part (521) and a contact switch (54); The first gear (43) is meshed with the gear ring below the driving ring (3), the first gear (43) is connected with the first shell (44), the first shell (44) is rotationally connected with the first support (45), the wheel body (51) is connected with the first shell (44), a plurality of notches (511) are annularly and equidistantly arranged on the outer wall of the wheel body (51), the clamping parts (53) can be clamped in the corresponding notches (511), the clamping parts (53) are arranged on the elastic pieces (52), the extending parts (521) are arranged on the elastic pieces (52), and the tail ends of the extending parts (521) correspond to the contact ends of the contact switches (54); When the clamping part (53) is not contacted with the notch (511) on the wheel body (51), the extension part (521) is contacted with the contact switch (54).
  10. 10. The smart watch according to claim 9, wherein the bottom case assembly (1) further comprises a battery (13), a pressure sensor (17), a vibration unit (14) and a magnetic charging head (18); The battery (13), the pressure sensor (17), the vibration unit (14) and the magnetic charging head (18) are arranged on the protective shell (11), and the pressure sensor (17) is used for identifying the pressure value of the environment where the intelligent watch is located.

Description

Multidimensional composite input control method and intelligent watch applying same Technical Field The invention relates to the field of intelligent diving watches, in particular to a multidimensional compound input control method and an intelligent watch applying the same. Background The conventional intelligent watch generally adopts a touch screen as a main interaction mode, and is assisted with a button or a rotary input structure to perform interface switching and function control. However, when such a device is used in a diving environment, due to the existence of factors such as water conduction, screen wetting, wearing of gloves by a wearer, external water pressure and the like, the conventional touch input mode has the problems of low recognition rate, high false touch probability, no directivity, difficulty in executing confirmation operation and the like, and is difficult to meet the operation requirement in the diving scene. In order to reduce false touches, some diving watches use physical buttons to replace touch input, but the number of buttons is limited, the input dimension is low, and the simple operations such as one-way page turning or single-step switching can only be realized, and compound interactions such as multi-layer menus, mode switching or numerical adjustment cannot be supported. In addition, the physical buttons have the problem that the water pressure change in the deep water environment causes the button stroke change, and the deep-diving gloves further reduce the sensitivity of button triggering. Some devices attempt to input by using a rotating ring structure, but such structures generally only output non-directional pulse signals, and rely on additional hall sensors, angle encoders or magnetic sensing modules to identify directionality, which increases cost and complexity, and still makes it difficult to execute confirmation or locking instructions. In summary, the prior art still lacks an interactive mode capable of realizing low false touch, direction determination, executable residence confirmation, supporting mode switching and no complex sensor structure in a diving environment, and particularly lacks a control method for realizing multidimensional interaction by combining rotation input, touch input and residence signals. Disclosure of Invention According to the embodiment of the invention, a multi-dimensional composite input control method and a smart watch applying the same are provided. Is used for solving the technical problems in the background art. In a first aspect of the present invention, a multi-dimensional composite input control method and a smart watch using the same are provided. The multidimensional composite input control method comprises the following steps: S1, monitoring pulse signals generated by a first input source in real time, and monitoring trigger states of a second input source and a third input source; S2, carrying out time domain analysis on the pulse signal of the first input source, and if the duration time of the pulse signal under the effective level is monitored to be smaller than a preset time threshold value, configuring the pulse signal as a stepping signal; If the duration of the pulse signal under the effective level is monitored to be greater than or equal to the time threshold value, the pulse signal is configured to be a stay signal; S3, performing primary processing on the step signal according to the states of the second input source and the third input source to generate an adjusting instruction with directivity; s4, generating a state switching instruction according to the combination state of the resident signal and the second input source or the third input source. Preferably, the first stage processing in step S3 specifically includes defining the adjustment instruction as a forward increment or page up when the second input source is detected to be in a triggered state and the step signal is received at the same time; when the third input source is monitored to be in a triggered state and the stepping signal is received at the same time, defining the regulating instruction as reversely decrement or page down; When the second input source or the third input source is not monitored to be triggered, the regulating instruction is defined as unidirectional cyclic switching. Preferably, in the locked state, none of the step signal, the dwell signal, or the single touch signal triggers a state switch; The unlocking process is that the resident signal is triggered through rotation operation, and when the second input source is detected to be triggered in the period of maintaining the resident signal, an unlocking instruction or an entering instruction is generated. Preferably, when the pulse signal generation level jump of the first input source is monitored to enter an effective state, the vibration unit is immediately driven to generate short navigation vibration, and the user is prompted to be at a resident position; If