CN117420906A - Vibration feedback method of electronic system and vibration feedback electronic system - Google Patents

Abstract

The vibration feedback method of the electronic system comprises the following steps: pairing an electronic device with a first wireless communication module and an input device with a second wireless communication module and a vibration feedback motor unit; inputting a control signal to the electronic device through the input device; and according to the control signal, a first wireless communication module of the electronic device is used for sending a wireless vibration signal to a second wireless communication module of the input device, and the second wireless communication module is used for directly driving the vibration feedback motor unit to vibrate according to the wireless vibration signal. The invention uses the second wireless communication module to replace the traditional extra motor driving chip, thereby simplifying the circuit layout of the input device and reducing the cost thereof.

Description

Vibration feedback method of electronic system and vibration feedback electronic system

Technical Field

The present invention relates to a vibration feedback method, and more particularly, to a vibration feedback method for an electronic system and a vibration feedback electronic system, in which an input device can drive a vibration motor without a motor driving chip.

Background

The vibration feedback system is widely applied to various electronic devices such as smart phones, tablets, notebook computers and desktop computers, and can provide corresponding vibration feedback for users through a vibration motor built in the input device according to instructions input to the electronic devices by the users through the input devices such as a mouse and a touch pen or according to output information presented by a user interface of the electronic devices, so that man-machine interaction between the users and the electronic devices is improved.

Conventional vibration Feedback (Haptic Feedback) techniques have a vibration motor control chip built into an input device, and further incorporate manufacturer specific vibration algorithms to provide Feedback from user interface on the electronic device 8 with display unit, such as error, click and touch Feedback. The advantage of this technique is the elasticity and consistency across systems and different vibration motors. However, the input device using the additional control chip increases power consumption of the input device, increases cost of the input device, and increases a circuit board layout within the input device, resulting in difficulty in lightening the volume of the input device. In addition, because of the general principles of vibrating wafers, the fine tuning of a particular vibrating motor product may not achieve the desired finesse.

Referring to fig. 1, a vibration feedback electronic system using the conventional vibration feedback technique includes an electronic device 8 and an input device 9. The electronic device 8 is provided with a bluetooth module 82 and an operating system 81. The input device 9 is a peripheral device such as a mouse or a stylus capable of inputting signals to the electronic device 8, and includes: a main control unit 91, a bluetooth module 92, a motor driving chip 93, and a vibration motor 94. The main control unit 91, the bluetooth module 92, the motor driving chip 93, and the vibration motor 94 are electrically connected to each other. In operation, the input device 9 and the electronic device 8 are coupled to each other via the two bluetooth modules 82 and 92, and then the input device 9 inputs a control signal to the electronic device 8 via the input device, and the two bluetooth modules 82 and 92 communicate according to the control signal, so that the input device 9 can receive a feedback signal from the operating system 81 via the two bluetooth modules 82 and 92. The bluetooth module 82, 92 of the input device 9 then commands the motor driver chip 93 to drive the vibration motor 94 according to the received feedback signal.

However, as described above, the motor driver chip 93 interposed between the bluetooth modules 82, 92 and the vibration motor 94 of the input device 9, while providing for cross-device and cross-system applications, the motor driver chip 93 increases the circuit layout and size of the input device 9 against the miniaturization of the input device 9, increases hardware costs, and lacks desirable fine tuning for a specific motor.

Disclosure of Invention

The present inventors have proposed a vibration feedback method for an electronic system and a vibration feedback electronic system according to the disadvantage that the input device of the existing vibration feedback electronic system must drive the vibration motor through a built-in motor driving chip.

The invention mainly aims to provide a vibration feedback method of an electronic system, which comprises the following steps:

the device pairing step comprises pairing an electronic device and an input device, wherein a first wireless communication module is arranged in the electronic device, a second wireless communication module and a vibration feedback motor unit electrically connected with the second wireless communication module are arranged in the input device, and the electronic device and the input device are mutually and wirelessly connected through the first wireless communication module and the second wireless communication module;

an operation step, including inputting a control signal to the electronic device through the input device; and

and a motor driving step, which comprises the steps of sending a wireless motor driving signal to a second wireless communication module of the input device by a first wireless communication module of the electronic device according to the control signal, generating a wired motor driving signal by the second wireless communication module according to the wireless motor driving signal, and directly transmitting the wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate.

In a preferred embodiment of the present invention, the first wireless communication module is a first bluetooth module, and the second wireless communication module is a second bluetooth module.

In a preferred embodiment of the present invention, the first wireless communication module is a first Wi-Fi module, and the second wireless communication module is a second Wi-Fi module.

In a preferred embodiment of the present invention, the second wireless communication module includes a wireless signal control unit, a memory, and a signal output unit, wherein the wireless signal control unit 51 is electrically connected to the memory and the signal output unit, and the signal output unit is connected to the vibration feedback motor unit.

In a preferred embodiment of the present invention, a motor vibration mode data unit is disposed in the signal output unit, and the motor driving step further comprises: according to the control signal, a first wireless communication module of the electronic device is used for sending a wireless motor driving signal to a second wireless communication module of the input device, the second wireless communication module generates a wired motor driving signal according to the wireless motor driving signal and the motor vibration mode data unit in the signal output unit, and the wired motor driving signal is directly transmitted to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate according to the vibration mode in the motor vibration mode data unit.

In a preferred embodiment of the present invention, a motor vibration mode data unit is provided in the memory, and the motor driving step further comprises: according to the control signal, a first wireless communication module of the electronic device sends out a wireless motor driving signal to a second wireless communication module of the input device, and the second wireless communication module calls the motor vibration mode data unit in the memory to generate a wired motor driving signal according to the wireless motor driving signal and the signal output unit, and directly sends out the wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate according to the vibration mode in the motor vibration mode data unit.

In a preferred embodiment of the present invention, an operating system is built in the electronic device; before the motor driving step, the electronic system vibration feedback method further comprises a vibration judging step, wherein the vibration judging step comprises the step of detecting whether triggering vibration information exists in the control signal by the operating system, and when the operating system detects the triggering vibration information, the first wireless Bluetooth module is driven to send out a wireless motor driving signal.

Another object of the present invention is to provide a vibration feedback electronic system, including:

the electronic device comprises a main control module, a first wireless communication module and an operating system, wherein the first wireless communication module is electrically connected with the main control module, and the operating system is connected with the main control module; and

the input device is used for being connected with the electronic device in a wireless way and inputting a control signal to the electronic device, and comprises a main control unit, a second wireless communication module and a vibration feedback motor unit, wherein the second wireless communication module is electrically connected with the main control unit and is used for being connected with the first wireless communication module in a wireless way so that the electronic device is connected with the input device in a wireless way, and the vibration feedback motor unit is electrically connected with the second wireless communication module and is used for vibrating the wired motor driving signal directly sent by the vibration feedback motor unit according to the second wireless communication module.

In a preferred embodiment of the present invention, the input device inputs a control signal to the electronic device; according to the control signal, the first wireless communication module of the electronic device sends a wireless motor driving signal to the second wireless communication module of the input device, and the second wireless communication module generates a wired motor driving signal according to the wireless motor driving signal and directly transmits the wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate.

In a preferred embodiment of the present invention, the first wireless communication module is a first bluetooth module, and the second wireless communication module is a second bluetooth module.

In a preferred embodiment of the present invention, the first wireless communication module is a first Wi-Fi module, and the second wireless communication module is a second Wi-Fi module.

In a preferred embodiment of the present invention, the second wireless communication module includes a wireless signal control unit, a memory, and a signal output unit, where the wireless signal control unit is electrically connected to the memory and the signal output unit, and the signal output unit is connected to the vibration feedback motor unit.

In a preferred embodiment of the present invention, a motor vibration mode data unit is disposed in the signal output unit, wherein when the vibration feedback electronic system is operated, the first wireless communication module of the electronic device sends a wireless motor driving signal to the second wireless communication module of the input device according to the control signal, and the second wireless communication module generates a wired motor driving signal according to the wireless motor driving signal and the motor vibration mode data unit in the signal output unit, and directly transmits the wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate according to the vibration mode in the motor vibration mode data unit.

In a preferred embodiment of the present invention, a motor vibration mode data unit is disposed in the memory, wherein when the vibration feedback electronic system is operated, the first wireless communication module of the electronic device sends out a wireless motor driving signal according to the second wireless communication module of the input device, and the second wireless communication module calls the motor vibration mode data unit in the memory to generate a wired motor driving signal according to the wireless motor driving signal and the signal output unit, and directly sends out a wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate according to the vibration mode in the motor vibration mode data unit.

In a preferred embodiment of the present invention, the operating system is configured to detect whether the trigger vibration information exists in the control signal, and when the operating system detects the trigger vibration information, the operating system drives the first wireless bluetooth module to send a wireless motor driving signal.

The invention has at least the following advantages:

1. the invention relates to a vibration feedback method of an electronic system and a vibration feedback electronic system, wherein the input device uses a second wireless communication module as a driver of a vibration feedback motor unit directly, so that an additional motor driving chip is omitted, the hardware circuit layout in the input device is simplified, the input device can be further reduced to achieve light weight, and the manufacturing cost of the input device is reduced.

2. The signal output unit or the memory in the second wireless communication module of the input device can be pre-stored or built with a motor vibration mode data unit, namely a motor vibration mode data table or a hardware circuit, wherein the motor vibration mode data table or the hardware circuit provides various vibration modes of the motor, such as high-frequency vibration, low-frequency vibration, continuous vibration, intermittent vibration or composite vibration combining the various vibrations. Alternatively, the motor vibration pattern data table or hardware circuit contains a vibration algorithm defining at least one relational equation covering the moving speed of the input device and the vibration frequency of the vibration feedback motor unit. By the technical scheme, the second wireless communication module can provide a plurality of fine motor effects, and one or more motor effects in the signal output unit or the memory can be started by the set software of the manufacturer before the input device leaves the factory.

Drawings

Technical solutions and other advantageous effects of the present application will be made apparent from the following detailed description of specific embodiments of the present application with reference to the accompanying drawings.

Fig. 1 is a schematic diagram of a conventional vibration feedback electronic system.

Fig. 2 is a flowchart illustrating steps of a vibration feedback method of an electronic system according to the present invention.

FIG. 3 is a block diagram of a vibration feedback electronic system according to the present invention.

Fig. 4 is a block diagram of a second wireless communication module according to an embodiment of the invention.

Fig. 5 is a block diagram of a second embodiment of a wireless communication module according to the present invention, wherein direct memory access (Direct Memory Access, DMA) technology is used.

Detailed Description

Referring to fig. 2 and 3, the present invention provides a vibration feedback method of an electronic system and a vibration feedback electronic system, which are described in detail below.

Referring to fig. 3, the vibration Feedback (Feedback) method of the electronic system of the present invention includes: a device pairing step S01, an operation step S02, and a motor driving step S04.

The device pairing step S01 includes pairing an electronic device 1 and an input device 2, wherein a first wireless communication module 20 is disposed in the electronic device 1, a second wireless communication module 50 and a vibration feedback motor unit 60 electrically connected to the second wireless communication module 50 are disposed in the input device 2, and the electronic device 1 and the input device 2 are mutually connected and paired wirelessly through the first wireless communication module 20 and the second wireless communication module 50.

In addition, the electronic device 1 may be a smart phone, a tablet computer, a desktop computer, a notebook computer, etc. The input device 2 may be one of a stylus, a mouse, a joystick, a game controller, a wristwatch, a wristband, a glove, and a ring.

The operation step S02 includes inputting a control signal to the electronic device 1 through the input device 2. In a preferred embodiment, the control signal includes at least one control command for controlling the electronic device. For example, when the electronic device 1 is a tablet computer and the input device is a stylus, the manipulation command of the manipulation signal may include: the tablet computer screen is enabled to sense the cursor moving or moving speed of the touch pen, or the pen pressure information of the touch pen, or the tablet computer is enabled to set the touch pen type to be different pen touch modes such as a pencil, a microphone pen, a pen … and the like and different vibration feedback modes. .

The motor driving step S04 includes sending a wireless motor driving signal to the second wireless communication module 50 of the input device 2 by the first wireless communication module 20 of the electronic device 1 according to the control signal, wherein the second wireless communication module 50 generates a wired motor driving signal according to the wireless motor driving signal, and directly transmits the wired motor driving signal to the vibration feedback motor unit 60 to directly drive the vibration feedback motor unit 60 to vibrate.

In a preferred embodiment of the present invention, the touch device

In the preferred embodiment of the present invention, the first wireless communication module 20 is a first bluetooth module, and the second wireless communication module 50 is a second bluetooth module.

In the preferred embodiment of the present invention, the first wireless communication module 20 is a first Wi-Fi module, and the second wireless communication module 50 is a second Wi-Fi module. The Wi-Fi module is a wireless communication module conforming to the institute of Electrical and electronics Engineers (Institute of Electronic and Electronics Engineers, IEEE) 802.11 protocol standard. The IEEE802.11 protocol standard may include: IEEE802.11 a, IEEE802.11b, IEEE802.11 n, IEEE802.11 ac, IEEE802.11 ax, etc.

In the preferred embodiment of the present invention, the second wireless communication module 50 includes a wireless signal control unit 51, a memory 52, and a signal output unit 53, wherein the wireless signal control unit 51 is electrically connected to the memory 52 and the signal output unit 53, and the signal output unit 53 is connected to the vibration feedback motor unit 60.

Referring to fig. 4, in the preferred embodiment of the present invention, a motor vibration mode data unit 500 is disposed in the signal output unit 53, and the motor driving step S04 further includes: according to the control signal, the first wireless communication module 20 of the electronic device 1 sends a wireless motor driving signal to the second wireless communication module 50 of the input device 2, and the second wireless communication module 50 generates a wired motor driving signal according to the wireless motor driving signal and the motor vibration mode data unit 500 in the signal output unit 53, and directly transmits the wired motor driving signal to the vibration feedback motor unit 60 to directly drive the vibration feedback motor unit 60 to vibrate according to the vibration mode in the motor vibration mode data unit 500. In this embodiment, the motor vibration mode data unit 500 may be a data table or a hardware circuit built in the signal output unit 53.

Referring to fig. 5, in the preferred embodiment of the present invention, a motor vibration mode data unit 500 is disposed in the memory 52, and the motor driving step S04 further includes: according to the control signal, the first wireless communication module 20 of the electronic device 1 sends out a wireless motor driving signal to the second wireless communication module 50 of the input device 2, and the second wireless communication module 50 invokes the motor vibration mode data unit 500 in the memory 52 to generate a wired motor driving signal according to the wireless motor driving signal and the signal output unit 53, and directly sends out a wired motor driving signal to the vibration feedback motor unit 60 to directly drive the vibration feedback motor unit 60 to vibrate according to the vibration mode in the motor vibration mode data unit 500. The motor vibration mode data unit 500 of fig. 5 is called up by using the direct memory 52 access (Direct Memory Access, DMA) technique, in other words, the signal output unit 53 takes the motor vibration mode data unit 500 from the memory 52.

In the preferred embodiment of the present invention, an operating system 30 is built in the electronic device 1; before the motor driving step S04, the vibration feedback method of the electronic system further includes a vibration determining step S03, the vibration determining step S03 includes detecting the presence of the trigger vibration information in the control signal by the operating system 30 and driving the first wireless bluetooth module to send a wireless motor driving signal according to the related control signal command, such as the moving cursor or moving speed of the stylus, or the stylus pressure information, or setting the stylus type to be different corresponding to the touch of the pen such as pencil, microphone, pen …, etc., when the operating system 30 detects the trigger vibration information. In addition, the operating system 30 may be software.

Referring to fig. 3, the vibration feedback electronic system of the present invention includes: an electronic device 1 and an input device 2.

The electronic device 1 includes a main control module 10, a first wireless communication module 20, and an operating system 30.

The main control module 10 may include a processor, a memory, and an input device sensing unit. The input device sensing unit may be configured to receive, parse, and convert signals from the input device 2.

The first wireless communication module 20 is electrically connected to the main control module 10.

The operating system 30 is connected to the main control module 10. In addition, the operating system 30 may be software.

The input device 2 is used for wirelessly connecting the electronic device 1 and inputting a control signal to the electronic device 1, and comprises a main control unit 40, a second wireless communication module 50, and a vibration feedback motor unit 60. The main control unit 40 is used for controlling the operation of the input device 2, and may include a processor, a memory, and a sensing signal output unit. The sensing signal output unit is used for outputting a sensing signal to the electronic device 1. The second wireless communication module 50 is electrically connected to the main control unit 40 and is used for being wirelessly connected to the first wireless communication module 20 so that the electronic device 1 is wirelessly connected to the input device 2, and the vibration feedback motor unit 60 is electrically connected to the second wireless communication module 50 and is used for vibrating the wired motor driving signal directly sent by the vibration feedback motor unit 60 according to the second wireless communication module 50.

In the preferred embodiment of the present invention, the input device 2 inputs a control signal to the electronic device 1; according to the control signal, the first wireless communication module 20 of the electronic device 1 sends a wireless motor driving signal to the second wireless communication module 50 of the input device 2, and the second wireless communication module 50 generates a wired motor driving signal according to the wireless motor driving signal and directly transmits the wired motor driving signal to the vibration feedback motor unit 60 to directly drive the vibration feedback motor unit 60 to vibrate.

In the preferred embodiment of the present invention, the first wireless communication module 20 is a first bluetooth module, and the second wireless communication module 50 is a second bluetooth module.

In the preferred embodiment of the present invention, the first wireless communication module 20 is a first Wi-Fi module, and the second wireless communication module 50 is a second Wi-Fi module.

In the preferred embodiment of the present invention, the second wireless communication module 50 includes a wireless signal control unit 51, a memory 52, and a signal output unit 53, wherein the wireless signal control unit 51 is electrically connected to the memory 52 and the signal output unit 53, and the signal output unit 53 is connected to the vibration feedback motor unit 60.

Referring to fig. 4, in the preferred embodiment of the present invention, a motor vibration mode data unit 500 is disposed in the signal output unit 53, wherein when the vibration feedback electronic system is operated, the first wireless communication module 20 of the electronic device 1 sends a wireless motor driving signal to the second wireless communication module 50 of the input device 2 according to the control signal, and the second wireless communication module 50 generates a wired motor driving signal according to the wireless motor driving signal and the motor vibration mode data unit 500 in the signal output unit 53, and directly transmits the wired motor driving signal to the vibration feedback motor unit 60 to directly drive the vibration feedback motor unit 60 to vibrate according to the vibration mode in the motor vibration mode data unit 500. In this embodiment, the motor vibration mode data unit 500 may be a data table or a hardware circuit built in the signal output unit 53.

Referring to fig. 5, in the preferred embodiment of the present invention, a motor vibration mode data unit 500 is disposed in the memory 52, wherein when the vibration feedback electronic system is operated, the first wireless communication module 20 of the electronic device 1 sends out a wireless motor driving signal according to the second wireless communication module 50 of the input device 2, and the second wireless communication module 50 calls the motor vibration mode data unit 500 in the memory 52 to generate a wired motor driving signal according to the wireless motor driving signal and the signal output unit 53, and directly sends out a wired motor driving signal to the vibration feedback motor unit 60 to directly drive the vibration feedback motor unit 60 to vibrate according to the vibration mode in the motor vibration mode data unit 500. The motor vibration mode data unit 500 of fig. 5 is called up by using the direct memory 52 access (Direct Memory Access, DMA) technique, in other words, the signal output unit 53 takes the motor vibration mode data unit 500 from the memory 52.

In a preferred embodiment of the present invention, the operating system 30 is configured to detect whether the trigger vibration information exists in the control signal, and when the operating system 30 detects the trigger vibration information, the first wireless bluetooth module is driven to send a wireless motor driving signal.

1. In the vibration feedback method and the vibration feedback electronic system of the present invention, the second wireless communication module 50 is directly used as the driver of the vibration feedback motor unit 60 in the input device 2, so that an additional motor driving chip is omitted, the hardware circuit layout in the input device 2 is simplified, the input device 2 can be further reduced to achieve light weight, and the manufacturing cost of the input device 2 is reduced.

2. The signal output unit 53 or the memory 52 of the second wireless communication module 50 of the input device 2 of the present invention may be pre-stored or built with a motor vibration mode data unit 500, i.e. a motor vibration mode data table or a hardware circuit, which provides various vibration modes of the motor, such as high frequency vibration, low frequency vibration, continuous vibration, intermittent vibration, or a composite vibration combining the above-mentioned various vibrations. Alternatively, the motor vibration pattern data table or hardware circuit contains a vibration algorithm defining at least one relational equation covering the moving speed of the input device 2 and the vibration frequency of the vibration feedback motor unit 60. By the above technical solution, the second wireless communication module 50 can provide a plurality of fine motor effects, and one or more motor effects in the signal output unit 53 or the memory 52 can be activated by the manufacturer's setting software before the input device 2 leaves the factory.

Claims (15)

1. An electronic system vibration feedback method, comprising:

the device pairing step comprises pairing an electronic device and an input device, wherein a first wireless communication module is arranged in the electronic device, a second wireless communication module and a vibration feedback motor unit electrically connected with the second wireless communication module are arranged in the input device, and the electronic device and the input device are mutually and wirelessly connected with each other through the first wireless communication module and the second wireless communication module;

an operation step, including inputting a control signal to the electronic device through the input device; and

and a motor driving step, which comprises the steps of sending a wireless motor driving signal to a second wireless communication module of the input device by a first wireless communication module of the electronic device according to the control signal, generating a wired motor driving signal by the second wireless communication module according to the wireless motor driving signal, and directly transmitting the wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate.

2. The vibration feedback method of claim 1, wherein the first wireless communication module is a first bluetooth module and the second wireless communication module is a second bluetooth module.

3. The vibration feedback method of claim 1, wherein the first wireless communication module is a first Wi-Fi module and the second wireless communication module is a second Wi-Fi module.

4. The vibration feedback method of claim 1, wherein the second wireless communication module comprises a wireless signal control unit, a memory, and a signal output unit, the wireless signal control unit is electrically connected to the memory and the signal output unit, and the signal output unit is connected to the vibration feedback motor unit.

5. The method of claim 4, wherein a motor vibration mode data unit is disposed in the signal output unit, and the motor driving step further comprises: according to the control signal, a first wireless communication module of the electronic device is used for sending a wireless motor driving signal to a second wireless communication module of the input device, the second wireless communication module generates a wired motor driving signal according to the wireless motor driving signal and the motor vibration mode data unit in the signal output unit, and the wired motor driving signal is directly transmitted to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate according to the vibration mode in the motor vibration mode data unit.

6. The method of claim 4, wherein a motor vibration mode data unit is provided in the memory, and the motor driving step further comprises: according to the control signal, a first wireless communication module of the electronic device sends out a wireless motor driving signal to a second wireless communication module of the input device, and the second wireless communication module calls the motor vibration mode data unit in the memory to generate a wired motor driving signal according to the wireless motor driving signal and the signal output unit, and directly sends out the wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate according to the vibration mode in the motor vibration mode data unit.

7. The method of claim 1, wherein an operating system is built in the electronic device; before the motor driving step, the electronic system vibration feedback method further comprises a vibration judging step, wherein the vibration judging step comprises the step of detecting whether triggering vibration information exists in the control signal by the operating system, and when the operating system detects the triggering vibration information, the first wireless Bluetooth module is driven to send out a wireless motor driving signal.

8. A vibration feedback electronic system, comprising:

the electronic device comprises a main control module, a first wireless communication module and an operating system, wherein the first wireless communication module is electrically connected with the main control module, and the operating system is connected with the main control module; and

the input device is used for being connected with the electronic device in a wireless way and inputting a control signal to the electronic device, and comprises a main control unit, a second wireless communication module and a vibration feedback motor unit, wherein the second wireless communication module is electrically connected with the main control unit and is used for being connected with the first wireless communication module in a wireless way so that the electronic device is connected with the input device in a wireless way, and the vibration feedback motor unit is electrically connected with the second wireless communication module and is used for vibrating the wired motor driving signal directly sent by the vibration feedback motor unit according to the second wireless communication module.

9. The vibration feedback electronic system according to claim 8, wherein the input device inputs a control signal to the electronic device; according to the control signal, the first wireless communication module of the electronic device sends a wireless motor driving signal to the second wireless communication module of the input device, and the second wireless communication module generates a wired motor driving signal according to the wireless motor driving signal and directly transmits the wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate.

10. The vibration feedback electronic system of claim 8, wherein the first wireless communication module is a first bluetooth module and the second wireless communication module is a second bluetooth module.

11. The vibration feedback electronic system of claim 8, wherein the first wireless communication module is a first Wi-Fi module and the second wireless communication module is a second Wi-Fi module.

12. The vibration feedback electronic system according to claim 8, wherein the second wireless communication module comprises a wireless signal control unit, a memory, and a signal output unit, the wireless signal control unit is electrically connected to the memory and the signal output unit, and the signal output unit is connected to the vibration feedback motor unit.

13. The system of claim 12, wherein a motor vibration mode data unit is disposed in the signal output unit, wherein when the system is operated, the first wireless communication module of the electronic device sends a wireless motor driving signal to the second wireless communication module of the input device according to the control signal, and the second wireless communication module generates a wired motor driving signal according to the wireless motor driving signal and the motor vibration mode data unit in the signal output unit, and directly transmits the wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate according to the vibration mode in the motor vibration mode data unit.

14. The vibration feedback electronic system according to claim 12, wherein a motor vibration mode data unit is disposed in the memory, wherein when the vibration feedback electronic system is operated, the first wireless communication module of the electronic device sends out a wireless motor driving signal according to the second wireless communication module of the input device, and the second wireless communication module calls the motor vibration mode data unit in the memory to generate a wired motor driving signal according to the wireless motor driving signal and the signal output unit, and directly sends out a wired motor driving signal to the vibration feedback motor unit to directly drive the vibration feedback motor unit to vibrate according to the vibration mode in the motor vibration mode data unit.

15. The vibration feedback electronic system of claim 8, wherein the operating system is configured to detect the presence of the trigger vibration information in the control signal, and to drive the first wireless bluetooth module to send a wireless motor driving signal when the operating system detects the trigger vibration information.