TWM601419U - A wireless electronic with external gas pipe press-response system - Google Patents

Abstract

A wireless electronic with external gas pipe press-response system includes a press device and a data processing device. The pressing device comprises a flexible hollow shell, an electronic module including a circuit board, a switch, a controller, a pressure sensor, a wireless signal transmission module, a battery, a power port, and a gas pipe for connecting the flexible hollow shell and the pressure sensor of the electronic module. The pressure sensor comprises a pressure sensor vent port which is connected with the inner space of the flexible hollow shell through a gas pipe. When the user presses the flexible hollow shell to increase the internal gas pressure of the flexible hollow shell, the pressure sensor senses the variation signal related to the internal gas pressure of the flexible hollow shell through the air pipe and the vent port of the pressure sensor, and the controller transmits the user's pressing signal through the wireless signal transmission module. The time point for the user to press and relax is when the user cooperates with the application (APP) of the external mobile phone or computer. The data processing device receives the press signal sent by the press device, compares the start and end time of the press signal with the target trigger time in the application program (APP) of the mobile phone or computer, displays the result in the form of text, chart, animation, etc., and plays music, voice and other messages by the broadcast module. The wireless electronic with external gas pipe press-response system can play music information through the application program (APP) in the data processing device during operation, and the press device is equipped with a vibration module to increase the use sensitivity of the operator.

Description

Wireless electronic external tracheal compression response system

The present invention relates to a wireless electronic external tracheal pressure response system, in particular to an application program (APP) that is played by a broadcasting module and a display shows a moving image of the expected rhythm. The operator uses a flexible shell of a pressing device with a simple structure. The body cooperates with the moving image and music of the running application (APP) to perform repeated pressing and relaxing actions. The pressure sensor detects the pressure change in the flexible housing of the pressing device, and the pressure signal and time of the pressure change The switch signal is transmitted to the data processing device through wireless transmission; the data processing device compares the correctness of the user's pressing and relaxing action time points with the expected target time points of the application (APP), and matches text, graphics, animation, music or language The correct rate of the two signals compared is displayed on the broadcast module and display; the new model can be used in games, sensory integration training or mental rehabilitation and other fields to achieve game play, sensory coordination training, stroke and dementia The purpose of disease prevention and rehabilitation.

The intelligence and sensory integration training of young children and the prevention and rehabilitation of diseases of the elderly caused by mental degeneration are always the main issues of human health; The brain is the main axis. It takes external sensory input and movement learning, and coordinates the sensory integration of the body's senses and movements through the brain. It is aimed at young children and actively cultivates the ability of sensory integration. For the elderly or patients with sensory diseases, it strives to find humans. Basic integration capabilities.

The training direction of sensory integration ability is divided into vestibular sense, proprioception, touch, vision, hearing, smell and taste, etc.; there are also various sensory integration education teaching designed for children, the elderly, stroke or dementia patients at home and abroad. Or rehabilitation teaching aids, but the current design of related products tends to be singular, repetitive and uninteresting. It is less likely to resonate with children or the elderly or patients with diseases have long-term consistent training, resulting in limited education or rehabilitation effects.

The design is light and easy to carry, easy to learn and interesting, training record data storage and active guidance are the basic requirements for users to succeed. Regarding the prior art of the wireless electronic external tracheal compression response system, there are some traditional training equipment, but such equipment is monotonous and repetitive, and there is no automatic training recording or the use of wireless transmission technology to transmit training data to the remote training instructor in real time Or a co-training partner. There are also some training equipment designs, although there are additional devices such as wireless devices, but the design is complex and does not integrate with existing mobile phones and other systems, and their functions are many and limited.

In addition, when operating the system, the user will use the human body to apply force to the flexible housing, such as hands, feet, or abdomen to apply pressure to the flexible housing; the surface of the flexible housing is designed with The bumps that stimulate the human nerves. When the human body is subjected to the reaction force of the flexible shell, it is also pierced by the bumps on the human nerves. Excite, enhance the effectiveness of activating nerves. However, the prior art design does not design the pressing element with bumps in the system, and the use effect is relatively insignificant.

In addition, the similar pressing system of the prior art does not have the function of assisting the user to operate the training by himself; the peripheral module of this system is equipped with vibrators and other devices, and receives the application program (APP) feedback signal of the data processing device to generate vibration, which can make The user further feels the feedback of the system to the user during the sensory integration training process. For example, the user presses force with the signal of an application program (APP). When the user presses correctly, the pressing device generates vibration feedback to improve the user's perception effect.

Therefore, one of the technical problems to be solved by the present invention is to provide a wireless electronic external tracheal pressure response system. According to the new wireless electronic external tracheal pressure response system, its structure is simple, it can be operated with common devices such as mobile phones, it is designed for the characteristics of human nerve stimulation, and the feedback perception guiding device is easy for users to operate, and it is interesting to cooperate with applications (APP) The guidance and records of the user can fully improve the user’s lack of interest or limited training effectiveness.

A wireless electronic external tracheal pressure response system according to a preferred embodiment of the present invention includes a pressing device and a data processing device. The pressing device includes a flexible shell, the surface of the flexible shell is attached with bumps, the shell cover, the shell cover has a tracheal joint and is provided with air holes to communicate the internal space of the flexible shell with the outside, and the electronic module is installed in the flexible shell. The outside of the flexible housing includes a pressure sensor, a pressure sensor vent hole and a pressure sensor vent pipe on the pressure sensor, and the first wireless communication No. transmission module, battery, power switch, switch button, power port, power port interface, controller, circuit board, peripheral module. The pressing device is provided with a trachea to connect the flexible housing and the pressure sensor of the electronic module. The pressure sensor includes a pressure sensor vent and a pressure sensor vent pipe. The pressure sensor is electrically fixed on the circuit board. The pressure sensor vent pipe connects the pressure sensor and the pressure sensor vent The vent of the pressure sensor is connected to the second orifice of the trachea through the trachea to the first orifice of the trachea to connect to the vent and communicate with the inner space of the flexible housing to form a gas passage. The pressure sensor is electrically connected to the controller; the first wireless signal transmission module is electrically fixed on the circuit board and electrically connected to the controller. The peripheral module may include components such as a vibrator, which are electrically fixed on the circuit board and electrically connected to the controller, and can receive signals to cause the pressing device to generate a vibration response. The data processing device includes a storage module, a broadcasting module, a second wireless signal transmission module, a display, and at least one processor. The storage module stores therein a press response application (APP). At least one processor is electrically connected to the storage module, the broadcasting module, the display, and the second wireless signal transmission module, respectively. The user operates the data processing device to execute a press-responsive application (APP) through at least one processor, and selects one execution information from a plurality of preset press-responsive application (APP) information. When the operator presses and applies force to the flexible housing, the gas inside the flexible housing flows through the pressure sensor vent pipe through the air hole, trachea, and pressure sensor vent on the pressure sensor. Therefore, the pressure sensor can sense the pressure signal about the gas, and send the pressing and releasing pressure signal and the time switch signal through the first wireless signal transmission module. Capital At least one processor of the material processing device receives the pressure signal and the time switch signal through the second wireless signal transmission module. At least one processor compares the target signal of the selected press response application (APP) with the received pressure signal and time switch signal, and displays the time difference between the two signals in the form of text, pattern, animation, music or language on the display, Broadcast module.

In a specific embodiment, the wireless electronic external tracheal pressure response system according to the present invention further includes: at least one processor of the data processing device receives the pressure signal and the time switch signal and the selected pressure response application via the second wireless signal transmission module Program (APP) target signal comparison, and the time difference message between the two signals is transmitted to the first wireless signal transmission module through the second wireless signal transmission module, and then the controller of the pressing device converts the time difference message between the two signals The peripheral module control signals are used to control and drive peripheral module components, such as vibration motors, to increase the operator’s perception of feedback messages.

In a specific embodiment, the pressure sensor of the pressing device of the wireless electronic external tracheal pressing response system according to the present invention is arranged outside the flexible housing.

In a specific embodiment, the pressing device of the wireless electronic external tracheal pressing response system according to the present invention further includes a battery. The battery is arranged outside the flexible casing and electrically connected to the circuit board to supply the power required by the pressure sensor, the controller, the peripheral module, and the first wireless signal transmission module during operation.

In a specific embodiment, the wireless electronic external device according to the present invention The pressure device of the airway pressure response system also includes a power port. The power port is arranged outside the flexible casing and can be electrically connected to an external power source through the power port interface. The power port is electrically connected to the circuit board and the battery, and is used as a battery charging or external power supply to supply the power required by the pressure sensor, the controller, the peripheral module, and the first wireless signal transmission module during operation.

In a specific embodiment, the first wireless signal transmission module of the wireless electronic external tracheal pressure response system according to the present invention transmits the pressure signal and the time switch signal through a wireless communication protocol. The wireless communication protocol can be Wi-Fi protocol, WiMAX protocol, IEEE 802.11 series protocol (IEEE 802.11-based protocols), 3G network protocol, 4G network protocol, 5G network protocol, HSPA network protocol, LTE network protocol, Bluetooth protocol (Bluetooth protocol), or other commercial wireless communication protocols.

In a specific embodiment, the storage module of the data processing device of the wireless electronic external tracheal pressure response system according to the present invention also stores a plurality of corresponding pressure response applications (APP). The user selects a program to execute from a plurality of preset sub-programs by pressing a response application (APP).

In a specific embodiment, according to the storage module of the data processing device of the wireless electronic external tracheal pressure response system of the present invention, the learning and training application program and the storage use record information are also stored in it.

Different from the prior art, the wireless electronic external tracheal pressure response system according to the present invention has a simple structure, sensitive pressure sensing, and easy software updating through cloud technology. According to the new wireless electronic external tracheal pressing sound The application system allows users to achieve sensory integration training and functional rehabilitation in the game, and can assist users in training and recording training results.

The advantages and spirit of the invention can be further understood by the following detailed description of the novel and the accompanying drawings.

1: Wireless electronic external tracheal compression response system

2: pressing device

21: Flexible shell

211: bump

22: Shell cover

23: Electronic module

231: Pressure Sensor

231a: Pressure sensor vent port

231b: Pressure sensor snorkel

232: The first wireless signal transmission module

233: Battery

234: Power switch

234a: switch button

235: power port

235a: power port interface

236: Controller

237: Circuit Board

238: Peripheral Module

24: Trachea connector

25: Stoma

25a: First orifice of stoma

25b: The second orifice of the stoma

26: trachea

26a: First orifice of trachea

26b: Second orifice of trachea

3: Data processing device

32: storage module

34: Broadcast module

36: The second wireless signal transmission module

38: processor

39: display

Fig. 1 is an external view of a wireless electronic external tracheal pressure response system according to a preferred embodiment of the present invention.

FIG. 2 is an internal view of the flexible housing of the pressing device, which is an essential component of the wireless electronic external tracheal pressing response system in FIG. 1. FIG.

FIG. 3 is a view of the circuit board combination component of the pressing device, one of the necessary components of the wireless electronic external tracheal pressure response system in FIG. 1.

Fig. 4 is a functional block diagram of a wireless electronic external tracheal pressure response system according to a preferred embodiment of the present invention.

Please refer to Figure 1, Figure 2, Figure 3 and Figure 4, which schematically depict a wireless electronic external tracheal pressure response system 1 according to a preferred embodiment of the present invention. Fig. 1 is an external view of a wireless electronic external tracheal pressure response system 1 according to a preferred embodiment of the present invention. FIG. 2 is an internal view of the flexible housing of the pressing device, which is an essential component of the wireless electronic external tracheal pressing response system in FIG. 1. FIG. FIG. 3 is a view of the circuit board combination component of the pressing device, one of the necessary components of the wireless electronic external tracheal pressure response system in FIG. 1. Figure 4 is based on The functional block diagram of the wireless electronic external tracheal compression response system according to the preferred embodiment of the present invention. The functional block diagram depicts the components of the wireless electronic external tracheal compression response system 1 according to the preferred embodiment of the present invention. And some components.

As shown in FIGS. 1, 2 and 3, the wireless electronic external tracheal compression response system 1 according to a preferred embodiment of the present invention includes a compression device 2 and a data processing device 3. The pressing device 2 includes a flexible housing 21, a bump 211, a cover 22, a tracheal joint 24, a vent 25, a first vent 25a, a second vent 25b, a trachea 26, a first tracheal vent 26a, The second port 26b of the trachea and the electronic module 23 may include a pressure sensor 231, a pressure sensor vent port 231a, a pressure sensor vent pipe 231b, a first wireless signal transmission module 232, a battery 233, and a power switch 234. Power switch button 234a, power port 235, power port interface 235a, controller 236, circuit board 237, and peripheral module 238. The first port 26a of the trachea is connected to the tracheal joint 24, and the second port 26b of the trachea is connected to the pressure sensor vent pipe 231b. The flexible housing 21 and the electronic module 23 are combined by the trachea 26 to form a flexible housing The internal space of the body 21, the air hole 25, the air pipe 26, and the pressure sensor 231 air passage.

The structure of the flexible housing 21 of the pressing device 2 according to the present invention can be designed according to the ergonomic shape. As shown in Figures 1 and 2, the structure of the flexible housing 21 of the pressing device 2 is designed according to the shape of the hollow cylinder, but the structure of the flexible housing 21 of the pressing device 2 according to the present invention is not limited to the hollow Columnar shape, it can also follow other types of shapes, such as sphere, semi-circle, sweet Donuts and other shapes.

The electronic module 23 is arranged in the outer space of the flexible housing 21. The pressure sensor 231 is electrically fixed to the circuit board 237; when the user presses the flexible housing 21, the air flow and gas path in the flexible housing 21 are the first orifice 25a, the first orifice 25, The second port 25b of the air hole, the trachea 26, the pressure sensor vent 231a, and the pressure sensor vent pipe 231b reach the pressure sensor 231; the pressure sensor is electrically connected to the controller to sense the flexible shell The gas pressure inside the body 21.

In a specific embodiment, when the user presses and relaxes repeatedly on the flexible housing 21, the pressure sensor 231 and the controller 236 can also sense changes in gas pressure in the inner space of the flexible housing 21 and the user presses And the time of relaxation changes, thus generating pressure and time switch signals.

As shown in FIG. 3, in a specific embodiment, the power switch 234 may be various switching elements such as a mechanical switch, an electromagnetic switch, and a touch pad.

The first wireless signal transmission module 232 is electrically fixed on the circuit board 237 and electrically connected to the controller 236.

As shown in FIG. 4, the data processing device 3 includes a storage module 32, a broadcasting module 34, a second wireless signal transmission module 36, a display 39 and at least one processor 38. At least one processor 38 is electrically connected to the storage module 32, the broadcasting module 34, the second wireless signal transmission module 36, and the display 39, respectively.

The storage module 32 stores therein a plurality of corresponding press response applications (APP).

In a specific embodiment, the type of the data processing device 3 may be various data processing devices, for example, a desktop computer, a notebook computer, a smart phone, a tablet computer, etc.

The user operates the data processing device 3 to execute a press response application (APP) through at least one processor 38, and selects an execution program from a plurality of predetermined information through the press response application (APP).

When the user presses the flexible housing 21, the internal air of the flexible housing 21 passes through the pressure sensor vent 231a, the pressure sensor vent pipe 231b, and is sensed by the pressure sensor 231 about the flexibility. For the pressure signal of the internal air of the housing 21, the controller 236 receives the pressure signal of repeated pressing and releasing and the time switch signal transmitted by the pressure sensor 231. The controller 236 also sends the pressure signal and the time switch signal through the first wireless signal transmission module 232.

At least one processor 38 receives the pressure signal and the time switch signal sent by the first wireless signal transmission module 232 through the second wireless signal transmission module 36. At least one processor 38 compares the target pressure signal and time switch signal information with the received pressure signal and time switch signal information sent by the first wireless signal transmission module 232 according to the target pressure signal and time switch signal information of the selected execution program Yes, the comparison execution program predicts that the pressure signal and the time switch signal start and end are different from the pressure signal and the time switch signal sent by the first wireless signal transmission module 232. At least one processor 38 is displayed via the broadcasting module 34 and the display 39 Show time difference information. In this way, the user can learn whether the speed or rhythm of his operation is correct through the sound of the broadcasting module 34 and the image information of the display 39 based on the time difference information, and make self-correction to achieve the purpose of sensory integration training.

Different from the prior art, the wireless electronic external tracheal compression response system 1 according to the preferred embodiment of the present invention is that at least one processor 38 of the data processing device 3 executes the compression application (APP) of the storage module 32 and compares The operator physically presses the generated signal, and the broadcast module 34 or the display 39 of the data processing device 3 displays the difference information. All pressing applications (APP) and display actions are executed in the data processing device 3, and the pressing device 2 is responsible for generating pressure signals and time switch signals and transmitting the pressure signals and time switch signals to the data processing device 3. The data processing device 3 includes a second wireless signal transmission module 36. In addition to receiving the pressure signal and time switch signal transmitted by the pressing device 2, it can also receive other external wireless communication information; the wireless electronic external tracheal pressing response system 1 As long as the press response application (APP) of the storage module 32 is updated, the overall system update operation can be completed. Therefore, the wireless electronic external tracheal press response system 1 according to the preferred embodiment of the present invention can easily update the software through cloud wireless technology, and can even expand the wireless electronic external tracheal press response according to the preferred embodiment of the present invention Function of System 1.

The pressure sensor 231 used in the present invention can be manufactured using micro-electromechanical technology to improve its accuracy. Flexible housing 21 is subjected to external force After that, the gas inside the flexible housing 21 flows through the pressure sensor vent 231a and the pressure sensor vent pipe 231b so that the pressure sensor 231 senses the pressure change information, as the operator presses and relaxes With repeated operations, the pressure of the gas inside the flexible housing 21 will also increase repeatedly and return to the original pressure, which is sensed by the pressure sensor 231 to generate repeated pressure signals and time switch signals. The pressure sensor 231 senses the pressure change of the gas inside the flexible housing 21, and digitizes the gas pressure and the sensed value into a signal about the pressure change of the gas and the result of the time switch, which is also pressed and released by the operator The digitized pressure signal and time switch signal of the flexible housing 21. The pressure sensor 231 also transmits the pressure signal of the gas inside the flexible housing 21 and the time switch signal to the controller 236. As a result, the pressing device 2 according to the present invention can sensitively sense the pressure and the length of time the user presses, and then compare the expected pressure signal of the execution program and the time point of the start and end of the time switch signal through the broadcast module 34 The sound or display 39 accurately reflects the difference between the operator's operating pressure and actuation time point and the expected pressure and time point of the execution program.

As shown in FIGS. 2, 3 and 4, in a specific embodiment, the electronic module 23 of the pressing device 2 of the wireless electronic external tracheal pressing response system 1 according to the present invention further includes a peripheral module 238. Peripheral modules can include components such as vibration motors and gyroscopes. The at least one processor 38 of the data processing device 3 receives the pressure signal and the time switch signal from the first wireless signal transmission module 232 via the second wireless signal transmission module 36, and compares the selected press response application (APP) dynamics Signal, the time difference between the two signals through the second wireless The signal transmission module 36 is transmitted to the first wireless signal transmission module 232, and the controller 236 converts the information of the time difference between the two signals into a peripheral module 238 control signal to control and drive the peripheral module components, such as a vibration motor, etc. Increase the operator's perception of feedback from the operation of the wireless electronic external tracheal compression response system 1 of the present invention.

In a specific embodiment, the first wireless signal transmission module 232 transmits the pressure signal and the time switch signal through a wireless communication protocol. The wireless communication protocol can be Wi-Fi protocol, WiMAX protocol, IEEE 802.11 series protocol (IEEE 802.11-based protocols), 3G network protocol, 4G network protocol, 5G network protocol, HSPA network protocol, LTE network protocol, Bluetooth protocol, or other commercial wireless communication protocols. The second wireless signal transmission module 36 also receives the pressure signal and the time switch signal using the wireless communication protocol followed by the first wireless signal transmission module 232.

In a specific embodiment, as shown in FIG. 3, the pressing device 2 of the wireless electronic external tracheal pressing response system 1 according to the preferred embodiment of the present invention further includes a battery 233. The battery 233 is electrically connected to the circuit board 237 to supply power required by the electronic module 23 during operation. In practical applications, the battery 233 may be a dry battery or a rechargeable battery.

In a specific embodiment, as shown in FIG. 3, the power port 235 of the electronic module 23 of the pressing device 2 of the wireless electronic external tracheal pressing response system 1 according to the preferred embodiment of the present invention is electrically fixed to the circuit board The battery 233 is electrically connected to the 237, and the external power supply can be connected to the power supply through the power port interface 235a The port 235 can charge the battery 233 or directly drive the electronic module 23.

As shown in Figures 1 and 2, in a specific embodiment, the flexible housing 21 is provided with bumps 211 on the outside, so that pressing the flexible housing 21 during the operation process can more easily stimulate the nerves of the user system.

In a specific embodiment, as shown in FIG. 4, the storage module 32 also stores compression training applications and instruction programs.

From the above detailed description of the present invention, it can be clearly understood that the wireless electronic external tracheal compression response system 1 according to the present invention allows the user to operate the present invention only by intuition or simple guidance, and perform interesting and lively sensory integration training. Moreover, the pressing device 2 according to the present invention has a simple structure, sensitive pressure sensing, convenient software update, and easy manufacturing. The wireless electronic external tracheal compression response system 1 according to the present invention can assist the user in self-training, and transmit the training results and records to relevant personnel through the second wireless signal transmission module 36 described above.

Based on the detailed description of the preferred embodiments above, it is hoped that the characteristics and spirit of the present invention can be described more clearly, rather than limiting the aspect of the present invention by the preferred embodiments disclosed above. On the contrary, its purpose is to cover various changes and equivalent arrangements within the scope of the patent application for this new model. Therefore, the scope of the patent application for this model should be interpreted in the broadest way based on the above description, so as to cover all possible changes and equivalent arrangements.

1: Wireless electronic external tracheal compression response system

2: pressing device

21: Flexible shell

23: Electronic module

231: Pressure Sensor

231a: Pressure sensor vent port

231b: Pressure sensor snorkel

232: The first wireless signal transmission module

233: Battery

235: power port

235a: power port interface

236: Controller

237: Circuit Board

238: Peripheral Module

24: Trachea connector

25: Stoma

25a: First orifice of stoma

25b: The second orifice of the stoma

26: trachea

26a: First orifice of trachea

26b: Second orifice of trachea

3: Data processing device

32: storage module

34: Broadcast module

36: The second wireless signal transmission module

38: processor

39: display

Claims (8)

A wireless electronic external tracheal compression response system, including: A pressing device, including: A flexible shell; A circuit board is fixed on the outside of the flexible housing; A pressure sensor is electrically connected to the circuit board and includes a pressure sensor vent; A gas pipe connecting the inside of the flexible housing and the pressure sensor with gas; A controller which is electrically fixed on the circuit board and electrically connected to the pressure sensor; A first wireless signal transmission module electrically fixed on the circuit board and electrically connected to the controller; and A data processing device, including: A storage module, which stores multiple predetermined application program information; One broadcast module; A display A second wireless signal transmission module; and At least one processor is electrically connected to the storage module, the broadcasting module, the display, and the second wireless signal transmission module; One of the users operates the data processing device to execute the pressing application through the at least one processor. When the user repeatedly presses and releases the flexible housing, the pressure sensor senses the inside of the flexible housing The gas pressure changes, and the pressure signal and the time switch signal are controlled by the controller, and the pressure signal and the time are sent through the first wireless signal transmission module The at least one processor receives the pressure signal and the time switch signal through the second wireless signal transmission module, and the at least one processor compares the selected execution program information with the pressure signal and the time of the received operator The switch signal difference will be compared to the signal difference, and the information will be played in various forms such as text, pattern or animation through the broadcast module or display or together. The wireless electronic external tracheal pressure response system according to claim 1, wherein the pressing device further includes a rechargeable power supply device, which is connected to the circuit board and can be electrically connected to an external power source to supply the pressure The power required for the operation of the sensor, the controller and the first wireless signal transmission module. The wireless electronic external tracheal pressing response system according to claim 1, wherein the pressing device includes a non-rechargeable battery, which is connected to a circuit board to supply the pressure sensor, the controller, and the first A power required by the wireless signal transmission module during operation. The wireless electronic external tracheal pressure response system according to claim 1, wherein a plurality of convex points are provided on the outer surface of the flexible housing. The wireless electronic external tracheal press response system as described in claim 1, wherein the storage module also stores a plurality of press execution programs in it for the user to select and operate. The wireless electronic external tracheal press response system according to claim 1, wherein the first wireless signal transmission module transmits the pressure signal and the time switch signal by a wireless communication protocol, and the wireless communication protocol is selected from Wi- Fi protocol, WiMAX protocol, IEEE 802.11 series protocol, 3G network Protocol, 4G network protocol, 5G network protocol, HSPA network protocol, LTE network protocol, and Bluetooth protocol. The wireless electronic external tracheal compression response system according to claim 1, wherein the storage module further stores a plurality of compression training applications. The wireless electronic external tracheal pressing response system according to claim 1, wherein the pressing device is provided with a peripheral module, and the module includes a vibration motor element.

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