TW201320967A - Automatic wireless transmission physiological data monitoring system and monitoring method thereof - Google Patents

Abstract

An automatic wireless transmission physiological data monitoring system and a monitoring method thereof, the system comprising at least one peripheral module, a main detecting module and a servo platform, the peripheral module comprising a monitoring unit for monitoring the state of the user, The main detection module has a physiological detection unit; the main detection module has a detection state of a physiological measurement data of a user that does not simultaneously coexist, and a wireless connection between the peripheral module and a transmission state of the servo platform. The invention automatically collects the monitoring data of the peripheral module by the main detecting module, and uploads the data obtained by the physiological detecting unit to the servo platform through a wireless connection, for the observer to view, and automatically separates The detection status and transmission status can avoid the interference of the wireless signal to the detection instrument.

Description

Automatic wireless transmission physiological data monitoring system and monitoring method thereof

The invention relates to a physiological data monitoring system, in particular to an automatic wireless transmission type physiological data monitoring system.

Due to changes in daily life and eating habits, the symptoms of various chronic diseases such as high blood pressure, diabetes, or high cholesterol are greatly increased. In the formal medical system of the hospital, it is necessary to provide the doctor or care by establishing the patient's personal data, collecting the relevant physiological state data, and recording the various blood, urine, and eating conditions during the hospital stay. The basis for the administration of the person to establish a medical order. After the patient returns home, the home-based measuring instrument can be used for routine health testing to achieve self-health management. However, the hospital cannot know the follow-up health status after the patient leaves the hospital. Therefore, if the patient is negligent in self-management or has an emergency, it cannot be accurately and immediately judged by obtaining physiologically relevant information. Corresponding to treatment, there is a possibility of delaying the condition.

In order to avoid the above situation, the "Integrated Interactive Health Management Module" of the Republic of China Patent No. M342565, wherein the physiological information measured by the caregiver in a self-testing manner can be transmitted to a medical service platform, so that Relevant personnel involved in the treatment of the platform can learn about the home care situation of the care recipient, thereby avoiding the above situation. However, the method of data transmission was not disclosed in the case, and the signal transmitted by the data easily interfered with the detection signal, which may cause the measurement data to be inaccurate.

The main object of the present invention is to provide a physiological data monitoring system for fully automated wireless transmission, and to avoid the problem that the data transmission signal may interfere with the detection signal and cause the measurement data to be inaccurate.

To achieve the above objective, the present invention provides an automatic wireless transmission type physiological data monitoring system, comprising at least one peripheral module, a main detection module, and a servo platform wirelessly connected to the main detection module. The peripheral module includes a monitoring unit, a first wireless transmission unit electrically connected to the monitoring unit, and a periodic control unit electrically connected to the first wireless transmission unit, where the periodic control unit controls the first wireless transmission unit The opening interval. The main detection module includes a central processing unit and a physiological detection unit electrically connected to the central processing unit, a second wireless transmission unit, and a long-range wireless transmission unit. The second wireless transmission unit corresponds to the peripheral mode. The first wireless transmission unit of the group performs wireless data transmission. The main detection module is automatically connected to the servo platform through the long-range wireless transmission unit for transmission.

The central processing unit has a detection state and a transmission state that do not exist at the same time. The physiological detection unit can only detect when the detection state is performed, and in the transmission state, the second wireless transmission unit is turned on to perform a wireless connection. And data transmission. And the peripheral module periodically turns on the first wireless transmission unit through the periodic control unit, and when the primary detection module turns on the second wireless transmission unit in a transmission state, performs a wireless connection, and the monitoring unit obtains The monitoring data is transmitted to the main detection module, and is wirelessly connected to the servo platform via the long-range wireless transmission unit, thereby uploading the monitoring data and the physiological detection data.

In addition, the present invention also discloses an automatic wireless transmission type physiological data monitoring system, which comprises at least one peripheral module, a main detection module, and a servo platform wirelessly connected to the main detection module. The peripheral module includes a monitoring unit for obtaining a monitoring data and a first wireless transmission unit electrically connected to the monitoring unit. The main detection module includes a central processing unit, and a physiological detection unit electrically connected to the central processing unit, a second wireless transmission unit, a long-range wireless transmission unit, and a storage unit. The second wireless transmission The unit performs wireless data transmission corresponding to the first wireless transmission unit. The main detection module is automatically connected to the servo platform through the long-range wireless transmission unit for transmission.

The central processing unit has a detection state and a transmission state that do not exist at the same time. The physiological detection unit can only detect when the detection state is performed, and in the transmission state, the second wireless transmission unit is turned on to perform a wireless connection. And data transmission. When the primary detection module is in the transmission state, the second wireless transmission unit automatically searches for the peripheral module and obtains the monitoring data of the monitoring unit, and temporarily stores the monitoring data. And then transmitted to the servo platform by the long-range wireless transmission unit.

In addition, the present invention also discloses an automatic wireless transmission type physiological data monitoring method. The monitoring method performs a peripheral step and a main step for at least one peripheral module and a main detection module, and the peripheral steps include:

P1: obtaining and recording a monitoring data through a monitoring unit of the peripheral module;

P2: opening, by one of the peripheral modules, a first wireless transmission unit disposed on the peripheral module;

P3: determining the wireless connection status, determining whether the first wireless transmission unit is wirelessly connected to the primary detection module, if connected, proceeding to step P4, if not connected, proceeding directly to step P5;

P4: transmitting, by the first wireless transmission unit, the monitoring data to the primary detection module;

P5: turning off the first wireless transmission unit and performing standby;

And the main steps include:

S1: the main detection module is in a detection state, and a physiological detection data is obtained through a physiological detection unit of the main detection module;

S2: switching the primary detection module to a transmission state, and turning on one of the primary detection modules, the second wireless transmission unit;

S3: waiting for the connection, waiting for the first wireless transmission unit to connect with the second wireless transmission unit, if it is connected, proceed to step S4, if not connected, proceed directly to step S5;

S4: receiving the monitoring data;

S5: turning on one long-range wireless transmission unit of the main detection module, and transmitting data to a servo platform;

S6: Turn off the second wireless transmission unit and the long-range wireless transmission unit, and switch to the detection state.

In addition, the peripheral module is automatically connected to the main detection module for data transmission in the above manner, and the physiological data is monitored. The main detection module can also directly search for the peripheral module in an automatic search manner to obtain the monitoring. data. The peripheral steps of this monitoring method include:

P1a: obtaining and recording a monitoring information monitoring data through a monitoring unit of the peripheral module;

P2a: waiting for and starting the connection, waiting for the wireless signal of the main detection module to activate a first wireless transmission unit of the peripheral module;

P3a: connecting and transmitting, the monitoring information monitoring data is transmitted to the main detecting module by the first wireless transmission unit;

P4a: turning off the first wireless transmission unit and performing standby;

The main steps of this method include:

S1a: the main detection module is in a detection state, and a physiological detection signal data is obtained through a physiological detection unit of the main detection module;

S2a: switching the primary detection module to a transmission state, and turning on one of the primary detection modules, the second wireless transmission unit;

S3a: automatically search for a connection, automatically search for and connect with the first wireless transmission unit of the peripheral module, if it is connected, proceed to step S4a, if not, proceed directly to step S5a;

S4a: receiving the monitoring information monitoring data;

S5a: opening a long-range wireless transmission unit of the main detection module, and transmitting data to a servo platform;

S6a: Turn off the second wireless transmission unit and the long-range wireless transmission unit, and switch to the detection state.

It can be seen from the above description that the main detection module performs the detection of the physiological data and the transmission of the wireless data when the detection state and the transmission state coexist at different times, thereby eliminating the possibility of electronic interference by the wireless signal during the detection, and the electromagnetic wave is for medical treatment. The issue of equipment interference has been highly valued. Even in the standby state, there is a possibility of interference during detection. The present invention defines two states of coexistence by controlling the opening and closing of the wireless transmission unit. To ensure that the detection is free from electromagnetic waves, thereby increasing the dependence of the physiological detection data, and automatically transmitting the data in the peripheral module and the main detection module to the servo through automatic transmission. Platform to avoid the possibility of not transmitting data due to human factors. Moreover, the main detection module is connected to the servo platform in a wireless connection manner, so that data can be uploaded whenever and wherever.

The detailed description and technical contents of the present invention will now be described as follows:

Referring to FIG. 1 and FIG. 2, the present invention is an automatic wireless transmission type physiological data monitoring system. In the first embodiment, the monitoring system includes at least one peripheral module 10 and a main The detection module 20 and a servo platform 30 wirelessly connected to the main detection module 20. The peripheral module 10 includes a monitoring unit 11 , a first wireless transmission unit 12 electrically connected to the monitoring unit 11 , and a periodic control unit 13 electrically connected to the first wireless transmission unit 12 . The periodic control unit 13 The opening interval of the first wireless transmission unit 12 is controlled. The peripheral module 10 can be a pedometer, an image recording device, an electronic medicine box, a blood pressure meter, a weight scale, a body fat meter, an insulin pen or a thermometer, etc., so that the monitoring unit 11 is used to obtain the peripheral module 10 The measured value is a monitoring data, and the monitoring data may be used for exercise, diet, drug use or physical state data, etc., wherein the body state data may be body temperature, body weight, body fat or blood pressure. In the first embodiment, it has three peripheral modules 10a, 10b, 10c, which respectively represent the electronic medicine box 51, the pedometer 52, and the mobile phone 53 (used as an image recording device), thereby obtaining Know the user's medication time, exercise status, and the content and quantity of the diet.

The main detection module 20 includes a central processing unit 21 and a physiological detection unit 22, a second wireless transmission unit 23, and a long-range wireless transmission unit 24, which are respectively electrically connected to the central processing unit 21, and the second wireless transmission unit. Unit 23 performs wireless data transmission in response to first wireless transmission unit 12. The main detection module 20 is automatically connected to the servo platform 30 via the long-range wireless transmission unit 24. The manner in which the long-range wireless transmission unit 24 is wirelessly connected to the servo platform 30 may be a Global System for Mobile Communications (GSM), a General Packet Radio Service (GPRS), or a code division. Code division multiple access (CDMA), etc. The wireless transmission mode of the first wireless transmission unit 12 and the second wireless transmission unit 23 may be Bluetooth, infrared transmission, Zigbee, Ultra-wideband (UWB), and home radio (Home). RF), Worldwide Interoperability for Microwave Access (WiMax), Wireless Fidelity (Wi-Fi) or Radio Frequency Technology. Among them, the radio frequency technology includes a wide range of frequency-shift keying (FSK), Amplitude-shift keying (ASK) or phase-shift keying (Phase-shift keying). Technology such as PSK), this type of radio frequency technology has its own low-power characteristics, which can save power. In addition, the monitoring data is automatically transmitted at any time. The amount of data transmitted per time is not too much. Therefore, it is also suitable for The wireless transmission technology of this case. The main detection module 20 of the present invention conveniently has the function of detection by using the physiological detection unit 22, and the physiological detection unit 22 can be an apparatus for blood detection, saliva detection or urine detection, and has blood sugar, blood oxygen concentration, Blood lipids, cholesterol, uric acid, alcohol, triglycerides, ketone bodies, creatinine, lactic acid or heme detection. In addition, the main detection module 20 further includes an emergency connection unit 25 electrically connected to the central processing unit 21 and providing an emergency connection, and a display unit 26 for the user to view the detection result and the transmission status. Because the peripheral module 10 is small in size and convenient to carry, the user who is old or forgetful may be temporarily unable to find because of random placement, which causes inconvenience to the user. Therefore, the main detection module 20 can A call unit 27 is included, and the peripheral module 10 can also include a pair of voice prompting units 14 to be called, and the call unit 27 is connected to the central processing unit 21, and the voice prompting unit 14 and the first wireless transmission The unit 12 is connected, and the voice prompting unit 14 makes a sound by paging by the calling unit 27, and the user can search by voice prompt.

The central processing unit 21 has a detection state and a transmission state that do not exist at the same time. The physiological detection unit 22 can detect only when the detection state is performed, and the second wireless transmission unit 23 is turned off, and the transmission state is The second wireless transmission unit 23 can be enabled, and the primary detection module 20 performs wireless connection and data transmission with the peripheral modules 10a, 10b, and 10c. Please refer to "FIG. 3A" and "FIG. 3B". FIG. 3A and FIG. 3B are schematic diagrams showing a monitoring method according to a first embodiment of the present invention. The monitoring method is directed to the peripheral module 10 and the main detection mode. Group 20 performs a peripheral step and a main step, respectively, the peripheral steps including:

P1: The monitoring data is obtained and recorded by the monitoring unit 11, and the peripheral modules 10a, 10b, and 10c respectively record monitoring data of the user's medication time, exercise status, and dietary content and quantity;

P2: The first wireless transmission unit 12 is turned on by the cycle control unit 13. In order to save power, the cycle control unit 13 controls the opening interval of the first wireless transmission unit 12 only after acquiring the monitoring data; When the monitoring data is obtained, the cycle control unit 13 and the first wireless transmission unit 12 do not perform any action to save power;

P3: determining the wireless connection status, determining whether the first wireless transmission unit 12 is wirelessly connected to the primary detection module 20, if connected, proceeding to step P4, if not connected, proceeding directly to step P5;

P4: transmitting monitoring data, the first wireless transmission unit 12 transmits the monitoring data to the main detection module 20;

P5: The first wireless transmission unit 12 is turned off and standby is performed.

And the main steps include:

S1: The main detection module 20 is in the detection state, and the physiological detection unit 22 obtains a physiological detection data, and the detection system of the physiological detection is blood sugar, saliva or uric acid, and the like, and in the detection state, the second The wireless transmission unit 23 and the long-range wireless transmission unit 24 are in the off state to avoid data correctness of the detection state due to electromagnetic wave interference, and on the other hand, the power saving effect can be achieved;

S2: Switching the main detection module 20 to the transmission state, using the central processing unit 21 to switch to the transmission state, and turning on the second wireless transmission unit 23, the transmission state only lasts for a transmission time for the periphery. The modules 10a, 10b, and 10c perform wireless transmission, and if the time to be transmitted is exceeded, the transmission state is turned off to save power;

S3: waiting for the connection, waiting for the first wireless transmission unit 12 to be connected to the second wireless transmission unit 23, if it is connected, proceeding to step S4, if not, proceeding directly to step S5, wherein the cycle control unit 13 is The first wireless transmission unit 12 is periodically turned on, so that the peripheral modules 10a, 10b, and 10c and the main detection module 20 can only be wirelessly connected at a specific time;

S4: receiving the monitoring data, and transmitting the monitoring data obtained by the monitoring unit 11 to the main detecting module 20;

S5: The long-range wireless transmission unit 24 is turned on, and data is transmitted to the servo platform 30;

S6: The second wireless transmission unit 23 and the long-range wireless transmission unit 24 are turned off, and switched to the detection state.

The present invention also discloses a second embodiment. Referring to FIG. 4, an automatic wireless transmission type physiological data monitoring system of the present invention includes at least one peripheral module 10d, a main detection module 20, and A servo platform 30 wirelessly coupled to the primary detection module 20. The peripheral module 10d includes a monitoring unit 11 for obtaining a monitoring data and a first wireless transmission unit 12 electrically connected to the monitoring unit 11.

The main detection module 20 includes a central processing unit 21, and a physiological detection unit 22, a second wireless transmission unit 23, a long-range wireless transmission unit 24, and a storage unit 28 that are electrically connected to the central processing unit 21, respectively. The second wireless transmission unit 23 performs wireless data transmission corresponding to the first wireless transmission unit 12. The main detection module 20 is automatically connected to the servo platform 30 via the long-range wireless transmission unit 24. In addition, the main detection module 20 further includes an emergency connection unit 25 for electrically connecting to the central processing unit 21 and a display unit 26 for the user to view the detection result and the transmission status.

The central processing unit 21 similarly has a detection state and a transmission state that do not coexist at the same time. The physiological detection unit 22 can only detect when the detection state is performed, and in the transmission state, the second wireless transmission unit 23 is turned on. The main detection module 20 automatically searches for the peripheral module 10d and performs wireless connection and data transmission. Please refer to "FIG. 5A" and "FIG. 5B". FIG. 5A and FIG. 5B are schematic diagrams showing a monitoring method according to a second embodiment of the present invention. The peripheral steps in the monitoring method are as follows:

P1a: obtaining and recording the monitoring data through the monitoring unit 11;

P2a: waiting for and starting the connection, waiting for the wireless signal of the main detection module 20 to activate the first wireless transmission unit 12;

P3a: connection and transmission, the first wireless transmission unit 12 transmits the monitoring data to the main detection module 20;

P4a: The first wireless transmission unit 12 is turned off and on standby.

And the main steps include:

S1a: the main detection module 20 is in a detection state, and a physiological detection data is obtained through the physiological detection unit 22;

S2a: switching the main detection module 20 to a transmission state, using the central processing unit 21 to switch to the transmission state, and turning on the second wireless transmission unit 23;

S3a: automatically search for the connection, automatically search for the first wireless transmission unit 12 of the peripheral module 10d, and connect with it, if it is connected, proceed to step S4a, if not connected, proceed directly to step S5a;

S4a: receiving the monitoring data;

S5a: the long-range wireless transmission unit 24 is turned on, and data transmission is performed to the servo platform 30;

S6a: The second wireless transmission unit 23 and the long-range wireless transmission unit 24 are turned off, and switched to the detection state.

It should be noted that the second embodiment is different from the first embodiment in that the main detection module 20 automatically searches for the second wireless transmission unit 23 by using the control of the central processing unit 21 when in the transmission state. The peripheral module 10d obtains the monitoring data of the monitoring unit 11 and uploads to the servo platform 30 by using the long-range wireless transmission unit 24. If the upload is unsuccessful, it is temporarily stored in the storage unit 28, waiting for the next upload opportunity.

Finally, the information shown in FIG. 6 can be obtained on the servo platform 30, and the user's exercise data 41, diet data 42, physiological test data 43, and drug use data 44 at different time points can be known. The medical caregiver, the doctor or the relatives of the user can log in to the server platform 30 to learn the user's exercise data 41, diet data 42, physiological test data 43 and drug use data 44, and can further judge The user's physical condition or provide health advice.

In summary, the present invention has the following features:

1. The present invention performs the detection of physiological data and the transmission of wireless data through the detection state and the transmission state of the main detection module 20 at different times, thereby eliminating the possibility of electronic interference by the wireless signal during the detection, thereby improving the physiological condition. Detect the dependability of the data.

2. The automatic transmission method can automatically transmit the data in the peripheral module 10 and the main detection module 20 to the servo platform 30, thereby avoiding the possibility that the data may not be transmitted due to human factors.

3. The main detection module 20 is connected to the servo platform 30 in a wireless connection manner, so that the monitoring data and the uploading of the physiological detection data can be performed whenever and wherever.

Fourth, the use of system settings for automatic transmission, and eliminate the user's complicated transmission installation procedures, to achieve the purpose of non-inductive upload.

5. The data storage and display of the servo platform 30 is provided to viewers such as doctors, family members and caregivers who care about personal health.

Therefore, the present invention is highly progressive and conforms to the requirements of the invention patent application, and the application is filed according to law, and the praying office grants the patent as soon as possible.

The present invention has been described in detail above, but the foregoing is only a preferred embodiment of the present invention, and is not intended to limit the scope of the invention. That is, the equivalent changes and modifications made by the scope of the present application should remain within the scope of the patent of the present invention.

10, 10a, 10b, 10c, 10d. . . Peripheral module

11. . . Monitoring unit

12. . . First wireless transmission unit

13. . . Cycle control unit

14. . . Sound prompt unit

20. . . Main detection module

twenty one. . . Central processing unit

twenty two. . . Physiological detection unit

twenty three. . . Second wireless transmission unit

twenty four. . . Long-range wireless transmission unit

25. . . Emergency contact unit

26. . . Display unit

27. . . Call unit

28. . . Storage unit

30. . . Servo platform

41. . . Sports data

42. . . Dietary information

43. . . Physiological test data

44. . . Drug use data

51. . . Electronic kit

52. . . Pedometer

53. . . mobile phone

S1~S6, P1~P5. . . step

S1a~S6a, P1a~P4a. . . step

FIG. 1 is a block diagram showing the configuration of a first embodiment of the present invention.

FIG. 2 is a schematic diagram of a module used in the first embodiment of the present invention.

3A-3B are schematic views showing a monitoring method according to a first embodiment of the present invention.

4 is a block diagram showing the configuration of a second embodiment of the present invention.

5A-5B are schematic views showing a monitoring method according to a second embodiment of the present invention.

FIG. 6 is a schematic diagram showing the state of a servo platform according to the present invention.

10, 10a, 10b, 10c. . . Peripheral module

11. . . Monitoring unit

12. . . First wireless transmission unit

13. . . Cycle control unit

14. . . Sound prompt unit

20. . . Main detection module

twenty one. . . Central processing unit

twenty two. . . Physiological detection unit

twenty three. . . Second wireless transmission unit

twenty four. . . Long-range wireless transmission unit

25. . . Emergency contact unit

26. . . Display unit

27. . . Call unit

30. . . Servo platform

Claims (27)

An automatic wireless transmission physiological data monitoring system, comprising:
The at least one peripheral module includes a monitoring unit, a first wireless transmission unit electrically connected to the monitoring unit, and a periodic control unit electrically connected to the first wireless transmission unit, where the periodic control unit controls the first wireless The opening interval of the transmission unit;
a main detection module includes a central processing unit and a physiological detection unit electrically connected to the central processing unit, a second wireless transmission unit, and a long-range wireless transmission unit. The second wireless transmission unit corresponds to the first a wireless transmission unit for wireless data transmission; and a servo platform wirelessly connected to the main detection module, the main detection module is automatically connected to the servo platform through the long-range wireless transmission unit;
The central processing unit has a detection state and a transmission state at the same time, the physiological detection unit can only detect when the detection state is performed, and in the transmission state, the second wireless transmission unit is turned on for wireless connection and data transmission. The automatic wireless transmission type physiological data monitoring system of claim 1, wherein the period control unit controls the opening interval of the first wireless transmission unit only after the monitoring unit obtains a monitoring data. The automatic wireless transmission type physiological data monitoring system described in claim 2, wherein the servo platform comprises at least motion data, diet data, physiological test data, and drug use data. The automatic wireless transmission type physiological data monitoring system of claim 1, wherein the at least one peripheral module has a plurality of peripheral modules, and is selected from the group consisting of a pedometer, an image recording device, an electronic medicine box, a blood pressure meter, A group consisting of a weight scale, a body fat meter, an insulin pen, and a thermometer. The automatic wireless transmission type physiological data monitoring system of claim 1, wherein the main detection module further comprises an emergency connection unit electrically connected to the central processing unit and a display unit. The automatic wireless transmission type physiological data monitoring system according to claim 1, wherein the long-range wireless transmission unit is wirelessly connected to the servo platform, and is selected from the group consisting of global mobile communication technology, overall packet radio communication technology, and A group of code multiplex access communication technologies. The automatic wireless transmission type physiological data monitoring system of claim 1, wherein the wireless transmission mode of the first wireless transmission unit and the second wireless transmission unit is selected from the group consisting of Bluetooth, infrared transmission, and purple bee network. A group of road technology, ultra-wideband, home radio, global interoperability microwave access, wireless fidelity and radio frequency technology. The automatic wireless transmission type physiological data monitoring system of claim 1, wherein the wireless transmission mode of the first wireless transmission unit and the second wireless transmission unit is selected from a frequency shift keying modulation technique, A group consisting of amplitude shift keying modulation technology or phase shift keying modulation technology. The automatic wireless transmission type physiological data monitoring system according to the first aspect of the invention, wherein the main detection module acquires a physiological detection data through the physiological detection unit after the detection state, and switches to a transmission state, and turns on the The second wireless transmission unit. The automatic wireless transmission type physiological data monitoring system according to the first aspect of the invention, wherein the main detection module acquires a physiological detection data through the physiological detection unit after the detection state, switches to a transmission state, and turns on The second wireless transmission unit is turned off after a transmission time. The automatic wireless transmission type physiological data monitoring system of claim 1, wherein the main detection module comprises a call unit, the peripheral module comprises a pair of voice prompting units that should call the unit, and the calling unit and the call unit The central processing unit is connected, and the voice prompting unit is connected to the first wireless transmission unit. An automatic wireless transmission physiological data monitoring system, comprising:
At least one peripheral module includes a monitoring unit for obtaining a monitoring data and a first wireless transmission unit electrically connected to the monitoring unit;
a main detection module includes a central processing unit, and a physiological detection unit electrically connected to the central processing unit, a second wireless transmission unit, a long-range wireless transmission unit, and a storage unit, and the second wireless transmission The unit is configured to perform wireless data transmission with the first wireless transmission unit; and a servo platform wirelessly connected to the main detection module, the main detection module is automatically connected to the servo platform through the long-range wireless transmission unit;
The central processing unit has a detection state and a transmission state at the same time. The physiological detection unit can only detect when the detection state is performed. In the transmission state, the second wireless transmission unit is turned on to automatically search for the peripheral mode. Group and make wireless connections and data transmission. The automatic wireless transmission type physiological data monitoring system according to claim 12, wherein the servo platform comprises at least motion data, diet data, physiological test data, and drug use data. The automatic wireless transmission type physiological data monitoring system of claim 12, wherein the at least one peripheral module has a plurality of peripheral modules, and is selected from the group consisting of a pedometer, an image recording device, an electronic medicine box, a blood pressure meter, A group consisting of a weight scale, a body fat meter, an insulin pen, and a thermometer. The automatic wireless transmission type physiological data monitoring system of claim 12, wherein the main detection module further comprises an emergency connection unit electrically connected to the central processing unit and a display unit. The automatic wireless transmission type physiological data monitoring system according to claim 12, wherein the long-range wireless transmission unit and the servo platform are wirelessly connected to each other by a global mobile communication technology, an overall packet radio communication technology, and a point. A group of code multiplex access communication technologies. The automatic wireless transmission type physiological data monitoring system of claim 12, wherein the wireless transmission mode of the first wireless transmission unit and the second wireless transmission unit is selected from the group consisting of Bluetooth, infrared transmission, and purple bee network. A group of road technology, ultra-wideband, home radio, global interoperability microwave access, wireless fidelity and radio frequency technology. The automatic wireless transmission type physiological data monitoring system of claim 12, wherein the wireless transmission mode of the first wireless transmission unit and the second wireless transmission unit is selected from a frequency shift keying modulation technique, A group consisting of amplitude shift keying modulation technology or phase shift keying modulation technology. The automatic wireless transmission type physiological data monitoring system according to claim 12, wherein the main detection module acquires a physiological detection data through the physiological detection unit after the detection state, and switches to a transmission state, and automatically searches for The peripheral module performs wireless connection and data transmission. The automatic wireless transmission type physiological data monitoring system according to claim 12, wherein the main detection module acquires a physiological detection data through the physiological detection unit after the detection state, and switches to a transmission state, and automatically searches for After the peripheral module is to be transmitted for a while, the second wireless transmission unit is turned off. The automatic wireless transmission type physiological data monitoring system of claim 12, wherein the main detection module comprises a call unit, the peripheral module comprises a pair of voice prompting units that should call the unit, and the calling unit and the call unit The central processing unit is connected, and the voice prompting unit is connected to the first wireless transmission unit. An automatic wireless transmission type physiological data monitoring method, wherein the monitoring method performs a peripheral step and a main step for at least one peripheral module and a main detection module, and the peripheral steps include:
P1: obtaining and recording a monitoring data through a monitoring unit of the peripheral module;
P2: opening, by one of the peripheral modules, a first wireless transmission unit disposed on the peripheral module;
P3: determining the wireless connection status, determining whether the first wireless transmission unit is wirelessly connected to the primary detection module, if connected, proceeding to step P4, if not connected, proceeding directly to step P5;
P4: transmitting, by the first wireless transmission unit, the monitoring data to the primary detection module;
P5: The first wireless transmission unit is turned off and standby is performed; and the main steps include:
S1: the main detection module is in a detection state, and a physiological detection data is obtained through a physiological detection unit of the main detection module;
S2: switching the primary detection module to a transmission state, and turning on one of the primary detection modules, the second wireless transmission unit;
S3: waiting for the connection, waiting for the first wireless transmission unit to connect with the second wireless transmission unit, if it is connected, proceed to step S4, if not connected, proceed directly to step S5;
S4: receiving the monitoring data;
S5: turning on one long-range wireless transmission unit of the main detection module, and transmitting data to a servo platform;
S6: Turn off the second wireless transmission unit and the long-range wireless transmission unit, and switch to the detection state. The method for monitoring automatic wireless transmission type physiological data as described in claim 22, wherein the servo platform comprises at least motion data, diet data, physiological test data, and drug use data. The method for monitoring automatic wireless transmission type physiological data according to claim 22, wherein the at least one peripheral module has a plurality of and is selected from the group consisting of a pedometer, an image recording device, an electronic medicine box, and a blood pressure meter. A group consisting of a weight scale, a body fat meter, an insulin pen, and a thermometer. An automatic wireless transmission type physiological data monitoring method, wherein the monitoring method performs a peripheral step and a main step for at least one peripheral module and a main detection module, and the peripheral steps include:
P1a: obtaining and recording a monitoring data through a monitoring unit of the peripheral module;
P2a: waiting for and starting the connection, waiting for the wireless signal of the primary detection module to activate one of the first wireless transmission units of the peripheral module;
P3a: connecting and transmitting, the monitoring data is transmitted to the main detecting module by the first wireless transmission unit;
P4a: The first wireless transmission unit is turned off and standby is performed; and the main steps include:
S1a: the main detection module is in a detection state, and a physiological detection data is obtained through a physiological detection unit of the main detection module;
S2a: switching the primary detection module to a transmission state, and turning on one of the primary detection modules, the second wireless transmission unit;
S3a: automatically search for a connection, automatically search for and connect with the first wireless transmission unit of the peripheral module, if it is connected, proceed to step S4a, if not, proceed directly to step S5a;
S4a: receiving the monitoring data;
S5a: turning on one long-range wireless transmission unit of the main detection module, and transmitting data to a servo platform;
S6a: Turn off the second wireless transmission unit and the long-range wireless transmission unit, and switch to the detection state. The method for monitoring automatic wireless transmission type physiological data as described in claim 25, wherein the servo platform comprises at least motion data, diet data, physiological test data, and drug use data. The method for monitoring automatic wireless transmission type physiological data according to claim 25, wherein the at least one peripheral module has a plurality of and is selected from the group consisting of a pedometer, an image recording device, an electronic medicine box, and a blood pressure meter. A group consisting of a weight scale, a body fat meter, an insulin pen, and a thermometer.