TWM527570U - Wearable device with authentication function and authentication system thereof - Google Patents

Description

Wearable device with authentication function and its authentication system

The present invention relates to a wearable device with an authentication function and an authentication system thereof, and more particularly to a wearable device using a non-contact induction and having an authentication function and an authentication system thereof.

In recent years, with the rise of health awareness, more and more people are paying attention to their own health, paying attention to health related issues such as: improving metabolism, preventing cardiovascular disease, reducing the risk of heart disease and stroke, lowering cholesterol, etc. . Modern people's civilization diseases are mostly related to high blood sugar, high blood pressure or heart rate. In recent years, the combination of medical and scientific products has made the medical system gradually intelligent, but because many medical devices with physiological status are not convenient to carry, The user (patient) must still go to the hospital for testing. Furthermore, blood glucose machines, blood pressure machines, heart rate detectors, thermometers or portable physiological detection devices are currently available on the market, which can be combined with professional physicians to provide professional consultation and analysis on the patient's physiological data, or the patient can route through the network. The health report provided by the online analytics platform knows its own Health status. However, these physiological detecting devices must be placed in a fixed place, and the user must go to a fixed place to use the physiological detecting device, which greatly reduces the patient's willingness to use the physiological detecting device due to inconvenience in use.

In addition, patients are currently required to pass a health insurance card when they visit a hospital or clinic. However, sometimes patients forget to carry a health insurance card and cause inconvenience when they are seeing a doctor. In addition, the health insurance card will be directly contacted by many people during the visit, for example, the hands of doctors, nursing staff, and pharmacists, which are likely to cause the risk of direct contact with the vector. It can be seen from the above that there is a lack of a health insurance certification system that is safe, convenient, and can be combined with a physiological detection device. Therefore, relevant companies are seeking solutions.

Therefore, the present invention provides a wearable device with an authentication function and an authentication system thereof, which utilizes a wearable device and a sensing module to wirelessly transmit the sensed signal to a smart phone of a medical station or a medical staff. In addition, the application of the health care certificate can be realized through the encrypted wafer combined with the wearable device, and the voucher of the health insurance card can be replaced when the doctor is in medical treatment, and the wearer does not need to carry the additional health insurance card, which is both safe and convenient. Furthermore, in the transmission condition of the 13.56MHz frequency band, fast sensing and non-contact transmission can be realized, which can shorten the working time of the traditional health insurance card reader and save time for visiting, and reduce the vector transmission caused by contact. risks of.

One embodiment of the present invention is a wearable device with an authentication function for sensing the physical state of a wearer and transmitting an encrypted authentication information to a card reader, and the encrypted authentication information includes the health care card information of the wearer. . The wearable device with the authentication function includes a wearable body, a sensing module, a processor, a memory unit, an encryption chip, a radio frequency module, and an antenna. The sensing module is disposed on the wearable body, and the sensing module can sense the body state and output an analogy physiological signal. The processor is also disposed on the wearable body, and the processor signal is connected to the sensing module and receives an analog physiological signal. The processor converts the analog physiological signal into a digital physiological signal. In addition, the memory unit is disposed in the wearable body and the signal is connected to the processor. The memory unit receives and stores the digital physiological signal, and the memory unit stores one of the wearer's personal information. The encrypted chip is disposed on the wearable body, and the encrypted chip signal is connected to the processor and the memory unit. The encrypted chip receives the digital physiological signal and the personal information, and the encrypted chip converts the digital physiological signal and the personal information into an encrypted digital physiological signal and an encrypted personal information, respectively. Furthermore, the RF module is disposed on the wearable body, and the RF module signal is connected to the encrypted chip and receives the encrypted digital physiological signal and the encrypted personal information. The RF module generates a carrier and carries the encrypted digital physiological signal and the encrypted personal information on the carrier to form an encrypted authentication information. The carrier has a transmission frequency. The antenna is provided on the wearable body. The antenna signal is connected to the RF module and receives the encrypted authentication information, and the antenna transmits the encrypted authentication information to the card reader.

Therefore, the wearable device with the authentication function of the present invention utilizes the wearable device and the sensing module to wirelessly transmit the sensed signal to the smart phone of the medical station or the medical staff. In addition, through encryption The wafer-integrated wearable device can realize the application of the health insurance certificate, and can replace the voucher of the health insurance card when the doctor visits, and the wearer does not need to carry the additional health insurance card, which is both safe and convenient.

According to other implementations of the foregoing embodiments, the wearable device having the authentication function may include a display module and a power module, wherein the display module is disposed on the wearable body. The display module signal is connected to the processor and displays digital physiological signals and personal information. The power module is also located in the wearable body. The power module provides power to the sensing module, the processor, the memory unit, the encryption chip, the RF module, and the display module. Further, the aforementioned transmission frequency may be 13.56 MHz. The sensing module may include a heartbeat sensor, a blood pressure sensor, an integrated temperature sensor or a vibration sensor. The wearable device having the authentication function may include a second RF module disposed on the wearable body. The second RF module signal connects the encrypted chip and receives the encrypted digital physiological signal and the encrypted personal information. The second RF module generates a second carrier, and the encrypted digital physiological signal and the encrypted personal information are carried on the second carrier to form a second encrypted authentication information. In addition, the aforementioned wearable device having an authentication function may include a second antenna disposed on the wearable body. The second antenna signal is connected to the second RF module and the cloud server, and the second antenna receives the second encrypted authentication information and transmits through a WiFi, a Bluetooth transmission, and a general packet wireless communication (GPRS). A third generation communication (3G) or a fourth generation communication (4G) transmits the second encrypted authentication information to the cloud server.

Another embodiment of the present invention is an authentication system for a wearable device having an authentication function for sensing the body shape of a wearer state. The authentication system of the wearable device with the authentication function includes a wearable body, a sensing module, a processor, a memory unit, an encryption chip, a radio frequency module, an antenna, a card reader, and a cloud server. The sensing module is disposed on the wearable body, and the sensing module can sense the body state and output an analogy physiological signal. The processor is also disposed on the wearable body, and the processor signal is connected to the sensing module and receives an analog physiological signal. The processor converts the analog physiological signal into a digital physiological signal. In addition, the memory unit is disposed in the wearable body and the signal is connected to the processor. The memory unit receives and stores the digital physiological signal, and the memory unit stores one of the wearer's personal information. The certification information includes several physiological signals and personal information. The encrypted chip is disposed on the wearable body, and the encrypted chip signal is connected to the processor and the memory unit. The encrypted chip receives the digital physiological signal and the personal information, and the encrypted chip converts the digital physiological signal and the personal information into an encrypted digital physiological signal and an encrypted personal information, respectively. Furthermore, the RF module is disposed on the wearable body, and the RF module signal is connected to the encrypted chip and receives the encrypted digital physiological signal and the encrypted personal information. The RF module generates a carrier and carries the encrypted digital physiological signal and the encrypted personal information on the carrier to form an encrypted authentication information. The carrier has a transmission frequency. The antenna is provided on the wearable body. The antenna signal is connected to the RF module and receives the encrypted authentication information, and the antenna transmits the encrypted authentication information to the card reader. In addition, the card reader wireless signal is connected to the antenna and receives the encrypted authentication information, and the card reader transmits and outputs the encrypted authentication information through a wireless transmission mode. The cloud server connects to the card reader, and the cloud server receives and stores the encrypted authentication information, and the cloud server decrypts and checks the encrypted authentication information to generate an authentication result.

Therefore, the authentication system of the novel wearable device with the authentication function utilizes the wearable device and the sensing module, and the sensed signal can be wirelessly transmitted to the smart phone of the medical station or the medical staff. In addition, the application of the health care certificate can be realized through the encrypted wafer combined with the wearable device, and the voucher of the health insurance card can be replaced when the doctor is in medical treatment, and the wearer does not need to carry the additional health insurance card, which is both safe and convenient. Furthermore, in the transmission condition of the 13.56MHz frequency band, fast sensing and non-contact transmission can be realized, which not only shortens the working time of the traditional health insurance card reader, but also reduces the risk of vector transmission caused by contact.

According to other implementations of the foregoing embodiments, in the foregoing authentication system, when the decryption mechanism of the cloud server corresponds to the encryption mechanism of the encrypted chip, the authentication result is correct; otherwise, when the decryption mechanism of the cloud server is not corresponding to the encrypted chip When the encryption mechanism is used, the authentication result is an error. The aforementioned transmission frequency can be 13.56 MHz. The sensing module may include a heartbeat sensor, a blood pressure sensor, an integrated temperature sensor or a vibration sensor. In addition, the authentication system of the wearable device having the authentication function may include a second radio frequency module, which is disposed on the wearable body. The second RF module signal connects the encrypted chip and receives the encrypted digital physiological signal and the encrypted personal information. The second RF module generates a second carrier, and the encrypted digital physiological signal and the encrypted personal information are carried on the second carrier to form a second encrypted authentication information. Furthermore, the authentication system of the wearable device having the authentication function may include a second antenna disposed on the wearable body. The second antenna signal is connected to the second RF module and the cloud server, and the second antenna receives the second encrypted authentication information and transmits through a WiFi transmission and a Bluetooth transmission. (Bluetooth), a general packet radio communication (GPRS), a third generation communication (3G) or a fourth generation communication (4G) to transmit the second encrypted authentication information to the cloud server.

100,200‧‧‧Wearable devices with certified functions

110, 210‧‧‧ Wearable Ontology

120, 220‧‧‧ Sensing Module

130, 230‧‧‧ processor

140, 240‧‧‧ memory unit

150, 250‧‧‧ Encrypted Wafer

160, 260‧‧‧RF module

170, 270‧‧‧ antenna

180, 280‧‧‧ display module

190, 290‧‧‧ power module

260a‧‧‧second RF module

270a‧‧‧second antenna

300, 300a‧‧‧Certified system for certified wearable devices

310‧‧‧ card reader

320‧‧‧Cloud Server

330‧‧‧ medical station

1 is a block diagram of a wearable device having an authentication function according to an embodiment of the present invention.

FIG. 2 is a block diagram of a wearable device with an authentication function according to another embodiment of the present invention.

FIG. 3 is a schematic diagram showing the wearable device with the authentication function of FIG. 1 applied to the health insurance authentication system.

FIG. 4 is a schematic diagram showing the wearable device with the authentication function applied to the health insurance authentication system in FIG.

Hereinafter, a plurality of embodiments of the present invention will be described with reference to the drawings. For the sake of clarity, many practical details will be explained in the following description. However, it should be understood that these practical details are not intended to limit the novel. That is to say, in some embodiments of the present invention, these practical details are not necessary. In addition, some of the conventional structures and elements are illustrated in the drawings in a simplified schematic manner, and the repeated elements may be represented by the same reference numerals.

FIG. 1 is a block diagram of a wearable device 100 having an authentication function according to an embodiment of the present invention. The wearable device 100 with authentication function is used to sense the wearer's physical state and transmit encrypted authentication information to the card reader (not shown). The wearable device 100 having the authentication function includes a wearable body 110, a sensing module 120, a processor 130, a memory unit 140, an encryption chip 150, a radio frequency module 160, an antenna 170, a display module 180, and a power module. 190.

The wearable body 110 can be a watch, a waist ring, a bracelet, a necklace, a ring, or glasses. The wearable body 110 of the present embodiment is a wristwatch that is worn on the wrist of the wearer and can replace the voucher in the health insurance card, so that the wearer can view the medical treatment without carrying the health insurance card.

The sensing module 120 is disposed on the wearable body 110, and the sensing module 120 includes a heartbeat sensor, a blood pressure sensor, a body temperature sensor or a vibration sensor, and can sense the wearer's physical state and output A class of physiological signals. In detail, the heartbeat sensor is used to sense the heartbeat; the blood pressure sensor is used to sense the blood pressure; the body temperature sensor is used to sense the body temperature; and the vibration sensor is used to sense the magnitude and the number of times the wearable body 110 is vibrated. These sensors can sense a variety of physiological information for analysis and judgment by doctors or caregivers.

The processor 130 is disposed in the wearable body 110. The processor 130 is connected to the sensing module 120 and receives an analog physiological signal. The processor 130 converts the analog physiological signal into a digital physiological signal for signal processing by the module at the back end.

The memory unit 140 is disposed in the wearable body 110 and connected to the processor 130 by a signal. The memory unit 140 receives and stores the digital physiological signals, and the memory unit 140 stores one of the wearer's personal information. By storing the important digital physiological signals, personal information, and the key required to encrypt the wafer 150 by the memory unit 140, the health insurance certificate can be successfully completed.

The encrypted chip 150 is also disposed in the wearable body 110, and the encrypted chip 150 is connected to the processor 130 and the memory unit 140. The encrypted chip 150 receives the digital physiological signal and the personal information, and the encrypted chip 150 converts the digital physiological signal and the personal information into an encrypted digital physiological signal and an encrypted personal information, respectively. In this embodiment, the information and the signal are transmitted more securely through the encryption chip 150, which can greatly reduce the risk of stealing or leaking the health insurance information and personal information after being stolen by the interested person.

The RF module 160 is disposed within the wearable body 110. The RF module 160 signals the encrypted chip 150 and receives the encrypted digital physiological signal and the encrypted personal information. In addition, the radio frequency module 160 generates a carrier and carries the encrypted digital physiological signal and the encrypted personal information on the carrier to form an encrypted authentication information. The carrier has a transmission frequency, and the transmission frequency of the embodiment is 13.56 MHz. In other words, it conforms to the frequency band of Near Field Communication (NFC). Through NFC's fast sensing and non-contact transmission, it can not only shorten the working time of traditional health insurance card readers, but also reduce the risk of vector transmission caused by contact.

The antenna 170 is disposed on the wearable body 110, and the antenna 170 is connected to the RF module 160 and receives the encrypted authentication information. The antenna 170 can completely transmit the encrypted authentication information to the card reader 310, and its operation frequency The segment is also 13.56MHz. The antenna 170 and the radio frequency module 160 of the embodiment are matched to each other, and can transmit a stable radio frequency signal to the card reader 310.

The display module 180 is disposed on the wearable body 110. The display module 180 is connected to the processor 130 and the memory unit 140, and displays digital physiological signals and personal information. In this embodiment, the display module 180 corresponds to the screen of the watch, and the display of the screen allows the wearer to know his current physical state.

The power module 190 is also disposed in the wearable body 110. The power module 190 provides power to the sensing module 120, the processor 130, the memory unit 140, the encryption chip 150, the radio frequency module 160, and the display module 180. The internal circuit structure of the power module 190 is a conventional technique and will not be described again.

FIG. 2 is a block diagram of a wearable device 200 having an authentication function according to another embodiment of the present invention. As shown in the figure, the wearable device 200 with authentication function is used to sense the physical state of the wearer, and the encrypted authentication information can be transmitted in two ways. One way is to transmit the encrypted authentication information through the antenna 270. The encrypted authentication information is first transmitted to the card reader 310 and then transmitted to the cloud server 320 through wireless transmission; and the other method is to transmit the encrypted authentication information to the cloud server 320 directly through the wireless transmission method. Moreover, the wearable device 200 having the authentication function includes a wearable body 210, a sensing module 220, a processor 230, a memory unit 240, an encryption chip 250, a radio frequency module 260, an antenna 270, and a second radio frequency module 260a. The second antenna 270a, the display module 280, and the power module 290.

Referring to FIG. 1 and FIG. 2, the wearable body 210, the sensing module 220, the processor 230, the memory unit 240, the encrypted chip 250, the RF module 260, the antenna 270, the display module 280, and the power supply are provided. The module 290 and the wearable body 110, the sensing module 120, the processor 130, the memory unit 140, the encryption chip 150, the RF module 160, the antenna 170, the display module 180, and the power module 190 in FIG. The blocks are the same and will not be described again. In particular, the wearable device 200 having the authentication function of the embodiment of FIG. 2 further includes a second RF module 260a and a second antenna 270a. The second RF module 260a is disposed in the wearable body 210. The second RF module 260a signals the encrypted chip 250 and receives the encrypted digital physiological signal and the encrypted personal information. The second RF module 260a generates a second carrier and carries the encrypted digital physiological signal and the encrypted personal information on the second carrier to form a second encrypted authentication information. In addition, the second antenna 270a is disposed on the wearable body 210. The second antenna 270a is connected to the second RF module 260a and the cloud server 320, and the second antenna 270a receives the second encrypted authentication information and transmits through a WiFi transmission, a Bluetooth transmission, and a general packet radio. The communication (GPRS), a third generation communication (3G) or a fourth generation communication (4G) transmits the second encrypted authentication information to the cloud server 320. Therefore, the present invention provides a wearable device 200 with an authentication function, which can be used to transmit the sensed physiological signal to the cloud server 320 via a wireless transmission method by using the wearable device and the sensing module 220, or The measured physiological signals are transmitted to the card reader 310 through the NFC, so that the doctor or the caregiver can read the physiological signals to further diagnose the physical state of the wearer.

Please refer to FIG. 1 and FIG. 3 together. FIG. 3 is a schematic diagram showing the wearable device 100 with the authentication function applied to the health insurance authentication system of FIG. 1 . As shown, the authentication system 300 of the wearable device with authentication function includes a wearable device 100 having an authentication function, a card reader 310, a cloud server 320, and a medical station 330.

The card reader 310 wirelessly connects the antenna 170 and receives the encrypted authentication information through the 13.56 MHz NFC transmission mode, and the card reader 310 transmits and outputs the encrypted authentication information through the wireless transmission mode. The wireless transmission mode is WiFi transmission, Bluetooth transmission, GPRS transmission, 3G transmission or 4G transmission. In addition, the cloud server 320 signals the card reader 310 and the medical station 330. The cloud server 320 receives and stores the encrypted authentication information, and the cloud server 320 decrypts and checks the encrypted authentication information to generate an authentication result. When the decryption mechanism of the cloud server 320 corresponds to the encryption mechanism of the encryption chip 150, the authentication result is correct; otherwise, when the decryption mechanism of the cloud server 320 does not correspond to the encryption mechanism of the encryption chip 150, the authentication result is an error. In other words, the decryption mechanism of the cloud server 320 must decrypt the encrypted authentication information completely and correctly in order to obtain the correct authentication result. Therefore, the authentication system 300 of the wearable device with the authentication function of the present invention cooperates with the wearable device 100 having the authentication function by using the sensing module 120, and can transmit the sensed physiological signal to the wireless transmission mode or the card reader 310. Transferred to the cloud server 320. In addition, the decryption mechanism of the cloud server 320 can completely and correctly decrypt the encrypted authentication information to obtain the correct authentication result, and the doctor or the nursing staff can wirelessly transmit to the cloud server through the medical station 330 or the smart phone. The device 320 reads the physiological signal of the wearer to further diagnose whether the wearer's physical condition is normal.

Please refer to FIG. 2 and FIG. 4 together. FIG. 4 is a schematic diagram showing the wearable device 200 with the authentication function applied to the health insurance authentication system of FIG. 2 . As shown, the authentication system 300a of the wearable device with authentication function includes a wearable device 200 having an authentication function, a card reader 310, a cloud server 320, and a medical station 330.

Referring to FIG. 3, in the embodiment of FIG. 4, the card reader 310, the cloud server 320, and the medical station 330 are the same as those in the third embodiment, and will not be described again. In particular, the wearable device 200 with the authentication function of FIG. 4 can transmit physiological signals by using two channels, one of which is a 13.56 MHz NFC transmission mode, and the other channel is another wireless transmission mode, for example, WiFi transmission, Bluetooth. Transmission, GPRS transmission, 3G transmission or 4G transmission, this two-channel transmission can greatly increase the convenience of the wearer.

In addition, it is worth mentioning that the antennas 170 and 270 of FIGS. 1 and 2 can receive the authentication response signal from the card reader 310, and the RF modules 160 and 260 of FIGS. 1 and 2 include the first amplifier and automatic gain control. Loop, phase-locked loop, control unit, tag unit and second amplifier. The first amplifier signal is coupled to the antennas 170, 270, and the first amplifier amplifies the authentication response signals from the antennas 170, 270. The automatic gain control loop signal is connected to the first amplifier, and the first amplifier stably amplifies the authentication response signal by means of a feedback method to form an amplified authentication response signal. Furthermore, the phase locked loop signal is connected to the first amplifier and receives the amplified authentication response signal. And the consistent signal, and the phase-locked loop generates a carrier and a phase-locked clock. The control unit then signals the first amplifier to the phase-locked loop. The control unit receives the amplified authentication response signal, the carrier wave, and the phase-locked clock, and detects changes in the load impedance. The control unit generates an enable signal based on a change in load impedance. In addition, the tag unit signal is connected to the control unit for storing a tag information. The control unit transmits the authentication response signal to the tag unit and provides the phase-locked clock as the driving clock of the tag unit. The tag unit also varies the load impedance according to the tag information, and the control unit switches the drive clock according to the change of the load impedance. As for the second amplifier, the signal is connected to the control unit and the antennas 170, 270. The second amplifier is used to amplify the encrypted authentication information and transmit the amplified encrypted authentication information to the antennas 170, 270, and then transmit the encrypted authentication information to the read through the antennas 170, 270. In the card machine 310. Thereby, the circuit operation of the RF modules 160 and 260 is combined with the encryption mechanism of the encryption chip 150 and 250, so that the wearer's health insurance card data and personal information can be transmitted safely, and the quality of the medical treatment is improved and the medical treatment is effectively saved. time.

It can be seen from the above embodiments that the present invention has the following advantages: First, the wearable device and the sensing module can instantly transmit the sensed physiological signal to the medical staff through wireless transmission. Secondly, the application of the health insurance certificate can be realized through the encrypted wafer combined with the wearable device, and the voucher of the health insurance card can be replaced when the doctor is in medical treatment, and the wearer does not need to carry the additional health insurance card, which is both safe and convenient. Third, in the transmission condition of the NFC band, fast sensing and non-contact transmission can be realized, which can not only shorten the transmission. The operating time of the health insurance card reader and the time saved for the visit can also reduce the risk of vector transmission caused by contact.

Although the present invention has been disclosed in the above embodiments, it is not intended to limit the present invention. Any one skilled in the art can make various changes and retouchings without departing from the spirit and scope of the present invention. The scope is subject to the definition of the scope of the patent application attached.

100‧‧‧Wearing device with certification function

110‧‧‧Wearing ontology

120‧‧‧Sensor module

130‧‧‧Processor

140‧‧‧ memory unit

150‧‧‧Encrypted Wafer

160‧‧‧RF Module

170‧‧‧Antenna

180‧‧‧ display module

190‧‧‧Power Module

Claims (12)

A wearable device having an authentication function for sensing a physical state of a wearer and transmitting an encrypted authentication information to a card reader, the encrypted authentication information including the health care card information of the wearer, the wearable device having the authentication function The device includes: a wearable body; a sensing module disposed on the wearable body, the sensing module sensing the body state and outputting an analogy physiological signal; and a processor disposed on the wearable body The processor signal is connected to the sensing module and receives the analog physiological signal. The processor converts the analog physiological signal into a digital physiological signal. A memory unit is disposed in the wearable body and the signal is connected to the processor. The memory unit receives and stores the digital physiological signal, and the memory unit stores personal information of the wearer; an encrypted chip is disposed on the wearable body, the encrypted chip signal is connected to the processor and the memory unit, and the encrypted chip receives The digital physiological signal and the personal information, and the encrypted chip converts the digital physiological signal and the personal information into an encryption separately a physiological signal and an encrypted personal information, the encrypted authentication information including the encrypted digital physiological signal and the encrypted personal information; a radio frequency module disposed on the wearable body, the RF module signal connecting the encrypted chip and receiving the encryption The digital physiological signal and the encrypted personal information, and the radio frequency module generates a carrier, and the encrypted digital physiological signal and the encrypted personal information are carried on the carrier to form the encrypted authentication information, the carrier has a transmission frequency; An antenna is disposed on the wearable body, the antenna signal is connected to the radio frequency module and receives the encrypted authentication information, and the antenna transmits the encrypted authentication information to the card reader. The wearable device with the authentication function described in claim 1 further includes: a display module disposed on the wearable body, the display module signal connecting the processor and displaying the digital physiological signal and The personal information; and a power module disposed in the wearable body, the power module provides power to the sensing module, the processor, the memory unit, the encrypted chip, the RF module, and the display Module operation. A wearable device having an authentication function as described in claim 1, wherein the transmission frequency is 13.56 MHz. The wearable device with an authentication function according to claim 1, wherein the sensing module comprises a heartbeat sensor, a blood pressure sensor, an integrated temperature sensor or a vibration sensor. The wearable device with the authentication function described in claim 1 further includes: a second RF module disposed on the wearable body, the second RF module signal connecting the encrypted chip and receiving the encryption a digital physiological signal and the encrypted personal information, and the second RF module generates a second carrier, and the The encrypted digital physiological signal and the encrypted personal information are carried on the second carrier to form a second encrypted authentication information. The wearable device with the authentication function described in claim 5, further comprising: a second antenna disposed on the wearable body, the second antenna signal connecting the second RF module and a cloud a server, and the second antenna receives the second encrypted authentication information and transmits through a WiFi transmission, a Bluetooth transmission, a general packet radio communication (GPRS), a third generation communication (3G) or a first The fourth generation communication (4G) transmits the second encrypted authentication information to the cloud server. An authentication system for a wearable device having an authentication function for sensing a physical state of a wearer, the authentication system of the wearable device having an authentication function comprising: a wearable body; a sensing module disposed at the a wearable body, the sensing module senses the physical state and outputs an analog physiological signal; a processor is disposed on the wearable body, the processor signal is connected to the sensing module and receives the analog physiological signal, The processor converts the analog physiological signal into a digital physiological signal; a memory unit is disposed in the wearable body and the signal is connected to the processor, the memory unit receives and stores the digital physiological signal, and the memory unit stores the wearer One personal information; An encrypted chip is disposed on the wearable body, the encrypted chip signal is connected to the processor and the memory unit, the encrypted chip receives the digital physiological signal and the personal information, and the encrypted chip outputs the digital physiological signal and the personal information Converting into an encrypted digital physiological signal and an encrypted personal information; an RF module is disposed on the wearable body, the RF module signal is connected to the encrypted chip and receives the encrypted digital physiological signal and the encrypted personal information, and the RF The module generates a carrier, and the encrypted digital physiological signal and the encrypted personal information are carried on the carrier to form an encrypted authentication information, the carrier has a transmission frequency, and an antenna is disposed on the wearable body, the antenna signal Connecting the RF module and receiving the encrypted authentication information, and the antenna transmits the encrypted authentication information to the card reader; a card reader, the wireless signal is connected to the antenna and receiving the encrypted authentication information, and the card reader passes through a The wireless transmission mode transmits and outputs the encrypted authentication information; and a cloud server connects the card reader to the signal, Client server receiving and storing the encrypted authentication information, and the cloud server decrypts the encrypted authentication information collation and generating an authentication result. The authentication system of the wearable device with the authentication function described in claim 7 , wherein when the decryption mechanism of the cloud server corresponds to the encryption mechanism of the encrypted chip, the authentication result is correct; when the cloud server is When the decryption mechanism is not the encryption mechanism for encrypting the chip, the authentication result is an error. An authentication system for a wearable device having an authentication function as described in claim 7 wherein the transmission frequency is 13.56 MHz. The authentication system of the wearable device with the authentication function described in claim 7 , wherein the sensing module comprises a heartbeat sensor, a blood pressure sensor, an integrated temperature sensor or a vibration sensing Device. The authentication system of the wearable device with the authentication function described in claim 7 further includes: a second RF module disposed on the wearable body, wherein the second RF module signal is connected to the encrypted chip and Receiving the encrypted digital physiological signal and the encrypted personal information, and the second RF module generates a second carrier, and the encrypted digital physiological signal and the encrypted personal information are carried on the second carrier to form a second encryption. Certification information. The authentication system of the wearable device with the authentication function described in claim 11 further includes: a second antenna disposed on the wearable body, the second antenna signal being connected to the second RF module And the cloud server, and the second antenna receives the second encrypted authentication information and transmits a WiFi transmission, a Bluetooth transmission, a general packet radio communication (GPRS), and a third generation. The communication (3G) or a fourth generation communication (4G) transmits the second encrypted authentication information to the cloud server.