TWM531014U - Medical aid system - Google Patents

Description

Medical support system

This creation relates to a medical assistance system, and in particular to a medical assistance system that automatically senses the physiological state of a patient.

With the advancement of medical technology, the complexity of medical work has increased dramatically, and medical institutions require medical personnel to improve the quality and efficiency of medical work. In addition to professional care work (eg, identity check, drug delivery, injection, volume) Measuring physiological data, etc.), it is also necessary to assist in the handling of the work, so that the workload of the already shortage of nursing staff has increased significantly.

At present, Radio Frequency Identification (RFID) tags have been used as a technology for identifying patients or drugs. However, RFID tags can only passively respond to the information stored in the RFID signal after receiving the energy of the identifier. Does not have the function of measuring the physiological information of patients. In general, the patient's physiological information (eg, body temperature, blood pressure, heart rate, blood sugar, etc.) needs to be measured, recorded, and organized by the caregiver, and the heavy and overtime workload causes the caregiver's turnover. In the case of insufficient number of in-service nursing staff, the workload of existing medical staff is increased, creating a vicious circle. Therefore, there is an urgent need for automated medical aids that can effectively reduce the workload of caregivers.

To achieve the above objectives, the present invention provides a medical assistance system comprising: wearing Devices and mobile care vehicles. The wearable device includes: a first storage module, a sensing module, a first processing module, and a first communication module, wherein the first storage module stores the identity information of the user and the identification code of the sensing module. The sensing module is configured to sense a physiological state of the user to generate a sensing signal, and the first processing module is configured to edit the identity information, the identification code, and the sensing signal to generate a sensing signal packet of the user, and the first communication module The group is used to transmit the sensing signal packet of the user. The mobile care vehicle includes: a second communication module, a second storage module, and a second processing module, wherein the second communication module is configured to receive a sensing signal packet of the user from the first communication module, and the second storage module The group stores at least one analysis program for analyzing the sensing signal, and the second processing module is configured to generate the physiological information of the user according to the sensing signal packet and the analysis program of the user.

In one embodiment, the wearable device sets an encrypted identification code to the wearable device through the mobile care vehicle before use, and the mobile care vehicle obtains an encrypted identification code corresponding to the wearable device to make the wearable device The above-mentioned sensing signal packet transmitted by the device can only be accessed by the above-mentioned mobile care vehicle.

In one embodiment, the sensing module periodically detects the physiological state of the user to generate the sensing signal, and the first processing module encapsulates the sensing signal of the user generated after each sensing. After the first communication module receives the notification transmission command of the second communication module, the first communication module transmits the sensing signal packets of the user to the first Two communication modules.

In one embodiment, the second communication module sends a scan signal, and after the first communication module receives the scan signal, the first processing module generates a start sensing command, so that the sensing module detects the user Physiological state.

In an embodiment, the medical auxiliary system includes: a storage unit and a switch The module, wherein the storage unit is configured to place the medicine of the user, and the switch module is used to open or close the storage unit. The second storage module stores the identity information of the user, and the second processing module determines that the identity information of the user in the sensing signal packet of the user is consistent with the storage of the second storage module. After the user's identity information, the second processing module generates a medicine taking instruction, and the switch module opens the storage unit for the user to take the medicine after receiving the medicine taking instruction.

In one embodiment, the storage unit includes a container loaded with the drug, and after the storage unit is opened, when the container loaded with the drug is not used by the user for a period of time, the second processing module generates a drug. A warning signal to be taken.

In an embodiment, the second processing module selects the analysis program according to the identification code.

In an embodiment, the second storage module stores the identity information of the user, and after the second communication module receives the physiological signal packet of the user, the second processing module determines the user Whether the identity information in the sensing signal packet is the same as the identity information stored in the second storage module, and if the determination is not the same, the second processing module generates a warning signal; if the determination is the same, the The second processing module generates the physiological information of the user according to the sensing signal packet of the user and the analysis program.

In one embodiment, the mobile care vehicle further includes: a display module configured to display the physiological information or the warning signal of the user.

In one embodiment, the medical assistance system further includes: a medical server connected to the network, wherein the second communication module transmits the physiological condition of the user via the network Information is transmitted to the medical server.

The medical assistance system of the present invention comprises a wearable device and a mobile care device, the wearable device can automatically sense the physiological state of the user and generate a sensing signal packet of the user, and the mobile nursing car stores an analysis program useful for analyzing the sensing signal. And the physiological information of the user can be generated according to the user's sensing signal packet and the analysis program, thereby the medical auxiliary system of the creation can automatically sense the physiological state of the patient, thereby reducing the workload of the nursing staff and improving medical treatment. The quality of the service.

1,2‧‧ medical aid system

11,21‧‧‧Wearing device

12,22‧‧‧Mobile care car

13‧‧‧ medical server

100‧‧‧Network

110‧‧‧Flexible substrate

111,211‧‧‧First storage module

112,212‧‧‧Sensing module

113,213‧‧‧First Processing Module

114,214‧‧‧First communication module

120‧‧‧Electronic devices

121,221‧‧‧Second communication module

122,222‧‧‧Second storage module

123,223‧‧‧Second processing module

124,224‧‧‧ display module

225‧‧‧ Storage unit

226‧‧‧Switch Module

227‧‧‧Mobile Module

228‧‧‧Power Module

225a‧‧‧ Container

226b‧‧‧Dosing tank

225c‧‧"Recycling tank

1 is a block diagram of a first embodiment of a medical assistance system of the present invention; FIG. 2 is a schematic diagram of a usage scenario of a first embodiment of the medical assistance system of the present invention; and FIG. 3 is a second embodiment of the present invention A block diagram of the medical assistance system; and Fig. 4 is a schematic view showing the appearance of the mobile care vehicle of the second embodiment of the present invention.

The embodiments of the present invention are described below with reference to the specific embodiments, and those skilled in the art can readily understand the advantages and functions of the present invention from the disclosures disclosed herein. The present invention may be embodied or applied by other different embodiments. The details of the present specification may also be based on different opinions and applications, and various modifications and changes may be made without departing from the spirit of the present invention.

Figure 1 is a block diagram of the medical assistance system of the creation, and Figure 2 is a schematic diagram of the use of the medical assistance system of the creation. As shown in FIGS. 1 and 2, the medical assistance system 1 includes a wearable device 11 and a mobile care vehicle 12.

The wearable device 11 includes a first storage module 111, a sensing module 112, a first processing module 113, and a first communication module 114. The first storage module 111 stores user identity information and a sensing module. The identification code of group 112. The sensing module 112 is configured to sense a physiological state of the user to generate a sensing signal. The first processing module 113 generates a sensing signal packet of the user according to the user identity information, the identification code and the sensing signal, and the first communication module 114 is configured to transmit the sensing signal packet of the user.

In one embodiment, the first processing module 113 generates an encrypted identification code corresponding to the wearable device 11 through a specific encryption or encoding program according to the user's identity information and the identification code of the sensing module 112. The first processing module 113 generates the sensing signal packet according to the sensing signal sensed by the encryption identification code and the sensing module 112. Then, the first communication module 114 transmits the sensing signal packet to the mobile care vehicle 12. When the mobile care car 12 receives the sensing signal packet, the second processing module 123 executes a corresponding decryption or de-encoding program to obtain the identity information of the user from the encrypted identification code.

It should be noted that the decryption or de-encoding program of each of the mobile care vehicles 12 may be the same, but since the wearable device 11 first sets the wearable device 11 through the mobile care vehicle 12 before use, only the settings are made. The mobile care car 12 has encrypted information of the wearable device 11, such as the identity information of the user and/or the identification code of the sensing module 112. Furthermore, only the mobile care vehicle 12 that performs the setting can access the sensing signal sensed by the wearable device 11. When receiving the sensing signal packet, the second processing module 123 performs a corresponding decryption or decoding process according to the identity information or the identification code of the sensing module 112 to obtain the sensing module from the encrypted identification code. 112 identification code or identity information of the user. Briefly, in an embodiment, the second processing module 123 performs a corresponding decryption or de-encoding program according to the identity information to identify from the encryption. The identification code of the sensing module 112 is obtained in the code, and the received sensing signal packet is determined to be correct according to the identification code of the known sensing module 112.

In an embodiment, when the first communication module 114 and the second communication module 121 on the care car 12 are wirelessly connected or handed over, the first communication module 114 actively transmits the sensing signal packet to the first communication module 114. The second communication module 121. In another embodiment, when the first communication module 114 receives a request signal from the second communication module 121, the first communication module 114 transmits the sensing signal packet to the second communication module 121. In another embodiment, the first communication module 114 sends the sensing signal packet in a broadcast manner.

Specifically, the wearable device 11 has a flexible substrate 110 (for example, a resin material) for being worn on a user (for example, a head, a body, a hand or a foot), a first storage module 111, and a sensing mold. The functional circuits such as the group 112, the first processing module 113, and the first communication module 114 are electrically connected to each other and disposed on the flexible substrate 110.

The first storage module 111 includes non-volatile memory (eg, read-only memory ROM, electronic erasable rewritable read-only memory EEPROM, flash memory FlashMemory) for writing and storing the sensing module. The digitized data of the driver, the user's identity information, and the identification code of the sensing module 112, wherein the user's identity information includes the user's identity card number, telephone number, registration number or physiological characteristics (eg, fingerprint , face image).

The sensing module 112 is, for example, a sensing circuit of physical signals such as light, electricity, magnetism, pressure, sound, displacement, or temperature. The sensing module 112 can sense the physiological state of the user via contact or non-contact. An analog or digital sensing signal is generated. The identification code of the sensing module 112 stored in the first storage module 111 indicates the circuit type and signal type of the sensing module 112.

The first processing module 113 is a system chip including a central processing unit and peripheral circuits. (System on Chip), the first processing module 113 can edit the identity information of the user stored in the first storage module 111 and the identification code of the sensing module 112 and the sensing signal generated by the sensing module 112. A signal packet that conforms to a specific communication protocol.

The first communication module 114 is a wireless communication circuit that supports at least one wireless communication protocol, including but not limited to Near Field Communication (NFC), Bluetooth, Zigbee, and ANT ⁺ . In this embodiment, the first communication module 114 is a Bluetooth Low Energy (BLE) communication module, and after receiving the BLE sensing signal packet generated by the first processing module 113, A communication module 114 can actively or passively transmit a BLE sensing signal packet of the user.

The wearable device 11 includes a battery module (not shown) for supplying electrical energy. The wearable device 11 may further include a connection port (for example, a universal serial bus USB) for connecting an external device such as a power source, a precision detecting instrument, a pump, a motor, or the like. In general use (eg, sensing light, electricity, magnetism, sound, displacement, or temperature), the wearable device 11 can perform sensing operations independently, and in specific situations (eg, measuring blood pressure), can be connected by a transmission line, respectively. The port of the wearable device 11 is connected to an external device (eg, a pump) to perform sensing operations, or to receive/transmit the required programs or information.

The mobile device 12 includes a second communication module 121, a second storage module 122, and a second processing module 123. The second communication module 121 is configured to receive a sensing signal packet of the user from the first communication module 114. The second storage module 122 stores an analysis program for analyzing the sensing signals. The second processing module 123 is configured to generate physiological information of the user according to the sensing signal packet and the analysis program of the user.

Specifically, the mobile care car 12 can be provided with an electronic device 120 having a computing and mobile communication function, a second communication module 121, a second storage module 122, and a second processing module 123. The display modules 124 are electrically connected to each other and disposed in the electronic device 120.

The second communication module 121 is a wireless communication circuit and supports at least one communication protocol including: NFC, Bluetooth, Zigbee, ANT ⁺ , Wi-Fi, third generation (3G) or fourth generation (4G) mobile communication technology. The second communication module 121 can receive or transmit signal packets of different communication protocols. In this embodiment, the second communication module 121 can receive or send Bluetooth, BLE, Wi-Fi, and 3G or 4G communication protocol signal packets.

In this embodiment, the sensing module 112 can be configured to periodically sense (eg, seconds, minutes, or hours) to sense the physiological state of the user to generate a sensing signal. The first processing module 113 The sensor's sensing signal packet generated by each sensing is stored in the first storage module 111. When the nursing staff carries the mobile nursing car 12 to the patient's location, the nursing staff utilizes the input mode of the mobile nursing car 12. The group 125 (for example, a touch panel or a keyboard) inputs an instruction to notify the wearable device 11 to transmit a sensing signal of the patient's physiological state, and after the first communication module 114 receives the notification transmission instruction sent by the mobile care vehicle 12, A communication module 114 transmits the respective sensing signal packets of the patient to the second communication module 121. In other words, the mobile care vehicle 12 can obtain a plurality of sensing signals corresponding to the physiological state of the patient for a period of time to further determine the condition of the patient.

In another embodiment, when the caregiver carries the mobile care car 12 to the patient's location, the caregiver inputs an instruction using the input module 125 of the mobile care car 12 (eg, a touch panel or a keyboard, etc.), the second communication mode. The group 121 sends a scan signal. After the first communication module 114 receives the scan signal, the first processing module 113 and the first communication module 114 respond to the scan signal to establish a connection with the second communication module 121. The first processing module 113: generating a sensing command to enable the sensing module 112 to sense the physiological state of the patient, and generating a sensing signal seal for the physiological state of the patient in the first processing module 113 The first communication module 114 transmits the sensing signal packet of the patient's physiological state to the second communication module 121.

The second storage module 122 stores an analysis program for analyzing physical signals such as light, electricity, magnetism, pressure, sound, displacement, or temperature, and inputs the sensing signals into various analysis programs to obtain physiological information having specific meanings. The second processing module 123 reads the identification code in the sensing signal packet of the user to determine the type of the sensing signal, and then selects an analysis program corresponding to the identification code in the second storage module 122. The second processing module 123 is configured according to the second processing module 123. The physiological signals generated by the program operation sensing module 112 generate the sensing signals, such as body temperature, heart rate, posture, electrocardiogram, respiratory number, blood pressure, blood sugar, blood oxygen concentration, and brain waves. The second processing module 123 can store the physiological information of the analyzed user on the second storage module 122, and can transmit the physiological information of the analyzed user to the display module 124 for display. Physiological information of the user.

The wearable device 11 continuously or immediately senses the physiological state of the patient, and transmits the sensing signal packet of the patient's physiological state to the mobile care vehicle 12. The caregiver does not need to manually measure and record the physiological condition of the patient. Status, which greatly reduces the workload of the caregiver.

In addition, in order to avoid human error, the second storage module 122 may pre-store the user's identity information, and after the second communication module 121 receives the sensing signal packet of the user transmitted by the first communication module 114, The second processing module 123 determines whether the identity information in the sensing signal packet of the user is the same as the identity information stored in the second storage module 122. If the second processing module 123 determines that the two identity information is different, The second processing module 123 generates an alert signal, and the display module 124 displays an alert signal to prompt the caregiver. The second processing module 123 can further compare the identity information and the second storage module in the user's sensing signal packet. Information on the identity of other users stored in 122 to ascertain the cause of the user identity or the error of the person receiving the sensor; The processing module 123 determines that the two pieces of identity information are the same, and the second processing module 123 generates the physiological information of the user according to the user's sensing signal packet and the analysis program.

In this embodiment, the medical assistance system 1 may further include a medical server 13 connected to the network 100, which may be an internet or a regional network. After the second processing module 123 generates the physiological information of the user, the second processing module 123 can transmit the physiological information of the user to the second communication module 121, and the second communication module 121 can utilize Wi-Fi and 3G. Or 4G wireless communication technology transmits the physiological information of the user to the medical server 13 via the network 100 to record the physiological information of the user, and the nursing staff does not need to go to the ward and the nursing station to manually sense the physiological state of the patient. Input to the medical server, whereby the caregiver can increase the time spent caring for the patient, thereby improving the quality of the medical service.

In another embodiment, the mobility car 12 can have different functions depending on time. For example, during the day (eg, 6:00 to 18:00 of the day, or 7:00 to 19:00 of the day, etc.), the function of the mobile care vehicle 12 may be a medical aid that assists the medical staff in providing the patient's medication. At night (for example, from 18 o'clock in the day to 6 o'clock on the next day, or from 19 o'clock in the day to 7 o'clock on the next day, etc.), the action car 12 can perform automatic rounds according to the preset route, and receive the wear on the patient. Sensing data of the wearable device on the body to obtain physiological information of the patient.

3 is a block diagram of the medical assistance system of the second embodiment of the present invention, and FIG. 4 is a schematic view showing the appearance of the mobile care vehicle of the second embodiment. As shown in FIGS. 3 and 4, the medical assistance system 2 includes a wearable device 21 and a mobile care vehicle 22. The wearable device 21 that is worn on the user (patient) includes a first storage module 211, a sensing module 212, a first processing module 213, and a first communication module 214. The function of the wearable device 21 is as in the first embodiment of the present invention. Said.

The mobile care vehicle 22 further includes a storage unit 225, a switch module 226, a mobile module 227, and electric energy, in addition to the second communication module 221, the second storage module 222, the second processing module 223, and the display module 224. Module 228. The storage unit 225 is used to place a user's medicine. The switch module 226 is used to open or close the corresponding storage unit 225. The mobile module 227 can be manually or automatically operated to move the mobile care vehicle 22. The power module 228 (for example, a large-capacity lithium battery) can be charged by using an AC power of 110V or 220V to supply the power required by the mobile care vehicle 22 for a long time (for example, several hours to several tens of hours).

In the present embodiment, the storage unit 225 further includes a container 225a for displacing the drug, a dosing tank 225b for loading the drug, and a recovery tank 225c for placing the drug. In addition to the container 225a of the drug.

During the daytime period, the medical staff can use the second communication module 222 of the mobile care car 22, the display module 224 or other operation interface (eg, keyboard, not shown) before the medical staff uses the mobile care vehicle 22 to deliver the medicine. The identity information, medical record information, prescription information, identification information, and the like of each patient are input to the second storage module 222 of the mobile care vehicle 22.

Next, the mobile care car 22 moves to the pharmacy to load the drug, and the pharmacy staff or the existing automatic dispensing system (not shown) places the drugs of each user in each storage unit 225 according to the information of each patient. The person can transmit the drug information and the identity information of the patient of each storage unit 225 to the second communication module 222 by using a wired or wireless data transmission method (for example, Wi-Fi), and the second processing module 223 compares the storage units 225. The drug information and the identity information of the patient are provided for the first time for the pharmacist to confirm whether the drugs placed in each patient in each storage unit 225 meet the requirements of the doctor to open to each patient. When the second processing module 223 compares the information of the patient When the drug information of the storage unit 225 is not met, the second processing module 223 generates a warning signal for the drug placement error to notify the drug personnel to check and replace the drug.

Then, the mobile care vehicle 22 is moved back to the nursing station, and the medical staff inputs a password (for example, a certificate number or a bar code representing the medical staff identity) and checks through the operation interface of the second communication module 221 or the display module 224 of the mobile care vehicle 22 The medicine module, the switch module 226 sequentially opens the corresponding storage unit 225, and the display module 224 synchronously displays the patient information, so that the medical staff can confirm the medicines of each patient placed in each storage unit 225 for the second time. The medical prescription information stored by the storage module 222 and the medical information input by the pharmacy personnel.

The second communication module 222 of the mobile care vehicle 22 can automatically receive the sensing signal packet transmitted by the first communication module 214 of the wearable device 21 on the patient when the mobile care vehicle 22 assists the nursing staff to perform the drug delivery work. The second processing module 223 determines whether the identity information in the sensing signal packet of the patient meets the patient identity information stored by the second storage module 222. If the second processing module 223 determines that the result is consistent, the second processing module 223 generates a medicine taking instruction, and the switch module 226 corresponding to the patient identity information opens the storage unit 225 for the patient to take the medicine after receiving the medicine taking instruction.

When the second processing module 223 determines that the sensing signal packet does not match the patient identity information of the second storage module, the second processing module 223 generates a warning signal of the patient error to prompt the nursing staff to handle the abnormal state.

After the storage unit 225 conforming to the patient identity information is turned on, when the drug-filled container 225a is not taken by the patient (for example, the container placed in the administration tank is not moved) for a certain period of time (for example, tens of seconds to several minutes) The second processing module 223 generates a warning signal that the medicine is not taken to prompt the medical staff that the patient has not taken the medicine.

In this embodiment, the mobile module 227 includes a detecting unit and a navigation unit (not shown). The detecting module may be a plurality of existing photoelectric components for detecting objects within a certain distance (for example, but not limited to, ultrasonic, infrared, The laser is used to detect an object in the vicinity of the mobile care vehicle 22 or an indoor micro-positioning component (for example, a radio frequency identification tag RFID, a beacon beacon) on the moving route to generate detection data. The second storage module 222 can further store the predetermined movement route of the mobile care vehicle 22, and the second processing module 124 transmits the predetermined movement route stored by the second storage module 222 to the navigation unit, and the navigation unit is based on the detection data and the movement. The route generates positioning information, and the mobile module 227 can adjust the moving speed and direction of the mobile care car 22 according to the detected data, the positioning data, and the moving route data. In other embodiments, the mobile module 227 can further provide a receiving unit and a transmitting unit (not shown). The receiving unit is configured to receive the remote control signal of the remote control device, and the medical staff can operate the mobile care vehicle to move by using the remote control device. The launching unit is used to transmit control signals of the elevator and the door so that the mobile care car 22 can be automated to different floors and rooms. The structure and function of the mobile module 227 can be referred to various commercial robots. Thereby, during the nighttime period, the creative action car of the present invention can automatically move to the ward according to the preset route to receive the sensing signal package of the wearable device worn on the patient to obtain the physiological information of the patient.

In summary, the medical assistance system of the present invention comprises a wearable device and a mobile care device. The wearable device can automatically sense the physiological state of the user and generate a sensing signal packet of the user, and the mobile care vehicle stores useful for analyzing the physiological condition. The analysis program of the signal, and the physiological information of the user can be generated according to the user's sensing signal packet and the analysis program, thereby the medical auxiliary system of the creation can automatically measure the physiological state of the patient, thereby reducing the workload of the nursing staff. To improve the quality of medical services.

The above embodiments are merely illustrative of the principles of the present invention and their effects, rather than Limit this creation. Anyone who is familiar with this subject can modify and change the above embodiments without departing from the spirit and scope of this creation. Therefore, all equivalent modifications or changes made by those skilled in the art without departing from the spirit and the principles of the invention disclosed herein are still covered by the scope of the invention.

1‧‧ medical aid system

11‧‧‧Wearing device

12‧‧‧Mobile care car

13‧‧‧ medical server

100‧‧‧Network

111‧‧‧First storage module

112‧‧‧Sensor module

113‧‧‧First Processing Module

114‧‧‧First communication module

121‧‧‧Second communication module

122‧‧‧Second storage module

123‧‧‧Second processing module

124‧‧‧Display module

Claims (10)

A medical auxiliary system comprising: a wearable device, comprising: a first storage module, a sensing module, a first processing module, and a first communication module, wherein the first storage module stores user identity information And the sensing module of the sensing module, the sensing module is configured to sense the physiological state of the user to generate a sensing signal, and the first processing module edits the identity information, the identification code, and the physiological signal. Generating a sensing signal packet of the user, the first communication module is configured to transmit the sensing signal packet of the user; and the mobile care vehicle comprises: a second communication module, a second storage module, and a second a processing module, wherein the second communication module is configured to receive the sensing signal packet of the user from the first communication module, and the second storage module stores at least one analysis program for analyzing the sensing signal The second processing module is configured to generate the physiological information of the user according to the sensing signal packet of the user and the analysis program. The medical assistance system of claim 1, wherein the wearable device sets an encrypted identification code to the wearable device through the mobile care vehicle, and the corresponding wearable device is obtained by the mobile care device. The encryption identification code is such that the sensing signal packet transmitted by the wearable device can only be accessed by the mobile care vehicle. The medical assistance system of claim 1, wherein the sensing module periodically detects the physiological state of the user to generate the sensing signal, and the first processing module generates the sensor after each sensing. The sensing signal packet of the user is stored in the first storage module, and after the first communication module receives the notification transmission command of the second communication module, the first communication module is the user Each of the sensing signal packets is transmitted to the second communication module. The medical assistance system of claim 1, wherein the second communication module sends a scan signal, and after the first communication module receives the scan signal, the first processing module generates a start sensing command to The sensing module senses the physiological state of the user. The medical assistance system of claim 1, wherein the mobile care vehicle comprises: a storage unit for placing the user's medicine; and a switch module for opening or closing the storage unit; The second storage module stores the identity information of the user, and the second processing module determines that the identity information of the user in the sensing signal packet matches the user stored in the second storage module. After the identity information, the second processing module generates a medicine taking instruction, and the switch module opens the storage unit for the user to access the medicine after receiving the medicine taking instruction. The medical assistance system of claim 5, wherein the storage unit comprises a container loaded with the medicine, and after the storage unit is opened, when the container loaded with the medicine is not used by the user for a period of time At the time, the second processing module generates a warning signal that the medicine is not taken. The medical assistance system of claim 1, wherein the second processing module selects the analysis program according to the identification code in the sensing signal packet of the user. The medical assistance system of claim 1, wherein the second storage module stores the identity information of the user, after the second communication module receives the sensing signal packet of the user, The second processing module determines whether the identity information in the sensing signal packet of the user is the same as the identity information stored in the second storage module, and if the determination is not the same, the The second processing module generates a warning signal. If the determination is the same, the second processing module generates the physiological information of the user according to the sensing signal packet of the user and the analysis program. The medical assistance system of claim 8, wherein the mobile care vehicle further comprises: a display module for displaying the physiological information or the warning signal of the user. The medical assistance system of claim 1, further comprising: a medical server connected to the network, wherein the second communication module transmits the physiological information of the user to the medical server via the network .