CN203153715U - Multi-parameter long-distance medical monitoring system - Google Patents

Abstract

The utility model discloses a multi-parameter long-distance medical monitoring system comprising a monitoring system, a long-distance server and a central workstation. The monitoring device is used for transmitting monitoring data information collected from a human body to the long-distance server. The long-distance server is used for transmitting the received monitoring data information sent by the monitoring device to the central workstation in real time. The central workstation is in coupling connection with the long-distance server. The multi-parameter long-distance medical monitoring system can be used in a long distance from a hospital and achieves 24-hour continuous monitoring. Besides, the monitoring device is small in size and convenient to carry. Meanwhile, by means of long-distance transmission in a 3G mode, remote consultation for a patient can be achieved, monitoring expands from the inside of the hospital to the outside of the hospital, commodity hospitals outside the hospital and monitoring of family wards are available, and the multi-parameter long-distance medical monitoring system is suitable for managing and monitoring the chronic disease crowd outside the hospital.

Description

Multi-parameter remote medical monitoring system

Technical Field

The utility model relates to a medical engineering technical field particularly, relates to a multi-parameter telemedicine monitor system.

Background

Conventional medical monitoring systems typically consist of a bedside monitor and a central monitoring workstation installed in a patient room. When the bedside monitor monitors a patient, the bedside monitor displays the vital sign parameters of the patient, such as parameter information of electrocardio, respiration, blood pressure, blood oxygen, pulse, body temperature and the like, on a screen of the monitor in real time, performs acousto-optic alarm in time when abnormal data occur, and sends the data to the central monitoring workstation, and the central monitoring workstation can monitor the patient conditions of a plurality of beds in a ward in a real-time centralized manner through the data sent by the bedside monitor so as to send medical care personnel to analyze and diagnose the patient with the abnormal conditions in time.

However, the conventional bedside monitor is bulky, and generally needs to be bound to a bedside for monitoring during monitoring, which greatly limits the application range of the monitor and the activity freedom of the patient, so that the monitor is generally only used in critical wards such as an Intensive Care Unit (ICU) or a Coronary heart disease (CCU) in a hospital, and cannot be applied to non-critical patients suffering from general diseases, such as cardiovascular chronic patients, elderly patients or children patients. Moreover, the traditional medical monitor has no good low-power consumption and electricity-saving performance, the battery working time of one bedside monitor is generally only 2 hours, and the requirement of long-time continuous real-time monitoring when no alternating current exists or the bedside monitor is in a moving state cannot be met.

In addition, the connection mode between the monitor and the central workstation can be a wired mode (for example, a wired local area network is used) or a wireless mode (for example, a WIFI wireless local area network is used), but the range is generally dozens of meters, namely, effective signals can be received only within the range of the department. Because of no good remote wireless real-time communication mode, the monitor bureau can only be used in the department of the hospital, can not be applied to monitoring and observation of the majority of chronic disease patients outside the hospital (such as remote monitoring in a family community ward), and can not meet the requirements of remote monitoring during emergency rescue before the hospital (remote monitoring and treatment at the first time of an emergency rescue site).

Moreover, the central workstation itself is also an "island", and all vital sign information monitored by the central workstation can only be seen locally at the workstation, that is, remote monitoring consultation at different places cannot be performed.

Therefore, how to solve the technical problems that the prior art cannot perform remote consultation at different places, has large equipment volume and inconvenient operation, and is urgently needed to be solved.

SUMMERY OF THE UTILITY MODEL

The utility model provides a multi-parameter remote medical monitoring system to solve the remote consultation that can't carry out the strange land and equipment problem bulky, the inconvenient operation.

In order to solve the above technical problem, the present invention provides a multi-parameter remote medical monitoring system, which is characterized by comprising: a monitoring device, a remote server and a central workstation, wherein,

the monitoring device is coupled with the remote server and is used for transmitting monitoring data information which is collected from a human body and related to vital signs to the remote server;

the remote server is respectively coupled with the monitoring device and the central workstation and is used for forwarding the received monitoring data information sent by the monitoring device to the central workstation in real time;

and the central workstation is coupled with the remote server and is used for receiving the monitoring data information transmitted by the remote server and synchronously displaying the monitoring data information in real time.

Further, wherein the synchronous real-time display is further a display of waveforms and numbers.

Further, wherein the monitoring device comprises: the physiological parameter acquisition component, the data conversion component, the data processing component, the data transmission component, the display component and the power supply component; wherein,

the physiological parameter acquisition element is coupled with the data conversion element and the power supply element and is used for monitoring and acquiring physiological data analog signals and transmitting the physiological data analog signals to the data conversion element;

the data conversion element is coupled with the physiological parameter acquisition element and the data processing element and is used for receiving a physiological data analog signal sent by the physiological parameter acquisition element, converting the physiological data analog signal into a physiological data electric signal and transmitting the physiological data electric signal to the data processing element;

the data processing element is respectively coupled with the data conversion element, the display element, the data transmission element and the power supply element, and is used for receiving the physiological data electric signal sent by the data conversion element, converting the physiological data electric signal into a physiological data digital signal, and sending the physiological data digital signal to the data transmission element and the display element; meanwhile, a key instruction sent by the display element is received, and data operation and processing are carried out according to the key instruction; receiving a judgment result fed back by the data transmission element and sending the judgment result to the display element;

the data transmission element is coupled with the data processing element, the power supply element and the remote server and is used for receiving the physiological data digital signal sent by the data processing element, converting the physiological data digital signal into a physiological data electric signal and transmitting the physiological data electric signal to the remote server; meanwhile, receiving a judgment result fed back by the remote server and transmitting the judgment result to the data processing element;

the display element is coupled with the data processing element and the power supply element and is used for receiving and displaying the physiological data in the digital format sent by the data processing element; meanwhile, a key instruction is generated according to the key operation of an operator and is sent to the data processing element;

the power supply element is respectively coupled with the physiological parameter acquisition element, the data conversion element, the data processing element, the data transmission element and the display element and is used for providing a stable power supply for the physiological parameter acquisition element, the data conversion element, the data processing element, the data transmission element and the display element.

Further, the physiological parameter collecting element is a physiological data collecting element which is further composed of a multi-lead cardiac wire, a blood pressure cuff, a blood oxygen nail cover and a body temperature wire.

Further, the display element is a display element composed of a liquid crystal display, a corresponding key and an acoustic circuit.

Further, wherein the data conversion element is further an analog amplifier with type INA 333.

Compared with the prior art, a multi-parameter telemedicine monitoring system, reached following effect:

1) the multi-parameter remote medical monitoring system of the utility model adopts remote 3G transmission, thus realizing remote consultation of patients at different places, and the application of monitoring is expanded from the inside of a hospital to the outside of the hospital, so that the monitoring of community hospitals and family wards outside the hospital becomes possible, and the system is suitable for the external management and monitoring of the hospitals of chronic disease crowds;

2) the multi-parameter remote medical monitoring system of the utility model realizes that the monitor is changed into a palm size from an original heavy bedside, thereby being capable of carrying out mobile wearable monitoring, monitoring a plurality of vital sign parameters (multi-lead electrocardio, respiration, blood pressure, blood oxygen, pulse and body temperature) in a mobile way in real time, greatly improving the freedom of the movement of patients and expanding monitored objects from critical patients of CCU and ICU to common chronic disease people;

3) the multi-parameter remote medical monitoring system can be applied to the field of emergency monitoring, and can play a critical role in the processes of 'on-site treatment' and 'monitoring and transferring', so that the on-site situation and rear experts of a command center can remotely communicate with each other, and the success rate of rescue is greatly improved;

4) the multi-parameter remote medical monitoring system of the utility model makes the remote consultation of the central hospital and the community primary hospitals possible, and can conduct the remote guidance and management of the central hospital to the community primary hospitals;

5) multi-parameter telemedicine monitor system, realized that telemedicine technique and backstage expert analytic system platform technique combine together, be convenient for carry on chronic patient crowd like the long-term observation outside the institute of cardiovascular chronic disease and management.

Drawings

FIG. 1 is a block diagram of a multi-parameter telemedicine monitoring system according to an embodiment of the present invention;

fig. 2 is a block diagram illustrating a specific structure of a monitoring device 10 in a multi-parameter remote medical monitoring system according to an embodiment of the present invention.

Detailed Description

As used in the specification and in the claims, certain terms are used to refer to particular components. As one skilled in the art will appreciate, manufacturers may refer to a component by different names. This specification and claims do not intend to distinguish between components that differ in name but not function. In the following description and in the claims, the terms "include" and "comprise" are used in an open-ended fashion, and thus should be interpreted to mean "include, but not limited to. "substantially" means within an acceptable error range, within which a person skilled in the art can solve the technical problem to substantially achieve the technical result. Furthermore, the term "coupled" is intended to encompass any direct or indirect electrical coupling. Thus, if a first device couples to a second device, that connection may be through a direct electrical coupling or through an indirect electrical coupling via other devices and couplings. The following description is of the preferred embodiment for carrying out the invention, and is made for the purpose of illustrating the general principles of the invention and not for the purpose of limiting the scope of the invention. The scope of the present invention is defined by the appended claims.

The present invention will be described in further detail with reference to the accompanying drawings, but the present invention is not limited thereto.

As shown in fig. 1, the multi-parameter remote medical monitoring system of the present invention comprises a monitoring device 10, a remote server 20 and a central workstation 30, wherein,

the monitoring device 10 is coupled with the remote server 20 and is used for transmitting monitoring data information about vital signs collected from a human body to the remote server 20;

the remote server 20 is respectively coupled to the monitoring device 10 and the central workstation 30, and is configured to forward the received monitoring data information sent by the monitoring device 10 to the central workstation 30 in real time;

in a specific embodiment, the remote server 20 is generally hosted in a telecommunication room, and the requirements on hardware are that it has a fixed IP address, it needs to open a corresponding port, and a dedicated data bandwidth of at least 5M, and the server itself has a dual backup function and is provided with a firewall and other measures.

The central workstation 30 is coupled to the remote server 20, and is configured to receive the monitored data information transmitted by the remote server 20 and synchronously display the monitored data information in real time, where the displayed content includes waveforms and numbers, and the central workstation has real-time alarm, data playback, data management and analysis functions.

The monitoring device 10 of the present invention integrates the above-mentioned components on a micro circuit board, and is very convenient to carry. Of course, in order to enable wireless transmission with the remote server 20 for the remote bedside monitor that is not easily moved, a 3G wireless transmitter-receiver is coupled to the remote bedside monitor. Thus, the 3G transceiver can also transmit the monitored data from the remote bedside monitor to the central workstation 30 through the remote server 20, and thus, can be remotely monitored by the central workstation 30.

Specifically, as shown in fig. 2, the monitoring device 10 includes: a physiological parameter acquisition element 101, a data conversion element 102, a data processing element 103, a data transmission element 104, a display element 105 and a power supply element 106; wherein,

the physiological parameter collecting element 101 is coupled to the data converting element 102 and the power supply element 106, and is configured to monitor and collect an analog signal of physiological data and transmit the analog signal to the data converting element 102.

In a specific embodiment, the physiological parameter collecting element 101 may be a multi-lead cardiac cable, a blood pressure cuff, a blood oxygen nail cover and a body temperature cable, and can detect and collect physiological data of a patient, such as a multi-lead electrocardiogram waveform, a respiration waveform, a blood pressure value, a blood oxygen value, a pulse wave and a body temperature value, in real time. The physiological data signal includes: electrocardio signals and respiratory pressure change signals extracted by the multi-lead electrocardiowire, pulse pressure value signals extracted by the blood pressure cuff, red light and infrared light signals extracted by the blood oxygen nail sleeve and body temperature signals extracted by body temperature wires. The above is not limited in detail.

The data conversion element 102 is coupled to the physiological parameter acquisition element 101 and the data processing element 103, and is configured to receive the physiological data analog signal sent by the physiological parameter acquisition element 101, convert the physiological data analog signal into a physiological data electrical signal, and transmit the physiological data electrical signal to the data processing element 103.

In a specific embodiment, the data conversion element 102 may be an analog amplification conversion circuit with a model number INA333, and the power consumption may be controlled to be 1 mA. Specifically, the data conversion element 102 receives the electrocardiographic signal, the respiration signal, the pulse pressure value signal, the red light and infrared light signal, and the body temperature signal sent by the physiological parameter acquisition element 101, converts the analog signals into electrical signals through an analog amplification circuit, performs differential amplification and corresponding low-frequency and high-frequency filtering, and sends the electrical signals to the data processing element 103. The above is not limited in detail.

The data processing element 103 is coupled to the data conversion element 102, the display element 105, the data transmission element 104 and the power supply element 106, and configured to receive the physiological data electrical signal sent by the data conversion element 102, convert the physiological data electrical signal into a physiological data digital signal, and send the physiological data digital signal to the data transmission element 104 for transmission and the display element 105 for real-time display; meanwhile, a key instruction sent by the display element 105 is received, data operation is carried out according to the key instruction, and real-time sound and light alarm of multi-parameter over-limit and setting of related parameters are controlled; and receives the decision result fed back by the data transmission element 104 and transmits it to the display element 105, and also has simple software filtering and playback functions.

The data transmission element 104 is coupled to the data processing element 103, the power supply element 105 and the remote server 20, and is configured to receive the physiological data digital signal sent by the data processing element 103, convert the physiological data digital signal into a physiological data electrical signal, and transmit the physiological data electrical signal to the remote server 20.

Specifically, the data sent by the data transmission element 104 automatically enters the nearest wireless 3G mobile network base station through a TCP/TP protocol, and then automatically enters the INTERNET. The data transmission element 104 is connected with a built-in antenna, when the device is used, a 3G SIM card (wireless random access network card) is inserted to ensure that data transmission can be carried out, a target address and a port number of the remote server 20 are set in a startup parameter setting menu, after a normal real-time monitoring interface is seen, a wireless communication connection button is pressed, the data processing element 103 requests the 3G module to be connected at the moment, the data processing element 103 is notified of successful connection after successful connection, and then the CPU of the data processing element 103 starts to transmit the multi-parameter data to the remote server 20 at a timing of 1 time per second. In addition, when the data transmission element 104 detects a disconnection, it can automatically re-search for a target address and a port number to automatically re-connect, and it also has a certain data caching function, so as to ensure smooth output of data when the network is congested, and can receive a request command of blood pressure inflation, thereby controlling local inflation of blood pressure.

The display element 105 is coupled with the data processing element 103 and the power supply element 106, and is used for receiving and displaying the physiological data in the digital format sent by the data processing element 103; meanwhile, a key instruction is generated according to the key operation of the operator and sent to the data processing element 103.

The display element is further composed of a liquid crystal display, a corresponding key and a sound circuit. Specifically, the display element 105 is configured with LCD liquid crystal graphic waveform display, buzzer sound warning and key input control modes through the general input/output interface of the data processing element 103, so as to realize that the remote mobile monitor prompts or alarms the patient's own physical sign, the lead electrode wire falling condition and the equipment running state carried by the patient in the modes of sound, light, graphic display and the like.

The power supply element 106 is coupled to the physiological parameter collecting element 101, the data converting element 102, the data processing element 103, the data transmitting element 104 and the display element 105, respectively, and is configured to provide a stable power supply for the physiological parameter collecting element 101, the data converting element 102, the data processing element 103, the data transmitting element 104 and the display element 105.

In one embodiment, the monitoring device 10 is configured with a 3000mAH high capacity polymer rechargeable battery as the power supply element 106, which distributes current and voltage to the entire terminal stably, and which has a continuous active operating time of up to 24 hours.

The following is an application example of the multi-parameter remote medical monitoring device of the present invention.

First, the monitoring device 10 of the multi-parameter remote medical system in the embodiment is a small-sized mobile monitor carried by a patient, and as a patient-side device in the embodiment of the present invention, a hardware system thereof mainly comprises a physiological parameter acquisition element 101, a data conversion element 102, a data processing element 103, a data transmission element 104, a display element 105 and a power supply element 106. Remove monitor adopt the miniaturized integrated technology of height, will many physiological parameter acquisition element 101 and data processing component 103, data transmission component 104 etc. circuit have all concentrated on the circuit board of a palm size, small, convenient to carry. Wherein, the physiological parameter collecting element 101 comprises a multi-lead cardiac wire, a blood pressure cuff, a blood oxygen nail cover and a body temperature line. The specific connection mode of the medical device and the human body is as follows:

1) the patient uses the multi-lead electrocardio wire, one end with the electrode buckle is connected with the electrocardio electrode slice and is attached to the corresponding part of the human body surface, and the other end of the plug is inserted into the electrocardio socket of the mobile monitor;

2) the blood pressure cuff is used for being pushed to the upper arm (the position which is horizontally level with the heart part) of a person, and the plug at the other end is inserted into the blood pressure socket of the mobile monitor;

3) using a blood oxygen wire to sleeve the blood oxygen nail on the finger of a person, and inserting the plug at the other end into the blood oxygen socket of the mobile monitor;

4) the body temperature probe is fixed under the armpit of the human body by an adhesive tape by using a body temperature line, and the plug at the other end is inserted into the body temperature socket of the mobile monitor.

After the remote mobile monitor is connected with a human body, a switch of the remote mobile monitor is turned on, and at the moment, each analog signal of the remote mobile monitor terminal is finally input into the data processing element 103 through the analog amplifying circuit and the filter circuit matched with the analog amplifying circuit, which is specifically represented as follows:

firstly, electrocardiosignals enter an amplifying and filtering circuit (comprising a low-pass, high-pass and 50HZ trap circuit) of the electrocardiosignals through a multi-lead electrocardio wire and are input into a data processing element 103;

secondly, the respiratory signal enters an amplifying and filtering circuit of the respiratory signal through a multi-lead cardiac wire and is input to the data processing element 103;

thirdly, the blood pressure signal enters the amplifying and filtering circuit of the pulse wave and the pressure value of the blood pressure through the blood pressure cuff, then enters the blood pressure module to calculate the CPU, calculates the blood pressure value and finally inputs the blood pressure value to the data processing element 103;

fourthly, the blood oxygen signal enters the amplifying circuit of red light and infrared light through the blood oxygen nail cover, then enters the blood oxygen calculating CPU, calculates the blood oxygen value and finally inputs the blood oxygen value to the data processing element 103;

fifthly, the body temperature signal enters the body temperature amplifying circuit through the body temperature line and is finally input to the data processing element 103.

In order to prevent the wireless remote 3G signals from interfering the analog signals, all analog circuits are shielded by a wireless shielding case.

Secondly, after the switch of the remote mobile monitor is turned on, the data of the remote mobile monitor terminal will automatically enter the port of the remote server 20 nearest to the remote monitor terminal through the data transmission element 104, and then automatically enter the INTERNET. The remote server 20 is generally hosted in a telecommunication room, and has requirements on hardware that a fixed IP address is provided, a corresponding port needs to be opened, a dedicated data bandwidth of at least 5M is provided, the server has a dual backup function, and firewall measures are provided.

Finally, the central workstation 30 can be connected to the internet in different ways (including wired, wireless 3G, or WIFI), and the specific connection process between the central workstation 30 and the remote server 20 is: firstly, a target address and a port number section of a remote server 20 to be accessed are required to be set at a client of a central workstation 30, then, through a network, the central workstation 30 and a corresponding IP address and a corresponding port number of the remote server 20 perform handshaking, after the connection is successful, the central workstation 30 can continuously receive data of the mobile monitor terminal forwarded by the remote server 20 from the remote server 20 in real time, and synchronously display the data of each monitor terminal 10 forwarded by the server 20 in real time, wherein the data comprises waveforms and numbers, and meanwhile, the functions of real-time alarming, data playback, data management and analysis are provided.

The following is another specific embodiment, and the working process of implementing the remote centralized monitoring outside the hospital in this embodiment is as follows:

firstly, each person of the monitored high-risk cardiovascular chronic patient group in the embodiment carries one remote mobile monitor, certainly, when the patient cannot walk and only stays at home or in a hospital, a remote bedside monitor can be installed in a home or a hospital department, but at this time, a 3G wireless remote communication transceiver is also needed to be installed on the bedside monitor so as to perform remote interaction with the remote server 20. The monitor working in the normal monitoring state collects data information of the patient such as an electrocardiographic signal, a blood oxygen signal, a pulse signal, a blood pressure signal, a body temperature signal and the like in real time, and forwards the physiological data information data to the central workstation 30 in real time through the remote server 20.

Then, the central workstation 30 can monitor a plurality of patients in real time, the communication service system of the central workstation 30 receives data sent by the remote mobile monitors carried by each patient located at remote places outside the hospital, each place inside the hospital or each patient at home, and stores the monitoring information of the patients into the database after decompressing, converting the communication protocol and other processing, and analyzes system software through embedded experts, such as: the dynamic electrocardiogram analysis software, the dynamic blood pressure discovery software, the sleep respiration analysis software and the like carry out a series of expert system analysis on the data of the remote monitoring terminal stored in the database and issue an analysis summary report, thereby realizing that one doctor finishes centralized real-time monitoring on a plurality of patients inside and outside a hospital through one central workstation 30.

Finally, when a patient is sick, the carried remote mobile monitor can carry out preliminary analysis and diagnosis on abnormal electrocardio or blood pressure, blood oxygen and other related information, and sound and light alarm can be given out to prompt the patient. At this time, the monitored data is also uploaded to the central workstation 30 through the wireless network at full speed, and then the central workstation 30 automatically analyzes and diagnoses the alarm information and the monitored information of the indicated patient, and an alarm event is generated when the diagnosis result is abnormal. Then, the doctor on duty can make timely treatment for the alarm event by combining the diagnosis result analyzed by the expert analysis system software, i.e. deeply analyzing the monitoring information of the patient with disease and diagnosing and eliminating the false alarm of the system, and timely rescuing the patient whose life health is in a dangerous state to ensure the life health safety of the patient.

However, for the alarm event that the disease symptoms are complicated and the doctor on duty can not diagnose in time, the doctor on duty can organize the relevant specialist doctor in time, contact the specialists of other hospitals for remote consultation through the communication service system of the central workstation 30, and the diagnosis advice of each specialist is relayed and distributed through the remote server 20, so as to diagnose the disease finally.

Compared with the prior art, a multi-parameter telemedicine monitoring system, reached following effect:

1) the multi-parameter remote medical monitoring system of the utility model adopts remote 3G transmission, thus realizing remote consultation of patients at different places, and the application of monitoring is expanded from the inside of a hospital to the outside of the hospital, so that the monitoring of community hospitals and family wards outside the hospital becomes possible, and the system is suitable for the external management and monitoring of the hospitals of chronic disease crowds;

2) the multi-parameter remote medical monitoring system of the utility model realizes that the monitor is changed into a palm size from an original heavy bedside, thereby being capable of carrying out mobile wearable monitoring, monitoring a plurality of vital sign parameters (multi-lead electrocardio, respiration, blood pressure, blood oxygen, pulse and body temperature) in a mobile way in real time, greatly improving the freedom of the movement of patients and expanding monitored objects from critical patients of CCU and ICU to common chronic disease people;

3) the multi-parameter remote medical monitoring system can be applied to the field of emergency monitoring, and can play a critical role in the processes of 'on-site treatment' and 'monitoring and transferring', so that the on-site situation and rear experts of a command center can remotely communicate with each other, and the success rate of rescue is greatly improved;

4) the multi-parameter remote medical monitoring system of the utility model makes the remote consultation of the central hospital and the community primary hospitals possible, and can conduct the remote guidance and management of the central hospital to the community primary hospitals;

5) multi-parameter telemedicine monitor system, realized that telemedicine technique and backstage expert analytic system platform technique combine together, be convenient for carry on chronic patient crowd like the long-term observation outside the institute of cardiovascular chronic disease and management.

While the foregoing description shows and describes several preferred embodiments of the invention, it is to be understood, as noted above, that the invention is not limited to the forms disclosed herein, but is not intended to be exhaustive or to exclude other embodiments and may be used in various other combinations, modifications, and environments and is capable of changes within the scope of the inventive concept as expressed herein, commensurate with the above teachings, or the skill or knowledge of the relevant art. But that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention, which is to be limited only by the claims appended hereto.

Claims (6)

1. A multi-parameter telemedicine monitoring system, comprising: a monitoring device, a remote server and a central workstation, wherein,

the monitoring device is coupled with the remote server and is used for transmitting monitoring data information which is collected from a human body and related to vital signs to the remote server;

the remote server is respectively coupled with the monitoring device and the central workstation and is used for forwarding the received monitoring data information sent by the monitoring device to the central workstation in real time;

and the central workstation is coupled with the remote server and is used for receiving the monitoring data information transmitted by the remote server and synchronously displaying the monitoring data information in real time.

2. The system of claim 1, wherein said synchronized real-time display is further a waveform and number display.

3. The multi-parameter telemedicine monitoring system of claim 1, wherein the monitoring device comprises: the physiological parameter acquisition component, the data conversion component, the data processing component, the data transmission component, the display component and the power supply component; wherein,

the physiological parameter acquisition element is coupled with the data conversion element and the power supply element and is used for monitoring and acquiring physiological data analog signals and transmitting the physiological data analog signals to the data conversion element;

the data conversion element is coupled with the physiological parameter acquisition element and the data processing element and is used for receiving a physiological data analog signal sent by the physiological parameter acquisition element, converting the physiological data analog signal into a physiological data electric signal and transmitting the physiological data electric signal to the data processing element;

the data processing element is respectively coupled with the data conversion element, the display element, the data transmission element and the power supply element, and is used for receiving the physiological data electric signal sent by the data conversion element, converting the physiological data electric signal into a physiological data digital signal, and sending the physiological data digital signal to the data transmission element and the display element; meanwhile, a key instruction sent by the display element is received, and data operation and processing are carried out according to the key instruction; receiving a judgment result fed back by the data transmission element and sending the judgment result to the display element;

the data transmission element is coupled with the data processing element, the power supply element and the remote server and is used for receiving the physiological data digital signal sent by the data processing element, converting the physiological data digital signal into a physiological data electric signal and transmitting the physiological data electric signal to the remote server; meanwhile, receiving a judgment result fed back by the remote server and transmitting the judgment result to the data processing element;

the display element is coupled with the data processing element and the power supply element and is used for receiving and displaying the physiological data in the digital format sent by the data processing element; meanwhile, a key instruction is generated according to the key operation of an operator and is sent to the data processing element;

the power supply element is respectively coupled with the physiological parameter acquisition element, the data conversion element, the data processing element, the data transmission element and the display element and is used for providing a stable power supply for the physiological parameter acquisition element, the data conversion element, the data processing element, the data transmission element and the display element.

4. The system of claim 3, wherein the physiological parameter acquisition element is a physiological data acquisition element comprising a multi-lead cardiac wire, a blood pressure cuff, a blood oxygen nail cover, and a body temperature wire.

5. The system of claim 3, wherein said display element is further comprised of a liquid crystal display, corresponding buttons, and an audio circuit.

6. The multi-parameter telemedicine monitoring system of claim 3, wherein the data conversion element is further an analog amplifier of type INA 333.

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