CN210582456U - Human physiological signal monitoring system based on internet - Google Patents

Abstract

The utility model provides a human physiological signal monitoring system based on the internet, which comprises a human physiological signal acquisition terminal, a cloud data processing center and a mobile terminal; the human body physiological signal acquisition terminal is connected with the cloud data processing center through the internet; the user mobile terminal and the doctor mobile terminal are connected with the cloud data processing center through the internet; the human body physiological signal acquisition terminal comprises a human body physiological signal sensor, a sensor interface, a signal conditioning circuit, a central processing unit, a data transmission module and a power supply module; the human physiological signal sensor is connected with the signal conditioning circuit through the sensor interface, the output end of the signal conditioning circuit is connected with the central processing unit, and the central processing unit is remotely connected with the cloud data processing center through the data transmission module. The utility model discloses combine human physiology signal sensor and internet, realize that many customers' human physiology information gathers and long-range storage.

Description

Human physiological signal monitoring system based on internet

Technical Field

The utility model belongs to wisdom medical service field, concretely relates to human physiology signal monitoring system based on internet.

Background

Intelligent medical treatment is a medical service mode taking patient data as a center, and is mainly divided into three stages: data acquisition, knowledge discovery, and remote services. The data acquisition is completed through the medical Internet of things, the knowledge discovery is mainly carried out by means of the powerful big data processing capacity of the medical cloud platform, the remote service is provided by the cloud service and the portable intelligent medical terminal together, the three stages are repeated, and the circulation of intelligent medical treatment is formed.

The medical aspect of China is continuously developed and advanced, the development direction of different medical treatments along with the demands of people is changed, in the future, the Internet of things and the wearable intelligent medical equipment can promote the whole industry to develop towards intelligent medical treatment, so that the intelligent medical equipment is more beneficial to daily health care of patients with chronic diseases, and plays a certain role in improving the overall health level of people.

With the promotion of science and technology, the Internet of things can promote the rapid development of intelligent medical treatment, the medical service area is intelligentized by the application of high technology such as sensing technology, artificial intelligence and the like, and the intelligent medical treatment system is gradually popularized to common people, so that the intelligent medical treatment system can play a good role in monitoring high-incidence chronic diseases at present. For example, a portable blood sugar detector is provided for a diabetic, the detection result can be transmitted to an online database anytime and anywhere by connecting the device with a mobile phone or a computer, and once a problem occurs, the intelligent database system has a reminding function, so that the method is very helpful for the diabetic, and also for other chronic patients, and more help is brought to the health of the chronic patients through the development of intelligent medical treatment. However, in the aspect of monitoring physiological indexes of patients, most of current cloud platform-based medical service platforms only monitor data for a certain physiological index, and a few systems with integrated multi-parameter human physiological index acquisition are large in size, inconvenient to carry and use and difficult to meet actual requirements of users.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is: the human physiological signal monitoring system based on the Internet can remotely store and inquire various human physiological signals.

The utility model discloses a solve the technical scheme who above-mentioned technical problem took and be: the utility model provides a human physiology signal monitoring system based on internet which characterized in that: the system comprises a human body physiological signal acquisition terminal, a cloud data processing center and a mobile terminal; wherein, at least 2 personal physiological signal acquisition terminals are respectively connected with the cloud data processing center through the Internet; the mobile terminal comprises a user mobile terminal and a doctor mobile terminal, and is respectively connected with the cloud data processing center through the internet;

each human physiological signal acquisition terminal has the same structure and comprises a human physiological signal sensor, a sensor interface, a signal conditioning circuit, a central processing unit, a data transmission module and a power supply module; the human physiological signal sensor is connected with the signal conditioning circuit through a sensor interface, the output end of the signal conditioning circuit is connected with the central processing unit, the central processing unit is remotely connected with the cloud data processing center through the data transmission module, and the power supply module is respectively connected with the central processing unit and the data transmission module.

According to the system, the human physiological signal sensor comprises at least 2 of a blood pressure sensor, a blood oxygen sensor, a temperature sensor, a fetal heart sensor, an electrocardio electrode plate, a blood fat sensor and a blood sugar sensor.

According to the system, the blood pressure sensor is a patch type pressure sensor.

According to the system, the blood oxygen sensor is a blood oxygen saturation probe.

According to the system, the blood fat sensor comprises a blood fat test strip and a signal conversion element, an electrode is arranged at the tail end of the blood fat test strip and is connected with the signal conversion element, and the output end of the signal conversion element is connected with the sensor interface.

According to the system, the blood sugar sensor comprises a blood sugar test strip and a signal conversion element, an electrode is arranged at the tail end of the blood sugar test strip and is connected with the signal conversion element, and the output end of the signal conversion element is connected with the sensor interface.

According to the system, each human physiological signal acquisition terminal further comprises a human-computer interaction input device, and the human-computer interaction input device is connected with the central processing unit.

According to the system, the man-machine interaction input device is a key keyboard, a handwriting board or a touch screen.

According to the system, the signal conditioning circuit comprises a differential amplifier, a filter and a rectifying circuit which are connected in sequence.

The utility model has the advantages that: the human physiological signal sensor is combined with the Internet, so that the human physiological information of multiple clients is summarized and remotely stored, and the clients, family members and doctors can inquire the information at any time, so that the users and the doctors can conveniently know the continuity of the human physiological information, and data support is provided for intelligent remote monitoring and diagnosis between doctors and patients.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of a human physiological signal acquisition terminal.

Detailed Description

The present invention will be further described with reference to the following specific examples and accompanying drawings.

The utility model provides a human physiological signal monitoring system based on the internet, as shown in figure 1, which comprises a human physiological signal acquisition terminal, a cloud data processing center and a mobile terminal; wherein, at least 2 personal physiological signal acquisition terminals are respectively connected with the cloud data processing center through the Internet; the mobile terminal comprises a user mobile terminal and a doctor mobile terminal, and is respectively connected with the cloud data processing center through the internet.

As shown in fig. 2, each of the human physiological signal acquisition terminals has the same structure, and includes a human physiological signal sensor, a sensor interface, a signal conditioning circuit, a central processing unit, a data transmission module and a power supply module; the human physiological signal sensor is connected with the signal conditioning circuit through a sensor interface, the output end of the signal conditioning circuit is connected with the central processing unit, the central processing unit is remotely connected with the cloud data processing center through the data transmission module, and the power supply module is respectively connected with the central processing unit and the data transmission module.

Further refined, the human physiological signal sensors comprise at least 2 of a blood pressure sensor, a blood oxygen sensor, a temperature sensor, a fetal heart sensor, an electrocardio-electrode slice, a blood fat sensor and a blood sugar sensor. The more the types of the sensors are, the more comprehensive the acquired human physiological signals are, the more comprehensive the sensor interfaces can be a plurality of interfaces corresponding to each sensor, and the universal RCA interfaces can also be used for transmission, so that all the sensors can conduct data import through plugging.

The blood pressure sensor is a patch type pressure sensor, such as a patch type pressure sensor chip of American MEAS-MS 1471.

Blood oxygen sensor for oxyhemoglobin saturation probe, can directly purchase conventional finger presss from both sides formula blood oxygen detection module and accomplish blood oxygen detection function, conventional blood oxygen module model as follows: nellcor DS-100A blood oxygen probe.

The temperature sensor is used for detecting the temperature of a human body, and the models of the conventional temperature sensor are as follows: high precision body temperature sensor WD 3703.

The fetal heart sensor can select a conventional fetal heart probe to acquire fetal heart signals, and the model can be specifically selected as follows: CHX-H103CHX-6D 2C + + probe.

The electrocardioelectrode slice is a conventional medical consumable, and the selectable models are as follows: w50 non-woven fabric electrode lead patch.

The blood fat sensor and the blood sugar sensor both adopt biosensors, and blood fat or blood sugar signals can be converted into weak electric signals through the test paper. Specifically, the blood lipid sensor comprises a blood lipid test strip and a signal conversion element, wherein an electrode is arranged at the tail end of the blood lipid test strip and is connected with the signal conversion element, and the output end of the signal conversion element is connected with the sensor interface. The blood sugar sensor comprises a blood sugar test strip and a signal conversion element, wherein an electrode is arranged at the tail end of the blood sugar test strip and is connected with the signal conversion element, and the output end of the signal conversion element is connected with the sensor interface.

Because the original physiological signal of the human body collected by the above sensor is weak and is an analog signal, signal conditioning is needed, the original physiological signal is enhanced by adopting a conventional differential amplification and multistage amplification circuit, clutter is filtered by combining an RC high-pass and band-pass filter circuit, and the selectable types of conventional signal amplification chips are as follows: LM741, S9014 and 2N 3459. In this embodiment, the signal conditioning circuit includes a differential amplifier, a filter, and a rectifying circuit, which are connected in sequence, and finally becomes a digital signal and transmits the digital signal to the central processing unit.

In this embodiment, the central processing unit, i.e., the MCU, may select a central processing unit including an ARM-Cortex series core in order to meet the signal processing requirements of each sensor, and the model of the conventional chip may be selected as follows: MK60FX512VLQ15, MK60DN512ZVLQ10, LPC1768FBD100, and the like.

The data transmission module can be a wifi module, is connected with a household router through an intranet, and then is transmitted to the cloud data processing center; the GPRS module can also be directly connected with the cloud data processing center through the Internet; the Bluetooth or Zigbee module can be further included to provide multiple wireless connection modes.

The power module can adopt 2000mah lithium battery to supply power.

The cloud data processing center can select an Ali cloud server to provide background processing service, and can also be provided with a server.

Preferably, each human physiological signal acquisition terminal further comprises a human-computer interaction input device, and the human-computer interaction input device is connected with the central processing unit, so that human physiological signals acquired by hospitals and the like can be manually input into the human physiological signal acquisition terminal to provide more signal input modes. The man-machine interaction input device can be a key keyboard, a handwriting pad or a touch screen.

In addition, the system can also be provided with a display screen connected with the central processing unit at the human physiological signal acquisition terminal, or can be connected with a computer or a mobile terminal for displaying.

Here, the applicant emphasizes that the circuit portions of the above devices are all conventional devices. The invention has the innovation point that the technical effects of 'human physiological information summarization and remote storage of multiple clients and query by the clients, family members and doctors at any time are directly brought by the networking connection form of the human physiological signal acquisition terminal, the cloud data processing center and the mobile terminal and the specific hardware composition of the human physiological signal acquisition terminal, so that the users and the doctors can conveniently know the continuity of the human physiological information and data support is provided for intelligent remote monitoring and diagnosis between doctors and patients'. The access mode of the mobile terminal to the cloud data processing center, the classification and summarization of the collected data by the cloud data processing center, the permission setting of the mobile terminals with different roles and other software are all conventional technical means.

The above embodiments are only used for illustrating the design ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and to implement the present invention, and the protection scope of the present invention is not limited to the above embodiments. Therefore, all the equivalent changes or modifications made according to the principles and design ideas disclosed by the present invention are within the protection scope of the present invention.

Claims (9)

1. The utility model provides a human physiology signal monitoring system based on internet which characterized in that: the system comprises a human body physiological signal acquisition terminal, a cloud data processing center and a mobile terminal; wherein, at least 2 personal physiological signal acquisition terminals are respectively connected with the cloud data processing center through the Internet; the mobile terminal comprises a user mobile terminal and a doctor mobile terminal, and is respectively connected with the cloud data processing center through the internet;

each human physiological signal acquisition terminal has the same structure and comprises a human physiological signal sensor, a sensor interface, a signal conditioning circuit, a central processing unit, a data transmission module and a power supply module; the human physiological signal sensor is connected with the signal conditioning circuit through a sensor interface, the output end of the signal conditioning circuit is connected with the central processing unit, the central processing unit is remotely connected with the cloud data processing center through the data transmission module, and the power supply module is respectively connected with the central processing unit and the data transmission module.

2. The internet-based human physiological signal monitoring system of claim 1, wherein: the human physiological signal sensor comprises at least 2 of a blood pressure sensor, a blood oxygen sensor, a temperature sensor, a fetal heart sensor, an electrocardioelectrode slice, a blood fat sensor and a blood sugar sensor.

3. The internet-based human physiological signal monitoring system of claim 2, wherein: the blood pressure sensor is a patch type pressure sensor.

4. The internet-based human physiological signal monitoring system of claim 2, wherein: the blood oxygen sensor is a blood oxygen saturation probe.

5. The internet-based human physiological signal monitoring system of claim 2, wherein: the blood fat sensor comprises a blood fat test strip and a signal conversion element, wherein an electrode is arranged at the tail end of the blood fat test strip and is connected with the signal conversion element, and the output end of the signal conversion element is connected with the sensor interface.

6. The internet-based human physiological signal monitoring system of claim 2, wherein: the blood sugar sensor comprises a blood sugar test strip and a signal conversion element, wherein an electrode is arranged at the tail end of the blood sugar test strip and is connected with the signal conversion element, and the output end of the signal conversion element is connected with the sensor interface.

7. The internet-based human physiological signal monitoring system of claim 1, wherein: each human physiological signal acquisition terminal also comprises a human-computer interaction input device which is connected with the central processing unit.

8. The internet-based human physiological signal monitoring system of claim 7, wherein: the man-machine interaction input device is a key keyboard, a handwriting board or a touch screen.

9. The internet-based human physiological signal monitoring system of claim 1, wherein: the signal conditioning circuit comprises a differential amplifier, a filter and a rectifying circuit which are connected in sequence.

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