CN115736941A - Intelligent wearable animal electrocardiogram monitoring system - Google Patents

Abstract

The invention provides an animal intelligent wearable electrocardiogram monitoring system which can transmit and check an electrocardiogram in real time, is long in detection time and can be used for continuously monitoring and recording the electrocardiogram for a long time. It includes: the wearable detection equipment comprises a wearable device, an electrocardiograph and a data acquisition sensor; the intelligent terminal is internally provided with a corresponding APP; a cloud big data system; the data acquisition sensor is detachably connected with the electrocardiograph through the wearing device and provided with a plurality of sensors, the sensors are respectively attached to the skin of an animal, and the sensors are connected with the electrocardiograph through a circuit integrated in the wearing device; the electrocardiograph comprises a filtering unit, an analog front end, a memory and a processing transmission module, wherein the processing transmission module comprises a lossless compression processing unit and a wireless transmission unit, and electric signals transmitted by the sensor are processed by the filtering unit, the analog front end and the lossless compression processing unit and then are wirelessly transmitted by the wireless transmission unit.

Description

Animal intelligence wearing formula electrocardio monitoring system

Technical Field

The invention relates to the technical field of animal electrocardio monitoring, in particular to an intelligent wearable animal electrocardio monitoring system.

Background

With human intervention in animal lifestyle and dietary structure, chronic diseases, mainly cardiovascular diseases, are becoming the first killers of animal health and spread at an alarming rate. Taking canines as an example, 10% -15% of canines currently suffer from heart disease, which has become the second largest disease after cancer. Cardiovascular diseases are characterized by long development period, unobvious early symptoms, urgent and serious morbidity, and death or serious disability is often caused if the optimal treatment opportunity is missed after the morbidity. In the past, due to the lack of sufficient medical resources and technical means, the chronic diseases cannot be effectively managed and prevented in the disease development period.

At present, the diagnosis and treatment power of cardiovascular diseases of domestic animals is focused on operations and drug treatment, but the prevention and treatment means is weak, and the dilemma that medical resources are more and more tense and patients are more and more treated is formed. In recent years, with the advance of clinical medicine and public health, the medical community has realized that reducing the incidence of cardiovascular diseases focuses on screening prevention and chronic disease management, and medical resources are being largely regulated from late treatment to early prevention through medical improvement.

Electrocardiograms have irreplaceable clinical value for early screening and chronic disease management of cardiovascular diseases. However, the conventional electrocardiogram and Holter dynamic electrocardiograph which are commonly used at present have the defects of short monitoring time, uncomfortable wearing, large signal interference, lack of auxiliary software and the like, and cannot meet the requirement of modern chronic disease management. Therefore, the development of a dynamic electrocardiograph system capable of continuously monitoring the electrocardio for a long time, the recording of the heart activity by using the dynamic electrocardiogram provides valuable diagnostic data for clinical diagnosis and treatment, and has very important significance for the early detection of heart diseases and the evaluation of heart functions.

Some novel miniaturized single-lead equipment electrocardio monitoring equipment have appeared on the market at home and abroad at present, and the electrocardio monitoring equipment has the characteristics of small volume and convenient use, but the equipment has some defects, so that the practicability is not enough. Such as: (1) The heart chart cannot be transmitted and checked in real time due to the lack of a wireless transmission function; (2) The monitoring time is only 24 hours, and the electrocardiogram is difficult to be continuously monitored in a long range; (3) Only temporary measurement can be carried out, and the electrocardiogram cannot be continuously monitored and recorded for a long time, so that the asymptomatic electrocardio abnormality is difficult to capture.

Therefore, the existing novel electrocardio equipment is still difficult to meet the increasing requirements of animal electrocardio monitoring and chronic diseases management. Aiming at the situations, the inventor of the invention designs a brand-new technical scheme, can solve the problems of the equipment and realizes innovative intelligent electrocardio monitoring equipment.

Disclosure of Invention

In order to solve the problems, the invention provides an animal intelligent wearable electrocardiogram monitoring system which can transmit and check an electrocardiogram in real time, has long detection time and can be used for continuously monitoring and recording the electrocardiogram for a long time.

The utility model provides an animal intelligence wearing formula electrocardio monitoring system which characterized in that, it includes:

the wearable detection equipment comprises a wearable device, an electrocardiograph and a data acquisition sensor;

the intelligent terminal is internally provided with a corresponding APP;

a cloud big data system;

the data acquisition sensor is detachably connected with the electrocardiograph through a wearing device and is provided with a plurality of sensors, the sensors are respectively attached to the skin of an animal, and the sensors are connected with the electrocardiograph through a circuit integrated in the wearing device;

the electrocardiograph comprises a filtering unit, an analog front end, a memory and a processing transmission module, wherein the processing transmission module comprises a lossless compression processing unit and a wireless transmission unit, and electric signals transmitted by the sensor are processed by the filtering unit, the analog front end and the lossless compression processing unit and then are wirelessly transmitted by the wireless transmission unit;

be equipped with corresponding APP intelligent terminal's receipt handle the data that transmission module transmitted, intelligent terminal's APP contains graphical display module, inquiry module, history and wears data module and sets up the module, the big data system in high in the clouds carries out remote data transmission with the intelligent terminal that is equipped with corresponding APP.

It is further characterized in that:

the intelligent terminal comprises a mobile phone and PAD hardware equipment, the APP comprises functions of data interaction, data analysis and data analysis, and the cloud big data system comprises an analysis alarm module;

the data acquisition sensor has a use mode of flexibly adjusting according to different animal body types and heart positions;

the number of the sensors on the data acquisition sensor is 2;

the filtering unit comprises an electrostatic impedor, a T-shaped filtering unit, a pi-shaped filtering unit and a Zener breakdown protection circuit which are connected in parallel;

the T-type filtering unit comprises a first resistor and a first capacitor, the pi-type filtering unit comprises the first capacitor, a second resistor and a second capacitor, a first end of the first resistor is connected with the data acquisition sensor, a second end of the first resistor is respectively connected with a first end of the first capacitor and a first end of the second resistor, a second end of the second resistor is respectively connected with a first end of the second capacitor and an input end of the A/D conversion module, and a second end of the first capacitor and a second end of the second capacitor are both grounded;

the electrocardiograph is also provided with an induction falling module, and the induction falling module comprises an accelerometer, a gyroscope and a geomagnetic sensor;

the electrocardiograph is also provided with a thermometer, a respiration rate sensor and a skin electricity detection sensor;

the electrocardiograph is also provided with a corresponding charging seat, and the charging seat charges the electrocardiograph in a pogopin or wireless mode;

the APP comprises a user registration login module, a one-to-one binding relationship is formed between a user and the electrocardiograph peripheral, and the electrocardiograph real-time data oscillogram is displayed after login;

a doctor list, doctor details, a user order list and a dialogue list are preset in the inquiry module;

the doctor list comprises a doctor list for online consultation and related brief introduction; the doctor details comprise personal detailed introduction information of a doctor, user evaluation and historical order user evaluation; the user order list records the consultation orders submitted by the user and the state information from submission to consultation completion; the user can communicate with the doctor for consultation one to one through the timely communication mode of the conversation list;

the historical wearing data module comprises a historical wearing data list and a report calendar; the report calendar is provided with an analysis report of the date of wearing the data record; the historical wear data list contains downloaded, downloaded wear data, which is divided by a single wear; uploading the wear data to a server for analysis after the wear data is downloaded, wherein the analyzed data has a complete analysis report;

the setting module comprises animal information viewing and maintenance; the operation unit is used for binding, unbinding, clearing data and upgrading firmware of the electrocardiograph; the information management unit of customer service, opinion feedback and application version;

the analysis alarm module comprises a data receiving module, an analysis module and an early warning information sending module.

The animal intelligent wearable electrocardiogram monitoring system has various functions, can continuously monitor and record electrocardiogram for more than 7 days, and can analyze, manage and alarm acquired electrocardiogram data, thereby being beneficial to mastering the comprehensive condition of animals and fully meeting the actual use requirement.

Drawings

FIG. 1 is a block diagram of an embodiment of an intelligent wearable electrocardiographic monitoring system for animals according to the present invention;

FIG. 2 is a diagram of a real object after a data acquisition sensor is combined with an electrocardiograph;

FIG. 3 is a schematic block diagram of the central meter of FIG. 1;

FIG. 4 is a circuit diagram of the filter unit of FIG. 3;

fig. 5 is a schematic block diagram of the intelligent terminal including the APP in fig. 1;

FIG. 6 is a block diagram of the cloud big data system of FIG. 1;

FIG. 7 is a schematic diagram of a sensor of the animal intelligent wearable electrocardiogram monitoring system of the present invention;

fig. 8 is a perspective view of the wearing detection device of the present invention.

Detailed Description

As shown in fig. 1, the animal intelligent wearable electrocardiogram monitoring system of the invention comprises a data acquisition sensor 1, a wearable device 2, an electrocardiogram instrument 3, an intelligent terminal 4 containing APP, and a cloud big data system 5.

The data acquisition sensor 1 is attached to the skin of an animal through a couplant, is used for realizing the conduction of animal electric signals and transmitting the electric signals to the electrocardiograph 3. In particular, the data acquisition sensor 1 has several sensors, which are applied to the skin of the animal. The plurality of sensors are arranged at different positions of the data acquisition sensor 1, the number of the sensors can be selected according to needs, and the number of the sensors can be specifically 2. Any sensor is connected with the electrocardiograph 3 through the wearing device 2.

To achieve the sensor's conformity to the animal's skin, in one embodiment the sensor is conformed to the animal's skin by physical means or by sensor glue through a couplant under the fixation of the applicator 2. In addition, the sensor has two forms, one is a sensor in physical contact as shown in fig. 7, the sensor design takes the problem of pet hair into consideration, and a special bump and multipoint design is adopted for short-time detection such as screening and the like; the other is still provided with from the type layer for adopting on the viscidity face of conductive adhesive and laminating glue, should be from the type layer and can protect the viscidity face before the laminating, can take off the type layer when the laminating, and this design is used for long-term monitoring. The wearing device 2 is designed to be suitable for animals with different body types aiming at medium-large animals and small animals as shown in figure 8, and the stability of collected signals is guaranteed. In addition, the data acquisition sensor 1 can shield most of environmental electromagnetic interference, resist a part of movement interference and ensure the accuracy of acquired data.

As shown in fig. 2, the electrocardiograph 3 is used for receiving the electric signals transmitted by the data acquisition sensor 1, processing and transmitting the electric signals, and can continuously monitor and record the electrocardiogram for more than 7 days. Specifically, the data acquisition sensor 1 is detachably connected to the electrocardiograph 3, and thus, when the data acquisition sensor 1 needs to be replaced, the data acquisition sensor 1 and the electrocardiograph 3 connected together can be separated, and a new data acquisition sensor 1 is installed on the electrocardiograph 3.

As shown in fig. 8, the wearing device 2 is used for fixing and connecting the electrocardiograph 3 and the data acquisition sensor 1, so as to ensure data transmission and stability between the two, and play a role in fixing the two. The wearing device 2 can be compatible with animals of different body types by adopting a unique adjustable design. The wearer 2 has two designs for medium and large animals and small animals, respectively. The wearing device 2 is assembled with the data acquisition sensor 1 and the electrocardiograph 3 through detachable connection.

In one embodiment, the data acquisition sensor 1 is removably connected to the electrocardiograph 3 via the applicator 2. Wherein, sensor buckle or connector still can transmit the signal of telecommunication of sensor conduction to electrocardio appearance 3 when realizing that data acquisition sensor 1 and 3 dismantlement formulas of electrocardio appearance are connected.

As shown in fig. 3, the electrocardiograph 3 includes a filtering unit 21, an analog front end 22, a memory, and a processing and transmitting module 23, wherein the processing and transmitting module 23 includes a lossless compression processing unit and a wireless transmission unit, and the electric signal transmitted by the sensor is processed by the filtering unit 21, the analog front end 22, and the lossless compression processing unit, and then is wirelessly transmitted by the wireless transmission unit. The memory is a large-capacity memory, and continuous storage and acquisition of all electrocardiogram data can be realized by arranging the large-capacity memory, so that signals are not missed. Meanwhile, a large-capacity memory can also be used as a cache for real-time data transmission, so that the data integrity is ensured.

As shown in fig. 4, in particular, the filtering unit 21 is disposed between the data acquisition sensor 1 and the analog front end 22, which enhances the resistance to noise interference, and it achieves the maximum noise immunity while ensuring the data fidelity by the cooperation of multiple sets of filters. The filter unit 21 includes an electrostatic resistor 210, a T-type filter unit 211, a pi-type filter unit 212, and a zener breakdown protection circuit 213, which are connected in parallel with each other.

The T-type filtering unit 211 includes a first resistor and a first capacitor, the pi-type filtering unit 212 includes a first capacitor, a second resistor, and a second capacitor, a first end of the first resistor is connected to the data acquisition sensor, a second end of the first resistor is connected to a first end of the first capacitor and a first end of the second resistor, a second end of the second resistor is connected to a first end of the second capacitor 52 and an input end of the a/D conversion module, and a second end of the first capacitor and a second end of the second capacitor are both grounded.

A first terminal of the electrostatic impedance 210 is connected to a first terminal of a first resistor, and a second terminal of the electrostatic impedance 210 is grounded.

The zener breakdown protection circuit 213 includes a first diode and a second diode, a first terminal of the first diode and a first terminal of the second diode are connected to a second terminal of the second resistor, respectively, a second terminal of the first diode is connected to VDD, and a second terminal of the second diode is grounded. The data acquisition sensor is grounded.

The analog front end 22 is used for receiving and processing the electrical signal processed by the filtered power supply, and in one embodiment, the analog front end 22 is an ADC chip 22, and preferably, the model of the ADC chip 22 is: one of ADS1291, ADS1292, ADS1294, ADAS1000-1, ADAS1010-2, LH001.

After the data is processed by the lossless compression processing unit, the data volume of storage and transmission can be greatly reduced, so that the energy consumption is greatly reduced, and the data security is improved. Meanwhile, the low-power consumption design greatly reduces the capacity of the used battery, so that the occupied space of the battery is reduced, and the design volume is reduced. In addition, the compact circuit design and the structural design are adopted, so that the space utilization rate is further increased, and the purposes of ultra-light and ultra-small are achieved. The lossless compression processing unit operates as follows:

a. and setting the length N of the data compression packet and the calculation depth D according to available memory system resources and requirements on real-time performance. Increasing N and D may achieve higher compression ratios, but may occupy more system computing resources and reduce real-time performance; setting whether lossy compression is allowed or not; if lossy compression is allowed, setting lossy compression parameters: an approximation threshold K, an approximation upper bound H;

b. according to the calculated depth D, carrying out D-order differential operation on the first N data of the input data stream to obtain a difference value array dev _1, 8230, dev _ N-D-1;

c. sorting the difference value arrays to obtain arrays a _1, \ 8230, a _ N and a maximum value Max from small to large, and finding out a minimum N value which satisfies 2 and has the power N less than or equal to Max;

d. if lossy compression is allowed, the following decision is added: if the number of the segments which are not more than H and are continuously smaller than the value K exist in the array, the starting value position b and the number H of the segments are recorded, and all data in the segments are processed according to 0;

e. setting the unit length of the result bit stream as n, writing the difference value into the result bit stream in sequence, and filling zero in the leader with the length less than the unit length. If lossy compression is allowed, the data processed as 0 will not be added to the bitstream, but only parameters b and h are recorded;

f. a typical compressed packet data structure is: header data | dev _1| \8230 | dev _ N;

g. after the bit stream is set, respectively adding 2-byte boundary marks at two ends, and after the start of marking, increasing the length of the whole compressed data packet for isolating the compressed data packet in storage and verifying the integrity of the compressed data packet after transmission;

h. in addition, a set of data is set for recording the setting parameters in step 1. If dynamic adaptation is needed, the data should be dynamically adjusted along with the compression process, and a parameter set corresponding to the initial position of the original data is recorded;

i. decompression: according to the recorded parameter group, the inverse operation of the above steps is carried out, namely, the head data is found through the boundary mark, and then the addition operation is carried out with the following data in sequence. If lossy compression is performed, the above operation is performed after inserting the value 0 into the corresponding position according to b and h.

The wireless transmission unit is used for transmitting the data processed by the analog front end 22 to the intelligent terminal 4 containing APP. Furthermore, the electrocardiograph 3 further comprises a battery, which is preferably a rechargeable battery, which is a lithium battery. The electrocardiograph 3 is also equipped with a charging cradle that can charge a lithium battery. The charging mode of the charging seat can be pogopin charging or wireless charging. Therefore, the electrocardiograph 3 can be charged synchronously in a wearing state, so that the electrocardiograph 3 can be charged in real time, and the real-time acquisition of animal electrocardiograph data is realized.

The electrocardiograph 3 also integrates various functions. In one embodiment, the electrocardiograph 3 further comprises an inductive fall module comprising an accelerometer, a gyroscope, a geomagnetic sensor. The integrated accelerometer, gyroscope and geomagnetic sensor can be used for monitoring the motion posture of a person under guardianship so as to realize falling alarm. In addition, the electrocardiograph 3 includes a thermometer, a respiration rate sensor, and a galvanic skin detection sensor. Wherein, the thermometer can monitor the body temperature of animal, and then plays the effect of auxiliary analysis when big data system 5 analyzes electrocardio data, and respiration rate sensor and skin electricity sensor then carry out the collection of respiration rate data and skin electricity data to play auxiliary analysis's effect when big data system 5 in the high in the clouds analyzes electrocardio data.

The data acquisition sensor 1 and the electrocardiograph 3 are also provided with waterproof designs, and specifically, the electrocardiograph monitoring system is provided with a waterproof cavity and waterproof glue, wherein the electrocardiograph 3 is accommodated in the waterproof cavity, the data acquisition sensor 1 is connected with the electrocardiograph 3 through a through hole in the waterproof cavity, and the waterproof glue covers the data acquisition sensor 1. Meanwhile, the data acquisition sensor 1 is provided with a hollow structure for the sensor on the data acquisition sensor 1 to leak.

When data acquisition sensor 1 and the electrocardio appearance 3 that link together were worn, can wear according to the laminating mode of difference according to the monitoring demand of difference. The data acquisition sensor 1 has a transverse attaching mode, a longitudinal attaching mode, and an oblique attaching mode. The different attachment methods correspond to different monitoring areas of the animal's chest, so that the data acquisition sensor 1 is attached to the monitoring area of the animal's chest in a corresponding attachment method.

As shown in fig. 5, the intelligent terminal 4 containing APP is used for wirelessly receiving data sent by the electrocardiograph 3 or the cloud big data system 5, processing the data, forming a final electrocardiographic waveform, presenting the final electrocardiographic waveform to a user, and generating electrocardiographic interpretation analysis and statistical data. If high-risk electrocardio is abnormal, the intelligent terminal containing the APP sends out an early warning signal to automatically inform the family and the doctor of the user. Specifically, intelligent terminal 4 including APP receives and processes data transmitted by transmission module 23, and intelligent terminal 4 including APP includes graphical display module 31, inquiry module 32, history wearing data module 33, and setting module 34.

The graphic display module 31 includes a user registration login module, which enables a one-to-one binding relationship to be formed between a user and an electrocardiograph peripheral, and performs electrocardiographic real-time data oscillogram display after login. Specifically, after the user registers and logs in the module, the display of the electrocardiogram real-time data oscillogram is divided into two display modes of refreshing and translating, and the walking speed and the gain of the display mode are customized by the user. Wherein the real-time heart rate display performs QRS detection according to the real-time electrocardiogram waveform, and the filtering mode comprises notch filtering, median filtering and low-pass filtering.

The inquiry module 32 has a doctor list, doctor details, user order list, and dialog list preset therein. The doctor list comprises a doctor list for online consultation and related brief introduction; the doctor details comprise personal detailed introduction information of the doctor, user evaluation and historical order user evaluation; the user order list records the consultation orders submitted by the user and the state information from submission to consultation completion; the dialogue list is communicated in a timely manner, so that the user can communicate with the doctor in inquiry one to one.

The historical wearing data module 33 comprises a historical wearing data list and a report calendar; the report calendar provides an analysis report of the date of wearing the data record; the historical wearing data list comprises the downloaded and downloaded wearing data which are divided according to single wearing; and uploading the wear data to a server for analysis after the wear data is downloaded, wherein the analyzed data has a complete analysis report.

The setting module 34 includes: the animal information checking and maintaining unit and the user log out of the login operation unit; the operation unit is used for binding, unbinding, clearing data and upgrading firmware of the electrocardiograph; customer service, opinion feedback, information management unit of application version.

In one embodiment, the APP-containing smart terminal 4 may be an electronic product such as a smart phone or a tablet computer.

As shown in fig. 6, the cloud big data system 5 is used for processing a large amount of data including real-time electrocardiographic data simultaneously based on a high-throughput cloud server, and performing analysis by an intelligent algorithm. After the big data background acquires the data uploaded by the electrocardiograph, an intelligent algorithm is called in real time to detect abnormal electrocardiograph signals and label and classify the abnormal electrocardiograph signals, and meanwhile correlation analysis can be performed on the electrocardiograph abnormalities and other physiological data provided by an accelerometer, a gyroscope, a geomagnetic instrument, a temperature sensor, a respiration rate sensor and a skin electric feedback sensor, so that more comprehensive health assessment is given. After logging in the cloud big data system, a doctor can check physiological data such as electrocardio and the like, modify and confirm automatic analysis, then issue an electrocardiogram report and provide diagnosis opinions. In addition, doctors can check the big data information of all animals, including species, sex, past medical history, medicine and the like, and use the big data tool to carry out comprehensive statistical analysis.

Specifically, the cloud big data system 5 includes an analysis alarm module. The analysis alarm module comprises: a data receiving module 41, an analyzing module 42 and an early warning information transmitting module 43.

Wherein, electrocardiograph 3 periodically sends electrocardio data to intelligent terminal 4 that contains APP in real time, and wherein, the electrocardio data of sending transmit to intelligent terminal 4 that contains APP with wireless mode, and intelligent terminal 4 that contains APP further uploads the electrocardio data of receiving to data processing module.

The data receiving module 41 receives the electrocardiogram data uploaded by the intelligent terminal 4 containing the APP and transmits the received electrocardiogram data to the analyzing module 42, the analyzing module 42 stores a data threshold value representing normal electrocardiogram physical signs of the animal, the analyzing module 42 compares the received electrocardiogram data with the stored data threshold value, when the received electrocardiogram data is within the stored data threshold value, it is indicated that the electrocardiogram physical signs of the animal are in a normal level, otherwise, it is indicated that the electrocardiogram physical signs of the animal are abnormal, and the analyzing module 42 notifies the early warning information sending module 43 to perform early warning. Early warning information sending module 43 carries out data communication with intelligent terminal 4 who contains APP who uploads electrocardio data, and intelligent terminal 4 who contains APP can receive the early warning information that early warning information sending module 43 sent. In addition, when intelligent terminal 4 that contains the APP is a plurality of, early warning information sending module 43 still can send early warning information to other intelligent terminal 4 that contain the APP that contain APP that upload electrocardio data is relevant in step. In addition, when the monitored person is in a serious condition, the early warning information sending module 43 also sends the early warning information to medical care personnel synchronously, the medical care personnel can analyze the electrocardiogram data of the monitored animal and can manually communicate with the monitoring person in time, so that the real-time rescue measures of the monitored animal can be realized as soon as possible, and the health of the monitored animal can be further ensured.

In addition, the animal intelligent wearable electrocardio-monitoring system also has a data intermittent storage mode, when the animal intelligent wearable electrocardio-monitoring system is in the intermittent storage mode, data collected in real time are analyzed by the analysis module 42, and when the received electrocardio-data exceed the stored data threshold, the analysis module 42 starts the event recorder to record abnormal data, so that valuable data are selectively recorded, and the burden of a cloud big data system is reduced.

In conclusion, the animal intelligent wearable electrocardiogram monitoring system has various functions, can continuously monitor and record electrocardiogram for more than 7 days, and can analyze, manage and alarm acquired electrocardiogram data, thereby being beneficial to mastering the comprehensive conditions of animals with diseases and fully meeting the actual use requirements of users.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. The utility model provides an animal intelligence wearing formula electrocardio monitoring system which characterized in that, it includes:

the wearable detection equipment comprises a wearable device, an electrocardiograph and a data acquisition sensor;

the intelligent terminal is internally provided with a corresponding APP;

a cloud big data system;

the data acquisition sensor is detachably connected with the electrocardiograph through a wearing device and provided with a plurality of sensors, the sensors are respectively attached to the skin of an animal, and the sensors are connected with the electrocardiograph through a circuit integrated in the wearing device;

the electrocardiograph comprises a filtering unit, an analog front end, a memory and a processing and transmitting module, wherein the processing and transmitting module comprises a lossless compression processing unit and a wireless transmission unit, and electric signals transmitted by the sensor are processed by the filtering unit, the analog front end and the lossless compression processing unit and then are wirelessly transmitted by the wireless transmission unit;

be equipped with corresponding APP intelligent terminal's receipt handle the data that transmission module transmitted, intelligent terminal's APP contains graphical display module, inquiry module, history and wears data module and sets up the module, the big data system in high in the clouds carries out remote data transmission with the intelligent terminal that is equipped with corresponding APP.

2. The intelligent wearable animal electrocardiogram monitoring system as claimed in claim 1, wherein: the intelligent terminal comprises a mobile phone and PAD hardware equipment, the APP comprises functions of data interaction, data analysis and data analysis, and the cloud big data system comprises an analysis alarm module.

3. The intelligent wearable animal electrocardiogram monitoring system of claim 1, wherein: the number of sensors on the data acquisition sensor is 2.

4. The intelligent wearable animal electrocardiogram monitoring system of claim 1, wherein: the filtering unit comprises an electrostatic impeder, a T-shaped filtering unit, a pi-shaped filtering unit and a Zener breakdown protection circuit which are connected in parallel.

5. The intelligent wearable animal electrocardiogram monitoring system of claim 1, wherein: the electrocardiograph is further provided with an induction falling module, and the induction falling module comprises an accelerometer, a gyroscope and a geomagnetic sensor.

6. The intelligent wearable animal electrocardiogram monitoring system of claim 1, wherein: the electrocardiograph is further provided with a thermometer, a respiration rate sensor and a skin electricity detection sensor.

7. The intelligent wearable animal electrocardiogram monitoring system of claim 1, wherein: the electrocardiograph is also provided with a corresponding charging seat, and the charging seat charges the electrocardiograph in a pogopin or wireless mode.

8. The intelligent wearable animal electrocardiogram monitoring system as claimed in claim 1, wherein: the APP comprises a user registration login module, the user and the electrocardiograph peripheral equipment form a one-to-one binding relationship, and the electrocardiograph real-time data oscillogram is displayed after login.

9. The intelligent wearable animal electrocardiogram monitoring system of claim 1, wherein: a doctor list, doctor details, a user order list and a dialogue list are preset in the inquiry module.

10. The intelligent wearable animal electrocardiogram monitoring system as claimed in claim 1, wherein: the setting module comprises animal information viewing and maintenance; the operation unit is used for binding, unbinding, clearing data and upgrading firmware of the electrocardiograph peripheral; customer service, opinion feedback, information management unit of application version.

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