CN111060217A - Real-time extraction system of livestock health record - Google Patents

Abstract

A real-time livestock health record extraction system, the system comprising: the livestock health recorder is used for storing body temperature data and environment temperature data of the whole life process of livestock in real time and locally, and when the temperature data needs to be read by the handheld reading device and/or the slaughterhouse automatic reading data device, the required temperature data is transmitted in a wireless communication BT/ZIGBEE wireless protocol mode. The animal health recorder is worn by each livestock, and the body temperature of the animal health recorder is sampled at a settable frequency every day from the beginning of wearing, and is stored in the recorder body, so that the body temperature health of the livestock in the whole life cycle is recorded and stored in the whole process; the quality of the meat product is controlled from the source by recording the animal body temperature data to the local in the whole course of the life cycle of the animal body temperature data, actively awakening the animal body temperature data through an awakening mechanism when needed and extracting all historical body temperature data.

Description

Real-time extraction system of livestock health record

Technical Field

The invention relates to an extraction system, in particular to a real-time extraction system for livestock health records, and particularly relates to a body temperature health information record in the whole growth process of livestock, belonging to the technical field of livestock health and meat product safety control products.

Background

At present, the judgment of the health condition of livestock mainly depends on the subjective visual observation of breeding personnel, and a few breeding plants are provided with infrared temperature detection equipment or an image monitoring mode at the passage to monitor the health of individual or group livestock. These approaches only allow for sampling temporary health determinations for a large group or individual animal, and do not allow for a full life cycle temperature health record for each animal. The existing inspection for abnormal/disease quarantine possibly existing in the process of slaughtering livestock is judged by instruments and manual (veterinarians), and the technical defect of consuming a large amount of manpower and material resources exists.

Due to untimely and inadequate health safety detection in the process of livestock breeding, the disease rate can be improved, and if the breeding process is not strictly controlled, unqualified livestock can be sold as qualified livestock and flow to the market. According to the statistics of live pigs in Gao' an city, Jiangxi province, 200 million live pigs are discharged in average every year, 110 million live pigs are stored in a fence, and about 9 million pigs are died of diseases every year according to the 3% normal death rate of the live pigs. According to the regulation, the pigs died from diseases are subjected to harmless treatment under the supervision of relevant management departments, but due to the problem of artificial supervision, some unqualified livestock still flow to the market. How to develop a set of system, wear the health recorder to the livestock and carry on the statistical management of data to the growth process of the livestock, and its temperature data of the whole life cycle record, can call out all historical body temperature health data recorded and carry on the automatic scientific scoring assessment when needing to know, but not rely on the artificial subjective to carry on the rough assessment, become the main research direction of the invention.

Meanwhile, on the other hand, the system gives supervision to upstream breeding enterprises and puts higher breeding level requirements on the upstream breeding enterprises. How to solve the problem of the artificial subjective judgment of the health condition of each livestock by downstream slaughter and meat product enterprises and related government regulatory departments. In view of the defects of the prior art, the inventor of the present application has conducted continuous experimental research and finally designed a real-time livestock health record extraction system.

Disclosure of Invention

The invention aims to provide a real-time livestock health record extraction system which is convenient to use and accurate and can locally store and remotely extract a data set.

In order to achieve the purpose, the technical scheme adopted by the invention is as follows:

a real-time livestock health record extraction system, the system comprising: the livestock health recorder 1 is used for storing body temperature data and environment temperature data of the whole life process of livestock locally in real time, and when the handheld reading device 2 and/or the slaughterhouse automatic reading data device 3 need to read the temperature data, the required temperature data are transmitted in a wireless communication BT/ZIGBEE wireless protocol mode.

The real-time extraction system of livestock health record, the livestock health record appearance 1 includes: the awakening triggering working module is a front-end RFID detection receiving module 11 which is used for receiving specific RFID frequency signals sent by the handheld reading equipment 2 and/or the slaughterhouse automatic reading data equipment 3;

a singlechip module 13 for controlling the work of the recorder and storing local data;

a built-in battery module 15 for providing power for the operation of the singlechip module 13;

a BT/ZIGBEE wireless communication module 14 for data communication with the handheld reading device 2 and/or the slaughterhouse automatic reading data device 3;

an in-vivo temperature sensor module 16 closely attached to the skin of the ear root of the livestock and used for monitoring the temperature of the ear root of the livestock;

an in vitro temperature sensor module 17 which is far away from the skin of the livestock and is used for monitoring the temperature of the environment around the livestock;

the in-vivo temperature sensor module 16 and the in-vitro temperature sensor module 17 send measured temperature data to the single-chip microcomputer module 13, when the single-chip microcomputer module 13 receives an instruction of the front-end RFID detection receiving module 11 and needs to transmit the data to the handheld reading equipment 2 and/or the slaughterhouse automatic reading data equipment 3, the single-chip microcomputer module 13 sends an instruction to the BT/ZIGBEE wireless communication module 14 to send the handheld reading equipment 2 and/or the slaughterhouse automatic reading data equipment 3 through a wireless communication BT/ZIGBEE wireless protocol.

According to the real-time extraction system for the livestock health records, body temperature data of the in-vivo temperature sensor module 16 and the in-vitro temperature sensor module 17 are stored in a non-loss Flash storage space of the single-chip microcomputer module 13, and the Flash storage space can support continuous recording of the body temperature data for 2 years or more than 2 years.

The real-time livestock health record extracting system comprises a handheld automatic reading device 2 and a control device, wherein the handheld automatic reading device comprises: the system comprises a front-end RFID specific frequency transmitting module 21, an intelligent operating system core mainboard 23, an internal battery module 25, a BT/ZIGBEE wireless communication module 24 and an LTE communication module 26; the built-in battery module 25 provides a working power supply for the intelligent operating system core mainboard 23; the intelligent operating system core mainboard 23 sends an instruction to the front-end RFID specific frequency transmitting module 21, the front-end RFID specific frequency transmitting module 21 triggers the livestock health recorder 1 to start working through a specific RFID frequency signal, and the BT/ZIGBEE wireless communication module 24 calls temperature data in the livestock health recorder 1 through a wireless communication BT/ZIGBEE wireless protocol; the LTE communication module 26 directly transmits the historical body temperature data read from the core motherboard 23 of the intelligent operating system to the background cloud database for storage through LTE wireless communication.

The real-time extraction system for the livestock health record comprises a slaughterhouse automatic data reading device 3: the system comprises a front-end RFID specific frequency transmitting module 31, an intelligent operating system core mainboard 33, a built-in battery module 35, a BT/ZIGBEE wireless communication module 34 and an LTE communication module 36; the built-in battery module 35 provides a working power supply for the intelligent operating system core mainboard 33; the intelligent operating system core mainboard 33 sends an instruction to the front-end RFID specific frequency transmitting module 31, the front-end RFID specific frequency transmitting module 31 triggers the livestock health recorder 1 to start working through a specific RFID frequency signal, and the BT/ZIGBEE wireless communication module 34 transfers temperature data in the livestock health recorder 1 through a wireless communication BT/ZIGBEE wireless protocol; the LTE communication module 36 directly transmits the historical body temperature data read from the core motherboard 33 of the intelligent operating system to the background cloud database for storage through LTE wireless communication.

The real-time extraction system of livestock health record, the livestock health record instrument 1 adopts two start-up modes: one is that the reading device wakes up to trigger the start-up, and the other is that a timer is triggered to start-up.

Firstly, the livestock health record instrument 1 is in an initialization state, when the handheld reading equipment 2 and/or the slaughterhouse automatic reading data equipment 3 reads data of the livestock health record instrument 1, the reading equipment is awakened to trigger the livestock health record instrument 1 to start, and the temperature sampling ADC parameter is initialized; collecting ADC values of ear temperature and environment temperature, and converting the corresponding ADC values into corresponding temperatures; then the ear temperature and the ambient temperature are stored in the local FLSAH; the BE/ZIGBEE communication module is initialized, and signals are sent to the handheld reading equipment 2 and/or the slaughterhouse automatic data reading equipment 3 through the BE/ZIGBEE communication module.

In the system for extracting the livestock health record in real time, the single chip module 13 in the livestock health record instrument 1 judges whether a response message of the reading device is received? If so, executing and finishing the task and the command issued by the reading terminal, and then executing and closing all module power supplies; if not, all module power supplies are closed, data is stored at the latest sampling frequency, and a start alarm clock is set; the system then enters a deep sleep state.

Firstly, the livestock health record instrument 1 is in an initialization state, when the handheld reading equipment 2 and/or the slaughterhouse automatic reading data equipment 3 reads data of the livestock health record instrument 1, a timer triggers the livestock health record instrument 1 to start, and temperature sampling ADC parameters are initialized; collecting ADC values of ear temperature and environment temperature, and converting the corresponding ADC values into corresponding temperatures; then the ear temperature and the ambient temperature are stored in the local FLSAH; the BE/ZIGBEE communication module is initialized, and signals are sent to the handheld reading equipment 2 and/or the slaughterhouse automatic data reading equipment 3 through the BE/ZIGBEE communication module.

In the system for extracting the livestock health record in real time, the single chip module 13 in the livestock health record instrument 1 judges whether a response message of the reading device is received? If so, executing and finishing the task and the command issued by the reading terminal, and then executing and closing all module power supplies; if not, all module power supplies are closed, data is stored at the latest sampling frequency, and a start alarm clock is set; the system then enters a deep sleep state.

The beneficial effects of the invention are as follows: the invention has the innovation that the animal health recorder worn by each livestock can sample the body temperature of the livestock at a settable frequency every day from the beginning of wearing, store the body temperature in the recorder body and record and store the body temperature health of the livestock in the whole life cycle in a whole process; the animal body temperature data is recorded to the local in the whole life cycle, and is actively awakened through an awakening mechanism when needed, so that all historical body temperature data are extracted; the quality of the meat product is controlled from the source. The invention obtains a scientific and accurate health judgment method for each livestock for downstream slaughter enterprises, meat product enterprises and government epidemic prevention and food supervision departments; the most source quality and safety problems of meat products are guaranteed from the perspective of supervision of downstream enterprises and governments, and various meat products which are safe and reassuring are protected by scientific and technological means, so that the health and safety of people are guaranteed.

Drawings

The invention will be further explained with reference to the drawings, in which:

FIG. 1 is a schematic diagram of the livestock health record real-time extraction system of the present invention;

FIG. 2 is a control flow chart of the real-time livestock health record extracting system of the invention;

FIG. 3 is a block diagram of the livestock health recorder of the present invention;

FIG. 4 is a block diagram of the handheld reading device of the present invention;

fig. 5 is a block diagram of an automatic data reading device for a slaughterhouse according to the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are only for descriptive purposes and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "connected," "secured," and the like are to be construed broadly, and for example, "secured" may be a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

As shown in fig. 1, a real-time livestock health record extracting system comprises: the livestock health recorder 1 is used for storing body temperature data and environment temperature data of the whole life process of livestock locally in real time, and when the handheld reading device 2 and/or the slaughterhouse automatic reading data device 3 need to read the temperature data, the required temperature data are transmitted in a wireless communication BT/ZIGBEE wireless protocol mode.

As shown in fig. 3, the livestock health recorder 1 includes: the awakening triggering working module is a front-end RFID detection receiving module 11 which is used for receiving specific RFID frequency signals sent by the handheld reading equipment 2 and/or the slaughterhouse automatic reading data equipment 3; a singlechip module 13 for controlling the work of the recorder and storing local data; a built-in battery module 15 for providing power for the operation of the singlechip module 13; a BT/ZIGBEE wireless communication module 14 for data communication with the handheld reading device 2 and/or the slaughterhouse automatic reading data device 3; an in-vivo temperature sensor module 16 closely attached to the skin of the ear root of the livestock and used for monitoring the temperature of the ear root of the livestock; an in vitro temperature sensor module 17 which is far away from the skin of the livestock and is used for monitoring the temperature of the environment around the livestock;

the in-vivo temperature sensor module 16 and the in-vitro temperature sensor module 17 send measured temperature data to the single-chip microcomputer module 13, when the single-chip microcomputer module 13 receives an instruction of the front-end RFID detection receiving module 11 and needs to transmit the data to the handheld reading device 2 and/or the slaughterhouse automatic reading data device 3, the single-chip microcomputer module 13 sends an instruction to the BT/ZIGBEE wireless communication module 14 to send the handheld reading device 2 and/or the slaughterhouse automatic reading data device 3 through a wireless communication BT/ZIGBEE wireless protocol; the body temperature data of the in-vivo temperature sensor module 16 and the in-vitro temperature sensor module 17 are stored in the non-loss Flash storage space of the single chip microcomputer module 13, and the Flash storage space can support continuous recording of body temperature data for 2 years or more than 2 years.

It is explained here that the front-end RFID detection receiving module 11 uses a NordicVLSI nRF905 type chip in the prior art; the singlechip module 13 adopts an AT89C2051 type chip of Atmel company in the prior art; the BT/ZIGBEE wireless communication module 14 adopts an Onsemi RSL10 type chip in the prior art; the internal temperature sensor module 16 adopts a JOYIN JTD503F395D12087N model high-precision temperature sensor module in the prior art; the external temperature sensor module 17 adopts a JOYIN JTD503F395D12087N high-precision temperature sensor module in the prior art;

as shown in fig. 4, the handheld automatic reading device 2 includes: the system comprises a front-end RFID specific frequency transmitting module 21, an intelligent operating system core mainboard 23, an internal battery module 25, a BT/ZIGBEE wireless communication module 24 and an LTE communication module 26; the built-in battery module 25 provides a working power supply for the intelligent operating system core mainboard 23; the intelligent operating system core mainboard 23 sends an instruction to the front-end RFID specific frequency transmitting module 21, the front-end RFID specific frequency transmitting module 21 triggers the livestock health recorder 1 to start working through a specific RFID frequency signal, and the BT/ZIGBEE wireless communication module 24 calls temperature data in the livestock health recorder 1 through a wireless communication BT/ZIGBEE wireless protocol; the LTE communication module 26 directly transmits the historical body temperature data read from the core motherboard 23 of the intelligent operating system to the background cloud database for storage through LTE wireless communication.

It is explained here that the front-end RFID specific frequency transmitting module 21 uses a NordicVLSInRF905 type chip of the prior art; the intelligent operating system core mainboard 23 adopts a MTK MT6290 type chip in the prior art; the BT/ZIGBEE wireless communication module 24 adopts an Onsemi RSL10 type chip in the prior art; the LTE communication module 26 uses a FIBOCOM L718 chip of the prior art.

As shown in fig. 5, the automatic data reading device 3 for slaughterhouses comprises: the system comprises a front-end RFID specific frequency transmitting module 31, an intelligent operating system core mainboard 33, a built-in battery module 35, a BT/ZIGBEE wireless communication module 34 and an LTE communication module 36; the built-in battery module 35 provides a working power supply for the intelligent operating system core mainboard 33; the intelligent operating system core mainboard 33 sends an instruction to the front-end RFID specific frequency transmitting module 31, the front-end RFID specific frequency transmitting module 31 triggers the livestock health recorder 1 to start working through a specific RFID frequency signal, and the BT/ZIGBEE wireless communication module 34 transfers temperature data in the livestock health recorder 1 through a wireless communication BT/ZIGBEE wireless protocol; the LTE communication module 36 directly transmits the historical body temperature data read from the core motherboard 33 of the intelligent operating system to the background cloud database for storage through LTE wireless communication.

It is illustrated that the front-end RFID specific frequency transmitting module 31 employs a NordicVLSInRF905 type chip of the prior art; the intelligent operating system core mainboard 33 adopts a MTK MT6290 type chip in the prior art; the BT/ZIGBEE wireless communication module 34 adopts an Onsemi RSL10 type chip in the prior art; the LTE communication module 36 uses a FIBOCOM L718 chip of the prior art.

As shown in fig. 2, a real-time livestock health record extracting system, the livestock health record instrument 1 adopts two startup modes: one is that the reading device wakes up to trigger the start-up, and the other is that a timer is triggered to start-up.

As a first way, the control flow of the wake-up trigger startup of the reading device is as follows: firstly, the livestock health recorder 1 is in an initialization state, when the handheld reading equipment 2 and/or the slaughterhouse automatic data reading equipment 3 reads the data of the livestock health recorder 1, the reading equipment wakes up to trigger the livestock health recorder 1 to start up, and the temperature sampling ADC parameter is initialized; collecting ADC values of ear temperature and environment temperature, and converting the corresponding ADC values into corresponding temperatures; then the ear temperature and the ambient temperature are stored in the local FLSAH; a BE/ZIGBEE communication module is initialized, and signals are sent to the handheld reading equipment 2 and/or the slaughterhouse automatic reading data equipment 3 through the BE/ZIGBEE communication module; is the one-chip microcomputer module 13 in the livestock health recorder 1 judge whether a reading device response message is received? If so, executing and finishing the task and the command issued by the reading terminal, and then executing and closing all module power supplies; if not, all module power supplies are closed, data is stored at the latest sampling frequency, and a start alarm clock is set; the system then enters a deep sleep state.

The control flow from the timer to the startup triggering as the second mode is as follows: firstly, the livestock health recorder 1 is in an initialization state, when the handheld reading equipment 2 and/or the slaughterhouse automatic data reading equipment 3 reads the data of the livestock health recorder 1, a timer triggers the livestock health recorder 1 to start up, and the temperature sampling ADC parameter is initialized; collecting ADC values of ear temperature and environment temperature, and converting the corresponding ADC values into corresponding temperatures; then the ear temperature and the ambient temperature are stored in the local FLSAH; a BE/ZIGBEE communication module is initialized, and signals are sent to the handheld reading equipment 2 and/or the slaughterhouse automatic reading data equipment 3 through the BE/ZIGBEE communication module; in the system for extracting the livestock health record in real time, the single chip module 13 in the livestock health record instrument 1 judges whether a response message of the reading device is received? If so, executing and finishing the task and the command issued by the reading terminal, and then executing and closing all module power supplies; if not, all module power supplies are closed, data is stored at the latest sampling frequency, and a start alarm clock is set; the system then enters a deep sleep state.

In addition, the technical solutions in the embodiments of the present invention may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination of technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way. Those skilled in the art can make numerous possible variations and modifications to the described embodiments, or modify equivalent embodiments, without departing from the scope of the invention. Therefore, any modification, equivalent change and modification made to the above embodiments according to the technology of the present invention are within the protection scope of the present invention, unless the content of the technical solution of the present invention is departed from.

Claims (10)

1. A real-time livestock health record extraction system, the system comprising: the livestock health recorder (1), the handheld reading device (2) and/or the slaughterhouse automatic reading data device (3) are characterized in that the livestock health recorder (1) stores body temperature data and environment temperature data of the whole life process of livestock locally in real time, and when the handheld reading device (2) and/or the slaughterhouse automatic reading data device (3) need to read the temperature data, the required temperature data are transmitted in a wireless communication BT/ZIGBEE wireless protocol mode.

2. The real-time livestock health record extraction system of claim 1, wherein said livestock health record meter (1) comprises:

the awakening triggering working module is a front-end RFID detection receiving module (11) which is used for receiving specific RFID frequency signals sent by the handheld reading equipment (2) and/or the slaughterhouse automatic reading data equipment (3);

a singlechip module (13) for controlling the work of the recorder and storing local data;

a built-in battery module (15) for providing power supply for the operation of the singlechip module (13);

a BT/ZIGBEE wireless communication module (14) used for carrying out data communication with a handheld reading device (2) and/or a slaughterhouse automatic reading data device (3);

an in-vivo temperature sensor module (16) which is tightly attached to the skin of the ear root of the livestock and is used for monitoring the temperature of the ear root of the livestock;

an in vitro temperature sensor module (17) which is far away from the skin of the livestock and is used for monitoring the temperature of the environment around the livestock;

the temperature data that will survey are sent for single chip module (13) to internal temperature sensor module (16) and external temperature sensor module (17), single chip module (13) receive front end RFID survey receiving module (11) the instruction need with data transmission hand-held reading equipment (2) and/or slaughterhouse automatic reading data equipment (3) time, single chip module (13) send the instruction for BT/ZIGBEE wireless communication module (14) through wireless communication BT/ZIGBEE wireless protocol send hand-held reading equipment (2) and/or slaughterhouse automatic reading data equipment (3).

3. The system for extracting the livestock health record in real time as claimed in claim 2, wherein the body temperature data of the in-vivo temperature sensor module (16) and the in-vitro temperature sensor module (17) are stored in a non-loss Flash storage space of the single chip microcomputer module (13), and the Flash storage space can support continuous recording of the body temperature data for 2 years or more than 2 years.

4. The livestock health record real-time extraction system of claim 1, wherein said hand-held automatic reading device (2) comprises:

the system comprises a front-end RFID specific frequency transmitting module (21), an intelligent operating system core mainboard (23), a built-in battery module (25), a BT/ZIGBEE wireless communication module (24) and an LTE communication module (26); the built-in battery module (25) provides a working power supply for the intelligent operating system core mainboard (23); the intelligent operating system core mainboard (23) sends an instruction to the front-end RFID specific frequency transmitting module (21), the front-end RFID specific frequency transmitting module (21) triggers the livestock health recorder (1) to start working through a specific RFID frequency signal, and the BT/ZIGBEE wireless communication module (24) calls temperature data in the livestock health recorder (1) through a wireless communication BT/ZIGBEE wireless protocol; the LTE communication module (26) directly transmits the historical body temperature data read from the intelligent operating system core main board (23) to the background cloud database for storage through LTE wireless communication.

5. The real-time livestock health record extraction system of claim 1, wherein said slaughterhouse automatic data reading device (3) comprises:

the system comprises a front-end RFID specific frequency transmitting module (31), an intelligent operating system core mainboard (33), a built-in battery module (35), a BT/ZIGBEE wireless communication module (34) and an LTE communication module (36); the built-in battery module (35) provides a working power supply for the intelligent operating system core mainboard (33); the intelligent operating system core mainboard (33) sends an instruction to the front-end RFID specific frequency transmitting module (31), the front-end RFID specific frequency transmitting module (31) triggers the livestock health recorder (1) to start working through a specific RFID frequency signal, and the BT/ZIGBEE wireless communication module (34) calls temperature data in the livestock health recorder (1) through a wireless communication BT/ZIGBEE wireless protocol; the LTE communication module (36) directly transmits the historical body temperature data read from the intelligent operating system core main board (33) to the background cloud database for storage through LTE wireless communication.

6. The real-time livestock health record extraction system of claim 1, wherein said livestock health record instrument (1) adopts two power-on modes: one is that the reading device wakes up to trigger the start-up, and the other is that a timer is triggered to start-up.

7. The real-time livestock health record extraction system according to claim 6, characterized in that, firstly, the livestock health record instrument (1) is in an initialization state, when the hand-held reading device (2) and/or the slaughterhouse automatic reading data device (3) reads the data of the livestock health record instrument (1), the reading device wakes up to trigger the livestock health record instrument (1) to be powered on, and temperature sampling ADC parameters are initialized; collecting ADC values of ear temperature and environment temperature, and converting the corresponding ADC values into corresponding temperatures; then the ear temperature and the ambient temperature are stored in the local FLSAH; and initializing the BE/ZIGBEE communication module, and sending a signal to the handheld reading equipment (2) and/or the slaughterhouse automatic data reading equipment (3) through the BE/ZIGBEE communication module.

8. The real-time livestock health record extraction system of claim 7, characterized in that the single-chip module (13) in the livestock health record instrument (1) determines whether a reading device response message is received? If so, executing and finishing the task and the command issued by the reading terminal, and then executing and closing all module power supplies; if not, all module power supplies are closed, data is stored at the latest sampling frequency, and a start alarm clock is set; the system then enters a deep sleep state.

9. The real-time livestock health record extraction system according to claim 6, characterized in that, firstly, the livestock health record instrument (1) is in an initialization state, when the hand-held reading device (2) and/or the slaughterhouse automatic reading data device (3) reads the data of the livestock health record instrument (1), the timer is triggered to start the livestock health record instrument (1) and initialize the temperature sampling ADC parameter; collecting ADC values of ear temperature and environment temperature, and converting the corresponding ADC values into corresponding temperatures; then the ear temperature and the ambient temperature are stored in the local FLSAH; and initializing the BE/ZIGBEE communication module, and sending a signal to the handheld reading equipment (2) and/or the slaughterhouse automatic data reading equipment (3) through the BE/ZIGBEE communication module.

10. The real-time livestock health record extraction system of claim 9, characterized in that the single-chip module (13) in the livestock health record instrument (1) determines whether a reading device response message is received? If so, executing and finishing the task and the command issued by the reading terminal, and then executing and closing all module power supplies; if not, all module power supplies are closed, data is stored at the latest sampling frequency, and a start alarm clock is set; the system then enters a deep sleep state.

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