• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    Method and system for management, monitoring and traceability of extensive livestock. The present invention relates to a method and system for the localization and monitoring of animals by means of devices (itm) (1) associated thereto. These devices transmit, wirelessly, the status information and location of the animal to communication nodes (nc) (2) arranged in the installation. These nc devices may have associated installation monitoring devices (3) that measure physical parameters of the installation. In turn, the nc devices communicate with a central server (4) where information is collected and analyzed. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2599381A1
    申请号:ES201530947
    申请日:2015-07-01
    公开日:2017-02-01
    发明作者:Carlos Callejero Andres;Ignacio GOMEZ MAQUEDA;Ruben BLANCO CARRERA
    申请人:Carlos Callejero Andres;Ignacio GOMEZ MAQUEDA;Ruben BLANCO CARRERA;
    IPC主号:
    专利说明:

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    Previously, the central server of the installation will be configured as a repeater;
    • Receive on the general central server from the central server, information about an anomaly in the state of the animal associated with the ITM device or an anomaly related to the status of the operation measured by a sensor present in a monitoring device of the installation;
    • Receive on the general central server, from the central server, information on status or environment sensors from the NC nodes or from the ITM devices or from the installation monitoring devices;
    • If the activation of an alarm is determined, send to the owner of the farm or to the intervening agent that a message with information about said alarm and the estimated location of the animal for which the alarm has been activated is activated through the general central server;
    • Store, analyze and extract patterns in relation to the information coming from the different sensors of the different farms so that it constitutes an algorithm for the early detection of anomalies.
    • Interact with the different agents involved in the solution by providing information regarding their role in a friendly way.
    • Store records related to the animal and its associated meat products from the moment of birth of the animal until its consumption by final consumers.
    Finally, in a final aspect of the invention a computer program is presented comprising instructions executable by computer to implement the method described above. The computer program can be run on a computer, a digital signal processor, an application-specific integrated circuit, a microprocessor, a microcontroller or any other form of programmable hardware.
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    Figure 4 schematically shows the block architecture of a communications node NC according to an embodiment of the invention. Figure 5 schematically shows the block architecture of a device that can be associated with the system for monitoring the environment according to an embodiment of the invention. Figure 6 shows schematically the block architecture of the central server of the installation that communicates with the rest of the NC according to an embodiment of the invention. Figure 7 schematically shows the block architecture of the general central server of the system that can control one or more installations according to an embodiment of the invention. DETAILED DESCRIPTION OF THE INVENTION
    The objective of the present invention is to develop a method and system consisting of several devices and algorithms that provide a service for extensive livestock, for all agents involved in the process from start to finish: farmers, veterinarians, feed suppliers, slaughterhouses , cutting, packaging and distribution rooms, public administrations (animal health and welfare, health and consumption) and final consumers. The invention will facilitate the exchange of information between them, improving the productivity of farmers, the welfare of animals, the traceability of meat products from the origin to the final consumer; it will allow the detection and control of pandemics, it will reduce the use of medicines, it will allow to know if the cattle ranch meets certain conditions of certification, its transport and distribution conditions will also be known. For this purpose, animal monitoring devices, hereinafter ITM, will be used, which will allow the control of the location, monitoring of physical parameters such as activity, temperature, etc .; devices for the monitoring of the farm, hereinafter devices for monitoring the farm, which will allow the monitoring of physical parameters of the farm such as climatology and monitoring of feeders, drinking fountains, etc .; communications nodes deployed by the installation, hereinafter NC, a method and algorithms that allow the traceability of the meat product from the origin to the final consumer, through the exchange of information with different agents in the distribution chain.
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    Figure 1 shows the overall architecture of the complete system in its most basic version. The system consists of several basic and essential fundamental elements such as the monitoring and location devices of ITM animals, (1); the NC communications nodes, (2) that receive the information from the ITMs (1). Additionally, these NC communication nodes (2) can communicate wired or wireless with environment sensors (19) grouped in one or more monitoring devices (3) that monitor environment variables such as temperature, humidity, etc. The third fundamental element is the central or installation server (4) that communicates with the NC communication nodes and will be located on the farm. The last fundamental element of the system is the general central server (5) that can be located at any point given the current possibilities of network servers.
    Communication between the different elements can be done wirelessly (via WiFi, Bluetooth, ZigBee communication, mobile telephony or any other type of wireless communication). In order to carry out the different services, all the elements can communicate with each other through the central server or server of the installation (4) or through the general central server (5). Communications with the installation server and / or with the general central server can be done through different NC communication nodes (2), which communicate the different previous elements (ITMs (1), environment sensors that monitor physical variables of the environment present in the monitoring devices of the installation and central server (4)). These communication nodes are necessary for various reasons, to facilitate the location of the animals through the strength of the received signal as will be explained later. and to communicate the ITM (1) with the central server (4) since the distance between them is high.
    The ITM (1) monitor different variables related to the state of the animal such as its temperature, activity level, heart rate, location, etc. and send it to the NC communication nodes (2). The NC (2) in the animal's coverage area receive this information and forward it to the central server (4) or server of the installation (4) and / or to the general central server (5) where it can be analyzed and generate alarms in values function. Alternatively, the central server may, in turn, forward this information to the general central server where this information will be analyzed based on the collected values, based on historical data from other farms, etc., and the possible ones will be generated
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    alarms The detail of the information monitored by the sensors (10) incorporated in the ITMs (1) is:
     Information regarding the state of the animal from sensors such as temperature sensors, heart rate sensors of the animal, motion sensors, or any other type of sensors that allow the monitoring of physical variables related to the state of the animal.  Information on the location of the animal. Each ITM device will transmit a beacon signal at regular intervals. This beacon signal is received by several NC (2) that transmit the information of the power received in said beacon signal to the central server (4). The central server (4) will calculate the position of the animal based on the power received by different NC (2) and based on a previous mapping of the farm. Alternatively, the central server (4) will retransmit the power information to the general central server (5) so that it estimates the position of the animal. Additionally, the ITM (1) may contain a GPS sensor to calculate the position of the animal for applications that require greater accuracy.
    Additionally, and alternatively, the ITM (1) will be able to analyze the information coming from the sensors related to the monitoring of the state of the animal by means of algorithms that detect anomalies in the measured parameters comparing them with adaptive thresholds of precalculated detection. When an anomaly is detected, the ITM (1) sends an animal identification and an anomaly identification to the NC (2) that relays it to the central server (4) or installation server (4) and / or to the general central server
    (5) to carry out the appropriate actions such as reanalyzing the information, notify the owner of the operation, etc. In the preferred embodiment, the information is sent unprocessed from the ITMs (1) to the central server or the installation (4), through the NCs (2), for analysis and processing. In a further embodiment, what is done is a mixture of the two previously proposed solutions, that is, some parameters are processed in the ITM itself (1) and the server (4) is notified in case of failure (for example, the The animal's body temperature has exceeded a certain threshold) and other parameters (for example, the level of activity of the animal) are sent to the central server (4) or to the general central server (5), who detect the possible anomalies.
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    Additionally, the ITM (1) may inform periodically or by request of the central server (4), the central server (4) and / or the general central server (5) of the battery status of said device. Thus, for example, if the battery charge is below a threshold, the central server (4) can, for example, send an alarm to the owner of the facility indicating the location and identification of the animal in which Low battery level.
    Both the ITM (1), as the NC (2), as the optional devices for the monitoring of the installation and the central server (4), are portable devices and, being able to be powered by batteries or solar panels, can be installed in several farms in case the cattle are itinerant.
    The NC communications nodes (2) that are installed in mesh form on or around the farm to ensure coverage throughout the field consist of a hardware platform with one or more wireless communication interfaces to perform a triple function:
     Firstly, to ensure communication between the ITMs (1) and the central server (4). The sensors will be deployed in mesh form throughout the farm or in the surroundings to ensure bidirectional communication between the ITMs (1) and the central server (4). Thanks to this communication, the ITM (1) will send the information related to the animal's status and location.
     Secondly they receive and calculate a beacon signal from each of the ITMs (1). Each ITM (1) at regular intervals emits a beacon signal, this beacon signal is received by one or more communication nodes. These communications nodes calculate the power of the received beacon signal and send the calculated value to the central server (4) for processing.
     Thirdly, the communication nodes are responsible for guaranteeing bidirectional communication between the sensors that monitor physical parameters of the installation, present in the monitoring devices of the installation (3), and the central server. Through this communication channel, the values of the physical quantities are
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     When the farmer sells the animal to a fattening or slaughterhouse to be slaughtered, the farmer fills a record in the system and proceeds to remove the ITM (1) from the animal.  The owner of the slaughterhouse and the cutting room fills in the records associated with their activity. As a date of sacrifice, broken units, etc. Once the products are sold, fill in new records.  In this way, records will be filled according to the meat product progressed along the distribution chain.  Finally, the final consumer when acquiring the meat product may consult a code associated with the product and thus have real and truthful information about the product purchased.  Additionally and in parallel to the process, public authorities may have access to the information generated throughout the entire process.
    The interaction between the agents along the distribution chain gives added value to these participants by having truthful information about the meat product they are acquiring. In addition, a series of automatisms are generated that allow the reduction of costs and the increase of productivity by the agents involved in the system.
    With this system, the public authorities gain a tool for the control and analysis of pandemics since there is a monitoring system for the animal from birth to death, as well as the feed consumed and the vaccines and veterinary treatments received. So if at any given time a problem with a vaccine or feed is detected, the authorities know in real time which animals have been treated with said vaccine or have eaten said feed and what is its status along the distribution chain .
    Additionally, the farmers themselves can also, according to one of the embodiments of the invention, prevent sanitary problems in their animals by historical comparison with the events that occur in other farms. In this way, if it is detected, in an operation, that a certain animal has had a series of behaviors that have resulted in a disease, the present invention may include said parameters in the detection of anomalies and notify farmers whose animals present the same type of behavior
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    权利要求:
    Claims (4)
    [1]
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    -if the activation of an alarm is determined, send a message with information about said alarm to the owner of the installation or other agent involved.
    [14]
    14. System according to claim 13 wherein the general central server (5) in addition
    5 comprises an anomaly search module configured to store, analyze and extract patterns based on the information received from the sensors (10, 15, 19) of different facilities with which to find common points between the historical data of the affected animals, compare said common points found with the historical data of each animal in each of the facilities; and identify and locate the animals that
    10 have been exposed to the same causes as sick animals.
    [15]
    15. System according to any of claims 11-13 wherein at least one ambient condition sensor and / or at least one status sensor are external to the ITM monitoring device (1) and communicate with the ITM monitoring device (1) by
    15 a communications interface.
    [16]
    16. A computer program product comprising computer executable instructions for performing the method according to any of claims 1-10, when the program is executed on a computer.
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    同族专利:
    公开号 | 公开日
    WO2017001717A1|2017-01-05|
    ES2599381B1|2017-11-08|
    引用文献:
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    ES2688738A1|2017-05-05|2018-11-06|Jose Ignacio GARCIA FERREÑO|Method for the management of production, warehouse and inventories with RFID system for identification and traceability of bales and their movements |
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    US11071279B2|2014-09-05|2021-07-27|Intervet Inc.|Method and system for tracking health in animal populations|
    法律状态:
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    ES201530947A|ES2599381B1|2015-07-01|2015-07-01|Method and system for the management, monitoring and traceability of extensive livestock|ES201530947A| ES2599381B1|2015-07-01|2015-07-01|Method and system for the management, monitoring and traceability of extensive livestock|
    PCT/ES2016/070486| WO2017001717A1|2015-07-01|2016-06-29|Method and system for management, monitoring and traceability for extensive livestock farming|
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