CZ309763B6 - An assembly for transmitting measurement data from a probe located in the rumen of cattle and a method of transmitting the measurement data - Google Patents

Abstract

An assembly for the transmission of measurement data from a probe (S) located in the rumen of cattle, especially dairy cattle, to an extracorporeal receiver (M), when a device (Z) adapted to receive and transmit the data from the probe (S) to the extracorporeal receiver (M) is incorporated between the probe (S) and the extracorporeal receiver (M). The method of transmission of the measurement data is characterized by the fact that the data from the rumen probe (S) is received and processed by one device (Z) paired with the rumen probe (S) and located on the body of the cattle, while the data is subsequently received and processed by any extracorporeal receiver (M).

Description

Assembly for transmitting measured data from a probe placed in the rumen of cattle and method of transmitting measured data

Field of technology

The subject of the invention is an assembly for transferring measured data from a probe placed in the rumen of cattle, especially dairy cattle, to an extracorporeal receiver. The subject of the invention is also a method of transmitting measured data.

Current state of the art

The health of high-producing dairy cows is closely related to their nutrition, especially during calving. At the beginning of lactation, the rapidly increasing milk production results in high energy demands. In order to cover the increased energy requirements as much as possible, freshly calved cows receive feed with a higher proportion of grains as a source of starch and sugars. In the rumen, amylolytic bacteria produce lactic acid, which, if present in excess, can lower the pH of the rumen contents. Rumen acidification can be enhanced by poor forage structure, leading to reduced rumination intensity and thus a reduction in the influx of sodium bicarbonate, a buffer, into the rumen. A typical consequence is subacute ruminal acidosis, Subacute Ruminal Acidosis - SARA, which is manifested by chronic episodes of reduced rumen pH (<5.8), resulting in a cascade of undesirable consequences, such as a reduced ability of the microbiota to digest fiber, reduced acetic acid production, lower microbial protein production, decreased milk yield and multiple health disorders.

Continuous measurement of rumen content parameters (such as pH, temperature, ORP, i.e. oxidation-reduction potential, interpretation of measured values in the context of other variables such as diet, milk yield, milk quality, movement, rumination and taking appropriate measures allows to improve care during the transition period , to set a balanced nutritional strategy and improve the health of dairy cows. This contributes to reducing veterinary costs, reducing the frequency of premature slaughter, extending the productive life of cows and increasing milk production. The not-negligible consequence is also an improvement in the living conditions of the animals and an overall increase in the cost-effectiveness of breeding.

A device for data transmission between a probe and an extracorporeal receiver is known from the state of the art, for example from WO 2012173502 A1, US 6694161 B2 and US 20020128542 A1. Existing methods of monitoring condition in the rumen of cattle are described in US 10905100 B2. From the document US 20080236500 A1, a method of monitoring dairy cattle in particular is known, which is implemented between a probe located in the rumen and an extracorporeal device, whereby the identification of a specific animal is given by the connection between the extracorporeal receiver and the RF ID tag located in the ear of a specific animal.

The disadvantage of all mentioned solutions is that the data transfer from the rumen is realized by direct communication between the extracorporeal receiver and the rumen probe forming the existing equipment for the transfer of measured data. However, these devices and the method of transmitting measured data have a considerably limited range, lower reliability and higher energy consumption. This is due to the fact that the radio signal originates from the aqueous environment of the rumen and continues to pass through the tissues of the animal, being significantly attenuated in both of these environments. This problem is significantly eliminated by the solution described in the present invention.

The essence of the invention

The essence of the invention is an assembly for the transmission of measured data from a probe located in the rumen of cattle, especially dairy cattle, to an extracorporeal receiver, while a device adapted to receive and transmit data from the probe to the extracorporeal receiver is incorporated between the probe and the extracorporeal receiver. A condition

- 1 CZ 309763 B6 required function of the device adapted to receive and transmit data is that it is located near the probe, which is located in the rumen of the animal.

It is advantageous if the data from the probe is received and processed by a device placed on the body of the cattle, thus ensuring the mutual proximity of the probe and the device. This device is technically referred to as a so-called wearable device, the data sent from this device is subsequently received and processed by an extracorporeal receiver. With this arrangement and the resulting method of data transmission, the reliability and energy efficiency of the transmission is significantly increased, and the communication range is increased many times over. The connection between the rumen probe and the electronic device placed on the body of the cattle is always 1:1.

The device placed on the body of the cattle consists of a radio transmitter-receiver attached to a collar, which is placed on the neck of the cattle. Alternatively, it can be placed on the limb of the animal in whose rumen there is a probe. The probe, i.e. the bolus, is paired with just one device placed on the cattle's body, and conversely, this device is tied to only one probe placed in the rumen of the same animal. Both interacting units, i.e. the rumen probe and the electronic device on the animal's body, are assigned a unique ID, i.e. the device address. During the configuration phase, before or after application of the rumen probe, the probe is paired with a device placed on the cattle's body. The ID is stored in the power-independent, i.e., flash memory of both the probe and the device on the animal's body and is used to distinguish communication from other pairs of probe - device on the animal's body, installed on/in neighboring animals.

For reasons of energy saving, algorithms are used for precise time synchronization between individual communication nodes: a rumen probe, a device placed on the cattle's body, a base station, and a TDM transmission scheme, i.e. Time Division Multiplexing. Communicating devices first negotiate transmission windows and wake up from a power-saving deep sleep mode only for a short time to exchange data. It is possible to use, for example, a transmission window with a length of 2 ms scheduled every 20 s. However, the timing is not limited to this scheme.

It is advantageous if the probe is paired with exactly one information device located on the body of the cattle. Conversely, the electronic device placed on the body of the cattle is bound to only one probe placed in the rumen of the animal, i.e. 1:1 binding.

It is advantageous if the data, after being received by the device placed on the body of the cattle, is stored in the buffer memory of this device. The data transmitted from the rumen probe is protected by a CRC code and its reception by the device on the animal's body must be confirmed - the probe keeps the measured data in a buffer and repeats the transmission until the data reception is confirmed by the device on the animal's body. The data received by the device placed on the animal's body is then included in the FIFO buffer and is the subject of further transmission to the base station, i.e. to the extracorporeal device.

A device placed on the neck of the monitored animal is therefore inserted into the communication chain, which serves as a buffer for the measured data and at the same time as a retransmitter. The strongly attenuated signal from the rumen probe is therefore transmitted only a short distance from the rumen to the animal's neck and then unattenuated or Incomparably less damped air-to-air channel to the extracorporeal receiver, i.e. to the base station. With this mechanism, the reliability and energy efficiency of the transmission is significantly increased and the communication range is increased many times over.

It is advantageous if the data, after being received from the memory of the extracorporeal receiver, are subsequently stored on a global server. This is achieved by saving the obtained data for further analysis or further evaluation of the health status of the animals. Alternatively, the data is stored on local storage.

It is advantageous that the device placed on the body of the cattle is not paired with a specific extracorporeal receiver. This method of communication makes it possible to install multiple extracorporeal devices in the breeding area and to transmit data from the device on the animal's body to any extracorporeal receiver near which the animal happens to be.

- 2 CZ 309763 B6

It is advantageous if the device on the animal's body also consists of an accelerometer sensing the movement of the animal with a subsequent classification of movement types, for example sleep, rest, walking, chewing, food intake. The times spent on individual activities help to indicate the health status of the animal.

It is advantageous to place the extracorporeal device near the points of interest of the animals - drinking troughs, troughs with feed or milking parlors. This ensures frequent transmission of measured data from the device placed on the animal's body.

It is advantageous if the data transmission from the probe to the device located on the body of the cattle takes place at a frequency in the range of 150 MHz to 450 MHz. The reason is the lower attenuation of radio waves by the tissues and water environment of the rumen at lower frequencies.

It is also advantageous if the wireless data transmission from the device placed on the body of the cattle and the extracorporeal receiver is implemented at a frequency in the range of 150 MHz to 5.5 GHz. The mentioned frequency range contains several free bands and standardized protocols, from which it is possible to select a suitable candidate for a specific application.

Clarification of drawings

The overall scheme of the assembly for the transfer of measured data from the probe placed in the rumen is shown in Fig. 1, Fig. 2 shows the scheme of the assembly with the method of data transmission between communication nodes: rumen probe, device placed on the body of cattle, base station, global server .

An example of the implementation of the invention

The assembly for the transmission of measured data from a probe placed in the rumen of a dairy cattle consists of a probe S, an extracorporeal receiver M, between which is incorporated a device Z adapted to receive data from the probe S and transmit data to the extracorporeal receiver M. In this particular exemplary embodiment, the device Z placed on the body of the cattle, in whose rumen the probe S is placed. The device Z is placed on the collar, which is placed on the neck of the animal. Probe S contains an electrochemical pH sensor, a temperature sensor and a platinum electrode for measuring ORP. The S probe also includes a battery and electronics that ensure the amplification of input signals, periodic measurements and data preprocessing and their transmission using a radio signal. Probe S is paired with exactly one device Z. Device Z contains a buffer memory. The device Z also allows data to be transmitted to one or more extracorporeal receivers M. The device Z also contains a MEMS accelerometer. By analyzing the data measured by it, it is possible to determine the animal's movement type, and the ratio of time spent in different types of movement can then help determine the animal's health status. The extracorporeal receiver M, which is adapted to receive data sent by the device, is connected to the global server C. At the same time, the data is stored on local storage. Probe S and device Z communicate with each other at a frequency between 150 MHz and 450 MHz. Device Z and extracorporeal receiver M communicate with each other at a frequency between 150 MHz and 5.5 GHz.

The method of transmitting the measured data between the rumen probe S and the device on the body of the cattle Z is implemented in such a way that the data from the rumen probe S is received and processed by one device Z placed on the body of the cattle paired with the rumen probe S. The rumen probe S contains an electrochemical pH sensor, a temperature sensor and a platinum electrode for measuring the ORP redox potential. The rumen probe S also contains a battery and electronics ensuring the amplification of input signals, periodic measurement and data preprocessing and their transmission using a radio signal. All components of the rumen tube S are attached to a solid plastic frame and hermetically sealed in a silicone bolus. The device Z placed on the body of the cattle is placed on the collar of the animal. The data, after reception, is stored in the buffer FIFO memory of the device Z located on the body of the cattle. The data is subsequently received and processed by any extracorporeal receiver M near which the animal is

- 3 CZ 309763 B6 occurs. The number of extracorporeal devices M is arbitrary and it is advisable to place them near the points of interest of the animals - drinking troughs, troughs with feed or milking parlors. This will ensure frequent transmission of measured data from the device Z located on the animal's body. After the data is received by the extracorporeal receiver M, it is then stored on the global server C or in the local database. The radio transmission of data from the rumen probe 5 S to the device Z located on the body of the cattle takes place in this particular embodiment at the frequency

433 MHz in the unlicensed ISM band. Data transmission from the device Z placed on the body of the cattle and the extracorporeal receiver M takes place at a frequency of 2.4 GHz in the unlicensed ISM band.

Industrial applicability

The tool described according to the invention finds its application in diagnosing the state of health of animals, monitoring the parameters of the content of the internal organs of farm animals, especially dairy cattle.

Claims (8)

1. Assembly for the transmission of measured data from a probe (S) located in the rumen of cattle, especially dairy cattle, to an extracorporeal receiver (M), characterized by the fact that a device (Z) adapted to to receive and transmit data from the probe (S) to at least one extracorporeal receiver (M) located near the movement of the cattle, when the device (Z) is placed on the body of the cattle, in the rumen of which the probe (S) paired with exactly one device ( OF). 2. An assembly for the transmission of measured data according to claim 1, characterized in that the device (Z) placed on the body of the cattle is wirelessly connected to at least one extracorporeal receiver (M). 3. An assembly for the transmission of measured data according to claim 1 or 2, characterized in that the device (Z) contains an accelerometer. 4. An assembly for the transmission of measured data according to one of the preceding claims, characterized in that the extracorporeal receiver (M) is connected to a global server (C). 5. An assembly for the transmission of measured data according to one of the preceding claims, characterized in that the device (Z) contains a memory buffer. 6. The method of transmitting measured data according to one of the preceding claims, characterized in that the data from the probe (S) is received and processed by one device (Z) paired with the probe (S) located on the body of the cattle, whereby the data is subsequently received and processed by any extracorporeal receiver (M). 7. The method of transmitting measured data according to claim 6, characterized in that the probe (S) and the device (Z) communicate with each other at a frequency in the range of 150 MHz to 450 MHz. 8. The method of transmitting measured data according to claim 6 or 7, characterized in that the device (Z) and the extracorporeal receiver (M) communicate with each other at a frequency in the range of 150 MHz to 5.5 GHz.