AT517847B1 - Probe unit for measuring at least one state variable of the organism of a farm animal and method for their commissioning - Google Patents

Abstract

The invention relates to a method for starting up a probe unit (1) for measuring at least one state variable of the organism of a farm animal (2), comprising the following steps: a) activating the probe unit (1) from a switched-off state into a switched-on state; b) performing an automatic function test within the probe unit (1), c) reproducing a first signal (301) by the probe unit (1) when the bump test is successfully completed, and reproducing a second signal (302) different from the first signal (301) ) by the probe unit (1) if the bump test is not completed successfully. The invention further relates to a probe unit (1) for measuring at least one state variable of the organism of a farm animal (2) of a farm animal, wherein the probe unit (1) in the gastrointestinal tract (3) of the farm animal can be arranged and according to the invention at least one signal output unit (12) Reproduction of a signal (301, 302, 399, 401, 601, 602).

Description

description

PROBE FOR MEASURING AT LEAST ONE CONDITIONAL SIZE OF THE ORGANISM OF ANIMATED ANIMAL AND METHOD OF COMMISSIONING THEREOF

The invention relates to a method for commissioning a probe unit for measuring at least one state variable of the organism of a farm animal and such, can be arranged in the gastrointestinal tract of the livestock probe unit.

The operational structures of agricultural enterprises are changing worldwide increasingly in the direction of large farms. Here, for example, for farmers in livestock herd management, especially in the field of individual health monitoring or performance-appropriate feed allocation, increasingly difficult. The parameters that play a role in the well-being and feed requirements of the individual animals include, in addition to external state information such as temperature, oxygen content or air humidity in the barn, physiological parameters such as gastric juice pH, body temperature or others.

With increasing operating size is due to this variety of parameters an individualized feeding little more possible; Also, disease symptoms in individual animals often can not be detected in time. Nevertheless, in order to enable species-appropriate husbandry and economic production, it is of enormous importance for the farmer to know about the parameters that play a role in the well-being of the animals.

This is increasingly resorting to electronic management aids. For example, DE 199 01 124 A1 describes a bolus-shaped probe which can measure sensors for measuring various physiological state variables such as pressure, temperature, conductivity, pH value or ammonia content and is introduced into the gastrointestinal tract of a cattle. The Applicant's AT 509 255 B1 describes a similar probe unit in which the measurement data can be transmitted wirelessly, wherein the measurement sensor system for protection against mechanical damage within an acid-resistant housing is at least partially surrounded by a cylindrical protective device. In this case, the probe unit can transmit data to base stations distributed in a stall and can be operated or read via the latter via the Internet.

In particular, the activation is relatively complex: After production and delivery routes, the probe unit reaches the user in an energy-saving state - measuring sensors and transmission unit are disabled. This means, for example, that the correct channel is not yet used for the data transmission or the time settings can deviate from a system time. Furthermore, the measuring sensor is partially not yet calibrated.

According to the prior art, therefore, the probe unit must be activated by the user and by contacting a remote station - usually a PC with the required software and a radio unit, e.g. a USB antenna - to be configured. Upon contact, the user is notified that the probe unit is in operation and a process is started that changes the configuration of the probe unit over several communication steps, synchronizes it with a correct time retrieved from the Internet, changes the channel of the probe unit and User at the end indicates that this probe unit can now be used. In addition, the measurement sensor system is calibrated in the course of this initialization, for example by placement in a calibration solution.

This approach has a number of disadvantages: A PC with suitable software is required, whose installation usually requires administrator rights, a radio interface and an antenna as well as associated drivers and also an Internet connection. Thus, the activation of probe units is only possible in certain places that meet all these requirements, such as offices.

Since the probe units are provided with resistant housings without openings and with as few ornaments as possible, a correctly initialized probe unit can not be distinguished from a new or a defective unit. Thus, it can not be said with certainty whether the probe unit can be input to an animal.

Since the initialization is done via radio, it comes to consuming battery capacity of the probe unit - in an accidentally initialized unit is not visible from the outside that it is already running. Since the radio interface between the PC and the probe unit is shared - transmission medium air only a few units can be initialized in parallel.

In WO 2011/073987 A1, a system for initializing an imaging in vivo device is described, with a test unit for functionality test; The functionality test is based on a radio signal that is sent to the in-vivo device. US 2010/0300462 A1 discloses a bolus for monitoring livestock parameters that are transmitted as radio signals to a receiver site. Another bolus, namely for monitoring physiological parameters, is described in US 6,099,482. Further boluses and devices for measuring livestock parameters are disclosed in GB 2455 700 A, US 2002/0128542 A1, WO 2012/047150 A1 and US 2010300922 A1.

It is therefore an object of the invention to remedy the above-mentioned disadvantages and to provide a method with which a commissioning of a probe unit can be done in a simple manner without a large amount of equipment.

It is further an object of the invention to provide a corresponding probe unit, which can be activated quickly and easily and reduces or makes impossible erroneous operations.

This object is achieved by the method mentioned above according to the invention by the following steps: a) activating the probe unit from a turned-off state in a switched-on state; B) performing an automatic functional test within the probe unit, c) reproducing a first signal by the probe unit when the bump test is successfully completed, and reproducing a second signal different from the first signal by the probe unit if the bump test fails successfully completed.

In other words, after the activation takes place an internal functional test and depending on the result of a perceptible outside the probe unit signaling. The invention thus allows a commissioning of the probe unit without contacting the environment - the user can clearly identify from the signals whether the commissioning was successful and the probe unit is ready for use or defective. This reduces the complexity of commissioning, it requires no additional equipment with specific characteristics and the duration of the probe unit is extended because no radio communication must be disputed during initialization. Quick and uncomplicated, a large number of probe units can be put into operation anywhere. The probe unit does not need to have special switches or interfaces and can therefore be completely sealed and therefore liquid and gas tight. This variant of the invention is particularly suitable for probe units without expensive measuring sensors, e.g. Temperature and motion sensors, applicable.

This is, depending on the field of application of the probe unit in the first and / or the second and / or the third and / or the fourth and / or the fifth signal to at least one of the following signals: an acoustic, an optical, a haptic, a motion signal, combinations of two or more of the foregoing. Acoustic signals can be single tones or tone sequences. Optical signals can be light signals or light signal patterns of individual light sources in always the same or different colors, but also the attachment of small screens in the housing of the probe unit is possible. A haptic signal is understood to be tactile signals, e.g. a change in temperature of parts of the complete probe unit or a vibration. A motion signal may mean more vibration or twitching of the probe unit. Combinations, such as light patterns and tone sequences or others, are possible. This makes it easy for the user to understand and perceptible with his sensory signals signals with little energy consumption feasible.

In a variant of the invention, the following steps are carried out after step c): d) Positioning of the probe unit in a calibration environment, preferably one

calibration; [0022] e) automatic calibration of at least one sensor element of the probe unit by the probe unit; F) reproducing a fourth signal by the probe unit when the calibration is successfully completed and reproducing a fifth signal by the probe unit if the calibration is not completed successfully. Advantageously, after completion of step d), the reproduction of a third signal by the probe unit.

According to this variant, the commissioning of probe units with more complicated measuring sensors to be calibrated - e.g. pH sensors - simply possible. In a step dO), by playing back a sixth signal, the user may be requested to insert the probe unit into the calibration environment. The calibration environment may be e.g. a room with a certain gas composition or just a calibration solution, in the case of a pH sensor to a pH buffer solution with a predetermined composition. The probe unit can in each case be introduced into the calibration environment completely or only in the area of the measurement sensor system to be calibrated. Thus, no additional external device or an external interface is necessary for the calibration.

In order to facilitate the understanding of the meaning of the various signals is provided in a variant of the invention that the fourth signal is identical to the first signal and / or that the fifth signal is identical to the second signal. Thus, the intended for the proper functioning or proper completion signals and the malfunction indicating signals are each made equal.

In a variant of the invention, the signals are at least partially executed as light signals. The first, second, third, fourth, fifth and sixth signals are thus realized with light. The light signals can be simple on / off signals, flashing or light patterns and always run with the same or in different colors. This realizes a particularly easy-to-understand signaling.

In order to enable the simplest possible operation, the activation of the special unit takes place in step a) by bringing at least a portion of the probe unit in contact with a magnetic element arranged outside thereof. This malfunction can be reduced or completely excluded, also can be dispensed with due to the non-contact function on externally operable switch.

Further advantages in the operation can be achieved if, prior to step a), a step aO) is carried out in which at least one of the following information is loaded into a memory element of the probe unit: radio frequency, transmission channel, system time. Thereby, upon activation of the probe unit, the necessary settings can be used immediately without having to connect to an external data source, e.g. the Internet or a configuration PC, is necessary.

In a variant of the invention takes place in at least one of the steps following step a) contacting the probe unit wirelessly with a transmitter station arranged outside of the probe unit, preferably carried out by the probe unit transmitting and receiving steps. The transmission of information that is not yet available or the necessary initialization steps, such as logging on to a network, can thus be done quickly and easily.

As a conclusion of commissioning the probe unit is in a final step z) within a farm animal, preferably in the gastrointestinal tract, placed with proper initialization or calibration of the probe unit advantageously.

The object of the invention is also achieved with a probe unit mentioned in the introduction, which has the following components arranged in a housing: [0032] at least one sensor element for measuring at least one state variable of the

Organism of a livestock, at least one transmitting device, preferably with at least one antenna, for wireless transmission of information, and - at least one control unit for controlling the probe unit, wherein the probe unit according to the invention comprises at least one signal output unit for reproducing a signal ; In this case, the signal output unit for reproducing at least one of the following signals is set up: acoustic signal, optical signal, haptic signal, motion signal, combinations of two or more of the aforementioned.

Various sensor elements are possible, for example for measuring temperature, pH, movement, density, pressure, conductivity, sound, optical properties and others. In addition, conveniently at least one device is provided for powering the probe unit, for example a battery, e.g. by means of "energy harvesting" methods rechargeable accumulator or a capacitor (e.g., double-layer or supercapacitor).

Thanks to the invention, it is possible to arrange all required for the commissioning of the probe unit devices within the probe unit, whereby a simple, misconduct resistant and possible at any location initialization is possible.

In a variant of the invention, the signal output unit has at least one light guide element which connects at least one light source in the interior of the probe unit to a housing of the probe unit. Advantageously, for this purpose, the probe unit is designed with a cylindrical housing and the light guide element is connected to a cover and / or bottom portion of the cylindrical housing.

In order to facilitate initialization without connection to an external data source, in a variant of the invention, at least one memory element connected to the control unit is provided in the probe unit, on which at least one of the following information can be stored: radio frequency, transmission channel, system time.

The invention will be explained in more detail with reference to a non-limiting embodiment, which is illustrated in the drawings. In the drawings, which are given by way of illustration only and thus do not limit the invention in any way, are shown schematically: Figure 1 shows a cow as an exemplary livestock and the arrangement of a probe unit in the gastrointestinal tract; FIG. 2 shows a perspective view of a probe unit according to the invention in the closed state; FIG. Fig. 3 is a side view of the probe unit of Fig. 2 with open lid and

Bottom portion; FIG. 4 is a sectional view of the probe unit; FIG. 5 is a perspective view of a probe unit according to the invention with geöff netem bottom portion. and Fig. 6 is a flow chart of the method according to the invention.

The same elements are provided in the various figures for reasons of clarity with the same reference numeral. Fig. 1 shows the sectional view of a cow 2, wherein the cow 2 is mentioned here only as a possible example of a farm animal, in the gastrointestinal tract 3, a probe unit 1 according to the embodiment of the invention can be introduced. Other suitable farm animals would be, for example, sheep, goats or wild ruminants such as red deer.

The food taken up by the cow 2 and chewed enters the gastrointestinal tract 3 of the cow 2, for example in the rumen or the reticulum. From the network stomach, the ingested food is transported on the one hand into the rumen, on the other hand transported back to the mouth of the cow 2 for ruminating. From the measurement of the status data of the contents of the gastrointestinal tract 3, any effects or conclusions can be determined on the health status of the animal. If the pFI value is too low, for example, dangerous rumen acidosis may occur. The probe unit 1 is therefore located in the gastrointestinal tract 3 of the animal to detect status data.

Fig. 2 shows the probe unit 1 in a perspective view with the housing 4 in the closed state. In the Fign. 3 and 4 cover 41 and bottom portion 42 of the housing 4 are opened. 3 shows a first sensor element 51 projecting out of the housing 4, which is lapped by liquid in the gastrointestinal tract 3-corresponding openings are provided in the lid section 41 for this purpose. The first sensor element 51 is, for example, a pH sensor.

Fig. 4 shows a schematic view of the probe unit: Within the housing 4, a first 51 and a second sensor element 52 are arranged.

As already described, the first sensor element 51 may be a pH sensor, and the second sensor element 52 may be a temperature or motion sensor. Also sensors for the measurement of glucose, volatile fatty acids, acetate, propionate, butyrate and lactate may be provided. Of course, other sensor combinations than described are possible, for example, a temperature and a motion sensor. Also, further sensor elements may be provided.

The sensor elements 51, 52 are connected to a control unit 6, which serves to control the probe unit 1. The control unit 6 is designed, for example, as a correspondingly programmed microprocessor. The control unit 6 controls and processes the data from the sensor elements 51, 52. For storing the data, a memory element 7 may be provided, for example a memory chip or an SD card. The memory element 7 stores both measured values of the sensor elements 51, 52 and operating parameters of the probe unit 1 such as radio frequency, transmission channel, system time and others.

About the transmitting device 8, which has an antenna 9, data is transmitted, for example to a base station (not shown), which is arranged in the vicinity of the farm animal. Conveniently, the transmitting device 8 is designed as a transceiver that can both send and receive data.

The power supply of the probe unit 1 takes place e.g. via a power supply device 10, which may be designed, for example, as a battery, accumulator or capacitor. Recharging through "energy harvesting" methods is also possible.

In the illustrated embodiment, the described components are enclosed within the housing 4 by a hollow, at least the power supply device 10 surrounding protective device 11, which protects against mechanical action. This prevents that the livestock, the probe unit 1 and in particular the components arranged therein, especially the power supply device 10, bites when they in the course of

Rumbling back into the mouth. The protective device 11 can be made of any, resistant material, such as plastics or metals.

According to the invention, the probe unit 1 now has a signal output unit 12, which is arranged within the housing 4. The signal output unit 12 may be configured to emit an audible, visual, haptic, motion signal, or combinations of two or more of the foregoing. For example, the signal output unit 12 may be embodied as a light source, sound generator, as a vibration element or screen.

Thus, it is possible that a user of the probe unit 1 by various signals information is transmitted, for example, the function, the initialization status or the calibration status.

In the exemplary embodiment shown, the signal output unit 12 has a light source 121 arranged inside the housing, for example a single- or multi-colored LED, and a light conductor element 122 which leads from the light source 121 to the bottom section 42 of the housing 4. The light guide element 122 thus connects the light source 121 to the housing 4 (FIG. 5). In the bottom section 42, a transparent window region or a material dilution 123 may be provided, so that the light is easily recognizable from the outside.

The above-mentioned signals can thus be individual light pulses - on / off or signal pattern. Also different colors can be played.

A method according to the exemplary embodiment of the invention using a described probe unit 1 now provides the following steps according to FIG. 6: In a first step 100, the probe unit 1 is activated from a switched-off state into a switched-on state. This can be done, for example, by holding a magnet to a designated activation area 13 (see FIG. 3). Of course, other activation mechanisms are possible, the mechanism described has the advantage that accidental activation of the probe unit 1 can be practically excluded.

In a variant of the invention, information can be uploaded into a memory element 7 of the probe unit 1 in a step 99 upstream of the first step 100. The information may be, for example, the radio frequency to be used, the transmission channel or the system time. Other information is possible.

In a variant of the invention, the system time can be set only when the probe unit 1 is first active in a measuring system - for example, a number of probe units 1 during operation in contact with one or more base or transmitting stations are the Read data, send and another contact eg to the Internet. The probe unit 1 then makes contact with this measuring system after successful commissioning and adapts itself to the system time applicable there.

In a second step 200, a functional test is automatically carried out within the probe unit 1. This functional test consists of a sequence of self-test routines to ensure the proper functioning of the probe unit 1.

Depending on the result of the functional test, then in a third step 300 either a first signal 301 is reproduced when the functional test has been successfully completed and the probe unit 1 is functioning properly, or a second signal 302 different from the first signal 301 is reproduced if a malfunction occurs was determined.

The signals 301, 302 can consist of different light patterns, sequences of tones or vibration sequences.

Thanks to the invention, it is therefore not necessary for a user to establish a connection with a PC with suitable software for the initialization of the probe unit 1, but it is sufficient to activate the probe unit 1 - by reproducing the signals, the user can recognize whether the probe unit 1 is ready for use.

If the probe unit 1 comprises sensor elements which require calibration, this can also be carried out without external devices or interfaces: In a fourth step 400, the probe unit 1 is positioned in a calibration environment. This fourth step 400 may either follow immediately on the first signal 301 or be triggered by a sixth signal 399.

The calibration environment may be, for example, a calibration solution - in the case of a pH sensor unit, a corresponding buffer solution. The probe unit 1 can either be completely submerged or only in the region of the corresponding sensor element, which is arranged in the illustrated embodiment in the region of the lid portion 41 of the housing 4. In a variant of the invention, after proper execution of the fourth step 400, ie if the probe unit 1 is positioned in the calibration environment such that the calibration is possible, a third signal 401 can take place. Thus, if the third signal 401 fails, the user knows that calibration is not possible - because e.g. the positioning has not been done correctly or the calibration environment is not suitable.

In a fifth step 500, an automatic calibration of the sensor element or of the sensor elements is then carried out by running calibration sequences of a known type.

In a sixth step 600, a fourth signal 601 is reproduced by the probe unit 1 or its signal output unit 12 if the calibration has been successfully completed and the probe unit 1 is ready for use. If the calibration was not completed successfully, a fifth signal 602 is output.

To facilitate the operation, the respective positive signals - the first signal 301 and the fourth signal 601 - and the respective negative signals - the second signal 302 and the fifth signal 602 - may be identical to each other.

As described above, the signals 301, 302, 399, 401, 601, 602 are output through a signal output unit 12 disposed within the probe unit 1. Accordingly, the signals may be acoustic, optical, haptic, motion or combinations of two or more of the foregoing. In the described embodiment, the signals 301, 302, 399, 401, 601, 602 are implemented as light signals.

In at least one of the steps following the first step 100, a contact-receiving step 700 may take place with the probe unit 1 contacting wirelessly with a transmitting and receiving station (not shown) located outside the probe unit 1, preferably with the probe unit carried out transmitting and receiving steps. This contact-receiving step 700 may be advantageous if additional data must be imported into the probe unit 1 during the initialization. In this case, for example, the system time can be recorded.

In the meantime, or even during the commissioning, information about the status, e.g. the commissioning or calibration state, via radio link such as e.g. NFC, RFID, etc. are transmitted to a mobile device such as a smartphone, tablet or the like. This transmission can either be initiated by the probe unit 1 or requested by the mobile device.

The inventive method can be completed regardless of the variant carried out with a final step 999, in which the finished initialized and calibrated probe unit 1 within a farm animal, preferably in the gastrointestinal tract 3, is placed.

Thanks to the method according to the invention and the probe unit 1 described simplified commissioning is possible in which no additional equipment is necessary and the possibilities for incorrect operation are drastically limited.

Claims (13)

claims 1. A method for starting a probe unit (1) for measuring at least one state variable of the organism of a farm animal (2), comprising the following steps: a) activating the probe unit (1) from an off state to an on state; b) performing an automatic function test within the probe unit (1), c) reproducing a first signal (301) by the probe unit (1) when the bump test is successfully completed, and reproducing a second signal (302) different from the first signal (301) ) by the probe unit (1) when the bump test is not successfully completed, wherein the signals (301, 302, 399, 401, 601, 602) are at least one of the following: an audible signal, an optical signal haptic signal, a motion signal, combinations of two or more of the foregoing. 2. The method according to claim 1, characterized in that after step c) the following steps are carried out: d) positioning of the probe unit (1) in a calibration environment, preferably a calibration liquid; e) automatic calibration of at least one sensor element (51, 52) of the probe unit (1) by the probe unit (1); f) reproducing a fourth signal (601) by the probe unit when the calibration is successfully completed and reproducing a fifth signal (602) different from the fourth signal (601) by the probe unit (1) if the calibration is not successfully completed. 3. The method according to claim 2, characterized in that after completion of step d), the reproduction of a third signal (401) by the probe unit (1). 4. The method according to claim 2, wherein the fourth signal is identical to the first signal and / or the fifth signal is identical to the second signal. 5. The method according to any one of the preceding claims, characterized in that the signals (301, 302, 399, 401, 601, 602) are at least partially executed as light signals. 6. The method according to any one of the preceding claims, characterized in that the activation of the probe unit (1) takes place in step a) by contacting bring at least one activation region (13) of the probe unit (1) with a magnetic element arranged outside thereof. 7. The method according to any one of the preceding claims, characterized in that prior to step a) a step aO) is performed, in which at least one of the following information in a memory element (7) of the probe unit (1) is loaded: radio frequency, transmission channel, system time. 8. The method according to any one of the preceding claims, characterized in that in at least one of the steps following step a) contacting the probe unit (1) by wireless path with a outside of the probe unit (1) arranged transmitting station, preferably with the Probe unit (1) carried out transmitting and receiving steps, takes place. 9. The method according to any one of the preceding claims, characterized in that in a final step z) the probe unit (1) within a farm animal (2), preferably in the gastrointestinal tract (3), is placed. 10. probe unit (1) for measuring at least one state variable of the organism of a farm animal (2) of a farm animal, wherein the probe unit (1) in the gastrointestinal tract (3) of the farm animal can be arranged and the following, arranged in a housing components comprises - at least a sensor element (51, 52) for measuring at least one state variable of the organism of a farm animal (2), - at least one transmitting device (8), preferably with at least one antenna (9), for wireless transmission of information, and - at least one control unit (6 ) for controlling the probe unit (1), characterized in that the probe unit (1) has at least one signal output unit (12) for reproducing a signal, wherein the signal output unit (12) is arranged to reproduce at least one of the following signals: acoustic signal, optical Signal, haptic signal, motion signal, combinations of two or more of the foregoing. 11. probe unit (1) according to claim 10, characterized in that the signal output unit (12) has at least one light guide element (122), the at least one light source (121) inside the probe unit (1) with a housing (4) of the probe unit ( 1) connects. 12. Probe unit (1) according to claim 11, characterized in that the probe unit (1) is designed with a cylindrical housing (4) and the light guide element (122) with a cover (41) and / or bottom portion (42) of the cylindrical Housing (4) is connected. 13. Probe unit (1) according to any one of claims 10 to 12, characterized in that at least one of the control unit (6) connected to the memory element (7) is provided, on which at least one of the following information can be stored: radio frequency, transmission channel, system time , For this 2 sheets of drawings