EP1377813A1

EP1377813A1 - Method and device for controlling the quality and/or optically characterizing milk

Info

Publication number: EP1377813A1
Application number: EP02732607A
Authority: EP
Inventors: Peter Kaever; Marek Krasutzki; Jan-Hermann Reurik
Original assignee: WestfaliaSurge GmbH
Current assignee: GEA Farm Technologies GmbH
Priority date: 2001-04-12
Filing date: 2002-04-12
Publication date: 2004-01-07
Also published as: WO2002084260A1; DE10118329A1

Abstract

The inventive method for optically characterizing milk (5) with the aid of an optical system (1) comprises the following steps: the optical system is initially calibrated; at least one optical spectrum of the milk is then detected at at least one frequency; a first representation is used to image the spectrum thus obtained onto at least one color vector within a color range; and a second representation is used to image the at least one color vector onto at least one feature vector within a feature vector range. The features of consumable milk can thus be formulated in a compact manner and a high degree of selectivity can be provided, requiring little numeric complexity.

Description

METHOD AND DEVICE FOR QUALITY TESTING OR ON THE OPTICAL CHARACTERIZATION OF MILK

The invention relates to a method for quality testing of milk or for the optical characterization of milk and an apparatus for performing these methods.

10

In the product development of automatic milking systems, after a first phase, in which the basic functionality of milking systems was shown, a second phase emerged, in which extended functions, in particular functions to ensure quality standards of milk as well as

15 Move testing for milk that has been changed to the fore. Obviously altered milk means that the milk is contaminated by blood, pus or flakes, i.e. the appearance in terms of color, smell or consistency has been undesirably changed. Various methods are known for determining the relevance. Some methods use conductance or density

20 measurements or sieves to determine the content of flakes in the milk, others detect obvious changes in color changes in the milk. WO 98/30084 discloses a method for determining the presence in the milk of certain substances obtained from individual animals during successive milking processes. With the help of a

The color sensor measuring device determines the intensity of frequencies in a number of specific frequency bands, in particular the intensity of a number of specific colors in the light. The intensity values determined in this way are stored in a file available for a respective animal in a computer. These intensity values are shared with each other

30 also compared with corresponding intensity values that were recorded in the course of one or more existing milking processes. The results of this comparison process are displayed. Analyzers previously used on Ba- sis optical methods have extensive sensors, which are voluminous and expensive, so that such analysis devices usually have to be accommodated in a stationary manner.

The disadvantages of available devices that work by color evaluation of the milk mainly relate to the performance of the evaluation methods, which only capture partial aspects of the color vector based on the absolute values or ratios of the optical spectra and thus do not provide an efficient basis for describing marketable samples in color Provide assessment of meaningfully modified milk. The raw information on the colors that is subjected to simple signal processing in existing devices is not a sufficiently simple and comprehensive quantity with which a decision about the relevance can be derived.

It is an object of the present invention to overcome the disadvantages of the prior art mentioned and to provide a method for the optical characterization of milk on the one hand and a method for quality testing of milk on the other hand, with which decision criteria about the sensibility can be derived with optical means. In addition, devices for performing these methods are to be specified.

This object is achieved by the features of claims 1 and 2 and by the features of claims 29 and 30, respectively. Advantageous further developments are the subject of the respective dependent claims.

The method according to the invention for the optical characterization of milk with an optical system captures the following method steps: First, the optical system is calibrated at at least one frequency. Then at least one optical spectrum of the milk is recorded at at least one frequency, whereupon the spectrum obtained is mapped onto at least one color vector with the aid of a first image in a color space. Finally at least one color vector is mapped onto a feature vector using a second mapping in a feature space. The method according to the invention for quality inspection of milk comprises the same method steps as the method according to the invention for the optical characterization of milk and the further one, that the feature vector is compared with a reference vector.

With the aid of the method according to the invention, the milk is characterized without contact, in real time and in the flow method. The optical transmission function of the optical system is determined by the calibration so that it can later be calculated from the optical spectra recorded with milk. For example, the offset adjustment for the raw values of the sensor and an automatic calibration with reference values take place. In this step, the individual raw values are considered in isolation.

With this step e.g. Color changes in the sensor head compensated. In a special operating mode of the sensor, depending on external system states, calibration algorithms can be initiated, which are required to determine the offset adjustment values.

The transfer function of the optical system is determined by the light spectrum imitated by a light source and by the spectral sensitivity of the detector. Furthermore, additional optical components of the optical system (e.g. windows of a measuring chamber in which the milk is guided, mirrors, etc.) or impurities in the optical beam path have an influence on the optical transmission function.

The spectrum of the light used can be in the infrared spectral range, in the visible and / or in the UV spectral range of the electromagnetic spectrum. A combination of different frequency ranges, as well as the

Combination of narrowband and broadband frequency ranges is partial if the contamination in milk such as blood, pus or flakes can be recognized differently well at different frequencies, ie the contrast between the respective types of contamination compared to marketable milk is different at different frequencies.

With the first mapping of the spectrum obtained into the color space on at least one color vector, a reliable and robust classification of the color of the milk is possible. This illustration enables a closed formulation of the assessment criteria, while at the same time the entire information of the measured spectral ranges is included. The first figure reduces the complexity of an optical spectrum to a comparatively simple color vector, which has a few numbers as entries, but which comprehensively describe the optical properties of milk.

With the help of the second illustration, the color vector is mapped into a feature space on a feature vector. With this mapping, the color vector, which reproduces the color of the milk, is thus mapped to a feature vector with a few, but relevant, entries. For example, the angle with which the color vector has rotated about a specific axis in the color space or the factor by which the color vector is compressed or stretched can be an entry of the feature vector.

The comparison of the feature vector with a reference vector provides a criterion for the quality of milk that has been altered in a meaningful way. The reference vector can be specified externally and could therefore be a specified standard. However, it can also be a previously stored feature vector from previous measurements, so that the milk can be compared between two different times. With the help of the feature vector, the chronological development of the color properties of the milk can be traced, from which information about the state of health of a cow or the herd or the deviation of the physiology of a cow from that of the herd can be drawn. With the help of the As a result of the reference vector, mean values and / or fluctuation ranges are specified by or within which a characteristic vector must lie so that the milk meets a specified quality standard.

In a development of the invention, the reference vector is a previously stored feature vector of an animal or an animal group or herd. By comparing the feature vector with previous feature vectors, a change in the milk of a cow is determined at an early stage.

The feature vector or the result of the comparison of a feature vector with a reference vector can provide an animal with individual or herd-specific information. If necessary, the feature vectors with other recognized variables, such as. B. the electrical conductivity, the viscosity and / or the proportion of the suspended matter in the milk, further information about the quality of the milk and about the animal supplying the milk. These variables can be used to make statements about the state of health, the state of the animal within a lactation period, the nutritional behavior of the animal and, if necessary, other interesting statements about the animal or the herd.

The course of the change in the feature vector of an animal can be predicted from the knowledge of the feature vectors of an animal, which have been obtained from a large number of successive milking processes. If, for example, the course of the change in an animal's characteristic vector is dependent on the lactation level, the amount of milk that will be expected in the future can also be predicted if the relationships between the lactation level and the amount of milk depending on the lactation level are known. A refinement of the statement about the quality of the milk or about a noticeable change in the milk can also be achieved by forming udder-quarter individual characteristic vectors. This can also Statements can be made about, for example, pathological changes in a cow's udder quarter.

In an advantageous embodiment of the invention, a transmission spectrum is recorded. In the case of a transmission spectrum, a particularly good signal-to-noise ratio is achieved by suitable selection of the distance within the milk to be traversed by the light beam. For example, contamination in the optical system (ie not in milk) is less significant if the distance through which light travels in milk is longer, since the influence of the optical properties of the milk on the optical transmission spectrum scales with the distance and the contamination in the optical Systems become proportionately smaller.

In a further embodiment of the invention, a reflection spectrum is recorded. The advantage of the reflection spectrum lies in a simpler optical structure, since the two windows that are usually required for transmission spectra are eliminated. It is also possible for both a transmission spectrum and a reflection spectrum to be recorded. The advantage here is that both the absorptive and the dispersive components of the optical properties of the milk are recorded. While a transmission spectrum primarily captures the absorptive properties, a reflection spectrum primarily captures the dispersive properties, since the reflection coefficient is primarily influenced by the refractive index and thus by the dispersion. This is particularly advantageous if certain changes in the milk are better in the absorption, other changes in the reflection.

In a development of the invention, the optical spectrum is recorded in pulse mode. Pulse mode here means that at predeterminable time intervals the optical spectrum is recorded so that a history of the color changes of the milk is possible even within a milking process.

In a still further embodiment, the optical spectrum is recorded continuously, it being possible at any time to characterize the milk with regard to its optical properties.

In a further preferred embodiment of the invention, the at least one optical spectrum is mapped linearly on color vectors of known color systems. This mapping maps the complexity of the optical spectrum to a set of a few numbers without losing important information (in the case of milk). This means that the optical properties of milk are described with sufficient accuracy using a set of a few numbers. Optical features can thus be numerically recorded and used efficiently. The mapping is carried out in such a way that, with respect to a suitable choice of color base vectors (for example red, green, blue in the RGB system), e.g. Saturation and intensity parameters are quantified. The mapping of the optical spectrum onto a color vector is generated with the help of a computer in an efficient manner by superpositions of the individual colors. Known color systems (e.g. RGB, CMY, ...) are characterized in that the mapping of the optical spectrum to a color vector is unambiguous, i.e. the entries in the color vector are well defined.

In a further preferred embodiment of the invention, the second image is a non-linear image. For example, the amount of the color vector is determined. Depending on the color system, the amount of the color vector provides information about the brightness of the milk. Alternatively, the rotation of the color vector with respect to a predeterminable axis is determined in the color space. The rotation of the color vector indicates a shift in color. For example, if a milk colored with blood is irradiated with white light, the color shifts from white to red. The rotation of the color vector is determined with threshold values and / or tolerance compared areas. In a further embodiment of the invention, the at least one color vector is standardized. The standardization allows conclusions to be drawn about air pockets, foam or deposits in the milk or on the sensor head.

In a further embodiment of the invention, the second image is the intensity image, i.e. the color vector is set equal to the feature vector. The feature vector directly reflects the color of the milk.

According to an advantageous embodiment of the method, it is proposed that at least one feature vector of an overall milk of an animal be formed. Several feature vectors can also be formed, which are determined one after the other in time. The representation of the feature vectors of an overall milk has the advantage that the quality of the entire milk can be checked.

With regard to a more differentiated diagnosis, it is proposed according to yet another advantageous embodiment of the method that at least one feature vector of a teat-specific milking is formed. This makes it possible, for example, to form exactly one feature vector in quarter-milking cows. Pathological changes of individual teats and the associated areas can be inferred from different feature vectors of the teat-specific milking.

In view of the fact that the composition of a foremilk, the milking and the post-milking can be of different consistency and composition, it is proposed that at least one feature vector describes the foremilking and / or the milking.

In a special embodiment of the invention, the feature vector is stored. Through animal-specific storage and comparison with past Values can be used to draw conclusions about the health of the cow. By storing the feature vector, a temporal course of the optical properties of the milk is recorded.

According to yet another advantageous embodiment of the method, it is proposed that the current feature vector be compared with a milking corn vector from an earlier milking process. This has the advantage that this direct comparison allows conclusions to be drawn about the composition and consistency of the

Milk can be closed.

According to yet another advantageous embodiment of the method, it is proposed that a signal be triggered when a result of the comparison between the feature vector and the reference vector lies outside a predetermined tolerance range. In particular, a meaningful change in the milk should be taken into account by the tolerance range. According to a preferred method, it is proposed that the content of blood in the milk be taken into account by checking the feature vector with the reference vector in the tolerance range. In addition, aqueous components, suspended matter, in particular flakes and / or pus, can also be taken into account to determine the quality of the milk.

According to yet another advantageous embodiment of the invention, the calibration of the optical system is carried out using reference variables. Since the color of the light source, the detector and any additional optical components such as windows change transmitted or reflected light rays, this influence must be corrected for a precise characterization of the milk. This is done, for example, by measuring a reference quantity with known optical properties instead of milk. Another liquid can be used instead of milk or water as a reference quantity. Alternatively, the optical system can also be characterized by removing the milk from the optical beam path is removed. A calibration liquid is preferably used as the reference quantity instead of the milk.

Instead of the calibration liquid described above, a general calibration medium can also be used. The calibration medium can also be, for example, a gas, preferably air.

The optical system is preferably calibrated in a milking-free time. The time of the calibration can also be adapted to the processes in the milking parlor. For this purpose, it is proposed that the calibration take place during or outside a cleaning phase of the milking device. During the cleaning phase of the milking device, for example, water is flushed through the lines and hoses of the milking device, so that a relatively defined calibration medium is available.

A suitable value is suggested for the purpose of calibration. This can be used from at least two values that were determined during different milking phases.

According to a still further advantageous embodiment of the method, it is proposed that the calibration be carried out with a special control of the transmitting elements of the transmitter, in particular with a lower or higher transmission power, which can also be controlled in a spectrally different manner. To ensure that fluctuating ambient conditions within the detector, it is proposed that these be compensated for or taken into account in the calibration. This can be, for example, the temperature measurement or the recording of the relevant environmental influences, which could have a relative influence on the result of the measurement.

The device according to the invention for the optical characterization of milk for carrying out the method according to the invention comprises a control unit and an optical system with a light source, a detector and a measuring chamber which can be filled with milk, the light source, ^" the measuring chamber, and the detector being arranged in an optical path and the data of the detector being fed to the control unit.

The device according to the invention for checking the quality of milk, in particular of obvious milk for carrying out the method according to the invention, comprises a control unit which has a comparator and an optical system with a light source, a detector and a measuring chamber which can be filled with the milk the light source, the measuring chamber and the detector are arranged in a beam path and the data of the detector are added to the control unit, the comparator of which compares the data with predefinable and / or stored data.

In a transmission setup, the measuring chamber is located between the light source and the detector, the light beam radiating through the milk to be examined. In a reflection setup, the light beam scans the surface of the milk to be examined, starting from the light source, and is reflected to the detector. The comparator compares the data determined by the control unit with predetermined and / or previously stored data, with which changes in animal physiology can be recognized. By simply comparing the data with the threshold values and tolerance ranges specified for marketable milk, a test is carried out to determine whether the milk is sensible. This check, which takes place in the feature space, allows a comparison based on fewer scalar parameters. More complex features such as The color change of the milk can thus be compared by scalar measures with the values determined in trafficable milk, with tolerance ranges in particular being easy to specify.

In a further embodiment of the invention, a calibration liquid can be introduced into the measuring chamber. With this calibration fluid the optical system calibrated as such without the milk to be examined, in particular the functionality of the device can be monitored hereby. ^" It is advisable to store the optical transfer function of the optical system, in particular to store the resulting offset compensation or the calibration values, in a database in order to monitor the functionality of the device.

The method proposed here allows a compact formulation of the characteristics of trafficable milk. The two-stage mapping of raw values into the color space with a subsequent mapping into the feature space brings a high degree of grip in the development of the methods and allows the efficient implementation of methods with a high degree of selectivity and low numerical effort. The method can be designed in such a way that the vacuum drop is extremely low and there is excellent cleanability, especially since the method works without contact.

According to a further advantageous embodiment of the device, it is proposed that the light source and / or an element of the calibration unit can be controlled by the calibration unit for calibration with different transmission power and / or spectrally different. The milk can be examined, for example, using a high-performance spectrometer.

Further advantages and preferred configurations are explained with the aid of the following drawing. This is to be understood schematically as an explanation of the invention and not as restricting the spirit of the invention, but is only intended to illustrate some components of the invention by way of example. They show schematically:

1 shows a device for quality inspection according to the invention; and

Fig. 2 shows a known color system. 1 schematically shows a device according to the invention for the quality inspection of milk, in particular of milk which has been changed in a sensible manner, with an optical system 1, a light source 2 and a detector 3, the light beam 10 emanating from the light source 2 passing through the windows 7 of a measuring chamber 4 occurs. The measuring chamber 4 can be filled with milk 5 via a milk inlet 8. The color of the milk 5 is advantageously measured in the flow, which is made possible by the milk inlet 8 and a milk outlet 9. The data from the detector 3 are fed to a control unit 6, which evaluates the data, preferably using the method according to the invention, and forwards them to a comparator 11, which compares them with data of marketable milk or stored data, whereupon the comparison results via a display 12 be issued.

2 shows the known RGB color system. Each color to be displayed is represented by a point in the cylinder, the angle describing the color or the mixture of colors from point R (red) to point G (yellow) to point B (blue) and back to point R (red) , the amount r of the vector projected onto the base of the cylinder indicates the saturation of the color tones and the height h indicates the intensity of the color. In this system, all pure shades of gray are on the central axis of the cylinder, the uppermost point O on the central axis of the cylinder representing pure white and the lowest point U representing pure black. A rotation of the color vector around the central axis of the cylinder describes a shift in the color tone, an extension or compression of the color vector generally means a change in intensity and a change in saturation. In this way, the color of the milk is clearly determined by giving 3 numbers.

The method according to the invention for the optical characterization of milk 5 with an optical system 1 comprises the following method steps: First the optical system is calibrated, then at least one optical spectrum of the milk at at least one frequency, then the spectrum obtained is mapped to at least one color vector with the aid of a first mapping in a color space, and finally the at least one color vector is mapped to a feature vector with the aid of a second mapping in a feature space. The method allows a compact formulation of the characteristics of trafficable milk and offers a high degree of selectivity with little numerical effort.

Bezuagszeϊclieiiliste

optical system

light source

detector

measuring chamber

milk

control unit

window

milk inlet

milk outlet

beam of light

comparator

display

Claims

claims

1. A method for the optical characterization of milk (5) with an optical system (1), which comprises the following method steps: a. the optical system (1) is calibrated at at least one frequency; b. at least one optical spectrum of the milk (5) is recorded at at least one frequency; c. the spectrum obtained is mapped with the aid of a first mapping into a color space on at least one color vector; and d. the at least one color vector is mapped to a feature vector using a second mapping in a feature space.

2. Procedure for quality inspection of milk (5), in particular more obvious

Milk (5), with an optical system (1), which comprises the following process steps: a. the optical system (1) is calibrated at at least one frequency; b. an optical spectrum of the milk (5) is at least one

Frequency added; c. the spectrum obtained is mapped with the aid of a first mapping into a color space on at least one color vector; d. the at least one color vector is mapped onto a feature vector with the aid of a second mapping in a feature space; and e. the feature vector is compared with a reference vector.

3. The method according to claim 2, characterized in that the reference vector is a previously stored feature vector.

4. The method according to any one of the preceding claims, characterized in that a transmission spectrum is recorded.

5. The method according to any one of the preceding claims, characterized in that a reflection spectrum is recorded.

6. The method according to any one of the preceding claims, characterized in that the optical spectrum is recorded in pulse mode.

7. The method according to any one of the preceding claims 1 to 5, characterized in that the optical spectrum is recorded continuously.

8. The method according to any one of the preceding claims, characterized in that the at least one optical spectrum are mapped linearly on color vectors of known color systems.

9. The method according to any one of the preceding claims, characterized in that the second mapping is a non-linear mapping.

10. The method according to claim 10, characterized in that the amount of

Color vector is determined.

11. The method according to claim 9 or 11, characterized in that the rotation of the color vector is determined with respect to a predetermined axis in the color space.

12. The method according to any one of claims 9 to 11, characterized in that the at least one color vector is normalized.

13. The method according to any one of the preceding claims 1 to 8, characterized in that the second image is the identity image.

14. The method according to any one of claims 1 to 13, characterized in that at least one feature vector of a whole milking of an animal is formed.

15. The method according to any one of claims 1 to 14, characterized in that at least one feature vector of a teat-specific milking is formed.

16. The method according to any one of claims 1 to 15, characterized in that at least one feature vector of a foremilk and / or milking is formed.

17. The method according to any one of the preceding claims, characterized in that the at least one feature vector is stored.

18. The method according to claim 17, characterized in that the current feature vector is compared with a feature vector of at least one previous milking process.

19. The method according to any one of claims 1 to 18, characterized in that a signal is triggered when a result of the comparison between the feature vector and the reference vector lies outside a predetermined tolerance range.

20. The method according to claim 19, characterized in that a change in the milk is taken into account by the tolerance range.

21. The method according to claim 19 or 20, characterized in that the tolerance of the content of blood in the milk is taken into account.

22. The method according to claim 19, 20 or 21, characterized in that the aqueous portion in the milk is taken into account by the tolerance range.

23. The method according to any one of claims 19 to 22, characterized in that suspended matter, in particular flakes and / or pus, are taken into account in the milk due to the tolerance range.

24. The method according to any one of the preceding claims, characterized in that the calibration of the optical system (1) is carried out using at least one reference variable.

25. The method according to claim 24, characterized in that a calibration medium, in particular a calibration liquid in place of the milk (5), is used as the reference quantity.

26. The method according to claim 24 or 25, characterized in that the calibration takes place in a milking-free time.

27. The method according to claim 26, characterized in that the calibration takes place during or outside a cleaning phase of the milking device.

28. The method according to any one of claims 24 to 27, characterized in that the at least one reference variable is determined from at least two values which were determined during different phases of milking

29. Device for the optical characterization of milk (5), in particular for carrying out the method according to the invention according to claim 1 with a control unit (6) and an optical system (1) comprising a ne light source (2), a detector (3) and a measuring chamber (4) which can be filled with milk (5), the light source (2), the measuring chamber (4) and the detector (3) being arranged in a beam path and the Data from the detector (3) are fed to the control unit (6).

30. Device for quality control of milk (5), in particular for performing the method according to the invention according to claim 2, preferably of obvious milk, with a control unit (6) having a comparator (7) and an optical system (1) comprising one Light source (2), a detector (3) and one that can be filled with milk (5)

Measuring chamber (4), the light source (2), the measuring chamber (4) and the detector (3) being arranged in a beam path and the data from the detector (3) being fed to the control unit (6), the comparator (11) of which Compares data with specifiable and / or stored data. ,

31. Device according to claim 29 or 30, characterized in that a calibration fluid, in particular a calibration liquid, can be introduced into the measuring chamber (4).

32. Apparatus according to claim 29 or 30, characterized in that a

Calibration unit is provided, which enables calibration.

33. Device according to claim 32, characterized in that the light source (2) and / or an element of the calibration unit can be controlled by the calibration unit for calibration with different transmission power and / or spectrally different.