DE102016220222A1 - Diagnostic device and method for state detection of an object by means of the diagnostic device - Google Patents

Abstract

The invention relates to a diagnostic device (1). This has a housing (10) in which a plurality of transducers (14, 15, 16), at least one output element (13) and a selection device (111) are arranged. The selection device (111) is set up to select one or more of the transducers (14, 15, 16) for performing a measurement as a function of a predetermined analysis question. A method for detecting the state of an object (3) by means of the diagnostic device (1) comprises presetting an analysis query by a user, selecting at least one transmitter (14, 15, 16) in dependence on the analysis query position, performing a first analysis of the object ( 3) by means of sensors (141, 151, 161) of the selected transducers (14, 15, 16), and performing a first multivariate analysis of data output by the selected transducers (14, 15, 16).

Description

The present invention relates to a diagnostic device. Furthermore, the present invention relates to a method for condition detection of an object by means of the diagnostic device. Moreover, the present invention relates to a computer program which is set up to carry out steps of the method according to the invention, as well as a machine-readable storage medium on which the computer program is stored.

State of the art

Various individual sensors are used to detect the states of an object. Food, such as fruits, can thus be examined for their degree of ripeness. For example, pharmaceuticals can be tested for their authenticity to distinguish them from counterfeit products that are ineffective or even harmful to health. For diagnosis, only a single sensor signal is used in each case. The probability of a correct classification of the condition varies depending on the exact application. In addition, depending on the analytical question, the user may have to select another individual sensor in order to be able to carry out meaningful status recognition.

Disclosure of the invention

The diagnostic device has a housing in which a plurality of transducers, at least one output element and a selection device are arranged. The selection device is set up to select one or more of the transducers for carrying out a measurement, depending on a predetermined analysis question. As a result, a compact system is provided, which can detect and correlate several sensor measurement quantities for the state detection on an object.

At least two transducers are preferably selected from the group consisting of spectrometers, gas sensors, ambient light sensors, cameras, ultrasonic transducers, mass spectrometers, NMR scanners, humidity sensors, Raman spectrometers and fluorescence spectrometers. These transducers allow the diagnostic device to answer a large number of different analysis questions. It is preferred that the transducers comprise at least one spectrometer, since spectrometers can provide particularly meaningful information about an object to be examined.

As a further transmitter, for example, force sensors or distance sensors can be used. These can provide auxiliary measurements for the evaluation of the data of the other transducers.

In order to allow a simultaneous examination of an object with several or all of the transducers, it is preferred that all the sensors of the diagnostic device are located on the same side of their housing. Each transmitter has at least one of the sensors. In principle, each of the sensors can have its own measuring access. The measurement access may be, for example, an optical window, a fluidic opening or a mechanical contact receiver. However, it is particularly preferred that at least two sensors have a common measuring access in order to allow a particularly compact construction of the diagnostic device.

In particular, the selection device can be part of a control device which activates the transducers and is implemented there as a component or as a software function.

In one embodiment of the diagnostic device, the output element is set up to directly display a diagnosis result to a user. For this purpose, it can be designed, in particular, as a screen or as an optical signal generator, for example in the form of a light-emitting diode (LED). In another embodiment of the diagnostic device, the output element is configured to pass the diagnostic result in analog or digital form to another device for further processing. For this purpose, it can be designed in particular as a plug or as an antenna.

The diagnostic device can either be designed as a standalone device or be integrated as a subsystem in another device. This is possible, for example, in an end-user area, in the household sector or in a kitchen environment. If the diagnostic device is a subsystem of another device, then its housing may be part of the housing of the other device or even be identical to its housing.

The method for detecting the state of an object by means of the diagnostic device begins with the specification of an analysis question by a user. Depending on the analysis question, at least one of the transmitters of the diagnostic device is automatically selected. A first analysis of the object is carried out by means of sensors of the selected transducers. The data selected by the Transmitters are subjected to a multivariate analysis. For this purpose, they can be summarized beforehand in a data vector. The multivariate analysis allows a weighting of the individual sensor measured values according to their relevance and thus leads to a more reliable analysis result than several independently performed individual analyzes.

In a simple embodiment of the method, the state detection can be completed already after performing the first multivariate analysis. However, it is preferred that at least one transmitter is selected depending on the result of the first multivariate analysis and then a second analysis of the object is performed by means of sensors of the selected transmitter. Subsequently, a second multivariate analysis of data output by the selected transmitters is performed. This allows for energy savings by first performing only a first analysis with a single transmitter or a small group of transducers and then, based on the analysis result, determining which other transducers still need to be activated to provide sufficiently high reliability of the result of the second multivariate analysis to obtain.

In addition, it is preferred that data from at least one transmitter involved in the first analysis of the object be evaluated to output instructions for positioning the diagnostic device relative to the object to the user prior to performing the second analysis. This can be instructed, for example, to change the distance and / or the angle of the diagnostic device to the object or to direct the diagnostic device to another measurement point. It may also be advantageous, after the repositioning of the diagnostic device, to reuse one or more of the transducers already used in the first analysis of the object in the second analysis in order to obtain a more reliable analysis result.

If a check reveals that a release condition of a transmitter is not met, it is preferred that the transmitter in question is not taken into account in the selection for the first analysis or in the selection for the second analysis. Such a release condition may be, for example, that the diagnostic device must rest on the object in order to use certain transducers, such as a force sensor can.

In one embodiment of the diagnostic device, the first multivariate analysis and / or the second multivariate analysis take place in a computing device within the diagnostic device. In another embodiment of the method, the multivariate analysis is performed outside the diagnostic device, for example in a cloud.

The output element is driven in the last step of the method, in particular depending on the result of the first or the second multivariate analysis. If the first multivariate analysis has already provided a sufficiently reliable result of the condition detection so that no second multivariate analysis is performed, then the result of this multivariate analysis is output. If, on the other hand, a second multivariate analysis is performed, the result of the first multivariate analysis is discarded and only the result of the second multivariate analysis is output.

The computer program is set up to perform steps of the method, in particular if it is executed in a computing device of the diagnostic device or in a cloud. It allows the implementation of different embodiments of the method in a diagnostic device, without having to make any structural changes. For this purpose it is stored on the machine-readable storage medium.

list of figures

• 1 zeigt schematisch eine Diagnosevorrichtung gemäß einem Ausführungsbeispiel der Erfindung.
• 2 zeigt ein Ablaufdiagramm eines Ausführungsbeispiels des Verfahrens zur Zustandserfassung eines Objektes.

Embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description.

• 1 schematically shows a diagnostic device according to an embodiment of the invention.
• 2 shows a flowchart of an embodiment of the method for detecting the state of an object.

Embodiments of the invention

A portable diagnostic device 1 according to an embodiment of the invention is in 1 shown. It has a control unit 11 on, in which a selection device 111 is implemented. Furthermore, it has a data acquisition unit 12 on that via a communication module 121 with a cloud 2 communicates. The data acquisition unit 12 can transfer data to an external interface 13 output. The outside interface 13 is executed in the present embodiment as a screen. In other embodiments of the invention, it may for example also be designed as an LED plug or antenna.

Both the control unit 11 as well as the data acquisition unit 12 each with three transmitters 14 . 15 . 16 in connection. The first transmitter 14 has in the present embodiment as a sensor 141 a gas sensor for the analysis of volatile organic gas components. The second transmitter 15 points as a sensor 151 an ultrasonic transducer for analyzing the ultrasonic attenuation. The third transmitter 16 points as a sensor 161 a microspectrometer for the analysis of backscattered spectrally resolved light. These components of the diagnostic device 1 are in a housing 10 arranged, which on one side 101 a measuring access 102 in which the three sensors 141 . 151 . 161 are arranged. You can simultaneously access an object to be examined 3 be directed. In the present embodiment, the object to be examined is 3 an orange whose degree of ripeness is to be determined. This is done in the diagnostic device 1 and in the cloud 2 a computer program is executed which performs the steps of a method according to an embodiment of the invention.

A flow chart of this method is in 2 shown. A start 40 of the method takes place with the switching on of the diagnostic device 1 , Subsequently, the user makes a predetermination 41 an analysis question. This analysis question, which in this case is the determination of the degree of maturity of an orange, can be selected by the user from various analysis questions. For this purpose is not shown, with the control unit 11 connected, input element provided. After the questionnaire has been answered, a check is first made 421 whether the release conditions of all transducers 14 . 15 . 16 are fulfilled. Transducers whose release conditions are not met will be included in the following selection 431 at least one transmitter 14 . 15 . 16 not considered. For example, the condition detection of the object could 3 selecting the second transmitter 15 and the third transmitter 16 respectively. Then carried out 441 a first analysis of the object by means of the sensors 151 . 161 of the two selected transmitters 15 . 16 , The data of the two transducers 15 . 16 be from the data acquisition unit 12 captured and sent to the cloud 2 passed. There is a performing 451 a first multivariate analysis of the data. If this analysis still does not provide sufficient state detection of the object 3 allows, the procedure is in step 47 continued. Otherwise, the result of the analysis is output by activation 48 of the output element 13 and the process is terminated 49.

In step 47 it is first checked whether, before performing further measurements, a different positioning of the diagnostic device 1 makes sense. If, for example, it has been detected by means of the ultrasonic transducer that the distance or angle of the diagnostic device 1 to the object 3 is not optimal for the measurement, this is done by means of the output element 13 communicated to the user and the process interrupted until the user the diagnostic device 1 has positioned differently and this has been confirmed by a user input. Otherwise, the procedure is skipped by stepping 47 continued immediately. There is another check 422 whether the release conditions of all transducers 14 . 15 . 16 are fulfilled. Depending on the result of the first multivariate analysis, a selection then takes place 432 at least one transmitter for a second analysis of the object. For example, it is possible to select that now also a measurement by means of the first transmitter 14 should be done and that the measurement by means of the third transmitter 16 should be repeated under a new positioning of the diagnostic device. A performing 442 a second analysis of the object then takes place by means of the sensors 141 . 161 , the transmitter selected for this second analysis 14 . 16 , The data acquisition unit 112 in turn, sends the measurement data to the cloud 2 Next, where to perform 452 a second multivariate analysis takes place, in which both the data from the first analysis of the object and the data from the second analysis of the object are taken into account. This is followed by a control 48 of the output element 13 to output the analysis result and exit 49 of the procedure.

Claims (12)

Diagnostic device (1), comprising a housing (10) in which a plurality of transducers (14, 15, 16), at least one output element (13) and a selection device (111) are arranged, wherein the selection device (111) is adapted to Dependent on a predetermined question of analysis, one or more of the transmitter (14, 15, 16) to select a measurement. Diagnostic device (1) after Claim 1 , characterized in that the transducers (14, 15, 16) comprise at least one spectrometer. Diagnostic device (1) after Claim 1 or 2 , characterized in that each transmitter (14, 15, 16) at least one sensor (141, 151, 161), wherein all the sensors (141, 151, 161) on the same side (101) of the housing (10) are arranged. Diagnostic device (1) after Claim 3 , characterized in that at least two Sensors (14, 15, 16) have a common measuring access (102). Method for detecting the state of an object (3) by means of a diagnostic device (1) according to one of the Claims 1 to 4 comprising: - predetermining (41) an analysis query by a user, - selecting (431) at least one transmitter (14, 15, 16) as a function of the analysis question, - performing (441) a first analysis of the object (3 by means of sensors (141, 151, 161) of the selected transducers (14, 15, 16), and - performing (451) a first multivariate analysis of data output by the selected transducers (14, 15, 16). Method according to Claim 5 , further comprising the following steps: - selecting (432) at least one transmitter (14, 15, 16) as a function of the result of the first multivariate analysis, - performing (442) a second analysis of the object (3) by means of sensors (141, 151 , 161) the selected transducers (14, 15, 16), and - performing (452) a second multivariate analysis of data output from the selected transducers (14, 15, 16). Method according to Claim 6 characterized in that data from at least one transmitter (14, 15, 16) is evaluated to output to the user (47) instructions for positioning the diagnostic device relative to the object prior to performing the second analysis. Method according to one of Claims 5 to 7 , characterized in that a transmitter (14, 15, 16) is not taken into account in the selection (431, 432) if a test (421, 422) reveals that a release condition of the transmitter (14, 15, 16) is not met is. Method according to one of Claims 5 to 8th , characterized in that the multivariate analysis takes place in a cloud (2). Method according to one of Claims 5 to 9 , characterized in that the output element (13) is driven (48) in dependence on the result of the first or the second multivariate analysis. Computer program, which is set up, steps of the procedure according to one of Claims 1 to 10 perform. Machine-readable storage medium on which a computer program is based Claim 11 is stored.

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