ES2486891B1 - Method of analysis of a gas and artificial nose - Google Patents

Abstract

Method of analysis of a gas and artificial nose. # The method of analysis is performed using an artificial nose that comprises at least one sensor, and comprises detecting a sample of the gas to be analyzed and adaptively modulating at least one parameter that affects the operating regime of the sensor based on a signal obtained from the detection of the sensor and a measure of efficiency. The artificial nose comprises at least one odor sensor and processing means adapted to adaptively modulate at least one parameter that affects the operating regime of the sensor as a function of a signal obtained from the detection of the sensor and a measure of efficiency. The incorporation of adaptive modulation strategies gives the artificial nose of the invention reduced dimensions, therefore, high portability, a wide range of applicability and a reduced production cost.

Description

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DESCRIPTION

METHOD OF ANALYSIS OF A GAS AND ARTIFICIAL NOSE

5 OBJECT OF THE INVENTION

The present invention relates to a method of analyzing a gas by means of an artificial nose and a bio-inspired artificial nose of general application, which uses adaptive modulation strategies of the sensor parameters directed by the objective given to the nose.

The incorporation of said strategies gives the artificial nose of the invention reduced dimensions, therefore, high portability, a wide range of applicability and a reduced production cost.

BACKGROUND OF THE INVENTION

15 Electronic noses are machines designed to accurately detect and discriminate odors. A generally accepted definition of an artificial olfactory system was given by Gardner and Bartlett in 1994 (Oxford Press): “instrument comprising a cluster of chemical sensors with partially overlapping sensitivities next to a

20 pattern recognition system, capable of analyzing and recognizing simple or complex aromas ”.

The origins of the electronic nose date back to the 1960s, when the Bacharac Inc. company built a first device. In the 80s, two groups of

25 researchers, at the University of Warwick in Great Britain and at the Argonne National Laboratory (ANL) in the United States, the first publications owing to Krishna Persaud and George Dodd (1982).

Since then there have been advances that have led to the commercial manufacture of electronic noses for use in different fields: agribusiness, environmental pollution, safety, medicine, etc.

In electronic noses, three modules are generally distinguished: detection, electronic and processing. Sensors responsible for translating directly or indirectly the presence of a smell into electrical signals are included in the detection module. When they come into contact with volatile components present in the gas, the sensors react,

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experiencing a physical change in their properties. The sensor response is received in the electronic module, which transforms the signal into a digital value. The values are analyzed below in the processing module, which is responsible for recognizing and / or classifying the recorded signals.

5 The method of operation of an artificial nose comprises a learning or training stage, in which the artificial nose is subjected to the analysis of a series of recognized samples to construct reference models. At a later stage of odor acquisition, the artificial nose is able to recognize new samples from the models of

10 reference

There are many types of olfactory sensors based on different physical principles: chemoresistive, chemocapacitive, potentiometric, gravimetric, optical, acoustic, thermal, polymeric, ammeter, chromatographic, spectrometric, effect of

15 field, etc.

Chemosensitive sensors are the most widespread due to their small size and easy integration into an electrical circuit. In the state of the art matrices are used that combine sensors of this type, which offer certain advantageous characteristics when based on them.

20 the design of a commercial electronic nose. However, sensor arrays or multisensor components also have clear economic disadvantages, reliability, stability over time and miniaturization.

DESCRIPTION OF THE INVENTION

The disadvantages present in the prior art mentioned above are overcome by a method of analyzing a gas according to claim 1 and an artificial nose according to claim 13. Preferred embodiments of the present invention are defined in the dependent claims.

In a first inventive aspect a method of analysis of a gas by an artificial nose comprising at least one sensor is presented, the method comprising:

(to)

detect at least one sensor a sample of the gas to be analyzed, and

(b)

 adaptively modulate at least one parameter that affects the rate of

35 sensor operation based on a signal obtained from sensor detection and an efficiency measure.

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In a preferred embodiment, the adaptive modulation of at least one parameter is performed by a feedback function that modifies at least one parameter that affects the operating mode of the sensor.

5 In a preferred embodiment, the efficiency measurement is determined from the comparison of the signal obtained from the detection with at least a second signal. The second signal may be a theoretical or reference signal, or it may be a second signal obtained by detection.

In a preferred embodiment, the efficiency measure is determined from the comparison of the signal obtained from the detection with at least one threshold value.

The modulation of at least one parameter can be carried out based on measures of efficiency of recognition of odors and / or discrimination of odors and / or classification of odors and / or in a learning stage.

The adaptive modulation of the parameters can be discrete (responding to specific events detected in the acquisition of the signal), or continuous (throughout the entire acquisition process). The activation of the modulation starts depending on the task assigned to the nose. For the problem of smell recognition, the modulation of the parameters is preferably activated when it is determined that a smell is not identified with the current sensor parameters. For the problem of discrimination between similar speakers, modulation of the parameters is preferably activated when it is determined that the signal of an odorant does not

25 provides sufficient discriminant characteristics with the current sensor parameters. Typical events that define the need to start a new modulation are the saturation of the signal or the arrival at a steady state of the same when the objective of the task assigned to the nose has not yet been achieved.

30 Adaptive modulation of at least one parameter can be performed during an artificial nose training stage or during the odor acquisition stage by the artificial nose.

In a preferred embodiment, the parameter to be modulated is the gas flow rate that affects the sensor and / or the heating temperature.

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The parameters to be modulated are selected according to the type of sensor, which can be any olfactory sensor. In the case of using a chemoresistant sensor, two parameters that can be adaptively modulated are the heating temperature of the sensor and the gas flow that affects the sensor (sniffing). For an optical sensor, for example, the flow rate, the incident wavelength on the sensitive surface and the optical path length can be modulated. In chemocapacitive sensors, the flow rate and amplitude (in voltage and intensity) of the frequency signal used are likely to be modulated to determine the electrical capacity of the sensor. In QCM gravimetric sensors (quartz crystal micro balance) the flow rate and the base resonant frequency of the set can be varied

10 modulating Young's module with a piezoelectric prestress. In SAW gravimetric sensors (Surface acoustic wave) you can modulate the flow rate and the type of pulse that is propagated (square wave, sine wave, ramp ...). In potentiometric sensors the flow and the working pressure can be modulated in order to vary in a controlled way the partial pressure of the gas in the solution.

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In a second inventive aspect an artificial nose is presented comprising: -one or several olfactory sensors, and -processing means adapted to adaptively modulate at least one

parameter that affects the operating mode of the sensor as a function of a signal 20 obtained from the detection of the sensor and a measure of efficiency.

The artificial nose according to the second inventive aspect is adapted to perform the method according to the first inventive aspect and its different embodiments.

Advantageously, the artificial nose of the invention can be based on a single sensor, adapted to work in different regimes obtained from the application of strategies consisting of the adaptive modulation of at least one parameter that affects the operation and, consequently, to the sensitivity of the sensor. Thus, the artificial nose of the invention has dimensions and weight much lower than the olfactory devices considered

30 as portable in the market, so it can be considered ultraportable.

In a preferred embodiment, the sensor consists of a single sensitive surface.

In a preferred embodiment, the processing means comprise a microcontroller, a PC or a PLC (programmable logic controller).

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The introduction of adaptive modulation strategies in the learning or training stage and / or during the acquisition of the smell, results in a more versatile artificial nose than the state of the art, by expanding the range of sensitivities with respect to artificial noses based on non-matrix sensors. In this way your

5 use in electronic noses of general application obtaining detection and separation capabilities of analogous and even higher aromas than those obtained in systems based on a matrix of sensors of greater cost and size.

The artificial nose and the method of the invention have clear competitive advantages,

10 related to both its low production cost and its robustness, in addition to a substantial simplification of the electronics responsible for amplifying, filtering and conditioning the measured signal, which substantially reduces the size and weight of the nose artificial and its portability is increased.

In a preferred embodiment of the artificial nose, the sensor is of the chemoresistant type and adaptive modulation is carried out on the incoming air flow and / or on the heating temperature, which is the temperature at which the sensor works.

With adaptive modulation of the flow or air flow (sniffing), analogously to how

20 occurs in nature, the information from the odorous particles found in the gas under analysis is enriched by introducing into it fluid dynamic complexity that affects pressure, temperature, the mean free path of the particles, diffusivity, etc. Adaptive air flow modulation can be performed both during the learning stage and during the acquisition of the smell.

25 With the adaptive modulation of the heating temperature, in a controlled manner and dependent on the situation in which the analysis is found, the range of temperature values to which the sensor's sensitive surface is subjected is regulated. The variation of the heating temperature affects the concentration of odorants on the surface

30 sensitive, in its diffusivity, etc. Adaptive modulation of the heating temperature of the sensor can be performed both during the learning stage and during the acquisition of the smell.

Although the present method of analysis is intended to be preferably performed in

35 an artificial nose with a single sensor is also applicable in artificial noses with more than one sensor.

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The invention allows the theoretical and operational establishment of the best adaptive modulation functions based on the objective, which can be for example the detection of a smell, the discrimination between two or more odors, the classification of one or more odors in a series of

5 categories, the identification of an odorant in a mixture, the maintenance of the effective stability of the sensor, etc.

All features and / or the method steps described herein (including the claims, description and drawings) may be combined in any combination, except for combinations of such mutually exclusive features.

The present invention is applicable in a number of areas, including:  Industry: Product quality control, production management aid, expiration detection, originality, etc.

15  Citizen security, crime and counterterrorism control: detection of drugs, explosives, prohibited products and harmful substances, olfactory security booths or arches at airports and stations, anti-copy systems of perfumes, colognes and consumables in general, search for survivors in disasters etc.

 Environment: Control of landfills, wastewater, environmental quality, etc. 20  Health of inhabited environments: Atmospheric quality in offices, classrooms, public centers, etc.

 Health field: infection detection, study of anosmias and early prediction of associated neurodegenerative pathologies, detection of oncological conditions, blood or biogenic fluid analysis, pathologies of the endocrine system, characterization

25 clinical olfactory tests, etc.  Leisure industry: science museums, technological devices, gaming industry, recreational facilities.  Robotics (mobile and industrial).

30 DESCRIPTION OF THE DRAWINGS

To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, according to a preferred example of practical realization thereof, an integral part of said description is accompanied by an

35 set of figures where, for illustrative and non-limiting purposes, the following has been represented:

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Figure 1.- Shows a schematic elevation representation of an artificial nose according to the invention.

5 Figure 2.- Shows a schematic representation in perspective of the path made by a gas under analysis in an artificial nose according to the invention.

Figure 3.- Shows a schematic representation of the signals and control elements of an artificial nose according to the invention.

10 Figure 4.- It shows a representation of (A) an array of six standard chemoresistant sensors and (B) a virtual array of sensors obtained thanks to the variation of different heating and flow temperature values.

Figure 5.-Sample (A) a schematic representation of the flow of information between the sensory, electronic and processing modules of an artificial nose according to the state of the art and (B) according to the present invention.

Figure 6.- Shows two sets of signals of two different odors made by a matrix of four sensitive surfaces.

Figure 7.-Sample (A) two readings obtained from two different odors made in different instants by the same surface without modulation and (B) the reading of these two same odors subjected to different modulation regimes at moments t2, t3 and t4 .

Figure 8.- Shows an example of adaptive modulation according to the invention for the task of discriminating two very similar concentrations of ethanol.

PREFERRED EMBODIMENT OF THE INVENTION

In view of the figures, a preferred embodiment of the artificial nose object of this invention is described below.

An ultraportable artificial nose according to an embodiment of the invention is schematically shown in Figures 1 and 2. The artificial nose comprises a sensor (10), an electronic board

(3) and a microcontroller (12) housed inside an envelope (2). The envelope has a series of accesses through which the entry and / or exit of the gas to be analyzed in the artificial nose is allowed.

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During operation of the artificial nose, the gas is penetrated (7) into the artificial nose at

5 through a first access (4). In this case, the gas inlet is forced through a fan (9), so that the gas directly affects the sensor (10). The sensor (10) selected to illustrate the invention is of the chemoresistant type and has four pins, two for the supply of the heating temperature and another two for its signal output.

10 In this exemplary embodiment, the fan responsible for pumping gas is a small axial fan capable of generating a flow of up to 2.7m3 / h. Preferably, the fan (9) is fixed to an inner wall of the enclosure (2), so that it forces the gas inlet directly on the sensor.

The artificial nose of the example has a second access (5), made as a set of holes (5), for the exit (8) of the gas to the outside of the nose. Additional accesses can be provided, for example a third access (6) for the output of a multi-wire cable (11) responsible for carrying the communications and electrically feeding the artificial nose.

20 The electronics have been placed inside a 50 x 35 x 17 mm commercial ABS envelope (2) on whose side the passage of the power and communications cable has been facilitated with a hole. In the cover (1) of the envelope (2) two sets of holes have been machined for the access and exit of the gas to be analyzed. The size of the gas inlet holes

(4) is preferably about 0.4 mm. The size of the exit holes of

Gas (5) is preferably about 1 mm. The size of the hole for the communication cable (6) is preferably about 5 mm in diameter.

For the implementation of the artificial nose according to this preferred embodiment, there is a microcontrolled electronic device capable of regulating both the heating temperature

30 as the gas flow. The adaptive modulation of the heating temperature and the flow rate is carried out in this embodiment by means of two PWM type FET gate power control systems with low pass filter.

To facilitate its eventual connection with external processing means (17), such

35 As a computer or a PLC (Programmable logic controller), the device has two communication modes: a USB protocol communication module and an RS-485 module for long distance multipoint systems. The processing means must be adapted for the acquisition of the signal readings and their analysis. Thus, the adaptive modulation of the gas flow and the heating temperature of the sensor can be controlled by the microcontroller embedded in the artificial nose or by an external PC or PLC. The possibility of

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5 Modulate both the gas flow rate and the temperature is integrated as an additional functionality in the learning and / or classification algorithm, increasing the discrimination capacity of the equipment. During the analysis process both parameters can be adjusted dynamically and in real time based on the state of acquisition in which the artificial nose is located.

10 In the embodiment exemplified in FIG. 3, the microcontroller (12) housed in the electronic board (3) modulates the respective activity of the heating temperature power control systems (13) of the chemoresistant sensor (10) and of the fan flow (14)

(9) by means of two signals (18) regulated by pulse width (classical method of regulation

15 and energy management typically known as PWM). It also has two communication modules (15, 16) dedicated to the transfer of information to external processing means (17).

A matrix of six sensors (a-f) is shown by comparison in Figure 4

20 real chemoresistant of an artificial nose of the state of the art (A) and the matrix of virtual sensors (represented in lighter color) with different sensitivities of an artificial nose according to the invention (B), obtained from a single sensor ( parameter sensor T1, F1 represented darker), subject to different heating temperatures Tx over time and different gas flow or flow values with Fy odorant that is made

25 go through its surface.

Thanks to the adaptive modulation of parameters, the artificial nose of the invention is able to obtain different and partially overlapped effective sensitivities from a single sensitive surface, equivalent to the sensitivities that would be obtained using a

30 high number of virtual sensors running consecutively. By modulating its operating regime with different flow rates and heating temperatures, similar and even higher results are obtained with a single sensor than those obtained by using one at a time the different sensitive surfaces of a matrix of multiple sensors, due to the increase in the specificity of the registered signal.

In a preferred embodiment, adaptive modulation is performed by a function of

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feedback m (t) that modifies the parameters of acquisition (and / or learning and / or recognition) based on a function of efficiency of the objective given to the nose (for example a function that measures the distance between signals). For example, adaptive temperature modulation to discriminate between two Sa1 and Sa2 signals with a single sensor at 5 can be expressed as mT (t) = f [d (Sa1 (t, T (t)), Sa2 (t, T (t ))], where d is the distance function that compares signals S1 and S2 at a time t and T is the value of the temperature of the sensor at that time. Similarly, adaptive flow modulation can be expressed as: mF (t) = f [d (Sa1 (t, F (t)), Sa2 (t, F (t))], where F is the air flow of the sensor at time t.A adaptive modulation by flow and temperature can be expressed as

10 mTF (t) = f [d (Sa1 (t, T (t), F (t)), Sa2 (t, T (t), F (t))]. In general, an adaptive modulation of p parameters represented by the vector α to discriminate n signals can be expressed as: mα (t) = f [d (Sa1 (t, α (t)), Sa2 (t, α (t)), ..., San (t, α ( t))].

The module responsible for managing the adaptive modulation of the parameter (s) is the

15 processing module, which is able to vary these parameters in real time in an adaptive way to optimize the detection and discrimination of the smell.

This practice discretizes over time the possibility of reading each virtual sensor and is equivalent to multiplying in the analogical field the number of possible sensors. That is, in a classic sensor array such as that shown in Figure 4A, the signals from each and every one of the actual sensors that compose it are accessible at the same time. With the artificial nose and the method according to the invention, only one single sensor can be read at any time. However, the size of the virtual sensor array accessible over a period of time is increased by several orders of

25 magnitude and shape can be adapted to the dynamics of each reading.

The sensory (21), electronic (22) and processing modules are shown in Figure 5A

(23) together with the flow of information that occurs between them in a traditional artificial nose. Similarly, in Figure 5B the modules are represented respectively

30 sensory (24), electronic (25) and processing (26) together with the flow of information and the modulation that occurs between them in the artificial nose according to the present invention.

Figure 6 is an example of the classic method for odor discrimination. It shows, as a function of time (t), two sets of signals (Sa1, Sb1, Sc1, Sd1; Sa2, Sb2, Sc2, 35 Sd2) for two different odors (1 and 2) made by a matrix of four sensitive surfaces (a, b, c, d). The figure shows that although the signals (Sc1, Sc2) obtained by

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the same surface are hardly distinguishable for the two odors, the other signals (Sa1, Sb1, Sd1; Sa2, Sb2, Sd2) are clearly different for the two odors, that is, three of the four sensitive surfaces provide additional information on the smell with which is possible to discriminate.

5 Figure 7A shows a graph representing two signal readings (Sa1; Sa2) obtained for two different odors as a function of time, made at different times by the same sensitive surface to keep the modulation parameters constant. As noted, it may be the case that both odors produce

10 signals that are difficult to distinguish in a given sensor operating regime. Figure 7B shows the effect produced in the reading of signals for these two same odors, which at first (t1) are indistinguishable but subject to different regimes at instants (t2, t3, t4) in which has adaptively modified a modulation parameter, they are easily distinguishable. In the case of sensors

Chemistors 15 These parameters can be the heating temperature and / or the flow rate.

An example of gas flow modulation to discriminate two very similar concentrations of ethanol is shown in Figure 8. Without modulation the nose is not able to discriminate these two concentrations. In this example Sa1 corresponds to the signal 20 recorded by the artificial nose of the invention for 0.5% ethanol and Sa2 corresponds to the signal recorded for 0.45% ethanol. Modulation mF (in this example, gas flow F) is performed until the distance d between the two signals reaches an appropriate threshold. The moments in which a flow modulation is performed are indicated by arrows. The panel on the left shows the signals obtained as a function of time and the panel on the right 25 shows the instantaneous distance (d) between the signals, together with the threshold considered suitable for discrimination (0.04 V in this example). That is, in this example the measure of process efficiency would be the distance between the two recorded signals, made as the difference between one and the other. In other embodiments the distance between signals can be calculated in another way, so that it is not necessarily the difference

30 between one and the other.

While the distance is less than the established threshold value, adaptive modulation of the incident gas flow over the sensor is performed.

35 The lower panel shows the modulation function (mF) used in this example, which corresponds to a step function that changes in gas flow at 6-second intervals if the discrimination threshold has not been reached in this period. Once the distance between the two signals has reached the established threshold, the discrimination between the two signals is considered satisfactory and the process ends. In this case the modulation function is a step function that increases the gas flow in a constant increase,

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5 independent of the distance between the signals, but in other cases more complicated functions can be used, for example a feedback function in which the modification of the parameter to be modulated is dependent on the distance between signals, in this case, or the measurement of efficiency employed, in a more general case.

10 In the example illustrated by Figure 8 the adaptive modulation of the parameters is discrete, but in other cases it could be continuous.

Although in several examples the gas flow rate and the heating temperature have been mentioned as modulable parameters in relation to a chemoresistant sensor,

15 will understand that the above explanations are equally applicable to other modulable parameters in relation to other types of olfactory sensors.

Claims (15)

image 1 image2 1. Method of analysis of a gas characterized in that it is carried out by means of an artificial nose comprising at least one sensor, and because it comprises the following steps: 5 detecting by means of at least one sensor a sample of the gas to be analyzed, and adaptively modulate at least one parameter that affects the operating mode of the sensor based on a signal obtained from the detection of the sensor and a measure of efficiency. A method of analyzing a gas according to claim 1, characterized in that the modulation of the at least one parameter is carried out by means of a feedback function that modifies the at least one parameter as a function of the efficiency measurement. 3. Method of analysis of a gas according to claim 1 or 2, characterized in that the The efficiency measure is determined from the comparison of the signal obtained from the detection with at least a second signal. 4. Method of analysis of a gas according to claim 3, characterized in that the second signal is a reference signal. twenty

5.

 Method of analysis of a gas according to claim 3, characterized in that the second signal is a second signal obtained from a detection.

6.

Method of analysis of a gas according to claim 1 or 2, characterized in that the

The efficiency measure is determined from the comparison of the signal obtained from the detection with at least one threshold value. 7. Method of analysis of a gas according to any one of the preceding claims, characterized in that the modulation of at least one parameter is performed according to 30 measures of efficiency of recognition and / or discrimination and / or classification and / or learning of the signal obtained from the detection. 8. Method of analysis of a gas according to any one of the preceding claims, characterized in that the adaptive modulation of at least one parameter is discrete. 35 9. Method of analysis of a gas according to any one of claims 1-7, 14 image3 image4 characterized in that the adaptive modulation of at least one parameter is continuous. 10. Method of analysis of a gas according to any one of the preceding claims, characterized in that the modulation of at least one parameter is performed during a stage 5 of training the artificial nose. 11. Method of analyzing a gas according to any one of the preceding claims, characterized in that the modulation of at least one parameter is carried out during an acquisition stage of the artificial nose. 10 12. Method of analyzing a gas according to any one of the preceding claims, characterized in that the parameter to be modulated is the flow of air that affects the sensor and / or the heating temperature. 15 13. Artificial nose characterized in that it comprises: -at least one odor sensor (10) and -processing means (12) adapted to adaptively modulate at least a parameter that affects the operating regime of the sensor (10) as a function of a signal obtained from the detection of the sensor and a measure of efficiency. twenty 14. Artificial nose according to claim 13 characterized in that the sensor (10) is a sensor with a single sensitive surface. 15. Artificial nose according to claim 13 or 14, characterized in that the sensor (10) is a chemoresistant sensor. 16. Artificial nose according to one of claims 13-15, characterized in that the processing means (12) are adapted to modulate the air flow that affects the sensor and / or the heating temperature. 30 17. Artificial nose according to one of claims 13-16, characterized in that the processing means comprise a microcontroller, a PC or a PLC. fifteen