WO2004010676A2 - System of measuring the quality of an environment and a local beacon therefor - Google Patents

Abstract

The invention relates to an environment quality-measuring system. The inventive system comprises devices (BRC) for measuring the quantity of a reference component and of another component which is different from said reference component, at least one local beacon (DEPi) which is used to obtain a local measurement of the reference component and a centre (C) which comprises: means of establishing an estimated cartography of the measured quantities of components; means of calculating a dilution factor using the local measurement and the reference component-related cartography data; means of calculating the estimated local measurement of the other component using the dilution factor and the data from the cartography related to the other component; and means of transmitting the estimated local measurement to the local beacon (DEPi).

Description

 SYSTEM FOR MEASURING THE QUALITY OF AN ENVIRONMENT AND LOCAL BEACON FOR THE MEASUREMENT SYSTEM

TECHNICAL FIELD AND PRIOR ART The invention relates to a system for measuring the quality of an environment.

In most developed countries, legislation requires large cities to set up air quality management systems capable of providing air quality information to institutions and the public.

The measurements relate, depending on the stations, to nitrogen oxides (NOx), ozone (0 ₃ ), sulfur dioxide (S0 ₂ ), benzene, toluene and xylene (BTX), carbon monoxide. carbon (CO), dust of different particle sizes (PM10, PM2.5, black smoke), etc. Metals such as As, Cd, Ni, Pb and organic compounds are generally analyzed in the laboratory. The measurements carried out lead to the formation of an index which reflects the air quality.

Typically, different index levels are defined for each pollutant, depending on its concentration in the air and the duration of exposure. These index levels vary by country and, for example, the table below gives the French air quality index (ATMO index) relating to four types of pollutants, namely S0 ₂ , 0 ₃ , N0 ₂ and dust. The ATMO index varies from 1 to 10 and the corresponding thresholds, for each of the pollutants, are expressed in μg / m ³ for a duration T:

The measurements are carried out for an area whose extent is typically of the order of several km ² . At present, an individual seeking to know the level of pollution in an area or district can consult this information through various media (press, telephone, internet network, etc.). The information it receives is representative of the area or neighborhood as a whole. If an individual is interested precisely in the level of pollution that is close to him, the information he receives does not represent - except exception - this level of pollution. On the other hand, the measurements given by the network do not allow this individual to obtain an evolution in real time of the level of pollution that surrounds him.

Furthermore, it now appears that industrial and environmental policies are increasingly dependent on public perception. From this point of view, the current system of communication of information relating to the environment only responds partially waiting for the public. It is therefore difficult for the public to correctly understand the information they receive, or even to consider this information as credible. The invention does not have the drawbacks mentioned above.

Statement of the invention

Indeed, the invention relates to a system for measuring the quality of an environment. The system includes:

- at least one reference device comprising means for establishing at least one measurement relating to the quantity of at least one reference constituent and at least one measurement relating to the quantity of at least one other constituent, different from the reference constituent and transmission means for transmitting said measurements to a communication center, at least one local tag containing at least one detector to establish at least one local measurement relating to the quantity of said reference constituent present near the local tag and transmission / reception circuits for transmitting the local measurement to the communication center, and - the communication center which comprises: first means for establishing, from the measurements carried out by the reference device, a mapping of levels, at different scales, of the estimated quantity of at least one reference constituent and at least one of said other constituents ants, second means for calculating a dilution factor from the local measurement of said reference constituent made by the local beacon and from data from said cartography relating to the reference constituent,

- third means for calculating an estimated local measurement of at least one of said other constituents from the dilution factor and data from said mapping relating to said other constituent, and - communication means for transmitting the estimated local measurement to the local beacon.

According to an additional characteristic of the invention, the means for establishing at least one local measurement relating to the quantity of said reference constituent comprise at least one microsensor for measuring the oxidizing power of the environment, the reference constituent then consisting of all the oxidizing gases present in one environment. According to yet another characteristic of the invention, the microsensor for measuring the oxidizing power is based on semiconductor metal oxides.

According to yet another additional characteristic of the invention, the microsensor for measuring the oxidizing power consists of at least one metallic oxide semiconductor reactive with respect to reducing gases or oxidizing gases.

According to yet another characteristic of the invention, the reference device is consisting of at least one fixed or mobile collective beacon distant from the local beacon.

According to yet another characteristic of the invention, the reference device comprises at least one additional local beacon distant from the local beacon.

According to yet another characteristic of the invention, the local tag comprises:

- means of consolidating the local measure to obtain at least one consolidated local measure,

display means, and

- an input interface.

According to yet another characteristic of the invention, the means for consolidating the local measurement comprise said transmission / reception circuits for receiving at least one consolidated local measurement originating from the exchange, the consolidated local measurement originating from the exchange being obtained on the basis for the execution, in the central office, of a consolidation program applied to local measurement.

According to yet another characteristic of the invention, the consolidation means comprise said transmission / reception circuits able to download consolidation data and processing circuits to locally execute at least one consolidation program based on the local measurement and consolidation data.

According to yet another characteristic of the invention, the consolidation means, the display means and the input interface are combined in a sub-assembly physically separate from the detector and the detector and the sub-assembly communicate with each other by transmission / reception means.

According to yet another characteristic of the invention, the consolidation means, the display means and the input interface are combined in the same sub-assembly and the detector plugs into an external port of the sub-assembly.

According to yet another characteristic of the invention, the consolidation means, the display means and the input interface are combined in the electronics of the same sub-assembly and the detector is directly integrated in the electronics of the subset. According to yet another characteristic of the invention, the sub-assembly is a cell phone.

On the basis of the estimated and / or consolidated local measurements, the system according to the invention advantageously offers each individual a service for assisting with behavior and judgment as regards environmental problems.

The system is advantageously distinguished, in cost, performance and dissemination, from known professional metrology.

The objective of an individual's understanding and acceptance of environmental risks involves trivializing the information that this individual receives. The personalized environmental quality qualification system according to the invention achieves this objective. The system provides continuous (and not only event-specific) information, independent (outside the institutional circuit), and personalized (in a time and space scale which interests the individual).

The sensitivity of the measurements advantageously gives relativity to the different sources of signals perceived as nuisances

(comparison with natural levels, geographic variations, etc.).

The system allows, technically and economically, access for the greatest number to environmental measurement (air quality, radioactivity, etc.). This is done by implementing a triple break with existing measurement networks such as those mentioned above, namely:

- a densification of the sampling of pollution measurements, - the production of a personal measurement on the scale of an individual's immediate environment,

- the communication and consolidation of these different scales to acquire and disseminate a global and local intelligence of pollution and its evolution.

The system according to the invention allows a qualification of the air quality. A wide variety of measures can thus be envisaged, namely measurements of radioactivity, solar radiation, pollutant, allergen levels, pollen levels, etc. The air quality management systems implemented in the various developed countries mentioned above require monitoring of the general level of pollution in cities. The system according to the invention determines the local fluctuations in the pollution of cities and proposes to supplement the monitoring of the general level of pollution by an aid to the behavior of the individual in his relation to one environment. The pollution of cities is a physical field which contains several scales of variation:

1 km (at this scale, the physical field is very dependent on the weather),

100 m (this is the scale of the district, the physical field here is very dependent on the sources of pollution),

10 m (it is the close environment, the physical field is very dependent on the capacity of evacuation of pollutants; for example, the streets "canyon" trap pollution), - 1 m (it is the immediate environment of an individual, the physical field is very dependent on the location of the individual and the local capacity for diluting pollutants; for example, proximity to cars or height above the ground are all influencing factors).

The network according to the invention is a distributed network which makes it possible to establish a map of levels of the estimated quantity of constituents of the environment at different scales and to juxtapose this map with a local measurement.

Individual local measurement tags, hereinafter referred to as “personal environment detector” (DEPi), make it possible to acquire personalized measurements which take into account local phenomena such as, for example, the dilution factor. Data on a local scale is significant in itself, for example to follow local spatial and / or temporal variations of a pollution level. However, without linking this data with data from a global network, it is not possible for a user to obtain an overall perception allowing him to situate himself correctly in his environment. Without this connection, local data provides the user with limited behavioral assistance. According to the preferred embodiment of the invention, the qualified medium is air. More generally, the invention applies to the qualification of any type of gaseous or even liquid environment.

Brief description of the figures FIGS. 1A and 1B represent two variants of a local beacon according to a first embodiment of the invention; - Figures 2A and 2B show two variants of a local tag according to a second embodiment of the invention; FIG. 3 represents an example of a local beacon detector according to the invention; - Figure 4 shows an example of a measurement system according to the invention. In all the figures, the same references designate the same elements.

Detailed description of methods of implementing the invention

FIGS. 1A and 1B represent two variants of local beacon according to a first embodiment of the invention and FIGS. 2A and 2B represent two variants of local beacon according to a second embodiment of the invention.

A local DEPi beacon according to the invention is a fixed or mobile light device. It produces data on an individual local scale. It provides information that can be consulted in real time. The DEPi tag includes a detector 1 and a sub-assembly or platform 2 comprising, among other things, transmission / reception circuits 3, a processing circuit 4, display means 5 and an input interface 6 ( keyboard, touch screen, voice control, etc.). The power supply of the detector 1 can be supplied by the platform 2.

According to a first variant of the invention (cf. FIGS. 1A and 2A), the detector 1 and the platform 2 are separated from one another. The detector 1 and the platform 2 communicate with each other by means of transmission / reception 8, 9. A transmitter 8 placed on the detector 1 transmits to a receiver 9 placed on the platform 2 a signal 7 representative of the measurements performed. The signal 7 can be, for example, an acoustic signal, an electrical signal (wired connection), an infrared signal, a signal electromagnetic VHF or microwave, etc.

According to a second variant of the invention (cf. FIGS. 1B and 2B), the detector 1 and the platform 2 are mounted on the same ^' support. The detector 1 can then consist of an extension plugged into an external port of the platform 2. The detector can also be directly integrated with the electronics of the platform 2.

The DEPi tag can be a portable device by an individual or a fixed device placed in public or private premises. It can also be installed in a motor vehicle, measuring the air inside or outside the passenger compartment.

Mobile type, platform 2 is preferably a cell phone operating for example according to GSM (GSM for “Global System for Mobile communication.”), Or GPRS (GPRS for “General Packet Radio Service”, or UMTS (UMTS) protocols. for "Universal Mobile Telecommunications System"), in networks of established mobile telephony operators. These networks allow in particular the geolocation of the detector. In the case where the platform is a cellular telephone, the detector 1 can also be coupled to the smart card (SIM card) connectors on the cell phone.

The local measurements made by the detector 1 can be used as such. They make it possible to judge the situation at the level of the detector 1. A program for processing the local measurement is executed in the processing circuits 4. According to the invention, the local tag DEPi receives estimated measures of concentration of constituents which are not directly measured by the local beacon as well as measures consolidated by consolidation data supplied by an external network. Consolidation data relate to the general situation of the environment (overall measures, trends, etc.). They may also relate, for example, to personalized advice.

Two embodiments are possible for implementing the consolidation of local measures with the consolidation data.

According to a first embodiment of the invention (cf. FIGS. 1A, 1B), the local measurement data dL are transmitted to a central. C, via the means of transmission / reception 3. On the basis of local measurements and consolidation data, a consolidation program is executed by the central C. This results in complete dLc information in terms of detailed interpretations (measurement consolidated local) which is transmitted to the DEPi tag.

According to a second embodiment of the invention (cf. FIGS. 2A, 2B), the consolidation program is executed in the local tag. The consolidation data dR is then received by the beacon, via the transmission / reception means 3. On the basis of the local measurements and the consolidation data, the consolidation program is executed in the processing circuits 4. This results complete information in terms of detailed interpretations. Treatment and consolidation programs for local measurement can be loaded a priori in a memory circuit of platform 2. They can also be downloaded from an external network. The transmission / reception circuit 3 then allows the downloading of the program as well as its updating.

The consolidated local measurements are displayed on the display means 5. The consolidated local measurements advantageously allow an overall assessment in terms of evolution and, therefore, behavioral assistance.

FIG. 3 represents an example of a beacon detector according to the invention. The detector 1 comprises three chemical microsensors MCA1, MCA2, MCA3 capable of measuring the same constituent A and three chemical microsensors MCB1, MCB2, MCB3 capable of measuring the same constituent B different from A. The constituents A and B can be, for example, one of the gases mentioned above (carbon monoxide, ozone, etc.). Control electronics (not shown in the figure) ensure the operation of the detector on the basis of one of the microsensors MCA1, MCA2, MCA3, for example the microsensor MCA1, for the measurement of component A and one of the microsensors MCBl, MCB2, MCB3, for example the microsensor MCBl, for the measurement of component B.

In normal operation, measurement cycles are then carried out regularly, for example every minute, by the microsensors MCA1 and MCBl. The microsensors MCA2, MCA3, MCB2 and MCB3 are not used to make the measurements.

On a slower pace, for example once per week, the control electronics initiate a self-calibration procedure. For reasons of convenience, the self-calibration procedure according to the invention will now be described for the only microsensors MCA1 MCA2, MCA3. It is clear to a person skilled in the art that the same self-calibration procedure also concerns the microsensors MCB1, MCB2 and MCB3.

During the self-calibration procedure, the control electronics initiate alternating operation, on the one hand, of the microsensor MCA1 and, on the other hand, of one of the reserve microsensors MCA2 or MCA3. The measurements obtained are then compared. If the microsensor MCA1 delivers signals which are substantially different from the signals delivered by the microsensor MCA2, this means that the microsensor MCA1 has drifted. Below a certain drift threshold, the control electronics modify the calibration curve of the MCA1 sensor to align it with that of the MCA2 microsensor. A recalibration program is used for this purpose. Above the drift threshold, recalibration is no longer possible and the microsensor for measuring component A becomes the microsensor MCA3.

Advantageously, such a system makes it possible to multiply by two or three the lifetime of a microsensor by successive recalibrations.

FIG. 4 represents an example of a measurement system according to the invention. The system consists of three elements: - a BRC reference device comprising at least one collective tag Bk, - a personalized local beacon or DEPi personal environment detector,

- a central unit C which is in communication with the reference device BRC and the local beacon DEPi in order to transmit data to the local beacon for obtaining consolidated local measurements.

In general, in the following description, a tag (individual DEPi or collective Bk) has all or part of the following characteristics:

- it delivers measurements (measurements of chemical pollutants such as ozone (0 ₃ ), carbon monoxide (CO), nitrogen oxides (NOx), sulfur oxides (SOx), oxidizing power, dust, pollen, alpha, beta, gamma, radon radioactivity, etc.) allowing the quantification of environmental parameters for an individual or a city by different types of devices (filters, pumps, micro-sensors, etc.), - it constitutes a communicating tool making it possible to transmit to one or more exchanges representative signals of the measurements carried out, processed or not, its location, its identifier, making it possible to receive measurement orders, programs, returnable information, information for the correct operation (test, etc.), communications being carried out by wired telephone links, or VHF, or JR, or by GSM, GPRS, UMTS, Bluetooth, etc. protocols. ; - it is a localizable tool allowing to determine the geolocation of the measurement (position X _/ Yι 2) by GSM triangulation systems, by GPS, ... or interactively and the time t of the measurement;

- it includes a display allowing information from the sensors to be read online or after processing by the central office, using a liquid crystal screen, by audible alarm, etc. ;

- it includes an interface allowing control, input, local interrogation using a keyboard, a tactile or vocal system, etc. ;

- it allows to process primary data

(filtering, averages, thresholds, comparisons, validity checks, etc.), run sequences and programs, format data, the processing being carried out by microprocessor.

The collective reference device BRC which networks collective beacons Bk gives a representation of the pollution signal usable as a reference for the measurement of local pollution. The collective Bk tags are deployable tags, for example, to a hundred copies. They deliver pollution data on a collective scale.

A collective tag Bk can be installed on a support ensuring its supply. The support can be fixed (urban equipment) or mobile (non-dedicated vehicle such as bus, taxi, utility vehicles). The mobile support technique advantageously makes it possible to acquire information where the population density is high. The collective tag provides information that may relate to a wide variety of pollutants (NOx, S0 ₂ , 0 ₃ , radon, etc.).

The use of mobile collective beacons is an important factor in optimizing the sampling of measurements in space and in time. A good quality measurement will be given, for example, by a mobile collective beacon which will have passed, less than an hour ago, near the place where the individual beacon makes the measurement (typically less than one km). The collective tag accesses central C, for example by the GSM function, to deliver a complete service to the user in terms of detailed interpretations of the measurement and additional knowledge (general situation of the environment, trends, personalized advice, functioning tests, etc.). The relevance of the measurement result is obtained by consolidating the local measurement of the DEPi tag concerned and information from the BRC network on a large scale. Central C controls and manages communications with the BRC network and the local DEPi beacon.

Central C receives dBRC data from the BRC reference device and dDEPi data (dL, etc.) from the DEPi beacon. It sends to the DEPi tag consolidation data dC capable of consolidating the local measurement (dLσ, dR, etc.).

The dBRC data includes all or part of the data measured by all of the Bk tags of the reference device. According to an improvement of the invention, the dBRC data also includes the measurements carried out by a set of portable beacons DEPj of other users j (j ≠ i). Bk tags are generally able to measure a large number of constituents present in the atmosphere such as 03, CO, NOx, SOx, dust, pollens, alpha radioactivity, beta, gamma, radon, etc. Central C can also receive public or private dP data from, for example, institutional networks and making it possible to assess trends ^' (data relating to road traffic, weather information, etc.).

Central C thus constitutes a set of consolidated information on the basis of all the dBRC, dDEPj (j ≠ i) and dp data. It is then possible to establish a dynamic database relating to the mapping of pollution levels. The sampling of tags is preferably chosen to be dense enough to be relevant with respect to variations in time and / or in space of the physical pollution field. Central C also constitutes, over a limited period, for example a period of ten minutes, a "physical" database made up of data of interest obtained directly or by correlation in the relevant physical units with a consistency check. and a rejection of questionable data. Rejection filters are specified for this purpose.

From the “physical” database, central C builds the mapping of pollution levels at different scales and extrapolates on time trends and / or space.

The principle of using the dilution factor to supplement the local measurement will now be described. When a user queries his mobile

DEPi, the latter transmits its location to central C as well as a measurement carried out locally by the dDEPi mobile. From the location of the local measurement and the level mapping, the central C establishes a dilution factor for each component measured by the DEPi tag.

Central C receives all of the measurements made by Bk beacons and which relate to a large quantity of constituents. According to the invention, the central office C is advantageously able to transfer data relating to constituents which are not measured locally by the DEPi beacon to the local beacon DEPi.

The central unit C is thus able, for example, to estimate the local concentration of a constituent X present in the environment of the DEPi tag and not measured by the DEPi tag. This estimate is calculated from knowledge of the dilution factor present in the environment of the DEPi tag and collective measurements carried out on component X. This estimate can be transferred to the local tag. The local measurements made by the DEPi beacon then relate to a reference constituent Y different from the constituent X. The exchange C determines the dilution factor relating to the position of the individual equipped with the local DEPi beacon from the mapping of levels of Y and of the local measurement of Y. Knowledge of the dilution factor then makes it possible to deduce the concentration CX of the constituent X present at the level of the tag DEPi. The consolidation data dC transmitted to the portable beacon DEPi can then contain data representative of the concentration CX thus determined.

More generally, the consolidation data dC capable of consolidating the local measurement can contain the consolidated measurement data dLc calculated in the central C (cf. the first embodiment, FIGS. 1A and 1B). They can also contain the dR consolidation data mentioned above (cf. the second embodiment, FIG. 2A and 2B), consolidated data on the quality of the personal environment, comparison data, trends, as well as advice. .

According to an improvement of the invention, the local tag DEPi also measures environmental parameters such as temperature, pressure and humidity. These measurements are useful for the interpretation of signals and have an informative value for the user. They can be transmitted to the user. A detector 1 comprises at least one microsensor. By way of nonlimiting examples, a microsensor according to the invention measures one or more oxidizing gases, and / or one or more reducing gases, and / or carbon monoxide (CO), and / or gamma radiation relevant for the radon detection, and / or temperature, and / or hydrometry, etc. According to the preferred embodiment of the invention, the measurement relating to the reference constituent Y making it possible to determine the dilution factor is the measurement of the oxidizing power (simplicity, relevance, cost).

The oxidizing power is a measurable quantity, indicative of the presence, at different concentration levels, of polluting gases in atmospheric air. The oxidizing power is a monotonic function of the concentrations of polluting gases such as, for example, nitrogen dioxide, sulfur dioxide, ozone, carbon monoxide, whether these gases are present alone or as a mixture in the air. In the case of a gas mixture, the oxidizing power is a combination of the oxidizing powers of the different polluting gases present in the mixture.

The oxidizing power measures the capacity of a gaseous mixture containing one or more polluting gases to modify the surface condition of a material judiciously chosen to be used as a reactive component. In the measurement devices proposed according to the invention, the oxidizing power of a polluting gas remains a monotonous function of the concentration of the gas in the whole range of specified concentrations. The corresponding generated signals are, therefore, for each polluting gas, a monotonic function of its concentration.

The table below is a representative example of the advantage of using oxidizing power as a measure to determine the dilution factor in order to estimate local concentrations which are not measured by the local DEPi tag.

For reasons of simplicity, the system for measuring the quality of the environment according to the example chosen comprises a single beacon B1, a central station C and a portable beacon DEPi.

USE OF OXIDIZING POWER AS A POLLUTION INDICATOR

The reference tag Bl measures the oxidizing power P (A, B, C) relative to a mixture of three gases A, B, C as well as the individual concentrations CA, CB, CC of each of the three gases A, B, C. The measurements of P (A, B, C), CA, CB and CC carried out by the tag Bl give respectively, for example, 100, 80, 10 and 10. The local measurement of P (A, B, C) carried out by the DEPi tag gives 50, it is then possible to determine a dilution factor and to deduce the local concentrations XA, XB, XC of the respective constituents A, B, C which exist at the level of the local tag DEPi, namely 40, 5 , 5. The local concentrations XA, XB, XC are thus calculated by the central C and transmitted to the portable beacon DEPi.

Advantageously, the choice of the oxidizing power as an indicator of pollution allows a local user to know, on the basis of a single measurement carried out locally, a set of local information which would otherwise require several additional local measures.

In general, gases are classified into two categories, oxidizing gases and reducing gases, according to whether they lead to measured signals increasing or decreasing monotonic function of their oxidizing power. These two categories of gas can contribute to the indicator of oxidizing power of a gas mixture. In the air quality measurement system proposed according to the invention, the quantification of the oxidizing power of a gaseous mixture is preferably based on a set of measurements, at least two, making it possible to discriminate the two categories of gas. The system then relies on the use of several sensors and / or of several modes of operation of the sensors in order to measure at least two series of signals induced, respectively, by the oxidizing gases and by the reducing gases. By way of example, the materials whose surface condition depends on the oxidizing power of the ambient air, can be semiconductors consisting of a metal oxide, a mixture of metal oxides or any other combination metal oxides and another constituent. In the presence of a gaseous mixture containing polluting gases, the surface condition of the aforementioned materials is modified by sorption of the gases and / or by chemical reactions (in particular by redox reaction) between the gases and the material. Preferably, the air quality measurement device integrates two categories of sensors, sensors using reactive semiconductor metal oxides toward oxidizing gases and sensors implementing reactive semiconductor metal oxides toward reducing gases.

The interpretation of the measurement signals from detector 1 is obtained by calibration and experimental learning. The use of a number of identical sensors greater than 2 improves the robustness of the calibration. FIG. 2 represents an example of a detector according to the invention able to carry out the calibration of the detector.

Claims

1. System for measuring the quality of an environment, characterized in that it comprises: - at least one reference device (BRC) comprising means for establishing at least one measurement relating to the quantity of at least one constituent reference (Y) and at least one measurement relating to the quantity of at least one other constituent (X), different from the reference constituent and the transmission means for transmitting said measurements to a communication center (C), at at least one local beacon (DEPi) containing at least one detector (1) for establishing at least one local measurement relating to the quantity of said reference constituent present near the local beacon and the transmission / reception circuits (3) for transmitting local measurement towards the communication center (C), and - said communication center (C) which comprises: first means for establishing, from the measurements carried out by the reference device, a map of n levels, at different scales, of the estimated quantity of at least one reference constituent and at least one of said other constituents, of the second means for calculating a dilution factor from the local measurement of said reference constituent carried out by the local and data beacon of said cartography relating to the reference constituent, third means for calculating an estimated local measurement of at least one of said other constituents from the dilution factor and data from said cartography relating to said other constituent, and - communication means for transmitting the estimated local measurement to the local beacon (DEPi).

2. Measuring system according to claim 1, characterized in that the detector (1) comprises at least one microsensor (MCAl, MCA2, MCA3) for measuring the oxidizing power of the environment, the reference constituent then consisting of all the oxidizing gases present in the environment.

3. Measuring system according to claim 2, characterized in that the microsensor (MCAl, MCA2, MCA3) for measuring the oxidizing power is based on semiconducting metal oxides.

4. Measuring system according to any one of claims 2 or 3, characterized in that the microsensor (MCAl, MCA2, MCA3) for the measurement of the oxidizing power consists of at least one reactive semiconductor metal oxide vis- with respect to reducing gases or oxidizing gases.

5. Measuring system according to any one of the preceding claims, characterized in that the reference device (BRC) consists of at least one fixed or mobile collective beacon (Bk) distant from the local beacon.

6. Measuring system according to any one of the preceding claims, characterized in that the reference device (BRC) comprises at least one additional local beacon (DEPj) distant from the local beacon (DEPi).

7. Measuring system according to any one of the preceding claims, characterized in that the local tag comprises: - consolidation means (3, 4) of the local measurement to obtain at least one consolidated local measurement,

display means (5), and

- an input interface (6).

8. Measuring system according to claim 7, characterized in that the means for consolidating the local measurement comprise said transmission / reception circuits (3) for receiving at least one consolidated local measurement (dLc) coming from the central, the consolidated local measurement from the central being obtained on the basis of the execution, in central (C), of a consolidation program applied to the local measurement.

9. Measuring system according to claim 7, characterized in that the consolidation means comprise said transmission / reception circuits (3) able to download consolidation data (dR) and processing circuits (4) to execute locally. at least one consolidation program on the basis of local measurement and consolidation data.

10. Measuring system according to any one of claims 7 to 9, characterized in that the consolidation means (3, 4), the display means (5) and the input interface (6) are combined in a sub-assembly (2) physically separate from the detector

(1) and in that the detector (1) and the subassembly (2) communicate with each other by transmission / reception means (8, 9).

11. Measuring system according to any one of claims 7 to 9, characterized in that the consolidation means (3, 4), the display means (5) and the input interface (6) are combined in the same sub-assembly (2) and in that the detector (1) plugs into an external port of the sub-assembly (2).

12. System according to any one of claims 7 to 9, characterized in that the consolidation means (3, 4), the display means (5) and the input interface (6) are combined in the electronics of the same sub-assembly (2) and in that the detector (1) is directly integrated into the electronics of the sub-assembly (2).

13. System according to any one of claims 10 to 12, characterized in that the sub-assembly (2) is a cell phone.