FR3038185A1 - SENSOR EMITTING TO A MOBILE PHONE - Google Patents

Abstract

Characterized device comprising a single identifier beacon and a sensor (1), the beacon comprising a static memory (2), the static memory comprising a unique identifier, the beacon comprising a dynamic memory (4) and the beacon comprising a communication interface non-contacting device (3) transmitting to a mobile terminal (5), wherein the sensor (1) is connected to the dynamic memory (4), in which the communication interface (3) is connected to the static memory (2) and wherein the communication interface (3) is connected to the dynamic memory (4).

Description

The present invention generally relates to the connection of sensors to a telecommunications network.

The prior art to the invention knows sensors of various physical quantities such as sound level meters, pressure sensors, temperature or pollution. These sensors are very useful in urban environments for measuring environmental information. The prior art to the invention also knows telecommunications networks that allow the long-distance transmission of data representing voice or video. In particular, IP ("Internet Protocol") networks are used by the telecommunications networks of the prior art. Since the prior art also knows sensor networks, there is a long-standing need to create a sensor network by means of a telecommunications network in order to centralize the measurements of these sensors, for statistical or forecasting purposes. For this, an interface with the telecommunications network is, at a minimum, to be installed on the sensors. However, in the prior art, the sensors are optimized in energy consumption to minimize maintenance costs by maximizing their autonomy. It is therefore not easy to connect them to a telecommunications network because the interface to this network to transmit to a network antenna, requires an expenditure of energy not compatible with the autonomy of the sensor, in practice. In addition, in the case where one could increase the energy reserve of a sensor, to the extent necessary to power a transmitter compatible with the telecommunications network, such a transmitter would be incompatible with the metrology of the sensor by constituting a source of electromagnetic disturbances all the more important as its power and its coverage area are extended. The cost of the magnetic shielding that should result would be clearly incompatible with the cost of a sensor. In the prior art, the sensors are therefore not equipped with a low-power interface with a telecommunications network. This does not allow their simplified implementation in a network of sensors, especially at the scale of a territory.

The prior art to the invention also knows mobile terminals or mobile or mobile phones, which are connected to a telecommunications network by an interface using signals using radio frequencies. They make it possible to connect to a telecommunication network using so-called "3G" or "4G" radio frequency protocols for medium distances as well as access points using WIFI or Bluetooth technologies for short distances. A mobile terminal having by nature an interface with a telecommunications network, it could be envisaged to add to it sensors or to use those which it embarks natively. However, this mode of use would suffer from the same drawbacks as those mentioned above: decrease in the autonomy of the mobile terminal because of the power supply of the sensor, potential impact on the metrology of the sensor in the vicinity of this disruptive communication interface measurements. In the prior art, mobile phones can be provided with sensors but do not meet the need expressed by the deployment of a network of independent sensors.

Furthermore, the prior art has low-power communication interfaces because they operate in the near field, such as NFC technology or low-power Bluetooth technology, known as BEACON or i-Beacon. However, the reading by a mobile phone of a sensor equipped with a near-field interface encounters the need to locate the sensor and thus to provide either the mobile phone or the sensor with an interface to a global positioning system. or "GPS" ("in English" Global Positioning System "). However, since such a system is global and therefore expensive in energy, the addition of such a GPS system and an NFC interface to a sensor would not be retained in practice by a person skilled in the art of sensors in the search for a connection. low consumption and metrological from a sensor to a telecommunication network.

The prior art to the invention also knows contextual tags or tags, unique identifier, using near field communication technologies, such as NFC (in English "Near Field Communication"), which allows to transmit a an invariable unique identifier associated with a tag in a global database for location purposes of a mobile terminal. These tags are however not usable as such by one or sensors, only for locating the mobile phone equipped with a beacon reader, during playback. They are, in fact, provided with a static memory or read-only or ROM, fixed or invariable content, equal to the unique and invariable identifier of the tag. In the prior art, the beacons are therefore not equipped with sensors and do not seem suitable for use in conjunction with sensors.

Furthermore, the prior art has dynamic memories or RAM, adapted to read and write data as well as the conservation of data between writing and reading. In this context, the invention relates to a device comprising a single identifier beacon and a sensor, the beacon comprising a static memory, the static memory comprising a unique identifier, the beacon comprising a dynamic memory and the beacon comprising a communication interface. non-contact emitting to a mobile terminal, wherein the sensor is connected to the dynamic memory, wherein the communication interface is connected to the static memory and wherein the communication interface is connected to the dynamic memory. In variants: the communication interface is an NFC (Near Field Communication) interface. - the communication interface is a low-power Bluetooth interface ("Bluetooth low energy"). the sensor is a physical sensor. 3038185 3 - the sensor is a chemical sensor. - The beacon is arranged on street furniture. the beacon is arranged in a vehicle. the physical sensor is a sound level meter. 5 - The chemical sensor is a carbon monoxide (CO) sensor. The invention also relates to a method comprising the following steps: - receiving a measurement of a sensor in a single identifier beacon - transmitting the measurement and the unique identifier of the beacon, from the beacon, to a mobile terminal connected to 10 a telecommunications network. In a variant of the method, it comprises the additional step of: transmitting the measurement and the unique identifier of the beacon, from the mobile terminal, to the telecommunications network.

It can be seen that the device of the invention makes it possible to solve with simple means the problem of the long-distance transmission of the measurements of a set of sensors by a telecommunications network, making these sensors communicating on a large scale. Starting from a network of beacons each transmitting a unique identifier whose contactless reading can be performed on a mobile telephone, connected to a telecommunication network, the modification of each beacon by attaching a sensor to it and sending each beacon the identifier and the measurement of the sensor to which the beacon has been associated, makes it possible, by transmission to the telecommunications network via a mobile terminal receiving the transmission of the beacon, of a message containing the identifier and the measure of disposing on this network of ways to build a network of communicating sensors at the network scale, that is to say on a global scale.

The sensor network obtained is occasional and collaborative, in the sense that the measurement is transmitted only when a mobile telephone connected to the telecommunications network reads the beacon and is programmed to transmit the measurement in addition to the unique identifier of the tag, which involves the collaboration of the user of the phone. Such a sensor array is, remarkably, extremely energy efficient since the entire transmission only corresponds to the lengthening of the unique identifier of the beacon in the message sent to the mobile phone, which impacts at a minimum on the autonomy of the phone and the beacon. Such a sensor network is also extremely respectful of the metrology of the sensor, the near-field emission power being very low.

Such a sensor network also makes it possible, in connection with a global database of unique identifiers connected to the network and associated with a context of the beacon (absolute geographic location in latitude longitude or relative to a moving object such as a bus) to obtain the location of the read sensor, as well as the measurement date, at the latency time near the telecommunication network.

This result is achieved without requiring global locating means of the user's position in the telecommunications network or by a GPS system. It is thus possible to present to a user measurements from a large number of sensors and in particular sensors mounted on beacons adjacent to the beacon that he reads, if the user agrees to transmit the value of the sensor connected to the tag, to allow him to compare the physical magnitudes of interest to the user instead of reading, by reference to its vicinity. The beacon network is therefore used not only to locate points of interest but to provide comparative contextual information about a neighborhood of the point of interest. In the case of a sound level measurement, a user who transmits sound level information at a bus stop will be able to obtain the one of the beacons at other stops and choose the stop 15 that he wishes to use according to the noise level. of this criterion. It would be the same for the temperature or any other size. The invention will be better understood in connection with the list of figures in which: FIG. 1 represents the device of the invention with an NFC beacon and a sensor which is a sound level meter in which the beacon has been modified to transmit at the same time that its unique identifier a value of the sound level measured by the sensor. The beacon is contactless and transmits to a mobile terminal.

In a first embodiment of the invention, with reference to FIG. 1 for the numbers in parentheses, a sensor (1) is used which is a sound level meter equipped with an output interface to make the measurement of the sound level meter available. This interface may be a connector or a contactless interface of the "Zigbee" type. The beacon is provided with a ROM (2) containing a unique identifier of the beacon and a communication interface of this value via a contactless NFC (3) communication interface operating in a near field and transmitting sufficient to be picked up by a mobile phone (5). The transmission level of this interface will be defined according to the reading distance acceptable by the mobile terminal and the acceptable power not to disturb the metrology of the sensor, via electromagnetic interference with the sensor circuits.

The beacon is also provided with a RAM (4), modifiable in reading and writing and connected to the sensor to the extent necessary to receive the measurement emitted by the sensor and to keep it for a reading of the measurement. same time as the unique identifier, by a mobile phone.

The sensor (1) is connected to the RAM (4) and the communication interface (3) is connected to the ROM (2) and the RAM (4). The communication interface (3) is programmed to send a message comprising the unique identifier, contained in the ROM (2), and the measurement of the sensor, contained in the RAM (4), to the mobile phone (5), connected to a telecommunications network.

For a microcontroller performing the function of reading the ROM and transmitting it via the NFC interface, it will be sufficient to logically contiguate the address ranges of the ROM and the RAM in the range of addressing the microcontroller and having the microcontroller read a memory length defined as the sum of the lengths or the number of memory cells of the ROM and the RAM, in order to obtain, with maximum economy of means, the reading and therefore the transmission of the unique identifier 10 and measurement of the sensor via the NFC communication interface of the tag, to the mobile phone. Alternatively, it will be possible to program an integrated circuit, such as a VLSI or a microcontroller, to read two disjointed memory ranges, that of the ROM and that of the RAM, in sequence for sending them together via the communication interface. of the tag.

A transmission via the mobile phone of these two pieces of information in the same IP or http message can then be carried out by the telephone by changing the length of the message associated with the transmission of the unique identifier on the telecommunications IP network connected to the mobile telephone. . If the length of the identifier has been provided as a variable in a standard of the telecommunications network, it will thus be possible to directly input the change making available the measurement of the sensor, in an existing standard. The two joint modifications of the beacon by adding a dynamic memory receiving a measurement of a sensor and the joint transmission by the beacon, of an invariable and unique identifier of the beacon at the same time as the measurement of the sensor therefore appears. as a flexible integration device and method for connecting sensors to an existing telecommunications network.

Advantageously, the near-field beacon, for example NFC or BEACON, is associated at the level of a telecommunications network with the address of an application or an application service, delivering to the user the schedules of the passing buses. by the shelter or bus station on which the beacon is installed. For this, a database associating tags or tags with a location or a context of the tag will be maintained at the global level. The location accuracy of the tag or tag will be equal to that of the location of the terminal for near-field reading. Depending on the technologies used, this distance may be from a few centimeters to a few tens of meters. This distance can be tuned to the accuracy and metrology of the desired sensor, taking into account the transmit powers and the variation of the measured physical magnitude with the distance. With such a database, beacons according to the invention can be associated in a network with an application delivering the sound levels of the neighboring bus stations or located on the line, so as to inform the user on quantities of interest of its environment by a cartography making it possible to compare its neighborhood to its place of reading of the beacon.

The combination of geographic or contextual points of interest with environmental and contextual relevant interest quantities for the user also allows acceptance of transmission of these data on a large scale, increasing the amount of data collected by a network. sensors associated with tags modified according to the present description.

With other sensors, environmental variables (temperature, pressure, hygrometry, etc.) of interest to a user can also be easily collected and presented to the user equipped with a simple mobile terminal, without the sensors are equipped with telecommunication interface compatible with a telephony network, which allows the use of the communication means provided for these sensors, means which are thus optimized in energy to communicate with the beacon. A wire connection on a printed circuit common to the tag and the sensor or cable and connector or contactless interface Zigbee are thus possible between the sensor and the tag, without departing from the teaching of the invention. For a contactless interface such as Zigbee, the beacon will be equipped with a Zigbee compatible reception interface. Likewise, other technologies for transmitting the measurement of a sensor can be used, as long as the beacon has a corresponding read module. An RFID technology is thus possible. The invention thus makes it possible by modifying a beacon transmitting only a unique identifier to a mobile telephone, by adding a sensor and by modifying the transmitter of the beacon to make it transmit the measurement of the sensor and the unique identifier, d integrate the sensor with an existing mobile telephone network and make this sensor communicating on a large scale. The invention is susceptible of industrial application in the field of sensor networks. For the purposes of the present application, the word "connected" is meant as meaning for two elements (in particular sensors, memories, communication interfaces, ...) the existence of means for exchanging information between these two elements.

Claims (1)

REVENDICATIONS1. Device characterized in that it comprises a beacon with a unique identifier and a sensor (1), the beacon comprising a static memory (2), the static memory 5 comprising a unique identifier, the beacon comprising a dynamic memory (4) and the beacon comprising a contactless communication interface (3) transmitting to a mobile terminal (5), wherein the sensor (1) is connected to the dynamic memory (4), wherein the communication interface (3) is connected to the static memory (2) and wherein the communication interface (3) is connected to the dynamic memory (4). [2] Device according to claim 1 wherein the communication interface (3) is an interface NFC ("Near Field Communication"). [3] Device according to claim 1 wherein the communication interface (3) is a low-power Bluetooth interface ("Bluetooth low energy"). The device of claim 1, wherein the sensor (1) is a physical sensor. [5] Device according to claim 1, wherein the sensor (1) is a chemical sensor. [6] Device according to claim 1 20 urban furniture. [7] Device according to claim 1, vehicle. [8] Device according to claim 4, sound level meter. [9] Device according to claim 5, carbon monoxide (CO). [10] A method comprising the following steps: - receiving a measurement of a sensor in a single identifier beacon - transmitting the measurement and the unique identifier of the beacon, from the beacon, to a mobile terminal connected to a network of beacons telecommunications. The method according to claim 10, comprising the further step of: transmitting the measurement and the unique identifier of the beacon from the mobile terminal to the telecommunications network. in which the beacon is disposed on a one in which the beacon is disposed in a one in which the physical sensor is one in which the chemical sensor is a sensor