FR2893717A1 - Weather station, e.g. consumer weather station, for locally measuring e.g. pressure, has sensor, where station has unit exchanging data with remote server and mobile telephone by using global system for mobile communication type network - Google Patents

Abstract

The station has a sensor (12) e.g. thermometer, measuring temperature. The station has an exchange unit exchanging a data with a remote server (18) and a mobile telephone (50) by using a global system for mobile communication (GSM) type network (20). The station transmits short message service (SMS) type messages, by a data transmission unit (14), during the exchange of the data with the server. The station has a unit (16) receiving the data. The messages have meteorological observations data representing the temperature and data representing date and hour at which measurements are performed.

Description

WEATHER STATION CAPABLE OF EXCHANGING DATA WITH A SERVER

  The present invention relates to a portable weather station capable of exchanging data with a remote server via a cell broadcast network.

  There are currently many types of consumer weather stations for locally measuring, for example in an individual, atmospheric parameters such as temperature, pressure or the humidity of the air. These measurements are made by sensors connected to the station either wired or via a radio link. These stations usually have a screen to display these measurements as alphanumeric characters or as pictograms. These stations have no means of knowing the weather forecast for the coming hours; they can only be used to display the current meteorological situation and possibly an evolution towards the future from the extrapolation of these measured parameters. Stations capable of receiving forecast bulletins are available on the market, but these stations are generally intended for professionals, that is to say that they are relatively sophisticated meteorological stations and therefore relatively expensive. In addition, there is also another type of weather station for transmitting meteorological data. Users of this type of station can register on a website and, through this site, transmit to other users the data collected by their station. For this, they must connect the station to their computer so that the transfer of information can be made. Such an approach is not necessarily very practical to achieve since it requires the intervention of the user and the connection of the station to a computer.

  The problem to be solved is therefore to provide a mass weather station capable of receiving weather forecasts and transmitting its observations transparently to a user of the station.

  The invention solves this problem with a weather station having means for transmitting to and receiving from a remote server data via a cell broadcast network.

  The invention thus relates to a portable weather station comprising a central unit and at least one sensor measuring at least one atmospheric parameter and transmitting at least one measurement to the central unit, the central unit having transmission and reception means of data forming messages, this data being exchanged with at least one remote server via a cell broadcast network, and at least one of the messages transmitted by the station containing meteorological observations from measurements made by the s) sensor (s). A weather station according to the invention is intended to be installed for example in an individual, in particular to allow him to know the atmospheric parameters around his home. This station may contain one or more sensors, depending on the use desired by the individual. Thus, the station is preferably of relatively small size, so that it can be installed in a dwelling without occupying too much space and without being inconvenient for the users of the premises.

  Moreover, such a weather station is able to connect with a remote server which groups meteorological observations made by different stations, and which can thus transmit them from one station to another.

  Thus, said weather station can also receive observations and / or forecasts from this remote server. These data exchanges between the weather station and the server are in the form of coded messages with a predetermined format.

  For these exchanges to be possible, the central unit comprises, in one embodiment, coding means for creating, at least on the basis of measurements collected by the sensor (s) and a correspondence table, messages observations in a predetermined format, these messages being intended to be transmitted to the server by the transmitting means. It is also possible, in one embodiment, to create the messages from observations data made by the user, such as cloudiness, type of precipitation and visibility. For the input of these data, the central unit comprises for example an input means, and / or means allowing the user to select one of the previous parameters using drop-down menus.

  The central unit also comprises decoding means for decoding, from a correspondence table, messages received from the server via the reception means, these messages containing in particular observations and weather forecasts. The correspondence table used by the coding means, called the first table, is created specifically for a given server and a type of meteorological station, and it makes it possible to associate a code with a meteorological phenomenon, for example rain, or at a given time. numerical value such as temperature or wind speed.

  The messages may also contain other parameters such as the time or date of the observation. Similarly, the central unit has means for decoding, from a correspondence table identical or not to the first, messages containing forecasts and / or meteorological observations. In one embodiment of the invention, the forecasts and / or meteorological observations come from a database made up at least partially of data received from meteorological stations of the same type as said portable weather station. Thus, a set of weather stations such as that defined by the present invention can be used to create a network of weather observations and / or forecasts over a wide area.

  The correspondence table (s) used in the coding and decoding means can be stored for example on the server, but they can also be stored locally in the central unit of the weather station. Thus, in one embodiment, the central unit has a memory, in particular for containing a correspondence table. The messages are exchanged between the meteorological station and the remote server via a cell broadcast network. In such a network, it is sometimes necessary that the different components have identifiers, so that the data transmission is done correctly.

  For this purpose, in one embodiment, the portable weather station comprises a SIM card-type smart card, enabling the identification of the station in the cellular network. The SIM-type smart cards are the cards used for the identification of mobile phones in a telecommunications network, they can therefore be used in a station according to the invention, especially when the cell broadcast network is of GSM type.

  In this case, a SIM card present in a station can be set up so that the message exchanges are carried out exclusively between the station and a predefined remote server. These SIM cards can also be used to identify the weather station in networks other than GSM. In the case where the station comprises such a card, a correspondence table may, in one embodiment, be stored in an entry of the SIM card directory.

  Depending on the use made of the weather station and the location in which it is installed, a user may choose to install in addition to the central unit 30 different sensors such as a thermometer, a solar collector, a rain gauge or still an anemometer. Thus, in one embodiment, the atmospheric parameters measured by the sensor (s) are comprised in the group comprising: the outside temperature, the internal temperature, the pressure, the hygrometry, the wind speed, the direction of the wind, sunshine, amount of precipitation. Humidity is the measure of the degree of humidity of the air.

  Once the measurement of the atmospheric parameters has been carried out, the sensor (s) transmits (measures) the measurements to the central unit of the station. This transmission is performed, according to an embodiment of the invention, by a wired link, or by a radio link, for example in the 433 MHz band, or by an infrared link. Different types of links can be used for a given weather station, depending on the type of sensor it contains. For example, in the case where a station has a thermometer for measuring the indoor temperature and an anemometer: the indoor thermometer can be installed right next to the central unit, and thus be connected by a wire connection, while the anemometer must be located outside, and in this case it is better to use a wireless link.

  In order to achieve an ergonomic interface with the users, the central unit is provided, in one embodiment, with display means, for example an LCD type screen, making it possible to display information in the form of alphanumeric characters and / or pictograms. The information displayed is, according to the embodiment of the invention, included in the group comprising: date, time, meteorological observations from measurements made by the sensor (s), and forecasts or observations received the server. These display means will be described in detail later.

  For a meteorological observation made by a station to be useful to persons other than the users of said station, it may be necessary to know the exact geographical position of that station. In one embodiment, location data of the station is determined by a user of this station which provides this data to the central unit and / or the server.

  For example, the user can enter in the station's central unit the postal code of the place where the station is installed, or the latitude and longitude of the place, if he knows them or if he has determined. Alternatively, the user can register on a website managed by the server on which he identifies his station and its exact location, by entering an address or other information such as geographical coordinates.

  In another embodiment, the station has a satellite geo positioning system, in particular of the GPS type, which makes it possible to determine the exact coordinates of the station. In yet another embodiment, the station comprises a SIM card-type smart card, and the geographical location of the station is achieved by GSM triangulation. Triangulation is a process in which a device equipped with a SIM card determines its distance from three relay antennas as a function of the intensity of the radio signals it receives. From these distances he can deduce his position.

  When the location of the station has been carried out, it is necessary to transmit these location data to the server so that it can record them in a database and subsequently associate them with observations received from this station. For this purpose, in one embodiment, one of the messages transmitted by the meteorological station to the server, preferably the first message, is a message containing location data of the station.

  In one embodiment, the messages consist of a series of alphanumeric characters and / or symbols, the number of characters and / or symbols being preferably less than 160, representing in a predetermined format one or more types of data included in the group comprising: data representing the type of message, data representing the coding format, data representing the date and time, and observation data and / or weather forecasts. The alphanumeric characters and / or symbols present in the messages come from a correspondence table. The structure of such messages will be described in more detail later. The preferential number of 160 characters is due to the fact that, in one embodiment, the messages transmitted and / or received by the station are messages of the SMS type. Indeed, in this case, the alphanumeric characters and / or symbols will be contained in the body of the SMS message, and this message body is limited to 160 characters.

  Moreover, the use of SMS type messages makes it possible to make these messages compatible with mobile phones. Thus, in one embodiment, the central unit exchanges messages with mobile phone type devices through the means of transmitting and receiving data. For this purpose, it may be useful for the mobile phone to be provided with an application, for example of the Java application type, making it possible to decode these messages and to translate them into language understandable by a user.

  Thus, the user can, while away from home, receive on his mobile phone a message giving him information on the weather at home.

  Other features and advantages of the invention will become apparent with the nonlimiting description of some of its embodiments, this description being made using the figures in which: FIG. 1 represents a system comprising a meteorological station in accordance with FIG. the invention, dialoguing with a remote server, Figure 2 shows a central unit of a weather station according to the invention, and Figure 3 shows the structure of a message transmitted by a station according to the invention.

  In Figure 1 there is shown a portable meteorological station comprising a central unit 10 and a sensor 12, for example a thermometer. The central unit 10 and the sensor 12 are connected by a wire connection 22.

  The central unit 10 has means for exchanging data with a remote server 18 and a mobile telephone 50 via a network 20 of the GSM type. In order for the station to be identified in the GSM network, it is provided with a SIM card 28. When data is exchanged with the server 18, the station transmits messages of the SMS type, using a transmission means 14, and can receive them via a reception means 16.

  The messages sent regularly by the station are messages of meteorological observations. These messages contain data representing the temperatures measured by the thermometer 12, as well as data representing the date and time at which the measurements were made. In order for these messages to be understandable by the server 18 and by a user of the telephone 50, the transmitted data must be encoded by coding means 24, using a correspondence table stored in an entry of the SIM card directory. 28. For a numeric value such as a measured temperature, the lookup table matches this value to itself. On the other hand, for data such as a type and / or a precipitation intensity, it is necessary to have correspondence codes. These codes will be illustrated later by the description of the structure of a message.

  In the same way, when the station receives a message through the reception means 16, this message is decoded by a decoding means 26 which translates the received data into meteorological data which can for example be displayed by the station if it has display means.

  Such display means are particularly illustrated in FIG. 2. In this figure, the central unit 10 comprises a screen 30 of the LCD type. This screen can be black and white or in color. This screen allows you to display different information in the form of alphanumeric characters and pictograms. The screen has a first field 32 containing the current time. It also includes a second field 34 containing a pictogram representing a sun and a numerical value. The pictogram means that at the present time the sky is clear near the station, and the numerical value represents the outside temperature. The third field 36 includes weather forecasts for the hours to come, for example for a time slot starting six hours later. These weather forecasts are transmitted regularly, for example every six hours, to the station by a remote server in the form of messages, as described above.

  A central unit such as that shown in Figure 2 may also include ancillary features, not attractive to meteorology. Thus, it can have a wake up function, a radio receiver functionality or even a lighting feature. Moreover, this central unit can be provided with means enabling a user to be woken up by a voice message giving him current weather observations and forecasts for the day to come. For example, the weather station can be configured so that at a time set by the user, it calls an audiotel-type telephone service, and transfers this call to a speaker to broadcast the message of the audiotel. Another way to realize such a wakeup function may be to integrate in the station a vocoder, that is to say a device for transforming the weather observation and forecast data present in the station into voice messages that can to be broadcast to the user.

  FIG. 3 represents the structure of a message transmitted by a meteorological station according to the invention. This message comprises a first field 40 containing a code representing the type of the message. The OBS code means that it is an observation message. For a station location message, the code used would be LOC.

  The next field (42) is a field representing the encoding format of the message, here 12, so that the server knows which correspondence table to use to decode this message. Field 44 represents the date and time of the observation. The last field (46) represents the observation itself. The data present in this field are defined in advance and depend in particular on the types of sensors present in the station.

  In the example presented here, the message is transmitted by a meteorological station including at least one thermometer, a barometer, an anemometer and a hygrometer.

  Thus, the field 46 has the following elements: the current temperature (24) the minimum temperature of the previous 12 hours (05) the maximum temperature of the previous 12 hours (40) the pressure (1030) the direction and the force of the wind (240) / 20) the percentage of humidity (90).

  This information was measured directly by the sensors at the time of the creation of the message or was stored in memory while waiting to be transmitted, particularly as regards the temperatures in the previous hours.

  Messages received from a remote server may be encoded in the same way or in another form. For example, these messages may consist of a series of concatenated digits representing: a sky code, a precipitation code, a wind direction code, the wind force (in Beaufort), a wind gust code, a temperature, a code reliability, and pressure. In this case, the station has a correspondence table allowing a decoding means present in the central unit to associate each code with its meteorological significance. For example, one can have a table such as Table I below.

  Thus, when the station receives a message containing the value 01 in the field intended to receive the sky code, and the value 02 in the field containing the precipitation code, it will be able to display a pictogram representing a cloud. and a flake. Table I: Code sky Meaning Associated pictogram 00 Clear sky Sun 01 Sky slightly cloudy Cloud 02 Cloudy sky Two clouds Precipitation code Meaning Associated pictogram 00 No precipitation None 01 Rain Drops of water 02 Snow Flake 10

Claims (2)

  1. Portable weather station comprising a central unit (10) and at least one sensor (12) measuring at least one atmospheric parameter and transmitting at least one measurement to the central unit, the central unit having transmission means (14) ) and receiving (16) data forming messages, this data being exchanged with at least one remote server (18) via a cell broadcast network (20), and at least one of the messages transmitted by the station containing meteorological observations from measurements made by the sensor (s).   2. portable weather station according to claim 1 wherein the central unit further comprises: encoding means (24) for creating, at least from measurements collected by the sensor (s) and a correspondence table, observation messages in a predetermined format, these messages being intended to be transmitted to the server by the transmission means (14) and / or - decoding means (26) for decoding, from a correspondence table, messages received from the server via the reception means (16), these messages including observations and weather forecasts. 5. portable weather station according to claim 2 wherein the meteorological observations and forecasts are derived from a database consisting at least partially of data received from meteorological stations of the type of said portable weather station. 6. Portable weather station according to one of the preceding claims wherein the central unit (10) has a memory, in particular for containing a correspondence table. 5. Portable weather station according to one of the preceding claims comprising a SIM card-type smart card (28) for identifying the station in the cellular network. The portable weather station of claim 5 wherein a look-up table is stored in an input of the SIM card (28). 7. Portable weather station according to one of the preceding claims wherein the atmospheric parameters measured by the (s) sensor (s) (12) are included in the group comprising: the outside temperature, the internal temperature, the pressure, the hygrometry, wind speed, wind direction, sunshine, amount of precipitation. 8. Portable weather station according to one of the preceding claims wherein the transmission of measurements between the sensor (s) and the central unit is performed by a link (22) included in the group comprising: a type connection wired, a radio link, for example in the 433 MHz band, and an infrared link. 9. Portable weather station according to one of the preceding claims wherein the central unit (10) is provided with display means, for example a screen (30) of LCD type, for displaying for a user information under alphanumeric characters (32) and / or pictograms (34) .10. Portable weather station according to claim 8 wherein the information displayed by the central unit is comprised in the group comprising: date, time, meteorological observations from measurements made by the sensor (s), and weather forecasts contained in messages sent by the server. 11. Portable weather station according to one of the preceding claims wherein station location data are determined by a user of this station which provides these data to the central unit (10) and / or the server (18). 12. Portable weather station according to one of claims 1 to 10 wherein the station has a geo positioning satellite system, including GPS type. 13. Portable weather station according to one of claims 1 to 10 comprising a SIM card-type smart card, and wherein the geographical location of the station is carried out by GSM triangulation. 14. Portable weather station according to one of claims 11 to 13 wherein one of the messages transmitted by the weather station to the server (18), preferably the first message, is a message containing location data of the station. 15. Portable weather station according to one of the preceding claims wherein the messages consist of a sequence of alphanumeric characters and / or symbols, the number of characters and / or symbols being preferably less than 160, representing in a predetermined format one or more data types comprised in the group consisting of: data (40) representing the type of message, data (42) representing the encoding format, data (44) representing the date and time, and data (46) observation and / or weather forecasts. 16. Portable weather station according to one of the preceding claims wherein the messages transmitted and / or received by the station are SMS type messages. 17. Portable weather station according to one of the preceding claims wherein the central unit exchanges messages with devices of the mobile phone type (50) through the means of transmitting (14) and receiving (16) data. .