WO1999031831A1 - Method for electromagnetic transmission of coded meterological data and device comprising an electromagnetic receiver for receiving said coded meterological data - Google Patents

Abstract

The invention concerns a method for transmitting coded meteorological data which consists in transmitting, every twenty-four hours, a plurality of time codes each providing in coded form a different real time and in transmitting within this interval a plurality of meteorological codes each defining meteorological data of a given geographical region among a plurality of different corresponding regions. In particular, each meteorological code is associated with a predetermined time code whereof at least one part defines at least partially said meteorological addressing code or identification code. The invention also concerns a device comprising an electromagnetic receiver and arranged for receiving and processing time codes and meteorological codes concerning several geographical regions and for displaying at least partially meteorological data contained in said meteorological codes. The coded meteorological data being addressed by using time codes which define at least partially the addressing codes of the meteorological codes.

Description

 ELECTROMAGNETIC TRANSMISSION METHOD OF

ENCODED METEOROLOGICAL DATA AND DEVICE INCLUDING

AN ELECTROMAGNETIC RECEIVER FOR RECEIVING

THESE ENCODED METEOROLOGICAL DATA

The present invention relates to a method of electromagnetic transmission of coded meteorological data. It also relates to a device comprising an electromagnetic receiver and a coded data decoding circuit defining in particular weather codes, this device comprising means for displaying meteorological information.

Knowledge of weather information is generally appreciated by the public. This information can be known by means of daily newspapers and also by means of the telephone, of a computer having a telephone link with an information network, by radio or television. However, it may be interesting to know the meteorological data of several regions, or even of several countries, using an electronic device provided for this purpose. For personal use, such a device is preferably portable.

Although meteorological information can be obtained using portable telephones, it will be noted that these telephones are relatively expensive and bulky and that in addition it is necessary to know the telephone numbers making it possible to obtain the desired meteorological data. To find out the weather conditions in several regions which can extend over several countries, the use of a mobile phone is expensive and relatively complex since it is necessary to establish various communications with regional meteorological information centers or national. It can thus be seen that the use of a mobile telephone is not particularly easy for obtaining meteorological data and that it is more expensive. It will also be noted that in the case of a Communication with an information center covering, for example, several regions of the same country, the user must generally listen to information concerning several regions before obtaining specific information for a specific region.

It will also be noted that the average user is used to receiving meteorological information in visual form, which a mobile phone generally does not allow. An object of the present invention is to provide a method of electromagnetic transmission of encoded meteorological data which can be received and decoded by devices provided for this purpose, in particular portable electronic devices. Another object of the invention is to provide an electronic device provided with a receiver and means for decoding coded meteorological data transmitted by a transmitter provided for this purpose according to the transmission method of the present invention. The device according to the present invention can be of various nature. For example, this device is an integral part of a wristwatch, a table clock or a pendulum. This device can also be an integral part of a large panel that can be arranged in a station, a store or in any public place, in particular to attract customers or for advertising purposes.

In the case of portable devices, it will be noted that it is generally desirable to reduce consumption as much as possible. In the case of a device arranged to receive meteorological data from several different regions and also for different time periods, reducing the energy consumption without limiting the scope of the intended application is a problem that the present invention also proposes to solve.

The present invention firstly relates to a method of electromagnetic emission of meteorological data coded codes consisting in transmitting, by twenty-four hour period, a first plurality of time codes each giving a different time and in transmitting, by twenty-four hour period, a second plurality of weather codes defining meteorological data of a third plurality of different geographic regions, each weather code of said second plurality being associated with a time code of said first plurality at least part of which, comprising at least partially the coded time, at least partially defines an address code and / or identification of said each weather code.

Several advantages result from the transmission method according to the present invention. First, the fact of jointly issuing time codes and weather codes makes the transmitter multi-functional and allows the device according to the present invention to also be multi-functional, that is to say to be able to display the precise time given by the transmitter and meteorological data also transmitted by this transmitter. Secondly, the fact of using at least part of a predetermined time code as the addressing and / or identification code of a determined weather code makes it possible to reduce the total number of binary pulses to be supplied for the reception of time codes and weather codes for different geographic regions.

A third very important advantage of the present invention follows from the fact that a determined weather code is associated with a predetermined time code which at least partially defines an address and / or identification code for this weather code.

By weather code is understood a set of coded meteorological data forming a weather report for a single predefined geographic region or a set of given geographic regions associated in a natural and predefined manner. To specify whether the weather report is partial or complete, it can be mentioned that the weather code is partial or complete. According to a particular characteristic of the method according to the invention described above, it is expected that a single weather code of said second plurality is transmitted between two successive time codes of said first plurality. Preferably, each weather code of said second plurality is associated with the time code of said first plurality which precedes or follows it in the succession of codes transmitted.

It results in particular from this preferred mode of implementation a determined temporal distribution of the various weather codes whose emission is planned. Thus, by providing means for selecting any particular geographic region, from a plurality of given geographic regions, in the devices intended to receive the weather codes transmitted according to the method of the present invention and also by providing an internal clock to the Within these devices, it is possible to activate these devices only within limited time intervals within which the weather code, corresponding to a selected geographic region, is issued. The associated time code can also be received in this time interval. This time code can be used for radio synchronization of the internal clock provided in each of these devices. Several variants are possible for the emission of weather codes. According to the invention, it is necessary for a predetermined weather code to be transmitted substantially at a predefined given time. In addition, each code must have a unique addressing code. Thus, provision can be made to supply within an elementary period, defined by the emission of two different successive time codes, either a single partial or complete weather code, or several partial or complete weather codes in a predefined order. In the latter case, the receiving device is provided with means for isolating each weather code and determining its position of emission among the emission of said several weather codes in said elementary period and / or bits are provided. address in each weather code used to form, together with the associated time code, the address code of each weather code. Two addressing bits are sufficient for the transmission of four weather codes per elementary period.

For example, the emission of a specific weather code and a time code associated with it by means of a low-frequency, high-power transmitter, making it possible to cover a very large geographic region, may occur. within a time interval of approximately one minute starting at a specific time corresponding substantially to the time coded in the time code received in this time interval.

By providing in particular for a double transmission allowing a check of the good reception of the weather codes, the time interval of activation will be for example about two minutes. Thus, by planning for example to transmit meteorological data for thirty different geographic regions, it is possible in the latter case to send meteorological data for a particular geographic region every hour. Thus, the receiving device will need to be activated every hour only about one minute or two minutes as appropriate. This makes it possible to considerably reduce the electrical energy consumption of a portable device used for the reception and display of meteorological data supplied by a transmitter emitting according to the method of the present invention. In addition, it is possible to plan to renew the weather reports only every three or six hours. However, in the event of poor reception, the receiver is preferably switched on again the following hour.

According to a practice in force in the transmission of time codes by a high power antenna operating at low frequency, the time codes are transmitted successively with a determined frequency defining a constant period. Binary pulses defining time codes are sent for example to the frequency of 1 Hz. This situation is notably that of the HBG transmitter located in Prangins in Switzerland and the DCF transmitter located in Mainflingen in Germany.

In particular for the two above-mentioned transmitters, a time code is transmitted every minute. A complete time code including the actual time, the date, the day of the week and the information relating to summer time requires a transmission time not exceeding 45 seconds at a rate of 1 bit per second. In this case, there is at least 15 seconds of emission per minute that can be attributed to the emission of a weather code outside the period of emission of the time code. It is possible to transmit in a specific format approximately 4 bits per second in addition to the top second provided with a frequency of 10 Hz. Thus, these are approximately 60 bits in a NRZ format

(No Return to Zero) which can be assigned per minute to a given weather code. The emission of a weather code under the aforementioned conditions does not disturb the reception of the time codes by usual receivers. One can thus understand a particular advantage of the present invention where it is planned to use at least part of the time code to form the addressing code of a weather code associated with this time code. The resulting saving in bits increases the amount of weather data transmitted. In particular, it is thus possible to transmit meteorological data within a given meteorological code which relates, for a determined geographic region, to several different time periods. This refines the information given and also provides short and medium term forecasts. A single partial or complete weather code is preferably issued between two successive time codes.

A second object of the present invention relates to a device comprising: an electromagnetic receiver, a coded data decoding circuit defining weather codes and time codes, a weather memory comprising a first plurality of zones respectively assigned to a second plurality of geographical regions, an addressing circuit arranged to assign each received weather code, from a third plurality of weather codes capable of being received by said receiver and be decoded by said decoding circuit, to a respective area of said weather memory.

In this device, each weather code of said third plurality is associated with a time code of a fourth plurality of time codes comprising at least the coded time and capable of being received by said receiver and of being decoded by said circuit. decoding, at least part of each time code associated with a weather code of said third plurality at least partially defining an address code for this weather code which is supplied to said addressing circuit, the latter affecting each weather code of said third plurality to a respective area of said weather memory as a function of the address code associated therewith, this address code at least partially comprising said coded time.

In a preferred embodiment, each weather code of said third plurality is associated with the time code of said fourth plurality which precedes or follows it in the succession of codes received by said device.

According to a particular characteristic, each zone of said meteorological memory is subdivided into several parts intended to store meteorological data for several respective different time periods.

According to another particular characteristic of the device according to the invention, said different time periods concerned by a weather code of said third plurality depends on the time of reception of the time code associated therewith. o

In particular, the device according to the invention is associated with a radio-synchronized clockwork movement and comprises means for displaying time data and meteorological data. The present invention will also be explained with the aid of the following description made with reference to the appended drawings, given by way of non-limiting example, in which: FIG. 1 schematically shows an installation allowing the implementation of the emission method according to the invention and a receiving device according to the invention; Figure 2 schematically shows in somewhat more detail a receiving device according to the invention; FIG. 3 schematically represents the partial arrangement of the weather memory of the device of FIG. 2; FIG. 4 schematically represents a possible binary coding used for the transmission of meteorological data coded by the installation represented in FIG. 1; FIG. 5 schematically represents a watch forming a device for receiving meteorological data coded according to the invention, and FIG. 6 represents a panel of large dimensions also defining a device for receiving meteorological data coded according to the invention.

In FIG. 1, the transmission installation for implementing the transmission method according to the invention comprises a transmitter 2 formed by an electrical control 4 and an electromagnetic antenna 6. The electrical control 4 of 1 'antenna 2 is electrically connected to a control center 8, for example the Cantonal Observatory of Neuchâtel, which maintains atomic clocks 10 making it possible to very precisely determine the passage of time. These clocks are known to those skilled in the art. The control center 8 transmits to the electric control 4 the time data and other data necessary for the emission of complete time codes, that is to say giving in a coded manner the minute, the hour, the date, the day, the month and the year. In addition, the transmitter transmits binary pulses at the frequency of 1 Hz in synchronization with the atomic clock (s) 10. In addition, there are normally provided in each time code information bits for summer time. Control bits can also be provided. The pulse marking the start of each second corresponds to an interruption of the carrier wave for 0.1 or 0.2 seconds. A double interruption marks the start of a minute, i.e. a low carrier level of 0.1 seconds followed by a high level with an equivalent duration and a second low level with an equivalent duration . In the case of the Prangins transmitter in Switzerland, the carrier frequency is 75 kHz and the nominal power is 20 kW. It will be noted that, apart from a few particulars, the transmitter in Mainflingen in Germany operates in substantially the same way for the transmission of the time codes used for the radio synchronization of devices provided for this purpose. For the latter transmitter, the start of a minute is marked by the absence of a top second to the previous second. The above-mentioned two variants can be combined without further ado for the start of the minute signal, which is defined by a missing time signal followed by a double interruption of the carrier wave.

The time code is therefore formed by a succession of binary pulses emitted at the frequency of 1 Hz. To do this, the pulse giving the start of each second is used. An interruption in the carrier frequency, defining a low level of the modulated signal transmitted, defines a bit "0" when the duration of the low level is substantially 0.1 seconds, while the value of the bit is at "1" when this low level lasts approximately 0.2 seconds.

The range of the above-mentioned transmitter is around 500 km by day and around 3,000 km by night. A full time code is issued every minute and takes about 45 seconds to transmit. There is therefore approximately 15 seconds for the transmission of other data. According to the invention, it is planned to transmit meteorological data in addition to the time codes provided by the transmitter 2. Given the extended range of the transmitter 2 and to make the application more attractive, it is provided according to the invention to send a plurality of weather codes corresponding to the weather forecasts for a plurality of respective different geographic regions. For Switzerland for example, it is possible to subdivide the country into 5 or 6 different regions for which a specific weather report can be provided. To do this, the control center 8 receives meteorological information from various centers or institutes, for example from the Swiss Meteorological Institute (12), Météo France (14) and also from other meteorological data providers (16). . In Figure 1 is also shown schematically a device 20 according to the invention. The device 20 comprises an electromagnetic wave receiver 22 arranged to receive the time and weather codes transmitted by the transmitter 2. The electromagnetic signals received by the receiver 22 are supplied in the form of electrical pulses to a processing unit 24, which is used in particular for decoding time codes and weather codes received by the receiver 22. The unit 24 transmits to a clock register 26 at least partially each time code received comprising new information and transmits to a weather memory at least partially the content of weather codes received from a plurality of weather codes corresponding to a plurality of different geographic regions.

Note that it is also possible to enter data from the time codes or deduced from these time codes into the weather memory, in particular the date (s) concerned by the meteorological information received. Note also that it is possible to provide for two successive transmissions of the same weather code so as to allow a check of the correct reception of said weather code before the meteorological data included in this code are compared with the corresponding meteorological data from the weather memory and / or entered in this memory weather.

With the aid of FIG. 2, an embodiment of the device according to the invention will be described schematically. This device comprises a receiver 22, a decoding circuit (decoder) 32, which receives in the form of electrical signals electromagnetic signals picked up by the receiver 22. In particular, the electromagnetic signals are amplitude modulated. The decoder is arranged to process the electrical signals received and provide bit sequences defining either a weather code 34 or a time code 36. Each specific weather code received is intended to be stored in an area 38.1 to 38.5 of the weather memory 28 (fig. 1). To do this, an addressing circuit 40 is provided, which is arranged to receive at least part of a specific time code associated with a respective weather code received by the device. This part of the time code at least partially includes the coded time and at least partially defines an address code for said respective weather code.

There is therefore a correlation between each weather code received and a predetermined time code associated with it. This makes it possible to reduce the number of binary pulses necessary for the reception and processing of the weather codes and time codes received. In addition, as already mentioned, each specific weather code is associated with a predetermined time code, which is transmitted substantially at the time corresponding to the time coded in this time code. Therefore, it is possible to precisely determine the time of emission of each weather code, which makes it possible to activate the receiving device only within a limited time interval to receive a particular weather code. Outside this interval In time, it is possible to deactivate the receiving device so as to minimize the electrical energy consumption of the device.

In a preferred embodiment of the device according to the invention, there is provided in this device an electronic clock radio-controlled by means of the time codes received by the receiver 22 and used for addressing the weather codes. This radio-controlled electronic clock includes an internal time base used to select the time interval for activating the receiving device. Preferably, the device according to the invention comprises means for displaying the information contained in the time code. However, in an alternative embodiment, it is possible that these display means are not provided.

The plurality of zones 38.1 to 38.5 of the weather memory are intended to receive the weather data from several different respective regions. It is possible to provide as many zones as different weather codes capable of being received by the device according to the invention. However, in a variant, it is possible to provide fewer zones than the different geographic regions concerned. In the latter case, means are provided for assigning a plurality of different geographic regions selected to the plurality of areas provided in the weather memory. Those skilled in the art can make the addressing circuit 40 and the weather memory in several ways depending on the intended use of the weather data likely to be received by the device according to the invention.

In a preferred embodiment, provision is made to subdivide each zone 38.1 to 38.5 of the weather memory into several parts 42.1 to 42.6 (FIG. 3) intended to receive meteorological data for several different time periods. This makes it possible to give relatively fine weather reports for each of the several defined geographical regions. It is thus possible to store in each zone a bulletin complete weather forecast with short and medium term forecasts. This complete bulletin can be the subject of a single weather code defining a continuous sequence of bits or be the subject of several weather codes relating to several respective time periods. Again, the skilled person has several possible embodiments. It is in particular possible to assign each part 42.1 to 42.6 of each zone X to as many predefined time periods. For example, period 1 is assigned to the data concerning the morning, period 2 to the data concerning the afternoon, period 3 to the data concerning the night, period 4 to the data concerning the following day and the period 5 to the data concerning the day after tomorrow. Part 42.6 can be assigned to a period 6 covering at least partially periods 1 to 5 and containing general information for a given geographic region.

It is also possible to predict that the time periods concerned by a received weather code depend on the time of reception of this weather code. Thus, for example, when the weather code is received between 6 a.m. and 8 p.m., periods 1 and 2 concern the morning and afternoon of the same day. On the other hand, when the weather code is received between 8 p.m. and 12 p.m., periods 1 and 2 relate respectively to the morning and the afternoon of the following day. It is also possible to vary the different periods concerned by the weather code as a function of the time of reception of this weather code or more particularly of the time of reception of the time code associated therewith, these two codes preferably being transmitted one after the other. By again using the time code associated with the weather code, it is possible to store together with the weather data the time periods concerned respectively assigned to parts 42.1 to 42.6 of each zone X as a function of the coded time.

According to the number of predefined geographic regions for the emission of weather reports respective, each of these bulletins can be renewed with a given frequency. For example, a renewal can take place every hour or every three hours. It is possible to plan more or less renewals. In order to minimize the consumption of electrical energy, the frequency of renewal per 24 hours will be rather low. On the other hand, for a precise information purpose and in particular to decrease the time of reception of a weather report concerning a geographical region newly selected by a user, the frequency of renewal will be rather high.

It will be noted that each of the parts 42.1 to 42.6 may include a sub-part used to record the time period concerned by the meteorological data stored in this part. On the other hand, in the case where a given part is assigned to a fixed predetermined time period, only the arrangement of a memory in which the successive predefined time periods concerned by a received weather code are recorded is sufficient for the correct operation of the various meteorological data received.

In Figure 4 is shown schematically the form of a coded signal received by the device and used to define the weather codes. As mentioned previously, the high-frequency low-power transmitters used for the radio synchronization of radio-controlled clock movements generally send a pulse 46 marking the start of each new second (with the exception of the top second +59 in a mode of given achievement). With this type of transmitter, it is possible to modulate the carrier wave with a frequency of approximately 10 Hz over an elementary half-period between two time pulses, namely one second in the present case. By using an NRZ code, it is possible for example to define 4 bits 48.1 to 48.4 between 0.1 and 0.5 seconds after the rising edge of each pulse 46, that is to say it is possible to transmit 4 bits by second for data weather in the time intervals between the transmissions of the seconds seconds. In a more sophisticated embodiment, it is possible to envisage the emission of binary pulses partially defining a weather code within the periods reserved for the emission of time codes.

The pulses 46 define start bits for the next 4 weather bits and allow the receiver to synchronize with the coded signal received to ensure correct reading. Each weather code can have one or more initial pulses defining the start of this weather code for the receiver. This weather code start signal preferably corresponds to the minute signal of the time code. However, this weather code start signal does not necessarily belong to the time code according to other modes of implementing the method according to the invention, in particular in the absence of radio synchronization of the time. However in the latter case, the clock must have an accuracy of half a period of the frequency of emission of the weather codes.

It will be noted here that a person skilled in the art can make the best possible use, within technological limits, of the time space outside the periods strictly reserved for the binary pulses defining the scheduled time codes. The technological limits are given in particular by the transmitter, in particular by the nominal power of emission and by the frequency of emission. Technological limits are also given by the receiving devices. Obviously, at least some of these technological limits change in conjunction with technological development.

In Figures 5 and 6 are shown two different embodiments of a device according to the invention. In FIG. 5, the device according to the invention is integrated in a wristwatch 50. This watch comprises analog or digital means for indicating the time, which is radio-synchronized by means of the received hour codes. Means are also provided display of various weather data contained in the weather codes received.

These meteorological data, defining the weather reports for specific geographic regions, include in particular the sunshine or cloud cover, the amount of precipitation, the direction of the wind and its strength, the minimum and maximum temperatures expected over a given time period. Optionally, the risk of thunderstorms, the rain / snow limit, the 0 ° C isotherm, the pressure trend, etc. will also be given. Depending on the receiving device, it is possible to provide for displaying only part of the set of meteorological data included in the weather codes issued. In the case of wristwatch 50, it is planned to display cloudiness, precipitation (not shown), wind direction and strength, as well as the maximum temperature (18 °) expected. In addition, it is planned to display the date and the time period concerned by this meteorological data, as well as the geographic region concerned, this latter indication being provided in coded form (in the example of FIG. 5: CH-4 for Ticino in Switzerland). Watch 50 includes two pushers 52 and 54 and a crown 56 defining actuation means which allow the user to manually perform various operations.

The actuation means make it possible to preselect a geographic region or a limited number of geographic regions from the plurality of geographic regions covered by the issuance of weather codes. Then, these actuation means make it possible to select a specific geographic region and, where appropriate, a given time period for the display of meteorological data that can be displayed. Note that the date concerned by the meteorological information displayed comes from the time codes which include the time, day, month and year at the time of the time code emission. This information can be used in relation to the various predefined time periods to allow the display of the date concerned by the weather forecasts, in particular those concerning the next day and the day after the day of reception of a weather code.

In FIG. 6, the device according to the invention forms a large-scale panel giving for the morning and the afternoon certain meteorological information, namely cloudiness, precipitation, wind direction and strength, as well as the maximum temperature expected in each of these two time periods. In addition, the date of the weather forecast is displayed. Of course, it is also possible to display the radio synchronized time as well as other information. Among this other information, there may be messages of non-reception or incorrect reception of time codes and weather codes. In addition, it is possible to provide alarm messages stating that the bulletin displayed concerns the past. It is also possible to display the time of the next renewal of a given weather report by announcing the time at which the corresponding weather code will be received. If a new geographic region is selected, it is possible to plan to display the time at which the next relevant weather code will be received, issued by a transmitter whose device receives electromagnetic signals. It is also possible to provide means which can be actuated manually by a user to deactivate the mode for receiving meteorological data. Likewise, such means can be provided to deactivate the reception of the time codes used for radio synchronization, in particular when the device according to the invention is outside the range of action of a transmitter from which it is capable of receiving. correctly coded information. Any means of managing a multi-function watch known to a person skilled in the art can be used for the production of devices according to the present invention. A person skilled in the art knows in particular how to use various types of displays in a timepiece. It also knows several arrangements for the management and display of various information.

Claims

1. A method of electromagnetic transmission of coded meteorological data consisting in transmitting, by 24-hour periods, a first plurality of time codes each giving a different coded time corresponding substantially to real time and in transmitting, by 24-hour period, a second plurality of weather codes defining meteorological data from a third plurality of different geographic regions, each weather code of said second plurality being associated with a time code of said first plurality at least part of which includes at least partially the coded time, at least partially defines an address and / or identification code for said each weather code.

2. Method according to claim 1, characterized in that a single complete weather code of said second plurality is transmitted between two successive time codes of said first plurality.

3. Method according to claim 2, characterized in that each weather code of said second plurality is associated with the time code of said first plurality which precedes or succeeds it.

4. Method according to one of the preceding claims, characterized in that said first plurality of time codes is also used for radio synchronization of electronic watch movements.

5. Method according to one of the preceding claims, characterized in that said time codes of said first plurality are transmitted successively with a first determined frequency defining a constant period.

6. Method according to claim 5, characterized in that each weather code of said second plurality is transmitted a second time before the emission of a next weather code of said second plurality and before the emission of the next time code of said first plurality of so as to allow control of the correct reception of each weather code of said second plurality.

7. Method according to claim 5, characterized in that said constant period is 1 minute, each of said time codes being formed of a series of binary pulses consisting of a modulation of a carrier wave, this series of binary pulses occurring at a frequency of 1 Hz.

8. Method according to one of the preceding claims, characterized in that said coded meteorological data defined by each weather code of said second plurality relates to several different time periods, these time periods being associated with different sequences of binary pulses of said each weather code .

9. Method according to claim 8, characterized in that the time of emission of said time code associated with a determined weather code defines said different time periods concerned by this transmitted weather code.

10. Method according to one of the preceding claims, characterized in that the time code also includes the date of the day of issue in coded form, this information of the date of the day of issue being used to provide the date or dates ( s) concerned by the meteorological data transmitted.

11. Device (20) comprising: an electromagnetic receiver (22), a decoding circuit (32) of coded data defining weather codes (34) and time codes (36), a weather memory (28) comprising a first plurality zones (38.1 to 38-5) respectively assigned to a second plurality of geographic regions, an addressing circuit (40) arranged to assign each received weather code, from a third plurality of weather codes capable of being received by said receiver and to be decoded by said decoding circuit, to a respective zone of said weather memory, each weather code of said third plurality being associated with a time code of a fourth plurality of time codes comprising at least the coded time and capable of to be received by said receiver (22) and to be decoded by said decoding circuit (32), at least part of each time code associated with a weather code of said third plurality at least partially defining an address code for this weather code which is supplied to said addressing circuit, the latter assigning each weather code of said third plurality to a respective area of said weather memory as a function of said addressing code which is associated with it, this addressing code comprising at at least partially said coded time.

12. Device according to claim 11, characterized in that a single weather code is received between two successive time codes, and in that each weather code of said third plurality is associated with the time code of said fourth plurality which precedes it or the succeeds.

13. Device according to claim 11 or 12, characterized in that it further comprises an electronic clock radio-controlled by means of said time codes of said fourth plurality received by this device.

14. Device according to one of claims 11 to 13, characterized in that each zone of said weather memory (28) is subdivided into several parts (42.1 to 42.6) intended to store meteorological data for several different time periods.

15. Device according to claim 14, characterized in that said different time periods concerned by a weather code of said third plurality depends on the time of reception of the time code associated therewith.

16. Device according to claim 15, characterized in that it comprises a memory in which successive time periods are recorded concerned by a weather code received as a function of the time of reception of the associated time code, each of said several parts of said weather memory having a sub-part used to record the time period concerned by the meteorological data stored in this part or being assigned to a single predetermined time period.

17. Device according to one of claims 14 to

16, characterized in that means are provided for displaying the date or dates concerned with the meteorological data recorded in any zone of said meteorological memory.

18. Device according to one of claims 11 to

17, characterized in that it is associated or integrated in a timepiece, in particular a wristwatch, comprising means for displaying time data and means for displaying weather data.