EP0136217A1 - Luminous information display unit - Google Patents

Abstract

The present invention relates to a luminous display device for information messages at the sites of public events. According to the invention, the display device (1) comprises an electronic circuit controlled by an impact detector (D) and fixed behind a basketball back-board (2) in order to display on the display system (10) any piece of information when the basketball strikes the basketball back-board. The present invention finds application, in particular, in the displaying of advertising messages in stadia having at least one basketball court. <IMAGE>

Description

The present invention relates to a luminous display device for information messages in places of public events, in particular sporting events such as basketball stadiums.

Luminous display devices are known which are used in basketball stages to visualize the mark between two teams in play and the counting of the duration of the stoppages of play before the end of the game.

However, the location of such display devices, generally in the back of the stadium hall for the brand display device and on the table where the timekeeper is located for the remaining time display device does not always allow players to know where the mark is and how much time they have left to play. The information to the players of this information is very important since the result of a basketball match is often final only at the last second of this match.

The present invention aims to eliminate the above drawbacks by providing a display device immediately informing basketball players of the brand and the time remaining to play. Match.

For this, the invention provides a device for the luminous display of information messages in places of shows and public events, in particular sporting events such as stadiums or the like, the device being characterized in that it comprises at least one generator for coded characters of each message, associated with the display system.

According to a characteristic of the invention, the light display takes place through at least one of the transparent basketball panels.

According to another characteristic of the invention, the light display is triggered each time the basketball enters a predetermined part of space, in particular adjacent to the basketball backboard, for example in the goal area, or each once the balloon cuts a directional wave beam emitted for this purpose and established for example at the entrance to the basket.

According to yet another characteristic of the invention, the display is triggered by each impact of the ball on the basketball backboard.

According to one characteristic of the invention, the coded character generator is a programmable read only memory in which are stored several words with several characters corresponding to the messages displayed.

• La figure 1 est une vue en perspective d'un panneau de basket-ball, du type suspendu, derrière lequel est monté le dispositif d'affichage selon l'invention.
• La figure 2 est un schéma bloc électronique du dispositif d'affichage selon l'invention.
• La figure 3 représente un autre mode de réalisation du dispositif d'affichage selon l'invention.

The device according to the invention is not limited to the display of the mark and of the time remaining to play a basketball match, but also can display advertising messages sequentially. The invention will be better understood and other objects, details, characteristics and advantages thereof will appear more clearly during the explanatory description which follows, made with reference to the appended schematic drawings given solely by way of example illustrating several modes. of the invention, and in which:

• Figure 1 is a perspective view of a basketball panel, of the suspended type, behind which is mounted the display device according to the invention.
• Figure 2 is an electronic block diagram of the display device according to the invention.
• FIG. 3 represents another embodiment of the display device according to the invention.

FIG. 1 shows the display device 1 according to the invention having the shape of a rectangular box situated behind a basketball panel 2, of the suspended type, supporting the basketball basket 3 and made of a rigid transparent material such only plexiglass. The display device 1 comprises, inside the parallelepiped box, an electronic circuit which will be detailed later, and a display system 10 for characters such as letters, numbers, dots, etc. The parallelepiped box is fixed behind the panel 2 so that the display of the characters of the message appears in a rectangle situated substantially above the upper half of the panel 2 and parallel to the upper longitudinal edge of this panel. In addition, the box of the display device is fixed so that the display system is located at a distance for example of about 50 mm preventing any contact during smashing or violent assault on the basket or on the panel. Of course, the display device can be fully integrated into the basketball backboard.

In the present case, the display system consists of a certain number of displays, for example 10, at 35 points, these displays being designated in FIG. 1 by the references 10a to 10d. Each 35-point display is made up of a network of matrix lamps of five columns-seven rows. Of course, the present invention is not limited to the 35-point matrix display system and other display systems, for example of the liquid crystal, luminescent, laser, fiber optic, etc. type. ; can be used.

The electronic circuit located in the parallelepiped box of the display device is connected via cables to a general power supply device of the device located in a geometric position suitable for each basketball event.

In D in FIG. 1 is designated a shock detector connected to the electronic circuit of the display device and whose role will be explained later.

It is understood that by the display device 1 of the invention, it is possible to view through each basketball panel advertising messages, brand information according to the progress of the match, and at the end of each match whenever it is useful the time remaining to play.

The way in which such information is displayed will be explained below after description of the electronic circuit of the display device 1 shown. in figure 2.

Such a circuit includes the shock detector D, the output of which is connected to the input of a monostable circuit M1 having its output Q connected to an AND gate ET1 with two inputs, the second input being connected to a general clock H.

The output of detector D is also connected to the input of another monostable inhibition circuit M2, whose role will be explained below, and having its output Q connected to detector D.

The output Q of the monostable circuit M1 is connected to an input of an AND gate ET2 having its second input connected to the second input of the gate ET1 and therefore to the clock H. The output of the gate ET2 is connected to a divider programmable DV1 which is made in programmable counter connected in divider by the door NAND ND1. The output of the programmable divider DV1, for example in BCD code, is connected to a BCD decoder circuit DC1 generating address signals for example on six outputs. This decoder DC1 is connected by its outputs to a programmable read only memory ME1 wherein multiple words are loaded messages to multiple charac _- ters. The number of these stored message words can for example be equal to 40.

A coded wheel system RC is also connected to the programmable memory ME1 to select in a desired order and determined by the signals from the decoder DC1 the successive call of the corresponding message words stored in the programmable read-only memory ME1 and this automatically or manual by an operator.

ME1 read-only memory generates characters in series of each word of messages to display. The output of this read-only memory is connected via a switch CM1, whose role will be explained later, to a series-parallel conversion circuit CV1. As shown, the CV1 conversion circuit on this line provides the current ASCII code in computer science.

The seven output lines of the converter CV1 are applied to a holding circuit MA1 constituted by seven flip-flops for example of the type D having their outputs connected via inverters IV1 to IV7 to a circuit for decoding a character of the word message to display. This decoding circuit includes five programmable read only memories ME2 to ME6, each of these memories driving on its seven output lines the seven lamps L forming light points of a column of a 35 point matrix. Of course, as is known per se, the display of a character of a matrix will be done, in the present case, by scanning by columns, therefore horizontally and therefore in five execution times. The ROMs ME2 to ME6 are of the type capable of decoding the ASCII code available at the output of the holding circuit MA1.

The output of gate ET1 is connected to a second divider DV2, the output of which is connected via a first NAND input ND2 to the clock input of flip-flops D of the holding circuit MA1.

The programmable read-only memory ME1 simultaneously transmits with each coded character an identification signal of this character, this identification signal appearing via a switch CM2 at the input of a second series-parallel conversion circuit CV2 having four output lines providing a BCD coded signal. The four output lines of the CV2 conversion circuit are connected to a decoder BCD with 16 bits of output and referenced by DC2. As shown in FIG. 2, the 16 output terminals of the DC2 decoder are available and can be connected via jumpers to sixteen other output terminals connected in common to the second input of the NAND gate ND2. It is understood that by placing jumpers appropriately on some of the sixteen terminals opposite, the DC2 decoder identifies the BCD code appearing at the output of the CV2 conversion circuit and corresponding to the character number to be displayed.

It is understood that other circuits comprising circuits identical to circuits MA1, IV1-IV7, ME2-ME6 are connected to the seven output lines of the conversion circuit CV1. Thus, since the display system comprises ten 35-point displays, there will be nine other circuits identical to those mentioned above connected to the outputs of the CV1 conversion circuit. Similarly, there will be nine other decoders identical to the DC2 decoders connected to the four output lines of the CV2 conversion circuit.

FIG. 2 also shows the existence of an alphanumeric keyboard CL delivering signals in ASCII code to a programmable random access memory ME7 also connected to the six output lines of the decoder circuit DC1. The random access memory ME7 generates in series characters coded in ASCII and applied via the switch CM1 to the conversion circuit CV1. The RAM ME7 also generates, simultaneously with each coded character, a binary identification signal applied via the switch CM2 to the input of the conversion circuit CV2.

Note the presence of two display screens EC1 and EC2 respectively used to display the characters being typed on the keyboard CL and the message displayed on the 35-point displays of the display system.

The operation of the display device of the invention already follows in part from the description given above of the electronic circuit and will be briefly explained below with reference to other characteristics of the invention.

The display device of the invention is triggered when the basketball hits the basketball backboard. The shock is detected by the detector D which emits a trigger pulse for the monostable circuit M1. The output of this monostable circuit passes for a determined duration and short in state 1 so as to allow the clock pulses of the clock H to pass through the gates ET1 and ET2. It should be noted that the pulse from detector D also triggers the monostable circuit M2, the output of which goes low, cuts off the supply to detector D, thus preventing detector D from detecting other subsequent shocks likely to disrupt the display of the message.

The programmable divider DV1 divides the clock signals appearing at the output of the gate ET1 and delivers at output a binary signal BCD decoded by the decoder DC1 which emits at each of its outputs an address signal indicative of the order of appearance message words to be displayed, coding wheels RC selecting the message word encoded in the memory ME1 according to the chosen order of appearance of the message words to be displayed. It is understood that instead of using, as shown in FIG. 2, six coding wheels corresponding to the display of the six successive messages, a larger number of coding wheels can be chosen. It will then be necessary to provide a number DC1 decoder output line correspondent.

The characters of each message word coded in ASCII are then applied via the conversion circuit CV1 to the inputs of each of the holding circuits MA1 (10 in number). The programmable divider DV2 dividing the signal appearing at the output of the gate ET2 determines the display time of each of the message words and, via the NAND gate ND2, acts on the clock input of the flip-flops D of each circuit MA1 holding so as to maintain at the output of each of the D flip-flops the logic state applied to the inputs of these flip-flops. The ASCII code 10 of the flip-flops D is then decoded by the memories ME2 to ME6 which attack each of the 35-point matrices to display the characters of the message word coded at the input of each holding circuit MA1. As already explained above, the identification signal accompanying each character and coming from the memory ME1 is applied to the conversion circuit CV2 to be decoded by the decoder DC2 which determines the position of the character on the display of the display system.

The display cycle of advertising messages in the manner described above therefore takes place automatically. It should be noted the presence, at the input of the monostable circuit M1, of a push button BP allowing an operator to act manually on the display cycle of the advertising messages.

The display time of each message can be adjusted by acting, for example, on potentiometer P1 of the monostable circuit M1 from 0.1 to 3 seconds. The duration of the inhibition signal appearing at the output of the monostable circuit M2 can be performed as being at least twice the display time of each message and this via potentiometer P2.

It should be noted that the initiation of the display cycle for advertising messages can be carried out other than by the detection of a shock on the basketball backboard. Thus, it is possible to display advertising messages each time the basketball enters a predetermined portion of space adjacent to the basketball backboard for example in the goal area, and this using a proximity sensor. The light display can also be triggered each time the balloon cuts a directional wave beam emitted for this purpose and established, for example, at the entrance to the basket 3.

It is possible at the request of an advertiser or other requester, to view live an advertising message composed from the keyboard CL and to memorize it in the programmable random access memory ME7. The characters generated by the RAM ME7 can then be given priority, by simple switching of the switches CM1 and CM2, in automatic mode to broadcast and view the words of messages not available in the ROM ME1.

FIG. 2 also shows the presence of an auxiliary input designated by AUX which is intended for information coming from external synchronization sources. Such external synchronization, of the electronic chronometer type used in basketball, may aim to visualize the time remaining to be played in the game. Switching to stopwatch takes precedence, taking priority over any other information in automatic or manual mode. This switching, within the reach of those skilled in the art, must be able to be made from the official brand table. Of course, the code appearing at the auxiliary link must be in ASCII.

On this auxiliary socket, information relating to the provisional mark may be brought at the progress of the match, such information also becoming priority over all other information.

FIG. 3 represents an electronic circuit for the display of advertising messages in a predetermined area of the region of the basketball stadium where the public is located. This display is carried out from lamps or other discrete light elements L, each of the lamps being supported for example by the head of a spectator. The light elements are dispersed in the predetermined area and are arranged so as to form the characters of an advertising message. By way of example, the luminous elements for forming a character of the message are 35 in number with a maximum of ten characters of messages. Of course, it is possible to provide different numbers of message characters provided that an advertising message is visible when the appropriate light elements are excited.

Certain elements of the electronic circuit of FIG. 1 are identical to elements used in the electronic circuit of FIG. 2 and are designated by the same references.

Thus, we find, designated by M1, the monostable circuit M1 triggered by the push button BP which also triggers the monostable circuit M2 whose output Q inhibits any subsequent action of the push button, for example via a contact relay r, during the display of the message word. The output of the monostable circuit M1 is connected to the programmable divider circuit DV1 via the gate ET1 which also receives pulses from the clock H. The divider DV1 supplies, via the decoder DC1, signals of address to the programmable read-only memory ME1 representative of the display order of the message words stored in this memory. Also found, referenced in RC, the coding wheel comprising for example six elements.

During each display cycle triggered by manual action on the push button BP, the memory ME1 delivers in series, on the one hand, the characters of each word of messages to be displayed and, on the other hand, the associated identification signal for each character sent.

A series-parallel conversion circuit CV1 is connected to the output of the memory ME1 on which the characters appear while a conversion circuit CV2 receives from the memory ME1 each identification signal associated with a character.

The serial-parallel conversion circuit CV1 emits at its output on seven lines a coded signal such as ASCII, while the parallel-serial converting circuit CV2 produces at its output the i _den ti- fication encoded in BCD signal (decimal binary code).

The seven output lines of the conversion circuit CV1 are respectively connected to seven generator circuits G1 to G7 of a signal of a determined frequency. The generator G1 delivers a signal of frequency f1 when it receives a high level signal from the output line of the circuit CV1. Similarly, the generators G2 to G7 respectively produce at their outputs signals of frequencies f2 to f7.

The four output lines of the conversion circuit CV2 are respectively connected to four generators G8 to G11 of a determined frequency. The generator G8 produces at its output a signal of frequency f8 when it receives from the corresponding output line of the conversion circuit CV2 a high level signal, the generators G9 to G11 respectively producing at their outputs signals of frequencies f9 at f11.

Of course, when a low level signal appears at one of the inputs of the generators G1 to G11, the generator in question produces no output signal.

These outputs of the generators G1 to G11 are applied to a multiplexer circuit MX1, the output of which is connected to a transmitter device EM. The signals of different frequencies appearing at the output of the multiplexer MX1 modulate, in a manner known per se, a carrier wave, so as to transmit the signals representative of the character code and of the identification signal code of each character by modulation, such as as for example amplitude or frequency modulation.

There is shown, on the right-hand side of FIG. 3, a group of N identical receiving devices each receiving the modulated signal coming from the emitter EM. Each receiving device comprises a signal processing circuit for driving a light element L as will be described below.

In FIG. 3, only one group of receiving devices has been shown, but it is understood that there are as many groups of receiving devices as there are message characters to be displayed. So, for example, each group of receiving devices has a number N of receiving devices equal to 35 (which corresponds to the 35 light elements of a character).

The modulated signals received by each receiving device are applied, via a bandpass filter F to a detection and demodulation circuit DEM which delivers, at its outputs, on the one hand, the signals of determined frequencies defining the code of a character and, on the other hand, the signals of determined frequencies defining the code of the identification signal associated with the character.

Conversion circuits CV3 to CV9 are respectively connected to the seven output lines of the DEM circuit and each convert the received frequency signals into a high level signal, a low level signal being output from the converters not receiving signals. The ASCII code of the character to be displayed is thus found at the output of the converters CV3 to CV9. This coded signal is applied to a decoder DEC by means of a holding circuit MA 'identical to that used in the circuit of FIG. 2 and constituted for example by flip-flops of type D. In the present case, the decoder DEC is an ASCII-35 point decoder, the outputs of which are connected so as to excite the light element L via the drive circuit CA according to the ASCII code appearing at the inputs of the decoder circuit.

Four converters CV10 to CV13 are connected to the outputs of the DEM circuit delivering the identification signal associated with the character to be displayed. Each converter converts the frequency it receives into a high level signal (a low level signal is sent to each converter if no signal of a determined frequency is sent to it). So we find in output of the four conversion circuits CV10-CV13 the identification signal coded in BCD. This coded signal is applied to a decoding circuit constituted for example by a programmable read-only memory ME8, the output of which is connected to a monostable M3 controlling, by means of the clock inputs of the flip-flops D, the holding circuit MA 'and this during a determined duration corresponding to the display time of the light element if excited.

It goes without saying that the read-only memory ME8 is programmed so as to deliver an output signal only when it receives only the coded signal BCD corresponding to the coded character appearing at the inputs of the holding circuit MA '. All the ME8 read-only memories of the group of receiving devices shown in the figure are programmed in the aforementioned manner. For example, assuming that the first character of the word to be displayed is an E, it will appear at the inputs of the holding circuit MA 'and therefore at the inputs of the decoder circuit DEC the ASCII code corresponding to the character E and the coded signal BCD, when identical to the signal coded in ROM ME8, will indicate the number of the character to be displayed, ie character number 1. In addition, the decoders DEC of the receiving devices of each group have their outputs connected differently, for example by means of jumpers, so as to excite the luminous elements of the character to be displayed.

The memories of each of the other groups of the receiving devices are programmed so as to indicate to the holding circuits of the associated decoders the number of the character of the word to be displayed. Of course, under these conditions, each decoder receives the ASCII code of one of the other characters of the word to be displayed.

It is also possible to associate the electronic circuit of FIG. 3 with the keyboard CL and the RAM ME7 shown in FIG. 2 to display live, at the request, for example, of an advertiser, an advertising message.

Of course, the invention is not limited to the arrangement of the circuit described above and other modifications can be made without departing from the scope of the invention. Thus, in the case of the display device on the basketball board, it is possible to fix above this board each display device, normally located at the diagonal corners of the basketball court indicating the time remaining for the players of a team before shooting on goal. This remaining time to shoot can also be displayed on the display device located behind the basketball backboard using a down counter controlled by a clock activated by a referee and the down counter signals can be applied to the AUX auxiliary input in Figure 2.

It is also possible to provide for the recording on te of one or more writing lines to display scrolling advertising messages in FIGS. 2 and 3. Once again, the AUX auxiliary input will be used in this application.

Claims (46)

1. Device for the luminous display of information messages in places of shows and public events, in particular sports such as stadiums or the like, characterized in that it comprises at least one generator (ME1); (CL, ME7) of coded characters of each message and associated with the display system (10). 2. Device according to claim 1, for a stadium comprising at least one basketball court, characterized in that the aforementioned light display takes place through at least one of the transparent basketball panels. 3. Device according to claim 1 or 2, characterized in that the aforementioned light display is triggered each time the basketball enters a predetermined portion of space in particular adjacent to the basketball backboard (2) by example in the goal area. 4. Device according to one of the preceding claims, characterized in that the aforementioned luminous display is triggered each time the basketball cuts a directional wave beam emitted for this purpose, established for example at the level of the basket basket (3) entrance. 5. Device according to one of claims 1 to 3, characterized in that the aforementioned light display is triggered by each impact of the basketball on the basketball board (2). 6. Device according to one of the preceding claims, characterized in that the aforementioned coded character generator is a programmable read only memory (ME1) in which are stored several words with several characters corresponding to the messages to be displayed. 7. Device according to claim 6, characterized in that it comprises a selection circuit (RC, DV1, DC1) connected to the aforementioned memory (ME1) for choosing in a determined order the words to be displayed successively in the display system (10). 8. Device according to claim 7, characterized in that the aforementioned selection circuit comprises at least one coding wheel (RC) selecting the code word to be displayed and a programmable divider (DV1) controlled by a clock (H) and generating signals of addresses indicative of the order of appearance at the output of the memory (ME1) of the coded words to be displayed. 9. Device according to one of the preceding claims, characterized in that the successive display of the message words is carried out automatically by triggering a first monostable circuit (M1) whose output is connected to the input of a door AND (ET1) having its output connected to the aforesaid programmable divider (DV1), the other input of the AND gate (ET1) being connected to the output of the above-mentioned clock (H). 10. Device according to claim 9, characterized in that the aforementioned first monostable circuit (M1) is triggered by a shock detector (D) of the basketball on the basketball board (2). 11. Device according to one of the preceding claims, characterized in that it comprises a push button (BP) for manual triggering of the first monostable circuit (M1). 12. Device according to one of the preceding claims, characterized in that it comprises a second monostable circuit (M2) connected at the output of the above-mentioned shock detector (D) and inhibiting the functioning of the detector for a predetermined time. 13. Device according to one of the preceding claims, characterized in that it comprises a second programmable divider (DV2) connected to the outputs of the above-mentioned first monostable circuit (M1) and of the clock (H) by means of an AND gate (ET2) for determining the display time of each of the aforementioned message words. 14. Device according to one of the preceding claims, characterized in that the aforementioned predetermined inhibition time is greater than the aforementioned display time and is for example equal to twice the latter. 15. Device according to one of the preceding claims, characterized in that the aforementioned generator (ME1) also produces, simultaneously with each coded character, a character identification signal. 16. Device according to one of the preceding claims, characterized in that each coded character of the generator (ME1) is decoded by a read-only memory decoding circuit (ME2), (ME3), (ME4), (ME5), ( ME6) attacking the display system (10). 17. Device according to one of the preceding claims, characterized in that each coded character is applied to the above-mentioned decoding circuit by means of a holding circuit (MA1) also receiving the output of the second programmable divider (DV2) and the identification signal of said character. 18. Device according to one of the preceding claims, characterized in that the coded characters of the generator (ME1) and the identification signal of each character are transmitted in series. 19. Device according to one of the preceding claims, characterized in that the coded characters sent in series from the generator (ME1) are applied to each holding circuit (MA1) via a series-parallel conversion circuit ( CV1). 20. Device according to one of the preceding claims, characterized in that each identification signal of each of the coded characters is applied via a series-parallel conversion circuit (CV2) to several decoder circuits (DC2) each connected to each holding circuit (MA1) via a NAND gate (ND2) also receiving the output of the aforementioned second programmable divider (DV2). 21. Device according to one of the preceding claims, characterized in that the aforementioned light display system (10) consists of several matrices (10a-10j) with 35 light points. 22. Device according to one of the preceding claims, characterized in that the aforementioned read-only memories of each aforementioned decoding circuit are five in number and each attack seven light points of a column of a said matrix. 23. Device according to one of the preceding claims, characterized in that each aforementioned holding circuit (MA1) consists of flip-flops of type D whose clock inputs are connected to the output of the aforementioned NAND gate. 24. Device according to one of the preceding claims, characterized in that it comprises a second generator (CL); (ME7) of coded characters constituted by a random access memory (ME7) associated with a keyboard (CL) to compose and display directly a word of messages to the display system (10). 25. Device according to one of the preceding claims, characterized in that the aforementioned random access memory of the second generator is connected in parallel to the aforementioned generator (ME1). 26. Device according to one of the preceding claims, characterized in that it comprises an auxiliary input (AUX) capable of receiving information relating to the mark and to the time remaining to play in the basketball match. 27. Device according to claim 1, characterized in that the aforementioned light display takes place in a predetermined area of the region of the stadium where the public is located by means of discrete light elements (L) each of which is supported by the head of a spectator. 28. Device according to claim 1 or 27, characterized in that the coded character generator is a programmable read only memory (ME1) in which are stored several words with several characters corresponding to the messages to be displayed. 29. Device according to one of claims 1, 27 and 28, characterized in that it comprises a selection circuit (RC), (DV1), (DC1) connected to the read-only memory (ME1) above to choose according to a order determined the words to be displayed successively. 30. Device according to claim 29, characterized in that the aforementioned selection circuit comprises at least one coding wheel (RC) selecting the code word to be displayed and a programmable divider (DV1), controlled by a clock (H) and generating address signals indicative of the order of appearance at the output of the memory of the coded words to be displayed. 31. Device according to one of claims 1, 27 to 30, characterized in that the successive display of the message words is carried out automatically by triggering a first monostable circuit (M1) whose output is connected to the input an AND gate (ET1) having its output connected to the aforesaid programmable divider (DV1), the other input of the AND gate (ET1) being connected to the output of the above-mentioned clock (H). 32. Device according to one of claims 1, 27 to 31, characterized in that it comprises a push button (BP) for manual triggering of the aforementioned first monostable circuit (M1). 33. Device according to one of claims 1, 27 to 32, characterized in that it comprises a second monostable circuit (M2) triggered by the aforementioned push button (BP) and inhibiting any subsequent manual action of this push button during the display of each of the message words. 34. Device according to one of claims 1, 27 to 33, characterized in that the generator (ME1) also produces, simultaneously, with each character a character identification signal. 35. Device according to one of claims 1, 27 to 34, characterized in that each word of messages and the identification signal associated with each character coded word are transmitted by air or over the air and received by several groups of receiving devices, each of the groups of receiving devices receiving a character of the message word and the identification signal associated with this character and exciting some of the light elements (L ) to view the character of the message word. 36. Device according to one of claims 1, 27 to 35, characterized in that two series-parallel conversion circuits (CV1); (CV2) are connected at the output of the aforementioned generator (ME1) and respectively deliver on their output lines the code of each character of the word to be displayed and the code of the identification signal associated with each character, each of the output lines of the two series-parallel conversion circuits being connected to a circuit (G1-G10) generating a frequency determined according to the output level of the associated line, the frequencies of said generators being different from each other. 37. Device according to one of claims 1, 27 to 36, characterized in that the outputs of the above generators are connected to a multiplexer (MX1) whose output is connected to a transmitter device (EM) for the transmission by modulation of signals of determined frequencies applied to the multiplexer. 38. Device according to one of claims 1, 27 to 37, characterized in that each of the receiving devices of each group of receiving devices comprises a detection and demodulation circuit (DEM) delivering the signals of determined frequencies corresponding to the character to display and the associated identification signal. 39. Device according to claim 38, characterized in that each of the output lines of the above-mentioned detection and demodulation circuit (DEM) is connected to a conversion circuit (CV3); (CV4); (CV5); (CV6); (CV7); (CV8); (CV9); (CV10); (CV11); (CV12); (CV13) of the determined frequency appearing there in a logical level. 40. Device according to one of claims 1, 27 to 39, characterized in that the output lines on which the character code appears are connected to a decoder circuit (DC3) attacking, by means of a circuit d 'attack (CA), a luminous display element. 41. Device according to claim 40, characterized in that between the above-mentioned decoder circuit (DC3) and the conversion circuits (CV3-CV9) is interposed a holding circuit (MA ') constituted for example by flip-flops of the type ( D), said holding circuit being controlled by the coded identification signal of the character appearing at the outputs of the converters (CV10-CV13). 42. Device according to claim 41, characterized in that the aforementioned coded identification signal is applied to a programmable read-only memory whose output is connected to a monostable circuit (M3) controlling the above-mentioned holding circuit (MA '). 43. Device according to claim 42, characterized in that the aforesaid monostable circuit (M3) is connected to the clock inputs of the flip-flops (D) of the aforementioned holding circuit (MA '). 44. Device according to one of claims 1, 27 to 43, characterized in that the aforementioned display light elements (L) of each character are at number of 35, each group of receiving devices thus comprising 35 receiving devices. 45. Device according to one of claims 1, 27 to 44, characterized in that the groups of aforementioned receiving devices are 10 in number. 46. Device according to one of the preceding claims, characterized in that the code of each character is in (ASCII) and in that the code of each identification signal is in (BCD).

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