FR2800500A1 - Rotating light emitting diode graphic or image display having rotating disc with radial LED networks having diodes and central card providing command signals and electrical power - Google Patents

Abstract

The image display has a rotating disc (102) with radial LED networks (103-106) each network with a number of diodes (107-110). A central card (120) provides LED command signals and electrical power. A coder provides transparent and opaque sections. An origin detector (123) detects an origin bar.

Description

 The present invention relates generally to an image display system using electroluminescent elements, and more particularly to a visual display system. in which a one-dimensional array of electroluminescent elements is rotated while the elements are illuminated / extinguished in accordance with a predetermined illumination / extinguishing program so as to display various characters or graphical elements on a plane.

Conventionally, image display devices have been proposed in which a one-dimensional array of electroluminescent elements is rotated while they are lit / extinguished so as to display images such as characters or graphic elements. .

Such a conventional image display device is disclosed in Japanese Patent Publication Laid-open No. Heisei 6-214509 (filed Aug. 10, 1992) and shown in Figure 1 herein. Referring to FIG. 1, it is noted that a signal lamp unit comprises a rotating substrate 1, a multiplicity of light-emitting diodes 2 arranged in a straight line on the outer end portion of the rotating substrate 1, parallel to an axis 4, a movable proximity switch element 7 and a fixed proximity switch element 11 arranged face to face for detecting a rotational position of the rotating substrate 1, and means for illuminating / extinguishing light-emitting diodes 2 in accordance with FIG. at a multiplicity of time sequences whenever the movable proximity switch element 7 and the fixed proximity switch element 11 are arranged face to face, thereby forming characters, graphic elements, etc., on a rotational path of the rotating substrate 1. In the signal lamp unit having the structure mentioned above, the substrate 1 is coupled to a frame supported by the axis of rotation 4, and the light-emitting diodes are disposed on the outer end portion of the rotating substrate 1 are rotated about the axis of rotation 4. Whenever the Mobile proximity switch element 7 disposed at the lower end of the rotating substrate 1 faces the stationary proximity switch element 11 placed on the pedestal, a microcomputer 10 illuminates / extinguishes, or The LEDs 2 are flashed according to a multiplicity of time sequences, so as to form characters of the graphic elements, etc.

Another conventional image display device disclosed in U.S. No. 5,818,401 (filed Apr. 18, 1996) is shown in Figures 2a to 2c herein. Referring to Figures 2a to 2c, it is noted that the display device comprises a pedestal 10 having a vertical shaft with two bearings mounted thereon, a cylindrical display body 20 rotatably mounted on the pedestal 10, a plurality of light-emitting diodes 11-18 disposed on the outer wall of the display body 20 to display information when the display body 20 rotates, a control circuit 55 for controlling a rotation speed of the body vi sualization 20 and the information visualized on the display device, a power supply 60 having a positive terminal and a negative terminal, embodied in the pedestal 10 to provide the energy required by the viewing device, and a toroidal array (encoder) fixed to the pedestal 10 and constituted by a transparent material carrying a multiplicity of opaque bands extending radially. The toroidal network 30 includes light switches 36 and 38, each having a transmitting portion Tx and a receiving portion Rx, formed as a single component.

In the display device with the aforementioned structure, the electroluminescent lines 11-18 are arranged on the outer wall of the display body 20 at regular intervals, and they are illuminated / extinguished by energy supplied under control. of the control circuit 55. The toroidal network 30 is adapted to define the temporal conditions of illumination / extinction of the electroluminescent lines 11-18. For this purpose, the toroidal network 30 is formed by a transparent plate coated with an annular opaque portion on a surface extending from an inside diameter of the plate, and a multiplicity of opaque strips 34 extending radially outside the annular opaque portion 32, thereby to define a corresponding white number 35. The photointerrupters 36 and 38, each having the transmitting portion Tx and the receiving portion Rx, are respectively disposed at the inner diameter of the toroidal network. 30 to determine a rotation period and a lighting / extinguishing period.

Another conventional image display device disclosed in Korean Patent Application No. 10-201551 (filed by the Applicant on April 10, 1996 and issued thereto), and is shown in FIG. Referring to FIG. 3, it is noted that the image display device comprises a light emitting module A comprising a one-dimensional network 12 of electrolumines hundred elements 10 and a drive motor 14 for rotating the network of light emitting elements. electroluminescent elements 12, a control module B for controlling the light emitting module A, and a power supply module C for supplying energy to the light emitting module A and to the control module B. The control module B comprises a central control unit 26, a local memory 16, a buffer memory buffer 22, an address / control logic generator 20 and address multiplexer 26. The image display device comprises in addition to a position detection unit 18 for detecting the position of the array of electroluminescent elements 12. The position detecting unit 18 comprises a photodiode 30 facing the array of electromechanical elements. 12 and rotatable together with the grating 12 to function as a transmitting means, a phototransistor 32 operating as a receiving means, and a disc-type encoder 34 having a multiplicity of holes 33 formed along the edge of a disk, at regular intervals, for transmitting / interrupting the light from photodiode 30 to phototransistor 32.

In the image display device having the above-mentioned structure, light emitting module A with light emitting array 12 is rotated at a specific speed, together with photodiode 30, and at phototransistor 32, located beneath the module so that information about the position of the light emitting module A is detected by the holes 33 in the disk-type encoder 34, fixed between the photodiode 30 and the phototransistor 32. L Detected position information is transmitted to control module B, then transmits an address relating to a position and time conditions of image information to be displayed, thereby to visualize two-dimensional image using a visual remanence effect.

To summarize, in the signal lamp unit disclosed in Japanese Patent Laid-Open Publication No. Hei-sue 6-214509, two light-emitting diode arrays are respectively placed at both ends of a rotating substrate, and lighting / extinguishing time conditions of these diodes are controlled by a microcomputer based on a rotating position of the rotating substrate, detected by a movable proximity switch component attached to the lower end of the rotating substrate, and a fixed proximity switch component attached to a pedestal. As a result, it is not easy for the signal lamp unit to coincide with the time conditions for eliminating the extinction of the electro-luminescent diodes with the rotational speed of the rotating substrate, since the pair of components The proximity switch must first detect the rotational position of the rotating substrate, and the microcomputer must then illuminate the light-emitting diodes of the two arrays. Thus, if the single proximity switch detects the rotating position of the rotating substrate, the microcomputer illuminates! then sequentially extinguishing the plurality of light emitting diodes in accordance with a predetermined time sequence, while the rotating substrate completes a revolution. Consequently, the lighting / extinction time conditions of the light-emitting diodes are not constant, which makes a displayed image jump, or makes it difficult to visualize complex information.

In the display device which is described in U.S. No. 5,818,401, there is a multiplicity of cylindrical networks of light-emitting diodes, and a toroidal network (encoder) and a multiplicity of photo-interrupters interact to determine lighting / extinction time conditions of the light-emitting diodes by detecting bands in the light-emitting diode. toroidal network. A photointer switch adapted to detect the origin of the toroidal network and the other photo-switch is adapted to detect the bands in the toroidal network. Similar to the above signaling lamp unit, it is difficult for the display device to match illumination / extinguishing intervals of a plurality of light emitting diode arrays with a single one with the other. photo-switch, which leads' a visualized image that jumps.

In the image display device is disclosed in Korean Patent Publication No. 10-201551, a single array of electroluminescent elements is formed on a single rotating substrate to view a variety of images by rotation of the rotating substrate. However, the image display device can hardly avoid image jumps and mutually coincide illumination / extinction intervals of a multiplicity of electroluminescent elements, with a position detection unit comprising an encoder with a multiplicity of holes, a photodiode and a phototransistor.

The present invention has thus been made in consideration of the above problems, and an object of the present invention is to provide an image viewing system using electroluminescent elements, wherein a multiplicity of position sensors are respectively connected to a multiplicity of arrays of electroluminescent diodes, an original sensor is incorporated to detect the origin of a coder formed by bands, to thereby avoid an image jump and a discordance of illumination / extinction intervals of electroluminescent dio networks, in order to visualize more definite and precise information.

It is another object of the present invention to provide an image viewing system utilizing light emitting elements, in which a communication port, a wireless communication modem, etc., are incorporated to simultaneously transfer data from a computer. image from a computer or image information transfer means to a plurality of image display units, in a wired or wireless manner, for viewing the image data and wherein the image display units are configured in various forms to double the image transfer effect.

In accordance with the present invention, it is possible to achieve the above and other objects by means of an image display system comprising a multiplicity of troluminescent electron diode arrays arranged radially on a rotating disk. , at angular intervals, each of the arrays having a multiplicity of light-emitting diodes arranged in a straight line on the rotating disk a main board placed at the center of the rotating disk and supplying power supply and control signals to the light-emitting diode arrays ; an encoder placed behind a rear surface of the rotating disk and having a transparent and opaque coded band along its outer edge; a multiplicity of position sensors at the ends of the arrays on the rear surface of the rotating disk and placed at positions corresponding to the coded band of the encoder to thereby detect the coded band; an original sensor mounted on the rear surface of the rotating disk at a position corresponding to selected position sensors, and used to detect an original bar; a fixed disk carrying the encoder and the original bar; transparent window constituted by a transparent material and mounted along an outer edge of the fixed disk, using a locking ring, in a position in front of the rotating disk; a power supply for rectifying external AC power and for supplying the system with the resulting DC power, or for supplying the AC power directly to the system; a drive motor powered by electrical power supplied by the power supply; a power distributor for distributing to the system elements electrical energy from the power supply; a rotatable pulley coupled to the drive motor by a belt, so as to rotate the turning member using a rotational force of the motor; a communication port adapted to receive input control signals or input drive signals and to transfer the input signals to the main board; and a cover adapted to protect elements disposed in a region behind the fixed disk.

Other features and advantages of the invention will be better understood on reading the detailed description of embodiments, given as non-limiting examples. The following description refers to the accompanying drawings, in which Figures 1 to 3 are representations showing the structures of conventional image display devices; Fig. 4 is a plan view of an image display system using electroluminescent elements according to the present invention; Figure 5 is a sectional view of the image display system of Figure 4; Figure 6 is a detailed diagram of an encoder according to the present invention; Fig. 7 is a circuit diagram of the image display system of Fig. 4; Fig. 8 is a circuit diagram illustrating connections between a memory and light emitting diode modules in accordance with the present invention; Figures 9 and 10 are representations illustrating conventional examples of images displayed in the case of a single position sensor; Figures 11 and 12 are representations illustrating examples of images viewed in the case of four position sensors according to the present invention; Figs. 13-16 are front views showing various forms of the image display system according to the present invention; Fig. 17 is a block diagram showing an exemplary application of the image display system of the present invention.

Fig. 18 is a block diagram showing the generator / manager structure construction in Fig. 17; and Fig. 19 is a block diagram showing the structure of a cable communication network in Fig. 17.

FIG. 4 is a plan view of an image display system using electroluminescent elements according to the present invention, and FIG. 5 is a sectional view of the image display system of FIG. 4.

A plurality of light-emitting diode arrays (e.g., four arrays) 103-106 are respectively mounted radially on a circular rotating disk 102, at an angle of 90 relative to neighboring arrays, and each of them comprises a multiplicity of diodes. The electroluminescent electrodes 107, 108, 109 or 110 arranged in a straight line on the rotating disk 102. Each of the light-emitting diode arrays 103 106 comprises a multiplicity of light-emitting diode illuminating / quenching integrated circuits (ICs). , </ B> 112, <B> 113 </ B> or 1 to illuminate / turn off the corresponding light emitting diodes 107, 108, 109 110. The illumination / extinction diodes of LEDs 1, 112, 113 or 114 are in a number which is determined by the number of corresponding light emitting diodes 107, 108, 109. Light-emitting diodes 107-110 emit light of various colors, for example red, green, yellow, blue, etc. The light-emitting diode arrays 103-106 are adapted to receive information regarding the lighting / extinguishing time-out conditions of light-emitting diodes 107-110, from a main board 220, via respective cables 116. -119.

The main board 120 is mounted at the center of the rotating disk 102 and adapted to supply power and control signals to the light-emitting diode arrays 103-106. The main board 120 includes a central processing unit (CPU) 150 for calculating input / output signals and outputting control signals in accordance with the calculated results, a memory 152 for recording input / output data, a decoder 154 for transmitting data relating to the illumination / extinction time conditions of the light-emitting diodes 107-110, and a buffer 155 for decoding a data signal or a sensor signal from the central unit 150, and outputting the decoded result to light-emitting diode arrays 103-106. The main board 120 further comprises a wireless communication modem 130 for receiving a radio signal via a transmitting-receiving antenna 130, or transmitting a control signal from the central unit 150. The modem Wireless communication 130 operates to receive visualization information data from a remote site to transmit the received data to the CPU 150.

An encoder 122 is placed behind the rear surface of the rotating disk 102, comprises an opaque transparent coded band 140. Thus, the coded band 140 is disposed along the outer edge of the encoder 122, and includes a plurality of transparent portions 141 , transmitting light, and a multiplicity of opaque portions 142 stopping the light which are arranged evenly and alternately along the strip. The coded band 140 of the coder 122 thus generates a wave in the form of pulses, or a square wave. In the present invention, the transparent and opaque portions 141 and 142 of the coiled band 140 may be irregularly disposed along the outer edge of the encoder 122.

A plurality of position sensors 124 to 127 are fixedly mounted at the inner ends of the troluminescent diode arrays 103 to 106 on the rear surface of the rotating disk 102 so as to be placed in positions around the outer edge of the encoder. 122, to thereby detect the coded band 140 of the coder 122. The position sensors 124 to 127, integrated at the inner ends of the light emitting diode arrays 103 to 106, are U-shaped elements, and they cover the band 140 in a radial direction. Each of the position sensors 124 to 127 preferably comprises a photocoupler, consisting of a light emitting photodiode Tx and phototransistor Rx on opposite branches of the emitter. In the operation of the image display system of this invention, the photodiode Tx of the position sensors 124 to 127 emits a beam of light to the phototransistor Rx. The phototransistor Rx is thus selectively activated in response to the beam from the photodiode Tx, and forms a desired pulse wave (a desired square wave). An origin sensor 123 is placed on the rear surface of the turn 101 to detect an original bar 128 fixed to a fixed member 101. In the present invention, the original sensor 123 can be integrated with a selected one of the sensors. from position 124 to 127, can be mounted on the rotating disc 101 in a position corresponding to the selected position sensor. The original sensor 123 has the same structure as the position sensors 124 to 127. Thus, the original sensor 123 is a U-shaped element which is positioned so that it is not above the bar of the sensor. This source U-shaped sensor 123 preferably comprises a photocoupler, consisting of a light emitting photodiode Tx and a phototransistor Rx on its opposite branches. In the operation of the image display system of this invention, the original sensor 123 detects the origin bar 128, and emits the wave as pulses (the square wave).

The fixed disk 101 carries on it the encoder 122 and the original bar 128. Thus, the encoder 122 is held on the bearing housing 121, with the original bar 128 fixed to the disk 101 at a corresponding position. to the radius of gyration of the original sensor 123. The fixed disk is fixed externally to the hub of the bearing housing 121, with multiplicity of bearings 132 and 133 disposed inside the means of the bearing housing 121, to maintain rotating way a rotating tree 134.

A transparent window 115, constituted by a transparent material, is mounted along the outer edge of the fixed disk 101 using a locking means, such as a locking ring, in a position in front of the rotating disk 102. The transparent window 115 makes it possible to show outside the image display system of this invention an image produced by the light-emitting diode arrays 103 to 106. This window 115 also protects the interior of the image display system vis-à- of the atmosphere, thereby preventing foreign substances from being undesirably introduced into the system. In the present invention, it is preferable to make the transparent window 115 using a hard and rigid material which is less likely to be bent or broken easily. On the other hand, the system includes a power supply that recovers input AC power and provides the resulting DC power system, or provides the AC power directly to the system. In the present invention, it is preferable to provide the power supply 139 with a circuit designed to stop or absorb an overvoltage in the input energy, or noises.

drive motor 131 is incorporated in the system. This motor 31 is driven by electrical energy applied to produce a rotational force to operate the rotating disk 102 and the encoder 122. In the present invention, it is preferable to design the motor 131 to produce a rotational force. predetermined constant rotation force.

The image display system of this invention also includes a power distributor 137, which is used to properly distribute to the system elements the electrical energy from the power supply 139.

A rotating pulley 135 is mounted at the end of the energy distributor 137, while a belt 136 couples the pulley 135 to the output pulley of the rotating disk 102, thereby rotating the rotational pulley 135 using force. The rotational pulley 135 preferably has a reduction ratio which can reduce to a desired level the rotational force of the motor 131. In addition, the belt 136 is preferably designed to transmit accurately the rotational force of the motor 131 to the rotating pulley 135.

The system also includes a communication port 138, which receives the input control signals or input drive signals. communication port 138 receives information data from a computer or other image information transfer means, via a cable, and transmits the input training data to the 120 main board through the energy scorcher 137.

Components in the area behind the fixed disc are covered and protected by a cover. In the present invention, it is preferable to design the cover 129 to effectively protect the components in the area behind the fixed disk 101 against foreign substances. It is also preferable to design the cover 129 so that it is étan che.

The operation of the image display system of the present invention utilizing light-emitting diodes will be described below.

Fig. 6 is a perspective view of the encoder included in the system of this invention. As shown in the drawing, the encoder 122 fixedly and concentrically mounted on the fixed disk 101, with the position sensors 124 to 127 movably positioned to rotate about the outer edge of the encoder 122. The band coded 140, constituted by the transparent and opaque portions 141 and 142 arranged regularly and alternately, is formed along the outer edge of the encoder 122. The position sensors 127, individually comprising an integrated body constituted by Tx photo diode acting as a light emitting element, and a phototransistor Rx acting as a light receiving element, are placed at positions around the outer edge of the encoder 122, covering the web 140 in a radial direction, thereby detecting the encoded band 140 of the encoder 122. In detail, four position sensors 124 to 127 are oppositely positioned diagonally, to detect the coded band 140. The position sensors 124 to 127 thus produce a pulse wave (square wave) due to the alternating position of the transparent and opaque portions 141 and coded band 140. Of course, it should be noted that the number of position sensors is not limited to four, but can be changed as desired without affecting the operation of this invention. When the system has five or more position sensors with the same number of light-emitting diode arrays, the position sensors must be arranged at regular intervals so that the sensors detect coded band 140 of the encoder as desired. In addition, the original sensor 123 is placed on the rear surface of the rotating disk 102 at a position corresponding to a selected one of the position sensors 124 to 127, and detects the original bar 128 attached to the disk. fixed 101 before transmitting a detection signal to the central unit 150.

In order to operate the image display system of the present invention, the power supply 139 supplies electricity to the drive motor 131, which has the effect of activating the motor 131. The driving motor 131 thus generates a rotational force, which is transmitted to the rotational pulley 135 by the belt 136. The revolving pulley 135 is rotated with a reduction in its rotational speed. Therefore, the rotating disk 102 as well as the position sensors 124 to 127 are rotated together with the turntable pulley 136, because the rotational force of the pulley 136 is transmitted to disk 102 and to the position sensors 124 through 127 in such a case, it is necessary that the rotating disk 102 and the position sensors 124 to 127 rotate precisely about the central axis of the rotating shaft 134. When the The sensors 124 to 127 rotate precisely around the axis of the rotating shaft 134, as described above, the encoded band 140 of the encoder 122 is interposed accurately between the Tx photodiodes and the Rx phototransistors. The position sensors 124 to 127 are thus accurately rotated along the coded band 140 to accurately detect the band 140 and to pulse a pulse wave. Siree. In addition, it is necessary for the light emitting diode arrays 103 to 106 to be precisely disposed on the rotating disk 102, being in correspondence with a center of gravity of the disk 102. In such a case, the display system image displays a sharp image.

In the above manner, each of the 103-106 troluminescent diode arrays is controlled to have such an illumination / extinction period and such a precise period of rotation, in order to visualize a defined image, without jumping, as one will describe in detail after referring to Figure 7.

FIG. 7 is a circuit diagram of the image display system of FIG. 4. Each of the position sensors 124-127 adapted to periodically detect the band 140 of the encoder 122, so as to generate a signal in the form of pulses, which is then applied to the CPU 150.

The CPU 150 reads information data for image display from memory 152 in response to a pulse signal applied thereto, and transmits control signal to decoder 154 and the buffer 155, based on the information data read. The central unit 150 also receives external information data through the communication port 138.

The decoder 154 decodes the information data from the CPU 150 and applies the decoded result to the 111-114 light-emitting diode lighting / quenching ICs in the light-emitting diode arrays 103-106, which also receive a decoded result. if there is a shift clock from the buffer 155 and information data from the CPU 150.

Respective data from light-emitting diode illumination / extinction ICs 111-114 are applied to latch registers and shift registers in light-emitting diode illumination / extinction ICs 111-114 to thereby illuminate / extinguish a light-emitting diode. multiplicity of light-emitting diodes D. the figure a resistance R has the function of producing a drop of a voltage applied to it.

Respective groups of light-emitting diodes D connected to the illumination / extinction diodes 111-114 of light-emitting diodes are illuminated / extinguished by associated information data.

The central unit 150 wirelessly receives, via a wireless communication medium 130, information data from the remote site, and applies the received data to the light-emitting diode lighting / extinction ICs 111. 114, thereby to illuminate / extinguish the light-emitting diodes D in a manner similar to the signals from the encoder 122 and the buffer 155.

Fig. 8 is a circuit diagram illustrating connections between memory 152 and light emitting diode modules according to the present invention. As shown in this drawing, the memory 152 contains information data for displaying stored images M1, M2, ..., M n / 4, M n / 4 + 1, ..., M 2n / 4, M 2n / 4 + 1, ..., M 3n / 4, M 3n14 + 1, ..., n-2, M n-1, Mn, denoting by M a position of the memory and an encoder number indicating the number of pixels at the edge of the encoder. As a result, corresponding information is applied to the shift registers in the Illumination / Illumination Diode ICs 111-114, which has the effect of illuminating / switching off the corresponding LEDs in a similar manner. sensor data and deceleration clock signal.

Hereinafter, a description will be given of images viewed when light-emitting diodes 107-110 in light-emitting diode arrays 103-106 in the present image display system are illuminated / extinguished, with reference to Figs. 9 to 12.

FIGS. 9 and 10 are representations illustrating conventional examples of visualized images in the case where only one position sensor 124-127 is used, and FIGS. 11 and 12 are representations illustrating examples of images viewed in the Position sensors 124-127 are respectively integrated with the light-emitting diode arrays 103-106 in accordance with the present invention.

Figure 9 shows an image displayed when the encoder is incorrectly aligned at its center, as in most systems of the prior art. In this case, the number of encoder gates is eight and the number of light emitting diode arrays is two.

the encoder has a slight interval difference in its entirety, it will have a considerable jump in the entire image.

A pulse signal shown at the top of a graphical representation of Fig. 9 is produced when the encoder is incorrectly aligned at its center, and a pulse signal below it is produced when the encoder is correctly aligned at its center. For the letter "A" which is displayed, a part a is displayed when the encoder is incorrectly aligned at its center, and a part b constituted by a first group of electroluminescent diodes and part c is constituted by a second group of light emitting diodes. each part having a reduced height for viewing. As can be seen in the figure, the "A" lette may show a jump although the groups of light-emitting diodes are precisely aligned. Starting with the rising edge of each impulse from the encoder, fine dotted lines indicate the lighting conditions of the first group of light emitting diodes, and thick dashed lines indicate the lighting conditions of the second group of light emitting diodes. electroluminescent diodes. These lines show three cases, first in which the diodes of the second group of light-emitting diodes are illuminated earlier and extinguished later, the second in which the diodes of the second group of light-emitting diodes are illuminated later and extinguished later, and the third group of electroluminescent diodes are illuminated later and extinguished later; wherein the diodes of the second group of light-emitting diodes are illuminated earlier and extinguished earlier. In any case, there is an important jump in the entire image.

On the other hand, Fig. 11 shows an image displayed in the case where the number of position sensors is two, the number of light emitting diode networks two and the number of encoder gates is eight. As can be seen from this drawing, the letter "A" is not subject to any jump, although pixels are arranged at irregular intervals and the encoder is incorrectly aligned at its center.

Thus, the visualized image is not subject to any jump in that the diodes of the second group of light emitting diodes are aligned substantially with those of the first group of light emitting diodes.

As indicated above, in cases where position sensors are respectively mounted in association with a multiplicity of light emitting diode arrays, a more defined image is displayed without jumping, in comparison with the case in which a single position sensor is mounted.

In addition, Fig. 11 shows the case where the encoder has a fourth different grid and four parts are jump-prone for a single position sensor. Black bars (bands) at the upper portion of the graphical representation are opaque portions 142 of the encoder, for example 32 opaque portions, and a pulse signal below them is generated for a single position sensor. As can be seen in FIG. 11, a part shows a jump in each of the images visualized by the four networks of electroluminescent diodes 103-106. Thus, jump portions are respectively present at a rising edge d of the fourth "S" pulse for the first light emitting diode array, at one edge of the fourth "A" pulse for the second light emitting diode array. electroluminescent diodes, at a rising edge f of the fourth pulse of "T" for the third array of light-emitting diodes, and at a rising edge of the fourth pulse of "." for the fourth array of light-emitting diodes.

Figure 12 shows the case where the encoder has a different fourth grid and a wider part and narrower part are visualized for four position sensors. Thus, for each of the first to fourth light-emitting diode arrays 103-106, a narrower third portion and a fourth wider portion are displayed at the fourth encoder gate.

Therefore, in the case where the position sensors 124 127 are respectively mounted in association with diol networks of electroluminescent 103-106, the jump which affects visualized image so low that it is hardly perceived by the human eye. As a result, the case provides a much more defined picture than when only one position sensor is mounted.

Figures 13 to 16 show various forms of the image display system according to the present invention. The image display system of Fig. 13 comprises a cylindrical display body 160 and four light-emitting diode arrays 161 mounted on the body 160. The image display system of Fig. 14 includes a spherical display body 170. and four light-emitting diode array 171 mounted on the body 170. The image display system of FIG. 15 comprises a dome-shaped viewing body 180 and four light-emitting diode arrays 181 mounted on the body 180. the image display system of FIG. 16 comprises a conical viewing body 190 and four light-emitting diode arrays 191 mounted on a body 190. Pedestals 162, 172, 182 and 192 are respectively installed beneath the display bodies 160, 170, 180 and 190.

Fig. 17 is a block diagram showing an exemplary application of the image display system of the present invention. Referring to FIG. 17, it is noted that a multiplicity of image display devices 212 and 213 are installed to receive wire or wireless image data, and to view images of the received data. For wireless reception, each image display device is adapted to display characters or graphic elements using a character message service provided with a radio network 208 or a mobile telecommunication network company. For wire reception, each image display device receives image data from a personal computer or a portable computer connected to a cable communication network 210 or a recording medium 211. in the communication network 210, via a communication port, and it displays the received image data. A generator / manager structure 206 creates image data and transmits it to the radio network 208 or the cable communication network 210. For the cable communication, the generator / manager structure 206 may transmit the image data. generated via a telephone line or private line.

The generator / manager structure 206 collects data from an information provider 200, a central government agency 202 and a reporter 204, and generates image data resulting from the collection.

Fig. 18 is a block diagram showing the generator / manager structure 206 in Fig. 17. As shown in the drawing, the generator / manager structure 206 receives data from the information provider 200 from the central government agency 202 and a reporter 204 via the cable communication network or the wireless communication network. Then, in the generator / manager structure 206, a data receiving / summarizing unit 206a receives and ranks the data from the information provider 200, the central government agency 202 and the reporter 204. An image recording unit 206b records image data classified by the data receiving / classification unit 206a. An image display command recording unit 206c records image display commands classified by the data receiving / classification unit 206a. An image code data register unit 206d records image code data classified by the data receiving / classification unit 206a.

A microprocessor 206e processes the data recorded in the image recording unit 206b, the image display command recording unit 206c and the image code data recording unit 206d, according to a predetermined program, and transmits the processed results to the cable communication network 210.

The image data recorded in the image recording unit 206b is encoded regions, societies or subjects in accordance with the image code data recorded in the image code data recording unit 206d, and they are then transmitted to associated cable communication networks.

Fig. 19 is a block diagram showing the structure of the cable communication network 210 in Fig. 17. As shown in this drawing, the cable communication network 210 includes an image recording unit 210a for recording data of the data communication network 210. image from the generator / manager structure 206, and an image display command recording unit 210b for recording image display commands from the generator / manager structure A microprocessor 210c processes the data recorded in the image recording unit 210a and the image display gold recording unit 210b according to a predetermined program recorded in a program recording unit 210d, and transmits the processed results to an image display 214, 215 or corresponding, in real time, via a multiple port 210e and a corresponding 210f, 210g or 210h cable communication modem. Alternatively, the microprocessor Oc may simultaneously transmit the processed image data to the image display devices 214-216 through the multiple port 210e and the 210f-21 Oh cable communication modems.

The image display devices 214-216 are respectively connected to the 210f-210h cable communication modems for receiving image data through a corresponding one of them. The multiple port 210e is adapted to select a specific one of the 210f-210h modems under the control of the microprocessor 210c.

In addition, the generator / manager structure 206 transmits processed image data to a corresponding one of the image display devices 212-216 over the radio communication network 208 or the cable communication network 210. .

As described above, the present invention provides an image display system utilizing electrolumines cent elements. For effectively managing image display data, the system of this invention records selected image data in a database, the image data being classified as information data for the public, information data relating to companies, news, etc. In particular, the heading "news" is intended to provide the public with meteorological information, stock market information, urgent news, sports information, etc. In the recent "network society", the provision of such image information to the public can effectively be managed by a task allocation, and thus it is possible to maximize the supply effect of information and to achieve rapid and effective information provision.

The electroluminescent image display system according to this invention is designed to display desired images, such as a variety of letters, characters and graphics, using a visual remanence effect of the image. viewer according to input information data relating to lighting / extinguishing time conditions of light-emitting diodes, and a rotating period of a rotating disk carrying light-emitting diode arrays.

The image display system of this invention comprises a multiplicity of position sensors mounted on a multiplicity of light emitting diode arrays and used to detect pulse waves of an encoder. The system also includes an original sensor used to detect an original bar. In system operation, the system receives image, wired or wireless image information data via a communication port or a wireless communication modem, and displays images expressing the information, using pro signals from the sensors and the information data signals from a memory. The image display system of this invention is therefore preferably used to quickly provide the public with public information from government and public agencies and the police. This system is also preferably used to quickly and clearly provide the public with information about companies on busy streets or residential streets. The operation of the image display system according to this invention can be controlled by wire or wireless, by means of a remote control process. Therefore, this invention preferably replaces billboards, advertising prospectuses and advertising posters. The systems of this invention are also produced at a low cost, which makes users buy them without hesitation. Another advantage of an image display system of this invention is that two or more systems can be used in different locations to provide the same image information at the same time.

It goes without saying that many modifications can be made to the device described and shown without departing from the scope of the invention.

Claims (1)

    <U> CLAIMS </ U> <tb> System <SEP> of <SEP> visualization <SEP> of images <SEP> characterized <SEP> in <SEP> that <SEP> it <tb> includes <SEP>: <SEP> a <SEP> multiplicity <SEP> of <SEP> networks <SEP> of <SEP> LEDs <SEP> electroluminescent <tb> (103-106) <SEP> arranged <SEP> radically <SEP> on <SEP> a <SEP> disk <SEP> running <SEP> (102) <SEP> to <SEP> of <SEP> inter angular <SEP> vales, <SEP> each <SEP> of <SEP> these <SEP> <SEP> networks having <SEP> a <SEP> <SEP> multiplicity of <SEP> diodes <tb> electroluminescent <SEP> (107-110) <SEP> arranged <SEP> of <SEP> way <SEP> rectilinear <SEP> on <SEP> the <SEP> say that <SEP> rotating; <SEP> a <SEP> card <SEP> main <SEP> (120) <SEP> placed <SEP> at the <SEP> center <SEP> of <SEP> disk <SEP> running <SEP> (1 <SEP > and <SEP> providing <SEP> of <SEP> the <SEP> power of <SEP> power and <SEP> of <SEP> <SEP> signals of <tb> <SEP> command to <SEP> networks <SEP> of <SEP> <SEP> electroluminescent <SEP> diodes (1 <SEP> 106); <SEP> a <SEP> controller <SEP> (122) <SEP> placed <SEP> behind <SEP> a <SEP> <SEP> surface <SEP> of the <SEP> <SEP> drive running <SEP> (102) <SEP> and <tb> having <SEP> a <SEP> band <SEP> encoded <SEP> transparent <SEP> and <SEP> opaque <SEP> (140) <SEP> the <SEP> long <SEP> of <SEP> its <SEP> edge <tb> outside; <SEP> a <SEP> multiplicity <SEP> of <SEP> sensors <SEP> of <SEP> position <SEP> (124-1 <SEP> mounted <SEP> to <SEP> of <tb> <SEP> ends of <SEP> networks <SEP> (103-106) <SEP> on <SEP> <SEP> surface <SEP> back <SEP> disk <SEP> turn <SEP> (1 <SEP> and <SEP> placed <SEP> in <SEP> of <SEP> corresponding <SEP> positions <SEP> to <SEP> I <SEP> coded <SEP> band <tb> (140) <SEP> encoder <SEP> (122), <SEP> for <SEP> detect <SEP> thus <SEP> <SEP> <SEP> encoded <SEP> band (140); <SEP> a <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> Rooter <SEP> <SEP> <SEP> Surface <SEP> <SEP > disk <SEP> rotating <SEP> (102) <tb> to <SEP> a <SEP> <SEP> position corresponding to <SEP> to <SEP> a <SEP> selected <SEP> <SEP> <SEP> sensors <SEP> position <tb> (124-127) <SEP> and <SEP> used <SEP> for <SEP> detect <SEP> a <SEP> original <SEP> bar <SEP> (128); <SEP> a <SEP> fixed <SEP> disk <tb> (101) <SEP> carrying <SEP> on <SEP> it <SEP> the <SEP> encoder <SEP> (122) <SEP> and <SEP> the <SEP> original <SEP> bar <SEP> (128); <SEP> a <SEP> window <SEP> transparent <SEP> (115) <SEP> constituted <SEP> by <SEP> a <SEP> material <SEP> transparent <SEP> and <SEP> mounted <tb> the <SEP> long <SEP> of a <SEP> board <SEP> outside <SEP> of the <SEP> <SEP> fixed disk <SEP> (101) <SEP> in <SEP> using <SEP > a <SEP> ring <SEP> of <tb> blocking, <SEP> in <SEP> a <SEP> position <SEP> located <SEP> face <SEP> at <SEP> disk <SEP> running <SEP> (1 <SEP> a <SEP> ali <SEP> (139) <SEP> for <SEP> to rectify <SEP> of <SEP> energy <SEP> to <SEP> current <SEP> alternatï <SEP> external <SEP> and <tb> to <SEP> provide <SEP> to the <SEP> system <SEP> the resulting <SEP> to <SEP> continuous <SEP> continuous <SEP> energy <SEP> or <SEP> for <tb> supply <SEP> directly <SEP> to the <SEP> system <SEP> the energy <SEP> to <SEP> current <SEP> alternative; <SEP> a <SEP> engine <tb> drive <SEP> (131) <SEP> actuated <SEP> by <SEP> of <SEP> the energy <SEP> electrical <SEP> supplied <SEP> by <SEP> the power < SEP> (139): <SEP> a <SEP> distributor <SEP> of energy <SEP> (137) <SEP> for <SEP> to distribute <SEP> to <SEP> of <SEP> elements <SEP> <SEP> system <SEP> energy <SEP> electrical <SEP> from <SEP> of <SEP> power supply <SEP> (139); <tb> a <SEP> rotary <SEP> pulley <SEP> (135) <SEP> coupled <SEP> to the <SEP> drive <SEP> drive <SEP> (131) <SEP> by <tb> a <SEP> belt <SEP> (136), <SEP> from <SEP> way <SEP> to <SEP> do <SEP> turn <SEP> the <SEP> drive <SEP> run <SEP> (102) <SEP> in <tb> using <SEP> <SEP> SEP <SEP> <SEP> SEP <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> of <SEP> communication <tb> (138) <SEP> adapted <SEP> for <SEP> to receive <SEP> of <SEP> <SEP> signals from <SEP> <SEP> <SEP> <SEP> <SEP> command > if SEP <SEP> <SEP> <SEP> and <SEP> <SEP> <SEP> send <SEP> <SEP> <SEP> <SEP> input <tb> main <SEP> card <SEP> (120); <SEP> and <SEP> a <SEP> cover <SEP> (129) <SEP> adapted <SEP> for <SEP> to protect <SEP> from <tb> elements <SEP> <SEP> finding <SEP> in <SEP> a <SEP> <SEP> zone located <SEP> behind <SEP> <SEP> <SEP> fixed disk <SEP> (101) .

    System <SEP> of <SEP> visualization <SEP> of images <SEP> according to <SEP> the <SEP> claim <SEP> 1 <SEP>, <tb> characteri <SEP> "<SEP> in <SEP> this <SEP> that <SEP> the <SEP> card <SEP> main <SEP> (120) <SEP> includes <SEP>: <SEP> a <SEP> unit <SEP> cen tral <SEP> of <SEP> processing <SEP> (150) '<SEP> for <SEP> calculating <SEP> of <SEP> signals <SEP> input / output <SEP > and <tb> issue <SEP> <SEP> signals from <SEP> <SEP> command in accordance with <SEP> to <SEP> calculated <SEP> results; <tb> a <SEP> memoi <SEP> (152) <SEP> for <SEP> save <SEP> of <SEP> data <SEP> input / output: <SEP> a <SEP> decoder <SEP > (154) <SEP> for <SEP> to issue <SEP> of <SEP> data <SEP> concerning <SEP> of <SEP> conditions <SEP> times <SEP> of lighting / extinction <SEP> of < SEP> electroluminescent <SEP> diodes <SEP> (107-1 <SEP>: <SEP>) <tb> a <SEP> buffer <SEP> (155) <SEP> for <SEP> decode <SEP> a <SEP> <SEP> signal from <SEP> <SEP> data from <SEP> of <SEP> l 'SEP' <tb> Central <SEP> of <SEP> Processing <SEP> (150) <SEP> and <SEP> Transmitting <SEP> <SEP> Result <SEP> Decoded <SEP> to <SEP> Networks <SEP> of <SEP> electroluminescent <SEP> diodes <SEP> (103-106). <tb> System <SEP> of <SEP> visualization <SEP> of images <SEP> according to <SEP> <SEP> claims <SEP> 1, <tb> character <SEP> '<SEP> in <SEP> this <SEP> that <SEP> <SEP> band <SEP> encoded <SEP> (140) <SEP> is <SEP> formed <SEP> by <SEP> a <SEP> multiplicity <SEP> of <SEP> parts <SEP> transparent <SEP> (141) <SEP> transmitting <SEP> the <SEP> light <SEP> and <SEP> a <SEP> multiplicity <SEP> of <SEP> parts <SEP> opaque <SEP> (142) <SEP> stopping <SEP> the <SEP> light, <SEP> arranged <SEP> regularly <tb> and <SEP> in <SEP> alternation <SEP> the <SEP> long <SEP> of the <SEP> edge <SEP> outside <SEP> of the <SEP> encoder <SEP> (122). <tb> System <SEP> of <SEP> visualization <SEP> of images <SEP> according to <SEP> the <SEP> claim <SEP> 1, <tb> character <SEP> in <SEP> this <SEP> it <SEP> includes <SEP> in <SEP> in addition to <SEP> a <SEP> <SEP> modem <SEP> communication <tb> without <SEP> thread <SEP> (130) <SEP> for <SEP> receive <SEP> a <SEP> <SEP> signal from <SEP> <SEP> <SEP> message from <SEP> d 'a <tb> remote <SEP> site, <SEP> this <SEP> <SEP> signal <SEP> <SEP> <SEP> <SEP> message containing <SEP> <SEP> <SEP> data <SEP> <SEP> <SEP> <SEP> time <SEP> <SEP> conditions of <SEP> networks <SEP> <tb> LEDs <SEP> electroluminescent <SEP> (103-106) <SEP> and <SEP> of the <SEP> <SEP> data of <SEP> visualization. <tb> System <SEP> of <SEP> visualization <SEP> of images <SEP> according to <SEP> the <SEP> claim <SEP> 1 <SEP>, <tb> character <SEP> "<SEP> in <SEP> this <SEP> only <SEP> each <SEP> of <SEP> networks <SEP> of <SEP> LEDs <SEP> electroluminescent <tb> (103-106) <SEP> includes <SEP>: <SEP> a <SEP> multiplicity <SEP> of <SEP> integrated <SEP> circuits <SEP> (111- <SEP> 14) SEP <SEP> <SEP> <SEB> Illumination <SEB> Illumination <SEP> LEDs <SEP> </ br> <tb> switch off <SEP> of <SEP> corresponding <SEP> diodes <SEP> among <SEP> <SEP> LEDs <SEP> electroluminescent <SEP> (107-110), <SEP> these <SEP> circuits <SEP> integrated <SEP> lighting / extinguishing <SEP> of <SEP> diodes <tb> electroluminescent <SEP> being <SEP> in <SEP> a <SEP> number <SEP> which <SEP> is <SEP> determined <SEP> in <SEP> function <SEP> of <tb> number <SEP> of corresponding <SEP> <SEP> <SEP> <SEP> (107-110) <SEP> diodes, <SEP> and <tb> each <SEP> of them <SEP> including <SEP> a <SEP> <SEP> register of <SEP> <SEP> flip-flops for <SEP> brighten / <tb> switch off <SEP> of the <SEP> associated <SEP> diodes <SEP> among <SEP> the <SEP> light-emitting diodes <SEP> corresponding <tb> (107-110) <SEP>, <SEP> in <SEP> response <SEP> to <SEP> a <SEP> <SEP> signal from <SEP> sensor, <SEP> and <SEP> re registers <SEP> to <SEP> offset <SEP> for <SEP> receive <SEP> in <SEP> input <SEP> a <SEP> <SEP> clock signal <SEP> of <SEP> offset <tb> and <SEP> a <SEP> <SEP> signal <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP > scales; <SEP> and <SEP> one <tb> cable <SEP> for <SEP> receive <SEP> at <SEP> from <SEP> of <SEP> <SEP> card <SEP> main <SEP> (120) <SEP> of <SEP> l 'information

    on <SEP> the <SEP> <SEP> <SEP> time <SEP> <SEP> conditions of <SEP> diodes <tb> electroluminescent <SEP> (107-110). <tb> System <SEP> of <SEP> visualization <SEP> of images <SEP> according to <SEP> the <SEP> claim <SEP> 1, <tb> character <SEP> "<SEP> in <SEP> this <SEP> than <SEP> each <SEP> of <SEP> components <SEP> including <SEP> <SEP> networks <tb> LEDs <SEP> electroluminescent <SEP> (103-106), <SEP> the <SEP> disk <SEP> running <SEP> (102) <SEP> and <SEP> the <SEP> di <tb> <SEP> fixed <SEP> (101) <SEP> is <SEP> designed <SEP> for <SEP> to have <SEP> any <SEP> any <SEP> <SEP> forms <SEP > following <SEP>: <SEP> cylindrical, <SEP> spherical, <SEP> in <SEP> dome <SEP> and <SEP> conic. <tb> System <SEP> of <SEP> visualization <SEP> of images <SEP> according to <SEP> the <SEP> claim <SEP> 1, <tb> character <SEP> '<SEP> in <SEP> this <SEP> than <SEP> each <SEP> of <SEP> sensors <SEP> including <SEP> the <SEP> sensor <SEP> i gine < SEP> (123) <SEP> and <SEP> the <SEP> sensors <SEP> of <SEP> position <SEP> (124-127) <SEP> includes <SEP> a <SEP> photodi <tb> emission <SEP> of <SEP> light <SEP> (Tx) <SEP> and <SEP> a <SEP> phototransistor <SEP> of <SEP> reception <SEP> of <SEP> lumi ' <tb> (Rx), <SEP> this <SEP> phototransistor <SEP> being <SEP> integrated <SEP> with <SEP> the <SEP> photodiode <SEP> and <SEP> receiving <SEP> la <tb> light <SEP> i <SEP> comes <SEP> from <SEP> the <SEP> photodiode <SEP> for <SEP> issue <SEP> a <SEP> wave <SEP> under <SEP> form <tb> of ïmpulsi <tb> 8. <SEP> System <SEP> of <SEP> visualization <SEP> of images, <SEP> characterized <SEP> in <SEP> this <SEP> 'i <tb> includes <SEP>: <SEP> a <SEP> network <SEP> of <SEP> communication <SEP> by <SEP> cable <SEP> (210) <SEP> for <SEP> receive <tb> image <SEP> signal; <SEP> a <SEP> network <SEP> of <SEP> communication <SEP> without <SEP> thread <SEP> (208) <SEP> for <SEP> receive <tb> a <SEP> <SEP> signal from <SEP> message; <SEP> a <SEP> encoder <SEP> (122) <SEP> having <SEP> a <SEP> band <SEP> encoded <SEP> (1 <tb> transparent <SEP> and <SEP> opaque <SEP> the <SEP> long <SEP> of <SEP> its <SEP> outer <SEP> edge; <SEP> a <SEP> multiplicity <tb> sensors <SEP> position <SEP> (124-127) <SEP> for <SEP> detect <SEP> <SEP> band <SEP> encoded <SEP> (140): <tb> unit <SEP> central <SEP> of <SEP> processing <SEP> (150) <SEP> for <SEP> calculating <SEP> of <SEP> <SEP> signals received <SEP> by <tb> The <SEP> <SEP> <SEP> Network <SEP> Interaction of <SEP> <SEP> Communication with <SEP> <SEP> (210) <SEP> <SEP> <SEP> <SEP > network <tb> of <SEP> communication <SEP> without <SEP> thread <SEP> (208), <SEP> and <SEP> of <SEP> <SEP> signals detected <SEP> by <SEP> <SEP> sensors <tb> of <SEP> position <SEP> (124-127); <SEP> a <SEP> memory <SEP> (152) <SEP> for <SEP> save <SEP> of <SEP> data <tb> input / output, <SEP> a <SEP> decoder <SEP> (154) <SEP> for <SEP> issue <SEP> of <SEP> data <SEP> concerning <tb> <SEP> time <SEP> <SEP> time <SEP> times <SEP> of <SEP> multiplicity <SEP> of <SEP> <tb> pits <SEP> of <SEP> LEDs <SEP> electroluminescent <SEP> (103-106): <SEP> a <SEP> buffer <SEP> (155) <SEP> for <tb> decode <SEP> a <SEP> <SEP> signal from <SEP> <SEP> data from <SEP> from <SEP> <SEP> <SEP> unit <SEP> processing <tb> (150) <SEP> and <SEP> for <SEP> issue <SEP> <SEP> result <SEP> decoded <SEP> to <SEP> <SEP> networks <SEP> of <SEP> diodes <SEP> troluminescent elec <SEP> (103-106): <SEP> and <SEP> a <SEP> multiplicity <SEP> of <SEP> integrated <SEP> circuits <SEP> (1 <SEP> 1 114) < SEP> lighting / extinguishing <SEP> of <SEP> LEDs <SEP> electroluminescent, <SEP> for <SEP> lighting / <tb> switch off <SEP> the corresponding <SEP> <SEP> electroluminescent <SEP> diodes (107-110) <SEP> <tb> networks <SEP> LEDs <SEP> electroluminescent <SEP> (103-106), <SEP> in <SEP> response <SEP> to <SEP> of <tb> gnaux <SEP> output <SEP> from <SEP> of <SEP> the <SEP> memory <SEP> (152), <SEP> of <SEP> decoder <SEP> (154) <SEP> and < SEP> of <tb> buffer <SEP> 55): <SEP> thanks <SEP> to <SEP> what <SEP> various <SEP> <SEP> information <SEP> or <SEP> graphs from <SEP>

    <SEP> characters are <SEP> viewed <SEP> without <SEP> <SEP> visual jump. <tb> 9. <SEP> System <SEP> of <SEP> visualization <SEP> of images <SEP> according to <SEP> <SEP> claim <SEP> 8, <tb> characterized <SEP> in <SEP> this <SEP> that it <SEP> understands <SEP> in <SEP> besides <SEP>: <SEP> a <SEP> structure <SEP> of <SEP> generator / <tb> manager <SEP> (206) <SEP> for <SEP> to collect <SEP> <SEP> <SEP> data from <SEP> of a <SEP> multiplicity <tb> of <SEP> <SEP> providers of <SEP> information (200). <SEP> of a <SEP> multiplicity <SEP> of <SEP> reporters <SEP> (204) <tb> and <SEP> of a <SEP> organization <SEP> government <SEP> central <SEP> (202), <SEP> and <SEP> for <SEP> generate <SEP> of <tb> <SEP> image data <SEP> under <SEP> the <SEP> effect of <SEP> <SEP> collection: <SEP> <SEP> <SEP> network <SEP> communication <tb> without <SEP> thread <SEP> (208) <SEP> transmitting <SEP> with <SEP> the <SEP> intermediate of a <SEP> modem <SEP> of <SEP> communicating <SEP> without <SEP> thread <SEP> the <SEP> <SEP> image <SEP> data generated by <SEP> by <SEP> <SEP> <SEP> structure> generator / manager; <SEP> the <SEP> network <SEP> of <SEP> communication <SEP> by <SEP> cable <SEP> (210) <SEP> transmitting <tb> by <SEP> the <SEP> intermediate of a <SEP> line <SEP> of <SEP> communication <SEP> by <SEP> cable <SEP> <SEP> data <SEP> generated <SEP> image by <SEP> the <SEP> <SEP> structure of <tb> and <SEP> one <tb> multiplicity <SEP> of <SEP> <SEP> devices <SEP> <SEP> visualization of <SEP> images (212, <SEP> 213) <SEP> for <SEP> present <SEP> in <SEP> output <SEP> the <SEP> <SEP> image <SEP> data transmitted <SEP> by <SEP> the <SEP> <SEP> <SEP> network <SEP> communication without <SEP> thread <SEP> (208) <SEP> and <SEP> the <SEP> network <SEP> of <SEP> communication <SEP> by <SEP> cable <SEP> (210). <tb> 10. <SEP> System <SEP> of <SEP> visualization <SEP> of images <SEP> according to <SEP> the <SEP> claim <SEP> 9, <tb> characterized <SEP> in <SEP> this <SEP> that <SEP> <SEP> <SEP> structure <SEP> generator / manager <SEP> (206) <SEP> com takes <SEP>: < SEP> <SEP> <SEP> <SEP> <SEP> <SEP> Registration Unit <206 <SEP> for <SEP> <tb> <SEP> image data <SEP> from <SEP> <SEP> <SEP> <SEP> vendors <200>. <SEP> of <SEP> the <SEP> governmental <SEP> central <SEP> organization (202) <SEP> and <SEP> of the <SEP> reporters <SEP> (204): <SEP> one <SEP > unit <SEP> <SEP> <SEP> Orders <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> <SEP> Record <SEP> <tb> <SEP> <SEP> orders <SEP> <SEP> image <SEP> <SEP> orders <SEP> <SEP> <SEP> providers <SEP> <SEP> <SEP> > of <SEP> the organization <SEP> governmental <SEP> central <SEP> (202) <SEP> and <SEP> of <SEP> reporters <tb> (204): <SEP> A <SEP> <SEP> <SEP> Registration Unit of <SEP> <SEP> Data <SEP> <SEP> Code <SEP> Code (206d) <tb> for <SEP> to save <SEP> <SEP> <SEP> <SEP> <SEP> code <SEP> <SEP> <SEP> <SEP> data <tb> information <SEP> (200), <SEP> of <SEP> the organization <SEP> government <SEP> central <SEP> (202) <SEP> and <SEP> of <tb> reporters <SEP> (204); <SEP> a <SEP> microprocessor <SEP> (206e) <SEP> for <SEP> process <SEP> the <SEP> data <SEP> registered <SEP> in <SEP> the <SEP> unit of <SEP> <SEP> recording of images <SEP> (206b), <SEP> the <SEP> unit of <SEP> recording <SEP> orders of <SEP> <SEP> <SEP> (206c) <SEP> and <SEP> <SEP> <SEP> record <SEP> <SEP> data <SEP> <SEP> <SEP> code (206d). <SEP> and <SEP> for <SEP> issue <SEP> the <SEP> results <tb> processed <SEP> to <SEP> the <SEP> network <SEP> of <SEP> communication <SEP> by <SEP> cable <SEP> (210); <SEP> and <SEP> a <SEP> unit <tb> record <SEP> of <SEP> program <SEP> (206f) <SEP> for <SEP> save <SEP> a <SEP> program <tb> for <SEP> the <SEP> command <SEP> of <SEP> microprocessor <SEP> (206e). <tb> 11. <SEP> System <SEP> of <SEP> visualization <SEP> of images <SEP> according to <SEP> the <SEP> claim <SEP> 9, <tb> characterized <SEP> in <SEP> this <SEP> as <SEP> the <SEP> network <SEP> of <SEP> communication <SEP> by <SEP> cable <SEP> (210) <SEP> com - takes: an image recording unit (210a) for recording image data from the generator-manager structure (206); an image display command recording unit (210b) for recording image display commands from the generator / manager structure (206); a microprocessor (210c) for processing the data recorded in the image recording unit (210a) and the image display command recording unit (210b); a program recording unit (210d) for recording a program for microprocessor control (210c); a plurality of modems (210f-210h), each of which is for transmitting image data to a corresponding one of the image display devices (214-216); and a multiple port (210e) for transmitting to a specific modem the data processed by the microprocessor (210c).