FI88758C - Electronic communication system - Google Patents

Description

1 88758

Electronic display system

The invention relates to an electronic display system for displaying, for example, price and product information in a store environment, the display system comprising a plurality of display units located on different sides of the store and a central station for selectively transmitting display information to each display unit.

The price of the product for sale is currently shown on a price tag attached to the product-10 or, alternatively, on a price tag placed in the immediate vicinity of the product, for example on a shelf. Common to known systems is that changing the price or other product information presented requires manually changing the information to go to the location of the product. With the new cash register systems, various product codes have also been introduced, the input of which to the cash register terminal automatically gives the right price. Therefore, it is more advantageous for the store to place the product code on the product than on the price of the product, but on the other hand only if the product code is used, the buyer loses the opportunity to compare prices.

The present invention relates to a display system which makes it possible to display and change product information on a display located close to the product under the control of a cash register or other computer system. It further seeks to enable active pricing and thus the automation of margin control, which is carried out, for example, using an expert system.

This object is achieved by a system according to the invention, characterized in that the system further comprises at least one base station having a radio connection with the central station and including radio reception means according to the mode of communication used by the central station, common to a plurality of display units in the vicinity of the base station. via a common signal bus in connection with the base station, each display unit responding only to those signals transmitted on the signal bus whose address information corresponds to a predetermined address code of the display unit.

The basic idea of the invention is that a system, e.g. a cash register system, can send a signal message to all displays, which contains at least the address code and the display information to be displayed on the display. Each display 10 compares the received address code with a predetermined address code and displays the received display information when the codes match. This allows you to selectively change the content of a particular display.

The display address code can be the same as the product code of the product 15 for which it displays the price, so that the display content can be updated automatically while the price information corresponding to that product code is changed in the cash register system.

It is also an object of the invention to provide an inexpensive, compact display which can be placed, for example, on the edge of a shelf. Therefore, in a preferred embodiment of the invention, a plurality of displays, e.g. 10 to 150, have a common base station which includes part of the receiving devices and a power supply.

The system according to the invention makes it possible to easily change the mode of communication between the base station and the base station according to the above-mentioned alternatives by changing the transmitter / receiver units of the base and base stations without having to interfere in any other way with the system.

If the data transmission between the base station and the monitor or between the base station and the base station takes place wirelessly, the need for cabling is considerably reduced and the system becomes more flexible. The data-35 transmission between the base station and the displays takes place via a common bus. Simplifying the display unit by 3 '^ / L 8 reduces the cost of the display unit and thus the entire system.

The invention will now be described in more detail with reference to the accompanying drawing, in which Figure 1 shows a block diagram of a display system according to the invention, Figure 2 shows a block diagram of another display system according to the invention using base stations, Figure 3 shows a more detailed block diagram 10 B and C ', Fig. 5 illustrates the placement of the system of Fig. 2 on a shelf, and Fig. 6 illustrates the attachment of a display unit to the edge of the shelf.

In Figure 1, a computer system is connected to a base station A which includes a radio transmitter / receiver. The address and Product Information 20 from the computer system are modulated to the desired radio frequency and sent to the display units C1-Cn. Alternatively, the data transmission can take place using another transmission method, such as infrared transmission or even via a cable connection. The structure of the base station A then varies depending on the transmission method and the signal format. In the preferred embodiment described, however, wireless radio frequency transmission is used without limiting the invention.

In Figure 1, each display unit C independently receives the transmitted radio frequency signal. The display unit C can then be as shown in Fig. 3. The radio frequency signal is received by the antenna 313 and detected at the receiver 310. In the preferred embodiment, the detected signal is an audio frequency signal in which the frequency corresponding to the logic level 4 and the frequency corresponding to the logic level 1 alternate between the 35 serial bit data to be transmitted. In this case, the audio frequency signal, after detection, is rectified, amplified, and strongly limited at the receiver 310 so that it can be passed to the recognition and synchronization block 315, which converts the signal into a serial pulse train. The pulse train is input to a comparison block 317 and a transmission memory 318. The comparison block 317 identifies frame synchronization and address data, such as store and commodity addresses, from the pulse train. If the address preset in the display unit 10 matches the received address, the information portion of the received signal, such as the price, is stored in the display memory 319. The reading in the display memory 319 is always displayed on the display unit number display 320, which is preferably a liquid crystal display. When the reference block 317 accepts the received signal, the transmission memory 318 supplies the received pulse train to the transmission logic 316, which converts the pulse train back into an audio signal. The transmission logic 316 supplies an audio signal to the transmitter 311, which transmits the radio frequency message 20 as an acknowledgment back to the base station A. The comparison block 317 controls the transmission of the acknowledgment by the control signal TXON. With the acknowledgment, the base station knows that the signal has been received and placed in the correct format in the display memory.

25 The compact display unit C shown in Figs. 1 and 3

to allow flexible use, each display unit must generally have its own power supply, preferably a battery. In this case, the battery replacement interval must be long enough. The high-frequency components of the display unit are the most significant in terms of power consumption. The display unit therefore has a timer 314 which repeatedly switches the receiver 310 for short periods of time for listening. This can happen, for example, once a minute for 1 ms. Control is via the RXON signal. Only the timer 35 314, the display memory 319 and the display 320 are active between listening periods.

5: a 7: B

the presence of a carrier is detected, the receiver 310 remains on for the time being, and the detection and synchronization block 315, the reference block 317, and the transmission memory 318 are turned on. If the display unit detects the signal assigned to it, the transmitter 311 and the transmission logic 316 are switched on during the acknowledgment transmission. The display unit returns to power save mode after the carrier is lost or acknowledged.

When each display unit has its own receiver-10, problems arise in receiving a radio frequency signal. The display unit aims at a compact structure, so that the maximum length of the antenna used is small, e.g. 10 cm. However, in the 230 MHz range, for example, the shortest effective antenna (efficiency about 95%) is about 32 cm long. The efficiency of a 10 cm long antenna with only 1 to 5% of the antenna of a compact display unit may therefore cause the following problems: 1. Poor efficiency.

2. The input impedance of the antenna becomes very low 20 (0.1 ohm - 5 ohm), whereby the impedance matching becomes narrowband, high loss and difficult to implement small - ..! under construction.

3. Interference to the logic caused by the RF field of the antenna.

25 4. Strong influence of the shelf edge and the proximity of objects on the shelves to the directional pattern and impedance of the antenna.

5. The effect of the physical location of the monitor on the direction pattern and impedance of the antenna.

.30 6. Mechanical implementation of the antenna in connection with the rest of the display.

7. For each display unit, the field strength is different depending on the above reasons.

Also in the infrared application, the system according to Figure 1 • 35 can cause problems, because the necessary "line of sight" between the base station and the 6/8 8 display unit is difficult to implement for all display units.

Figure 2 shows another display system according to the invention, in which the base station A communicates with the display units C 1 -C 3, via separate base stations B. In this second embodiment of the invention, the transmission connection between the base station A and the base station B is a radio connection, as was also the case in Fig. 1. Each base station B is associated with a number of display units via a common bus 20. In the preferred embodiment, the structure of blocks B and C of Figure 2 is as shown in Figure 4. Each base station B now comprises at least an antenna 413, a receiver 410, a transmitter 411 and a timer 414, the structure and operation of which are the same as in the corresponding blocks in Fig. 3.

15 When the receiver 410 detects a carrier during the listening period, it sends a wake-up signal to the bus, which turns on the detection and synchronization block 415, the reference block 417 and the transmission memory 418 in each display unit C '. Then, upon receiving 20 radio frequency messages, 310 in Fig. 3 and sends an audio frequency signal to bus 20. Each display unit C 'receives a signal from bus 20 to detection and synchronization block 415, which converts the signal to a digital pulse train applied to reference block 417 and transmission memory 418. Comparison block 417 compares to the set address code, and when the codes match, input the information portion of the received signal to the display memory 419, the contents of which si-30 are displayed on the display 420. When the reference block accepts the received signal, the transmission memory 41 8 feeds the received pulse train to the transmission logic 416, which converts it back into an audio signal which is fed to bus 20. Transmitter 411 of base station B receives this 35 acknowledgment signal from bus 20 and transmits it in radio frequency 7 ^ ?: 8 modulated back to the base station.

The advantage of the solution according to Figures 2 and 4 is e.g. that the common base station B can be located in a location advantageous for communication with the base station A, such as at the top of a shelf. Further, since one base station B serves a large number of displays C, the use of simpler and thus cheaper display units lowers the cost of the entire system. In addition, the transmitter / receiver of the base station can be made more efficient than the transmitter / receiver of 10 individual display units, whereby the reliability is improved. The power supply to the displays can also be handled as a DC supply from base station B using bus 20. In this case, the batteries can be omitted from the display units.

Figure 5 is a simplified illustration of the system of Figure 2 applied to a conventional store shelf. The base station B is located at the top of the shelf and is connected via a bus 20 to a number of display units C '. The display units C 'are located at the edges of the shelf levels at the corresponding products. The displays C are preferably secured to the edge of the shelf by a special rail 601 shown in Figure 6. The rail 601 comprises a base plate attached to the edge of the shelf 605 with contact portions 604 for the connector portions 604 of the display units C 'wired inside the rail.

The support frames 602 hold the display against the base plate 603. The rail 601 is preferably the entire length of the shelf, so that several displays C 'can be easily installed in parallel without separate wiring. The rails can be cut to the desired length 30 and have a male rail connector 606 at the beginning and a female rail connector 607 at the end, to which a second rail 603 or bus 20 can be connected.

In the embodiments shown, the received signal includes, in addition to the bit and frame synchronization sequences, 35 3-bit store addresses, 10-bit product addresses, and 8 'R 7: 3 16-bit (4 digits) product information. When nearby stores have different store addresses, the radio signal transmitted by the base station of the neighboring store does not affect the display units of the other store, even if they receive a sig-5 signal and use the same, possibly standardized, product codes.

The figures and the related explanation are only intended to illustrate the invention. The details of the display system according to the invention may vary within the scope of the appended claims. In addition to stores, the invention can also be used elsewhere when such a distributed selective display system is required to display numerical or alphanumeric information.

Claims (5)

9 δ δ 7 L 8 An electronic display system for displaying, for example, price and product information in a store environment, the display system comprising a plurality of display units (C ') located across the store and a central station (A) for selectively transmitting display information to each display unit, characterized in further comprising at least one base station (B); having a radio connection with the 10 central stations and comprising radio reception means according to the mode of communication used by the central station (A), common to a plurality of display units (C ') located in the vicinity of the base station (B) and connected to the base station 15 (B) via a common signal bus (20), each display unit (C ') reacting only to those signals transmitted on the signal bus whose address information corresponds to a predetermined address code of the display unit (C'). A system according to claim 1, characterized in that each display unit (C, C ') has transmitter means (416,418) for transmitting the received signal as an acknowledgment back down the signal bus (20) to the base station (B) if the received address information corresponds to the display unit address code, and -25 ma (B) comprises transmitter means (411) for transmitting a signal transmitted by the display unit to the base station (A). A system according to claim 1 or 2, characterized in that the base station (310,410) comprises timer means (314,414) for switching the base station to reception for short periodically recurring periods. System according to one of the preceding claims, characterized in that the display units (C) are fastened to a rail (603) mounted on the front edge of the product shelf (605), which comprises a connection for the display unit (C). For PR 7: 8 timers, connector parts connected to the bus (20) inside the rail (603) so that a plurality of display units can be mounted in parallel on the rail. A system according to claim 4, characterized in that a male rail connector (607) is mounted on one end of the rail (603) and a corresponding rail connector (606) is mounted on the other end. wherein a second rail (603) or other portion of the bus (20) is connectable to each end of the rail. 10 n Gä / CÖ