FR2953966A1 - ELECTRONIC SHELT LABEL SYSTEM HAVING AN ALARM FUNCTION BASED ON MAGNETIC FIELD DETECTION - Google Patents

Abstract

An electronic rack tag system (20) having a wake-up function by magnetic field detection, which detects a magnetic field emitted by an input unit (10) and thereby allows a electronic rack label in a standby mode to wake up automatically when the input unit (10) is present near the electronic rack label. The electronic rack label system (20) includes an input unit (10) having a magnetic field generating unit (11) generating a magnetic field in a surrounding area, and an electronic rack tag having a unit of magnetic field detection (21) detecting the magnetic field generated by the magnetic field generation unit (11), and a communication module (22) waking the input unit (10) and communicating with the latter when the magnetic field is detected by the magnetic field detection unit (21).

Description

The present invention relates to an electronic rack label (ESL) system, and more particularly, to an ESL system having an alarm function by means of an electronic racking system (ESL). a magnetic field detection, which detects a magnetic field emitted per input unit and thereby enables an electronic rack label in a standby mode to wake up automatically when the input unit is present near the electronic rack label.

In general, an electronic rack label (ESL), which is also referred to as an "electronic tag", is an electronic display device that replaces a paper tag to display information (for example, prices) relating to goods on a store shelf. The electronic rack tag may include a display unit (e.g., a liquid crystal display (LCD), electronic paper, or the like) for visually displaying information about goods, and a communication unit for receiving and process data for goods having variable information. Many kinds of merchandise can be displayed in a store to which the electronic rack label system is applied, and thus, it is virtually impossible to continuously supply energy to all electronic rack tags from an external source. Therefore, the electronic rack label is powered by a button cell or similar device. As a result, it is very important to reduce the consumption of the electronic rack label even in order to continuously use the electronic rack label for several years (eg, 5 years or more) while using only one battery. Typically, in order to minimize power consumption, power is supplied to the electronic rack label only if necessary, and as a result the electronic rack label makes communications or updates a display unit. . If there is no need to communicate or update the display unit, the electronic rack label operates in a sleep mode (for example, energy is consumed only for a display unit maintains the display of information, but the power supply for a communication unit is cut off during which the energy consumed is minimal. When the electronic shelving tag operates in the sleep mode, the electronic shelving tag should be able to wake up from sleep mode to receive new data. To awaken an electronic racking tag, prior art methods are known which include periodically waking an electronic rack tag at a predetermined time by a communication network applied to the electronic rack tag. the prior art is to awaken an electronic rack label by a manual trigger, performed by a department manager, a wake-up switch using the alarm switch present in the electronic racking label. In the state of the art, it is also well known to combine the two aforementioned methods. According to the prior art method of periodically waking up the electronic rack label, the electronic rack label wakes up periodically even in the case where data communication is not required. On the other hand, since a wakeup period should be very short in order to immediately carry out the data communication in a desired time, unnecessarily frequent awakenings require a large amount of energy, resulting in a decrease in the life of the battery the electronic rack label. Similarly, the method of the prior art of performing the awakening of the electronic rack label by manually triggering a switch has a problem in that the operation is too complicated and misguided because an operator must trigger a plurality of electronic rack tags one after the other. Therefore, in the present technical field, it is necessary to develop an electronic rack label system having functions not only capable of automatically awakening an electronic rack label immediately after a request from a user, but also rendering minimum power consumption. One aspect of the present invention is an electronic rack label (ESL) system that can automatically wake up an electronic racking label from a standby mode without an operator-separated trigger when a portable input unit is present at a standby mode. near the electronic rack label.

In accordance with one aspect of the present invention, there is disclosed an electronic rack label system having an alarm function using a magnetic field detection and comprising: an input unit having a generation unit magnetic field generating a magnetic field in a neighboring region; and an electronic racking tag having a magnetic field sensing unit detecting the magnetic field generated by the magnetic field generating unit, and a communication module waking up the input unit and communicating with it when the magnetic field is detected by the magnetic field detection unit. The communication module may further comprise: a power supply unit providing a supply voltage or a supply current; a switching unit allowing the supply voltage or the supply current supplied by the power supply unit to be available when the magnetic field is detected by the magnetic field detection unit, and to be switched off when the field magnetic is not detected by the magnetic field detection unit; and a transceiver operating upon receipt of the supply voltage or supply current by the switching unit, and communicating with the input unit. The magnetic field detection unit may be a Hall effect sensor comprising a Hall effect device generating a voltage corresponding to an intensity of a magnetic flux when the magnetic flux is generated. The communication module can wake up according to the voltage generated by the Hall effect device. The magnetic field detection unit may repeat an alarm mode and a sleep mode in a first period, and the communication module may repeat an alarm mode and a sleep mode in a second period longer than the first period. These and other aspects, features and advantages of the invention will become more clearly apparent on reading the following description, with reference to the accompanying drawings, in which: FIG. 1 is a diagrammatic view illustrating a environment in a store adopting an electronic rack label (ESL) system according to an embodiment of the present invention; Fig. 2 is a block diagram of an electronic rack tag system according to an embodiment of the present invention; Fig. 3 is a circuit diagram of a magnetic field sensing unit adopting an electronic rack tag system according to an embodiment of the present invention; and Fig. 4 is a flowchart illustrating an exemplary operation of an electronic rack tag system according to an embodiment of the present invention. Exemplary embodiments of the present invention will now be described in detail with reference to the accompanying drawings.

The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments presented herein. More exactly, these embodiments are provided so that this disclosure is thorough and complete, and will fully convey the scope of the invention to those skilled in the art. In the drawings, the thicknesses of the layers and regions are exaggerated for the sake of clarity. Identical reference numerals in the drawings designate identical elements, and their repeated description will be omitted. Fig. 1 is a schematic view illustrating a shop environment adopting an electronic rack label (ESL) system according to an embodiment of the present invention. With reference to FIG. 1, the electronic rack label system according to the embodiment of the present invention may include an electronic rack label displaying information on corresponding displayed goods on a site displayed on a display shelf. a magazine, 7 and a portable input unit 10 communicating with the electronic rack label 20 to input data for updating information displayed in a display unit of the electronic rack label 20. According to the illustration of FIG. 1, the embodiment of the present invention relates to an electronic rack label system allowing an electronic racking tag in a standby mode to be automatically woken up when an operator brings the portable entry 10 near the target electronic shelving label 20 to enter new donations born in the electronic rack label 20.

Fig. 2 is a block diagram showing in detail an electronic rack tag system according to an embodiment of the present invention. With reference to FIG. 2, the electronic rack label system according to the embodiment of the present invention may include an input unit 10 and an electronic rack label 20. The input unit 10 is designed to enabling an operator to enter data into the electronic racking tag 20, and may include a magnetic field generation unit 11 generating a magnetic field used to wake up a communication module 22 of the electronic rack tag 20. Likewise, the input unit 10 may further include an input device 12, such as a keyboard receiving operator manipulation, 8 a microprocessor (MCU) 13 performing a control operation with respect to the manipulation. of the operator received through the keyboard, and a transceiver 14 being controlled by the microprocessor 13 to wirelessly communicate with the electronic racking label 20. The magnetic field generating unit 11 may employ a permanent magnet capable of continuously generating a magnetic field with a magnetic flux whose intensity is required to awaken the communication module 22 of the electronic rack label. or an electromagnet that generates a magnetic field with a magnetic flux whose intensity is required to awaken the communication module 22 of the electronic rack label when a current is applied by manipulation of an operator. In addition, the magnetic field generation unit 11 may also employ a large number of well-known units capable of generating a magnetic field. The electronic racking tag 20 may include a magnetic field detecting unit 21 detecting a magnetic field generated by the magnetic field generation unit 11 of the input unit 10, and the communication module 22 communicating with the input unit 10 when the magnetic field is detected by the magnetic field detection unit 21. Furthermore, the electronic rack label 20 may comprise, in addition to the magnetic field detection unit 21, a power supply unit 23 supplying a supply voltage or a supply current to the communication module 22 and / or an LCD screen control unit 24, and an LCD screen 25 displaying information for goods. The magnetic field detecting unit 21 detects the magnetic field generated by the magnetic field generation unit 11 when the input unit 10 is brought into proximity. The magnetic field detection unit 21 may employ various devices capable of detecting a peripheral magnetic field, i.e., a change in a magnetic flux. The magnetic field detection unit may be configured with a Hall effect sensor having a Hall effect device that generates a voltage corresponding to a change in intensity of a magnetic flux. Fig. 3 is a circuit diagram of a magnetic field sensing unit adopting an electronic rack tag system according to an embodiment of the present invention, which figure merely shows a Hall effect sensor. With reference to FIG. 3, the Hall effect sensor 21 may comprise a Hall effect device 211. The Hall effect device 211 may be configured by a conductor or a semiconductor to which the power supply unit 23 is applied. supply voltage or supply current. Current flows along the surface of the Hall effect device 211 in a predetermined direction (for example, it flows from the ground to terminal Vdd in Fig. 3). When a perpendicular magnetic flux is generated on the surface of the Hall effect device 211, a current flows to the Hall effect device 211 and an electromotive force, i.e. a voltage Vo, is generated at terminals of the Hall effect device 211 in a direction perpendicular to the magnetic flux. In this way, the Hall effect sensor 21 detects a magnetic flux generated by the magnetic field and outputs it as a voltage. The magnetic field detection unit 21 may repeat a sleep mode and an alarm mode in a first predefined period to reduce power consumption. That is, the magnetic field detection unit 21 repeats the standby mode and the wake-up mode by periodically supplying and cutting a supply voltage or a supply current for the magnetic field detection unit 21. Since the communication module 22 should wake up immediately as requested by a user, the wakeup time of the magnetic field detection unit 21 can be set to a relatively short value. The communication module 22 may comprise a switching unit 221, a microprocessor (MCU) 222 and a transceiver 223. The switching unit 221 allows a supply voltage or a supply current supplied by the power supply unit 23 is supplied or cut off according to the detection of a magnetic field by the magnetic field detection unit 21. The microprocessor 222 operates upon receiving the supply voltage or the supply current by the switching operation of the switching unit 221, and controlling the entire operation of the electronic rack label 20. The transceiver 223 operates upon receipt of the power supply voltage or the power supply. power supply current caused by the switching operation of the switching unit 221, and is in wireless communication with the input unit 10. The switching unit 211, the MCU 222 and the transmitter-receiver r 223 can be integrated into a single chip such as a SoC.

The switching unit 221 can supply or cut off the supply voltage or the supply current supplied by the power supply unit 23 to the transceiver 223 or the MCU 222 in response to a control signal input. by the magnetic field detecting unit 21. That is, in the case where the magnetic field detecting unit 21 is configured with the Hall effect sensor according to the illustration of FIG. output voltage Vo outputted from the Hall effect sensor may serve as a control signal of the switching unit 221. If the output voltage Vo outputted from the Hall effect sensor is greater than a predefined reference voltage, the switching unit 221 determines that the input unit 10 is present at a neighboring position of itself, and connects the power supply unit 23 to the transceiver 223 and the MCU 222. Thus, the supply voltage or the supply current It is provided to transceiver 223 and MCU 222 to thereby awaken communication module 22. In contrast, if the output voltage Vo outputted from the Hall effect sensor is less than the voltage of preset reference, the switching unit 221 allows the supply voltage or supply current supplied by the power supply unit 23 to be cut off, which allows the communication module 22 to enter the standby. The electronic rack label system may operate as a wireless communication network in conjunction with a data receiving mode by one-to-one communication with the input unit 10 of an operator. In this case, the communication module 22 can operate according to an alarm period defined by a communication protocol for the wireless communication network.

Since the immediate data input can be performed using the method of the invention, a wakeup period (second period) for the wireless communication network is set to be relatively long, making it possible to increase the duration of the wavelength. a sleep mode of the communication module 22. In comparison with the first period, that is to say the waking period of the magnetic field detection unit 21, the second period can be very long. It is even possible to set the second period and wakeup period for a network according to the embodiment of the present invention longer so that the life of the battery of the electronic rack tag can be further lengthened. For example, the magnetic field detection unit 21 configured with the Hall effect sensor requires a current amount of only a few microamperes 13 for the alarm clock, while the communication module (SoC) 22 having the MCU 222 and transceiver 223 require several tens of milliamps to wake up. Accordingly, according to the embodiment of the present invention, since the wakeup time of the communication module 22 can be set long and the wakeup period of the magnetic field detection unit 21 can be set short, it is possible not only to enter real-time data immediately, but also to significantly increase a practical life of a battery used for the electronic rack label 20. The control unit of the LCD screen 24 receives the supply voltage or the supply current of the power supply unit 23, and determines the content displayed on the LCD screen 25 to thereby control the LCD screen 25. The displayed content or the brightness of the LCD screen 25 can be determined according to a control signal of the LCD control unit 24. Although Fig. 2 illustrates by way of example the LCD screen 25 as a display unit , others a The display units, such as electronic papers which are well known in the present technical field, may be substituted for the LCD 25, and accordingly the control unit may also be appropriately modified to control the unit. substitution display. Fig. 4 is a flowchart illustrating an exemplary operation of an electronic rack tag system according to an embodiment of the present invention. The functions and effects of the electronic rack label system according to the embodiment of the present invention will be described below with reference to the accompanying drawings. According to the illustration of FIG. 4, when an operation starts by supplying energy to the electronic rack label 20 in a non-powered state, a supply voltage or a supply current is supplied to all electronic devices included in the electronic rack label 20 from the power supply unit 23 to perform the initialization (S41).

After completion of the initialization operation (S41), a transceiver operation for receiving data relating to the contents to be displayed on the LCD screen 25 is performed by the transceiver 223 (S42). , and the information corresponding to the data received by the LCD control unit 24 is updated for the LCD screen (S43). The data transmission / reception operation (S42) can be performed by the wireless communication network of which the electronic racking tag 20 is part, or by a portable input unit 10 of a spoke manager, such as the electronic rack label system according to the embodiment of the present invention. During the initialization operation (S41), the data transmission / reception operation (S42) and the update operation of the LCD screen (S3), the switching unit 221 retains its connection state so that the power supply unit 23 provides the supply voltage or the supply current to the MCU 222 or the transceiver 223.

When the initialization operation (S41), the data transmission / reception operation (S42) and the update operation of the LCD screen (S3) are performed, the information for the goods to be displayed on the LCD 25 of the electronic rack label 20 are displayed. Then, the switching unit 221 interrupts the supply voltage or the supply current supplied by the unit power unit 23, allowing the communication module 22 to enter a sleep mode (S44). The sleep mode duration (S44) can be determined according to the second period, i.e. the wakeup period determined by a wireless communication network included in the electronic rack label 20. Thus, during the standby (S44), the magnetic field detection unit 21 attempts to detect a peripheral magnetic field while waking repeatedly on each first period. According to the illustration of FIG. 4, if the sleep mode is continued according to the second defined period even after the sleep mode duration (S45), the magnetic field detection unit 21 tries to detect a peripheral magnetic field (S46) . If the magnetic field detecting unit 21 detects a magnetic field, the switching unit 221 can wake up the communication module 22 by supplying the supply voltage or the supply current to the MCU 222 16 and to the transmitter receiver 223 from the power supply unit 23 (S47). The wok-up communication module 22 determines whether or not data to be transmitted by the neighboring input unit 10 exists (S48). If there is data, the data transmission / reception operation (S42) is performed, and if there is no data, the communication module 22 goes back to standby mode (S44).

Even after the sleep mode is not continued according to the second predefined period after the sleep mode time (S45), the switching unit 221 can wake the communication module 22 by supplying the supply voltage or the current. supplying the MCU 222 and the transceiver 223 from the power supply unit 23 (S47). Similar to the wakeup operation by the magnetic field detection unit 21 described above, the wok-up communication module 22 determines whether or not data to be transmitted from the neighboring input unit 10 exists (S48). If there is data, the data transmission operation (S42) is performed, and if there is no data, the communication module 22 goes back to standby mode (S44). According to the embodiment of the present invention, an electronic rack tag can wake up automatically by detecting a magnetic field generated by an input device without manual triggering when the input unit transmitting data is present in the vicinity of 17. the electronic rack label, thereby reducing the tedious operations of an operator. Additionally, according to the embodiment of the present invention, an electronic rack tag may be woken up by a magnetic field sensing unit having a short wakeup period when data transmission is required and, therefore, transmission. data can be immediately performed. Moreover, since the energy consumed to wake up the magnetic field detection unit is significantly smaller than the energy consumed to wake up a communication module itself, the power consumption of an electronic rack label can be minimized, which makes it possible to extend the life of the battery. Although the present invention has been presented and described in conjunction with the exemplary embodiments, it should be apparent to those skilled in the art that modifications and variations can be made without departing from the spirit and scope of the invention. invention as defined by the appended claims.

Claims (5)

REVENDICATIONS1. An electronic rack (ESL) tag system (20) having an alarm function characterized in that said alarm function is based on a magnetic field detection, and that the electronic rack label system (20) comprises: an input unit (10) comprising a magnetic field generating unit (11) generating a magnetic field in a neighboring region; and an electronic rack tag comprising a magnetic field sensing unit (21) detecting the magnetic field generated by the magnetic field generating unit (11), and a communication module (22) waking the input unit (10) and communicating with said input unit (10) when the magnetic field is detected by the magnetic field detection unit (21). An electronic rack label system according to claim 1, characterized in that the communication module (22) further comprises: a power supply unit (23) providing a supply voltage or a supply current ; a switching unit (221) allowing the supply voltage or the supply current supplied by the power supply unit (23) to be outputted when the magnetic field is detected by the detection unit magnetic field (21), and to be cut off when the magnetic field 19 is not detected by the magnetic field detection unit (21); and a transceiver (223) operating when it receives the supply voltage or the supply current through the switching unit (221), and communicating with the input unit (10). An electronic rack label system according to any of claims 1 and 2, characterized in that the magnetic field sensing unit (21) is a Hall effect sensor comprising a Hall effect device (211). generating a voltage corresponding to an intensity of a magnetic flux when the magnetic flux is generated. An electronic rack label system according to claim 3, characterized in that the communication module (22) wakes up according to the voltage generated by the Hall effect device (211). An electronic rack tag system according to claim 1, characterized in that the magnetic field detection unit (21) repeats an alarm mode and a standby mode in a first period, and the communication module (22) repeats an alarm mode and a sleep mode in a second period longer than the first period.