JP2011510596A - Wireless communication system and wireless communication method - Google Patents

Abstract

An electronic shelf label management system includes a server and a plurality of base stations each associated with a group of electronic shelf labels (ESL). Each base station communicates wirelessly with its group of ESLs that are all within the coverage area of that base station. Preferably, the server repeatedly communicates with different base stations in a period that does not overlap.
[Selection] Figure 2

Description

The present invention relates to a wireless communication system that wirelessly manages a plurality of remote information devices and a wireless communication method used therefor. More particularly, the present invention is applicable to managing electronic shelf label (ESL) systems of the type commonly used in supermarkets and department stores.

  Electronic shelf labels (ESL) are used to display prices and other information and manage inventory in stores and warehouses where goods are sold. For example, in a supermarket, an ESL is attached so that different products can be seen on a shelf. When changing the product price, the new price can be displayed “immediately”. In general, ESLs are grouped, and each group receives a service from each base station by radio, and the base station is connected to an ESL server. The base station communicates with the ESL, for example, wirelessly.

Many factors prevent the reliable operation and management of ESL in such systems.
For example, transmission and reception between the base station and the ESL may be difficult depending on the physical structure and layout of the store. These are due to the physical structure of the building and the placement of the ESL. For example, it is known that a standing wave is generated at a physical position to create a transmission / reception dead spot. Furthermore, the ESL is at various distances from the respective base stations, and the effect becomes weaker as the distance increases. It is also important to be able to detect inadequate ESL operations and malfunctions as soon as possible.

The present invention broadly aims to solve the above-described problems in existing wireless communication systems and wireless communication methods for managing wireless remote information devices. It is to minimize or eliminate communication failures, especially due to physical structure and site layout.
An object of the present invention is to increase the reliability of data communication in a site where a standing wave tends to be generated at a specific carrier frequency in such a wireless communication system.
Another object of the present invention is to increase the reliability of data communication in an ESL unit that is farthest from a base station in a group or overlaps with an area of a different base station.

A further object of the present invention is to increase the reliability of ESL and the detection speed of insufficient operation and malfunction.
The purpose of the invention is also reliable and and convenient in use, it is to provide a relatively inexpensive improved wireless communication system and a wireless communication method.

According to the present invention, a wireless communication system for a remote information device such as an electronic shelf label management system includes a server and a plurality of base stations each linked to a group of information devices such as an electronic shelf label (ESL). including. Each base station communicates wirelessly with ESLs in that group, all within the base station's scope. The server preferably communicates repeatedly with different base stations during non-overlapping periods.

  According to the present invention, the information device performs bidirectional communication with the base station. When the information device receives the information correctly, it responds with a confirmation signal. If the data is not received correctly, the base station will attempt further transmissions until the information is received correctly or is received incorrectly a predetermined number of times. Each round of information is preferably retransmitted to the ESL at a different carrier frequency. If the communication from the ESL to the base station fails, it is preferable that the communication is successful until the reception is successful or a predetermined number of transmissions are made. A single signal from the base station to the server can include the results of all attempts to one or more ESLs. Preferably, the base station attempts to transmit three times to the ESL at each carrier frequency of 2.41 GHz, 2.45 GHz, and 2.49 GHz. The server will control the carrier frequency applied to a particular ESL by the base station based on past data regarding the validity or invalidity of a carrier frequency to the ESL.

According to another feature of the invention, ESLs in the area of multiple base stations are given an identifier (ID) for each base station. Under the control of the server, if one base station fails or is marginal in data communication, another base station may try.
This not only improves communication reliability, but also enables the best communication state to be maintained by adaptive control. In connection with this feature, the intelligent power control of the base station is considered useful for ESL with distance problems. The server has a history of successes and a history of power levels to various base stations with long-range ESLs, and in addition to switching ESLs between base stations, the server provides the power of the signals applied from base stations to those ESLs. Will control.

  The foregoing brief description and further objects, features, and advantages of the present invention will be more fully understood from the description of the preferred embodiments of the present invention with reference to the accompanying drawings.

It is a functional block diagram of the system S which implemented this invention. 6 is a timing chart showing how N groups of information devices communicate according to an embodiment of the present invention. According to another embodiment of the present invention is a timing chart showing the base station whether the ESL is how to communicate intelligently. It is a flowchart for demonstrating in detail the preferable communication procedure by this invention. FIG. 5 is a schematic diagram illustrating a method for improving data reception by a peripheral ESL according to another embodiment of the present invention. FIG. 2 schematically illustrates a preferred method for dealing with the occurrence of standing waves at a site including a system embodying the present invention. It is a timing chart which shows operation | movement of other embodiment of the system by this invention.

In the drawings, FIG. 1 is a functional block diagram of a system S embodying the present invention. The system is composed of a server 10 and base stations BS1 to BSN having jurisdiction over groups (group 1... N) of electronic shelf labels ( hereinafter abbreviated as “ ESL ”) . Each base station communicates with a plurality of ESLs wirelessly. For example, the base station 1 serves ESL1-1 to 1-m, the base station 2 serves ESL2-1 to 2-n, and the base station N serves ESLN-1 to Np. Generally, each ESL is related to each product on the shelf or in the service area of the ESL, and the price display is changed by price data distributed by communication with the base station .

The base station has an action area R ₁ ... R _N having jurisdiction over planning. As you can see it, ESL1-m is located on the edge of the region R _1, it is slightly overlap in the region R _2.

  According to one embodiment of the present invention, different groups communicate repeatedly during assigned non-overlapping periods to avoid interference between them. FIG. 2 is a timing chart showing N groups communicating in this way. One skilled in the art will recognize that two groups of ESLs can be transmitted simultaneously where the two groups are very separate and no interference can occur between the signals in the two groups. In FIG. 2, it can be seen that data transmission of group 2 does not start until data transmission of group 1 is completed. In general, the time delay between successive group transmissions is on the order of 1 second, and even if there are many groups, a round of transmission to all N groups will be completed in just a few seconds.

  According to another embodiment of the invention, the ESL confirms receipt of new data. This is shown in the timing chart of FIG. 3 and shows data updates for base station 22 including three ESLs 24, 26 and 28. Initially, server 10 sends three sets of data, D_l, D_2 and D_3, containing new information for ESLs 24, 26 and 28, respectively. The data is received by the base station 22, which forwards the data to each ESL. The ESLs 24, 26 and 28 receive the data at successive timings. 21, 23, and 25, ESLs 24, 26, and 28 send ACK (confirmation) signals to base station 22 indicating that new data has been received (assuming that the data was received correctly), and Station 22 sends its confirmation signal to ESL server 10 where it is stored in a suitable storage device 27. Error detection techniques ACK signal is performed in ESL before being sent is well known in the art.

FIG. 4 is a flowchart for explaining the above-described transmission procedure in more detail. The procedure starts at start 100, and at step 102, data is transmitted from the server to each base station. The following steps show the operation of each base station, but it can be assumed that all base stations operate similarly. In step 104, the base station addresses the first ESL and in step 106 sends data to that ESL. When the ESL receives the data correctly, the ESL returns an acknowledgment signal (ACK) to the base station.

In step 108, the base station determines whether an ACK signal has been received from the ESL. If it is determined that it has been received, the success of the ESL is recorded in step 110, and control proceeds to step 112.

If the base station determines in step 108 that it has not received an ACK signal from the ESL, whether or not the base station has transmitted data i times to the ESL in step 114 (the system selects an appropriate value, for example, 3 as the predetermined number of times i). Execute to judge. If it is determined at step 114 that the data has been transmitted i times, the failure to ESL is recorded at step 116 and control proceeds to step 112. If it is determined in step 114 that the data has not been transmitted i times, the control proceeds to step 106, and the base station transmits the next data to the ESL.

In step 112, it executes the determination of whether the address to all the ESL. If not, the base station proceeds to step 118 where the next ESL is addressed, and then proceeds to step 106 where data is transmitted to the new ESL.
If it is determined in step 112 that all ESLs have been addressed, it means that data has been sent to each ESL and the success or failure has been recorded. In that case, the process proceeds to step 120, where the base station prepares the report and transmits it to the server. The procedure ends at end 122.

According to the procedure shown in FIG. 4, each base station receives data from the server and transfers it to each ESL of the base station. The base station determines whether the ESL has actually received data, and if not, retransmits the data to the ESL a predetermined number of times before declaring failure. The results of the procedure Ru are reported to the server. According to the present invention, various steps are taken so that reception is achieved even by ESL that has failed to receive data.
In the flow chart of FIG. 4, the base station is shown to report to the server after addressing all ESLs. One skilled in the art will recognize that individual ESLs can also be reported in real time. In that case, the report will be sent to the server after each of steps 110 and 116, before returning to step 112, and will proceed directly from step 112 to step 122.
The base station thus reports to the server as to whether the transmission to the ESL within the group of base stations was successful or unsuccessful, and reports on multiple transmissions to the ESL with a single or combined signal.

Referring to FIG. 1, ESL1-m is located in the peripheral region R ₁ of the group 1, it will be seen that also the periphery of the group 2 in the region R ₂ of the group 2. The schematic diagram of FIG. 5 illustrates a method for improving data reception by a peripheral ESL such as ESL1-m. Basically, ESL is registered with an identifier (ID) of each group, for example, ID 40 for group 1 and ID 42 for group 2. If data transmission in the first group fails, it will try again in the second group. One skilled in the art will recognize that an ESL can have several groups of adjacent IDs. It is not limited to two groups. Each time the ESL is addressed to an additional group, the likelihood that the data will be received correctly increases.

  In connection with registering one ESL with a plurality of different base stations, intelligent control of the transmission power of the base station by the server is considered useful at the same time. For example, when the transmission to ESL is switched from one base station to another base station, the transmission power level is adjusted based on the cumulative history. Therefore, in the above-described example, when the base stations of group 1 and group 2 are switched between the two groups, the server controls the base stations so as to use the optimum transmission power for ESL.

In another embodiment of the invention, special steps are taken so that data can also be received by an ESL in a “dead spot”. One reason for the occurrence of such a dead spot is that transmission at a specific frequency causes a standing wave due to the structure of the store. If a standing wave occurs at a certain position of the ESL, reception by that ESL will be reduced or impossible. FIG. 6 is a schematic diagram showing a method for dealing with this problem.
Base station 30 is attempting to transmit data to ESL 32. According to the embodiment of the present invention described above, when the base station 30 does not receive the ACK signal from the ESL, the base station 30 tries transmission i times (for example, three times).

  According to another embodiment of the invention, each time the base station 30 retransmits data to the ESL 32 is performed at a different carrier frequency. For example, assume that the frequency of the first transmission is f1. If the base station 30 cannot receive the ACK signal, data retransmission is performed at the frequency f2, and further retransmission is performed at the frequency f3. The generation of dead spots is mainly a frequency phenomenon and can be eliminated by changing the carrier frequency. The three frequencies are preferably 2.41 GHz, 2.45 GHz, and 2.49 GHz.

  When the technique of FIG. 6 is used and the base station 30 transmits one or more times to the ESL 32, the response is successfully received or failed at each frequency. When the base station returns a report to the server, it is preferable to send a signal indicating the success or failure of the response for each frequency alone or in combination.

  Those skilled in the art will also recognize that if data reception fails due to interference from a device near ESL 32, the interference may be reduced or eliminated by changing the transmission frequency. In other words, this technique can improve whenever data transmission failures are based on frequency phenomena. Also, those skilled in the art will know that if an ESL has consistently improved reception reliability at a particular frequency, each base station is adaptively controlled to transmit to that ESL at the carrier frequency that is consistently best. You will see that you get. Similarly, ESL can be controlled to prevent transmission on ineffective frequencies. In general, the server will have a record of information that controls the base station.

  FIG. 7 is a timing chart showing another embodiment according to the present invention. This is compared with the timing chart of FIG. 3, the operation of the system is the same except for the points described below. In this case, when data transmission / reception is not required, the base station and the ESL can operate in the “sleep” mode, so that the operation of the system with higher power efficiency can be obtained.

This is accomplished by using the beacon signal prior to any other information transmitted from the server 20 to the base station 22. After the communication procedure as shown in FIG. 4 is completed, the base station and its ESL time out and enter the sleep mode. When the server 20 transmits the beacon signal 29, the base station is activated and relay beacon signals are sent to the ESLs 24, 26, and 28, respectively. The base station and each ESL are then in standby mode, and then operate as described above with reference to the timing chart of FIG. 3 when the server 20 sends new data.
It will be appreciated that the use of beacon signals achieves significant energy savings since the base station and ESL are in sleep mode except in rare cases where data updates are required. The beacon signal is preferably composed of a time reference that is controlled in conjunction with an accurate reference clock such as that sent from GPS.

The beacon signal can be considered to contain more than just the start signal. For example, as shown in FIG. 6, if the data is retransmitted at a different frequency, the ACK signal storage device 27 will have a history of which transmission frequency is optimal for each ESL. . The beacon signal can also include information from the base station regarding intelligent power control. Before generating a beacon signal for a base station, the server can prepare instructions for the base station regarding which frequency to use first for transmission to each ESL and which frequency to use for subsequent retransmissions. These commands are incorporated into the beacon signal, so that the base station is preset with the optimal frequency to send to each ESL when new data is received.

In FIG. 7 (and FIG. 3), each ESL is shown to report an ACK signal in the case where multiple transmissions to the ESL are utilized to improve reception reliability, eg, FIG. It can be seen that the ESL is actually reporting a failure (NACK signal) at one or more of the transmission frequencies. For operational efficiency, the base station can send one signal that combines information (ACK or NACK) on all of the frequencies transmitted to a particular ESL.

While the preferred embodiment of the present invention has been described with reference to the accompanying drawings, those skilled in the art will recognize that many additions, modifications or replacements are possible without departing from the disclosed invention as defined by the appended claims. You will understand. For example, the actual price data transmitted to the ESL device is set in the server or set at the base station as required. The communication between the ESL device and the base station and server may use any protocol, and the system can operate using one or more servers.

Claims (30)

A system for wireless communication and control with a remote information device at a site,
A computer device as a server;
A plurality of base stations controlled by the server, each having a radio communication area, configured to transmit and receive information wirelessly, and having a duplicate area that repeatedly communicates with the server in a non-overlapping period With base stations,
A plurality of remote information devices each configured to perform two-way wireless communication with the base station within the region of at least one of the base stations, and each base station based on a physical location within the site And an information device assigned to a group that communicates. The system of claim 1, wherein
The information device is an electronic shelf label, and a system that facilitates a change in price display through the communication. The system of claim 1, wherein
The information device is configured to send a signal to the base station regarding whether the information transmitted from the base station has been successfully received or failed, and when the information device fails to receive the information device A system configured to retransmit the information to the information device up to a predetermined number of times. The system of claim 3, wherein
The base station reports to the server as to whether the transmission to the information device within the group of base stations succeeded or failed, and a single or combined signal regarding multiple transmissions to the information device. System configured to do with. The system of claim 3, wherein
The base station transmits information to the information device at an allocated frequency;
A system in which the frequency is changed under the control of the server or base station when retransmission is performed. The system of claim 5, wherein
The base station transmits to the information device up to three times at each frequency of 2.41 GHz, 2.45 GHz, and 2.49 GHz. The system of claim 5, wherein
The base station reports to the server as to whether transmission to the information device within the group of base stations was successful or unsuccessful, and reports a single or combined report regarding multiple transmissions to the information device. And the server is configured to store success / failure information of various frequencies. The system of claim 1, wherein
One of the information devices in the area of one subgroup of the base station is registered to be recognized by each base station in the subgroup;
The server controls the subgroup so that the one information device is switched between the base stations of the subgroup and selectively moves from one to the other in order to improve communication reliability. System that is configured as follows. The system of claim 8, wherein
A system configured such that base stations in the subgroup have transmission power controlled by the server. The system of claim 1, wherein
At least some of the base station and data device are normally in a sleep or power-down state, and the server generates a beacon signal that sends a beacon signal to the base station when communication with the information device is required The base station responds to the beacon signal by activation and transmits a relay beacon signal to an information device in the group upon activation, and the information device activates and receives communication for receiving the relay beacon signal. A system that goes into standby. The system of claim 10, wherein
The information device is configured to send a signal to the base station regarding whether the information transmitted from the base station has been successfully received or failed, and the base station is configured to receive a signal when the information device fails to receive. A system configured to retransmit the information to the information device up to a predetermined number of times. The system of claim 11, wherein
A system in which the base station transmits information to the information apparatus at an assigned frequency, and when the retransmission is performed, the frequency is changed under the control of the server or the base station. The system of claim 10, wherein
One of the data devices within an area of one subgroup of the base station is registered to be recognized by each of the base stations in the subgroup;
The server controls the subgroup so that the one information device is switched between the base stations of the subgroup and selectively moves from one to the other in order to improve communication reliability. System that is configured as follows. A method for wireless communication and control with a remote information device at a site, comprising:
A computer apparatus serving as at least one server, a plurality of base stations controlled by the server, each having a wireless communication area and configured to transmit and receive information wirelessly, and each of the at least one base station Using a system comprising a plurality of remote information devices configured for two-way wireless communication with the base station in a region;
Operating a group of base stations having overlapping regions to repeatedly communicate with the server in a plurality of non-overlapping periods;
Controlling each base station to communicate with one of the groups;
Assigning said information device to a group communicating with a particular base station based on a physical location within the site. 15. The method of claim 14, wherein
A method in which an electronic shelf label is used as the information device and the communication relates to price data distributed in relation to an article price update. 15. The method of claim 14, wherein
A procedure for operating the information device to send a signal to the base station as to whether the information transmitted from the base station was successfully received or failed;
And a step of operating the base station to retransmit the information to the information device up to a predetermined number of times when the information device fails to receive. The method of claim 16, wherein
In addition, the base station reports to the server as to whether the transmission to the information device in the group was successful or failed, and generates a single or combined signal for multiple transmissions to the information device. A method having a procedure to operate to. The method of claim 16, wherein
The method further comprises a step of operating the base station to change the frequency under the control of the server when transmitting information to the information device at an assigned frequency and performing retransmission. The method of claim 16, wherein
When the base station performs the retransmission, a method of transmitting to the information device up to three times at each frequency of 2.41 GHz, 2.45 GHz, and 2.49 GHz. The method of claim 16, wherein
Further, the base station reports to the server as to whether the transmission to the information device within the group of base stations has succeeded or failed, and reports related to multiple transmissions to the information device alone or in combination And a procedure for causing the server to store information regarding success or failure by various frequencies. 15. The method of claim 14, wherein
Registering one of the information devices in the area of one subgroup of the base station to be recognized by each base station in the subgroup;
The one information device is switched between the base stations of the subgroup, and the subgroup is controlled to selectively move from one to the other in order to improve communication reliability. A method of operating a server. The method of claim 21, wherein
A method comprising controlling a base station in the subgroup to have a transmission power controlled by the server. 15. The method of claim 14, wherein
Leaving at least some of the base station and data device normally in sleep or power down state,
Further, a procedure for generating a beacon signal to the base station at the server when communication with the information device becomes necessary;
In response to the beacon signal, the base station is activated and transmits a relay beacon signal to information devices in the group;
The information device is activated by receiving the relay beacon signal and enters a standby state for communication. 24. The method of claim 23, wherein
Operating the information device to send a signal to the base station as to whether the information transmitted from the base station was successfully or unsuccessfully;
And a step of causing the base station to operate to retransmit the information to the information device up to a predetermined number of times if the information device fails to receive. 24. The method of claim 23, wherein
Further, a method comprising operating the base station to change the frequency by controlling the beacon signal when information is transmitted to the information device at an assigned frequency and retransmission is performed. 24. The method of claim 23, wherein
A method in which the base station transmits to the information device up to three times at each frequency of 2.41 GHz, 2.45 GHz, and 2.49 GHz. 24. The method of claim 23, wherein
The beacon signal is generated with a time reference associated with a reference clock signal. 28. The method of claim 27, wherein
A method of providing the reference clock signal by GPS. The system of claim 10, wherein
A system in which the beacon signal is made with a time reference associated with a reference clock signal. 30. The system of claim 29.
A system in which the reference clock signal is provided by GPS.

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