JP2013070237A - Blockage signal transmitter - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a blockage signal transmitter capable of preventing erroneous detection of a tag by limiting a spatial area where a seizing signal transmitted by an LF transmitter can be received within an arbitrary area.SOLUTION: An LF transmitter 102a transmits a seizing signal 1401 to a tag at a cycle ct. A blockage signal transmitter 151a independently operates without being linked with the LF transmitter 102a to detect the seizing signal transmitted by the LF transmitter 102a, calculates a transition time st of the seizing signal 1401 and transmits a blockage signal (1411, 1412 and the like) at a cycle it1 shorter than st to thereby limit a spatial range where the tag can receive the seizing signal 1401. The transition time lt1 of the blockage signal has at least a signal length longer than a signal length (equivalent to n bit) in which the tag can perform error correction.

Description

  The present invention relates to a technique for managing the location of a holder using a tag, and more particularly, to prevention of erroneous tag detection.

  In recent years, a system for managing the location of a tag using a tag reader and a tag has been proposed (Patent Documents 1 and 2). For example, in offices, if a tag reader is installed on each desk in the line and each person has a tag, it can detect when the person with the tag approaches the tag reader. You can manage.

JP 2008-177775 A JP 2008-182666 A

  By the way, in the presence management as described above, regarding the activation signal transmitted by the tag reader, the transmission output of the activation signal of the tag reader is determined so as to cover the entire space desired to be received. In some cases, it may reach an area where reception of the activation signal is not desired. For example, it is only necessary that the activation signal be received by the tag only near the desk, and there may be a case where the reach of the activation signal extends from the restriction of the office layout or the like to the passage. In this case, the tag possessed by the person who passes through the passage simply receives the activation signal, and the false detection that the passerby is present is made.

  In view of the above problems, the present invention provides an interfering signal transmitter that can limit a spatial region in which an activation signal transmitted by an LF transmitter as a tag reader can be received to an arbitrary range and prevent erroneous tag detection. The purpose is to provide.

In order to solve the above problems, the present invention is an interference signal transmitter that is used together with a transmitter that periodically transmits an activation signal to a tag, and that limits a spatial range in which the activation signal is received by the tag, The interference signal is periodically transmitted at an interval shorter than the transmission time in one cycle of the activation signal.
Further, as the interference signal, a signal having the same frequency as the activation signal may be transmitted with a signal output weaker than the activation signal.

Further, the transmission time of the activation signal may be acquired by detecting the activation signal.
Further, as the interference signal, an interference signal having a signal length longer than a signal length capable of error correction by the tag may be transmitted.
The output level of the interference signal may be determined by detecting the activation signal and multiplying the detected reception level by a predetermined ratio.

The user may have an interface for designating the output level of the jamming signal, and the jamming signal may be output at the designated output level.
Further, as the periodic interference signal transmission, the interference signal may be transmitted every time the activation signal is detected.

  The interference signal transmitter of the present invention has the above-described configuration, so that the spatial area in which the activation signal can be received can be limited to an arbitrary range and tag misdetection can be prevented.

It is the figure which showed an example of the structure of the location management system which concerns on one embodiment of this invention. It is the figure which showed an example of the structure before installation in the location management system which concerns on one embodiment of this invention. It is a block diagram which shows the structure of the controller which concerns on one embodiment of this invention. It is a block diagram which shows the structure of the LF transmitter which concerns on one embodiment of this invention. It is a block diagram which shows the structure of the tag which concerns on one embodiment of this invention. It is a block diagram which shows the structure of the disturbance signal transmitter which concerns on one embodiment of this invention. It is a figure which shows the timing which LF transmitter which concerns on one embodiment of this invention transmits a starting signal. It is a figure for demonstrating the change by the disturbance signal of the receivable area | region of the starting signal which concerns on one embodiment of this invention. It is a figure for demonstrating the transmission signal of the starting signal which concerns on one embodiment of this invention, and an interference signal. It is a figure which shows the transmission timing etc. of the starting signal and disturbance signal which concern on the modification of this invention.

Hereinafter, the location management system which is one embodiment of the interference signal transmitter according to the present invention will be described.
1. Outline The present location management system includes a server for managing location of a tag, a plurality of tags, a plurality of LF transmitters for transmitting an activation signal for activating a tag using an LF (Low Frequency) band, and an LF transmitter A controller for adjusting the transmission timing of the activation signal by the receiver, receiving a signal transmitted from the activated tag using the UHF (Ultra High Frequency) band, and transmitting the reception result to the server, and an interfering signal transmitter Consists of including.

The tag, the LF transmitter, and the controller each store a tag ID, an LF antenna ID, and a controller ID, which are identification information, and transmit the identification information to each other.
The plurality of LF transmitters are arranged in advance in different positions in the area to be managed, and the activation signal to be transmitted includes an LF antenna ID for identifying the LF transmitter.
When the tag receives the activation signal, the tag transmits the LF antenna ID and the tag ID included in the activation signal to the controller. The controller transmits the tag ID, LF antenna ID, and controller ID to the server. The server stores in advance the arrangement of the LF transmitter identified by the LF antenna ID, and grasps the position of the tag using the received tag ID and LF antenna ID.

Here, the transmission output of the activation signal of each LF transmitter is set so that the arrival range of the activation signal can cover the area where the reception is desired. In some cases, it may reach an undesired area (hereinafter referred to as a reception unnecessary area).
The interference signal transmitter disables reception of the activation signal by the tag in the reception unnecessary area by transmitting the interference signal. That is, the interference signal transmitter limits the receivable range by the tag of the activation signal to an arbitrary range.
2. Configuration 2.1. Overall Configuration FIG. 1 is a diagram showing an example of the configuration of a location management system according to the present embodiment, and shows, for example, one area in a certain office.

  In this area, two desks 103a to 103d and two chairs 104a to 104d are arranged in two rows, and each row and the passage in the center of the area are partitioned by partitions 171a and 171b and partitions 171c and 171d. LF transmitters 102a to 102d that wirelessly transmit signals in the LF band (for example, 120 kHz to 130 kHz band) are arranged on the desks 103a to 103d. Each of the LF transmitters 102a to 102d is connected to one controller 101 via a communication cable such as RS485. The controller 101 is connected to the server 106.

  When a person to be managed sits on one of the chairs 104a to 104d (for example, the chair 104a) in the area, one of the LF transmitters 102a to 102d in the vicinity of the chair (for example, the LF transmitter 102a) transmits. A tag owned by the person receives the activation signal. The activation signal includes an LF antenna ID that identifies the LF transmitter that has transmitted the activation signal, and the tag transmits the LF antenna ID and the tag ID to the controller 101. Location information management is realized by transmitting tag information from the controller 101 to the server 106.

  Here, an area 121a indicated by a broken line in FIG. 1 indicates an area in which the tag can receive the activation signal transmitted by the LF transmitter 102a. The area inside the broken line is the receivable area. Similarly to the broken line 121a, areas 121b to 121d indicated by broken lines indicate areas in which the tag can receive the activation signal transmitted by the LF transmitters 102b to 102d. Here, the area 121a is an area after the area where the activation signal can be received originally is arbitrarily changed by the interference signal transmitted by the interference signal transmitter 151a. The regions 121b to 121d are the same as the region 121a.

FIG. 2 shows a configuration before the interference signal transmitters 151a and 151b are installed from the configuration shown in FIG. 1 (hereinafter referred to as a pre-installation configuration), and the area where the activation signal can be received is not changed.
In the pre-installation configuration, the activation signal transmitted by the LF transmitter 102a can be received in a region 121a ′ indicated by a circular broken line, and the receivable range extends to the back side (passage side) of the partition 171a.

In this case, when a passerby who passes through the passage reaches the area 122a indicated by the hatch in FIG. 2, the passer's tag receives an activation signal from the LF transmitter 102a and communicates with the controller 101. Resulting in. Eventually, the server 106 erroneously determines that the passerby is also seated in the chair associated with the LF transmitter 102a.
The interference signal transmitter 151a transmits an interference signal to prevent the activation signal from being received in the area 122a in order to avoid such a situation where an erroneous determination is made. That is, the jamming signal transmitter 151a changes the area where the activation signal transmitted by the LF transmitter 102a can be received from the area 121a ′ shown in FIG. 2 to the area 121a shown in FIG. 1 by transmitting the jamming signal. To do. Note that if the transmission output of the activation signal in the LF transmitter 102a is weakened, it is possible to avoid the activation signal from wrapping around the back side of the partition 171a. Even though it is necessary to receive the activation signal, an area where reception is not possible occurs.

Here, the change by the disturbance signal of the receivable area | region of a starting signal is demonstrated using FIG.
FIG. 8C is a diagram showing the arrangement of the LF transmitter and the interference signal transmitter.
The LF transmitter A is disposed at the origin position on the xy plane, and the interference signal transmitters C and E are disposed on the x axis so as to surround the LF transmitter A, and the interference signal transmitters B and D are disposed on the y axis. Is arranged.

Note that the configuration in FIG. 8C is for explaining that the receivable area of the activation signal can be arbitrarily changed by the interference signal, and is one-to-one with the configuration in FIGS. 1 and 2 described above. It does not correspond to.
An area 1721 in FIG. 8C shows an area where the tag can receive the activation signal transmitted by the LF transmitter A when it is assumed that no interference signal is transmitted by the interference signal transmitters B to E.

An area 1722 in FIG. 8C shows an area in which the tag can receive the activation signal transmitted by the LF transmitter A when the interference signal transmitters B to E transmit the interference signal.
In the following description, the circular area 1721 that was able to receive the activation signal when there is no interference signal is changed to a rectangular area 1722 by the transmission of the interference signal by the interference signal transmitters B to E. Is.

FIG. 8A shows the received electric field strength due to the radio waves transmitted by the LF transmitter A and the interference signal transmitters C and E on the x-axis of FIG. 8C.
The horizontal axis in FIG. 8A corresponds to the x-axis in FIG. 8C, and the vertical axis indicates the received electric field strength at each position.
A waveform 1701 indicates the received electric field strength of the activation signal transmitted by the LF transmitter A when there is no interference signal.

A waveform 1702 and a waveform 1703 indicate the received electric field strength of the disturbing signal transmitted by the disturbing signal transmitters C and E, respectively. The jamming signal is a signal having the same frequency as the activation signal.
Here, the boundary line 1704 in FIG. 8A indicates the minimum received electric field strength (114 dBuV / m) that the activation signal can be received, and the activation signal cannot be received in a range below the boundary line 1704.

  The waveform 1701 intersects this boundary line 1704 at a point P1 (x coordinate: P1x, y coordinate: P1y) and a point P2 (x coordinate: P2x, y coordinate: P2y). When there is no interfering signal, the tag 111 can receive the activation signal because the received electric field strength exceeds the minimum received electric field strength between the points P1 and P2 in the waveform 1701. P1x and P2x coincide with the x coordinate of the intersection of the region 1721 and the x axis in FIG.

FIG. 8B is a diagram illustrating a difference in received electric field strength between the activation signal from the LF transmitter A and the interference signals from the interference signal transmitters C and E when there is an interference signal.
The horizontal axis coincides with the x-axis in FIG. 8C, and the vertical axis indicates the CN (Carrier to Noise ratio) ratio.
A waveform 1711 in FIG. 8B shows the difference in received electric field strength between the activation signal from the LF transmitter A and the interference signals from the interference signal transmitters C and E.

Here, a boundary line 1712 in FIG. 8B indicates the lowest CN ratio (for example, 18 dB) at which the activation signal can be received. In the range where the CN ratio is lower than the minimum CN ratio, the tag cannot receive the activation signal.
The waveform 1711 intersects the boundary line 1712 at a point P4 (x coordinate: P4x, y coordinate: P4y) and a point P5 (x coordinate: P5x, y coordinate: P5y). Since the range from the point P4 to the point P5 in the waveform 1711 exceeds the minimum CN ratio, the tag 111 can receive the activation signal during this period.

The above description is about the x-axis in FIG. 8C, but the same applies to the y-axis.
Here, the area where the activation signal can actually be received is such that the received electric field strength exceeds the minimum received electric field strength (condition 1) as shown in FIG. 8A, and the CN ratio is as shown in FIG. 8B. This is a region that exceeds the minimum CN ratio (condition 2).

Therefore, the range in which the activation signal can be received when there is an interference signal is a region 1722 in FIG. 8C that satisfies both condition 1 and condition 2.
As described above, the receivable area by the tag of the activation signal transmitted by the LF transmitter can be changed to an arbitrary area by the interference signal transmitter transmitting the interference signal.
2.2. Individual configuration The configuration of each device will be described below.

FIG. 3 is a block diagram showing the configuration of the controller 101.
The controller 101 mainly includes a UHF band receiving unit 310, a control unit 320, and a storage unit 330.
The storage unit 330 includes a memory and the like, and has a function of storing various data and programs necessary for the operation of the controller 101. The storage unit 330 stores a controller ID 331.

  The UHF band receiving unit 310 performs communication with the tag and is connected to the UHF antenna 311. The UHF band receiving unit 310 includes a tag ID, an LF antenna ID, a controller ID, and the like that are transmitted as radio signals in the UHF band (for example, 300 MHz, 400 MHz, 900 MHz, and 2.4 GHz band) under the control of the control unit 320. It has a function of receiving and demodulating the notification signal and notifying the control unit 320 of reception notification data which is digital data after demodulation.

  The control unit 320 has a function of controlling each unit of the controller 101 by executing a stored program using a processor. Specifically, the control unit 320 checks the tag ID included in the reception notification data received from the UHF band reception unit 310, and sends the tag ID notification data including the tag ID, the controller ID, and the controller ID to the server 106. It has a function to transmit. The control unit 320 instructs the external eight LF transmitters to transmit activation signals.

FIG. 4 is a block diagram showing a configuration of the LF transmitter 102a.
The LF transmitter 102a mainly includes an LF band transmission unit 410, a control unit 420, and a storage unit 430.
The storage unit 430 includes a memory and the like, and has a function of storing various data, programs, and LF antenna IDs 431 necessary for the operation of the LF transmitter 102.

The LF band transmission unit 410 is connected to the LF antenna 411, and transmits an activation signal including a wake pattern, an LF antenna ID 431, a controller ID of a controller that has instructed transmission of the activation signal, to the tag via the LF antenna 411. It has the function to do.
The control unit 420 has a function of controlling each unit of the LF transmitter 102a by executing a program stored in the storage unit 430 by a processor. In response to the instruction from the controller 101, the control unit 420 instructs the LF band transmission unit 410 to transmit an activation signal including the LF antenna ID and the like.

The LF transmitters 102b to 102h also have the same configuration as the LF transmitter 102a.
FIG. 5 is a block diagram showing the configuration of the tag 111.
The tag 111 includes an LF band receiving unit 510, a UHF band transmitting unit 520, a control unit 530, a storage unit 540, and a battery 550 that supplies power to each unit.
The storage unit 540 includes a memory and the like, and has a function of storing various data and programs necessary for the operation of the tag 111. The storage unit 540 stores a tag ID 541.

The LF band receiving unit 510 is connected to the LF antenna 511, receives the start signal in the LF band from the LF transmitter, demodulates the received start signal, and controls the start data that is demodulated digital data. A function of notifying 530.
The UHF band transmission unit 520 is connected to the UHF antenna 521 for transmitting a signal in the UHF band, and receives reception notification data including the tag ID 541 notified from the control unit 530, the received LF antenna ID, the controller ID, and the like. It has a function of modulating and transmitting to the controller as a reception notification signal.

  The control unit 530 has a function of controlling each unit of the tag 111 by executing a program stored in the storage unit 540 by a processor. The control unit 530 starts the process when the head wake pattern of the activation data is recognized. The control unit 530 has a function of generating reception notification data including the LF antenna ID, the controller ID, and the tag ID 541 in the activation data and notifying the UHF band transmission unit 520.

FIG. 6 is a block diagram showing a configuration of the jamming signal transmitter 151a.
The interference signal transmitter 151a mainly includes an LF band transmission unit 610, a control unit 620, and a storage unit 630.
The LF band transmission unit 610 is connected to the LF antenna 611 and has a function of transmitting an interference signal via the LF antenna 611.

The jamming signal is a signal having the same frequency as the activation signal transmitted by the LF transmitter 102a.
The control unit 620 has a function of controlling each unit of the interference signal transmitter 151a by executing a program stored in the storage unit 630 by a processor.
The control unit 620 detects the activation signal transmitted by the LF transmitter, analyzes the detected activation signal, calculates the transmission period, transmission timing, transmission time length, etc. of the interference signal, and sends it to the LF band transmission unit 610. Send jamming signals.

The storage unit 630 includes a memory and the like, and has a function of storing various data and programs necessary for the operation of the interference signal transmitter 151a. The interference signal transmitter 151b also has the same configuration as the interference signal transmitter 151a.
3. Operation Hereinafter, the operation of the location management system having the above-described configuration will be described.
3.1. Overall Operation The server 106 transmits controller setting data to each controller arranged in each area, and each controller operates using this data. The controller 101 performs transmission control processing such as instructing transmission to the LF transmitters 102a to 102d installed on the four desks. Each of the LF transmitters 102a to 102d that has received the transmission instruction transmits an activation signal so that a tag possessed by a person who sits or leaves the seat can be received corresponding to each desk.

  FIG. 7 shows the timing at which each of the four units from the LF transmitter 102a to the LF transmitter 102d transmits an activation signal. Each of the LF transmitters 102a to 102d is assigned a period of t1 / 4, and transmits an activation signal within the allocated period. A bar (for example, bar 1001) in the figure indicates a period from the start of transmission of the activation signal to the end of transmission.

  When a person carrying the tag is present near each desk (sitting, etc.), the tag transmits a reception notification signal including the tag ID and the LF antenna ID included in the activation signal in response to the activation signal. . The controller 101 receives the reception notification signal, and then transmits tag ID notification data including the LF antenna ID and the tag ID to the server 106. The server 106 manages the tag location by checking the tag ID and the LF antenna ID included in the tag ID notification data.

The jamming signal transmitters 151a and 151b transmit the jamming signal, so that the receivable range of the activation signal transmitted by the LF transmitters 102a to 102d is changed from the range indicated by the broken lines 121a ′ to 121d ′ in FIG. 1 is changed to a range indicated by broken lines 121a ′ to 121d ′. Hereinafter, the transmission timing and transmission time of the interference signal will be described.
3.2. Transmission timing and transmission time of jamming signal As described above, the jamming signal transmitter operates independently of the LF transmitter, but changes the reception signal reception area to an arbitrary area.

Here, when the jamming signal transmitter always transmits the jamming signal (as a continuous signal), it is inferior in terms of low power consumption as compared with the case of intermittently sending the jamming signal.
When the interference signal is transmitted intermittently, the timing and transmission length for transmitting the interference signal vary depending on the specification of the activation signal and the error correction capability of the tag on the reception side of the activation signal. For example, if the tag fails to receive a part of the activation signal and is based on the specification that all activation signals are discarded, the interfering signal transmitter must cause the tag to receive a part of the activation signal. It's enough.

In addition, when a part of the activation signal is made unreceivable, it may be assumed that a specific part (for example, a wake pattern) needs to be made unreceivable.
Hereinafter, (1) a case where a part (unspecified part) of the activation signal is unreceivable, and (2) a case where a part (specific part) of the activation signal is unreceivable will be described.
(1) When the unspecified portion is made unreceivable The tag operates based on the specification that all received signals are discarded as illegal signals when any received activation signal is missing.

FIG. 9A is a diagram for explaining the transmission timing of the activation signal transmitted by the LF transmitter 102a and the interference signal transmitted by the interference signal transmitter 151a.
It is assumed that the LF transmitter 102a transmits a transmission signal 1401 whose time (transmission time) from the start of transmission to the end of transmission is st every cycle ct.
The interference signal transmitter 151a first detects the activation signal output from the LF transmitter 102a in the LF band transmission unit 610, calculates the signal length st of the activation signal in the control unit 620 from the detection result, and stores st in the storage unit This is stored in 630.

And the control part 620 determines it1 (it1 <st) which is a period shorter than st, and transmits a disturbance signal (1411, 1412, 1413 ...) for every period it1.
As a result, since the interference signal is always transmitted during the transmission period of the activation signal 1401, it is impossible for the tag to receive at least a part of the activation signal. Thus, the tag cannot receive a complete activation signal.

Here, the transmission time length lt1 of the interference signal needs to be a time length corresponding to a bit length exceeding the error correction capability of the tag. If the tag does not have an error correction function, lt1 may be equal to or longer than the time length corresponding to 1 bit length.
(2) Case where specific location is made unreceivable An example where normal processing cannot be performed when the tag cannot receive a specific location (for example, a wake pattern) in the activation signal will be described.

Here, the wake pattern is a bit string of a specific pattern for activating the control unit 530 included in the tag.
FIG. 9B is a diagram for explaining the transmission timing of the activation signal (wake pattern) transmitted by the LF transmitter 102a and the interference signal transmitted by the interference signal transmitter 151a.

Assume that the LF transmitter 102a transmits a transmission signal 1401 including a wake pattern at the beginning, with a time (transmission time) from the start of transmission to the end of transmission for each cycle ct.
The interference signal transmitter 151a first detects the activation signal output from the LF transmitter 102a in the LF band transmission unit 610, calculates the signal length st of the activation signal in the control unit 620 from the detection result, and stores st in the storage unit This is stored in 630.

Further, the transmission time length wt of the wake pattern is calculated by multiplying st by the ratio of the wake pattern to the entire activation signal, and stored in the storage unit 6430.
Then, the control unit 620 of the interference signal transmitter 151a determines an interference signal transmission period it2 shorter than wt (it2 <wt), and the interference signal (1471, 1472, ..., 1473) for each transmission period it2. , 1474...

As a result, for any wake pattern, at least a part of the wake pattern cannot be received due to the interference signal, and the complete wake pattern cannot be restored in the tag. Here, the transmission time length lt2 of the interference signal needs to be a time length corresponding to a bit length exceeding the error correction capability of the tag.
As described above, the interference signal transmitter can prevent reception of the activation signal in the unnecessary reception area by transmitting the interference signal intermittently based on the above-described time, timing, etc., and The power consumption can be reduced compared to the case where the interference signal is transmitted as a continuous signal.
4). Modifications As described above, the embodiment of the tag management system according to the present invention has been described. However, the location management system as an example of the exemplified tag management system can be modified as follows, and the present invention is implemented as described above. Of course, the location management system is not limited to that shown in the form.
(1) In the above-described embodiment, the interference signal is periodically transmitted. However, the present invention is not limited to this, and the interference signal may be transmitted every time the activation signal is detected.

For example, when it is sufficient to make it impossible to receive an unspecified portion of the activation signal as described above, the interference signal transmitter transmits the interference signal immediately after the detection when detecting the start of transmission of the activation signal.
In addition, a case where it is only necessary to make a specific location (wake pattern as an example) in the activation signal unreceivable will be described with reference to FIGS. 10 (a) and 10 (b).
FIG. 10B is an enlarged view of a part of FIG.

As shown in FIG. 10A, the activation signal transmitted by the LF transmitter 102a has a signal transmission time of st and is transmitted every cycle ct.
As shown in FIG. 10B, the activation signal is obtained by modulating digital data including, for example, a wake pattern, UW (unique word), UHF channel, controller ID, LF antenna ID, reserved area, and CRC. It is.

If each content of digital data is simply supplementarily explained, UW is unique identification information indicating the head of the data. The UHF channel information is information indicating which one of a plurality of frequency bands in the UHF band should be used by the tag. CRC is data inserted at the end of digital data transmitted by an activation signal for error correction.
FIG. 10A is a diagram for explaining the transmission timing of the activation signal transmitted by the LF transmitter 102a and the interference signal transmitted by the interference signal transmitter 151a.

The interference signal transmitter 151a first calculates the transmission cycle ct of the activation signal, the transmission length st, and the transmission length wt of the wake pattern. These calculation methods have already been described in the embodiments.
Thereafter, the jamming signal transmitter 151 constantly monitors the activation signal being transmitted.
When it is detected that the activation signal has been transmitted, the disturbance signal 1631 is transmitted within the time it3 (<wt) from the head of the activation signal, as shown as the disturbance signal 1 in FIG.

Thereby, the interference signal transmitter can prevent reception of the wake pattern by the tag. Moreover, the interference signal transmitter does not need to periodically transmit the interference signal, and can save power.
(2) In the modified example (1), the example of preventing the reception of the wake pattern arranged at the head of the activation signal has been described. However, the present invention is not limited to this. For example, reception of data that is not arranged at the head of the activation signal, such as the LF antenna ID, can be prevented.

In this case, the interference signal transmitter 151a first calculates the transmission cycle ct and the transmission length st of the activation signal. These calculation methods have already been described in the embodiments.
Also, the time from when the start signal is transmitted until the LF antenna ID is transmitted is calculated. Since it is known how many bytes from the beginning of the digital data transmitted by the activation signal are located, the LF antenna ID is transmitted when how long it has passed since the activation signal was transmitted. It can be calculated whether it is started (it4 in FIG. 10) or transmission ends (it5 in FIG. 10).

Then, after the start of transmission of the activation signal is detected, the interference signal is transmitted in a period including a period after it4 has elapsed and before it5 has elapsed.
Thereby, the interference signal transmitter can prevent reception of the LF antenna ID by the tag.
If the LF antenna ID cannot be received, the tag and the LF transmitter cannot be associated with each other, so that the same effect as preventing the reception of the entire activation signal can be obtained.

Further, since the interference signal transmitter does not need to periodically transmit the interference signal, power saving can be achieved.
(3) The output level of the interference signal may be determined according to the output level of the activation signal from the LF transmitter.
For example, the interference signal transmitter may detect the activation signal transmitted by the LF transmitter and transmit the interference signal at a level obtained by multiplying the detected reception level by a predetermined ratio.

The interference signal transmitter may have an interface for the user to specify the output level of the interference signal and output the interference signal at an output level specified by the user using the interface.
(4) A control program composed of a machine language or high-level language program code to be executed by the processor of each device shown in the embodiment and the modification and various circuits connected to the processor is recorded on a recording medium. Or distributed through various communication channels or the like. Such a recording medium includes an IC card, a hard disk, an optical disk, a flexible disk, a ROM, a flash memory, and the like. The distributed and distributed control program is used by being stored in a memory or the like that can be read by the processor, and the processor executes the control program to realize each function as shown in each embodiment. Will come to be. In addition to directly executing the control program, the processor may be compiled and executed or executed by an interpreter.
(5) Each functional component shown in the embodiment and the modification may be realized as a circuit that executes the function, or may be realized by executing a program by one or a plurality of processors. Further, the system shown in the embodiment and the modification may be configured as a package of an IC, an LSI, or another integrated circuit. This package is incorporated into various devices for use, whereby the various devices realize the functions as shown in the embodiments.
(6) An interference signal transmitter according to an embodiment of the present invention is used together with a transmitter that periodically transmits an activation signal to a tag as shown in FIG. 9, and the activation signal is received by the tag. A jamming signal transmitter that limits a spatial range, and periodically transmits a jamming signal at an interval shorter than a transmission time in one cycle of an activation signal.

With this configuration, reception of the activation signal 1401 by the tag is surely prevented by the interference signals 1411, 1412,.
Moreover, as shown in FIG. 8, it is good also as transmitting the signal of the same frequency as the said starting signal with a signal output weaker than the said starting signal as said disturbance signal.
With this configuration, as shown in FIG. 8B, the CN ratio that can be received only in the range of P4 to P5 is exceeded, and the reception range of the activation signal can be limited to the region 1722.

As shown in FIG. 10, the transmission time in one cycle of the activation signal may be obtained by detecting the activation signal.
With this configuration, the transmission period of the interference signal can be calculated using the actual transmission time of the activation signal.
Further, as shown in FIG. 9, each of the transmitters may transmit an interference signal having a signal length longer than a signal length that can be corrected by the tag.

With this configuration, even when the tag has an error correction function, reception of the activation signal can be reliably prevented.
The output level of the interference signal may be determined by detecting the activation signal and multiplying the detected reception level by a predetermined ratio.
With this configuration, the interference signal can be output with sufficient power necessary to prevent the reception of the activation signal. Also, the user has an interface for specifying the output level of the interference signal. The interference signal may be output at an output level.

With this configuration, it is possible to transmit an interference signal using a user's desired output.
Further, as shown in FIG. 10, as the periodic interference signal transmission, the interference signal may be transmitted every time the activation signal is detected.
With this configuration, by outputting the interference signal only when the activation signal is transmitted, output of an unnecessary interference signal can be suppressed and power consumption can be reduced.
(7) The above-described embodiments and modifications may be partially combined.

106 Server 101 Controller 102a-102d LF transmitter 111 Tag 121a-121d Activation signal receivable area 151a, 151b Interference signal transmitter

Claims (7)

An interfering signal transmitter that is used with a transmitter that periodically transmits an activation signal to a tag and limits the spatial range in which the activation signal is received by the tag,
An interference signal transmitter characterized by periodically transmitting an interference signal at an interval shorter than a transmission time in one cycle of an activation signal. The interference signal transmitter according to claim 1, wherein a signal having the same frequency as the activation signal is transmitted as the interference signal with a signal output weaker than the activation signal. The interference signal transmitter according to claim 1, wherein a transmission time in one cycle of the activation signal is obtained by detecting the activation signal. The interference signal transmitter according to claim 1, wherein an interference signal having a signal length longer than a signal length capable of error correction by the tag is transmitted as the interference signal. The interference signal transmitter according to claim 1, wherein the output level of the interference signal is determined to be a level obtained by detecting the activation signal and multiplying the detected reception level by a predetermined ratio. An interface for the user to specify the output level of the jamming signal;
The jamming signal transmitter according to claim 1, wherein the jamming signal is output at a specified output level. The interference signal transmitter according to claim 1, wherein, as the periodic interference signal transmission, the interference signal is transmitted every time the activation signal is detected.

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