JP2006275839A - Position detection system and position detection method for rfid tag - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a high-precision position detection system and position detection method using an RFID tag. <P>SOLUTION: The position detection method includes: a first step wherein a first reader sets a first attenuation ratio on a first attenuator, allows a first antenna to radiate radio waves, and then receives a first signal; a second step wherein a second reader sets a second attenuation ratio on a second attenuator, allows a second antenna facing the first antenna to radiate radio waves, and then receives a second signal; and a third step wherein a control section decides whether both the first and second signals are a predetermined value or over, wherein the first to third steps are repeated. In one cycle, for the execution of the second or later time first step, a first attenuation ratio which has been increased above first attenuation ratio a time before is used. In one cycle, for the execution of the second or later time second step, a second attenuation ratio which has been decreased below second attenuation ratio a time before is used. The RFID tag detection ranges of the radio waves radiated from the first antenna and the second antenna are thereby partly overlapping each other. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an RFID tag position detection device and a position detection method.

  In recent years, a position detection technique using RFID has attracted attention as a position detection technique that is lower in cost than a position identification technique using GPS, wireless LAN, Bluetooth, or the like. RFID is a responder (hereinafter referred to as a tag) having a memory for storing a large amount of information and an antenna for transmitting / receiving information, an interrogator having an antenna and a controller for transmitting commands to the tag and transmitting / receiving data. (Hereinafter referred to as a reader antenna or a reader / writer antenna). Since low-cost and small tags and a large number of tags can be recognized at a time, development is progressing with the aim of practical use.

  As the position specifying method using RFID, for example, the following various methods are known.

(1) Since the area where the reader antenna can detect a tag (hereinafter referred to as a tag detection area) is limited, a plurality of reader antennas are arranged in a predetermined area, and the position of the reader antenna where the tag is detected is determined as a tag. (See FIG. 12A)
(2) When the reader antenna is arranged so that the tag detection areas of adjacent reader antennas overlap, and a plurality of reader antennas detect one tag at the same time, representative points in the area where the tag detection areas overlap (for example, (Centroid) as a tag position (see FIG. 12B)
(3) A plurality of tags are laid in a predetermined area such as a floor, and the position of each tag is recorded in each internal memory, and the moving reader antenna acquires position information from nearby tags, thereby Method for specifying the position (see FIG. 12C)
(4) Method of measuring the intensity of radio wave output from one tag with three or more reader antennas and specifying the position of the tag by three-point surveying (see (d) of FIG. 12)
(5) A method of mounting a plurality of reader antennas having different communication distances and a function of reacting with these reader antennas on one tag, and specifying the position of the tag from the reader antenna to which the tag reacts (Patent Document 1 and FIG. (Refer to 12 (e))
(6) When the radio wave output and the tag response distance are measured in advance with respect to the radio wave output variable reader antenna, the radio wave output of the reader antenna is changed stepwise at a constant time period, and the reader antenna can detect the tag response Of specifying the position of the tag from the response distance (see Patent Document 2 below and FIG. 12 (f))
JP 2001-114405 A JP 2001-116583 A

  However, the method (1) has a problem of poor position accuracy.

  In the method (2), the positional accuracy is improved as compared with (1). However, when the tag is in an area having only one reader antenna capable of communication, there is still a problem that the positional accuracy is poor. is there.

  In the method (3), it is expensive to install a large number of tags. In addition, there is a problem that it is difficult to lay on the ground with large unevenness or sand.

  In the method (4), the positional accuracy is improved as compared with the methods (1) to (3). However, three or more reader antennas that can always communicate are necessary, and it is necessary to use an active tag (battery-mounted tag) having a long communication distance. In addition, the active tag has problems that the battery life, the cost, and the size are large compared to the passive tag (the tag not equipped with the battery).

  In the method (5), a dedicated tag having a plurality of antennas in the tag is required instead of the standard specification tag, which is costly, increases in size, and has only a position resolution corresponding to the number of antennas mounted. Therefore, there is a problem that the position accuracy is worse than (4).

  In the method (6), compared to (4), maintenance free, low cost, and a large degree of freedom in size and shape are large, and there are many fields of application. However, since the radio wave output of the communicable reader antenna differs depending on the posture of the tag with respect to the reader antenna, a position error occurs. In addition, it is difficult to specify the position of the moving tag.

  Accordingly, an object of the present invention is to provide a highly accurate position detection apparatus and detection method using a relatively inexpensive passive tag.

  In the RFID tag position detection method (1) according to the present invention, the control reading unit radiates the first antenna with a first attenuation ratio for a predetermined time, and then receives the first signal using the first antenna. After the first step and after the first step, the control reading unit causes the second antenna to emit a radio wave with a second attenuation ratio for a predetermined time, and then receives the second signal using the second antenna. A second step, and a third step in which the control reading unit determines whether or not both the first signal and the second signal are equal to or greater than a predetermined value at which it is determined that the signal from the RFID tag has been received. When the control reading unit determines in the third step that both the first signal and the second signal are equal to or greater than the predetermined value, the RFID tag detection range of the radio wave radiated from the corresponding first antenna And from the second antenna A fourth step of determining that the RFID tag exists within a range in which the RFID tag detection range of the radio wave to be emitted partially overlaps, and each of the first step to the fourth step is executed a predetermined number of times. 1 cycle, the first step to the fourth step are repeated, and when the first step is executed after the second time in the one cycle, the first damping ratio in the first step one time before is When the second step is executed after the second time in the one cycle using the increased first damping ratio, the second damping ratio is decreased from the second damping ratio in the second step one time before. It is characterized by using an attenuation ratio.

  The RFID tag position detection method (2) according to the present invention is the above-described RFID tag position detection method (1), wherein the first attenuation ratio and the second attenuation ratio are the same as the coil surface inside the RFID tag. The RFID tag is determined to be able to detect the RFID tag tilted within a predetermined angle from the vertical or vertical with respect to the opposing direction of the first antenna and the second antenna.

  The RFID tag position detection method (3) according to the present invention is the above-described RFID tag position detection method (2), wherein the RFID tag detection range of radio waves radiated from the first antenna at the first time of the one cycle The first attenuation ratio and the second attenuation ratio are set so that a range where the RFID tag detection range of the radio wave radiated from the second antenna overlaps is a predetermined region near the center between the first antenna and the second antenna. The first step and the second step are executed by setting the attenuation ratio, and in the third step following these, it is determined that only one of the first signal and the second signal is greater than or equal to the predetermined value. A region including a line on the line connecting the first antenna and the second antenna that includes a line close to the antenna on the side receiving the signal determined to be equal to or greater than the predetermined value from the center. As it is characterized by executing the first step to fourth step.

  The RFID tag position detection method (4) according to the present invention is the RFID tag position detection method (2) or (3) described above, wherein the control reading unit has a third attenuation ratio applied to the first antenna for a predetermined time. After radiating the radio wave, a fifth step of receiving a third signal using the first antenna, and after the fifth step, the control reading unit applies a fourth attenuation ratio to the second antenna for a predetermined time. The sixth step of receiving the fourth signal using the second antenna after emitting the radio wave, and the control reading unit receives the signal from the RFID tag together with the third signal and the fourth signal. A seventh step of determining whether or not the predetermined value is greater than or equal to the predetermined value, and the control reading unit is the seventh step, wherein the third signal and the fourth signal are both equal to or greater than the predetermined value. If it is determined that there is, the corresponding An eighth step of determining that the RFID tag exists within a range in which the RFID tag detection range of radio waves radiated from one antenna and the RFID tag detection range of radio waves radiated from the second antenna partially overlap; Including, after the one cycle, each of the fifth step to the eighth step is executed the same number of times as the first step to the third step, and the third damping ratio in the fifth step is The number of executions corresponding to the number of executions of the fifth step is a value obtained by increasing the first attenuation ratio used in the first step by a predetermined ratio, and the fourth attenuation ratio in the sixth step is the value of the first step. The second damping ratio used in the second step of the number of executions corresponding to the number of executions of 6 steps is a value obtained by increasing the predetermined number of times.

  The RFID tag position detection method (5) according to the present invention is the RFID tag position detection method (1) to (4) described above, wherein as a result of the determination in the third step, the first signal and When both of the second signals are equal to or greater than the predetermined value, or when both the third signal and the fourth signal are equal to or greater than the predetermined value as a result of the determination in the seventh step, the control reading is performed. The unit further includes a ninth step of controlling the imaging unit so as to image the superimposed region.

  The RFID tag position detection method (6) according to the present invention is the RFID tag position detection method (1) to (4) described above, wherein the imaging unit performs the first step and the second step, or In synchronism with the fifth step and the sixth step, the method further includes a ninth step of displacing so as to image the superimposed region.

  When the RFID tag position detection method (7) according to the present invention determines that the RFID tag is present in the eighth step in the RFID tag position detection method (4), the corresponding fifth step The third attenuation ratio used in step 4, the corresponding fourth attenuation ratio used in the sixth step, the RFID tag detection range of the radio wave radiated from the corresponding first antenna, and the corresponding second antenna. The inclination angle of the tag is obtained using the RFID tag detection range of the radiated radio wave.

  In the RFID tag position detection method (8) according to the present invention, the control reading unit radiates the first antenna with a first attenuation ratio for a predetermined time, and then receives the first signal using the first antenna. A second step of receiving a second signal using the second antenna after the control reading unit causes the second antenna to radiate a radio wave with a second attenuation ratio for a predetermined time; and After repeating the first step and the second step, each step of executing the first step and the second step a predetermined number of times, the control reading unit determines that the first signal and the second signal are both A third step for determining whether or not the signal from the RFID tag has been received is greater than or equal to a predetermined value, and the control reading unit includes the first signal and the second signal in the third step. Are both the predetermined If it is determined that the RFID tag detection range of the radio wave radiated from the corresponding first antenna and the RFID tag detection range of the radio wave radiated from the second antenna are partially overlapped, And a fourth step for determining that a tag is present, wherein the first attenuation ratio used in the first step executed a plurality of times in the one cycle is different for each of the first steps, and The second damping ratio used in the second step executed a plurality of times in a cycle is different for each second step, and the plurality of first damping ratios used in the one cycle are values. Are arranged in descending order, and a plurality of the second attenuation ratios used in the one cycle are arranged in ascending order of values, RF is emitted when radio waves are radiated at the corresponding first attenuation ratio and second attenuation ratio. The D tag detection range partially overlaps, and the first signal and the second signal to be determined in the third step have a large value for the plurality of first attenuation ratios used in the one cycle. When a plurality of the second attenuation ratios used in one cycle are arranged in order of increasing values, signals received when radio waves are emitted with the corresponding first attenuation ratio and second attenuation ratio. It is characterized by being.

  An RFID tag position detection apparatus (1) according to the present invention includes a first antenna and a second antenna, a first attenuator and a second attenuator, a first reading unit and a second antenna, which are arranged to face each other at a predetermined interval. A reading unit; and a control unit that receives signals from the first reading unit and the second reading unit, and the control unit or the first reading unit sets a first attenuation ratio in the first attenuator. , After radiating radio waves to the first antenna for a predetermined time, the first reading unit receives the first signal and transmits it to the control unit, and then the control unit or the second reading unit The second attenuator is set to a second attenuation ratio, and after the radio wave is radiated to the second antenna for a predetermined time, the second reading unit receives the second signal and transmits it to the control unit. RFID tag detection range of radiated radio wave, If the RFID tag detection range of the radio wave radiated from the antenna is partially overlapped and the control unit receives both the first signal and the second signal equal to or greater than a predetermined value, the RFID tag The radio wave emission and the signal reception are repeated with one cycle determined to be present and execution of the radio wave emission and the signal reception a predetermined number of times. During the one cycle, the first reading unit emits the radio wave after the second time. When the second reading unit performs radio wave emission for the second and subsequent times during the one cycle, using the first attenuation ratio increased from the first attenuation ratio set by radio wave emission one time before Further, the second attenuation ratio is set to be lower than the second attenuation ratio set by the previous radio wave radiation.

  An RFID tag position detection device (2) according to the present invention includes a first antenna and a second antenna, a switch unit, an attenuator, and a control reading unit, which are arranged to face each other at a predetermined interval, The reading unit sets a first attenuation ratio in the attenuator, controls the switch unit to connect the first antenna and the attenuator, and radiates radio waves to the first antenna for a predetermined time. The first signal is received using one antenna, and then the control reading unit sets a second attenuation ratio in the attenuator and controls the switch unit to connect the second antenna and the attenuator. After radiating radio waves to the second antenna for a predetermined time, the second signal is received using the second antenna, the RFID tag detection range of radio waves radiated from the first antenna, and the second antenna If the RFID tag detection range of the radio wave radiated from the signal is partially overlapped and the control reading unit receives both the first signal and the second signal that are equal to or greater than a predetermined value, the RFID tag The radio wave emission and the signal reception are repeated one cycle of executing the radio wave emission and the signal reception a predetermined number of times, and the control reading unit emits the radio wave after the second time during the one cycle. When the control reading unit performs radio wave emission for the second and subsequent times during the one cycle, using the first attenuation ratio increased from the first attenuation ratio set by radio wave emission of the previous time. It is characterized by using a second attenuation ratio that is smaller than the second attenuation ratio set by radio wave radiation one time before.

  The RFID tag position detection device (3) according to the present invention is the above-described RFID tag position detection device (1) or (2), wherein the first attenuation ratio and the second attenuation ratio are within the RFID tag. The coil surface has a value determined so as to be able to detect the RFID tag tilted within a predetermined angle from vertical or vertical with respect to a facing direction of the first antenna and the second antenna. Yes.

  When the RFID tag position detection device (4) according to the present invention is determined in any one of the RFID tag position detection devices (1) to (3) as described above, The image processing apparatus further includes an imaging unit that is controlled to image the superimposing region.

  An RFID tag position detection device (5) according to the present invention is configured to image the superimposed region in synchronization with the radio wave radiation in any of the RFID tag position detection devices (1) to (3). It is further characterized by further comprising an imaging unit that is displaced in the range.

  An RFID tag position detection device (6) according to the present invention includes a first antenna and a second antenna, a first attenuator and a second attenuator, a first reading unit and a second antenna, which are arranged to face each other at a predetermined interval. A reading unit; and a control unit that receives signals from the first reading unit and the second reading unit, and the control unit or the first reading unit sets a first attenuation ratio in the first attenuator. After the radio wave is radiated from the first antenna for a predetermined time, the first reading unit receives the first signal and transmits the first signal to the control unit, and then the control unit or the second reading unit receives the first signal. The second attenuator is set to a second attenuation ratio, and after the radio wave is radiated from the second antenna for a predetermined time, the second reading unit receives the second signal and transmits the second signal to the control unit. RFID tag detection range of radiated radio waves and previous If the RFID tag detection range of the radio wave radiated from the second antenna is partially overlapped and the control unit receives both the first signal and the second signal that are greater than or equal to a predetermined value, the RFID is placed in the overlap region. It is determined that a tag exists, and each of the first reading unit and the second reading unit executes radio wave emission and signal reception a predetermined number of times as one cycle, and repeats radio wave emission and signal reception. The first attenuation ratios that are set a plurality of times are different from each other, and the second attenuation ratios that are executed a plurality of times in the one cycle are different from each other, and a plurality of the first attenuation ratios that are used in the one cycle are used. Are arranged in descending order of values, and a plurality of the second attenuation ratios used in the one cycle are arranged in ascending order of values, radio waves are radiated at the corresponding first attenuation ratio and second attenuation ratio. RFID tag The detection range is partially overlapped, and the first signal and the second signal to be determined in the third step are arranged in order of increasing value from the plurality of first attenuation ratios used in the one cycle. When a plurality of the second attenuation ratios used in the one cycle are arranged in ascending order of values, signals received when radio waves are radiated at the corresponding first attenuation ratio and second attenuation ratio. It is characterized by use.

  According to the present invention, the position of the RFID tag between two opposed antennas can be accurately detected.

  In addition, the position of a tag that is not perpendicular to the opposing direction of the two antennas can be detected accurately.

  In addition, when the tag is detected, by controlling the imaging unit so as to image the corresponding detection area, it is possible to immediately capture a person carrying the tag or an object to which the tag is attached with high definition.

  Therefore, the present invention can be applied to various viewing systems. For example, the safety of a patient can be ensured by applying the RFID tag position detection apparatus according to the present invention to a viewing system in a hospital or a nursing facility. In hospitals and nursing homes, patients whose brain function has deteriorated due to dementia or injury may invade places that cause danger to their bodies due to deceit. In order to prevent this, it is effective to attach an RFID tag to the patient's clothes and place the antenna of this position detection device on the wall of the hallway leading to a dangerous area in the facility. In the conventional observation method, since the entire corridor is imaged with a camera, it is not easy to discriminate individual patients, but by linking the tag detection results with the camera, The periphery can be imaged with high definition. This makes it possible for a nurse or the like who watches the video displayed on the display device to pass the patient with his / her attendant (nurse or visitor) (safe passage) or to pass by the patient alone ( It is possible to easily determine whether it is a dangerous passage, and to prevent danger.

  Embodiments according to the present invention will be described below in detail with reference to the accompanying drawings.

  FIG. 1 is a block diagram (plan view) showing a schematic configuration of a position detection apparatus according to an embodiment of the present invention. This position detection apparatus is connected to the first antenna 1 and the second antenna 2 that are installed facing the wall surface of a passage such as a corridor, the first attenuator 3 and the second attenuator 4 connected thereto, and these. The first reading unit 5 and the second reading unit 6, the imaging unit 7, the first and second reading units 5 and 6, the control unit 8 that controls the imaging unit 7, and the image captured by the imaging unit 7 And a display unit 9 for displaying. FIG. 1 shows an RFID tag 10 (hereinafter also simply referred to as a tag) that is a detection target of the position detection apparatus. Here, it is assumed that the tag 10 is a passive type tag that includes an antenna coil and an IC chip (both not shown), but does not include power supply means.

  The control unit 8 includes a calculation unit (hereinafter referred to as a CPU) and a storage unit (hereinafter referred to as a memory). Processing performed by the control unit 8 described below is performed by the CPU appropriately using a memory as a work area. Use as run.

  The control unit 8 controls the first reading unit 5, sets a predetermined attenuation ratio in the first attenuator 3, and radiates radio waves having a predetermined intensity from the first antenna 1. Thus, if the tag 10 exists within the communication distance of the first antenna 1, the first reading unit 5 receives a predetermined signal from the tag 10 and transmits it to the control unit 8, and the control unit 8 receives the received signal. The position of the tag 10 and the information of the tag 10 (ID of the tag 10 etc.) are detected. Here, the communication distance of the antenna is a limit distance at which the antenna can communicate with the tag. Similarly, if the tag 10 exists within the communication distance of the second antenna 2, the control unit 8 can detect the position of the tag 10 and information on the tag 10.

  The imaging unit 7 outputs the captured video as a video signal of a predetermined format to the display unit 9, and thereby the captured video is displayed on the display unit 9. The control unit 8 can control a displacement mechanism (not shown) that displaces the image capturing direction of the image capturing unit 7 to image a specified direction.

  FIG. 2 is a flowchart showing the operation of the position detection apparatus according to the present embodiment. As shown in FIG. 1, it is assumed that the first and second antennas 1 and 2 are installed opposite to the walls on both sides of the passage where the movement of a person is to be monitored. The case of detecting the will be described. FIG. 3 is a diagram showing the positional relationship of radio waves radiated sequentially by the first and second antennas 1 and 2. In FIG. 3A, the radio wave distribution formed by the first antenna 1 at time t is indicated by L (t), and the radio wave distribution formed by the second antenna 2 at time t + Δt is indicated by R (t + Δt). Similarly, in (b) to (h), the first and second antennas 1 and 2 alternately show radio waves formed at different times by the time Δt.

Hereinafter, a specific description will be given according to the flowchart of FIG. 2 with reference to FIG. Here, in the initial setting, an upper limit i _max of a repetitive counter i, which will be described later, is set to 8, and all of the first flag F _1j and the second flag F _2j (j = 1 to 8) secured in a predetermined area on the memory. Is set to 0.

  In step S1, an initial value, for example, “1” is set in the counter i of the repetition process.

In step S <b> 2, the control unit 8 transmits the value of the counter i to the first reading unit 5. Thereby, the first reading unit 5 sets the attenuation ratio α _i corresponding to the value of the counter i in the first attenuator 3 and radiates radio waves from the antenna for a predetermined time T ₁ . The attenuation ratio α _i is set to decrease as i increases. For example, as shown in FIG. 1, when the first and second antennas 1 and 2 are divided into eight sections, and the first to eighth sections from the left, the first antenna 1 and the tag according to the counter i. The first attenuator 3 is set to an attenuation ratio α _i determined in advance so that the communicable range with 10 covers up to the i-th section. As a result, a radio wave having a communication range in the region indicated by L (t) in FIG. For example, when i = 1, the first antenna 1 forms a radio wave so as to include only the first section as a communication range. In FIG. 3, the section between the first and second antennas 1 and 2 is divided into 10 sections, and 8 sections excluding the sections at both ends are targeted for detection.

In step S < _b > 3, the first reading unit 5 stops radio wave emission for a predetermined time T < _b > ₂ , receives a signal, and transmits the received signal to the control unit 8. Here, receiving a signal means entering a reception mode and observing the signal. Accordingly, when only noise can be measured, the first reading unit 5 transmits a noise signal to the control unit 8.

In step S4, the control unit 8 determines whether or not the signal level received from the first reading unit 5 is a predetermined level or higher. Here, the predetermined level is a lower limit level at which it can be determined that the tag 10 has been detected. If it is determined that the level is equal to or higher than the predetermined level, the process proceeds to step S5, the first flag F _1i is set to “1”, the ID of the tag 10 is determined from the received data, and is recorded in the memory. The process proceeds to S6. If it is determined that the level is not higher than the predetermined level, the process proceeds to step S6.

In step S6, the control unit 8 transmits the value 9-i to the second reading unit 6 as in step S2. Thus, the second reading unit 6 sets the attenuation ratio β _9-i corresponding to the value of _9-i to the second attenuator 4 and radiates radio waves from the second antenna 2 for a predetermined time T _1. . Here, similarly to the first antenna 2, the attenuation ratio β _i is set so as to decrease as i increases (for example, when antennas having the same characteristics are used for the first and second antennas 1 and 2). , Α _i = β _i ). In accordance with the value of _9-i , the second attenuator is set to a predetermined attenuation ratio β _9-i so that the communicable range between the second antenna 2 and the tag 10 covers the “9-i” section. 4 is set. For example, when i = 1, the attenuation ratio is β ₈ corresponding to 9-1 = 8, which is the smallest. Accordingly, the second antenna 2 forms a radio wave so as to include a wide area up to the first section as a communication range, as indicated by R (t + Δt) in FIG. As described above, if radio waves are simultaneously radiated from the first and second antennas 1 and 2, a region (indicated by A (j) (j = 1 to 8) in FIG. 3) where the respective communication ranges overlap is predetermined. A radio wave is formed with an output including only one section. Therefore, if the tag 10 is present in the overlapping area A (j), the tag 10 can be detected by any of the first and second antennas 1 and 2.

In step S <b> 7, as in step S <b> 3, the second reading unit 6 stops radio wave emission and receives a signal for a predetermined time T ₂ , and transmits the received signal to the control unit 8. Again, receiving a signal means entering a receiving mode and observing the signal. When only noise can be measured, the second reading unit 6 transmits a noise signal to the control unit 8.

In step S8, as in step S4, the control unit 8 determines whether or not the signal level received from the second reading unit 6 is a predetermined level or higher. If it is determined that the level is equal to or higher than the predetermined level (corresponding to the detection of the tag), the process proceeds to step S9, and “1” is set in the second flag F _2i, and then the process proceeds to step S10. When it is determined that the level is not higher than the predetermined level, the process proceeds to step S10 as it is.

In step S10, the control unit 8 determines whether or not the values of the first and second flags F _1i and F _2i are both “1”. If both are determined to be “1”, the process proceeds to step S11, and the control unit 8 controls the displacement mechanism so that the imaging unit 7 captures the i-th section corresponding to i. As a result, the video of the i-th section in which the tag 10 is detected is displayed on the display unit 9. When it is determined that at least one of the first and second flags F _1i and F _2i is “0”, the process proceeds to step S12.

In step S12, the control unit 8, the counter i is judged whether the maximum value _{i max (= 8), i} = i max undesignated it is determined, by one counter i goes to Step S13 Increase and return to step S1. That is, the control unit 8 repeats the processes of steps S1 to S11 until i = i _max .

When determining that i = i _max , the control unit 8 proceeds to step S14, determines whether or not there is an end instruction, and repeats the processes of steps S1 to S13 until there is an end instruction.

  As described above, as shown in FIGS. 3A to 3H, by alternately increasing the radio field strength of one from the first and second antennas 1 and 2, the radio field strength of the other is sequentially decreased. When the signal is received and the tag 10 is detected by the determination in step S10, the image of the area where the tag 10 is present is displayed on the display unit 9 by controlling the imaging direction of the imaging unit 7 in step S11. Can do.

Various known means can be used to set the attenuation ratios α _i and β _i for the first and second attenuators 3 and 4. An example is shown in FIGS. FIG. 4 is a block diagram showing a variable attenuator in which switching type attenuators having a fixed attenuation ratio are connected in series in three stages. In FIG. 4, by controlling the potential of the ports 0 to 2 from the outside, each relay switch can be switched, and the output from the reading unit can be attenuated by a predetermined attenuation ratio and supplied to the antenna. Eight types of attenuation ratios of 0, 5, 15, 20, 25, 30, 40, or 45 dB can be realized depending on whether or not the switch connected to each port is switched to the attenuator side.

  FIG. 5 is a circuit diagram showing an attenuator using a PIN diode. The resistors R1 to R5, the capacitors C1 to C4, the coils L1 and L2, and the PIN diodes D1 and D2 are connected as shown in FIG. 5, and the analog voltages Vcont1 and Vcont2 applied to one end of the resistors R1 and R2 are changed to change the PIN. The currents DC0 and DC1 flowing through the diodes D1 and D2 can be changed, and the resistance values of the PIN diodes D1 and D2 with respect to the high frequency can be changed. Therefore, if the voltages Vcont1 and Vcont2 are set to predetermined values, the output from the reading unit can be attenuated by a predetermined attenuation ratio and transmitted to the antenna.

  In the above, the case where the first and second reading units 5 and 6 set the attenuation ratios of the first and second attenuators 3 and 4 has been described, but the present invention is not limited to this, and various configurations are possible. . For example, as shown in FIG. 6, the control unit 8 may directly set the attenuation ratio of the first and second attenuators 3, 4, and the control unit 8 can select either the first or second attenuator 3, 4. Only one attenuation ratio may be set, and the first and second reading units 5 and 6 may set the attenuation ratio of the other attenuator. In FIG. 6, the same components as those in FIG.

  Moreover, as shown in FIG. 7, it can also comprise and comprise the switch part 11. FIG. That is, in the configuration shown in FIG. 7, when the radio wave is radiated from the antenna, the control unit 8 sets a predetermined attenuation ratio in the attenuator 12 and controls the switch unit 11 to control the first and second antennas 1 and 2. One of them is connected to the attenuator 12 to emit radio waves. Thereafter, the reading unit 13 receives a signal using the same antenna that has radiated radio waves while maintaining the state of the switch unit 11. When the other antenna is used, the control unit 8 controls the switch unit 11 to connect the antenna to the attenuator 12, and similarly performs radio wave emission and signal reception. In this way, by newly adding a switch unit that selectively switches between two signal paths, only one reading unit and one attenuator are required, and the entire apparatus can be made inexpensive and small.

In order to detect a pedestrian with a tag, it is necessary to set the total time of the radio wave emission time T ₁ and the time T ₂ required for reception (hereinafter referred to as a reading time) to a predetermined value or less. . The upper limit of the reading time is determined according to the radio wave radiation pattern of the antenna to be used and the number of times the radio wave intensity is changed in one cycle. For example, as described above, the width direction of the passage is divided into eight, and radio waves are radiated from each antenna at eight levels, and the length of the radio wave overlap area A (j) shown in FIG. When the length is about 300 mm and the walking speed is 4 km / h, each reading time T ₁ + T ₂ is preferably about 17 msec or less.

  In the above detection process, it is assumed that the coil of the tag 10 is at a substantially constant angle with respect to the antenna. FIG. 8 shows an upper limit distance (reaction distance) at which a tag can be detected by arranging the tag and the tag at a certain angle, specifically, perpendicular to the radio wave radiation direction (X axis) of the antenna (see FIG. 9). It is the result of actually measuring the relationship between the antenna antenna attenuation ratio (attenuation amount). From this result, it can be seen that the attenuation ratio and the tag detection distance are substantially proportional.

  FIG. 10 is a diagram illustrating an example of an experimental result in which the angle of the tag with respect to the antenna is further changed. In FIG. 10, the angle of the tag is on the horizontal axis, the distance between the antenna and the tag is on the vertical axis, and the maximum communication distance for each attenuation ratio is indicated by different symbols (♦, ■, etc.). From FIG. 10, if the inclination angle of the tag with respect to the antenna is relatively small (angle change within about 30 to 40 degrees, more preferably within 20 degrees from the vertical), the relationship between the attenuation ratio and the tag detection distance (maximum communication distance). It can be seen that there is almost no change. Accordingly, the position of the tag 10 can be accurately identified by using the predetermined plurality of attenuation ratios as they are by the method shown in FIG. The result of FIG. 10 is an example, and the angle range in which the relationship between the attenuation ratio and the tag detection distance hardly changes may vary depending on the tag used. Therefore, it is desirable to set the attenuation ratio of the attenuator by experiment so that it can be applied to as wide an angular range as possible according to the tag to be used.

  On the other hand, FIG. 10 shows that when the inclination angle of the tag exceeds about 40 degrees, the relationship between the attenuation ratio and the tag detection distance changes. This means that a tag that is greatly inclined with respect to the antenna cannot be located even if radio waves having the intensity used for a tag with a relatively small inclination angle are used. The method described below is effective for this.

  It is assumed that there is a tag at a distance L1 from the antenna, and the tag is inclined at an angle greater than a predetermined angle with respect to the antenna. At this time, the radio wave output necessary for detecting the tag requires a larger output than when the tag is not tilted. That is, an output of γ (θ) × P is required using a coefficient γ larger than 1 with reference to the output P when the tag is not inclined. This coefficient γ is a function of the inclination angle θ of the tag, and can be determined in advance from experimental results (for example, FIG. 10) according to the antenna and tag used.

  FIG. 11 is a diagram for explaining a method of correcting a position error due to the inclination of the tag and a method of calculating the inclination angle of the tag. In FIG. 11A, the tag 10 is positioned between the first and second antennas 1 and 2 arranged on the left and right sides in a direction perpendicular to the direction in which these two antennas face each other. The distances between the first and second antennas 1 and 2 are L1 and L2, respectively. At this time, if the minimum powers of the first and second antennas 1 and 2 that can communicate with the tag 10 are P1 and P2, respectively, P1 + P2 becomes a constant value.

  In FIG. 11B, the tag 10 is inclined by an angle θ from the state of FIG. In this case, the minimum powers of the first and second antennas 1 and 2 that can communicate with the tag 10 are P1 ′ and P2 ′, respectively, and the value obtained by subtracting P1 + P2 from the sum P1 ′ + P2 ′ of these minimum powers is 2ΔP. Then, ΔP is the antenna power required depending on the angle θ. Since ΔP = (P1 ′ + P2 ′ − (P1 + P2)) / 2, if the value of P1 + P2 is measured in advance, ΔP can be obtained using P1 ′ and P2 ′ measured when the tag 10 is detected. it can.

  (C) of FIG. 11 shows the position of the tag 10 when it is assumed that the tag 10 is vertical corresponding to the powers P1 ′ and P2 ′ of the two antennas that can communicate with the tag 10 in the state of (b). FIG. That is, from the value of power P1 ′ (> P1), if the tag 10 is vertical, the distance from the first antenna 1 is L1 ′ = L1 + ΔL, and from the value of power P2 ′ (> P2), the tag 10 If it is vertical, it is determined that the distance from the second antenna 2 is L2 ′ = L2 + ΔL. However, actually, the measurement error ΔL is caused by the inclination of the tag 10 by the angle θ. That is, ΔL corresponds to the above ΔP. Since ΔP can be obtained as described above, ΔL can be obtained correspondingly. Therefore, L1 can be obtained from L1'-ΔL, and L2 can be obtained from L2'-ΔL. That is, even if the tag 10 is inclined, the position of the tag 10 can be obtained if it is known how much power can be used to communicate with the tag 10. If the relationship between the inclination angle θ of the tag 10 and ΔP is obtained in advance by measurement, the inclination angle θ of the tag 10 can be obtained from ΔP obtained from the actual measurement result as described above.

  As described above, if the tag is not detected even after performing steps S1 to S12 shown in FIG. 2, the tag actually exists between the first and second antennas 1 and 2, but the tag 10 May be unable to be detected due to the large inclination. Therefore, in this case, when executing the processes of steps S2 and S6 in the next scan, an output radio wave multiplied by coefficient γ (θ)> 1 is radiated. For example, in order to detect the case of θ = 0 to 40 (degrees), the processing described with respect to the flowchart of FIG. 2 is executed as it is (corresponding to γ = 1), and the case of θ = 50, 60, and 70 (degrees). The tag with a large inclination angle is detected using the respective coefficients γ (θ) of. Specifically, the tag detection process with a large inclination angle is the same as steps S1 to S12 using γ (50), and then the same process as steps S1 to S12 using γ (60). Processing is performed, and further, processing similar to steps S1 to S12 is performed using γ (70). Thereby, even if the tag is greatly inclined and positioned in the m-th section, the tag can be detected by the radio waves from the first and second antennas when the counter i = m.

  In the above, the case where the imaging unit 7 changes the angle in the imaging direction under the control of the control unit 8 has been described. However, the present invention is not limited to this. For example, while the imaging direction of the imaging unit 7 is fixed, The position of the imaging unit 7 may be changed in the width direction of the passage. Further, without receiving control from the control unit 8, in synchronization with the timing at which the first and second antennas 1 and 2 radiate radio waves to the detection target section, the section in which the imaging unit 7 autonomously corresponds is set. You may displace so that it may image. In that case, since a section in which the tag can be detected can always be imaged, there is no delay from the detection of the tag until the video of the section is actually displayed on the display unit. Furthermore, when a tag is detected in that state, processing for calling attention, for example, lighting of an alarm lamp, generation of an alarm sound, or the like may be performed.

  In addition, the case where one tag is detected has been described above. However, when a plurality of tags are detected, each tag can be identified by using the ID for each tag transmitted by the tag. The position of the tag can be specified.

  In the above description, the case where the section to be detected is scanned with radio waves from the first and second antennas 1 and 2 in order from one direction has been described. However, the present invention is not limited to this, and a predetermined area is divided into a plurality of areas. Each section may be scanned in any order as long as all sections can be scanned. For example, the above eight sections may be scanned in the order of the first, third, fifth, seventh, second, fourth, sixth, and eighth sections.

  Further, if the reading time is sufficiently short, the radio wave may be formed only from one antenna, and then the radio wave may be formed only from the other antenna. For example, radio wave radiation and signal reception may be repeated continuously 8 times only from the first antenna 1, and then radio wave radiation and signal reception may be repeated 8 times continuously only from the second antenna 2. In that case, the radio wave output (attenuation ratio) of the first antenna 1 and the radio wave output (attenuation ratio) of the second antenna 2 when the tag can be detected as a result of one scan (a total of 16 radio wave emissions and receptions). ), The section where the tag is located can be determined. The same applies to the detection processing when the tag is inclined as described above. That is, when detecting a tag having a large inclination angle using each coefficient γ (θ) in the case of θ = 50, 60, 70 (degrees), the first antenna 1 is used using one γ (θ). It is also possible to repeat radio wave radiation and signal reception 8 times continuously only from, and then repeat radio wave radiation and signal reception 8 times continuously only from the second antenna 2. In addition, using γ (50), γ (60), and γ (70), radio wave emission and signal reception are repeated 24 times (8 times × 3 cycles) continuously only from the first antenna 1, and thereafter the same. In addition, using γ (50), γ (60), and γ (70), radio wave emission and signal reception may be repeated continuously 24 times (8 times × 3 cycles) only from the second antenna 2. .

  Further, the present invention is not limited to the case where the entire section obtained by dividing the predetermined area to be detected by the tag is targeted. For example, first, a range in which a tag detection range of radio waves radiated from the first antenna and a tag detection range of radio waves radiated from the second antenna overlap is a section including the center between the first and second antennas. In this way, tag detection processing can be performed by setting the attenuation ratio of each antenna. In this case, when only one of the first and second antennas detects the tag, as described above, only the first half region from the center on the side close to the antenna where the tag is detected is used. The tag detection process is performed by changing the attenuation ratio of the attenuator. As a result, the number of measurements may be reduced compared to the case where the entire predetermined area is always targeted, and efficient tag detection becomes possible. When the number of sections is an odd number, the section including the center is first detected, and when the number of sections is an even number, one of the two sections near the center is first detected. That's fine.

  Further, the present invention is not limited to the case of using two antennas, and a horizontal two-dimensional region may be scanned by providing a plurality of antennas on each wall on both sides.

  Also, a vertical two-dimensional region may be scanned by providing a plurality of antennas in the vertical direction of each wall on both sides.

  Alternatively, antennas may be arranged two-dimensionally on the walls on both sides, and a three-dimensional space sandwiched between them may be scanned.

It is a block diagram which shows schematic structure of the position detection apparatus which concerns on embodiment of this invention. It is a flowchart which shows the process which the position detection apparatus which concerns on embodiment of this invention performs. It is a figure which shows the electromagnetic wave which the position detection apparatus which concerns on embodiment of this invention generate | occur | produces in time series. It is a block diagram which shows a switching type variable attenuator. It is a circuit diagram which shows the attenuator using a PIN diode. It is a block diagram which shows the modification of the position detection apparatus which concerns on embodiment of this invention. It is a block diagram which shows another modification of the position detection apparatus which concerns on embodiment of this invention. It is a figure which shows the result of having actually measured the relationship between a tag detection distance and an attenuation factor. It is a figure which shows the positional relationship of the antenna and tag at the time of experiment. It is a figure which shows the experimental result which changed the angle of the tag with respect to an antenna. It is a figure explaining the correction method of the position error by the inclination of a tag, and the calculation method of the inclination angle of a tag. It is a figure which shows notionally the conventional location specifying method using RFID.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 1st antenna 2 2nd antenna 3 1st attenuator 4 2nd attenuator 5 1st reading part 6 2nd reading part 7 Imaging part 8 Control part 9 Display part 10 RFID tag 11 Switch part 12 Attenuator 13 Reading part

Claims (14)

A first step of receiving a first signal using the first antenna after the control reading unit radiates the first antenna for a predetermined time with a first attenuation ratio;
After the first step, the control reading unit causes the second antenna to radiate radio waves with a second attenuation ratio for a predetermined time, and then receives a second signal using the second antenna;
A third step in which the control reading unit determines whether or not both of the first signal and the second signal are equal to or greater than a predetermined value determined to have received a signal from an RFID tag;
When the control reading unit determines in the third step that both the first signal and the second signal are equal to or greater than the predetermined value, the RFID tag detection range of the radio wave radiated from the corresponding first antenna; A fourth step of determining that the RFID tag exists within a range in which the RFID tag detection range of radio waves radiated from the second antenna partially overlaps,
Executing each of the first step to the fourth step a predetermined number of times as one cycle, repeating the first step to the fourth step,
During the one cycle, when the first step is executed after the second time, using the first damping ratio increased from the first damping ratio in the first step one time before,
An RFID tag characterized by using a second attenuation ratio that is smaller than the second attenuation ratio in the second step before the first time when the second step is executed after the second time in the one cycle. Position detection method.   In the first attenuation ratio and the second attenuation ratio, the coil surface inside the RFID tag is inclined perpendicularly or within a predetermined angle from the perpendicular to the opposing direction of the first antenna and the second antenna. The RFID tag position detection method according to claim 1, wherein the RFID tag position is a value determined so that the RFID tag can be detected. The first antenna and the second antenna have ranges in which the RFID tag detection range of the radio wave radiated from the first antenna and the RFID tag detection range of the radio wave radiated from the second antenna overlap at the first time of the one cycle. The first attenuation ratio and the second attenuation ratio are set so as to be a predetermined region near the center between, and the first step and the second step are executed,
In the subsequent third step, when it is determined that only one of the first signal and the second signal is greater than or equal to the predetermined value, the center of the lines connecting the first antenna and the second antenna The first to fourth steps are executed for an area including a line close to the antenna on the side receiving the signal determined to be equal to or greater than the predetermined value. RFID tag position detection method. A fifth step in which the control reading unit causes the first antenna to radiate a radio wave at a third attenuation ratio for a predetermined time and then receives a third signal using the first antenna;
After the fifth step, the control reading unit causes the second antenna to radiate radio waves with a fourth attenuation ratio for a predetermined time, and then receives a fourth signal using the second antenna;
A seventh step in which the control reading unit determines whether or not both the third signal and the fourth signal are equal to or greater than the predetermined value determined to have received a signal from an RFID tag;
When the control reading unit determines in the seventh step that both the third signal and the fourth signal are equal to or greater than the predetermined value, the RFID tag detection range of the radio wave radiated from the corresponding first antenna; And an eighth step of determining that the RFID tag exists within a range in which the RFID tag detection range of radio waves radiated from the second antenna partially overlaps,
After the one cycle, each of the fifth step to the eighth step is executed the same number of times as the first step to the third step,
The third damping ratio in the fifth step is a value obtained by increasing the first damping ratio used in the first step of the number of executions corresponding to the number of executions of the fifth step by a predetermined ratio,
The fourth attenuation ratio in the sixth step is a value obtained by increasing the second attenuation ratio used in the second step of the number of executions corresponding to the number of executions of the sixth step by a predetermined ratio. The method for detecting the position of an RFID tag according to claim 2 or 3, characterized in that: As a result of the determination in the third step, when both the first signal and the second signal are equal to or greater than the predetermined value, or
As a result of the determination in the seventh step, when both the third signal and the fourth signal are equal to or greater than the predetermined value,
5. The RFID tag position detection method according to claim 1, further comprising a ninth step of controlling the imaging unit so that the control reading unit captures the superimposed region.   The imaging unit further includes a ninth step of displacing the imaging unit so as to capture the superimposed region in synchronization with the first step and the second step, or the fifth step and the sixth step. The RFID tag position detection method according to any one of claims 1 to 4. If it is determined in the eighth step that the RFID tag is present,
The third damping ratio used in the corresponding fifth step;
The fourth damping ratio used in the corresponding sixth step;
RFID tag detection range of radio waves radiated from the corresponding first antenna;
5. The RFID tag position detection method according to claim 4, wherein an inclination angle of the tag is obtained using an RFID tag detection range of radio waves radiated from the corresponding second antenna. A first step of receiving a first signal using the first antenna after the control reading unit radiates the first antenna for a predetermined time with a first attenuation ratio;
A second step in which the control reading unit causes the second antenna to radiate a radio wave at a second attenuation ratio for a predetermined time and then receives a second signal using the second antenna;
After repeating the first step and the second step, each cycle of the first step and the second step being performed a predetermined number of times, the control reading unit transmits the first signal and the second signal. A third step of determining whether or not both are equal to or greater than a predetermined value determined to have received a signal from the RFID tag;
When the control reading unit determines in the third step that both the first signal and the second signal are equal to or greater than the predetermined value, the RFID tag detection range of the radio wave radiated from the corresponding first antenna; A fourth step of determining that the RFID tag exists within a range in which the RFID tag detection range of radio waves radiated from the second antenna partially overlaps,
The first damping ratio used in the first step executed a plurality of times in the one cycle is different for each of the first steps;
The second damping ratio used in the second step executed a plurality of times in the one cycle is different for each of the second steps,
When a plurality of the first attenuation ratios used in the one cycle are arranged in descending order and a plurality of the second attenuation ratios used in the one cycle are arranged in ascending order, the corresponding first A part of the RFID tag detection range when radio waves are radiated at the 1 attenuation ratio and the 2nd attenuation ratio overlap,
The first signal and the second signal to be determined in the third step are used in the one cycle by arranging a plurality of the first attenuation ratios used in the one cycle in descending order. A position of the RFID tag, which is a signal received when radio waves are radiated at a corresponding first attenuation ratio and second attenuation ratio when the plurality of second attenuation ratios are arranged in ascending order. Detection method. A first antenna and a second antenna disposed to face each other at a predetermined interval;
A first attenuator and a second attenuator;
A first reading unit and a second reading unit;
A control unit that receives signals from the first reading unit and the second reading unit;
After the control unit or the first reading unit sets a first attenuation ratio in the first attenuator and causes the first antenna to emit a radio wave for a predetermined time, the first reading unit receives the first signal. To the control unit,
Thereafter, the control unit or the second reading unit sets a second attenuation ratio in the second attenuator and causes the second antenna to emit a radio wave for a predetermined time, and then the second reading unit outputs a second signal. Receive and transmit to the control unit,
The RFID tag detection range of radio waves radiated from the first antenna and the RFID tag detection range of radio waves radiated from the second antenna partially overlap,
If the received first signal and the second signal are both equal to or greater than a predetermined value, the control unit determines that an RFID tag is present in the overlapping region,
Executing the radio wave radiation and the signal reception a predetermined number of times as one cycle, repeating the radio wave radiation and the signal reception,
During the one cycle, when the first reading unit emits radio waves after the second time, using a first attenuation ratio increased from the first attenuation ratio set by the previous radio wave emission,
During the one cycle, when the second reading unit emits radio waves after the second time, a second attenuation ratio that is lower than the second attenuation ratio set by the previous radio wave emission is used. RFID tag position detection device. A first antenna and a second antenna disposed to face each other at a predetermined interval;
A switch part;
With an attenuator,
A control reading unit,
The control reading unit sets a first attenuation ratio in the attenuator, controls the switch unit to connect the first antenna and the attenuator, and radiates radio waves to the first antenna for a predetermined time. Receiving a first signal using the first antenna;
Thereafter, the control reading unit sets a second attenuation ratio for the attenuator, controls the switch unit to connect the second antenna and the attenuator, and causes the second antenna to emit radio waves for a predetermined time. Then, the second signal is received using the second antenna,
The RFID tag detection range of radio waves radiated from the first antenna and the RFID tag detection range of radio waves radiated from the second antenna partially overlap,
The control reading unit determines that an RFID tag is present in the overlapping region if both of the received first signal and the second signal are equal to or greater than a predetermined value,
Executing the radio wave radiation and the signal reception a predetermined number of times as one cycle, repeating the radio wave radiation and the signal reception,
During the one cycle, when the control reading unit performs radio wave emission for the second time and thereafter, the first attenuation ratio increased from the first attenuation ratio set by the radio wave emission of the previous time is used.
During the one cycle, when the control reading unit emits radio waves after the second time, a second attenuation ratio that is reduced from the second attenuation ratio set by the previous radio wave emission is used. RFID tag position detection device.   In the first attenuation ratio and the second attenuation ratio, the coil surface inside the RFID tag is inclined perpendicularly or within a predetermined angle from the perpendicular to the opposing direction of the first antenna and the second antenna. 11. The RFID tag position detecting device according to claim 9 or 10, wherein the value is determined so that the RFID tag can be detected.   The RFID according to any one of claims 9 to 11, further comprising an imaging unit that is controlled so as to image the superimposed region when it is determined that an RFID tag is present in the superimposed region. Tag position detection device.   The RFID tag position detection device according to claim 9, further comprising an imaging unit that is displaced so as to image the superimposed region in synchronization with the radio wave radiation. A first antenna and a second antenna disposed to face each other at a predetermined interval;
A first attenuator and a second attenuator;
A first reading unit and a second reading unit;
A control unit that receives signals from the first reading unit and the second reading unit;
After the control unit or the first reading unit sets a first attenuation ratio in the first attenuator and radiates radio waves from the first antenna for a predetermined time, the first reading unit receives the first signal. To the control unit,
Thereafter, the control unit or the second reading unit sets a second attenuation ratio in the second attenuator and radiates a radio wave from the second antenna for a predetermined time, and then the second reading unit outputs a second signal. Receive and transmit to the control unit,
The RFID tag detection range of radio waves radiated from the first antenna and the RFID tag detection range of radio waves radiated from the second antenna partially overlap,
If the received first signal and the second signal are both equal to or greater than a predetermined value, the control unit determines that an RFID tag is present in the overlapping region,
Each of the first reading unit and the second reading unit executes radio wave radiation and signal reception a predetermined number of times as one cycle, and repeats radio wave radiation and signal reception,
The first damping ratios set a plurality of times in the one cycle are different from each other,
The second damping ratios executed a plurality of times in the one cycle are different from each other,
When a plurality of the first attenuation ratios used in the one cycle are arranged in descending order and a plurality of the second attenuation ratios used in the one cycle are arranged in ascending order, the corresponding first A part of the RFID tag detection range when radio waves are radiated at the 1 attenuation ratio and the 2nd attenuation ratio overlap,
The first signal and the second signal to be determined in the third step are used in the one cycle by arranging a plurality of the first attenuation ratios used in the one cycle in descending order. When the plurality of second attenuation ratios are arranged in ascending order, the RFID tag is a signal received when radio waves are radiated at the corresponding first attenuation ratio and second attenuation ratio. Position detector.

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