JP5121676B2 - Wireless tag reader, wireless tag reading program, and wireless tag communication system - Google Patents

Description

  The present invention relates to a wireless tag reading device, a wireless tag reading program, and a wireless tag communication system. For example, when identification information of an article or an individual is processed after a wireless tag stored after the bit width is expanded It can be applied to.

  In recent years, there has been a need for efficient manufacturing process automation systems and physical distribution systems, and an efficient identification system for articles is required. An efficient identification system is (1) the identification medium added to the article is inexpensive, (2) less susceptible to the surrounding environment (noise, dirt, etc.), and (3) the system for identifying individual data is simple. It can be realized by having features such as low operating costs.

  The M-sequence is one of pseudo-random sequences and is used for spreading code communication and the like, and is a deterministic signal generated by a shift register, but its statistical property is similar to a true irregular signal. Such M series has already been used as individual data for identification and authentication of articles and individuals (see, for example, Patent Document 1).

There is a system using a wireless tag (RFID) as a system for identifying an article or an individual, which is used in inventory management or room entry / exit management. For example, when an M-sequence is applied to a system using a wireless tag, there are advantages such as less interference with other wireless tags and access to a plurality of wireless tags at a time.
JP 2004-143806 A

  As a signal used for generating individual data for identification or authentication of an individual, it is required that a large amount of information can be placed and that noise resistance is high.

  For example, even in the case of an RFID system, not only when there is a lot of electromagnetic noise, it is often possible that the radio signal is disturbed due to reflection or absorption by the surrounding environment and becomes indistinguishable. The M-sequence has higher noise resistance than other signal sequences, but even if the M-sequence is applied, noise may be a problem, and the amount of information that can be put on the M-sequence alone is not sufficient. There is also.

  In view of the inconveniences described above, the applicant of the present application has already proposed that excellent noise resistance and a sufficient amount of information are achieved by generating a discrimination signal by combining preferred M sequences ( Japanese Patent Application No. 2007-316226).

  Further, in consideration of a system that performs simultaneous reading of a plurality of RFID tags, the applicant of the present invention has a ratio of “1” and “0” after conversion for each P (P is a natural number) bits of the identification signal. , Already proposed to improve simultaneous readability by converting to Q (Q is a natural number; Q> P) bits and writing to the wireless tag so that one is sufficiently larger than the other (this is called biased) (Japanese Patent Application No. 2008-59862).

  However, during actual operation, noise more than expected may occur, or more wireless tags than the number that can be simultaneously read may exist within the readable range of the wireless tag reader. When the wireless tag reader fails in simultaneous reading, it cannot be determined whether it is caused by noise more than expected or because there are many wireless tags. Also, for example, even in a situation where there is little noise, it is not possible to grasp how many wireless tags are present before executing the identification signal recognition processing of each wireless tag, and simultaneous reading ends in failure. Even in the situation, the recognition processing of the identification signal is performed wastefully.

  Therefore, there is a demand for a wireless tag reader, a wireless tag reading program, and a wireless tag communication system in which the reader side can grasp the communication state without executing communication for special measurement with the wireless tag.

  According to the first aspect of the present invention, after the conversion, the bit width is converted into Q (Q> P) bits so that the ratio of “1” and “0” is biased after conversion for every P bits of the individual data. Communication for detecting a ratio of “1” or “0” in a signal series received by a reading operation as an index representing a communication state in a wireless tag reader that reads a wireless tag having individual data as unique individual data. It has a state detection means.

  The RFID tag reading program of the second aspect of the present invention is converted into Q (Q> P) bits so that the ratio of “1” and “0” is biased after conversion for each P bit of the original individual data. Ratio of “1” or “0” in a signal sequence received by a computer mounted on a wireless tag reader that reads a wireless tag whose individual data is the individual data after the bit width extension is read. Is made to function as a communication state detecting means for detecting as an index representing the communication state.

  The wireless tag communication system of the third aspect of the present invention is converted into Q (Q> P) bits so that the ratio of “1” and “0” is biased after conversion for each P bit of the original individual data. The wireless tag includes the individual data after the bit width extension as unique individual data, and the wireless tag reader according to the first aspect of the present invention.

  According to the present invention, the reader side can grasp the communication state without executing communication for special measurement with the wireless tag.

(A) Main Embodiment Hereinafter, an embodiment of a wireless tag reading device, a wireless tag reading program, and a wireless tag communication system according to the present invention will be described in detail with reference to the drawings.

(A-1) Individual data writing device for wireless tag The wireless tag communication system of the embodiment has a wireless tag and a wireless tag reader as shown in FIG. The wireless tag communication system according to the embodiment is characterized by the configuration and function on the wireless tag reader side. This feature is based on the configuration of individual data written in the wireless tag. First, an individual data writing device for a wireless tag will be described.

(A-1-1) Configuration of Individual Data Writing Device for Wireless Tag FIG. 1 is a block diagram showing a configuration of an individual data writing device for a wireless tag, and FIG. It is a block diagram which shows a structure.

  In FIG. 1, a wireless tag individual data writing device 1 includes a management number / delay data conversion unit 2, a signal sequence generation unit 3, a bit width expansion unit 4, an individual data writing unit 5, and a data association storage unit 6. And a control unit 7.

  The management number / delay data conversion unit 2 sets a management number given from the control unit 7 when a blank wireless tag in which individual data is not stored becomes a new write target. This is converted to R0 to Rr and given to the signal sequence generation unit 3.

  The signal sequence generation unit 3 may be configured in hardware, or may be configured in software such that the function is realized by the CPU executing a signal sequence generation program. 3 is functionally configured as shown in FIG. The signal sequence generation unit 3 generates individual data before extending the bit width, which is determined by a detailed configuration described later and a delay data group given from the management number / delay data conversion unit 2. Here, the individual data output from the signal sequence generation unit 3 has substantially the same frequency of “1” and “0” bits.

  The bit width expansion unit 4 expands the bit width of the individual data output from the signal sequence generation unit 3 and makes the ratio of “1” bits sufficiently smaller than the ratio of “0” bits. . For example, a pulse position modulation (PPM) method can be applied as a bit width expansion method by the bit width expansion unit 4.

  FIG. 2 is an explanatory diagram of an example (PPM method) of the bit width extension method by the bit width extension unit 4. The example of FIG. 2 shows an example of expanding to a 16-bit width every 4 bits.

  Assume that the individual data output from the signal sequence generation unit 3 is “0000010100...” As shown in FIG. This individual data is divided into 4 bits. That is, it is divided into “0000”, “0101”, “00. Replace each 4 bits with hexadecimal notation 0-9, A (= 10) to F (= 15), and only the bit position represented by the number in hexadecimal notation is “1” in 16 bits, and the other bit positions are All are set to “0”. For example, since the first 4 bits are “0000”, it is “0” in hexadecimal notation. As shown in FIG. 2B, among bits 0 to F, hexadecimal notation “0” is set. It is converted into data in which bit 0 as the bit order takes “1” and other bits 1 to F take “0”. Since the second 4 bits are “0101”, it is “5” in hexadecimal notation. As shown in FIG. 2B, of bits 0 to F, hexadecimal notation “5” is bit. The order bit 5 is “1”, and the other bits 0 to 4 and bits 6 to F are converted to data “0”. That is, if the 4-bit hexadecimal notation is “x”, it is converted into data in which the bit x takes “1” and all other bits take “0”. In the example of FIG. 2, the ratio 1/16 of the “1” bit is sufficiently smaller than the ratio 15/16 of the “0” bit.

  The example of FIG. 2 shows an example in which every 4 bits are expanded to a 16-bit width, but it is needless to say that other expansion methods may be applied, such as an expansion to a 32-bit width every 5 bits.

  The individual data writing unit 5 is, for example, a first storage unit that initially stores blank wireless tags for a lot unit or a single wireless tag from the first storage unit and sets it at a writing position. Stores the feeding mechanism unit, the writing execution unit for writing the individual data after the bit width extension output from the bit width extension unit 4 to the blank wireless tag set at the writing position, and the wireless tag with the individual data written therein. A second storage unit, a moving mechanism unit for moving the wireless tag in which individual data is written from the writing position to the second storage unit, and the like are provided, and the individual data is written in the blank wireless tag.

  The data association storage unit 6 stores the delay data group (or management number) and the individual data after the bit width expansion in association with each other. The individual data after the bit width extension may be stored as it is, and in consideration of the accuracy of the cross-correlation process described later, each bit of the individual data after the bit width extension is extended to 3 bits having the same value. (That is, bit “0” of the individual data after the bit width extension is stored as “000”, and bit “1” of the individual data after the bit width extension is stored as “111”. ). In the following description, it is assumed that the individual data after the bit width extension is stored as it is.

  The stored association data is used for identification or authentication by a data processing system that processes data from a wireless tag, such as a manufacturing process automation system or a distribution system. Note that a system that uses individual data after bit width expansion as an ID may be used, and a system that uses a delay data group (or management number) as an ID may also be used. A wireless tag communication system and a communication method, which will be described later, assume a system that uses individual data after bit width extension as an ID.

  The control unit 7 controls the individual data writing device 1 as a whole, and writes the individual data after the bit width extension to the blank wireless tag as described above. Here, the control unit 7 may write a data portion for establishing synchronization such as a flag sequence in addition to the individual data after the bit width expansion to the blank wireless tag.

  As shown in FIG. 3, the signal sequence generation unit 3 is exclusive of M sequences from r + 1 M sequence generation units 10-0 to 10-r and all M sequence generation units 10-0 to 10-r. And an exclusive OR circuit 11 which is an adding means for taking an exclusive OR.

  Each of the M-sequence generation units 10-0 to 10-r includes an M-sequence generation body 20-0 to 20-r that is a plurality of M-sequence generation units, and variable delay units 21-0 to 21- that are variable delay addition units. r.

The M-sequence generation bodies 20-0 to 20-r generate M-sequences according to characteristic polynomials f ₀ (x) to f _r (x) having different orders n, and n-stage shift registers SR0 to SRr and , Has a well-known configuration of one or a plurality of exclusive OR circuits ExOR01 to ExORr1 that take an exclusive OR of the output of the stage determined by the characteristic polynomial.

  Of the r + 1 M sequences generated by the M sequence generation bodies 20-0 to 20-r, any two of them are in a preferred pair relationship. Here, for M sequences, a pair of M sequences in which the maximum value of the cross-correlation function between the M sequences of the same order and the M sequences having different characteristic polynomials is referred to as a preferred pair. The preferred pair is described in, for example, Document A “D. 619, 1980. ”.

  Each of the variable delay devices 21-0 to 21-r delays the M sequence generated by the corresponding M sequence generation main body 20-0 to 20-r by the instructed amount and supplies the delayed delay to the exclusive OR circuit 11. It is. The delay amounts in the variable delay devices 21-0 to 21-r are not necessarily the same, and the combination of these delay amounts is one parameter that defines the uniqueness of the individual data generated by the signal sequence generation unit 3. .

The variable delay devices 21-0 to 21-r are respectively associated with the corresponding M sequence generation bodies 20-0 to 20-20 so that an arbitrary delay amount shorter than the M sequence period 2 ⁿ -1 can be provided with a simple configuration. An exclusive OR of the multiplier groups D0-Dr that multiplies the set values by the values of the respective stages of the shift registers SR0-SRr at -r and the outputs of the corresponding multiplier groups D0-Dr. It consists of OR circuits ExOR02 to ExORr2.

The n pieces of data set in the multiplier groups D0 to Dr are delay data R0 to Rr given from the management number / delay data converter 2. For example, delay data R0 {r _0,0 ,..., R _{0, n−1} } is set in the multiplier group D0.

(A-1-2) Method for Obtaining Delayed M-sequence Next, the fact that the variable delay devices 21-0 to 21-r can be realized by the arithmetic configuration as shown in FIG. A description will be given using a model of a variable delay device.

If an M-sequence is given an initial state of the n-stage shift register SR, all subsequent states are determined. Therefore, the M-sequence x ^d delayed by an arbitrary delay amount d is determined at each stage of the shift register SR. It can be seen that the content x0,..., Xn-1 is given by the linear combination represented by the equation (1).

x ^d = r ₀ x ₀ + r ₁ x ₁ + r ₂ x ₂ +... + r _n−1 x _n−1 (1)
The coefficient r _i (i is 0 to (n−1)) is “0” or “1”. If the coefficient r _i is known, it can be determined which stage of the shift register SR should be added.

The delay amount d can take a value in a range shorter than one period 2 ⁿ −1 of the M sequence, and can take a value smaller than the number n of stages of the shift register SR or can take a number n or more.

When the delay amount d is smaller than the number n of stages of the shift register SR, the delayed M series can be extracted from the stage j corresponding to the delay amount d of the shift register SR. In this case, only the coefficients r _j for content x _j of that stage j is "1", all of the coefficients for the contents of the other stages may be "0".

Consider a case where the delay amount d is greater than or equal to the number n of stages of the shift register SR. When the delayed M sequence ^xd is divided by the characteristic polynomial f (x) related to the M sequence generation body, the following equation (2) is established. In equation (2), Q (x) is a quotient, and R (x) is a remainder polynomial.

x ^d = Q (x) f (x) + R (x) (2)
Pay attention to the right side of equation (2). Here, the degree of the remainder polynomial R (x) is smaller than n, and the degree part entrusted to the remainder polynomial R (x) in Q (x) f (x) is zero. Here, considering the same order as the right side of equation (1), equation (2) can be written as equation (3).

x ^d = R (x) (3)
From the comparison between the equations (1) and (3), the coefficient of the remainder polynomial R (x) becomes r _{0 to} r _n−1 for forming the M sequence x ^d delayed by the delay amount d. Yes. That is, in order to form the M-sequence x ^d which is delayed by the time delay d may be taken out of the coefficients of x ^d a characteristic polynomial f (x) obtained by dividing obtained remainder polynomial R (x).

(A-1-3) Operation of Wireless Tag Individual Data Writing Device Next, the operation of the wireless tag individual data writing device will be described.

  When a new blank wireless tag is to be written, the control unit 7 sets initial values in all the shift registers SR0 to SRr of the signal sequence generation unit 3 and manages the management number related to the wireless tag to be written. This is given to the number / delay data converter 2. The management number / delay data conversion unit 2 converts the management number into the delay data groups R0 to Rr and sets them in the multiplier groups D0 to Dr of the signal sequence generation unit 3.

  When such initialization processing ends, the control unit 7 causes the signal sequence generation unit 3 to start an operation based on the clock.

The M sequence generation body 20-0 of the M sequence generation unit 10-0 rewrites the contents of the stage of the shift register SR0 for each clock. The multiplier group D0 of the variable delay device 21-0 multiplies the contents of the stage of the shift register SR0 by the set value of the delay data group R0, and the multiplication result is added by the exclusive OR circuit ExOR02 ( And is output as an M series a ₀ (j + d ₀ ) delayed by a delay amount corresponding to the value of the delay data group R0.

The other M sequence generation units 10-1 to 10-r operate in the same manner, and output delayed M sequences a ₁ (j + d ₁ ) to a _r (j + d _r ).

The exclusive OR circuit 11 adds (exclusive OR) the delayed M sequences a ₀ (j + d ₀ ) to a _r (j + d _r ) from all the M sequence generators 10-0 to 10 -r. And output as individual data C _k (j).

In the output individual data C _k (j), the bit width is expanded by the bit width expansion unit 4, and the ratio of “1” bits is made sufficiently smaller than the ratio of “0” bits.

  The individual data after the bit width extension is written into the wireless tag to be written by the individual data writing unit 5. Further, the data association storage unit 6 stores the delay data group (or management number) and the individual data after the bit width expansion in association with each other.

(A-1-4) Concept of signal generation For M sequences, a pair of M sequences having the same order M sequence and a minimum cross-correlation function with an M sequence having different characteristic polynomials is So called Preferred Pair. It has been found that the maximum value H of the number of M-sequences that are mutually preferred pairs is as shown in Table 1 (see Document A above). However, it is not shown which pair is specifically a preferred pair.

  In the signal generation method described above, attention is paid to the fact that sequences generated by combining M sequences that are preferred pairs with each other are sequences having a small correlation with each other.

  In Table 1, suppose that the largest set (the number of elements is H) of a pair that is a preferred pair with each other is used for signal generation, the larger the n × H, the more information can be sent.

Assuming that there are r combinations whose maximum value of aggregate elements that are mutually preferred pairs is H, the total amount of information that can be sent is r × 2 ^{n × H.}

  Unlike the Gold sequence using two M sequences and the Kasami sequence using three M sequences, the signal generation method described above uses all or most of the H M sequences that are preferred pairs with each other. This is a method for generating a signal sequence with less interference, in which the type of information to be entered is increased by adding a delay after giving a delay to each.

  According to Table 1, the larger the product of the order n of the M sequence and the maximum value H of the number of preferred pairs, the larger the information that can be loaded. explain.

As for the degree 7, since it is known that the total number of characteristic polynomials is 18, as a result of selecting 6 (maximum value H) from these and searching for a combination in which any pair of them is a preferred pair, 18 sets of M series shown in Table 2 were found.

Note that the values defining the characteristic polynomial in Table 2 are expressed in octal and represent the following. The order is not 7, but the case of characteristic polynomial f (x) = 1 + x ⁴ + x ⁵ + x ⁶ + x ⁸ is taken as an example. In this case, when each power coefficient is represented by 0 and 1, and only the coefficient is extracted and represented, the characteristic polynomial f (x) can be represented as f (x) = 1000011101 (binary number). When such a binary display is displayed in octal, the characteristic polynomial f (x) can be expressed as f (x) = 435 (octal number). Table 2 applies such octal display.

One set out of 18 sets in Table 2 is selected, and r + 1 pieces forming the signal sequence generation unit 3 of FIG. 3 so as to follow the six characteristic polynomials f ₀ (x) to f ₅ (x) of the set (= H = 6) seventh-order M-sequence generators 10-0 to 10-r are formed. The delay data groups R0 to Rr are also obtained by using the selected set of six characteristic polynomials f ₀ (x) to f ₅ (x).

Signal generation when the 7th order M-sequence is used is expressed by the following equation (4) because the number of M-sequence generation units 10-0 to 10-r is six.

  The individual data output from the signal sequence generation unit 3 is a signal sequence with good noise resistance that can carry a large amount of information with little interference. However, since this signal sequence includes approximately the same amount of “1” and “0”, when this signal sequence is applied to a system in which the wireless tag reader can simultaneously read a plurality of wireless tags, The signals “1” overlap, making it difficult to distinguish each signal from the received signal.

  For this reason, the bit width extension unit 4 extends the bit width so that the ratio of “1” bits is sufficiently smaller than the ratio of “0” bits.

(A-2) Radio Tag Communication System (A-2-1) Configuration of Radio Tag Communication System FIG. 5 illustrates communication with a radio tag into which extended individual data is written by the individual data writing device 10 described above. 1 is a block diagram illustrating a configuration of an RFID tag communication system according to an embodiment.

  In FIG. 5, the wireless tag communication system 30 includes a wireless tag 31, a wireless tag reader 32, and a host device 33. The wireless tag reader 32 and the host device 33 constitute a wireless tag reader. The host device 33 is not always necessary, but it is preferable to have the host device 33 because the wireless tag reader 32 can be miniaturized when storing a large amount of data.

  The wireless tag 31 is written with the individual data expanded by the individual data writing device 10 described above, and attached to the article or individual for management such as identification or authentication of the article or individual. It is something that an individual possesses. The wireless tag 31 includes a loop transmission / reception antenna 40, an individual data memory 41 that records expanded individual data, a control unit 42 that controls the operation of the wireless tag 31, and an inquiry signal from the wireless tag reader 32. Is received and given to the control unit 42, and the control unit 42 includes a transmission / reception unit 43 that transmits the expanded individual data read from the individual data memory 41.

  For example, a resonance circuit (for example, an LC resonance circuit) that resonates with the carrier frequency of the interrogation signal is configured by the loop-shaped transmission / reception antenna 40 and a part of the constituent elements of the transmission / reception unit 43 or the control unit 42. An operating power supply for the tag 31 is obtained. The individual data memory 41 is preferably a nonvolatile memory. The digital modulation method between the wireless tag 31 and the wireless tag reader 32 is not limited. For example, an ASK (amplitude shift keying) modulation method, an FSK (frequency shift keying) modulation method, and a PSK (phase shift keying) modulation method are used. Applicable. In the following description, it is assumed that the ASK modulation method is applied.

  The wireless tag reader 32 radiates an inquiry signal to its surroundings under the control of the host device 33 and acquires expanded individual data of the wireless tag 31 existing in the vicinity of the wireless tag reader 32. is there.

  The wireless tag reader 32 digitally modulates the non-directional or directional transmission / reception antenna 50, the duplex unit 51 that separates the transmission system and the reception system, and the baseband interrogation signal given from the control unit 54 to the duplex unit 51. A transmission unit 52 for giving, a reception unit 53 for converting a reception signal from the duplex unit 51 into a baseband signal, and further converting into a binary (digital value) signal, a control unit 54 in charge of a function described later, and communication Correspondence information between the communication state storage unit 55 for storing the state, the delay data group (or management number), and the individual data after the bit width extension similar to the data association storage unit 6 of the individual data writing device described above And the reference data 56 storing the data and the individual data or the delay data obtained after the bit width expansion obtained during the identification process of the control unit 54. The candidate group (or control number) and a candidate storage unit 57 for buffering.

  The receiving unit 53 applies the sampling rate of the individual data after the bit width extension output from the wireless tag 31 as the sampling rate when converting the baseband signal into a binary (digital value) signal.

  The control unit 54 radiates a question signal and determines the communication state based on the subsequent capture signal. When the communication state is good, the control unit 54 is assigned to the wireless tag 31 existing in the vicinity of the wireless tag reader 32. Identification of extended individual data.

(A-2-2) Communication State Determination Method Hereinafter, a communication state determination method executed by the control unit 54 will be described with reference to the flowchart of FIG. 6 is provided in the control unit 54 as a communication state determination program, for example.

  For example, when the control unit 54 instructs to emit a question signal, when the predetermined time (determined in consideration of the response signal that arrives earliest) has elapsed from the time of the instruction, or the receiving unit 53 6 starts when the predetermined start condition is satisfied, such as when the first outputs “1”.

  First, the control unit 54 calculates the ratio of “1” within a predetermined period in the digital value series from the receiving unit 53 (step S100), and uses the calculated ratio of “1” as an index representing the communication state to indicate the communication state. The data is stored in the storage unit 55 (step S101). For example, if 4 bits before expansion is 1 word and 32 words are used as identification information, the ratio of “1” is calculated for 512 bits, which is 16 bits of 32 words expanded by 4 bits.

  Thereafter, the control unit 54 determines whether or not the calculated ratio of “1” is smaller than the threshold (step S102). If the calculated ratio of “1” is equal to or greater than the threshold, the control unit 54 reports, for example, that reading is not possible and the communication state value (the ratio of “1”) to the higher-level device 33 (step S31). S103). On the other hand, when the calculated ratio of “1” is smaller than the threshold value, the control unit 54 proceeds to the identification processing of the expanded individual data (step S104). Here, the information of the individual data obtained by the identification process is reported to the host device 33. As described above, even when the information of the individual data is reported to the higher-level device 33, the communication state value (the ratio of “1”) may be reported to the higher-level device 33.

  For example, when there are many wireless tags 31 within the readable range of the wireless tag reader 32, a large number of response signals to the question signal overlap, and the ratio of “1” in the digital value series from the receiving unit 53 is Get higher. When there are many wireless tags 31 present in such a readable range, the individual data from each wireless tag 31 cannot be correctly specified, and therefore it can be said that the communication state is poor.

  Further, for example, if the readable range of the wireless tag reader 32 is an environment where there is a lot of noise, the ratio of “1” in the digital value series from the receiving unit 53 increases due to the noise, and each wireless tag 31 individually It also happens that the data cannot be carved correctly. Naturally, in a noisy environment, the communication state is poor.

  In the case where the ratio of “1” is high, there is little meaning to discriminate whether the cause is that there are too many wireless tags 31 within the readable range of the wireless tag reader 32 or there is a lot of noise. Since it can be said that the communication state is bad, in this embodiment, if the calculated ratio of “1” is equal to or greater than the threshold value, reading is impossible and identification of individual data for each wireless tag 31 is not executed. .

  In the following, a method for determining a threshold for determining whether the communication state is good or bad will be described. The threshold value is determined by simulation.

Table 3 shows the results of the simulation. Table 3 shows individual data consisting of 4 bits × 32 words whose M-series order n is 7, and (111, 217, 235, 277, 357, 247) is generated using the combination, and the simulation result in the case where the bit width of each 4 bits of the individual data is expanded to 16 bits and the expanded 512 bits of individual data is stored in the wireless tag 31 is shown. Yes. Table 3 shows the simulation results when there is no background noise.

  The “added number” in Table 3 means that individual data after extending the bit width of the wireless tag is superimposed. For example, the total number (number of types) of codes (individual data after bit width extension) placed on a wireless tag is determined by the generation method, but the number of combinations corresponding to the added number is very large. The combination of individual data after the bit width expansion for the added number obtained by using random numbers or the like is targeted only for a predetermined set (10 million sets) (all combinations may be targeted), and each combination For each of the combinations, the individual data after the bit width extension corresponding to the number of additions in the combination is superimposed to obtain a 512-bit superimposed digital value series. A value obtained by averaging the ratios of “1” in the digital value series after superimposition in each combination is “ratio of 1 (%)” in Table 3. “Number of detections” in Table 3 represents the number of occurrences of the same digital value series after superposition.

  The ratio of “1” in the individual data after one bit width extension is 1/16, but the ratio of “1” after the individual data after two bit width extension is superimposed is not necessarily 2/16. It will not be. This is because there may be “1” at the same bit position in the two pieces of individual data after the bit width extension to be superimposed. However, as the “added number” increases, the proportion (average value) of “1” in the digital value series after superposition increases. Even if the combination of individual data after the bit width extension corresponding to the number of additions is different, if the number of additions increases, the digital value series after superimposition may be the same. When the number of additions is large as described above, the ratio (average value) of “1” in the digital value series after superposition is also large.

  For example, when the number of additions in Table 3 is “10”, the average value of the ratio of “1” in the digital value series after superposition is 47.6 (%) (512 × 0.476≈244), and 10 There is no combination in which the digital data series after superimposition is the same among the combinations having the individual data after the bit width expansion as the element (the “detection number” is 0). When the addition number is “15”, the average value of the ratio of “1” in the digital value series after superposition is 62.5 (%) (512 × 0.625 = 320), and after 15 bit width expansions There is one set (two) in which the digital value series after superimposition is the same among the combinations having the individual data as elements (the number of detections is 1).

  Therefore, in order to be able to recognize the individual data after the bit width extension of each wireless tag 31 even if the plurality of wireless tags 31 are within the readable range of the wireless tag reader 32, the threshold value in step S102 is set to 62. It is necessary to make it smaller than 5 (%). Moreover, 62.5 (%) mentioned above is an average value in simulation, and it is necessary to make the threshold value smaller than 62.5 (%) with a margin. Furthermore, since the simulation results in Table 3 were obtained on the assumption that there was no background noise, erroneous bits were also included in an environment with actual background noise, so there was room to have more than 62.5 (%). Must be determined in consideration of background noise. For example, in the simulation result of Table 3, the threshold value is selected to be about 53 (%). In such a case, even if there are 11 wireless tags 31 within the readable range of the wireless tag reader 32, in many cases, individual data can be correctly read from each wireless tag 31, and wireless Even when there are twelve wireless tags 31 within the readable range of the tag reader 32, the individual data may be correctly read from each wireless tag 31.

Table 4 is different from the embodiment described above, but after generating individual data of 5 bits × 26 words in which the order n of the M sequence is 7, each of the 5 bits of the individual data is changed to 32 bits. The simulation result in the case of extending the bit width and storing the expanded 832-bit individual data in the wireless tag 31 is shown. In the case of Table 4, about 52 (%) may be selected as the threshold value.

Table 5 is different from the above-described embodiment, but after generating individual data of 6 bits × 22 words in which the order n of the M sequence is 7, each 6 bits of the individual data is converted to 64 bits. The simulation result in the case where the bit width is expanded and the 1408-bit individual data after expansion is stored in the wireless tag 31 is shown. In the case of Table 5, about 41 (%) may be selected as the threshold value.

(A-2-3) Extended Individual Data Identification Method Next, an extended individual data identification method executed by the control unit 54 will be described. That is, the control unit 54 identifies the expanded individual data assigned to the wireless tag 31 existing in the vicinity as follows. The control unit 54 internally buffers the sampling data given from the receiving unit 53. Here, for example, buffering is performed after “1” arrives.

  First, assuming that the first buffered “1” is the value at the position of bit 0 (see FIG. 2) in the extended individual data, the post-expansion stored in the reference database 56 Of the individual data, the correlation value with the value of the position of bit 0 being “1” is obtained, and the correlation value is greater than or equal to the threshold value and stored in the candidate storage unit 57.

  In addition, when the correlation value for the entire period is obtained, if there are many wireless tags 31 around the wireless tag reader 32, the correlation value with the individual data of the corresponding wireless tag 31 becomes small. . In view of this, the correlation value may be obtained by limiting (masking) only the period in which the individual data stored in the reference database 56 is “1” with the individual data on the reference side. .

  Next, assuming that the first buffered “1” is the value at the position of bit 1 (see FIG. 2) in the extended individual data, the post-expansion stored in the reference database 56 Of the individual data, a correlation value with the value of the position of bit 1 being “1” is obtained, and those having a correlation value equal to or greater than a threshold value are stored in the candidate storage unit 57.

  Thereafter, similarly, it is assumed that the buffered leading “1” is the value of the bit x (x = 2 to 9 or A to F) in the expanded individual data, and for reference. Of the individual data after expansion stored in the database 56, the correlation value with the value of the position of the bit x is “1” is obtained, and the correlation value is equal to or greater than the threshold value and stored in the candidate storage unit 57. .

  When the candidate search at bit F is completed, the control unit 54 sends the candidate data stored in the candidate storage unit 57 to the higher-level device 33. It should be noted that the transmission of the question signal and the candidate search may be executed a plurality of times, and the candidates that have been candidates a predetermined number of times (for example, a majority) or more in a plurality of searches may be sent to the host device 33.

  In the above description, the wireless tag reader 32 executes the process of identifying the individual data from the received baseband signal. However, the host device 33 may execute the process of identifying the individual data. .

(A-3) Effects of Embodiment In the above embodiment, H sequences that are preferred pairs with each other using M sequences that are easily generated (for example, H = 6 in the 7th order, H = 6 in the 11th order, H = 4) After adding a delay to each of the M sequences, the signal sequence (individual data before expansion) is obtained by exclusive OR, and then the individual data with the expanded bit width is stored. The wireless tag reader that reads the wireless tag that is being read is assumed to represent the communication state in accordance with the ratio of “1” in the baseband signal obtained by reception. The communication state can be grasped without executing with the tag.

  As a result, it is possible to stop the identification processing of useless individual data, and also output a parameter indicating the communication state together with the identified individual data so that the user can recognize the level of authenticity of the obtained individual data. You can also

  The individual data before bit extension corresponding to the individual data after the bit width extension described above is exclusive after adding a delay to each of the H M series that are mutually preferred pairs using the M series that is easy to generate. Since it is obtained by performing a logical OR, it is a signal sequence with good noise resistance that can carry a large amount of information with little cross-correlation and little interference. As a result, the ratio of “1” in the baseband signal obtained by the wireless tag reader reflects the number of wireless tags present in the vicinity fairly well. In other words, the amount of noise is reflected quite well, which is an index that represents the communication state well.

(B) Other Embodiments In the above embodiment, an index (a ratio of “1”) that indicates a good communication state is used to determine whether or not individual data is to be identified, or the cause when no identification is performed Although information to be reported to the host device is shown as information, other processing may be executed using an index. For example, it may be displayed and notified to the user. Further, an interval until the next reading operation may be set according to the index.

  In the above embodiment, the threshold value for determining whether the communication state is good or not is fixed, but this threshold value may be variable. For example, if the determination that the communication state is bad continues for a predetermined number of times, the threshold value is changed to a value one step larger in order to establish communication, and if the determination that the communication state is good continues for a predetermined number of times, In order to improve communication quality, the threshold value may be changed to a value smaller by one step.

  Furthermore, in the above embodiment, individual data before bit extension is added by exclusive OR after adding delay to each of H M sequences that are preferred pairs using M sequences that are easy to generate. However, it may be generated by other methods. Even in this case, it is only necessary to grasp the relationship between the ratio of “1” and the number of wireless tags related to simultaneous reading and obtain a threshold value for determining whether the communication state is good or bad by simulation.

  In the above embodiment, the case where the ratio of “1” is applied as the index indicating the communication state is shown, but conversely, the ratio of “0” may be applied as the index indicating the communication state. In this case, the smaller the index, the worse the communication state.

  The wireless tag used in the present invention is not particularly limited, but a tag that has a built-in battery and transmits radio waves by itself or a tag that exchanges data using external radio waves can be used. Furthermore, the thing using electromagnetic induction, the thing using a radiated electromagnetic field, etc. can be used. Examples of the electric circuit (antenna circuit) in the wireless tag include a coil shape and a dipole type.

It is a block diagram which shows the structure of the separate data writing apparatus of the radio | wireless tag which the radio | wireless tag communication system which concerns on embodiment assumes. It is explanatory drawing of the bit width expansion method in the bit width expansion part of FIG. It is a block diagram which shows the structure of the signal sequence production | generation part of FIG. It is a block diagram which shows the model of the M series production | generation main body and variable delay device for demonstrating the method to obtain the delayed M series. 1 is a block diagram illustrating a configuration of a wireless tag communication system according to an embodiment. It is a flowchart which shows the determination method of the communication state in embodiment.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 3 ... Signal sequence production | generation part, 4 ... Bit width expansion part, 6 ... Data matching memory | storage part, 10-0-10-r ... M series production | generation part, 11 ... Exclusive OR circuit, 20-0-20-r ... M-sequence generation main body, 21-0 to 21-r ... variable delay device, 30 ... wireless tag communication system, 31 ... wireless tag, 32 ... wireless tag reader, 33 ... high-level device, 41 ... individual data memory, 54 ... wireless tag reader Control unit 55... Communication state storage unit 56... Reference database 57.

Claims (7)

Bit width extension converted to Q (Q is a natural number; Q> P) bits so that the ratio of “1” and “0” is biased after conversion for each P (P is a natural number) bits of the original individual data In a wireless tag reader that reads a wireless tag whose individual data is unique individual data later,
A wireless tag reader, comprising: a communication state detection unit that detects a ratio of “1” or “0” in a signal sequence received by a reading operation as an index representing a communication state.   When the original individual data described above are taken out by two, a plurality of M sequences that become preferred pairs are generated, and after the delay is given to each of the generated M sequences, the exclusive data is exclusive 2. The wireless tag reader according to claim 1, wherein a logical sum operation is performed.   Identification that prohibits identification of individual data after bit width expansion included in the signal sequence received by the read operation when the communication status is poor by comparing the detected index indicating the communication status with a threshold value The wireless tag reader according to claim 1, further comprising a prohibiting unit.   The wireless tag reading device according to any one of claims 1 to 3, further comprising a communication state display unit that displays an index representing the detected communication state.   Communication that outputs the index indicating the detected communication state together with the information indicating that the individual data after the bit width extension included in the signal sequence received by the reading operation is identified or that the identification operation is not executed The wireless tag reader according to claim 1, further comprising a status output adding unit. Bit width extension converted to Q (Q is a natural number; Q> P) bits so that the ratio of “1” and “0” is biased after conversion for each P (P is a natural number) bits of the original individual data A computer mounted on a wireless tag reader that reads a wireless tag whose individual data is unique individual data later,
A wireless tag reading program characterized by causing a function of communication status detection means for detecting a ratio of “1” or “0” in a signal sequence received by a reading operation as an index representing a communication status. Bit width extension converted to Q (Q is a natural number; Q> P) bits so that the ratio of “1” and “0” is biased after conversion for each P (P is a natural number) bits of the original individual data A wireless tag that makes the individual data later unique data,
A wireless tag communication system comprising: the wireless tag reader according to claim 1.

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