KR101133140B1 - Method and apparatus for obtaining backscatter link frequency in tag of rfid - Google Patents

Abstract

PURPOSE: A method and an apparatus for obtaining back-scattering link frequency from an RFID tag are provided to count clock pulses of a reference frequency and to use obtained pulse count value. CONSTITUTION: An apparatus counts clock pulses of a reference frequency at designated response time. The apparatus obtains a pulse count value(S51). The apparatus divides the pulse count value into designated division rate. The apparatus obtains count division rate(S52). The apparatus divides the reference frequency into the count division rate. The apparatus determines BLF(Backscatter Link Frequency)(S53).

Description

Method and apparatus for obtaining backscatter link frequency in RFF tag (RFID) tag

The present invention relates to a method and apparatus for obtaining a backscattered link frequency from an RFID tag, and more particularly, to a signal included in a query command signal from an RFID reader. The present invention relates to a method for obtaining a backscatter link frequency (BLF) in an RFID tag according to a specified response time and a predetermined frequency division rate.

1 is a view for explaining a communication principle of a reader and a tag in a general RFID system (RFID).

Referring to FIG. 1, the signal DP transmitted from the RFID reader 11 to the tag 12 includes an instruction signal and a power signal alternately. The tag 12 operating by the power from the power signal transmits the modulated backscatter signal MB to the reader 11 in response to the command signal from the reader 11.

As is well known, the RFID reader 11 outputs a query command signal to find the tag 12 to be communicated with.

Here, the tag 12 is a backscatter transmitted from the tag 12 to the reader 11 in accordance with the specified response time and the specified frequency division rate included in the query command signal from the reader 11. The frequency of the backscatter (MB) signal, that is, the backscatter link frequency (BLF) is obtained and applied.

FIG. 2 is a waveform diagram illustrating a structure of a preamble 2 of command signals transmitted from the reader 11 of FIG. 1 to the tag 12.

1 and 2, the preamble 2 of the command signals includes a delimiter (DL), a designated bit period (TA), a designated transmission time (RTcal), and a designated response time (TRcal). In FIG. 2, reference numeral PW denotes a unit pulse width.

A delimiter (DL) generated by switching from a high logic state to a low logic state signals the start of command signals. The designated transmission time RTcal is used by the tag 12 to find the transmission frequency of the reader 11. The designated response time TRcal is used by the tag 12 to obtain a backscatter link frequency (BLF).

FIG. 3 is a diagram for describing a sequential configuration of a query command signal 3 transmitted from the reader 11 of FIG. 1 to the tag 12. In Fig. 3, reference numeral 31 denotes the name of each component, and 32 denotes the number of bits of each component.

1 and 3, the query command signal 3 is composed of 4 bits of command data (CM), 1 bit of specified division ratio (DR), 2 bits of modulation type (M), and 1 bit of pilot. Tone information (TRext), 2 bits of tag-selection information (Sel), 2 bits of target value switching type (SS), 1 bit of target value (TG), 4 bits of slot value ( Q) and 5-bit Cyclic Redundancy Check codes.

The 1-bit specified division ratio DR, together with the specified response time TRcal in the preamble 2 of FIG. 2, is used by the tag 12 to obtain the backscatter link frequency (BLF). Used for When the bit value of the designated division ratio DR is binary "0", the designated division ratio DR indicates decimal "8". When the bit value of the specified division ratio DR is the binary "1", the specified division ratio DR indicates the decimal "64/3".

The two-bit modulation type M informs the tag 12 of the modulation type of the reader 11. If the bit value of modulation type (M) is binary "00", then Frequency Modulation; if binary "01", Miller-2 Modulation; if binary "10", Miller-4 Modulation (Miller) -4 Modulation, and binary "11" indicates Miller-8 Modulation, respectively.

One-bit pilot tone information TRext indicates whether pilot tone is used. Indicates that pilot tone is not used when the bit value of pilot tone information TRext is binary "0", and pilot tone is used when binary "1". .

The 2-bit tag-selection information Sel indicates information related to the reader 11 selecting the communication target tags. If the bit value of the tag-selection information (Sel) is binary "00" or "01", all tags are communication targets, and if binary "10", non-selection tags are communication targets, and binary "11". In this case, select tags are communication targets.

The 2-bit target value transition type (SS) indicates the type of conditions for switching the target value of the tag 12. If the bit value of the target value TG is binary "0", the target value TG is "A", and if the binary value "1", the target value TG is "B".

A 4-bit slot value (Q) indicates a value for allocating its own transmission slot time in a tag. The allocation slot time is inversely proportional to 2 ^Q.

4 is a view for explaining the range of the backscattered link frequency defined by C-type of ISO / IEC (International Standardization Organization / International Electrotechnical Commission) 18000-6.

In FIG. 4, reference numeral 41 denotes each item, 42 denotes prescribed values when the designated dividing ratio (DR of FIG. 3) is 64/3, and 43 is 8 when the designated dividing ratio (DR of FIG. 3) is 8. Indicates the prescribed values of.

In FIG. 4, reference numeral TRcal denotes the designated response time (TRcal of FIG. 2), BLF denotes a backscatter link frequency, FT denotes a frequency tolerance range, and FVB denotes an operation tolerance range.

3 and 4, the backscatter link frequency BLF is obtained by Equation 1 below.

In the above RFID system, since Equation 1 is directly calculated in the conventional tag, there are the following problems.

First, it is necessary to precisely measure the specified response time (TRcal).

Second, since a fraction of the specified response time TRcal is used as the divisor of the division operation, numerous logic gates are required to construct a multiplier and a divider. As a result, the integrated circuit area of the tag is increased and power consumption is increased, thereby shortening the recognition distance of the tag.

According to an embodiment of the present invention, in a method and apparatus for obtaining a backscattered link frequency in an RFID tag, it is not necessary to precisely measure a specified response time (TRcal) and to minimize logic gates required for an operation. It is intended to provide a method and apparatus.

According to an aspect of the present invention, a backscatter (BLF) backscatter in an RFID tag according to a specified response time and a predetermined frequency division rate included in a query command signal from an RFID reader. In the method for obtaining the link frequency, steps (a) to (c) may be included.

In step (a), clock pulses of a reference frequency are counted at the specified response time, and the resulting pulse count value is obtained.

In step (b), the pulse count value is divided by the specified division ratio, and the resulting count division ratio is obtained.

In step (c), the reference frequency is divided by the count division rate and the resulting value is determined as the backscattered link frequency (BLF).

Further, in the step (b), the designated division ratio is 8 or 64/3 in decimal number according to the provision of C-type of ISO / IEC (International Standardization Organization / International Electrotechnical Commission) 18000-6. When the division ratio is 64/3 decimal, the pulse count value may be multiplied by 3/64, and the resultant value may be the count division ratio.

According to another aspect of the invention, a backscatter link frequency (BLF: Backscatter) in an RFID tag according to a specified response time and a predetermined division rate included in a query command signal from an RFID reader. In the apparatus for obtaining the link frequency, a counter, a count-division ratio acquisition unit, and a frequency division unit may be included.

The counter counts clock pulses of a reference frequency at the specified response time to obtain a resultant pulse count value.

The count-division ratio obtaining unit divides the pulse count value by the predetermined division ratio and obtains a count division ratio that is a result value.

The frequency division unit divides the reference frequency by the count division ratio and determines a result value as the backscattered link frequency BLF.

In addition, according to the provision of C-type of ISO / IEC (International Standardization Organization / International Electrotechnical Commission) 18000-6, the designated division rate is 8 or 64/3 decimal, and the designated division rate is 64/3 decimal. In the case, the count-division ratio acquisition unit may multiply the pulse count value by 3/64 so that the result is the count division ratio.

The count-dividing ratio obtaining unit may include a first count-dividing ratio calculating unit, a second count-dividing ratio calculating unit, and a result selecting unit.

The first count-division ratio calculator divides the pulse count value from the counter by a decimal number 8 to obtain a first count division ratio that is a result value.

The second count-division ratio calculating unit multiplies the pulse count value from the counter by a decimal number 3/64 to obtain a second count division ratio as a result.

The result selector may include the first count division ratio and the first division ratio according to a predetermined division ratio DR included in a preamble signal of a query command signal from an RFID reader. Select one of two count division ratios and output it.

The first count-division ratio calculator may include a 3-bit remover and an adder.

The 3-bit remover removes the lower 3 bits of binary digits 0 to 2 from the pulse count value of 10 bits of binary digits 0 to 9.

The adder adds the bit value of the binary digit 2 to the value of 7 bits from the 3-bit remover to obtain the resultant first count division ratio.

The second count-division ratio calculator may include a 1-bit adder, a first adder, a 6-bit remover, and a second adder.

The 1-bit adding unit adds one bit of binary 0 as LSB (Last Significant Bit) to the 10-bit pulse count value having binary digits from 0 to 9, and has binary digits from 0 to 10. Get the value of 11 bits.

The first adder adds the 10-bit pulse count value to the 11-bit value from the 1-bit adder to obtain the 11-bit value.

The 6-bit remover removes the lower 6 bits of binary digits from 0 to 5 in an 11-bit value from the first adder.

And the second adder adds the 5-bit value from the 6-bit remover to the binary digit 5 bit value to obtain the second count division ratio as a result.

According to the embodiment of the present invention, since the clock pulses of the reference frequency are counted in the designated response time and the resulting pulse count value is used, it is not necessary to accurately measure the specified response time.

In addition, since the fraction of the specified response time TRcal is not used as the divisor of the division operation and an integer or a fraction is used, the binary multiplication or binary division operation can be replaced with a binary addition operation.

For example, the first count-division ratio calculator may be configured with only the 3-bit remover and the adder. That is, the pulse count value is divided by 8 by the 3-bit remover, and rounding is performed by the adder.

In addition, the second count-division ratio calculating unit may include only a 1-bit adder, a first adder, a 6-bit remover, and a second adder. That is, the output of the 1-bit adder is a result of multiplying the pulse count value by 2, the output of the first adder is a result of multiplying the pulse count value by 3, and by the 6-bit remover The output of the first adder is divided by 64, and rounding is performed by the second adder.

Thus, many logic gates are not needed to construct multipliers and dividers as in the prior art. Accordingly, the integrated circuit area and power consumption of the tag can be reduced, and thus the recognition distance of the tag can be long.

1 is a view for explaining a communication principle of a reader and a tag in a general RFID system (RFID).
FIG. 2 is a waveform diagram illustrating a preamble structure of command signals transmitted from a reader of FIG. 1 to a tag.
FIG. 3 is a diagram illustrating a sequential configuration of a query command signal transmitted from a reader of FIG. 1 to a tag.
4 is a view for explaining the range of the backscattered link frequency defined by C-type of ISO / IEC (International Standardization Organization / International Electrotechnical Commission) 18000-6.
5 is a flowchart illustrating a method of obtaining a backscattered link frequency according to an embodiment of the present invention.
6 is a flowchart showing the detailed operation of step S52 of FIG.
7 is a block diagram illustrating an apparatus for obtaining a backscattered link frequency of an embodiment of the present invention.
FIG. 8 is a block diagram illustrating a detailed configuration of a first count-division ratio calculator of FIG. 7.
FIG. 9 is a block diagram illustrating a detailed configuration of a second count-division ratio calculator of FIG. 7.

The following description and the annexed drawings are for understanding the operation according to the present invention, and a part that can be easily implemented by those skilled in the art may be omitted.

In addition, the specification and drawings are not provided to limit the invention, the scope of the invention should be defined by the claims. Terms used in the present specification should be interpreted as meanings and concepts corresponding to the technical spirit of the present invention so as to best express the present invention.

Embodiments of the present invention will now be described with reference to the accompanying drawings.

Figure 5 shows a method for obtaining the backscattered link frequency of one embodiment of the present invention. Referring to Figures 2 to 5, the method of obtaining the backscattered link frequency (BLF of Figure 4) of an embodiment of the present invention will be described.

First, in step S51, clock pulses of the reference frequency Fref are counted at the designated response time (TRcal in FIG. 2), and the resulting pulse count value Ntr is obtained.

In step S52, the pulse count value Ntr is divided by the designated dividing ratio (DR in Fig. 3), and the resulting count dividing ratio DN is obtained. This step S52 can be expressed as Equation 2 below.

In step S53, the reference frequency Fref is divided by the count division ratio DN, and the resulting value is determined as the backscattered link frequency BLF. This step S53 may be expressed as Equation 3 below.

Therefore, since the clock pulses of the reference frequency Fref are counted at the designated response time (TRcal in FIG. 2) and the resultant pulse count value Ntr is used, it is necessary to accurately measure the specified response time TRcal. none.

In addition, since the fraction of the specified response time TRcal is not used as the divisor of the division operation and an integer or a fraction is used, the binary multiplication or binary division operation can be replaced with a binary addition operation.

Thus, many logic gates are not needed to construct multipliers and dividers as in the prior art. Accordingly, the integrated circuit area and power consumption of the tag (12 of FIG. 1) may be reduced, and thus the recognition distance of the tag 12 may be longer.

6 shows the detailed operation of step S52 of FIG.

4 to 6, the designated fractional ratio (DR) is 8 or 64/3 in accordance with the definition of C-type of the International Standardization Organization / International Electrotechnical Commission (ISO / IEC) 18000-6.

Therefore, when the bit value of the specified division ratio DR is binary 0, the specified division ratio DR is 8 decimal (see Fig. 3 and description), so that 8 is divided by the pulse count value Ntr and the resulting value is obtained. Count division ratio DN (steps S61 and S62). That is, Equation 4 below is applied.

In addition, when the bit value of the specified division ratio DR is binary 1, since the specified division ratio DR is 64/3 decimal (see Fig. 3 and description), the pulse count value Ntr is multiplied by 3/64. The result is a count division ratio DN (steps S61 and S63). That is, Equation 5 below is applied.

7 shows an apparatus for obtaining the backscattered link frequency (BLF) of an embodiment of the present invention. In FIG. 7, reference numeral Sreset denotes a reset signal of the counter 71, Bdr denotes a bit value of the designated frequency division rate DR, and Strcal denotes a signal of the designated response time (TRcal of FIG. 2), respectively.

5 to 7, an apparatus for obtaining a backscattered link frequency (BLF) according to an embodiment of the present invention includes a counter 71, a count-division ratio obtaining unit 72 to 74, and a frequency dividing unit 75. Can be.

The counter 71 counts clock pulses CPfref of the reference frequency Fref at a predetermined response time (TRcal of FIG. 2) to obtain a pulse count value Ntr as a result.

The count-division ratio obtaining sections 72 to 74 divide the pulse count value Ntr by the designated division ratio (DR in Fig. 3) to obtain a count division ratio DN as a result (see Equations 2, 4, and 5). ).

The frequency division unit 75 divides the reference frequency Fref by the count division ratio DN, and determines the resulting value as the inverse scattering link frequency BLF.

In the count-dividing ratio obtaining sections 72 to 74, the designated dividing ratio DR is 8 or 64/3 in accordance with the provision of the C-type of ISO / IEC 18000-6. As described above, when the specified division ratio DR is the decimal number 8 when the bit value Bdr of the specified division ratio DR is binary 0, 8 is divided by the pulse count value Ntr and the resulting value is counted. The division ratio DN is obtained (see Equation 4 above). In addition, when the bit value Bdr of the specified division ratio DR is binary 1, the specified division ratio DR is 64/3 decimal, so the pulse count value Ntr is multiplied by 3/64. Count division ratio DN (see Equation 5).

Accordingly, the count-division ratio acquisition units 72 to 74 include a first count-division ratio calculation unit 72, a second count-division ratio calculation unit 73, and a result selector 74.

The first count-division ratio calculating unit 72 divides the pulse count value Ntr from the counter 71 by 8 decimals to obtain a first count division ratio DN0 as a result value.

The second count-division ratio calculator 73 multiplies the pulse count value Ntr from the counter 71 by the decimal number 3/64 to obtain a second count division ratio DN1 as a result.

The result selector 74 then uses the first count division ratio DN0 in accordance with the designated division ratio DR included in the preamble signal of the query instruction signal from the RFID reader. ) And the second count division ratio DN1 are selected and output.

FIG. 8 shows a detailed configuration of the first count-division ratio calculating unit 72 of FIG. 7. As described above, the first count-division ratio calculating unit 72 divides the pulse count value Ntr from the counter 71 by the decimal number 8 to obtain a first count division ratio DN0 as a result.

7 and 8, the first count-division ratio calculating unit 72 includes a 3-bit elimination unit 81 and an adding unit 82.

The 3-bit remover 81 removes the lower 3 bits having binary digits 0 to 2 from the pulse count value Ntr (9: 0) of 10 bits having binary digits 0 to 9. Hereinafter, a: b means that the number of digits of the Most Significant Bit (MSB) is a and the number of digits of the Least Significant Bit (LSB) is b.

The adder 82 adds the bit value of the binary digit 2 to the 7-bit value Ntr (9: 3) from the 3-bit remover 81 and results in the first count division ratio DN0 (6: 0). Obtain

Therefore, the pulse count value Ntr is divided into eight by the three-bit removing unit 81, and rounding is performed by the adding unit 82. FIG.

FIG. 9 shows a detailed configuration of the second count-division ratio calculator 73 of FIG. 7. As described above, the second count-division ratio calculation unit 73 multiplies the pulse count value Ntr from the counter 71 by the decimal number 3/64 to obtain a second count division ratio DN1 as a result value. .

7 and 9, the second count-division ratio calculator 73 includes a 1-bit adder 91, a first adder 92, a 6-bit remover 93, and a second adder. (94).

The 1-bit adding unit 91 adds one bit of binary 0 as LSB (Last Significant Bit) to the pulse count value Ntr (9: 0) of 10 bits having binary digits from 0 to 9, Obtain the 11-bit value Ntr (10: 0) with binary digits from 0 to 10.

The first adder 94 adds the pulse count value of the 10-bit Ntr (9: 0) to the 11-bit value Ntr (10: 0) from the 1-bit adder 91, which is the resultant value. Obtain the 11-bit value Ntr (10: 0).

The six-bit remover 93 removes the lower six bits of binary digits from 0 to 5 in the 11-bit value Ntr (10: 0) from the first adder 92.

The second adder 94 adds the 5-bit value Ntr (10: 6) from the 6-bit remover 93 to the bit value of the binary digit 5, resulting in a 6-bit second count division ratio. Find DN1 (5: 0).

Therefore, the output of the 1-bit addition unit 91 is the result of multiplying the pulse count value Ntr (9: 0) by 2, and the output of the first adding unit 92 is equal to the pulse count value Ntr (9: 0). 3 is the result of multiplication, the output of the first adder 92 is divided by 64 by the 6-bit remover 93, and rounding is performed by the second adder 94.

As described above, according to the embodiment of the present invention, since the clock pulses of the reference frequency are counted at the designated response time and the resulting pulse count value is used, there is no need to precisely measure the specified response time.

In addition, since the fraction of the specified response time TRcal is not used as the divisor of the division operation and an integer or a fraction is used, the binary multiplication or binary division operation can be replaced with a binary addition operation.

For example, the first count-division ratio calculator may be configured with only the 3-bit remover and the adder. That is, the pulse count value is divided by 8 by the 3-bit remover, and rounding is performed by the adder.

In addition, the second count-division ratio calculating unit may include only a 1-bit adder, a first adder, a 6-bit remover, and a second adder. That is, the output of the 1-bit adder is a result of multiplying the pulse count value by 2, the output of the first adder is a result of multiplying the pulse count value by 3, and by the 6-bit remover The output of the 1-bit adder is divided by 64, and rounding is performed by the second adder.

Thus, many logic gates are not needed to construct multipliers and dividers as in the prior art. Accordingly, the integrated circuit area and power consumption of the tag can be reduced, and thus the recognition distance of the tag can be long.

The present invention has been described above with reference to preferred embodiments. Those skilled in the art will understand that the present invention can be embodied in a modified form without departing from the essential characteristics of the present invention. Therefore, the above-described embodiments should be considered in an illustrative rather than a restrictive sense. The scope of the present invention is defined by the appended claims rather than by the foregoing description, and the inventions claimed by the claims and the inventions equivalent to the claimed invention are to be construed as being included in the present invention.

It can be used when the data of measurement time becomes a multiplier of multiplication or a divisor of division.

11 ... RFID reader, 12 ... RFID tag,
2 ... preamble signal, DL ... delimiter,
TA ... specified bit period (Tari), PW ... unit pulse width,
RTcal ... specified send time, TRcal ... specified response time,
3 ... query command signal, CM ... command data,
DR ... specified frequency division, M ... modulation type,
TRext ... pilot tone information, Sel ... tag-selection information,
SS ... target value conversion type, TG ... target value,
Q ... slot value, BLF ... backscatter link frequency,
FT ... frequency tolerance-error range, FVB ... operation tolerance-error range,
41 ... surrender, 42 ...
43 ... 2 Scope of Regulation, 71 ... Counter,
72 ... first count-divider calculation unit, 73 ... second count-divider calculation unit,
74 ... result selector, 75 ... frequency divider,
81 ... 3-bit remover, 82 ... adder,
91 ... 1-bit addition, 92 ... first addition,
93 ... 6-bit remover, 94 ... second adder.

Claims (7)

In a method for obtaining a backscatter link frequency (BLF) in an RFID tag according to a specified response time and a frequency division rate included in a query command signal from an RFID reader. ,
(a) counting clock pulses of a reference frequency at the specified response time to obtain a resultant pulse count value;
(b) dividing the pulse count value by the predetermined division rate to obtain a count division rate as a result; And
and (c) dividing the reference frequency by the count division rate and determining the resulting value as the backscattered link frequency (BLF). The method of claim 1, wherein in step (b),
In accordance with the provisions of C-type of ISO / IEC (International Standardization Organization / International Electrotechnical Commission) 18000-6, the specified division rate is 8 or 64/3 decimal,
Obtaining a backscattered link frequency (BLF) where the pulse count value is multiplied by 3/64 when the specified frequency division rate is 64/3 decimal, and the result is the count frequency division rate. In a device for obtaining a backscatter link frequency (BLF) in an RFID tag according to a specified response time and a frequency division rate included in a query command signal from an RFID reader. ,
A counter for counting clock pulses of a reference frequency at the specified response time to obtain a pulse count value as a result;
A count-division ratio obtaining unit for dividing the pulse count value by the predetermined division ratio and obtaining a count division ratio as a result value; And
And obtaining a backscattered link frequency (BLF) including a frequency divider which divides the reference frequency by the count division rate and determines a result value as the backscattered link frequency (BLF). The method of claim 3,
In accordance with the provisions of C-type of ISO / IEC (International Standardization Organization / International Electrotechnical Commission) 18000-6, the specified division rate is 8 or 64/3 decimal,
When the specified division ratio is 64/3 decimal, the count-division ratio obtaining unit multiplies the pulse count value by 3/64 to obtain a backscattered link frequency (BLF) whose value is the count division ratio. Obtain device. The method of claim 4, wherein the count-division ratio obtaining unit,
A first count-division ratio calculator for dividing the pulse count value from the counter by a decimal number 8 to obtain a first count division ratio as a result value;
A second count-division ratio calculator for multiplying the pulse count value from the counter by 3/64 as a decimal number to obtain a second count division ratio as a result value; And
Any one of the first count frequency division rate and the second count frequency division rate according to a predetermined division rate DR included in a preamble signal of a query command signal from the RFID reader. A device for obtaining a backscattered link frequency (BLF) including a result selector for selecting and outputting a signal. The method of claim 5, wherein the first count-division ratio calculating unit,
A 3-bit removing unit for removing the lower 3 bits having binary digits from 0 to 2 in the pulse count value of 10 bits having binary digits from 0 to 9; And
And an adder which adds the bit value of the binary digit 2 to the value of 7 bits from the 3-bit remover and obtains the resultant first count frequency division ratio. The method of claim 5, wherein the second count-division ratio calculating unit,
One bit of binary zero is added as LSB (LSB: Least Significant Bit) to the pulse count value of 10 bits with binary digits from 0 to 9 to obtain a value of 11 bits with binary digits from 0 to 10. A bit addition unit;
A first adder which adds the pulse count value of the 10 bits to the value of the 11 bits from the 1-bit adder and obtains a result of the 11-bit value;
A six-bit remover for removing the lower six bits having binary digits from 0 to 5 in the 11-bit value from the first adder; And
Obtaining a backscattered link frequency (BLF) including a second adder which adds the bit value of the binary digit 5 to the value of 5 bits from the 6-bit remover and obtains the resulting second count division ratio.

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