Radio-Frequency Surface-Acoustic-Wave Identification Tag and System

US 20100225449A1
Filed: 03/06/2010
Published: 09/09/2010
Est. Priority Date: 03/06/2009
Status: Abandoned Application

First Claim

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1. A device for radio sensing comprising:

an input-output port for receiving an input radio-frequency signal and for delivering an output radio-frequency signal derived from the input radio-frequency signal;

a plurality of M possible reflector positions, wherein M is a positive integer greater than two and wherein each individual possible reflector position is identified by an integer, h, in the range [1, . . . , M]; and

a plurality of N actual reflectors placed at a subset of the M possible reflector positions, wherein N is a positive integer greater than one and less than M and no two actual reflectors are at the same position, such that each actual reflector is identified by an integer, n, in the range [1, . . . , N] and by a position, h(n), wherein h(n) is a monotonically increasing function of n;

wherein the M possible reflector positions are arranged, relative to the input-output port, to achieve the following;

(i) each actual reflector reflects a portion of the input radio-frequency signal,(ii) each reflected portion of the input radio-frequency signal comprises a reflected signal that is an reduced-amplitude replica of the input signal, for a total of N reflected signals from the N actual reflectors,(iii) the N reflected signals arrive at the output port where they are linearly combined to generate the output radio-frequency signal,(iv) each of the N reflected signals arrives at the input-output port with a group delay and with a phase delay, wherein the group delay and the phase delay depend on the frequency of the input radio-frequency signal, and(v) for input radio-frequency signals within a pre-determined frequency band, each actual reflector n at possible reflector position h(n) generates a reflected signal with a group delay, D(h(n)), such that D(h) is a monotonically increasing function of h; and

wherein the N positions of the N actual reflectors, h(1) through h(N), satisfy the following constraints;

(a) each of the N−

1 separations between adjacent reflected signals, defined as h(m+1)−

h(m) and denoted as Δ

(m), is the sum of a base value, Δ

0(m), and an integer multiple of a position step, Δ

step, common to all separations, such that each separation can be expressed as Δ

(m)=Δ

0(m)+Δ

inc(m)—

Δ

step, wherein m is an integer in the range [1, . . . , N−

1],(b) Δ

0(m) is a positive integer that defines the minimum allowed value of separation Δ

(m),(c) Δ

step is a positive integer greater than one that defines the increment by which separation Δ

(m) can be increased, and(d) Δ

inc(m) is a non-negative integer.

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Abstract

A method of fabricating batches of linear RFID devices is disclosed. For example, the illustrative embodiments of the present invention provide a method for producing a batch of linear RFID devices that are advantageous in that they are less likely to be confused with each other than batches of similar devices in the prior art. Because the purpose of RFID devices is to identify something properly and accurately, anything that reduces the likelihood of misidentification is beneficial.

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38 Claims

1. A device for radio sensing comprising:
- an input-output port for receiving an input radio-frequency signal and for delivering an output radio-frequency signal derived from the input radio-frequency signal;
  
  a plurality of M possible reflector positions, wherein M is a positive integer greater than two and wherein each individual possible reflector position is identified by an integer, h, in the range [1, . . . , M]; and
  
  a plurality of N actual reflectors placed at a subset of the M possible reflector positions, wherein N is a positive integer greater than one and less than M and no two actual reflectors are at the same position, such that each actual reflector is identified by an integer, n, in the range [1, . . . , N] and by a position, h(n), wherein h(n) is a monotonically increasing function of n;
  
  wherein the M possible reflector positions are arranged, relative to the input-output port, to achieve the following;
  
  (i) each actual reflector reflects a portion of the input radio-frequency signal,(ii) each reflected portion of the input radio-frequency signal comprises a reflected signal that is an reduced-amplitude replica of the input signal, for a total of N reflected signals from the N actual reflectors,(iii) the N reflected signals arrive at the output port where they are linearly combined to generate the output radio-frequency signal,(iv) each of the N reflected signals arrives at the input-output port with a group delay and with a phase delay, wherein the group delay and the phase delay depend on the frequency of the input radio-frequency signal, and(v) for input radio-frequency signals within a pre-determined frequency band, each actual reflector n at possible reflector position h(n) generates a reflected signal with a group delay, D(h(n)), such that D(h) is a monotonically increasing function of h; and
  
  wherein the N positions of the N actual reflectors, h(1) through h(N), satisfy the following constraints;
  
  (a) each of the N−
  
  1 separations between adjacent reflected signals, defined as h(m+1)−
  
  h(m) and denoted as Δ
  
  (m), is the sum of a base value, Δ
  
  0(m), and an integer multiple of a position step, Δ
  
  step, common to all separations, such that each separation can be expressed as Δ
  
  (m)=Δ
  
  0(m)+Δ
  
  inc(m)—
  
  Δ
  
  step, wherein m is an integer in the range [1, . . . , N−
  
  1],(b) Δ
  
  0(m) is a positive integer that defines the minimum allowed value of separation Δ
  
  (m),(c) Δ
  
  step is a positive integer greater than one that defines the increment by which separation Δ
  
  (m) can be increased, and(d) Δ
  
  inc(m) is a non-negative integer.
- View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13)
- - 2. The device of claim 1:
    - wherein the group delay generated by actual reflector n can be expressed as D(n)=D0+h(n)·
      
      Dstep+n·
      
      Dcorr, wherein D0 and Dstep are positive values, and Dcorr is such that |Dcorr|<
      
      Dstep; and
      
      wherein the phase delay generated by actual reflector n can be expressed as T(n)=T0+h(n)·
      
      Tstep+n·
      
      Tcorr, wherein T0 and Tstep are positive values, and Tcorr is such that |Tcorr|<
      
      Tstep.
  - 3. The device of claim 1 further comprising a piezoelectric substrate;
    - wherein the input-output port comprises a transducer on the piezoelectric substrate;
      
      wherein the transducer(i) converts the input radio-frequency signal from an electrical signal to a surface acoustic wave (SAW) signal that travels on the surface of the piezoelectric substrate,(ii) converts the output radio-frequency signal from a SAW signal that travels on the surface of the piezoelectric substrate to an electrical signal; and
      
      wherein the M possible reflector positions are arranged in a linear sequence on the surface of the piezoelectric substrate.
  - 4. The device of claim 3:
    - wherein the M possible reflector positions are evenly spaced; and
      
      wherein for input radio-frequency signals within the pre-determined frequency band, two actual reflectors at consecutive possible reflector positions h and h+1 generate reflected signals whose phase delays differ from one another by a predetermined value, Tstep, which is the same for all values of h.
  - 5. The device of claim 4 wherein N has the value 4.
  - 6. The device of claim 5:
    - wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (e) Δ
      
      0(1) is even,(f) Δ
      
      0(2) is odd,(g) Δ
      
      0(3) is even,(h) Δ
      
      step has the value 2,(i) h(1)+h(4)≠
      
      h(2)+h(3);
  - 7. The device of claim 1:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (e) Δ
      
      0(1) is even,(f) Δ
      
      0(2) is odd,(g) Δ
      
      0(3) is even,(h) Δ
      
      step has the value 2,(i) h(1)+h(4)≠
      
      h(2)+h(3);
  - 8. The device of claim 1:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is odd,(b) Δ
      
      0(2) is even,(c) Δ
      
      0(3) is even,(d) Δ
      
      step has the value 2,(e) h(2)+h(4)≠
      
      2·
      
      h(3);
  - 9. The device of claim 1:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is even,(b) Δ
      
      0(2) is even,(c) Δ
      
      0(3) is odd,(d) Δ
      
      step has the value 2,(e) h(1)+h(3)≠
      
      2·
      
      h(2);
  - 10. The device of claim 1:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is odd,(b) Δ
      
      0(2) is odd,(c) Δ
      
      0(3) is even,(d) Δ
      
      step has the value 2,(e) h(1)+h(3)≠
      
      2·
      
      h(2),(f) h(1)+h(4)≠
      
      2·
      
      h(2),(g) h(1)+h(4)≠
      
      2·
      
      h(3);
  - 11. The device of claim 1:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is even,(b) Δ
      
      0(2) is odd,(c) Δ
      
      0(3) is odd,(d) Δ
      
      step has the value 2,(e) h(2)+h(4)≠
      
      2·
      
      h(3),(f) h(1)+h(4)≠
      
      2·
      
      h(2),(g) h(1)+h(4)≠
      
      2·
      
      h(3);
  - 12. The device of claim 1:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is odd,(b) Δ
      
      0(2) is even,(c) Δ
      
      0(3) is odd,(d) Δ
      
      step has the value 2,(e) h(1)+h(4)≠
      
      h(2)+h(3),(f) h(1)+h(4)≠
      
      2·
      
      h(2),(g) h(1)+h(4)≠
      
      2·
      
      h(3);
  - 13. The device of claim 1:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is odd,(b) Δ
      
      0(2) is odd,(c) Δ
      
      0(3) is odd,(d) Δ
      
      step has the value 2,(e) h(1)+h(3)≠
      
      2·
      
      h(2),(f) h(2)+h(4)≠
      
      2·
      
      h(3),(g) h(1)+h(4)≠
      
      h(2)+h(3);

14. A system for radio sensing comprising:
- a plurality of radio sensing devices wherein each device comprises;
  
  (A) an input-output port for receiving an input radio-frequency signal and for delivering an output radio-frequency signal derived from the input radio-frequency signal;
  
  (B) a plurality of N actual reflectors, wherein N is a positive integer greater than one that is the same for all radio sensing devices;
  
  wherein each of the N actual reflectors is positioned, within each device, at one of a plurality of M possible reflector positions, wherein(1) M is a positive integer greater than N that is the same for all radio sensing devices,(2) the plurality of M possible reflector positions is the same for all the radio sensing devices, and(3) each individual possible reflector position is identified by an integer, h, in the range [1, . . . , M];
  
  wherein the N actual reflectors are placed at a subset of the M possible reflector positions, with no two actual reflectors at the same position, such that each actual reflector is identified by an integer, n, in the range [1, . . . , N] and by a position, h(n), wherein h(n) is a monotonically increasing function of n;
  
  wherein the M possible reflector positions are arranged, relative to the input-output port, to achieve the following;
  
  (i) each actual reflector reflects a portion of the input radio-frequency signal,(ii) each reflected portion of the input radio-frequency signal comprises a reflected signal that is an reduced-amplitude replica of the input signal, for a total of N reflected signals from the N actual reflectors,(iii) the N reflected signals arrive at the output port where they are linearly combined to generate the output radio-frequency signal,(iv) each of the N reflected signals arrives at the input-output port with a group delay and with a phase delay, wherein the group delay and the phase delay depend on the frequency of the input radio-frequency signal, and(v) for input radio-frequency signals within a pre-determined frequency band, each actual reflector n at possible reflector position h(n) generates a reflected signal with a group delay, D(h(n)), such that D(h) is a monotonically increasing function of h; and
  
  wherein the N positions of the N actual reflectors, h(1) through h(N), satisfy the following constraints;
  
  (a) each of the N−
  
  1 separations between adjacent reflected signals, defined as h(m+1)-h(m) and denoted as Δ
  
  (m), is the sum of a base value, Δ
  
  0(m), and an integer multiple of a position step, Δ
  
  step, common to all separations, such that each separation can be expressed as Δ
  
  (m)=Δ
  
  0(m)+Δ
  
  inc(m)·
  
  Δ
  
  step, wherein m is an integer in the range [1, . . . , N−
  
  1],(b) Δ
  
  0(m) is a positive integer that defines the minimum allowed value of separation Δ
  
  (m),(c) Δ
  
  step is a positive integer greater than one that defines the increment by which separation Δ
  
  (m) can be increased,(d) Δ
  
  inc(m) is a non-negative integer(e) the values of Δ
  
  0(m), for all values of m in the range [1, . . . , N−
  
  1], and the value ofΔ
  
  step are the same for all radio sensing devices, and(f) no two radio sensing devices in the plurality of radio sensing devices have the same set of values for h(1) through h(N).
- View Dependent Claims (15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28)
- - 15. The device of claim 14:
    - wherein the group delay generated by actual reflector n can be expressed as D(n)=D0+h(n)·
      
      Dstep+n·
      
      Dcorr, wherein D0 and Dstep are positive values, and Dcorr is such that |Dcorr|<
      
      Dstep; and
      
      wherein the phase delay generated by actual reflector n can be expressed as T(n)=T0+h(n)·
      
      Tstep+n·
      
      Tcorr, wherein T0 and Tstep are positive values, and Tcorr is such that |Tcorr|<
      
      Tstep.
  - 16. The system of claim 14wherein each of the plurality of radio sensing devices further comprises a piezoelectric substrate;
    - wherein the input-output port comprises a transducer on the piezoelectric substrate;
      
      wherein the transducer(i) converts the input radio-frequency signal from an electrical signal to a surface acoustic wave (SAW) signal that travels on the surface of the piezoelectric substrate,(ii) converts the output radio-frequency signal from a SAW signal that travels on the surface of the piezoelectric substrate to an electrical signal; and
      
      wherein the M possible reflector positions are arranged in a linear sequence on the surface of the piezoelectric substrate.
  - 17. The system of claim 16:
    - wherein the M possible reflector positions are evenly spaced; and
      
      wherein for input radio-frequency signals within the pre-determined frequency band, two actual reflectors at consecutive possible reflector positions h and h+1 generate reflected signals whose phase delays differ from one another by a predetermined value, Tstep, which is the same for all values of h and for all radio sensing devices.
  - 18. The system of claim 17 wherein N has the value 4.
  - 19. The system of claim 18:
    - wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (e) Δ
      
      0(1) is even,(f) Δ
      
      0(2) is odd,(g) Δ
      
      0(3) is even,(h) Δ
      
      step has the value 2,(i) h(1)+h(4)≠
      
      h(2)+h(3).
  - 20. The system of claim 19 wherein the number of radio sensing devices comprising an actual reflector at position h does not exceed a fraction of the total number of radio sensing devices in the system equal to (N/M)·
    - (1+p), wherein p is a pre-determined value.
  - 21. The system of claim 14:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (e) Δ
      
      0(1) is even,(f) Δ
      
      0(2) is odd,(g) Δ
      
      0(3) is even,(h) Δ
      
      step has the value 2,(i) h(1)+h(4)≠
      
      h(2)+h(3).
  - 22. The device of claim 14:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is odd,(b) Δ
      
      0(2) is even,(c) Δ
      
      0(3) is even,(d) Δ
      
      step has the value 2,(e) h(2)+h(4)≠
      
      2·
      
      h(3);
  - 23. The device of claim 14:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is even,(b) Δ
      
      0(2) is even,(c) Δ
      
      0(3) is odd,(d) Δ
      
      step has the value 2,(e) h(1)+h(3)≠
      
      2·
      
      h(2);
  - 24. The device of claim 14:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is odd,(b) Δ
      
      0(2) is odd,(c) Δ
      
      0(3) is even,(d) Δ
      
      step has the value 2,(e) h(1)+h(3)≠
      
      2·
      
      h(2),(f) h(1)+h(4)≠
      
      2·
      
      h(2),(g) h(1)+h(4)≠
      
      2·
      
      h(3);
  - 25. The device of claim 14:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is even,(b) Δ
      
      0(2) is odd,(c) Δ
      
      0(3) is odd,(d) Δ
      
      step has the value 2,(e) h(2)+h(4)≠
      
      2·
      
      h(3),(f) h(1)+h(4)≠
      
      2·
      
      h(2),(g) h(1)+h(4)≠
      
      2·
      
      h(3);
  - 26. The device of claim 14:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is odd,(b) Δ
      
      0(2) is even,(c) Δ
      
      0(3) is odd,(d) Δ
      
      step has the value 2,(e) h(1)+h(4)≠
      
      h(2)+h(3),(f) h(1)+h(4)≠
      
      2·
      
      h(2),(g) h(1)+h(4)≠
      
      2·
      
      h(3);
  - 27. The device of claim 14:
    - wherein N has the value 4; and
      
      wherein the 4 positions of the 4 actual reflectors, h(1) through h(4), also satisfy the following additional constraints;
      
      (a) Δ
      
      0(1) is odd,(b) Δ
      
      0(2) is odd,(c) Δ
      
      0(3) is odd,(d) Δ
      
      step has the value 2,(e) h(1)+h(3)≠
      
      2·
      
      h(2),(f) h(2)+h(4)≠
      
      2·
      
      h(3),(g) h(1)+h(4)≠
      
      h(2)+h(3);
  - 28. The system of claim 14 wherein the number of radio sensing devices comprising an actual reflector at position h does not exceed a fraction of the total number of radio sensing devices in the system equal to (N/M)·
    - (1+p), wherein p is a pre-determined value.

29. A method comprising:
- fabricating L radio-frequency (RFID) devices, wherein L is a positive integer greater than one;
  
  wherein each of the L radio-frequency devices comprises N actual reflectors in M possible reflector positions;
  
  wherein at least C of the positions of the N actual reflectors in each of the L radio-frequency (RFID) devices are different from the positions of the N actual reflectors in each of the other L−
  
  1 radio-frequency (RFID) devices, wherein C is a positive integer greater than one;
  
  wherein each device comprises;
  
  (A) an input-output port for receiving an input radio-frequency signal and for delivering an output radio-frequency signal derived from the input radio-frequency signal;
  
  (B) a plurality of N actual reflectors, wherein N is a positive integer greater than one that is the same for all RFID devices;
  
  wherein each of the N actual reflectors is positioned, within each device, at one of a plurality of M possible reflector positions, wherein(1) M is a positive integer greater than N that is the same for all RFID devices,(2) the plurality of M possible reflector positions is the same for all the RFID devices, and(3) each individual possible reflector position is identified by an integer, h, in the range [1, . . . , M];
  
  wherein the N actual reflectors are placed at a subset of the M possible reflector positions, with no two actual reflectors at the same position, such that each actual reflector is identified by an integer, n, in the range [1, . . . , N] and by a position, h(n);
  
  wherein the M possible reflector positions are arranged, relative to the input-output port, to achieve the following;
  
  (i) each actual reflector reflects a portion of the input radio-frequency signal,(ii) each reflected portion of the input radio-frequency signal comprises a reflected signal that is an attenuated replica of the input signal, for a total of N reflected signals from the N actual reflectors,(iii) the N reflected signals arrive at the output port where they are linearly combined to generate the output radio-frequency signal,(iv) each of the N reflected signals arrives at the input-output port with a group delay and with a phase delay, wherein the group delay and the phase delay depend on the frequency of the input radio-frequency signal, and(v) for input radio-frequency signals within a pre-determined frequency band, actual reflector n at possible reflector position h(n) generates a reflected signal whose group delay, D(h(n)), is a monotonically increasing function of h(n);
  
  wherein the N positions of the N actual reflectors, h(1) through h(N), satisfy the following constraints;
  
  (a) each of the N−
  
  1 separations between adjacent reflected signals, defined as h(m+1)-h(m) and denoted as Δ
  
  (m), is the sum of a base value, Δ
  
  0(m), and an integer multiple of a position step, Δ
  
  step, common to all separations, such that each separation can be expressed as Δ
  
  (m)=Δ
  
  0(m)+Δ
  
  inc(m)·
  
  Δ
  
  step, wherein m is an integer in the range [1, . . . , N−
  
  1],(b) Δ
  
  0(m) is a positive integer that defines the minimum allowed value of separation m,(c) Δ
  
  step is a positive integer greater than one that defines the increment by which separation m can be increased,(d) Δ
  
  inc(m) is a non-negative integer(e) the values of Δ
  
  0(m), for all values of m in the range [1, . . . , N−
  
  1], and the value ofΔ
  
  step are the same for all RFID devices, and(f) no two RFID devices in the plurality of RFID devices have the same set of values for h(1) through h(N).
- View Dependent Claims (30, 31)
- - 30. The method of claim 29 wherein C is a function of L.
  - 31. The method of claim 29 wherein C is 3.

32. A method comprising:
- fabricating L radio-frequency (RFID) devices, wherein L is a positive integer greater than one;
  
  wherein each of the L radio-frequency devices comprises N actual reflectors in M possible reflector positions;
  
  wherein the positions of the N actual reflectors in each of the L radio-frequency (RFID) devices are different from the positions of the N actual reflectors in each of the other L−
  
  1 radio-frequency (RFID) devices according to a rule;
  
  wherein each device comprises;
  
  (A) an input-output port for receiving an input radio-frequency signal and for delivering an output radio-frequency signal derived from the input radio-frequency signal;
  
  (B) a plurality of N actual reflectors, wherein N is a positive integer greater than one that is the same for all RFID devices;
  
  wherein each of the N actual reflectors is positioned, within each device, at one of a plurality of M possible reflector positions, wherein(1) M is a positive integer greater than N that is the same for all RFID devices,(2) the plurality of M possible reflector positions is the same for all the RFID devices, and(3) each individual possible reflector position is identified by an integer, h, in the range [1, . . . , M];
  
  wherein the N actual reflectors are placed at a subset of the M possible reflector positions, with no two actual reflectors at the same position, such that each actual reflector is identified by an integer, n, in the range [1, . . . , N] and by a position, h(n);
  
  wherein the M possible reflector positions are arranged, relative to the input-output port, to achieve the following;
  
  (i) each actual reflector reflects a portion of the input radio-frequency signal,(ii) each reflected portion of the input radio-frequency signal comprises a reflected signal that is an attenuated replica of the input signal, for a total of N reflected signals from the N actual reflectors,(iii) the N reflected signals arrive at the output port where they are linearly combined to generate the output radio-frequency signal,(iv) each of the N reflected signals arrives at the input-output port with a group delay and with a phase delay, wherein the group delay and the phase delay depend on the frequency of the input radio-frequency signal, and(v) for input radio-frequency signals within a pre-determined frequency band, actual reflector n at possible reflector position h(n) generates a reflected signal whose group delay, D(h(n)), is a monotonically increasing function of h(n);
  
  wherein the N positions of the N actual reflectors, h(1) through h(N), satisfy the following constraints;
  
  (a) each of the N−
  
  1 separations between adjacent reflected signals, defined as h(m+1)-h(m) and denoted as Δ
  
  (m), is the sum of a base value, Δ
  
  0(m), and an integer multiple of a position step, Δ
  
  step, common to all separations, such that each separation can be expressed as Δ
  
  (m)=Δ
  
  0(m)+Δ
  
  inc(m)·
  
  Δ
  
  step, wherein m is an integer in the range [1, . . . , N−
  
  1],(b) Δ
  
  0(m) is a positive integer that defines the minimum allowed value of separation m,(c) Δ
  
  step is a positive integer greater than one that defines the increment by which separation m can be increased,(d) Δ
  
  inc(m) is a non-negative integer(e) the values of Δ
  
  0(m), for all values of m in the range [1, . . . , N−
  
  1], and the value of Δ
  
  step are the same for all RFID devices, and(f) no two RFID devices in the plurality of RFID devices have the same set of values for h(1) through h(N).
- View Dependent Claims (33, 34, 35, 36, 37, 38)
- - 33. The method of claim 32 wherein the rule is wherein at least C of the positions of the N actual reflectors in each of the L radio-frequency (RFID) devices are different from the positions of the N actual reflectors in each of the other L−
    - 1 radio-frequency (RFID) devices, wherein C is a positive integer greater than one.
  - 34. The method of claim 32 wherein C is a function of L.
  - 35. The method of claim 32 wherein C is 3.
  - 36. The method of claim 32 wherein the rule is wherein at least C of the positions of the N actual reflectors in each of the L radio-frequency (RFID) devices are at least Z positions from the positions of the N actual reflectors in each of the other L−
    - 1 radio-frequency (RFID) devices, wherein C is a positive integer greater than one, and wherein Z is a positive integer.
  - 37. The method of claim 32 wherein Z is a function of L.
  - 38. The method of claim 32 wherein Z is 2.

Specification

Resources

Litigation Campaign Assessment

Current Assignee
RF Saw Incorporated
Original Assignee
RF Saw Incorporated
Inventors
Hartmann, Clinton S.

Application Number

US12/718,966
Publication Number

US 20100225449A1
Time in Patent Office

Days
Field of Search
US Class Current

340/10.400
CPC Class Codes

G06K 19/0672 with resonating marks

G06K 19/0675 the resonating marks being ...

Radio-Frequency Surface-Acoustic-Wave Identification Tag and System

First Claim

1 Assignment

0 Petitions

Accused Products

Abstract

17 Citations

38 Claims

Specification

Use Cases

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Others

Radio-Frequency Surface-Acoustic-Wave Identification Tag and System

First Claim

1 Assignment

Subscription Required

Subscription Required

0 Petitions

Subscription Required

Accused Products

Subscription Required

Abstract

17 Citations

38 Claims

Specification

Subscription Required

Use Cases

Quick Links

Others