1. RFID DESIGN STUDIES Dr. KVS Rao Prof. Raj Mittra Intermec Technologies
Everett, WA, USA
Prof. Raj Mittra
Pennsylvania State University
University Park, PA, USA.

5. Applications Electronic Toll Collection Access Control Animal Tracking
Inventory Control
Tracking Runners in Races!

6. Radio Frequency Identification (RFID) System - Background Information
Introduction
Radio Frequency Identification (RFID) System
- Background Information
Applications of RFID
High Frequency (13.56MHz)
Supply Chain
Wireless Payment
Libraries Book ID
Ultra High Frequency (902 – 928 MHz)
Sensors
Libraries
Microwave Frequency (2.45GHz)
Electronic Toll Payments

7. Design Challenges Small Size Planar UHF Frequency Allocation
Europe MHz
North America MHz
Impedance Matching
ASIC Chip: High Capacitive Value, Small Resistive Value
Environmental Conditions

8. Antenna Parameters Characteristic Impedance
Power
3-Dimensional Radiation Patterns
Maximum Directivity
where Za = Ra + j Xa is the antenna impedance,
and Zs = Rs + j Xs is the source impedance.
where Umax is the radiation intensity
in maximum direction,
and Prad is the total radiated power.

9. Hybrid loop antenna
Top View of the antenna
Length of the antenna ~ one operating wavelength in free space
Outer loop terminated by inner loop  size reduction
Simple structure (one layer of dielectric substrate)
Antenna impedance must be highly inductive

10. Hybrid loop antenna (cont‘d)
Top View of the modified antenna
Realize a high value for the inductance by:
Changing the loop area (L ~ A)
Changing the length of the perimeter

11. Hybrid loop antenna : First design
Input Impedance
Perimeter of the loop antenna : 244 mm
Size used by the antenna : 39 x 40 (mm)
Resonance frequency : ~0.5 GHz and 1.26 GHz
Reactance +300 Ω at 1.01 GHz

12. Hybrid loop antenna : First design (cont‘d)
Far Field Pattern (normalized)
xy-plane
xz- (blue) and yz-(red) plane
Not omnidirectional Pattern in the xy-plane
 Non strictly symmetry of the geometry

13. Hybrid loop antenna : Parametric study
Changing the length of the inner loop Li
Li = 16 (red graph) mm  Li = 10 mm (blue graph)
Perimeter  , Loop area  : L 
Perimeter 244 mm  232 mm

14. Hybrid loop antenna : Parametric study
Changing the width of the inner loop Wi
Wi = 28 (red graph) mm  Wi = 30 mm (blue graph)
Perimeter  , Loop area  : L 
Perimeter 248 mm  252 mm

15. Hybrid loop antenna (cont‘d)
Far Field Pattern and Current distribution at 910 MHz
Current distribution : small current in the top part of the antenna  small influence on the inductance  Meandering

16. Meandered Hybrid loop antenna
Top View of the meanderd antenna
Perimeter 252 mm  302 mm
Maximum percentage at 910 MHz

17. Meandering technique reduces the size of the antenna
Hybrid Loop Antenna
OBSERVATIONS
Length of the antenna has a greater effect on the input impedance more than does the loop area
Meandering technique reduces the size of the antenna
Small percentage power delivered to the antenna  attributable to very small resistive part of the input impedance
The developed design did not prove to be too useful

18. Top and Side Views of the Antenna Structure
Dual cross-dipole
Top and Side Views of the Antenna Structure
Cross plarization sens can als be greatly improve by using more than one indep.antenna on the tag . Dual diple – provides operation that is almost orientation independent
Meandering dipole  size reduction
Cross-polarization sensitivity   dual dipole
Ground plane  can act as reflector  gain 

19. Dual cross-dipole : Design#1
Input Impedance
Length of the antenna : 218 mm ~0.66 λ (at 910 MHz)
Area used by the antenna : 51 x 51 (mm)
Reactance is too small in the desired frequency  Length of the antenna 
Resistive part is again very small

20. Dual cross-dipole : Design#2
Top View
“Load bar“ is added
Length of the antenna : 258 mm ~ 0.78 λ (at 910 MHz)
f300 at 900 MHz

21. Dual cross-dipole : Design#2
Far Field Pattern/Power delivered to the antenna/ Axial Ratio
~80 % of the power is delivered to the antenna
Narrow bandwidth (10.5 MHz more than 50 % is delivered)
Min. AR  3 dB (860 MHz – 960 MHz)

22. Dual cross-dipole : Parametric study
Influence of the height of the antenna
Decreasing h, increases the resonance frequency
By varying the height, input impedance can be adjusted for a good matching

23. Dual cross-dipole : Parametric study
Influence of the dielectric constant
Input Impedance and new design
Increasing the dielectric constant , drops the resonance frequency  length of the antenna 
Area used by the antenna was decreased ~ 19 % by using a higher dielectric (4 instead of 2.2 )
Max. Power delivered to the antenna was sligthly higher for the case with the higher dielectric constant (79 % vs 86 % )
Bandwidth wasn‘t influenced

24. Dual cross-dipole : New design
New design/Power delivered to the antenna
Area used by the antenna reduced ~ 35 % compared to the inital design (second case) and ~21 % compared to the previous case
Max percentage for the power plot : ~81 % (79 % second case / 86 % previous case)
Bandwidth didn‘t change

25. Inductively coupled Feed
Top View and structure
The proposed feed structure as well as the structure of the antenna system is shown in Fig. The antenna is composed of a small rectangular loop and a radiation body, which are coupled inductively. The radiation body correspond to the antenna D3) explored in the previous chapter. The feeding loop and the antenna are separated by a substrate with the substrate εr and the height h2 .
The strength of the inductive coupling is controlled by the distance between the feed and the antenna body (h2), as well as by the area of the loop (shape) .Fig shows the equivalent circuit of the inductively coupled feed structure. The inductive coupling is modelled by a transformer
Strength of the coupling depends on h2 and the size of the loop
Inductive coupling modeled by a transformer
Analyzing the input impedance by varying the size and shape of the loop

26. Inductively coupled Feed (cont‘d)
Changing length of the loop
There are two range of frequency where the antenna can operate, before and after the inductance gets his maximum.
To get the whole system in the right range, the antenna size could be reduced. But then we will have a very bad percentage of the power, which is transferred to the antenna, because of the very small resistive part in this frequency range
Increasing the loop size, increase the inductance
With this method the reactance increases ~200 Ω
Two operating range frequency
Antenna size needs to be adjusted (increased)

27. Inductively coupled Feed (cont‘d)
Changing the shape of the feeding loop
Same experiment as before (changing the size of the loop)
For one design we realized a very high percentage of power delivered (98 % at 899 MHz)
Bandwidth was narrow

28. Inductively coupled Feed (cont‘d)
OBSERVATIONS
Narrow bandwidth
Operating frequency can be varied by changing the size of the feeding loop
Antenna size must be increased to operate in the desired frequency range if we use a square loop.

29. Antenna Measurement
Top View of the antenna

30. Input Impedance Comparison : Measurement et Simulation

31. Field Pattern normalized (910 MHz) - Comparison
Measurement
Simulation
Anechoic chamber not ideal for 910 MHz
Different feeding part (balun for measurement)
Infinite substrate size used for simulation

32. PLATFORM-TOLERANT RFID DESIGNS

33. Dual-Band PIFA Design ASIC Chip: Zc=10-j160 [W] at 867 MHz
Parameter
Size (mm) L 62 W
51.3 H 3 S 5
gap (867/915 MHz) 1
gap (867/940 MHz)
1.9 er
2.35
ASIC Chip:
Zc=10-j160 [W] at 867 MHz
Zc=10-j150 [W] at 915 MHz
Zc=10-j145 [W] at 940 MHz

34. Dual-Band PIFA Design Dual-band Frequency Operation Open-Ended Stub
Gap Dimension and Stub Dimension Used to Tune
Platform Tolerance
Dominating Horizontal Current Distribution
Widening Short, Vertical Inductance Reduced, Antenna Lowered

35. Dual-Band PIFA Design Mounting Materials Dimensions 900 mm x 900 mm
Thickness=13 mm
Cardboard (er=2.5)
Glass(er=3.8)
Plastic(er=4.7)

36. Impedance [867/915 MHz] Dual-Band PIFA Design

37. Power Dual-Band PIFA Design
Power
(867 MHz)
(915 MHz)
(940 MHz)
No Material
83.49
64.92
74.07
Cardboard
54.53
86.28
80.5
Amount Increased
-28.96
21.36
6.43
Glass
54.81
80.72
72.9
-28.68
15.8
-1.17
Plastic
58.3
85.72 72
-25.19
20.8
-2.07

38. Radiation [867 MHz] Dual-Band PIFA Design
No Material
Cardboard
Glass
Plastic

39. Conclusions Dual-Band PIFA Design
Directivity
(867 MHz)
(915 MHz)
(940 MHz)
No Material
1.6841
1.832
1.8815
Cardboard
1.928
2.0704
2.3425
Amount Increased
0.2439
0.2384
0.461
Glass
2.4053
2.8135
3.9153
0.7212
0.9815
2.0338
Plastic
2.9936
3.4036
4.1411
1.3095
1.5716
2.2596

40. Environmental Change Dual-Band PIFA Design
Cardboard Box
900 mm x 900 mm
4 x 4
Thickness=13 mm
Metal sheet
450 mm x 450 mm
2 x 2
Height from Cardboard was Varied from 0 mm-20 mm
Radiation [867 MHz]
Metal 20 mm Under Cardboard
No Metal

41. Environmental Change Dual-Band PIFA Design
Power
(867 MHz)
(915 MHz)
Peak Directivity (867 MHz)
Peak Directivity (915 MHz)
No Metal
54.53
86.28
1.928
2.0704
Metal 0 mm
76.6
80.7
3.3105
3.0219
Amount Increased
22.07
-5.58
1.3825
0.9515
Metal 10 mm
91.08
73.11
3.1872
3.0167
36.55
-13.17
1.2592
0.9463
Metal 20 mm
73.25
76.82
3.2213
3.0599
18.72
-9.46
1.2933
0.9895

42. Ground Plane Optimization Dual-Band PIFA Design
No Material
Directivity
(867 MHz)
(915 MHz)
Original GP
1.6841
1.832
1 Inch Larger
2.3265
2.3131
2 Inch Larger
2.9306
2.918
3 Inch Larger
3.6696
3.7427
10 Inch Larger
4.5087
4.4954
Cardboard
1.928
2.0704
2.6915
2.7059
3.2191
3.2618
3.1907
3.3583
4.6297
4.687
Glass
Peak Directivity (867 MHz)
Peak Directivity (915 MHz)
Original GP
2.4053
2.8135
1 Inch Larger
2.5102
2.6094
2 Inch Larger
2.9178
3.0237
3 Inch Larger
2.7375
2.7357
10 Inch Larger
3.7178
4.1891
Plastic
2.9936
3.4036
2.9787
3.0035
3.0787
2.9965
3.1032
3.0408
3.0544
2.9356

43. Ground Plane Optimization Dual-Band PIFA Design

44. Inductively-Coupled Feed Loop PIFA Design
Impedance Matching
Inductively Coupled Feed Loop
Gap dimension between loop and radiators is used to tune
Designed to match Zc=10-j150 [W] at 915 MHz
Platform Tolerance
Reduced Current on Ground Plane

45. Inductively-Coupled Feed Loop PIFA Design
Mounting Materials
Dimensions
200 mm x 200 mm
( x )
Thickness=5 mm
Cardboard (er=2.5)
Glass with No Loss(er=3.8)
Glass with Loss(er=2.5) and Loss Tangent 0.002

46. Optimization of Impedance in Free Space
Power
915 MHz [%]
940 MHz [%]
Average
Gap 9 mm
9.09
4.39
6.74
Gap 9.25 mm
86.09
41.45
63.77
Gap 9.5 mm
77.38
34.50
55.94
Gap 9.75 mm
15.28
13.00
14.14

47. Directivity & Radiation
Directivity (915 MHz)
Directivity (940 MHz)
No Mounting Material
3.47
3.3
Cardboard (er=2.5)
3.43
2.94
Amount Increased
-0.04
-0.36
Glass No Loss (er=3.8)
3.4
3.25
-0.07
-0.05
Glass With Loss
(er=2.5) and loss 0.002
3.36
--0.11
867 MHz No Material
867 MHz Cardboard

48. Optimization of Impedance for Cardboard

49. Impedance Inductively-Coupled Feed Loop PIFA

50. Impedance Inductively-Coupled Feed Loop PIFA

51. Power Before and After Optimization Inductively Coupled Feed Loop PIFA
Power (915 MHz) [%]
Power (940 MHz) [%]
Free Space
86.09
41.45
Cardboard
16.29
6.5
Cardboard Optimized
61.19
31.69
Glass
24.06
9.48
Glass Optimized
56.59
69.36
Glass with Loss
11.65
23.81
Glass with Loss Optimized
61.6
52.55

52. Performance Enhancement with Artificial Magnetic Conductors
PMC Ground
Image Currents In Phase with Original Currents
PMC is reflective
Low Profile Antennas
High Impedance Surface
Current is filtered at selected frequencies so tangential magnetic field is small while electric field is still large
Suppression of Surface Waves=>Minimizes Backlobe
Reflection Coefficient of +1
PEC Ground
Reflects Half the Radiation
Gain can be increased by 3 dB
Image Currents Can Cancel Currents in Antenna
Limitation on distance between ground and radiating elements (/4)
Reflection Coefficient of -1

53. Metamaterials Challenges Electrical Ground Plane
Redirect one-half of the radiation  gain can be increased by 3 dB
Min. distance between antenna and ground : λ/4
Image currents cancel currents in antenna  poor radiation efficiency
Metamaterials→Material that exhibit electromagnetic properties not found in nature
EBG (Electromagnetic Band Gap) - Surface
Subclass of metamaterials
Can be designed to act as an AMC (Artificial Magnetic Conductor) ground plane
In many antennas a flat metal sheet is used as a ground plane or reflector. The presence of a ground plane redirects one-half of the radiation into the opposite direction, improving the antenna gain by 3 dB, and partially shielding objects on the other side. If the antenna is too close to the conductive surface, the image currents cancel the currents in the antenna, resulting in poor radiation efficiency. This problem is often addressed by including a quarter-wavelength space between the radiating element and the ground plane, but such a structure then requires a minimum thickness of λ/4.Since the antennas are considered to work in the UHF-range, the minimum thickness would be around 8 cm, which is not reasonable.

54. Metamaterial
AMC
Reflectivitiy “+1“ (reflection magnitude 1 and reflection phase 0°)
Can be achieved by utilizing periodic patch with via geometry or by planar achitecture without the need of vias  FSS (Frequency Selective Surface)
GA (Genetic algorithm) for an optimized FSS unit cell size,geometry and dielectric constant and thickness of the substrate material
by a planar architecture, without the need for vias, which incorporates a high impedance Frequency Selective Surface (FSS) into its design.
The EBG surface is obtained by utilizing a Frequency Selective Surface (FSS) on top of a thin dielectric substrate backed by a metallic ground plane, to act as an Artificial Magnetic Conductor (AMC). The antenna is then placed above the EBG surface to create the integrated EBG conformal antenna (Fig.).

55. Metamaterial - Simulations
FSS-design
GA-Output Parameter
For fabrication purposes, the designs were limited to a maximum dielectric thickness of 5.0 mm, a maximum dielectric constant of 12.2, and a maximum unit cell size of 5.6 cm what correspond to ~ λ/5 (at 910 MHz). The unit cell is always a square and contains 8-fold symmetry in order to guarantee the same response to a TE or a TM polarized incident wave. The above parameters will allow for a relatively thin, inexpensive structure to be fabricated that has a small unit cell size with respect to wavelength.
We tried in the following simulations to decrease the unit cell size as well as the maximum dielectric thickness on condition to get an AMC ground plane.
Another constraint was the total size of the ground plane; normally it should be a few wavelengths but as the antenna should be as small as possible to getting attach to even small objects the size of the ground has to be limited to ~10-11 cm (correspond to ~ λ/3 at the desired frequency range (860 MHz-960 MHz)). To build the AMC-ground plane an array of 2 x 2 unit cells has been used (Fig.).
Due to this size limitation, the surface wave won’t be prohibited and the directivity won’t be increased in this case.
Unit Cell
FSS-Screen with Antenna
Antenna Structure

56. Metamaterial – Simulations (cont‘d)
Input Impedance- Comparison (with and without using an FSS-layer)
Resonance frequency is decreasing by using a FSS-layer

57. Metamaterial – Simulations (cont‘d)
Bandwidth and maximum Directivity - Comparison
(with and without using an FSS-layer)
Higher Power transfer for the case with the FSS-layer (~94 % instead of 83 %)
Directivity is alternating in the range between 900 and 950 MHz around 1.2
Antenna could be made smaller  future work
Bandwidth sligthly smaller for the FSS-case
As before, the FSS-layer was removed to examine its influence on the antenna-system. The resonance frequency was shifted again, but within the considered range ( MHz), the input impedance is pretty similar. That is why it might have been possible to shrink the size of the antenna by a factor of Determining the extent to which the antenna size will change is an area for future work (see next chapter “Summary and Future work”).The directivity again shows some alteration (around 1.2) in the range between 900 and 950 MHz.
Two peaks appear on the power plot in the range between 910 MHz and 930 MHz. By comparing the input impedances, we observe that there is a kind of resonance frequency that could be due to the FSS-layer that was originally supposed to resonate in this range.
A higher peak is achieved by using an FSS-layer, but the bandwidth is slightly smaller in this case. A reason for this could be the very narrow frequency range, where we have AMC.

58. Metamaterials (cont‘d)
Summary
Using an FSS-layer drop the resonance frequency
Changing the size of the antenna to get a desired input impedance is very difficult
Directivity behaviour changes sligthly
Higher power delivered to the antenna with the FSS-layer
Bandwidth slighly smaller for the FSS-case
Future work
Increasing Bandwidth
Changing structure of the AMC instead of the antenna size
Antenna attached to metal objects  Performance will change
Tunable antenna design  provide tolerance for fabrication

59. Fabrication of AMCs
GA Input
Parameter Output
Configuration of AMC

60. FSS Layer FSS Unit Cell /2 x  /2 FSS Layer
Reflection Crosses 0 at 939 MHz

61. Directivity AMC Dual-Band PIFA Inductively Coupled PIFA Directivity
Directivity
867 MHz
940 MHz
PEC Ground
2.5255
2.6126
AMC Ground
2.892
3.125
Increased
0.3665
0.5124
Directivity
915 MHz
940 MHz
PEC Ground
2.7074
2.421
AMC Ground
3.6855
2.9899
Increased
0.9781
0.5689

62. Radiation [867 MHz] AMC Dual-Band PIFA Inductively Coupled PIFA PEC

63. Optimization Dual-Band PIFA Design

64. Optimization Dual-Band PIFA Design
STUB 2.8
Imaginary
867 MHz [W]
Real
Power
867 MHz [%]
Gap 2.6
157.45
40.29
63.56
Gap 2.5
142.94
3.55
29.90
Gap 2.4
153.95
26.54
77.39
Gap 2.2
131.14
2.66
10.70
Gap 2.1
128.29
2.69
9.23
Note: 915 MHz and 940 MHz were not able to be sufficiently matched.

65. Optimization Inductively-Coupled Feed Loop PIFA Design

66. Optimization Inductively-Coupled Feed Loop PIFA Design
Dimension [mm]
Imaginary 915 MHz [W]
Real
915 MHz [W]
Imaginary 940 MHz [W]
940 MHz [W]
Power
915 MHz [%]
940 MHz [%]
8.90
164.15
0.07
169.24
3.27
0.92
17.11
9.10
164.23
0.06
170.52
4.52
0.78
20.97
9.20
162.70
0.24
166.82
1.47
3.64
9.68
9.25
166.60
2.98
171.89
0.51
26.83
2.44
9.30
158.90
0.14
163.86
1.29
3.11
10.70
9.40
163.04
0.13
167.28
4.80
1.90
9.50
163.52
0.17
168.06
4.42
2.34
23.91

67. OBSERVATIONS
Dual-Band PIFA Design showed to be platform tolerant in numerous cases
Inductively Coupled Feed Loop PIFA was very sensitive to platform
An optimization was done for each mounting material with the Inductively Coupled Feed Loop PIFA
The AMC ground plane did significantly improve the directivity and reduce the backlobe in both antenna cases
An optimization needed to be done using the AMC for both antenna cases because the impedance was altered
The Dual-Band PIFA Design was optimized to sufficient operation but the Inductively Coupled Feed Loop PIFA was not

68. ALTERNATE PLATFORM-TOLERANT RFID DESIGNS
*courtesy of Prof. K.W.Leung
City University of Hong Kong

69. - Background Information
RFID Tag Design
- Background Information
Inductive-coupled feeding design

70. Platform Tolerant
Principle -Using a patch antenna as the resonating element -The Tag antenna and the surface material are isolated by the ground plane -The Tag has a stable performance regardless of the mounting surface

71. First Design Size of Ground Plane: 83.638 x 112.058mm (0.26λx 0.34λ)
RFID Tag Antenna Configuration
First Design
Size of Ground Plane: x mm (0.26λx 0.34λ)
Size of Printed Antenna: 64.4 x 89.95mm(0.2λ x 0.27λ)
Substrate thickness: mm
Substrate dielectric constant: 3.38
Substrate loss tangent:

72. Transmitted power of the Reader - 1W (30dBm)
RFID Tag Antenna Configuration
Chip Impedance – j116.67Ω
Transmitted power of the Reader - 1W (30dBm)
Gain of the Reader antenna - ~7.5dBi

73. Simulated Antenna Gain
RFID Tag Antenna Configuration
Simulated Antenna Gain
Gain: ~ -8.6 to dBi

74. Current Distribution (First Design)
RFID Tag Antenna Configuration
Current Distribution (First Design)
902 MHz

75. Current Distribution (First Design)
RFID Tag Antenna Configuration
Current Distribution (First Design)
915 MHz

76. Current Distribution (First Design)
RFID Tag Antenna Configuration
Current Distribution (First Design)
928 MHz

77. Result and Analysis
Measurement Method
-The Read Range was measured in the EMC Chamber -Reader Antenna was moved inside the EMC Chamber -Measure the maximum readable distance that the signal can be detected

78. RFID Tag Antenna Configuration
Measurement Method
- RFID Tag was fixed by the foam stand and measured at different orientation angles (0 deg, 45 deg, 90 deg) deg deg deg

79. Tag Antenna Configuration (by inductively-coupled feeding)
Result and Analysis
Tag Antenna Configuration (by inductively-coupled feeding)
-The tag has similar performances for different angles

80. Result and Analysis
Second Design
-A Philips’s chip SL3S10 01 FTT is used -Impedance of the chip: 16 – j380Ω (much more capacitive) -Difficult to match using the first design -Introduce a new feed network

81. Second Tag Antenna Design
RFID Tag Antenna Configuration
Second Tag Antenna Design
- Directly connect the feed network to the radiating patch at several point
Size of Ground Plane: x mm (0.26λx 0.34λ)
Size of Printed Antenna: x 93.3mm(0.17λ x 0.28λ)

82. Current Distribution (Second Design)
RFID Tag Antenna Configuration
Current Distribution (Second Design)
902 MHz

83. Current Distribution (Second Design)
RFID Tag Antenna Configuration
Current Distribution (Second Design)
915 MHz

84. Current Distribution (Second Design)
RFID Tag Antenna Configuration
Current Distribution (Second Design)
928 MHz

85. Platform Tolerance Test
Result and Analysis
Platform Tolerance Test
-Following surfaces were used in the test: -Acrylic (200 x 200 x 3 mm) -Wood (200 x 200 x 3 mm) -Aluminium (200 x 200 x 3 mm)

86. Result and Analysis
Platform Tolerance
-The tag has stable performance over different surfaces -The longest read range is obtained for the metal (Aluminium) case because EM wave is reflected by the metal