This three-part series presents
a detailed overview
of RFID encoder systems
and the antenna solutions
required for reliable printing
(writing) to individual tags
2. High Frequency Design
RFID ANTENNAS
quantities of HF and UHF RFID widely used in the automated valida- Accelerated in the recent years,
Printer-Encoders, Print Engine- tion procedures for Smart Labels and the evolution of the RFID technology
Encoders for applicators, and mobile cards, preventing their re-encoding and the hungry market for Printer-
Printer-Encoders working with fork- and data corruption, continuously Encoders has fueled the development
lifts in the warehouses. In addition to securing a smooth transition of many of specialized UHF antennas. Their
the printing and the initial encoding RFID pilot programs and extending ability to work with transponders in
purposes, this equipment is also the successes of existing applications. very close proximity and communi-
cate selectively with only one target-
ed transponder, tightly spaced with
others, essentially distinguishes the
specialized UHF antennas from the
conventional ones. In contrast to the
antennas designed for long range
RFID applications, these specialized
antennas are very similar to RF bi-
directional couplers based on electro-
magnetically coupled transmission
lines [4] that are common in the RF
and microwave realm. The difference
from RF couplers is the variable dis-
tance between the coupled devices,
the variability of transponder shapes,
and a single RF port of the antenna-
transponder structure.
Conventional antenna characteri-
zation parameters such as gain, radi-
ation pattern, radiation power effi-
ciency, directivity and beamwidth,
which are normally used in antenna
design for long range RFID applica-
tions, assume new meanings and def-
initions. For example, beamwidth
becomes transponder encoding range,
and antenna directivity becomes spa-
tial selectivity. The antenna-
transponder interaction occurs in a
complex printer environment, which
can disturb the nearby electromag-
netic field, the antenna characteriza-
tion parameters turn out to be depen-
dent on the surrounding objects,
transponder electrical parameters,
and dimensions. Furthermore, the
composite architecture of the Printer-
Encoders creates an RF unfriendly
environment, affects the transpon-
ders’ interrogation process, and
imposes limitations on the antenna
dimensions and location. Most impor-
tantly, the Printer-Encoder and
antenna designs also dictate the min-
imum acceptable size of the Smart
Labels and their transponder place-
ment. Because of these mechanical
3. constraints the transponders cannot
be placed arbitrarily in a Smart
Label—their placement must be sep-
arately specified for every printer
brand and model.
The Smart Labels specification,
which dictates a particular transpon-
der placement, indirectly expresses
the RFID printer’s encoding capabili-
ty. A list of parameters describing
transponders placement includes the
transponder placement range, the
placement starting distance, and the
separation distance between the
adjacent labels on a liner, known as
the pitch (Fig. 1(a) and (b)).
When the dimensions of labels
required for printing and encoding are Figure 1 · Smart Label structure and transponder placement. (a) Smart
4" × 6" or 4" × 4" and their length sig- Label design; (b) short labels with long pitch; (c) short Smart Labels; (d)
nificantly exceeds the transponder’s small labels with short pitch.
width, or the labels are relatively
short but far apart from each other
(Fig. 1 (b)), the antenna can easily tion and the challenge occur when the encoding a small component label
communicate with the targeted Printer-Encoder must encode short requires an antenna with high spatial
transponder without collision with the Smart Labels densely spaced on the resolution. This attribute is the so-
adjacent transponders. The complica- liner (Fig. 1 (c) and (d)). In this case called spatial selectivity that is the
4. High Frequency Design
RFID ANTENNAS
antenna’s capability to reliably interrogate the selected comparison.
transponder without activating surrounding ones. Section 4. UHF Antennas for Stationary Printer-
The ability of a printer to encode the transponders Encoders presents a comprehensive review of several TL
placed near the leading edge of the label defines the antennas developed for stationary UHF Printer-Encoders
transponder placement starting distance and directly cor- and qualitative analysis of their impact on the printer’s
relates with the antenna dimensions and its position encoding performance.
inside the printer. The most challenging design goal is to Section 5. UHF Antennas for Mobile Printer-Encoders
make a printer-encoder capable of working with short introduces the ultra-compact novel UHF stripline TL
Smart Labels, where the length of the Smart Label is antennas, their strengths for mobile RFID Printer-
nearly equal to the width of the embedded transponder Encoders, and optimization of the antenna geometries
(Fig. 1 (d)). and electrical parameters using HFSS.
This review examines the capabilities and limitations [Sections 3, 4 and 5 will be published in the October
of the different planar transmission line (TL) UHF anten- and November issues of High Frequency Electronics.]
nas, which are used for RFID Printer-Encoders requiring
the interrogation of a single transponder tightly spaced 2. Antenna-Transponder Coupling in Close
with other transponders and in very close proximity to Proximity
the antenna. The review focuses on the low profile spa- Although the UHF passive transponders produced by
tially selective mismatched stripline and double-conduc- the leading vendors could have their antennas shaped
tor stripline TL antennas designed for printers capable of similar to a meander-line [5], bow-tie [6], or cross dipole
interrogating densely spaced short Smart Labels. The [7], the majority of them are half-wavelength dipole or
mismatched resonant TL antennas typically have a nar- folded-dipole antennas [5], [8], [9]. The dipole antenna is
row bandwidth. To overcome this limitation a bandwidth most popular in various RFID applications because of the
improving technique originally developed for impedance near-omnidirectional radiation pattern in the far-field
matching TL transformers is applied to microstrip and [10] and a straightforward chip impedance matching pro-
stripline TL antennas. This article also presents an cedure [11]. The half-wavelength (λ/2), in free space, of an
empirical verification of the antenna geometries and elec- operational frequency 915 MHz (ISM US RFID band) is
trical parameters that were initially derived by using 164 mm. The physical length of the transponders may
Ansoft High Frequency Structure Simulator (HFSS). range from 120 to 20-25 mm depending on the permittiv-
The ultra-compact stripline UHF antennas enable: ity of their substrate materials and the antenna profiles.
There are three spherical spaces surrounding the
• Individual encoding of short Smart Labels with Reader and transponder antennas in the transmitting
small pitch; mode: reactive near-field, radiating near-field, and far-
• Acceptance of transponders with broad deviations of field [12, 13, 14, 15]. The radius of each sphere depends on
resonance frequency and activation power thresh- the operational frequency (or wavelength) and the largest
olds; linear dimension (D) of the antennas. The interaction
• Positioning of the transponder placement area near mechanism and the energy transfer between two anten-
the leading edge of the label; nas are determined by whether they are located within
• Printer batch mode encoding without involvement of each other’s near-field, radiating near-field, or far field.
the anti-collision management; For the RFID 915 MHz frequency band the dimension D
• Space saving design of the mobile RFID printers; of antennas is usually chosen as one-half wavelength.
• Effortless installation and straightforward RFID The far-field, having a propagating wave, starts out-
conversion of the existing bar code printers. side the sphere with radius R1, which can only be approx-
imated [12] because of the violated condition D > λ.
The next section, 2. Antenna-Transponder Coupling in
Close Proximity examines magnetic and electric field dis- D2
R1 > 2
tribution along the antenna-transponder structure, ener- λ
gy transfer and coupling mechanism between them. This
section also identifies two criteria for comparison of field Therefore, for an antenna with the largest linear
intensity and impedance bandwidth of the antennas. dimension D = 164 mm, the radius of the sphere for far-
Section 3. Printer-Encoder Environment classifies four field is R1 > 164 mm and is smaller for shorter antennas.
critical printer zones, relates their lengths to the con- When a transponder is located at distance R1 or far-
straints imposed by the antenna dimensions on the ther from the Reader’s antenna, the electromagnetic com-
Smart Label design and transponder placement parame- ponents of the propagating wave and its impedance are
ters, and establishes two geometrical criteria for antenna independent of Reader antenna’s geometry, and the field
32 High Frequency Electronics
5. High Frequency Design
RFID ANTENNAS
The electro-magnetic components of an antenna’s
reactive near-field and its wave impedance vary signifi-
cantly across the antenna’s physical structure. The anten-
na and the transponder inside a Printer-Encoder operate
in each other’s non-uniform reactive near-fields.
The electric and magnetic field strength distributions
for the half-wavelength transponder dipole antenna in
the transmitting mode are depicted in Figure 2. In close
proximity, the magnetic field is typically concentrated at
the center of the dipole, where the current attains its
maximum value, while the maximum electric field
strength is at the edges of the dipole arms [17]. Applying
the reciprocity theorem [12], which states that an anten-
na’s transmitting performance is equal to its receiving
performance, one can conclude that a Reader’s antenna
should have a similar to dipole electro-magnetic field dis-
tribution for the best coupling with a transponder.
Figure 2 · Dipole current distribution and fields. The source of antenna’s field is electric charges flow-
ing through the antenna. Charges slowly moving in space
create the reactive near-field and fast moving charges cre-
surrounding the transponder is uniform. In long range ate the far-field [18]. At the UHF band the charges also
UHF RFID applications, where the transponders are sev- vary in time with the period of 0.5 or 1 nanosecond. The
eral meters away from the Reader’s antenna, they are in temporal variation also contributes to the antenna’s far-
each other’s uniform far-field. During data transmission field radiation. The antennas radiated near-field and far-
the transponder varies the impedance of its antenna and field strengths significantly increase if charges are spa-
changes its field, but these field disturbances do not affect tially accelerated. Whenever a charge abruptly changes
the current distribution of the antenna in the transmit- direction or vanishes, for example, because of the anten-
ting mode or its electrical parameters. The antenna- na’s structure, the electrical energy applied to an antenna
transponder bi-directional communication is provided by is efficiently converted into radiation [19]. The antenna’s
the propagating wave, there is no coupling between them, radiation efficiency increases when its length approaches
and therefore no mutual influence. the half-wavelength of its operational frequency. This
Inside the sphere with the radius R1 is the radiating explains why the radiation of the half-wavelength dipole
near-field. The inner boundary of this region is approxi- antenna having zero current value at the ends of its arms
mated by the radius R2 is very efficient. High intensity radiation in the far-field
is desirable for the long range RFID systems, which are
D3 based on propagating waves. But to be appropriate for
R2 > 0.62
λ very close proximity applications, an antenna should have
a strong reactive near-field and a weak far-field to comply
For the frequency of 915 MHz and the half-wavelength with the EMI/RFI regulations.
antenna dimension D = 164 mm, the radius R2 = 72 mm. In very close proximity, the transponder activation
This field is partly a product of the continuous electric energy is mostly delivered through the quasi-static elec-
and magnetic field energy exchange with the antenna, tromagnetic coupling with the antenna. The coupling
but predominantly is a radiation wave. The antenna is grade of two closely spaced devices depends significantly
loosely coupled with the transponder and they have a on their separation distance, geometrical profiles, and
weak mutual influence. mutual alignment. Magnetic coupling is provided by
The region of the pure reactive near-field is within the mutual inductance [16] and electric coupling through
estimated radius R2. This field is the result of the contin- static capacitances [4]. Mutual inductance is an attribute
uous electric and magnetic field energy exchange with of closely spaced wires carrying current. The current
antenna electrical energy. The field strength is propor- through each antenna creates the corresponding magnet-
tional to the antenna’s Q-factor and the current flowing ic flux that induces voltage and current in the other
through it. For Printer-Encoders and other very close antenna. Static capacitance is an attribute of closely
proximity applications the antenna-transponder separa- spaced conductive plates or areas having opposite
tion distance is 5-10 mm and is much shorter than the lin- charges. The antenna or transponder dipole’s arms are
ear dimensions of the Reader’s or transponder’s antennas. these plates. The arms charges cause electric field
34 High Frequency Electronics
6. High Frequency Design
RFID ANTENNAS
strength variation and develop voltage across a nearby
antenna and transponder constructing elements, which
are in that field.
Transponders use a backscatter data transfer mecha-
nism, re-radiating received signals back to the interroga-
tor by their own antennas. For data transfer the
transponder modulates the impedance of its own antenna
and changes the surrounding antenna field distribution.
This modulation influences the field of the Reader’s
antenna and in turn changes its current distribution,
antenna impedance, and frequency tuning. An increase in
separation distance reduces the grade of antenna-
transponder electro-magnetic coupling.
The energy delivered to a transponder is used by the
transponder’s IC to support its interrogation. The RF
power (PT) delivered to a transponder is a product of its Figure 3 · Power delivered to a transponder and RF
coupling grade with an antenna and the strength of the power margin.
reactive near-field of the antenna powered by a Reader.
Regardless of the antenna type the power PT can be
expressed by the equation: Equation (1) demonstrates that the coefficient K,
power PA or both can be decreased for power reduction.
PT = K * PA (1) For some types of antennas the coefficient K is indepen-
dent of the antenna-transponder alignment and can be
where K is a power transfer coefficient and PA is Reader decreased to low power PT. The drawback of lowering the
power applied to an antenna. coefficient K or power PA is the loss of the RF power mar-
In the RFID systems with spatially independent and gin over the transponder activation power threshold for
high value coefficient K, the power delivered to a its placement range, as shown for Antenna #1 in Figure 3.
transponder can considerably exceed its activation power The RF power margin is defined as the maximum sup-
threshold. The activation power threshold is the Reader’s pression (in dB) of the Reader’s operational RF power
RF power level at which the transponder becomes ener- achieved in the middle of the transponder placement
gized and starts responding to the Reader’s commands. range, when the power falls to the transponder activation
This power threshold level is a complex function that threshold level and the transponder stops communicat-
depends on the antenna parameters, transponder IC ing. With a low power margin the interrogation process
impedance matching and its activation voltage threshold. becomes unreliable because of the system’s susceptibility
Most importantly, the activation power threshold may to the deviations of the transponder’s and the antenna’s
depend on the transponder’s location inside a printer. The electrical parameters and their precise tuning. Although
excessive activation power causes a relatively extensive some transponders with less than ideal parameters may
communication interval and substantially increases the have acceptable performance for long range applications,
transponder placement range (Fig. 1 (a)). the power delivered in the near-field may become insuffi-
At disproportionate energy levels the reactive field will cient and the transponder will be missed. To stabilize the
cover not only the targeted interrogation area but also the encoding process and make it robust, the RFID system
surrounding areas, which is not a problem when dealing should have the highest possible RF power margin.
with a single transponder, or when the transponders are In the RFID systems with spatially dependent coeffi-
spaced far apart. Although this spatial separation local- cient K, its value changes depending on the antenna-
izes the encoding interval, it also limits the minimum transponder coupling grade, which correlates to the ori-
achievable label length. With closely spaced transponders, entation and proximity to each other. For such a system,
the interrogation range must be controlled so as to prevent the coefficient K and the activation power achieve their
accidental communications with the neighboring maximum values only for the transponder which is clos-
transponders. One way to prevent this collision is to est to the antenna; they are noticeably lower for the adja-
reduce the Reader’s power and consequently the length of cent transponders.
the transponder placement range. In this case the deliv- A tightly spaced antenna and transponder behave as
ered power is higher than the transponder’s activation an air-dielectric variable capacitor, which plates are
power threshold only for the encoding range and is lower formed by the transponder and the antenna. Its capaci-
than the activation power threshold outside of this range. tance is proportional to the area of the overlapping sur-
36 High Frequency Electronics
7. High Frequency Design
RFID ANTENNAS
faces of the antenna and the transponder. When the
transponder moves closer to the antenna their mutual
surface grows and the static capacitance increases. This
increase in static capacitance improves the antenna-
transponder coupling and raises the power delivered to
the transponder as well. Similarly the magnetic coupling
increases when the two current carrying “wires” move
closer to each other. The power transfer coefficient varies
along the communication range and the power delivered
to the transponder throughout the encoding interval sig-
nificantly exceeds the transponder’s activation power
threshold. In this case the RFID system has a high RF
power margin, which is illustrated by the power curve for
Antenna #2 in Figure 3.
For a selected antenna-transponder separation dis-
tance, an RFID system achieves the maximum RF power
margin when their mutual overlapping area is compara-
ble with the transponders’ width. The limiting factor for
the maximum grade of coupling is the impedance induced
by the transponder in the antenna circuit. In very close
proximity this induced complex impedance could cause a
severe impedance mismatch between the Reader’s and
the antenna’s ports leading to a drastic reduction of the
transponder’s activation power. To characterize the RF
system power margin and the antenna-transponder cou-
pling grade the encoding field intensity is introduced.
The coefficient K, in addition to being dependent on
the antenna-transponder geometries and their alignment
in the general case, is also a function of the antenna tun-
ing frequency and the antenna impedance bandwidth Figure 4 · Antenna reflection coefficient and
(BW). To justify the antenna bandwidth, at least two impedance bandwidth (BW). (a) BW = 90 MHz; (b) BW =
aspects of the RFID system should be taken into account. 150 MHz.
The first one is the spectrum of modulated signals that
are used by the Readers for transponders interrogation.
For 915 MHz U.S. RFID band, the allocated spectrum
is 26 MHz ranging from 902 to 928 MHz. RFID uses fre-
BW1 ( SWR1 − 1) SWR2
quency hopping modulation around the central frequency = × (2)
of 915 MHz. Although the Readers from different vendors BW2 SWR1 ( SWR2 − 1)
operate at the same frequency band, they differ in their
ability to handle hopping frequency phase shifts associat- Substituting BW2 = 26 MHz at SWR2 = 1.4 and SWR1
ed with phase difference of signals reflected from the = 2 in Equation (2), we can find BW1 = 54.4 MHz. This BW
antenna port for different channels. The Readers, which is derived for a precisely tuned 915 MHz antenna.
are based on I-Q synchronous detection of the transpon- The second aspect of the RFID antenna’s BW selection
der’s re-radiated signals, typically require at their RF is associated with the deviations of antenna’s electrical
port a Standing Wave Ratio (SWR) of 1.4 or less in the and mechanical parameters. The antenna fabrication pro-
operational band in order to perform reliable interroga- cess typically utilizes non-ideal materials and non-ideal
tion. The BW definition for conventional antennas is a fre- operational procedures, which impact the antenna center
quency band over which an antenna has a SWR = 2 or has frequency, port impedance, and consequently the input
its reflection loss or S11 parameter that is less than –9.5 reflection coefficient (Γ). The reflection coefficient is relat-
dB. The tuning frequency is the center of the antenna’s ed to SWR by the well-known formula:
bandwidth. To obtain a standard BW value of an antenna,
the BW at SWR = 2 is calculated from the antenna BW at
SWR − 1
SWR = 1.4. For example, for a microstrip antenna, the fol- Γ= (3)
lowing equation from [20] can be used: SWR + 1
38 High Frequency Electronics
8. Using Equation (3) and SWR = The chosen impedance bandwidth
1.4, we obtain coefficient Γ = 0.166. criterion thus represents a character-
This value can be used as the maxi- istic of the antenna in terms of the
mum acceptable level of reflection for technological stability and the
the bandwidth. If the resonant fre- EMI/RFI immunity.
quency of a narrowband antenna
changes noticeably, the antenna [This article will continue in the
input reflection loss at the opera- next two issues of High Frequency
tional frequency increases, and the Electronics, beginning with with sec-
power transfer coefficient K drops. tion 3. Printer-Encoder Environment.
For example, a microstrip antenna All references will be listed at the end
based on the substrate material of the final installment.]
IS410 (ISOLA) with the dielectric
constant ε = 4.25 ±0.15 and BW = 90 Author Information
MHz can have a resonant frequency Boris Y. Tsirline is the Principal
from 900 to 930 MHz (Fig. 4 (a)) and Engineer at Zebra Technologies
maintain an unacceptably high Corporation in Vernon Hills, IL. He
reflection coefficient |Γ| below 0.24 received a BS and MS degrees in RF
(SWR = 1.63) for the 902-928 MHz & Microwave Engineering from
frequency span instead of the Γ = Moscow Aviation University, Russia
0.166 required for SWR = 1.4. If an in 1973 and a PhD in EE from
antenna based on the same dielectric Moscow State University in 1986.
material has BW = 150 MHz, its Before moving to the US in 1992, he
reflection coefficient magnitude is served as a Director of R&D at
|Γ| <0.14 for the 902-928 MHz band Automotive Electronics and Equip-
(Fig. 4 (b)) and it complies with the ment Corp., Russia, developing mili-
Reader SWR requirements. tary and aerospace electronic sys-
Deviations of other antenna tems. He has been in the Automatic
parameters including the thickness Identification and Data Capture
of the substrate and the copper industry since 1995; first as an RF
cladding have less influence on the Engineer involved in LF RFID design
antenna resonant frequency than the at TRW, and then at Zebra
dielectric constant and the BW of 150 Technologies Corporation since 1998.
MHz can be considered as a conser- He managed the development of
vative estimate for the desirable Zebra’s first HF RFID printer-
antenna bandwidth in order to toler- encoder and established the design
ate technological deviations of the methodology for HF and UHF spa-
antenna’s electrical and mechanical tially selective transponder encoding
parameters. On the other hand, an modules used throughout the corpo-
excessive antenna bandwidth is not ration divisions for RFID labels and
advantageous. Antennas with sub- cards printers. Dr. Tsirline holds
stantially wider than necessary three non-classified Russian and two
bandwidth could potentially be sus- US patents and has numerous pend-
ceptible to the electro-magnetic inter- ing patents for RFID enhancements.
ferences caused by the printer’s near- He can be reached by e-mail at
by electrical and electronic devices. BTsirline@zebra.com.
DO YOU HAVE A GREAT IDEA OR INTERESTING PROJECT TO SHARE?
Proposals for articles may be sent to Gary Breed, Editorial Director:
gary@highfrequencyelectronics.com
10. High Frequency Design
RFID ANTENNAS
zone shielding component may be used. The disadvantage
of a shielding solution is that the geometries of the shield-
ing components depend on the transponder dimensions
and involve adjustment for every new transponder form-
factor.
Targeted transponder zone generally depends on the
antenna and the transponder dimensions as well as the
Reader’s RF power. This zone is active, of course. When
the antenna occupies much of the space between the plat-
en roller and the media supply roll, the targeted transpon-
der zone is relatively long. An extended targeted transpon-
der zone requires either a long label or an outsized pitch
in order to avoid collisions or transponder re-encoding
with the wrong data. A short antenna, closely positioned
to the platen roller, affords a short placement starting dis- λ
Figure 6 · Open Transmission Line antenna—λ/4 wave-
tance for the transponders and their short transponder length microstrip patch.
placement range.
Relatively short labels often have a partition distance
between them that is only a fraction of their width (Fig. Two criteria are proposed for the integral characteri-
1(d)). Consequently, transponders embedded into such zation of relations between the antennas construction,
labels are grouped close to each other. In this dense the printer zone dimensions and the Smart Label design
arrangement all transponders can be activated simultane- parameters. The first criterion is the antenna structural
ously by a “low” resolution antenna. The long range RFID feasibility, which reflects the space required for the
systems commonly employ an anti-collision technique for antenna installation and designates the interval occupied
processing a group of transponders. This technique is by the antenna along a transponder’s path. The second
impractical for Printer-Encoders because it is unable to criterion is the transponder placement boundaries, which
identify single targeted transponder. Only an antenna characterizes the antenna spatial selectivity and the
with spatial selectivity can work with a single closest associated transponder placement parameters of the
transponder without activating the adjacent ones. The Smart Label.
higher the spatial selectivity of an antenna, the shorter These four criteria established above are intended to
the transponder placement range. In the best case the be utilized for the comprehensive study and comparison
transponder placement range can equal the transponder’s of the existing UHF antennas for stationary and mobile
width. The shielding components can also be used to form RFID Printer-Encoders and also to determine the corre-
the targeted transponder zone or to limit its longitudinal lation between the printer encoding function and the
length with the same disadvantages as for the following Smart Label parameters limitations.
adjacent transponders zone application described above.
Encoded transponder zone length mainly depends on 4. UHF Antennas for Stationary Printer-Encoders
the antenna field strength and the printer components Microstrip, stripline and others PCB transmission
surrounding this area. The encoded transponder zone lines developed primarily for RF energy transfer have
should be inactive. The antennas with highly intensive become accepted as antennas by UHF Printer-Encoders
electro-magnetic field and some printer components with and by other RFID close proximity applications. Their
the wave re-radiating ability can inadvertently make this planar structure, ability to handle relatively high RF
zone active. In this case every encoded and printed label power and inexpensive, precise fabrication process enable
must be either peeled or torn off in order to prevent the easy integration. Any transmission line antenna signifi-
transponders collision or an incorrect re-encoding. The cantly changes its behavior and electrical properties
need to take off the encoded transponders prohibits print- depending on the line length and its terminating status.
er operation in the batch processing mode. Alternatively There are two TL antenna types: Open TL type based on
the label pitch may be increased such that the encoded the open TL and Terminated TL type—antennas based on
transponder leaves this zone when the next transponder the loaded TL.
arrives for an encoding. The application of the shielding
components suppressing electro-magnetic field in the Antenna Based on Open TL
encoded transponder zone imposes functional limitations An Open TL antenna type is represented by a quarter-
on the printer. For example, the shielding elements mount- wavelength microstrip patch antenna (Fig. 6) [21], [22].
ed in this zone conflict with the use of an external cutter. The patch antenna for close proximity applications differs
38 High Frequency Electronics
11. High Frequency Design
RFID ANTENNAS
from a conventional patch antenna in having shielding of the patch (Fig. 6). Bandwidth of patch antennas with-
components along the non-radiating patch sides and a out a shield is narrow, approximately 30 to 50 MHz. In
much narrower radiating edge in order to decrease field order to tolerate parameter deviations the geometry of
strength in radiating near- and far-field zones. every antenna must be adjusted for frequency tuning and
impedance matching.
Antenna Structural Feasibility
This antenna is based on PCB and enclosed in shield- Antennas Based on Terminated TL
ing case with one open side. The antenna is arranged in In contrast to Open TL, antennas based on
parallel with a transponder in an encoding area and Terminated TL could be resonant or not-resonant. They
resides in interval of 20-25 mm (including its mounting may have wide or narrow bandwidths depending on the
components) behind the platen roller. TL length and the terminating load value. In the most
common case a terminated TL exhibits three specific fea-
Transponder Placement Boundaries tures that have defined three trends in UHF antenna
The antenna is positioned close to the platen roller development for very close proximity RFID applications.
and provides a short transponder placement range and These features are related to the TL input impedance.
placement starting distance, which allows the processing The input impedance ZIN of any loss-free TL having
of short Smart Labels with a short pitch. characteristic impedance ZC, a length l and terminated by
The antenna shielding elements are engaged to limit a load ZL in general is described [24] as
the transponder interrogation interval. Electro-magnetic
shielding is probably the oldest method of insulating the
⎛ Z + jZC tan β ⎞
transponder designated encoding area. In RFID technolo- ZIN = ZC ⎜ L ⎟ (4)
gy shielding was initially employed for selective single ⎝ ZC + jZL tan β ⎠
transponder testing in the presence of others [23]. The
shielding disadvantage appears when transponder form- where ß is the phase constant, which for a uniform,
factors change frequently, for example, for different label loss-free TL is inversely proportional to a wavelength λ
sizes, and so do the geometries of the shielding elements. and is given by
2π
Encoding Field Intensity β= (5)
λ
Parallel alignment of the antenna with a transponder
in the encoding area ensures improved coupling. Substituting (5) in (4) we obtain:
However, because electrical charges are highly accelerat-
⎛ 2π ⎞
ed at the open edge of the antenna, it has very strong ⎜ ZL + jZC tan λ ⎟
reactive and radiating near-field intensity. The antenna ZIN = ZC ⎜ ⎟ (6)
energy efficiency is very high and a transponder encoding ⎜ ZC + jZL tan 2π ⎟
⎝ λ ⎠
at 5-10 mm from the antenna requires a few milliwatts of
the Reader RF power. Shielding elements create losses in There are three conclusions of interest from equation (6).
the antenna near-field and change its distribution around
the antenna. Shielding reduces energy in the area of adja- 1. If TL characteristic impedance ZC meets the con-
cent transponders but works inefficiently for radiating dition:
near- field. A strong antenna electric field can potentially
activate the transponders in encoded transponder zone or ZC = ZL (7)
in following adjacent transponders zone (Fig. 5) and thus
this antenna requires RF power control to reduce this Then substitution of (7) in equation (6) gives:
field. The collision risk drives the Reader operational RF
power down to the level that is insufficient to activate ZIN = ZL (8)
transponders in the adjacent zones and significantly
decreases system power margin as illustrated by Antenna In reference to (8) the impedance ZIN is theoreti-
#1 in Figure 3. Magnetic field mostly concentrated near cally independent of TL length and equal to the
the grounded edge partly contributes to the transponder terminating load for any frequency. Although in
activating power. reality the bandwidth is limited by parasitic
effects associated with non-ideal TL components,
Impedance Bandwidth it can easily reach 5 to 6 GHz. In this case voltage
Antenna feeding port impedance match is achieved by standing wave ratio (VSWR) of the TL is about 1;
finding the appropriate point close to the grounded edge voltage along the whole TL length is equal to the
40 High Frequency Electronics
12. input voltage. The electric field strength distribu-
tion around the TL is also homogeneous.
2. If the TL length is a quarter-wavelength:
l =λ/4 (9)
Substituting ßl = π/2, from (5) and (9) in (6)
obtain:
ZC 2
ZIN ( f0 ) = (10)
ZL
The ability of TL to transform load impedance
(10) is widely used for impedance matching in the
vicinity of one particular operational frequency
(ƒ0).
3. If the TL length satisfies the condition:
l =λ/2 (11)
Substituting ßl = π, from (5) and (11) in (6) obtain:
ZIN ( f0 ) = ZL (12)
Equation (12) is valid for any impedance value ZC for Figure 7 · Antennas based on Terminated Non-
one particular frequency ƒ0. TL experiences a standing Resonant TL. (a) “Two-Wire” transmission line; (b) “Dual
wave with SWR ≥ 1 depending on how much impedance Microstrip” transmission line.
ZC differs from impedance ZL. In an extreme case for a
huge mismatch SWR >> 1, the voltage amplitudes near
the edges of a λ/2 wavelength TL are in anti-phase and mounting elements) from the platen roller back to the
can attain almost a double the input voltage value. This media roll. The antennas are very convenient for imple-
voltage amplification increases the electric field strength menting a transponder interrogation method known as
immediately adjacent to the TL and for SWR >> 1 is “encoding on the run” along the media feed direction. The
almost equivalent to the input power increase of up to 4 distance between the “wires” on the dielectric substrate is
times for the matched TL. 20-40 mm (Fig. 7(a)). The combined structure, “Dual
Microstrip” transmission line, is 45-60 mm in length with
Antennas Based on Terminated Non-Resonant TL two microstrips 20-40 mm apart (Fig. 7(b)).
The so-called Terminated Non-Resonant TL antennas
are presented by “Two-Wire” TL [25] (Fig. 7(a)) formed by Transponder Placement Boundaries
two PCB traces and by a combined arrangement of two Both antennas have an excellent selectivity outside of
microstrip transmission lines [26] (Fig. 7(b)). This group the targeted transponder zone (Fig. 5) to prevent commu-
of antennas utilizes the TL phenomena (8). For all anten- nications with adjacent transponders; however, the zone
nas based on terminated TL, their electrical charges slow- itself is much wider than a transponder width. Antennas
ly accelerate at the edges. Therefore, the antennas have a must be field upgradeable for different transponder form-
weak radiating near- and far-field intensity, while high factors and redesigned to adjust the transponder place-
current provides relatively strong reactive near-field. ment range (Fig. 1(b)). With these antennas a long pitch is
required to encode short Smart Labels.
Antenna Structural Feasibility
Both antennas, based on a highly technological PCB Encoding Field Intensity
fabrication process, have an orthogonal alignment of their Depending on permittivity of the dielectric substrate,
traces with the targeted transponder. Their structures antennas can have a width of traces approximately 1.5-3
take up to 45-60 mm in longitudinal length (including the mm either for the “Two-Wire” TL or for the “Dual-
October 2007 41
13. High Frequency Design
RFID ANTENNAS
Microstrip” TL to attain characteristic impedance of 100 Encoding Field Intensity
ohms. Because of the antenna-transponder orthogonal The microstrip TL base element for these antennas
orientation, the antennas form a small mutual static has a lower characteristic impedance ZC than the load
capacitance and have a loose coupling with transponders. impedance ZL and therefore a wider than non-resonant
The areas of the electric field strength for the “Two-Wire” TL conductive strip, which increases static capacitance
TL are not quite close to transponder’s most sensitive and a coupling with a transponder. The impedance mis-
edges. Both antennas have comparatively low power effi- match causes a wave reflection with standing wave ratio
ciency but could have a high RF power margin. The areas SWR >1 along the line and increases the electric field
of intensive electric field of the “Dual-Microstrip” struc- strength above the line. The reflection coefficient Γ is a
ture are positioned closer to the sensitive transponder complex voltage (current) ratio, which may be expressed
edges but the mutual overlapping area is small and the in terms of the antenna characteristic impedance and
coupling grade is still low. The electric field strength is load impedance (ZC and ZL) correspondingly:
homogeneous along both transmission lines and ampli-
fied by transformer usage. Magnetic field surrounding ZL − ZC
Γ= (13)
every TL is practically not contributing to transponders ZL + ZC
activation power.
Substituting (13) in (3) we obtain
Impedance Bandwidth
ZL
Both transmission lines are terminated by loads SWR = (14)
ZC
matching their characteristic impedances. They have
SWR ~1 over a frequency band that is much wider than 1 The equation (14) shows that an increase in ratio
GHz. The “Two-Wire” TL width W1 defines its character- between the load impedance ZL and the microstrip
istic impedance that is about 300 ohms. To satisfy the con- impedance ZC causes an amplification of SWR and makes
dition (7) TL is loaded by a 300 ohm resistor. An RF trans- stronger electric field above the TL. The impedance ZC is
former with impedance ratio equal to 6 is used to provide inversely proportional to the conductive strip width W2 or
the 50 ohm antenna port impedance match and anti- W3 (Fig. 8(a) and (b)). For both antennas the conductive
phase voltages. The combined structure—“Dual strip widths can be made comparable to the transponder
Microstrip” transmission line (Fig. 7(b)), loaded by two width and RF power margin can attain 3-6 dB level with-
100-ohm resistors R1, makes the characteristic out a significant expansion of the encoding range.
impedance of the antenna independent of the distance D. The quarter-wave TL antenna contributes to transpon-
It also uses an RF transformer with the impedance ratio der power delivery by electric field at one side of the TL and
of 2 for impedance matching and phase shifting. by magnetic field at the transponder’s center. The half-
wave TL antenna is twice as long, has double the mutual
Antennas Based on Terminated Uniform Resonant TL static capacitance with a transponder, and therefore main-
The second type of antennas is based on terminated tains an enriched coupling and encoding field intensity.
but mismatched TL. The so-called Terminated Uniform
Resonant TL antennas are demonstrated by the λ/4 (Fig. Impedance Bandwidth
8(a)) and the λ/2 (Fig. 8(b)) length of the uniform The geometries of λ/4 and λ/2 TL antennas, terminat-
microstrip TL. This group of antennas realizes TL phe- ed by mismatched loads, define their resonant frequency
nomena (10) and (12) respectively. Antenna port and consequently their bandwidth. The bandwidth ∆ƒ of
impedance is matched to the system impedance without the quarter-wave TL antenna can be obtained from [27],
additional matching network.
⎧
⎪ 4 ⎡ Γ 2 Z0 ZL ⎤⎫
⎪
Antenna Structural Feasibility ∆f = f0 ⎨2 − arccos ⎢ m
∗ ⎥⎬ (15)
⎪ π ⎢ 1 − Γ m ZL − Z0
2
⎥⎪
Both antennas are in parallel alignment with the tar- ⎩ ⎣ ⎦⎭
geted transponder and occupy a 20-30 mm interval
behind the printer’s platen roller. Applying equations for microstrip characteristic
impedance and strip width from [28], the bandwidth of
Transponder Placement Boundaries the quarter-wave TL antenna is calculated using equation
These antennas allow a printer to achieve a short (15) for the frequency 915 MHz as a function of the strip
transponder placement starting distance 10-15 mm and width for impedance ZL in the range of 2 to 8 ohms (Fig.
placement range 20-25 mm for transponders with dimen- 8(c)). The plot shows that the strip width W2 can be
sions 8 × 95 mm or 10 × 95 mm [11, 13]. The pitch for the increased up to 35 mm without violating the justified
labels is in the range of 40-50 mm. antenna bandwidth of 150 MHz.
42 High Frequency Electronics
14. Figure 8 · Antennas based on Terminated Uniform Resonant microstrip TL
for 915 MHz band. (a) λ/4 TL antenna; (b) λ/2 TL antenna; (c) λ/4 TL band-
width vs. width; (d) λ/2 TL antenna bandwidth vs. width.
Substituting the antenna length l = λ/2 in (6) for port impedance ZIN, for
the half-wave TL antenna the reflection coefficient Γ is:
(Z − ZL ) tan 4 θ + 4 ( Z0 ZL ) ( Z0 − ZL ) tan 2 θ
4 4 2 2 2 2 2
Γ=
0
⎢4 ( Z Z )2 + ( Z 2 + Z 2 )2 tan 2 θ ⎥ (16)
⎢
⎣ 0 L 0 L ⎥
⎦
where
f
θ = βl; θ = π
f0
For the maximum reflection coefficient Γm = 0.333 in (16) that corresponds
to SWR = 2, θm and the bandwidth ∆ƒ can be obtained,
⎛ θ ⎞
∆f = 2 f0 ⎜ 1 − m ⎟ (17)
⎝ π ⎠
where
fm
θm = π
f0
and ƒm corresponds to Γm.
Using equations for microstrip characteristic impedance and strip width
from [28], the bandwidth ∆ƒ from (17) of λ/2 wavelength TL antenna is plot-
ted versus strip width W3 (Fig. 8(d)) for ZL = 50 ohm and the frequency 915
MHz. In order to comply with the requirement of ∆ƒ = 150 MHz, the strip
width W3 of the half-wavelength TL antenna should not exceed 14 mm. This
bandwidth restriction limits the transponder placement range in the case
when printer design requires a wide transponder encoding area.
15. High Frequency Design
RFID ANTENNAS
Antennas Based on Terminated Tapered Resonant TL
Another sub-group of the second type of antennas is
the so-called Terminated Tapered Resonant TL antennas.
The design goal is to achieve for microstrip TL antennas
a relatively wide bandwidth and an increased grade of
coupling with transponders. This goal is accomplished by
implementing a method previously developed for band-
width enhancement of impedance matching TL trans-
formers. This method is based on the theory of small
reflections [24] applied to a tapered (non-linear) profile of
characteristic impedance for any TL. Antennas are pre-
sented by the λ/4 wave and the λ/2 wave non-uniform
microstrip TL.
Antenna Structural Feasibility
The width of the quarter-wave non-uniform
microstrip TL is tapered from W4 to W5 (Fig. 9(a)). The
edge widths of the half-wave non-uniform microstrip TL
antenna are W6 (Fig. 9(b)). Both antennas can be made
wider than the widths of uniform microstrip TL anten-
nas. The corresponding lengths of non-uniform
microstrip TL antennas are shorter than lengths of uni-
form ones because of the extension of the sides of the
tapered microstrip TL. The considered example is the
half-wave microstrip linear width (non-linear character-
istic impedance) taper TL (Fig. 9(b)). The width of the TL
varies linearly from 18 to 4.5 and back to 18 mm, the
dielectric constant of the substrate is 4.25, and the
height of the substrate and the length of the strip are 1.6
mm and 65 mm respectively.
Transponder Placement Boundaries
Terminated Tapered Resonant TL antennas can pro-
vide the same placement starting distance and placement
range compared to the Terminated Uniform Resonant TL
antennas with equally wide conductive strip. For an
extended transponder placement range the tapered con-
ductive strip can be made wider without sacrificing the
antenna bandwidth.
Encoding Field Intensity
Field distribution above the quarter-wave terminated
tapered TL antenna (Fig. 9(a)) covers only a part of the
targeted transponder thus delivering half the power of Figure 9 · Antennas based on Terminated Tapered
the half-wave TL antenna. Electric and magnetic field Resonant microstrip TL: (a) λ/4 TL antenna; (b) λ/2 TL
distribution of the half-wave terminated tapered TL antenna; (c) S11 parameter for λ/2 TL antenna dimen-
antenna (Fig. 9(b)) is concentrated at the most field sen- sions 4.5 × 18 × 65 mm.
sitive transponder areas. The antenna with linearly vari-
able width at the input end W6 = 18 mm maintains a
greater mutual static capacitance with the transponder Impedance Bandwidth
and provides a higher spatial selectivity than the uniform Like other terminated resonant TL antennas, the
TL antenna with the narrower conductive strip. The RF tapered TL antennas have their port impedance of 50
power margin can achieve 6 dB without a significant ohm without an additional matching network. In contrast
increase in the transponder encoding range. to the uniform TL, the λ/2 wavelength linearly tapered
44 High Frequency Electronics
16. width microstrip TL antenna has a widened bandwidth. Measured reflection
loss (S11) of an antenna with a conductive strip at the input end width W6 =
18 mm (Fig. 9 (c)) shows that its bandwidth exceeds 150 MHz. The taper
implementation for the λ/4 wave microstrip TL is not necessary for the band-
width enhancement unless dictated by other design reasons. The uniform λ/4
wave microstrip TL with a strip width W4 of up to 30 mm already has BW in
the range of 150 MHz (Fig. 8(c)). The importance of tapered λ/4 wave TL sec-
tions was shown by Young [29, 30] for a bandpass filter design. He demon-
strated that every second impedance step quarter-wave transformer replaced
with an opposite impedance step provides the equal input and output
impedances. It implies that the two parts of λ/4 wave tapered TL can be used
as building blocks for tapered λ/2 wave TL antennas.
It was shown by Collin [24] that reflection coefficient of tapered TL is:
( )
L
1 −2 jβz d
Γ IN ( f ) =
2∫
e ln Z dz (18)
0 dz
where z is the position along the taper, L is the taper length, Z is the taper
variation, Z0 represents the reference impedance at the input end of the taper.
There are numerous solutions for (18) available for several characteristic
impedance profiles (not strip width profiles) including exponential, linear, tri-
angular [27], Klopfenstein [31], and Hecken [32] in order to increase the band-
width. For example, for the exponential taper the input reflection coefficient
can be obtained [27]:
1 Z sin βL
Γ IN = Ln L e− jβL (19)
2 Z0 βL
This simplified solution (19) assumes TEM propagation mode for TL and
both its characteristic impedance and propagation coefficient are distance-
independent. Practically these parameters are changes along a line and prop-
agation wave is not quite TEM. The actual two-section combined TL length
then is shorter than λ/2 wavelength. For a maximum allowed reflection coef-
ficient in the pass band the taper profile introduced by Klopfenstein has the
shortest total length.
The reflection coefficient along a non-uniform TL can be described by a
non-linear Riccati-type differential equation [33], which does not have a gen-
eral analytical solution. The analysis can be based on numerical methods [34]
or performed using electromagnetic analysis software, such as HFSS from
Ansoft Corporation [35].
[This final part of this article series will appear in the nextissue of High
Frequency Electronics. All references will be listed at the end of Part 3.]
Author Information
Boris Y. Tsirline is the Principal Engineer at Zebra Technologies
Corporation in Vernon Hills, IL. He received a BS and MS degrees in RF &
Microwave Engineering from Moscow Aviation University, Russia in 1973 and
a PhD in EE from Moscow State University in 1986. He has been in the
Automatic Identification and Data Capture industry since 1995; first as an
RF Engineer involved in LF RFID design at TRW, then at Zebra Technologies
Corporation, where he has been since 1998. He can be reached by e-mail at
BTsirline@zebra.com.
18. High Frequency Design
RFID ANTENNAS
Figure 11 · Printer zones with stripline TL antenna.
enclosed by two ground planes, stitched by vias along the
other three sides of the antennas to organize electric
walls and reduce parasitic radiation. The inner layer pro-
file (Fig. 10 (a)) is a modified bow-tie shape with the width
linearly varied from 9 to 4.5 and back to 9 mm for the
stripline and from 10 to 3 to 10 mm for two strips of the
double-conductor TL antenna. The dielectric constant of
both substrates is 4.25 and their height is 3.5 and 6 mm
accordingly. The length of the single stripline TL is 64 mm
and for double-conductor line is 57 mm. The narrow cen-
ter part of the inner layer is positioned close to the active
edge of the TL in order to concentrate magnetic field at
the center of this edge. This position of the maximum
magnetic field usually corresponds to the center of a tar-
geted for encoding transponder and supports an optimal
energy transfer for the symmetrical antenna-transponder
alignment.
Transponder Placement Boundaries
The single stripline TL antenna with a thickness of
only 3.5 mm improves printer’s performance by providing
a short transponder placement starting distance from the
label’s leading edge. It enables individual encoding of
short Smart Labels with a short pitch comparable to the
transponders width (Fig. 1 (d)). The double-conductor
stripline TL antenna with a thickness of only 6 mm was Figure 12 · HFSS simulation of tapered stripline TL. (a)
developed for specific Smart Labels requiring a longer single conductor TL antenna—E field; (b) dual-conduc-
transponder placement range and higher antenna energy tor stripline TL antenna—E field; (c) S11 for dual-con-
efficiency than the single stripline TL antenna. ductor stripline TL antenna.
Encoding Field Intensity
Both antennas are in parallel alignment with target- coupling with a dipole type transponder antenna (Fig. 2).
ed transponders and are coupled with them by one open The capacitive coupling maintained by the stripline TL
long side edge. The electric field strength distribution antenna is relatively weak and permits very close posi-
simulated using Ansoft HFSS for the single stripline TL tioning to transponders. The stripline TL antenna is less
antenna (Fig. 12 (a)) and for the double-conductor spatially selective than the microstrip TL antenna but its
stripline TL antenna (Fig. 12 (b)) shows optimal shape for RF power margin is still about 3 dB without a significant
20 High Frequency Electronics
19. High Frequency Design
RFID ANTENNAS
bandwidth. They are shorter than λ/2. A solution for
reflection loss S11 and geometry calculations for the dou-
ble-conductor TL antenna are obtained by HFSS simula-
tion (Fig. 12 (c)) and verified empirically. For the above
samples the single stripline (Fig. 13 (a)) and double-con-
ductor stripline (Fig. 13 (b)) TL antenna S11 parameters
demonstrate bandwidths in excess of 150 MHz. By vary-
ing individual strip lengths the multi-conductor stripline
TL antenna enables further increase in bandwidth,
antenna sensitivity, spatial selectivity, power efficiency
and transponder placement range.
Conclusions
The article provided a thorough consideration of UHF
antennas for stationary and mobile printer-encoders.
Terminated TL antennas, while maintaining a consider-
able system power margin, can selectively interrogate
transponders without RF power suppression. Increased
available power delivered by the terminated resonant TL
antennas to the encoding interval tolerates usage of
transponders with large variation of their resonance fre-
quency and activation power threshold. Moreover,
enlarged bandwidth of terminated tapered resonant TL
antennas allowed using inexpensive RoHS PCB dielectric
materials with fairly wide deviations of permittivity,
thickness of a substrate and copper cladding.
The proposed miniature stripline TL antennas, with
their compressed encoding range, permit portable print-
er-encoders to work with short, densely spaced Smart
Labels. The stripline antennas geometry, their conductive
strip dimensions, and bandwidth obtained from Ansoft
HFSS modeling for RFID 915 MHz band, have been veri-
Figure 13 · Reflection loss S11 for stripline TL antenna fied empirically and found to be in a good agreement.
samples. (a) single conductor TL antenna: 4.5 × 9 × 64 Antenna analysis, mostly concentrated on microstrip and
mm; (b) dual-conductor TL antenna: 2× (3 × 10 × 57 stripline terminated TL, imposed no restrictions on the
mm). type of TL. Other TL structures, for example, the coplanar
waveguide or the slotline, may also be considered as
change in the encoding range. The double-conductor building blocks of antennas for close proximity RFID
stripline TL antenna in comparison with a single strip TL applications. Conclusively the stripline TL antenna is
has improved field intensity due to a higher SWR gener- judged as a vital component for RFID applications involv-
ated by an increased load. Its power efficiency, spatial ing equipment miniaturization or having spatial con-
selectivity and coupling grade with a transponder are also straints for an antenna installation.
increased due to a larger effective edge area. The double Besides RFID printer-encoders, there are many more
stripline TL antenna has an RF power margin in excess applications of compact UHF antennas, including access
of 6 dB. control (Homeland Security market), item-level RFID for
conveyors, testing small transponders during their high
Impedance Bandwidth volume manufacturing, quality validation in the Smart
The port impedance of a single conductor stripline TL Labels conversion process (Industrial market), and scan-
antenna is 50 ohms. For the double-conductor TL anten- ners of RFID Smart credit cards (Financial market). It is
na the port impedance of 50 ohms is realized without an believed that presented information on UHF antennas
additional matching network by connecting in parallel will be helpful in selection of UHF Printer-Encoder and as
two strips, each loaded by a 100 ohm resistor. Both anten- well as a tutorial guide for RFID newcomers. Although
nas utilize the same principles for bandwidth improve- the terminated TL antennas have low far-field radiation,
ment as other tapered TL antennas and have a widened they are still a source of UHF electromagnetic energy.
22 High Frequency Electronics
20. High Frequency Design
RFID ANTENNAS
Antenna mounting elements and nearby metal-plastic 9. D.M. Dobkin, S.M. Weigand, “UHF RFID and Tag
components can easily create a parasitic wave-guiding Antenna Scattering, Part II: Theory,” Microwave Journal,
structure for this energy transmission, causing excessive Vol. 49, No. 6, pp. 86-96, June 2006.
unintentional RF radiation that can interfere with the 10. (284) T. Breahna, D. Johns, “Simulation Spices
transponder encoding process. UHF terminated TL RFID Read Rates,” Microwaves and RF, pp.66-76, March
antennas have relatively low RF power efficiency in 2006.
exchange for their spatial selectivity and thus, represent 11. P.V. Nikitin, K.V.S. Rao, S.F. Lam, V. Pillai, R.
an improvement of energy conversion, and can be consid- Martinez, H. Heinrich, “Power Reflection Coefficient
ered as a subject for further research. Analysis for Complex Impedances in RFID Tag Design,”
Parts 1 and 2 of this series are available as PDF down- IEEE Transactions on Microwave Theory and Techniques,
loads from the Archives section of this magazine’s Web site: Vol. 53, No. 9, pp. 2721-2725, September 2005.
www.highfrequencyelectronics.com 12. C.A. Balanis, Antenna Theory: Analysis and
Design, 2nd Edition, John Wiley & Sons, 1996.
Acknowledgements 13. C. Capps, “Near field or far field?,” EDN Magazine,
The author would like to thank Zebra Technologies pp. 95-102, August 16, 2001.
Corporation and its associates K. Torchalski, Director of 14. I. Straus, “Loops and Whips, Oh My!,” Conformity,
RFID, and M. Schwan, System Manager for their helpful pp. 22-28, August 2002.
and productive discussions regarding UHF RFID Printer- 15. I. Straus, “Near and Far Fields—From Statics to
Encoders development, M. Fein, RF Engineer for his Radiation,” Conformity, pp. 18-23, February 2001.
HFSS counseling, and R. Gawelczyk, Engineering 16. B.Y. Tsirline, “Spatially Selective Antenna for Very
Technician for his outstanding support and assistance in Close Proximity HF RFID Applications-Part 1,” High
antenna fabrication, testing and evaluation. The author Frequency Electronics, Vol. 6, No. 2, pp. 18-28, February,
also would like to thank S. Kovanko, EE Engineer for 2007.
carefully reading parts of the manuscript. 17. J.D. Griffin, “A Radio Assay for the Study of Radio
Frequency Tag Antenna Performance,” MSEE Thesis,
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24 High Frequency Electronics
21. 16, 2005. at Automotive Electronics and Equip- spatially selective transponder
27. D.M. Pozar, Microwave ment Corp., Russia, developing mili- encoding modules used throughout
Engineering, 2nd Edition, John Wiley tary and aerospace electronic sys- the corporation divisions for RFID
& Sons, 1998. tems. He has been in the Automatic labels and cards printers. Dr. Tsirline
28. K.C. Gupta, R. Garg, I. Bahl, P. Identification and Data Capture holds three non-classified Russian
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Slotlines, Artech House, 1996. development of Zebra’s first HF RFID ous pending patents for RFID
29. L. Young, “The Quarter-Wave printer-encoder and established the enhancements. He can be reached by
Transformer Prototype Circuit,” IRE design methodology for HF and UHF e-mail at BTsirline@zebra.com.
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Author Information
Boris Y. Tsirline is the Principal
Engineer at Zebra Technologies
Corporation. He received a BS and
MS degrees in RF & Microwave
Engineering from Moscow Aviation
University, Russia in 1973 and a PhD
in EE from Moscow State University
in 1986. Before moving to the US in
1992, he served as a Director of R&D