Miniaturized Antenna Array with Low Correlation for Telemedicine
and Body Area Networks Applications
Haider Khaleel
1
, Chitranjan Singh
2
, Hussain Al-Rizzo
2
and Seshadri Mohan
2
1
Department of Engineering Science, Sonoma State University, Rohnert Park, California, U.S.A.
2
Department of Systems Engineering, University of Arkansas at Little Rock, Little Rock, Arkansas, U.S.A.
Keywords: Telemedicine, Antenna Array, Metamaterial, Multiple Input Multiple Output, Body Area Networks.
Abstract: The gain from Multiple-Input Multiple-Output (MIMO) techniques in wireless sensor networks equipped
with miniaturized sensor nodes cannot be fully exploited due to the difficulty encountered when placing
traditional multiple antennas with sub-wavelength physical separation. This paper presents a novel antenna
array design using µ-negative metamaterial (MNG) structures that lead to low correlation between antennas
when placed closely on a user’s body utilizing a telemedicine or a Body Area Network based system. The
obtained correlation coefficient of 0.04 is low enough for realizing full diversity gain from using such
antenna array on sensor nodes in a telemedicine WLAN environment. Furthermore, Bit Error Rate (BER)
simulation result for a 2×2 Alamouti diversity scheme in an IEEE 802.11a system is also presented. Design
and simulations are conducted using CST Microwave Studio which is based on the Finite Integration
Technique. Results suggest that the proposed design would be a suitable candidate for telemedicine and
BAN applications that are constrained by limited space.
1 INTRODUCTION
Telemedicine has evolved rapidly over the past
decade due to the increasing demand for remote
health monitoring of post-surgery patients, recovery
tracking, seniors, athletes, fire fighters and
astronauts (Fong et al., 2012). In telemedicine
systems, important health parameters such as body
temperature, blood pressure, and heart rate are
transmitted wirelessly to remote monitoring stations
(clinics, hospitals, etc…) (Algaet et al., 2013).
Obviously, a reliable wireless scheme which is
enabled by a use of antenna(s) is required for
optimal performance of such systems. In this
specific case, antennas are required to be small in
size, lightweight, robust with desired radiation
characteristics. They also need to be comfortable
and conformal to the shape of the body. Microstrip
antennas offer a favorable advantage in terms of a
close to hemi-spherical radiation pattern, i.e. radiates
away from the user’s body, thus, minimizes the
exposure to electromagnetic radiation. Furthermore,
they offer a low profile solution, low cost, and ease
of fabrication (Khaleel et al., 2010). However, this
class of antennas suffers from a very narrow
bandwidth, hence, a low profile antenna with a
directional radiation pattern and a wide bandwidth is
essential in telemedicine applications. Several
techniques have been proposed to achieve
directional radiation pattern by adding a cavity or a
shielding plane underneath the antenna, or using
absorbers (Haga et al., 2009). However these
techniques lead to either an unacceptable increase in
the antenna's height, or a more complicated
manufacturing process. In (Rowe et al., 2003), a
PEC reflector was inserted between a human head
and a folded loop antenna. This approach increases
the return loss and decreases the antenna’s
efficiency. In (Islam et al., 2009), a Single Negative
Metamaterial (SNG) is utilized to reduce the
electromagnetic exposure, though efficient, it leads
to a high profile system. Flexible Artificial Magnetic
Conductor (AMC) based antenna is proposed in
(Raad et al., 2013) for telemedicine application. A
polyimide based printed antenna is integrated with
an AMC ground plane which is utilized to minimize
the specific Absorption Rate (SAR) and the
impedance mismatch caused by the human tissues
proximity. Although the proposed design offers a
low profile solution, it is relatively large in some
applications.
On the other hand, MIMO techniques employing
39
Khaleel H., Singh C., Al-Rizzo H. and Mohan S..
Miniaturized Antenna Array with Low Correlation for Telemedicine and Body Area Networks Applications.
DOI: 10.5220/0004799000390044
In Proceedings of the International Conference on Biomedical Electronics and Devices (BIODEVICES-2014), pages 39-44
ISBN: 978-989-758-013-0
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
multiple antennas at one or both ends of a wireless
communication link have shown the potential to
reach higher spectral efficiencies (Chou et al., 2008),
(Abouda et al., 2006). By combining signals at
transmit antennas and receive antennas, MIMO
substantially improves either data rate using Spatial
Multiplexing (SM) or reliability using diversity
techniques. Space-Time Block Code (STBC), known
as Alamouti scheme (Alamouti, 1998) for two
transmit antennas, is the simplest technique with
linear receiver complexity to improve the reliability
of a wireless communication system. The capacity
and reliability of MIMO systems depend on the
Signal-to-Noise Ratio (SNR) and the correlation
properties among the channel transfer functions of
different pairs of transmit and receive antennas (Shiu
et al., 2000). One of the basic requirements to realize
the gains from MIMO systems is low correlation in
the effective channel. The correlation comes from
three sources, namely, the correlated fading channel,
correlation among the transmit antennas, and
correlation among the receive antennas. The
correlation between two antennas depends on the
coupling and isolation between them (Kyritsi et al.,
2003). The coupling in turn is dependent on the
physical separation between antennas and the
matching network.
Several papers including (Caban et al., 2007)
have previously presented analysis and simulation of
the effect of correlation between antennas on the
performance of Alamouti STBC scheme. The
Alamouti scheme starts losing performance as the
separation between the two antennas reaches
somewhere between 0.1λ to 0.3λ. The size of
traditional antenna is a major concern in placing
multiple antennas on a miniaturized sensor node.
The free space wavelength for the frequency band at
5.2 GHz, used in WLAN, is 5.77 cm. To obtain low
correlation for WLAN applications with physical
separation between antennas to be λ/2 = 2.88cm
is not difficult. However, application of MIMO in
wireless sensor networks, especially in medical
applications, requires multiple antennas to be placed
on tiny sensor nodes. To place multiple antennas
with physical separation of λ/2 on a sensor node is
very challenging using traditional antenna
technologies.
This paper presents a unique antenna design and
antenna array based on metamaterial that leads to
correlation coefficient of 0.42 without isolation
structure and 0.04 with proper isolation between
antennas. We present the design, radiation pattern of
antennas and BER performance of using them in a
WLAN system.
The design of the model of the proposed system
along with antenna correlation is introduced in
Section 2. The antenna design is presented in
Section 3 where both geometries and characteristics
of the antenna and the metamaterial structures are
provided. The error performance results of the
proposed antenna system are introduced in Section
4. Finally, we conclude the paper in Section 5.
2 SYSTEM MODEL WITH
ANTENNA CORRELATION
We considered a MIMO system with 2 transmit and
2 receive antennas having Alamouti STBC (Chou et
al., 2008) encoder that maps the two consecutive
symbols x
1
and x
2
to two antennas over two symbol
periods at the transmitter. The correlation coefficient
between the two transmit antennas Tx1 and Tx2 is α.
The transmitted signals pass through a Rayleigh flat-
fading wireless channel with a (2 × 2) channel
matrix H with element h
ij
= α
ij
exp (jθ
ij
) representing
the gain between transmit antenna j and receive
antenna i and additive white Gaussian noise
(AWGN). The correlation coefficient between the
two receive antennas Rx1 and Rx2 is β. The
decoding is based on linear combining of signals
received at the two antennas over two symbol
periods. This scheme performs maximum likelihood
detection of x1 and x2 using simple linear
combining. The discrete channel model for a (2 × 2)
MIMO system is given below in (1)-(3).
(1)
(2)
(3)
The correlation matrices between antennas at the
transmitter and receiver are given by C
T
and C
R
,
respectively in (3). The simple implementation of
linear combiner at the receiver would lead to a
minimal increase in the complexity of receiver at a
sensor node. The performance gain from using
Alamouti scheme has a direct relationship with the
coupling between the two antennas. The coupling
depends on the physical separation between the
antennas. When we consider a two transmit antennas
scenario, the correlation coefficient for a uniform
distribution of sources is given by (4). The
assumption of uniform distribution holds quite well
in an indoor environment. In (4), S
11
, S
12
, S
21
, S
22
, are
BIODEVICES2014-InternationalConferenceonBiomedicalElectronicsandDevices
40
scattering S-parameters for the antenna system. The
S-parameters takes into account the relationship
between voltage and current at the input and output
terminals of the antenna, the loading, and matching
network employed. The analytical derivation of S-
parameters is quite involved and requires several
approximations. The terms S
12
, and S
21
contain the
effect of mutual coupling between antennas. The
correlation coefficient can be computed either using
(4) after obtaining the S-parameters from full-wave
3-D electromagnetic simulation of antennas or
through measurement of antenna prototypes or using
(5) from the three-dimensional far-field radiation
pattern.
(4)
(5)
3 ANTENNA DESIGN
As mentioned previously, the reduction of mutual
coupling between closely-spaced antenna elements
is essential to the performance of MIMO systems
due to the fact that the mutual coupling affects the
phase and distribution of the current, input
impedance and radiation pattern in each antenna
element which significantly reduces the capacity of
the MIMO systems. Several techniques have been
reported to reduce the mutual coupling between
radiating elements in MIMO systems. Some of these
techniques are based on the use of Electromagnetic
Band Gap (EBG) structures (Ikeuchi et al., 2011),
defected ground plane (Caloz et al., 2004), and the
use of µ-Negative (MNG) structures. In (Bait-
Suwailam et al., 2010), MNG structures have been
used to reduce the mutual coupling between two
high profile monopoles, where the achieved
reduction in mutual coupling was 20 dB. In this
paper, we utilize MNG to reduce the mutual
coupling between two conformal micro strip
radiating elements sharing a common substrate
intended for applications that require compact space,
i.e, wearable medical devices and miniaturized
sensor nodes. When MNG structures are excited
with a specific polarization, an electric current is
induced through the loops of split ring resonators, as
a consequence, the structures act as magnetic dipoles
and an effective medium with a negative
permeability over a certain frequency range is
generated. As a result, the existence of real
propagating modes is prevented within this medium
(Pendry et al., 1999). This behaviour is utilized to
block the mutual coupling between the radiating
elements of the proposed antenna. The proposed
design consists of two elliptical shaped patch
elements with a major axis of 14 mm and a minor
axis of 4 mm placed on a 19 mm × 14.5 mm ×
0.85mm RO3006 substrate with a dielectric constant
of 6.15 backed by a ground plane. Two identical
elliptical radiating elements were designed to
resonate at 5.2 GHz. The inter-element separation
distance is 10.6 mm (0.18 λ), where λ is the free
space wavelength. Parametric study was performed
for the two coaxial feed locations to achieve optimal
impedance matching. The optimized locations are 8
mm along the major axis and 3 mm along the minor
axis for the first element, and 6 mm and 2.5 mm for
the second element. The return loss is -20 dB with a
-10 dB bandwidth of 50 MHz. A unit cell of a square
ring resonator is designed to provide an effective
negative permeability of -8 at 5.2 GHz, which
provides a reasonable isolation between the two
elements. Next, a set of 8 unit cells is arranged
horizontally between the radiating elements,
separated by 1.5 mm from each other. The unit cell
consists of two square metal strip inclusions with
opposite orientation printed on both sides of a 4.4
mm × 4.4 mm × 0.8mm RO3006 substrate. The gap
in each ring is 0.3mm. The height of the antenna
along with the metamaterial structures does not
exceed 6 mm which categorizes the design under
low profile antennas. The front view and side view
of the proposed antenna design along with
corresponding dimensions are depicted in Fig.1 and
Table 1, respectively.
Table 1: Dimensions of the proposed antenna system.
L 14.5 W
m
4.4
W 19 L
m
4.4
L
r
14 T 0.85
W
r
4 L
p
3.5
S 1.5 W
p
0.6
T
m
0.45 G 0.3
The antenna and MNG unit cell were designed and
simulated using both time-domain and frequency-
domain solvers of CST Microwave Studio which is
based on the Finite Integration Technique (FIT). The
simulated S-parameters for the proposed antenna are
shown in Fig. 2.
From the transmission coefficient S
12
, we
observe a large reduction in mutual coupling (-26
dB) at 5.2 GHz for the design with MNG structures
MiniaturizedAntennaArraywithLowCorrelationforTelemedicineandBodyAreaNetworksApplications
41
Figure 1: Two-element antenna array based on elliptical
patch radiating elements with MNG. Top view (top) and
side view (bottom).
Figure 2: Simulated S-Parameter for both cases (with and
without MNG).
compared to -4 dB for the design without MNG. We
also notice a slight shift in the resonance frequency
for the MNG case (around 20 MHz), which can be
compensated for by slightly adjusting the patch
length in order to keep the patch resonance
frequency identical in both cases. Moreover, we
simulated the correlation coefficient for both cases
(with and without MNG structures). The correlation
coefficient for the MNG case is 0.04 versus 0.42 for
the case without MNG. It is also worth mentioning
that the simulated correlation coefficient has been
extracted from the far-field analysis which is more
accurate than the S-parameter method (Blanch et al.,
2003). According to the S-parameters and
correlation coefficient analysis, the design with
MNG provides significant isolation between the
radiating elements compared to the design without
MNG with the same element spacing. The simulated
E-plane and H-plane combined far-field radiation
patterns at 5.2 GHz for the MNG case is presented in
Fig.3.
4 ERROR PERFORMANCE
SIMULATION
The setup for testing the performance of 2 × 2
Alamouti STBC scheme using the antenna array
proposed in Section 3 is based on WLAN IEEE
802.11a system with 5.2 GHz carrier frequency,
QPSK modulation scheme and simulation is
performed under flat-fading channel with Rayleigh
Fading coefficients. We used two transmit antennas
on one substrate at the transmitter and two receive
antennas on another substrate at the receiver. The
BER which is an essential parameter in
telecommunication systems, is the percentage of
transmitted bits that have errors relative to the total
number of bits received in a specific transmission
process.
The BER performance for a) uncorrelated
antennas at the transmitter (TX) as well as at the
receiver (RX), b) antenna array designed using
MNG structure (correlation coefficient at both TX
and RX is 0.04), and c) antenna array designed
without MNG structure (correlation coefficient at
both TX and RX is 0.42), proposed in Section 3, is
shown in Fig. 4.
We notice negligible performance loss for
antenna array from MNG structure as compared to
the performance for uncorrelated antennas.
5 CONCLUSIONS
In this paper, we presented a novel antenna array
designed with MNG structure for exploiting
diversity gain in a system where miniaturized sensor
devices are equipped with multiple antennas. The
negligible performance loss achieved by using the
proposed MNG based antenna array compared to
uncorrelated antennas renders the design suitable for
integration on medical sensor nodes used in
telemedicine systems that require miniaturization.
We presented design, radiation pattern of such
antennas and BER performance for such systems
BIODEVICES2014-InternationalConferenceonBiomedicalElectronicsandDevices
42
(a)
(b)
(c)
Figure 3: simulated (a) E-plane (YZ), (b) H-plane (XZ) and
(c) 3D radiation patterns for the proposed antenna design
at 5.2 GHz.
Figure 4: BER performance of (2 × 2) MIMO with
correlated transmit and correlated receive antennas.
operating in a WLAN environment. Results suggest
that the proposed design would be a reasonable
candidate for telemedicine and BAN applications
that are constrained by limited physical space.
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