Evaluation of Multi-Channel Communication for an Outdoor Industrial
Wireless Sensor Network
Ruan D. Gomes
1
, Emerson B. Gomes
2
, Iguatemi E. Fonseca
2
, Marcelo S. Alencar
3
and Cesar Benavente-Peces
4
1
Federal Institute of Para
´
ıba, Guarabira, 58051-900, Brazil
2
Federal University of Para
´
ıba, Jo
˜
ao Pessoa, 58058-600, Brazil
3
Federal University of Campina Grande, Campina Grande, CEP: 58401-490, Brazil
4
Universidad Politecnica de Madrid, Madrid, Spain
Keywords:
Industrial Wireless Sensor Networks, Multi-channel Communication, Wireless Channel Characterization,
Outdoor Industrial Environment.
Abstract:
This paper describes an experimental study which investigates relevant properties of multi-channel wireless
communications in an outdoor industrial environment. A testbed of IEEE 802.15.4 radios was developed in
order to evaluate the performance of the 16 channels defined by the standard, at all the nodes, simultaneously.
From the collected data, some relevant facts are discussed, such as the spatial variations in channel quality,
the differences in the characteristics of different channels, the link asymmetry, and the non-stationary charac-
teristics of the channel. The possible problems that can arise in the deployment of industrial wireless sensor
networks, based on the characteristics of the standards developed for this type of network, are described, as
well as some possible solutions.
1 INTRODUCTION
The use of Industrial Wireless Sensor Networks
(IWSN) to implement monitoring and control systems
has some advantages, such as low cost and high flex-
ibility to reconfigure the network. However, it is nec-
essary to deal with typical problems of wireless net-
works, such as noise, electromagnetic interference,
fading and high attenuation, due to the presence of
many objects and obstructions. Many industrial en-
vironments also present characteristics that make the
wireless channel non-stationary for long time peri-
ods (Agrawal et al., 2014).
Another problem is the link asymmetry. Some
protocols use acknowledgement per packet and, in
this case, it is necessary to guarantee a good quality of
communication in the two directions of the link. Spa-
tial variations in the channel quality can also occur in
IWSN. In (Watteyne et al., 2010), a coherence length
of 5.5 cm was found for IEEE 802.15.4 radios operat-
ing in the 2.4 GHz band. Hence, two nodes positioned
at a distance more than 5.5 cm apart from each other,
and using the same channel, can be considered uncor-
related, and thus the channel can present a high qual-
ity for one node, and a low quality for the other.
Some standards have been proposed in the last
years with a focus on industrial applications, such
as the WirelessHART and the ISA100.11a, which are
based on the physical layer of the IEEE 802.15.4 stan-
dard, but define their own MAC layer based on Time
Division Multiple Access (TDMA), to avoid colli-
sions, and reduce the power consumption. They also
use frequency hopping and blacklisting, to mitigate
the problems related to interference and fading.
More recently, the IEEE 802.15.4e standard was
released, which proposes solutions for applications
that require high reliability (e.g. industrial applica-
tions) (Guglielmo et al., 2016). Five modes of op-
eration are defined, but only the Time-Slotted Chan-
nel Hopping (TSCH), Deterministic and Synchronous
Multi-Channel Extension (DSME), and Low Latency
Deterministic Network (LLDN) modes have been ex-
plored in the literature, until now. In general, the
modes are based on TDMA or frequency hopping to
reduce collisions and mitigate the effects of interfer-
ence and fading.
60
Gomes, R., Gomes, E., Fonseca, I., Alencar, M. and Benavente-Peces, C.
Evaluation of Multi-Channel Communication for an Outdoor Industrial Wireless Sensor Network.
DOI: 10.5220/0006609200600066
In Proceedings of the 7th International Conference on Sensor Networks (SENSORNETS 2018), pages 60-66
ISBN: 978-989-758-284-4
Copyright © 2018 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
Even these new protocols define mechanisms to
deal with the unreliability problems of IWSN, it is
necessary to analyze the characteristics of the multi-
channel communication in such environments, in or-
der to properly deploy the network. For exam-
ple, when using channel hopping, the nodes usually
switch to a new channel before each transmission.
However, if a proper management of the blacklist is
not made, the network performance can be signifi-
cantly degraded (Grsu et al., 2016). Problems due to
the spatial variations in channel quality can also affect
the performance of beacon-based protocols.
In this paper, the characteristics of the 16 chan-
nels, defined by the IEEE 802.15.4 standard, are an-
alyzed, in an outdoor industrial environment, and for
eight different links. Based on the experimental re-
sults, possible problems that can arise in the deploy-
ment of IWSN, and some possible solutions are de-
scribed. The parameters of the log-normal shadow-
ing model for the environment were also determined.
Some studies have been performed in outdoor indus-
trial environments (Boano et al., 2010) to analyze the
impact of environmental aspects (e.g. temperature)
on link quality. The novel contribution of this paper
is the detailed analysis of the multi-channel commu-
nication in an outdoor industrial environment, which
may be important to design new techniques and pro-
tocols, as well as, more accurate simulation and theo-
retical models.
1.1 The Wireless Channel in Industrial
Environments
The industrial environment usually contains metallic
and mobile objects, such as robots, cars and people.
This influences both the large-scale and small-scale
fading. The power of the received signals depends
on the transmission power, the antennas gains, the
distance between transmitter and receiver and the ef-
fects caused by the environment. Even with the same
values for the aforementioned parameters, there is a
variation in the mean received power, depending on
the place where the measurement is performed, which
is known as log-normal shadowing. The log-normal
shadowing model has been used to model the large-
scale path loss and shadowing in industrial environ-
ments (Tanghe et al., 2008).
Besides path loss and shadowing, it is also nec-
essary to analyze the small-scale channel fading due
to rapid changes in the multipath profile of the en-
vironment, which is caused by the movement of ob-
jects around the receiver and transmitter. Experi-
ments demonstrated that, in industrial environments,
the temporal attenuation follows a Rice distribution.
In industrial environments the K factor of the Rice
distribution has a high value. For the experiments de-
scribed in (Tanghe et al., 2008), in industrial environ-
ments, K presented values between 4 dB and 19 dB,
while in office environments, values between -12 dB
and -6 dB were reported, as discussed in (Tanghe
et al., 2008). This can be explained by the open nature
of industrial buildings and the large amount of reflec-
tive materials. Thus, there are many time-invariant
rays and only a small part of the multipath profile is
affected by moving objects.
The IEEE 802.15.4 standard defines sixteen chan-
nels in the 2.4 GHz band, with 2 MHz of bandwidth,
and channel spacing of 5 MHz. Thus, the chan-
nels are highly uncorrelated. Experiments described
in (Amzucu et al., 2014) have found that changing
the communication channel can lead up to 30 dB dif-
ference in the received power, in an office environ-
ment. Varga et al. (Varga et al., 2016) performed ex-
periments for a short range, in an environment with-
out multipath, and with line-of-sight. In that experi-
ment, differences up to 10 dB were observed for some
channels. Thus, besides the variation in shadowing
observed depending on the place that the nodes are
positioned, there is also a variation in shadowing re-
garding the different channels. In the experiments de-
scribed in (Gomes et al., 2017), differences of up to
15 dB were found for different channels in an indoor
industrial environment, but only one link was ana-
lyzed.
In this paper, the aspects that influences the chan-
nel characteristics are discussed, based on experi-
ments performed in an outdoor industrial environ-
ments, and considering eight links simultaneously, to
analyze the temporal, spatial, and frequency varia-
tions in channel quality.
2 EXPERIMENT
METHODOLOGY
The sensor nodes used in the experiment include
an MRF24J40MA transceiver, with a transmission
power of 0 dBm, a PCB antenna with a gain
of 2.09 dBi, and a PIC18F46J50 micro-controller.
Eight sensor nodes (1 to 8), and a coordinator (9),
were placed in an outdoor industrial environment
(Fig. 1(a)), according to the schematic shown in
Fig. 1(b). The industrial unit is a water treatment and
injection station, which treats the water that comes
together with the oil from onshore oil fields and send
it, pressurized, to a group of platforms placed about
25 km from the station. During the experiments, the
station was operating normally, and the sensor nodes
Evaluation of Multi-Channel Communication for an Outdoor Industrial Wireless Sensor Network
61
Figure 1: (a) Environment where the experiments were per-
formed. (b) Schematic.
were placed alongside wired sensors that are currently
installed in the unit.
To allow the nodes to communicate using all chan-
nels, and without collisions, a protocol based on
TDMA and channel hopping was implemented. In the
protocol, the medium access occurs based on a slot-
frame structure, which repeats continuously, similar
to the slotframe defined on the TSCH protocol, but
with the use of beacons, transmitted by the coordina-
tor to synchronize the end-nodes in each cycle. The
temporal structure of the slotframe is shown in Fig-
ure 2.
Figure 2: Slotframe structure of the implemented protocol.
The slotframe repeats continuously and is com-
posed by 10 slots. In the first slot the coordinator
transmits the beacon in broadcast, and waits to receive
data packets that are transmitted by the end-nodes in
the following eight time slots (S1 to S8). There is an
inactive interval in the end of the slotframe, that is
used by the nodes to switch the channel and wait the
next slotframe.
When an end-node receives a beacon from the co-
ordinator, it waits until the time interval allocated to
it and performs the transmission of a data packet to
the coordinator. Each slot has a duration of 100 ms.
This protocol was developed to allow the characteri-
zation of the multi-channel communication for mul-
tiple links simultaneously, but it was not developed
taking under consideration any particular application.
In each slotframe a different channel is used, se-
quentially. To accommodate the use of channel hop-
ping in the transmission of the beacons, it is necessary
to have a mechanism to maintain the network syn-
chronized in case of failures during the reception of
a beacon. To do this, a timer is used in the end-nodes
to identify that a beacon has been lost. The coordina-
tor sends a new beacon for each 1 s, thus the timer is
configured to expire after 1.1 s. If a node receives a
new beacon before the timer expires, the timer is re-
seted. Otherwise, the node switches the channel, and
waits for the next beacon, which maintains the syn-
chronization.
After the reception of a beacon, the end-nodes ob-
tain the Received Signal Strength Indication (RSSI)
of the beacon, and transmit it back to the coordinator.
For each received packet at the coordinator, the RSSI
of the packet, as well as the RSSI of the beacon, sent
by the end-node, are uploaded to a computer through
a serial port. Thus, it is possible to analyze the spa-
tial variations in the channel quality, and asymmetry,
for all links. Even the individual RSSI samples are
obtained in different moments for the different nodes
and channels, due to the TDMA protocol, with the ac-
quisition of many samples over time, it is possible to
obtain the mean received power and the standard devi-
ation, and compare the characteristics of the different
channels for the different links.
Two experiments were performed, in two days,
with the nodes positioned in the same place. The net-
work operated for about 3 h and 10 h, in the first and
second days, respectively. The values of RSSI pro-
vided by the MRF24J40 transceiver varies between 0
and 255. For packets received with power between
-94 dBm (transceiver sensitivity) and -90 dBm, the
RSSI is equal to zero. However, despite this limi-
tation, it was possible to analyze the differences in
the characteristics of all channels, the spatial varia-
tions, and the non-stationary behavior of the wireless
channel, and drawn remarkable conclusions about the
SENSORNETS 2018 - 7th International Conference on Sensor Networks
62
Figure 3: Spatial variations in the channel quality for different nodes, in the first day of experiment.
multi-channel communication in outdoor industrial
environments.
3 RESULTS
Fig. 3 shows the mean received power, and the stan-
dard deviation, for each end-node, considering the ex-
periment performed in the first day. The mean re-
ceived power varies significantly, even for the adja-
cent channels and for the same end-node. For ex-
ample, for Node 1, the differences for some chan-
nels were higher than 10 dB (e.g. Ch 20 and Ch 25).
For Nodes 4 and 5, which were positioned in a place
without Line-Of-Sight (LOS) (see Fig. 1(b)), no com-
munication can be set, for example, when using Ch
22, due to a deep fading problem in the channel. All
channels shown a low quality for Node 5, but for
Node 4 some channels presented high quality, such
as the Ch 17. Deep fading problems have also oc-
curred for some other nodes and channels, in which
the number of packets received was very low.
From Fig. 3 it is also possible to analyze the spa-
tial variations in the quality of the channels. The val-
ues of received power for Nodes 3 and 7 are analyzed
in detail for two different channels. These nodes were
positioned at nearly the same distance to the coordina-
tor, and with a 1.6 m of difference in the height. The
Ch 17 presented a high quality for Node 3, but the
quality was significantly lower for the Node 7. On
the other hand, the Ch 21 presented a high quality
for Node 7, but a low quality for Node 3. The re-
ception power in the two directions of the links are
shown. There is a high correlation between the re-
ceived power in both directions of the links, but with
a small difference in the mean values. When the re-
ceived power is near to the sensitivity threshold of the
transceiver, such as is the case of Ch 21 for Node 3,
this small difference can provoke an asymmetry in the
link quality.
Hence, it is difficult to guarantee a good Quality of
Service (QoS) for all nodes when only one channel is
used in the whole network, such as in the MAC proto-
cols defined by the IEEE 802.15.4 standard. Even for
the new standards defined for IWSN, some problems
can arise due to the spatial variations in channel qual-
ity. In the LLDN mode, TDMA is used to avoid colli-
sions, with a star topology, to achieve very low laten-
cies (Anwar et al., 2016). However, only one channel
is used for all end-nodes. One possible solution is the
use of multiple sink-nodes, using different channels.
When the channel being used by an end-node starts
to present low quality, that node can switch to another
channel and communicate with a different sink. How-
ever, some mechanism to estimate the link quality in
real-time (Gomes et al., 2017), and a specific syn-
chronization mechanism needs to be developed. The
protocol described in (Patti and Bello, 2016) uses a
tree topology and multi-channel communication for
LLDN networks, with adaptive channel selection, but
the same channel is allocated to all nodes in the sub-
network, and spatial variations in channel quality can
also occur inside the same sub-network.
Even for protocols that use channel hopping or
channel adaptation, some problems may arise. For
example, the TSCH, WirelessHART, and ISA100.11a
Evaluation of Multi-Channel Communication for an Outdoor Industrial Wireless Sensor Network
63
Figure 4: Comparative results between the two days of experiment.
standards use TDMA and channel hopping. In this ap-
proach, all the channels can be used by the end-nodes
to perform communication. However, the blacklist
needs to be properly managed in order to achieve a
good QoS in the network. In (Du and Roussos, 2013)
it was observed that the larger the size of the black-
list, the better the communication performance. This
result corroborates with the results presented in (Grsu
et al., 2016). However, this type of behavior only oc-
curs if an adequate monitoring of the quality of the
channels is performed, in order to properly configure
the blacklist.
One problem is that, when a channel is black-
listed, all the nodes stop using that channel. In the
result shown in Fig. 3, Ch 21 presented a low quality
for four end-nodes and could be put on the blacklist.
However, this channel is the one that presents the best
quality for Node 7, and also presents good quality for
Nodes 1 and 6. Thus, the QoS for these nodes can de-
crease once this channel is put on the blacklist. When
the quality of the channel is affected by external in-
terference, as considered in (Du and Roussos, 2013),
putting a channel in the blacklist for all network can
be a good solution, but the challenge is higher when
spatial variations in channel quality, due to multipath
problems, affect the links.
The DSME mode employs channel hopping or
channel adaptation, during the contention free peri-
ods. When using the channel adaptation, a pair of
nodes can communicate using the same channel for
a long time period, and a channel switch only occurs
when the channel in use starts to present low quality.
Thus, it is possible to deal with the spatial variations
in the quality of the channels, since the decision about
the channel to be used can be made based on the qual-
ity of a specific link between a given pair of nodes.
The implementation of this procedure is not defined
by the standard (Guglielmo et al., 2016). The DSME
networks use beacon packets, transmitted in broad-
cast using a single channel. Sometimes it is difficult
to pick one channel that presents good quality for all
nodes in the network. Deep fading problems can also
occur, and some nodes can remain disconnected for a
long time. While the use of channel adaptation can be
a good solution for unicast data packets, channel hop-
ping can be a good solution for packets transmitted in
broadcast.
Fig. 4 shows a comparison between the results ob-
tained in the two days. Fig. 4(a) shows the mean re-
ceived power, and the variance for all channels. The
variance was high in all channels, due to the differ-
ences in the channel characteristics for the different
links. Fig. 4(b) shows the mean received power, and
the variance, for the eight different links, consider-
ing the 16 channels. There is also a significant vari-
ance, due to the differences in the characteristics of
the different channels in each link. Fig 4(c) shows the
results for a specific node (Node 2) and for all chan-
nels in both days. It is worthy to notice that while
some channels had an increase in quality, the quality
of other channels decreased significantly in the sec-
ond day. For example, the Ch 18 presented a good
quality in the first day for Node 2, but presented a
deep fading problem during the second day. Fig 4(d)
shows the results for a specific channel (Ch 21), and
for the eighth different links. It is possible to notice
SENSORNETS 2018 - 7th International Conference on Sensor Networks
64
that the characteristics of the channels vary differently
for the different nodes. For example, the Ch 21 pre-
sented a high quality for the Node 6 in the first day,
but a low quality in the second day. On the other hand,
it presented a higher quality on the second day for the
Node 2.
Some abrupt variations in the reception power for
some nodes and channels were also observed during
the second day (Fig. 5). This behavior was also ob-
served in (Agrawal et al., 2014) for an indoor indus-
trial environment. The quality of the Ch 24 decreased
after some time for Node 7, while at the same time the
channel showed an increase in its quality for Node 6.
Again, a high correlation between the two directions
of the links was observed, but with a small difference
in the mean value of each direction of the link.
Figure 5: Abrupt change in channel characteristics.
The chart in Fig. 6 shows the path loss (L(d)) for
a distance (d) between transmitter and receiver. The
values obtained for Node 1 were used as reference
(d
0
= 16.5 m). From this experiment, the path loss
exponent (n), the shadowing deviation (σ), and L(d
0
)
were obtained, to be applied in the log-normal shad-
owing model. Fig. 6 shows the curves of the model
for three different scenarios: with all nodes, with the
LOS nodes (Nodes 3, 6, 7 and 8), and with the NLOS
nodes (Nodes 2, 4, and 5). Node 1 was considered in
both cases as the reference. Table 1 shows the param-
eters for the three scenarios. These values can be used
to simulate outdoor IWSN.
To allow an accurate simulation, it is important
to consider all the aspects and conclusion discussed
in this paper, and also nodes with LOS and NLOS,
with different parameters for the path loss and shad-
owing. Also, the level of shadowing in each channel
for the different links need to be modified over time.
Sometimes abrupt changes can occur in the charac-
teristics of the channel, and the modifications occur
differently for the different channels and nodes, and
the protocols for IWSN need to be capable to dealing
with these modifications to maintain a good QoS over
time.
Table 1: Parameters for the log-normal shadowing model.
Path Loss
Exponent (n)
Shadowing
Deviation (σ)
L(d
0
)
All Nodes 2.00 4.53 dB 81.182 dB
LOS Nodes 2.43 4.54 dB 78.351 dB
NLOS Nodes 4.03 4.98 dB 80.352 dB
4 CONCLUSIONS
This paper describes a set of experiments to evalu-
ate and characterize the performance of multi-channel
communications in an outdoor IWSN. Relevant char-
acteristics of the wireless channel were described,
based on the experimental results. Some problems
that can occur in the deployment of an IWSN, as well
as some possible solutions, are discussed in the paper,
considering the characteristics of the wireless channel
in the environment under study, and the characteris-
tics of the protocols that are used to implement the
IWSN. The parameters of the log-normal shadowing
model were also obtained. The information contained
in this paper can be used to allow the implementation
of new techniques and protocols for IWSN, as well as
more accurate simulation models.
Based on the characteristics of the wireless chan-
nel that were observed in the experiments, some fu-
ture works can be outlined, such as the design and
implementation of mechanisms for dynamic config-
uration of the blacklist in protocols that use fre-
quency hopping, to deal with the time and spatial
variations in the quality of the channels. The use
of link quality estimators to monitor the quality of
the links continuously can be useful to improve the
blacklist management. Other alternative is the use of
channel adaptation mechanisms, in which the nodes
use only one channel to communicate, but the chan-
nel is changed whenever the quality of the channel
in use is below a certain threshold. All these as-
pects will be investigated in future works, as well
as new experiments in other types of outdoor in-
dustrial environments will be performed. The data
generated during the experiments are available at:
https://github.com/ruandg/ExpIWSNoutdoor.
Evaluation of Multi-Channel Communication for an Outdoor Industrial Wireless Sensor Network
65
Figure 6: Relation between the path loss and the distance between transmitter and receiver.
ACKNOWLEDGEMENTS
The authors would like to thank the support of the
Institute for Advanced Studies in Communications
(Iecom), the Brazilian Council for Research and De-
velopment (CNPq), the Coordination for the Improve-
ment of Higher Education Personnel (CAPES), and
Petrobras.
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