A Simultaneous Network Search Scheme for Fast Roaming and
Handover of the Simultaneous Voice and LTE Mobile Devices
Minsuk Ko, Myungchul Kim and Sungwon Kang
Korea Advanced Institute of Science and Technology (KAIST), Daejeon, South Korea
Keywords: Fast Roaming and Handover, Simultaneous Voice, LTE.
Abstract: Most of the countries in the world are currently providing 2G or 3G mobile communication services with
limited coverage of LTE services. Therefore when an LTE service user moves into or around such
countries, the LTE terminal needs to roam or handover to 2G or 3G network for service quality. For LTE
terminals that can be connected to 3GPP Legacy (such as GSM, UMTS, and HSPA) and CDMA networks,
it normally takes more than 2 minutes to select one of several candidate networks for roaming and 20
seconds to 2 minutes to handover to other networks before getting out of the LTE service area, which is
considered very long by many LTE users. This paper proposes a scheme for fast roaming and handover that
simultaneously searches for multiple networks with a Dual RF LTE terminal for both voice and data
communication. In our experiment with the simultaneous network search implemented in a commercial
LTE terminal with dual RF, the network selection time for roaming was reduced by 15% to 40% and the
delay time for handover in LTE network was reduced by 90%.
1 INTRODUCTION
Generations of mobile communication technology
include the 1st Generation (1G) to the 4th
Generation (4G) in accordance with data
transmission speeds which have been classified by
International Telecommunication Union (ITU).
Only voice communication was available in
analog 1G. Data transmission became possible in the
2nd Generation (2G), which was the first digital
mobile communication technology. 2G includes
Global System for Mobile communications (GSM)
in Europe and Code Division Multiple Access
(CDMA) in the U.S.A. region. However, their data
transmission speed was 14.4 to 64 Kbps so that only
SMS and email could be possible.
3G has opened the real mobile communication
era. The 3rd Generation Partnership Project (3GPP)
in the European region commercialized Wideband
Code Division Multiple Access (WCDMA), which
includes Universal Mobile Telecommunications
System (UMTS) and High Speed Packet Access
(HSPA). On the other hand, the 3rd Generation
Partnership Project2 (3GPP2) in the U.S.A. region
commercialized the Code Division Multiple Access
(CDMA2000), which includes 1xRTT and
Evolution-Data Only (EV-DO).
While 3GPP was commercialized as the 4G
technology with the Long Term Evolution (LTE) in
Korea, U.S.A., etc., 3GPP2 gave up developing a 4G
technology. Although another 4G technology,
Mobile WIMAX, was developed, it is used only in a
small number of countries. Therefore, LTE is a
predominant 4G technology. However, currently just
a few countries including Korea, U.S.A., etc., have
started providing LTE and the rest of the countries
are still providing 2G or 3G only. Therefore, when
the LTE users move into the countries with no LTE
networks, voice and data services must be provided
through 2G or 3G. Also, even in the countries with
LTE network, its coverage may not be as wide as
that of 3G, in which case LTE terminals need to
handover to 3G network when LTE network is not
available.
Since mobile communications are evolutionary
technologies, a mobile device for a new wireless
network should support the existing ones. Also, the
limited coverage of a new wireless network calls for
fast roaming and handover between different
wireless networks as they are essential for service
quality, which operators and terminal manufacturers
all aspire to provide (Tu, 2013).
One approach for fast roaming and handover is
to directly exchange necessary information between
36
Ko M., Kim M. and Kang S..
A Simultaneous Network Search Scheme for Fast Roaming and Handover of the Simultaneous Voice and LTE Mobile Devices.
DOI: 10.5220/0005037600360043
In Proceedings of the 11th International Conference on Wireless Information Networks and Systems (WINSYS-2014), pages 36-43
ISBN: 978-989-758-047-5
Copyright
c
2014 SCITEPRESS (Science and Technology Publications, Lda.)
two networks. Another is to make a mobile device
search for available network fast, which can save
cost and time compared to the former approach. In
particular, since LTE terminals with a Dual RF
supporting existing wireless networks can be used
for simultaneous network search, the network
selection time for roaming and handover can be
significantly reduced.
1.1 CS Domain and PS Domain
A network comprises of the access network and the
core network. The access network is used for users
to access to the core network and the core network
provides various services including telephony to the
users who are connected through the access network.
The core network in turn consists of the Circuit
Switched (CS) domain, which is for communications
such as voice and SMS, and the Packet Switched
(PS) domain, which is for data communication.
In the CS domain, one exclusive physical route
between a caller and a callee is established until a
telephone call connection is terminated. The route is
maintained during communication so that the service
is stable and delay is short. On the other hand, in the
PS domain, a physical route is established only when
data is transmitted in the form of packets and then
the route is disconnected until next packets are
created to send. Network resources are used only
when data are transmitted so that the resources are
managed efficiently but delay may be longer than in
the CS domain.
1.2 Simultaneous Voice and LTE
Since the LTE technology supports only the PS
domain, various technologies were proposed for
voice communication, for example, Voice over LTE
(VoLTE), Circuit Switched Fallback (CSFB), and
Simultaneous Voice and LTE (SVLTE).
For VoLTE, IP packet is used for voice
communication in LTE network. However, the LTE
service area is still not sufficiently wide and there
are interoperability issues among VoLTE services
by different providers.
CSFB is a technology used by the LTE service
provider who was a 3GPP 3G service provider. It
provides 3G WCDMA or GSM for voice
communication by disconnecting LTE if
communication is needed during data
communication. Since LTE is disconnected during
voice communication, both voice and data
communications are performed in 3G network
(Tanaka, 2009). Paper (Tu, 2013) studies the inter-
play of voice and data in operational LTE networks
and assesses how the popular CSFB-based voice
service affects the IP-based data sessions in 4G LTE
networks, and vice versa. Their findings reveal that
the interference between them is mutual.
SVLTE is a technology used by the LTE service
provider who was a 3GPP2 3G service provider.
Unlike CSFB, SVLTE can simultaneously transmit
data through LTE when voice communication uses
CDMA network (Qunhui, 2011). Terminal for this
service uses a dual RF: one RF to acquire and
register to the 1xRTT CDMA network for voice and
the other to acquire and register to the LTE network
for data communication. With a dual RF, data packet
can be transmitted in the LTE network while voice
communication is using the 1xRTT network and the
terminal can separately register to LTE and CDMA
networks by using different band classes. LTE
terminal using a dual RF has two modems, which
are connected to separate RF transceivers and
antennas for communication to networks: one
modem for data communication using LTE and
3GPP Legacy and the other for voice
communication using CDMA. Each modem can
communicate with the other using message passing.
1.3 Network Registration Procedure
The general procedure for mobile communication
terminal to register to a network has three steps as
follows: In Step 1, a mobile terminal acquires time
and frequency synchronization of the base station
using information such as frequency list, mobile
country code, and mobile network code in the SIM
card. In Step 2, the mobile terminal receives network
information that is periodically broadcasted from
network after successfully performing Step 1. The
network information, which is broadcasted by the
base station, includes network type, mobile country
code, and basic information for network connection.
In Step 3, the mobile terminal performs a
registration procedure to the selected network after
successful execution of Step 2. In this procedure,
Steps 1 and 2 are performed by the terminal itself
without assistance of the base station as the network
can recognize the terminal only in Step 3. In general,
the most time consuming of these steps is Step 1 as
it acquires time and frequency synchronization.
2 CONVENTIONAL NETWORK
REGISTRATION
This section introduces the conventional network
registration procedure and analyzes the conventional
roaming and handover.
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2.1 Conventional Network Registration
Procedure
In the conventional network registration procedure
depicted in Figure 1, the terminal first tries to
acquire time and frequency synchronization. If the
terminal fails to acquire time and frequency
synchronization, the network is considered to be
unavailable. If the terminal acquires time and
frequency, it tries to obtain network information that
is broadcasted by the network periodically. If the
terminal fails to obtain network information, the
network is considered to be unavailable. If the
terminal obtains network information, it tries to
register to the relevant network. If the terminal fails,
the network is considered to be unavailable. If the
terminal registers to the network, the network
registration has been successfully completed.
In general, service providers based on LTE and
CDMA network select a network registration
method for roaming and handover of SVLTE
terminal. Therefore, network registration is
performed in the order of LTE, HSPA, 1xRTT,
UMTS, and GSM. A mobile terminal searches for an
available network in this order so it searches for
LTE, HSPA, and 1xRTT networks sequentially prior
to searching for UMTS and GSM networks.
Figure 2 shows the conventional network
selection procedure. The terminal sets network
priority for search. The priority depends on the
policies of service providers. Network search for
registration is performed according to the priority
order. The conventional network registration
procedure is shown in Figure 1. If network
registration fails, it tries again for a next network
according to the priority order. If the terminal
registers to a network, the network selection has
been successfully completed.
When the priority is in the order of LTE, EVDO,
and UMTS and only UMTS network is available, the
terminal tries search in that order and then finally
registers to UMTS network.
Handover from LTE network to CDMA network
is important when the LTE coverage is not wider
than the CDMA coverage. Since the terminal
performs the procedure for handover to another
network before getting out of the LTE service area,
seamless data service can be provided to users even
though the data transfer rate becomes somewhat
lower.
LTE network may inform available CDMA
network information to a terminal for efficient
handover. CDMA network information, which LTE
network provides, includes frequency information
Figure 1: Conventional network registration procedure.
Start
Set network priority to
search
Network registration
procedure (Fig.1)
Registration
completed?
Success
Yes
No
Try again for next
network in priority order
Figure 2: Conventional network selection procedure.
and pseudo noise code (PN Code) of its neighboring
base stations. A terminal measures the signal
strengths of the neighboring CDMA base stations
periodically even though it is registered to LTE
network. Therefore, a terminal performs handover
from LTE to CDMA network based on the measured
WINSYS2014-InternationalConferenceonWirelessInformationNetworksandSystems
38
Figure 3: Conventional network registration procedure.
signal strength before getting out of the LTE service
area.
However, LTE network may not inform
available CDMA network information to a terminal.
In this case, the terminal selects CDMA network
after getting out of the LTE service area.
Because the service area of CDMA network is
wider than that of an LTE network, the terminal
does not perform handover from CDMA to LTE
network. However, since LTE has a higher priority
than CDMA, handover occurs when the terminal
searches for an LTE network periodically while it is
registered to CDMA network.
2.2 Time Analysis of the Conventional
Roaming and Handover
In this analysis, the time taken for network
registration for roaming was measured using an LTE
terminal with Exynos application chipset (Tanaka,
2009) operating in LTE, CDMA (EVDO, 1xRTT),
and 3GPP Legacy while signals of LTE and CDMA
networks are not available and only HSPA network
is available.
Figure 3 shows experimental results of network
registration for conventional roaming. Network
Terminal
LTE
network
3GPP Legacy
network
CDMA
network
Try to acquire synchronization of LTE network
1. LTE network search/registration
Try to acquire synchronization of CDMA network
Success of synchronization acquisition of LTE network
Network priority order:
1. LTE
2. CDMA (EVDO/1xRTT)
3. 3GPP Legacy (HSPA/UMTS/GSM)
LTE network information acquisition
Try LTE registration
Success of LTE registration
Success of synchronization acquisition of CDMA network
CDMA Network information acquisition
2. Out of LTE coverage
CDMA Network Registration procedure
Success of CDMA Network Registration
Figure 4: Conventional procedure for handover from LTE
to a CDMA network.
priority for search is in the order of LTE, CDMA
(EVDO/1xRTT), and 3GPP Legacy. The terminal
tries to acquire time and frequency synchronization
from the LTE network with the highest priority first.
Also it is confirmed that there is no available LTE
network by failure of its acquisition, which took 1 to
2 seconds. The terminal tries to acquire time and
frequency synchronization from CDMA network
based on the network priority order. However, it is
confirmed that there is no available CDMA network
by failure of acquisition of time and frequency of
CDMA network which took 140 seconds. Finally,
the terminal acquires time and frequency
synchronization of UMTS network with the lowest
priority. Then it receives network information which
UMTS network broadcasts periodically and then
completed registration which took 25 seconds.
Handover time from LTE to CDMA was
measured in the area that both LTE and CDMA
networks are available. LTE network doesn't provide
information of CDMA network to a terminal. The
signal strength of LTE was gradually reduced while
it is registered to LTE network with a higher
priority. We measured the time from when LTE
signal was reduced to the extent that normal service
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is not possible to when LTE terminal with Exynos
application chipset completes handover to CDMA
network.
Figure 4 shows the conventional procedure for
handover from LTE to CDMA network. The
terminal completes registration to the LTE network
with the highest priority. The strength of LTE signal
was gradually reduced for the experiment. Since the
terminal doesn't receive CDMA network information
from LTE network, it doesn't search for a CDMA
network while it is registered to LTE network. When
the strength of LTE signal is reduced to the extent
that normal service is impossible, the terminal
begins to search for a CDMA network. It took 30
seconds to 2 minutes to acquire time and frequency
synchronization of CDMA network, receive network
information, and complete registration.
The terminal performs search based on the
frequency list stored in the SIM card. The search
time varies according to the location in the
frequency list. That is, if the frequency, which is the
same as network frequency, is ahead in the
frequency list, it takes approximately 30 seconds
and, if it is behind, it takes up to 2 minutes.
The terminal searches for networks in the order
of LTE, EVDO, 1xRTT, UMTS, and GSM as
described in Section 2. In the roaming area where
neither LTE nor CDMA network is available, the
terminal can acquire UMTS or GSM network, in
which roaming is possible only after completion of
search for LTE, EVDO, and 1xRTT network. The
search time depends on the frequency of search and,
in general, several minutes are required.
Usually the terminal performs handover to
another network before getting out of the LTE
service area. However, if the signal strength from
the LTE network is reduced abruptly or LTE
network doesn't inform available neighboring
network information, the terminal is disconnected
from the LTE network, in which case it should
perform an initial network selection to acquire
CDMA.
3 SIMULTANEOUS NETWORK
SEARCH SCHEME
We propose a simultaneous network search that can
replace the conventional sequential one. The
proposed search scheme reduces network search
time for roaming and handover by a simultaneous
search for multiple networks.
Figure 5: Proposed network registration procedure.
3.1 Scheme to Reduce Time for
Network Registration in Roaming
and Handover
For SVLTE terminal, two RFs are used at the same
time for both voice and data. Therefore, if two
networks can be searched simultaneously by using
both RFs, the search time can be reduced. In
particular, since networks with a lower priority for
roaming and handover can be searched while high
priority networks are searched, the search will be
very efficient.
As with the network registration procedure in
Section 1.3, Steps 1 and 2 for acquisition of time and
frequency synchronization and reception of network
information are performed by the terminal itself
without assistance of the base station. Therefore, it is
possible that LTE terminal performs Steps 1 and 2 to
both of LTE and CDMA networks simultaneously.
WINSYS2014-InternationalConferenceonWirelessInformationNetworksandSystems
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Figure 6: Proposed network selection procedure.
Figure 5 shows the proposed network
registration procedure. The terminal tries to acquire
time and frequency synchronization of network. If
the terminal fails to acquire it, the network is
considered to be unavailable. If the terminal
succeeds, it tries to receive network information that
is periodically broadcasted by the network. If the
terminal fails to receive network information, the
network is considered to be unavailable. If the
terminal receives network information, it checks
whether the selected network has the highest
priority. If the selected network doesn't have the
highest priority, the terminal just waits for network
registration. If the selected network has the highest
priority, network registration is performed.
Figure 6 describes the proposed network
selection procedure using the UML activity diagram
(Object Management Group, 2011) to explicitly
show parallelism. The terminal first sets network
priority for search. The priority depends on the
policies of service providers. The order used in this
paper is LTE, CDMA, and 3GPP Legacy. The
terminal tries to register to LTE network with the
highest priority and to CDMA network
simultaneously. If the terminal registers to LTE
network, the network selection reaches the “LTE
network registration successful” state and
terminates. If the terminal fails to register to LTE
network, it tries to register to 3GPP Legacy network.
This procedure is performed while CDMA network
registration is performed as in Figure 5. So if the
terminal that has currently registered is the highest
priority one – LTE network, then it completes the
registration process. Otherwise it goes to the "Wait
for registration" state. Then if and only if when LTE
registration is not successful, it checks whether
CDMA network information has been received. If
the terminal has received CDMA network
information, it registers to CDMA network and
network selection terminates.
If the terminal hasn't received CDMA network
information, it checks if network information from
3GPP Legacy network has been obtained. If it has,
the terminal registers to 3GPP Legacy network and
network selection terminates. Otherwise, the initial
selection of LTE is resumed.
LTE network may not inform available CDMA
network information to a terminal. In this case, the
terminal selects a CDMA network after getting out
of the LTE service area. In this case, it takes the
terminal the same amount of time as the initial
network selection to obtain available CDMA
network. While a terminal is registered to LTE
network, it measures the signal strength of the
network periodically in order to reduce the network
selection time. If LTE signal is lower than a fixed
level, it begins to search for a CDMA network
regardless of whether the available network
information from the LTE network is received.
When a CDMA network is found, time and
frequency synchronization and network information
acquisition are performed except for its network
registration. If the signal strength of LTE network is
not high enough for normal service, it begins
registration to the CDMA network that it already
selected.
3.2 Roaming and Handover Time
Analysis for the Proposed Scheme
The time required for roaming was measured using
an LTE terminal that uses the Exynos application
chipset (Tanaka, 2009) and supports LTE, CDMA
(EVDO, 1xRTT), and 3GPP Legacy while signals of
LTE and CDMA networks are not available and
only HSPA network is available.
Figure 7 shows experimental results with the
proposed roaming scheme. Network priority for
search is in the order of LTE, CDMA
(EVDO/1xRTT), and 3GPP Legacy. The terminal
tries to acquire time and frequency synchronization
ASimultaneousNetworkSearchSchemeforFastRoamingandHandoveroftheSimultaneousVoiceandLTEMobile
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41
Terminal
LTE
network
3GPP Legacy
network
CDMA
network
Try to acquire synchronization of LTE network
1. Time and frequency synchronization / 2. Network information acquisition
Try to acquire synchronization of CDMA network
Failure of synchronization acquisition of LTE network
Try to acquire synchronization of 3GPP Legacy network
Failure of synchronization acquisition of CDMA network
Success of synchronization acquisition of 3GPP Legacy network
wait for search result for
CDMA network
Try 3GPP Legacy registration
Success of 3GPP Legacy Registration
3. Network registration procedure
Network priority order:
1. LTE
2. CDMA (EVDO/1xRTT)
3. 3GPP Legacy (HSPA/UMTS/GSM)
3GPP Legacy network information acquisition
Figure 7: Roaming scenario for experiments with the
proposed scheme.
from LTE network with the highest priority first.
The terminal tries to acquire time and frequency
synchronization from CDMA network with the next
priority at the same time because two RF modems
for LTE and CDMA can work simultaneously. It is
confirmed that there is no available LTE network
because it has failed to acquire time and frequency
synchronization of LTE while it is acquiring time
and frequency synchronization of CDMA. Then the
terminal tries to acquire time and frequency
synchronization of UMTS. Since signal of a UMTS
network is available, the terminal acquires time and
frequency synchronization of 3GPP Legacy and then
receives 3GPP Legacy network information. Though
the terminal acquires time and frequency
synchronization of 3GPP Legacy and receives
network information, it should wait for search result
for CDMA network without registering to 3GPP
Legacy network because it is trying to acquire time
and frequency synchronization of CDMA. The
terminal performs registration to 3GPP Legacy
network for roaming after confirming that there is no
CDMA network by failure of acquisition of time and
frequency synchronization of CDMA.
As described above, the time taken to acquire
time and frequency synchronization of CDMA was
longer than those of LTE (about 2 seconds) or 3GPP
(140 seconds at maximum), which is much shorter
than that of CDMA, and the time taken for
acquisition of time and frequency synchronization of
3GPP Legacy was 25 seconds, which is longer than
that of LTE but shorter than that of CDMA.
Compared with the conventional method, which
took 167 seconds to select a network for roaming,
our proposed method took about 140 seconds to
search for LTE, 3GPP Legacy, and CDMA networks
simultaneously.
The time for handover to CDMA network for
LTE terminal with the Exynos application chipset
based on the proposed method was measured in the
same experimental environment described in Section
2. Figure 8 shows experimental results using a
commercial SVLTE terminal with the proposed
handover procedure.
The terminal completes registration to the LTE
network with the highest priority. The strength of
LTE signal was gradually reduced in the experiment.
When the strength of LTE signal is reduced to a
fixed level, the terminal begins to search for CDMA
networks. In this paper, we set the LTE signal
strength level to -100 dBm to begin searching for
CDMA network. The terminal confirms availability
of CDMA network and receives network
information but just maintains time and frequency
synchronization without registration. If the terminal
considers that signal strength of LTE network is not
high enough for normal service, it begins to register
to the CDMA network that it already selected. The
time for registration to CDMA network is less than 1
second, which is shorter than that for initial
registration to CDMA network. Therefore, the
terminal can perform fast handover to CDMA
network for data communication when it moved out
of the LTE service area.
In the conventional method, the same experiment
took 20 seconds to 2 minutes. In the proposed
scheme, the time was reduced by up to 90% with the
exact reduction rate depending on the CDMA
frequency. Such a high performance improvement is
made possible by using parallelism and also
performing Steps 1 and 2 in advance in network
registration procedure.
Since two modems search for a network to
select, it consumes more battery than a sequential
search. But the battery is used just for the initial
network selection. So battery consumption is not
significant. Also the scheme to reduce the time for
handover from LTE to CDMA based on the early
WINSYS2014-InternationalConferenceonWirelessInformationNetworksandSystems
42
search of CDMA network may consume more
battery where LTE signal is weak but service is
available. In this paper, the threshold to begin an
early search was set to 100dBm. Battery
consumption can be reduced by decreasing the
number of early searches. More detail
experimentation and analysis will be performed
further.
4 CONCLUSIONS
The 4G era has begun with the LTE technology.
High-speed LTE will provide users with various
convenient services such as video conference and
streaming.
This paper proposed a scheme for reducing
network registration time for roaming and handover
time from LTE to CDMA network and demonstrated
that network registration time for roaming was
reduced by 15% through reduction of time for time
and frequency synchronization and network
information acquisition of UMTS and GSM. The
time depends on the frequency of searching and can
be reduced by as much as 45%. Handover time from
LTE to CDMA can be reduced by over 90% through
reduction of CDMA network search where LTE
network doesn't provide CDMA network
information.
The proposed scheme makes use of the existing
Dual RF in a commercial LTE terminal, and works
without change of network configuration and with
only change in LTE terminal. As a result, it gives
benefits such as fast roaming and handover to users
and network operators.
ACKNOWLEDGEMENTS
This work was supported by the National Research
Foundation of Korea Grant funded by the Korean
Government (NRF-2012R1A2A2A01008244).
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