Transcript Week_9

Mobility Management
in Mobile Wireless Systems
Lecture 9
Cellular Communication
• No matter what frequencies are used.
• There is no radio frequency which can carry data or voice to
long distances without serious attenuation.
• The entire communication is, therefore, achieved in multiple
“communication slots” to overcome this limitation.
• A communication slot is a geographical area within which the
RF can be used to set up communication.
• In cellular terminology this communication slot is referred to as
a cell, and the entire communication infrastructure is known as
cellular communication.
• The size of a cell is defined, keeping in mind the energy level
of RF to be used and the power of the transceiver.
Cellular Communication
• To provide communication over a geographical area
of any shape- for example, a city- it is logically divided
into a set of cells.
• This logical division helps to identify the best position
to install the transceiver for achieving the “best
coverage,” which means that a mobile device is able
to receive communication from any point of a cell.
• A mathematical model is used to identify the “best
coverage” pattern.
Cellular Communication
• To understand the meaning of the best coverage, let us use a
circle to develop a coverage pattern.
• Figure (1a) (in slide 5) illustrates an example of covering an
area using circles.
– It is obvious that the entire area cannot be fully covered by using
circle of any size.
– The space at the junction of three circles will always remain
uncovered.
• Figure (1b) illustrates the coverage using hexagons which
has no uncovered space anywhere.
Figure 1
Cellular Communication
• A cell must have a wireless component for
managing the communication.
• One of the important coverage factors is the
location of its “cell site,” which is the point in the
cell where the transceiver is installed.
• The main objective here is to cover maximum
number of calls efficiently.
Cellular Communication
• Figure (2a) (in slide 8) shows the arrangement used in
practice.
– The cell site is the smaller circle at the junction of three hexagons
which represent cells.
– The transceiver covers a portion, referred to as “sector” of each
cell, and provides each sector with its own set of channels.
• This arrangement can also be visualized as shown in Figure
(2b).
– It appears here that a cell site is located at the center of a cell.
Figure 2: Location of Cell Site
Cellular Communication
• In a cellular architecture a number of wireless and wired components are
required to establish the desired point-to-point or point-to-multipoint
communication.
• A Mobile Database System (MDS) is interested in the components that are
directly connected through wireless channel with mobile devices.
• One such component is the transceiver, which is usually referred to as a
base station (BS).
• A BS functions under the supervision of a telecommunication switch called
Mobile Switching Center (MSC) and connected to it through wired line.
• It is the MSC which connects the entire mobile system with PSTN (Public
Switched Telephone Network).
• Figure 3 illustrates a communication path
Figure 3
Frequency Reuse
• The continuous connectivity may also be affected
by interference, which can be defined as interaction
between two signals.
– Two communication sessions may interfere with each
other if the frequencies they use are quite close to each
other or even identical.
– It can also occur if the base stations of two closely or if
there is another active mobile unit communicating
mobile units are located in the vicinity or if there is an
active call in a nearby cell.
Frequency Reuse
• To avoid co-channel interference, two frequencies are kept
apart at least by 45 Hz, but in the case of higher frequencies
the separation may be less.
• Each cell is usually assigned 25 to 30 channels for
communication, which depends on the expected traffic volume
in the cell.
• This will support only 25 to 30 communication sessions.
• The number of channels for a cell is determined by a number
of factors such as: the density of callers, which indicates the
number of callers per square meter; the average activity factor,
which relates to the average use of phone in an hour; the
probability of blocked calls; and so on.
Frequency Reuse
• In cellular communication the system has to deal with cochannel interference and adjacent channel interference.
• Co-channel interference occurs when the same frequency is
used for communication in two nearby cells.
– Co-channel interference could be tolerable in a voice
communication because humans can guess reasonably accurately
the words in the presence of noise.
– This is not acceptable in data communication because it can
corrupt the data to an extent which cannot be recovered by the
receiver.
Frequency Reuse
• Co-channel interference is solved by keeping the
cells, which plan to use the same set of frequencies,
apart by a distance called frequency reuse distance.
• A frequency reuse distance is the minimum safe
distance between two cells which can reuse the same
frequencies without interference.
• This distance is expressed in terms of intervening
cells between the two cells where same frequencies
are reused.
• Frequency reuse is implemented through cell
clustering.
• A cell cluster is made up of a number of same size
cells and the cluster size depends on the entire
coverage area, the frequency plan, acceptable cochannel interference, so on.
• A cluster may be made up of 3,4,7,9, 12, 13, 16,
etc., cells; but out of these, 7-cell and 4-cell clusters
are most commonly used to cover an area.
• Figures 4a through 4d illustrate the composition of
clusters of sizes.
• In reality, an area is covered by a number of clusters,
each one composed of different size cells as
illustrated by Figure 4e.
• This cluster organization was in fact used by the
Vodafone company to provide communication service
around the area covered by M25 ringroad in England.
• The inner area was populated by smaller-size cells to
manage high communication traffic from highly
populated user community.
Figure 4
• To reuse the same set of frequencies in
another cell, it must be separated by frequency
reuse distance, which is usually denoted by D.
• Figure 5 illustrates the separation of cells by
frequency reuse distance in a cluster of seven
cells.
Figure 5
Location and Handoff
Management
• Mobile unit movement is random and therefore its
geographical location is unpredictable.
• This situation makes it necessary to locate the
mobile unit and record its location to HLR and
VLR when a call has to be delivered to it.
Location and Handoff
Management
• The entire process of the mobility management component
of the cellular system is responsible for two tasks:
– (a) location management- that is, identification of the current
geographical location or current point of attachment of a mobile
unit which is required by the MSC (Mobile Switching Center) to
route the call- and
– (b) handoff- that is, transferring (handing off) the current (active)
communication session to the next base station, which seamlessly
resumes the session using its own set of channels.
Location and Handoff
Management
• The entire process of location management is a kind
of directory management problem where locations
are current locations are maintained continuously.
• One of the main objectives of efficient location
management schemes is to minimize the
communication overhead due to database updates
(mainly HLR).
• The other related issue is the distribution of HLR to
shorten the access path.