cellular 2.ppt

Copyright © 2004, Dr. Dharma P. Agrawal and Dr. Qing-An Zeng. All rights reserved. 1
Chapter 5
The Cellular Concept

Outline
 Cell Shape
 Actual cell/Ideal cell
 Signal Strength
 Handoff Region
 Cell Capacity
 Traffic theory
 Erlang B and Erlang C
 Cell Structure
 Frequency Reuse
 Reuse Distance
 Cochannel Interference
 Cell Splitting
 Cell Sectoring

Cell Shape
Cell
R
(a) Ideal cell (b) Actual cell
R
R R
R
(c) Different cell models

Impact of Cell Shape and Radius on
Service Characteristics

Signal Strength
Select cell i on left of boundary Select cell j on right of boundary
Ideal boundary
Cell i Cell j
-60
-70
-80
-90
-100
-60
-70
-80
-90
-100
Signal strength
(in dB)

Signal Strength
Signal strength contours indicating actual cell tiling.
This happens because of terrain, presence of obstacles
and signal attenuation in the atmosphere.
-100
-90
-80
-70
-60
-60
-70
-80
-90
-100
Signal strength
(in dB)
Cell i Cell j

Handoff Region
BSi
Signal strength
due to BSj
E
X1
Signal strength
due to BSi
BSj
X3 X4 X2
X5 Xth
MS
Pmin
Pi(x) Pj(x)
• By looking at the variation of signal strength from either base station it is
possible to decide on the optimum area where handoff can take place.

Handoff Rate in a Rectangular
   




 cos
sin
sin
cos 2
1
2
2
1
1
X
X
R
X
X
R
H








sin
cos
cos
sin
2
1
2
1
2
1 X
X
X
X
A
R







cos
sin
sin
cos
2
1
2
1
2
2
X
X
X
X
A
R




X2
X1
Since handoff can occur at sides R 1 and
R 2 of a cell
where A=R 1 R 2 is the area and assuming it
constant, differentiate with respect to R1 (or
R 2) gives
Total handoff rate is
  




 cos
sin
sin
cos
2 2
1
2
1
X
X
X
X
A
H



H is minimized when =0, giving
2
1
2
1
2
1
2
X
X
R
R
and
X
AX
H 


side


side


Cell Capacity
 Average number of MSs requesting service (Average
arrival rate): 
 Average length of time MS requires service (Average
holding time): T
 Offered load: a = T
e.g., in a cell with 100 MSs, on an average 30 requests are
generated during an hour, with average holding time T=360
seconds.
Then, arrival rate =30/3600 requests/sec.
A channel kept busy for one hour is defined as one Erlang (a),
i.e.,
Erlangs
call
Sec
Sec
Calls
a 3
360
3600
30




Cell Capacity
 Average arrival rate during a short interval t is given by  t
 Assuming Poisson distribution of service requests, the
probability P(n, t) for n calls to arrive in an interval of
length t is given by
  t
n
e
n
t
t
n
P 
 

!
)
,
(
 Assuming  to be the service rate, probability of each call
to terminate during interval t is given by  t.
Thus, probability of a given call requires service for time t
or less is given by
t
e
t
S 


1
)
(

Erlang B and Erlang C
 Probability of an arriving call being blocked is
  ,
!
1
!
,
0



 S
k
k
S
k
a
S
a
a
S
B
where S is the number of channels in a group.
Erlang B formula
     
   
,
!
!
1
!
1
, 1
0








 S
i
i
S
S
i
a
a
S
S
a
a
S
S
a
a
S
C Erlang C formula
where C(S, a) is the probability of an arriving call being delayed with a
load and S channels.
 Probability of an arriving call being delayed is

Efficiency (Utilization)
 Example: for previous example, if S=2,
then
B(S, a) = 0.6, ------ Blocking probability,
i.e., 60% calls are blocked.
Total number of rerouted calls = 30 x 0.6 = 18
Efficiency = 3(1-0.6)/2 = 0.6
)
(channels
trunks
of
Number
traffic
nonrouted
of
portions
Erlangs
Capacity
nonblocked
Traffic
Efficiency




Cell Structure
F2 F3
F1
F3
F2
F1
F3
F2
F4
F1
F1
F2
F3
F4
F5
F6
F7
(a) Line Structure (b) Plan Structure
Note: Fx is set of frequency, i.e., frequency group.

Frequency Reuse
F1
F2
F3
F4
F5
F6
F7 F1
F2
F3
F4
F5
F6
F7
F1
F2
F3
F4
F5
F6
F7 F1
F2
F3
F4
F5
F6
F7
F1
F1
F1
F1
Fx: Set of frequency
7 cell reuse cluster

Reuse Distance
F1
F2
F3
F4
F5
F6
F7
F1
F2
F3
F4
F5
F6
F7
F1
F1
• For hexagonal cells, the reuse
distance is given by
R
N
D 3

R
where R is cell radius and N is the
reuse pattern (the cluster size or the
number of cells per cluster).
N
R
D
q 3


• Reuse factor is
Cluster

Reuse Distance (Cont’d)
 The cluster size or the number of cells per cluster is given by
2
2
j
ij
i
N 


where i and j are integers.
 N = 1, 3, 4, 7, 9, 12, 13, 16, 19, 21, 28, …, etc.
The popular value of N being 4 and 7.
i
j
60o

(b) Formation of a cluster for N = 7
with i=2 and j=1
60°
1 2 3 … i
j direction
i direction
(a) Finding the center of an adjacent cluster
using integers i and j (direction of i and j can
be interchanged).
i=2
i=2
j=1
j=1
j=1
j=1
j=1
j=1
i=2
i=2
i=2
i=2

(c) A cluster with N =12 with i=2 and j=2
i=3
j=2
i=3 j=2 i=3
j=2
i=3
j=2
i=3
j=2
i=3
j=2
(d) A Cluster with N = 19 cells with i=3
and j=2
j=2
j=2
j=2
j=2
j=2
j=2
i=2
i=2
i=2
i=2
i=2
i=2

Cochannel Interference
Mobile Station
Serving Base Station
First tier cochannel
Base Station
Second tier cochannel
Base Station
R
D1
D2
D3
D4
D5
D6

Worst Case of Cochannel Interference
Mobile Station
Serving Base Station Co-channel Base Station
R
D1
D2
D3
D4
D5
D6

Cochannel Interference
 Cochannel interference ratio is given by



 M
k
k
I
C
ce
Interferen
Carrier
I
C
1
where I is co-channel interference and M is the maximum
number of co-channel interfering cells.
For M = 6, C/I is given by









M
k
k
R
D
C
I
C
1
g
where g is the propagation path loss slope
and g = 2~5.

Cell Splitting
Large cell
(low density)
Small cell
(high density)
Smaller cell
(higher density)
Depending on traffic patterns the smaller
cells may be activated/deactivated in
order to efficiently use cell resources.

Cell Sectoring by Antenna Design
60o
120o
(a). Omni (b). 120o sector
(e). 60o sector
120o
(c). 120o sector (alternate)
a
b
c
a
b
c
(d). 90o sector
90o
a
b
c
d
a
b
c
d
e
f

Cell Sectoring by Antenna Design
 Placing directional transmitters at corners where three
adjacent cells meet
A
C
B
X

Worst Case for Forward Channel
Interference in Three-sectors
BS
MS
R
D + 0.7R
D
BS
BS
BS
  g
g 




7
.
0
q
q
C
I
C
R
D
q /


Interference in Three-sectors (Cont’d)
  g
g 




7
.
0
q
q
C
I
C
BS
MS
R
D’
D
BS
BS
BS
D
R
D
q /


Interference in Six-sectors
D +0.7R
MS
BS
BS
R
 
R
D
q
q
C
I
C
/
7
.
0


 g

cellular 2.ppt

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