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Transcript
Network Layer:
Location/Service Management
Y. Richard Yang
11/27/2012
Outline
 Admin. and recap
 Network layer
 Intro
 Location/service management
2
Admin.
 Project meeting slots posted on the Sign Up page of
classesv2


If none of the time works, please send me email to
schedule appointments
Each team needs to schedule two meetings to discuss your
project by the end of semester
 Sharing of devices (status post to a google doc?)
 4 x 10” Android (2 Xoom, 1 Nexus 10, 1 Galaxy Tab 2 10.1 )
 3 x 7” Android (2 Nexus 7/Wifi; 2 Nexus 7/Wifi/Cellular)
 1 x Android phone
 1 x iPad 2
 1 x iPad w/ Retina display
 1 x Nokia Lumia 920
 10 x GNURadio sets
 1 x Altera FPGA set
3
Recap: Improving
Wireless Capacity
Reduce
interf. area
Radio interface constraint
Interference constraint
 a single half-duplex
 transmission
transceiver at each
node
Multiple
successful if there are
no other transmitters
within a distance
(1+D)r of the receiver
transceivers
T
n
h(b)  WT

2
b 1L
Reduce
rate*distance
capacity:
T h ( b )
Approx.
optimal
16WT
(r ) 

2

D
b 1 h 1
h 2
b
Increase
W
8W
 L
n
 D
4
Recap: RRC State and App
 Given the large overhead for radio resource control (RRC),
wireless networks implement RRC state machine on mobile
devices for data connection
Courtesy: Erran Li.
Channel
Radio
Power
IDLE
Not
allocated
Almost
zero
CELL_FAC
H
Shared,
Low Speed
Low
CELL_DCH
Dedicated,
High Speed
High
5
Case Study: Pandora Streaming
Problem: High resource overhead of periodic audience measurements (every 1 min)
Recommendation: Delay transfers and batch them with delay-sensitive transfers
6
Recap: Wireless Link Layer
 The basic services of the link layer
 framing,
link reliability, etc
 link access: interference, quality of service (and
fairness) control, link state management
 Guided by network layer
 transmit to which neighbor at what quality
S
E
F
B
C
M
J
A
L
G
H
K
I
D
N
7
Outline
 Admin. and recap
 Network layer
 Intro to networks
8
Network Layer Services
 Transport packets from source to dest
 Network layer protocol in host and router
Basic functions:
 Control plane

S1
B
A
compute routing from
sources to destinations
E
D2
C
G
S2
I
K
J
M
L
D1
N
 Data plane: forwarding
 move packets from input interface to
appropriate output interface(s)
9
Network Layer: API
 API (provided to upper layer)
 transmit( info, src, dest, …);
 A key decision in network layer design is how to
represent destinations?


we refer to how a client specifies destination as the
addressing scheme
the supported addressing scheme(s) can have profound
impacts on usability, flexibility, scalability
request
src
dst
result
10
Discussion: How to Specify a
Destination?
S
E
F
B
C
M
J
A
L
G
H
K
I
D
N
11
Two Basic Approaches for
Identifying Destinations
 Locators
 Encode locations on
network topology
 Identifiers (ID)

B
C
A
F
D
E
Independent of
network topology
12
Addressing Scheme: Telephone
 Very first scheme: connection
by operators to business

Identifier or locator?
13
Addressing Scheme: Telephone
 The telephone numbering scheme:
 invented in 1888 by Almon Strowger,
an undertaker:
“No longer will my competitor steal
all my business just because his wife
is a BELL operator.”
14
Addressing Scheme: Telephone
 E.164: Maximum 15 digits
 Hierarchical addressing scheme: country
code + national destination (area) code
(optional) + subscriber number

e.g., +1-203-432-6400
 Why hierarchical addressing scheme?
S E
D
B C
M L
J
A
G
F
D
K
I
N
15
Evolution of Telephone
Addressing Scheme

Identifier (business, person)

Locator (hierarchical phone #)

Identifier (person again w/ mobile phones, 800)
16
IP Addressing
 Also a hierarchical
locator addressing
scheme


network part (high
order bits)
host part (low order
bits)
223.1.1.2
223.1.1.1
223.1.1.4
223.1.1.3
223.1.9.2
 What’s a network?
223.1.9.1
223.1.8.1
(from IP address
perspective)
223.1.2.6
 device interfaces with
same network part of
223.1.2.1
223.1.2.2
IP address
 link layer can
reach each other
223.1.7.0
223.1.8.0
223.1.7.1
223.1.3.27
223.1.3.1
223.1.3.2
17
Addressing Scheme: Sensornet Example
 Destination: message to a sensor (e.g., who
detected fire)
// id.
 <ID = D>
 <Lat=37.3169; Long=-121.8740> // loc
 <temperature = highest>
// id
S
B
A
E
D
C
J
G
F
I
K
M
L
D
N
18
Addressing Scheme: Printer
 How may we specify the destination as the
color printer on the 2nd floor of AKW

Internet domain name: lw2c.cs.yale.edu

Internet protocol (IP) address: 128.36.231.8

[building = AKW; floor=2; entity = printer;
quality = color]
19
Basic Network Layer Model
Each node is a network attachment
point (e.g., router, base station), to
which hosts/user device attaches
B
C
A
F
D
E
User device identified by
addressing scheme
• locator: identifies attachment
point
• identifier: independent of
location
20
Routing in IP/Telephone Networks
 Represent a network
as a graph
 Determine a path
to each destination
on the graph
5
2
A
2
1
 Key problems

B
D
3
C
3
1
5
F
1
E
2
Location management
• Find attached point for id-based naming

Routing
• Find path from src to dst attach point
21
Outline
 Admin.
 Network layer
 Intro to networks
 Location management
• service discovery
22
The Service Discovery Problem
request
src
dst
result
 How does a src connect to a dst in an ID-
based addressing scheme?
ID-based phone#
 IP address difficult to remember, uses domain
name lw2.cs.yale.edu

23
Today’s Internet: DNS
clients
DNS
<hostname, service>
routers
IP address
servers
24
DNS: Domain Name System
 Function
 map domain name (e.g. cs.yale.edu) and service type (e.g.,
email) to IP address (e.g. 128.36.232.5)
 Domain name: a hierarchical name space implemented
by a distributed database to allow distributed,
autonomous administration
called a zone
25
DNS: Naming Scheme
 Each DNS server stores resource records (RR)
RR format: (name,
 Type=A
 name is hostname
 value is IP address
 Type=NS
 name is domain (e.g.
yale.edu)
 value is the name of the
authoritative name
server for this domain
value, type, ttl)
 Type=CNAME
 name is an alias name
for some “canonical”
(the real) name
 value is canonical name
 Type=MX
 value is hostname of mail
server associated with name
26
DNS Name Resolution
 A host queries local DNS server, who may
forward the query to the corresponding DNS
server
27
Problems of Traditional DNS Service
Discovery
 Support fixed types of services, e.g., A, NS,
CNAME, MX

static and fixed record structure makes it difficult to
introduce new services or non-trivial service queries
 Depends on infrastructure: a DNS server
28
General Naming Paradigm: Linda
 “Distributed workspace” by David Gelernter
in the 80’s at Yale
 Very influential in naming and resource
discovery
29
General Naming Paradigm: Linda
 Naming scheme:
 arbitrary tuples (heterogeneous-type
vectors)
 Name resolution:
o Nodes write into shared memory
o Node read matching tuples from shared
memory

exact matching is required for extraction
30
Linda: Core API
 out(): writes tuples to shared space


example: out("abc", 1.5, 12).
result: insert (“abc”, 1.5, 12) into space
 read(): retrieves tuple copy matching arg list (blocking)


example: read(“abc”, ? A, ? B)
result: finds (“abc”, 1.5, 12) and sets local variables
A = 1.5, B = 12. Tuple (“abc”, 1.5, 12) is still resident in space.
 in(): retrieves and deletes matching tuple from space (blocking)

example: same as above except (“abc”, 1.5, 12) is deleted
 eval(expression): similar to out except that the tuple argument to
eval is evaluated
o example: eval("ab",-6,abs(-6)) creates tuple (“ab”, -6, 6)
31
Linda Extension: JavaSpaces
 Industry took Linda principles and made
modifications
add transactions, leases, events
 store Java objects instead of tuples
 a very comprehensive service discovery
system

 Definitive book, “JavaSpaces Principles,
Patterns, and Practice”

2 of 3 authors got Ph.D.’s from Yale
32
JavaSpaces – Visual Overview
33
Progress
 Support fixed types of services, e.g.,
A, NS, CNAME, MX
Linda name space
 Depends on infrastructure: a DNS
server

?
34
DNS without Central DNS Server: mDNS
 Multicast in a small world
 no central address server
• each node is a responder

link-local addressing
• send to multicast
address: 224.0.0.251
 Leverage DNS
169.254.1.219
format—DNS-SD

each node picks
own name:
<instance name> .
<app-proto> .
<service> .
<domain>
Network
Printer
169.254.10.29
169.254.4.51
35
DNS without Central DNS Server: mDNS
PC_BILL
169.254.1.219
Laserjet in the
Closet Under
the Stairs
Bill’s Files
Printer
Network
169.254.10.29
lj21569478
169.254.4.51
PC_LARRY
Larry’s Tunes
36
mDNS: Example
 Use the mDNS command on Mac as example
 Advertise an LPR printer on port 515
mDNS -R "My Test" _printer._tcp. . 515
pdl=application/postscript
 Advertise a web page on local machine
mDNS -R "My Test" _http._tcp . 80 path=/pathto-page.html
 Browse web pages on local machines
mDNS -B _http._tcp
37
Service Discovery in Android
 Based on mDNS/DNS-SD
 Foundation for peer-to-peer/Wi-Fi Direct in
Android
 See http://developer.android.com/training/connect-
devices-wirelessly/nsd.html
38
Service Registration in Android
public void registerService(int port) {
NsdServiceInfo serviceInfo = new NsdServiceInfo();
serviceInfo.setServiceName("NsdChat");
serviceInfo.setServiceType("_http._tcp.");
serviceInfo.setPort(port);
mNsdManager = Context.getSystemService(Context.NSD_SERVICE);
mNsdManager.registerService(
serviceInfo, NsdManager.PROTOCOL_DNS_SD, mRegistrationListener);
}
39
Service Discovery in Android
mNsdManager.discoverServices(
SERVICE_TYPE, NsdManager.PROTOCOL_DNS_SD, mDiscoveryListener);
public void initializeDiscoveryListener() {
// Instantiate a new DiscoveryListener
mDiscoveryListener = new NsdManager.DiscoveryListener() {
// Called as soon as service discovery begins.
@Override
public void onDiscoveryStarted(String regType) {
Log.d(TAG, "Service discovery started");
}
@Override
public void onServiceFound(NsdServiceInfo service) {
// A service was found! Do something with it.
Log.d(TAG, "Service discovery success" + service);
if (!service.getServiceType().equals(SERVICE_TYPE)) {
// Service type is the string containing the protocol and
// transport layer for this service.
Log.d(TAG, "Unknown Service Type: " + service.getServiceType());
} else if (service.getServiceName().equals(mServiceName)) {
// The name of the service tells the user what they'd be
// connecting to. It could be "Bob's Chat App".
Log.d(TAG, "Same machine: " + mServiceName);
} else if (service.getServiceName().contains("NsdChat")){
mNsdManager.resolveService(service, mResolveListener);
}
}
...
}
40
Challenge of using Name Resolution in
Mobile Computing
src
dst
location
name/
ID
SD
Name -> location binding can be
dynamic as a mobile device changes attach point
41
Mobile Name-Loc Binding Design Issues
 Binding database update
 Hand off
 dst may move during a session (phone call)
42
Outline
 Admin.
 Network layer
 Intro to networks
 Location/service management
• service discovery
• cellular network location management
43
MS (mobile station)
BSC (base station controller)
BTS (base transceiver station)
MSC (mobile switching center)
GMSC (gateway MSC)
GSM
Network &
Switching
Subsystem
and Operation
Subsystem
Location
Registry
GMSC
fixed network
MSC
MSC
BSC
MS
BSC
MS
Radio
Subsystem
BTS
MS
MS
MS
BTS
BTS
MS
BTS
BTS
44
Location Registry (LR) update in
Cellular Networks
Problem definition:
How
to update the mapping
between ph# and current
attachment point (BTS) of the
phone?
45
Two Primitives for Cellular
Location Management
 Mobile station: reports to the network of
the cell it is in
called update
 uses the uplink channel

 Network: queries different cells to locate
a mobile station
called paging
 uses the downlink channel

46
Performance of the Two Primitives
 A city with 3M users
 During busy hour (11 am - noon)
 Update only
 total # update messages: 25.84 millions
 Paging only
 call arrival rate: 1433 calls/sec
 total # paging transactions: 5.2 millions
47
Discussion
 A user receives one call for ~5 cells (25M
vs 5M) visited, thus may not need to
update after every switching of cell
 However, if no update at all, then paging
cost can be high—may need to page the MS
at every cell

Q: how do you page?
48
Location Management Through
Location Areas (LA)
 Used in the current cellular
networks
 A hybrid of paging and
update


Partitions the cells into
location areas (LA)
e.g., around 10 cells in
diameter in current systems
 A global home location
register (HLR) database
for a carrier
 An MSC of each LA
maintains a visitor location
register (VLR) of the LA
49
MS (mobile station)
BSC (base station controller)
BTS (base transceiver station)
MSC (mobile switching center)
GMSC (gateway MSC)
GSM
Network &
Switching
Subsystem
and Operation
Subsystem
HLR
MSC
GMSC
fixed network
MSC
VLR
VLR
BSC
MS
BSC
MS
Radio
Subsystem
BTS
MS
MS
MS
BTS
BTS
MS
BTS
BTS
50
LA Based Update/Paging
 Each cell (BTS) of an LA
periodically announces its
LA id
 If a MS moves to a new
LA, it reports its location
to visiting MSC
 MSC/VLR notifies HLR
that it currently has MS
 When locating a MS, the
network pages the cells in
an LA
51
GSM Location Update: Example
52
GSM Location Update: Example
53
GSM Location Update: Example
54
GSM Location Update: RR
Connection Setup
55
GSM Location Update: Update
56
GSM Location Update: Update
57
GSM Location Update: Update
58
GSM Location Update :
Authenticate Subscriber
59
GSM Location Update:
Enable Ciphering
60
GSM Location Update: RR
Connection Release
61
Remaining Issue: How to Decide the
LAs: A Simple Model
 Assume the cells are given
 Cell i has on average Ni users in it during
one unit time; each user receives  calls
per unit time
 There are Nij users move from cell i to cell
j in a unit of time
N12
Cell 2
Cell 1
N1
N21
N2
62
How to Decide the LAs:
A Simple Scenario
N12
Cell 2
Cell 1
N1
N21
N2
 Separate LAs for cells 1 and 2
 #update: N12 + N21
 #paging:  (N1 + N2)
 Merge cells 1 and 2 into a single LA
 #update: 0
 #paging:
2  (N1 + N2)
63
Cost Comparison
Separate
Merge
Cupdate (N12 + N 21 ) ? 2l (N1 + N2 )
where C_update is relative cost of update to
paging, assuming paging cost per cell is 1
• At the same mobility, if call arrival rate is
high, more likely separate
• At the same call arrival rate, if higher
mobility, more likely to merge
64
Extension: From GSM to GPRS
to 3G UMTS
65
Extension: From GSM to GPRS
to 3G UMTS
 Issue: it is anticipated that users will make
more connections in data network

Same mobility but higher lambda => smaller
location area
66
UMTS Location Update
67
Summary
 The LA/RA/UTRANA design considers
call pattern: when (how often) does a mobile
station receive a call
 mobility model: how does a mobile station move

 Issues of LA based
approaches

Users roaming in LA borders
may generate a lot of
updates
68