Notes/UNB/Year 4/Semester 2/CS3873/2024-01-22.md

Lecture Topic: Packet Switching Performance
# Packet Switching
## Congestion
A relevant example is air plane ticket overbooking. If an air plane has a capacity of 100 seats, and the probability of of a passenger showing up to their flight is 80%, then you can overbook ticket sales due to the probability of passengers not showing up
- If 110 tickets are sold, the probability of more than 100 passengers is 0.0058%
- If 115 tickets are sold, the probability goes up to 1.94%
- If 120 tickets are sold, the probability is 15.17%
- If 130 tickets are sold, the probability is 78.12%

## Performance
Throughput: Rate (bits/time) at which bits are transferred between sender/receiver
- Instantaneous: Receiving rate at any instant of time 
- Average: Receiving rate over a longer period of time

How fast a node (host or router) is transmitting depends on
1. How fast the sender is sending
2. How fast the link is transmitting

End-to-end throughput is constrained by rate of bottleneck link (the link of the minimum rate on an end-to-end path). The weakest link in the chain (of nodes) determines the throughput of the entire link.

## Delay and Loss
Packets queue in a router buffer (Store and Forward)
- They are delayed while waiting in the buffer for it's turn
- Slowed down while the queue keeps growing (congestion)
- Dropped (lost) if no free space in a full buffer

There is four sources of nodal delay:
1. Node processing: Decoding the incoming electronic signal and accounting for distortion (e.g. wireless signal distortion), and verifying the correctness of the packet, and determining the output link. Usually very small ($10^{-6}$ secs)
2. Queuing: Time waiting at the output link for transmission. Amount depends on the congestion of the network.
3. Transmission: $L/R$, L = Packet length, R = Link bandwidth
4. Propagation: $m/s$ m = Physical distance of link (e.g. 100m wire), s = propagation speed of link (e.g. speed of electricity)

The entire delay is the sum of all of these figures

### Measuring queuing delay
Traffic intensity is a measure of congestion.
$$ \frac{L \times a}{R} $$
a: Average packet arrive rate (packets/s)
L: Packet length/size (bits/packet)
R: Link bandwidth/rate (bps)

If this figure is 0, the delay on average is very small
If this figure is 1, the delay is large
If this figure is > 1, then more work arriving than serviced (severe congestion)

Note: There is a field called traffic engineering, and an important rule for this field is to not let the traffic intensity exceed 1.

## Example: Delay
Consider only transmission delay and propagation delay. S sends 1 packet of length L to D over a single link of rate R and distance m. s is the speed of the link

L = 1 kb
R = 100 kb/s
m = 100 km
s = $2\times10^8$ m/s

$d_{prop} = m/s = 10^5/(2\times 10^8) = 5 \times 10^{-4}$
2024-01-22 12:38:16 2024-01-22 12:38:16 -04:00			`Lecture Topic: Packet Switching Performance`
			`# Packet Switching`
			`## Congestion`
			`A relevant example is air plane ticket overbooking. If an air plane has a capacity of 100 seats, and the probability of of a passenger showing up to their flight is 80%, then you can overbook ticket sales due to the probability of passengers not showing up`
			`- If 110 tickets are sold, the probability of more than 100 passengers is 0.0058%`
			`- If 115 tickets are sold, the probability goes up to 1.94%`
			`- If 120 tickets are sold, the probability is 15.17%`
			`- If 130 tickets are sold, the probability is 78.12%`

			`## Performance`
			`Throughput: Rate (bits/time) at which bits are transferred between sender/receiver`
			`- Instantaneous: Receiving rate at any instant of time`
			`- Average: Receiving rate over a longer period of time`

			`How fast a node (host or router) is transmitting depends on`
			`1. How fast the sender is sending`
			`2. How fast the link is transmitting`

			`End-to-end throughput is constrained by rate of bottleneck link (the link of the minimum rate on an end-to-end path). The weakest link in the chain (of nodes) determines the throughput of the entire link.`

			`## Delay and Loss`
			`Packets queue in a router buffer (Store and Forward)`
			`- They are delayed while waiting in the buffer for it's turn`
			`- Slowed down while the queue keeps growing (congestion)`
			`- Dropped (lost) if no free space in a full buffer`

			`There is four sources of nodal delay:`
			`1. Node processing: Decoding the incoming electronic signal and accounting for distortion (e.g. wireless signal distortion), and verifying the correctness of the packet, and determining the output link. Usually very small ($10^{-6}$ secs)`
			`2. Queuing: Time waiting at the output link for transmission. Amount depends on the congestion of the network.`
			`3. Transmission: $L/R$, L = Packet length, R = Link bandwidth`
			`4. Propagation: $m/s$ m = Physical distance of link (e.g. 100m wire), s = propagation speed of link (e.g. speed of electricity)`

			`The entire delay is the sum of all of these figures`

			`### Measuring queuing delay`
			`Traffic intensity is a measure of congestion.`
			`$$ \frac{L \times a}{R} $$`
			`a: Average packet arrive rate (packets/s)`
			`L: Packet length/size (bits/packet)`
			`R: Link bandwidth/rate (bps)`

			`If this figure is 0, the delay on average is very small`
			`If this figure is 1, the delay is large`
			`If this figure is > 1, then more work arriving than serviced (severe congestion)`

			`Note: There is a field called traffic engineering, and an important rule for this field is to not let the traffic intensity exceed 1.`

			`## Example: Delay`
			`Consider only transmission delay and propagation delay. S sends 1 packet of length L to D over a single link of rate R and distance m. s is the speed of the link`

			`L = 1 kb`
			`R = 100 kb/s`
			`m = 100 km`
			`s = $2\times10^8$ m/s`

			$d_{prop} = m/s = 10^5/(2\times 10^8) = 5 \times 10^{-4}$