Week 3 - Lecture 5

Question 1

What are the layers of the OSI Reference Model?

Answer 1

Application Layer
Presentation Layer
Sessions Layer
Transport Layer
Network Layer
Data Link Layer
Physical Layer

The all the way back up on the other end

Question 2

What is a PAN?

Answer 2

Personal Area Network (About a square meter - around a single person)

Question 3

What is a MAN?

Answer 3

about 10km - A city

Question 4

What is a WAN?

Answer 4

Around 100 - 1000km - A country or a continent

Question 5

What is a LPWAN?

Answer 5

Low power wide area network

Question 6

What is the internet of things stack (Vs OSI stack)?

Answer 6

Application Layer
Transport layer
Network layer / IP
Link Layer
Physical Layer

Question 7

Why can’t we use OSI for IoT?

Answer 7

OSI created based on assumption of single technology stacks. IoT is characterised by high technology heterogeneity

The internet stack abstracts the physical layer due to, typically, fully homogeneous networks but this is not the case for IoT where different power constrained devices at the edge are utilised

Many of the low-level IoT devices used in constrained networks do not fully support IP compliant communication.

Question 8

What aspects should be considered for IoT protocol stacks?

Answer 8

Physical aspect
- Don’t exclude any available technology.
- For example, consider that a device with radio capabilities employs the Zigbee protocol while an application for a smartphone using the data produced by the device at the edge communicates with the database on cloud services through Wi-Fi or 3G cellular communication

Link Aspect
Should support heterogeneity (although more limited than in the physical layer) and underpin security solutions as well. In addition, this layer must provide upper layers with standardised capabilities and interfaces. Again the idea is not to limit the implementation of data link layer but rather ensure the coexistence of several solutions for the link layer

Network and ID aspects
- Provide functionalities as required by the network layer of the OSI stack. Providing a common communication platform for every possible networking solution can be the bottleneck for IoT systems. Alternatively, the ID aspect should provide identification functionalities and where necessary resolution functionalities between locators (descriptors of the location of a given IoT element in the network) and identifiers (unique descriptors of the Digital Artefact; either active or passive).
Consequently, this interoperability aspect takes care of the addressing issue in between any two systems irrespective of the particular technologies they utilize

End-to-end aspect
Reliability, transport issues, translation, proxy/gateway support and parameter configuration when the communication crosses different networking environments. This aspect is the final component for achieving a global M2M (machine-to-machine) communication model

Data aspect
Needs to model:
- Capability of providing structured attributes for data description
- Capability of being translated (possibly by compression / decompression) one to each other, e.g. COAP to HTTP by decompression or XML to EXI by compression, IPv4 to IPv6 by mapping

Question 9

What is an unconstrained network?

Answer 9

High-speed communication links (Mbit\s or higher). Wired internet we all know is an example. Link-level transfer latencies are also small and mainly affected by congestion events in the network rather than by the technology utilised for the physical layer

Question 10

What is a constrained network?

Answer 10

Relatively low transfer rates, typically smaller than 1 Mbit\s. These networks typically involve large latencies. These latencies are due to several factors including:
- Low-bitrate supported by the physical layer technology
- Power saving policies and mechanisms of the terminals populating these networks. Could be hibernation states or a policy for the periodic power off of their radios

Question 11

What is the most typical case for IoT communication approaches?

Answer 11

Constrained networks intermediated by an unconstrained network (e.g. the internet)

Question 12

What three things is communication subject to?

Answer 12

noise, interference and losses
- Each medium is subject to different loss mechanisms

Question 13

At what speed to signals usually propogate?

Answer 13

The speed of light

c = lambda * f
Where lambda is the wavelength (m) and f is the signal frequency [Hz}

Question 14

What is 1/4 wave antenna

Answer 14

The physical size of the antenna should be 1/4 of the signal wavelength

Assume signal transmission at 1 MHz. What’s the size of an 1/4 wave antenna?
(310^8) / (1x10^6) / 4 = 310^2/4 = 300/4 = 75m

At ISM band (2.4 GHz)
(310^8)/(2.410^9) / 4 = 1.25*10^-1 / 4 = 0.125/4 = 0.03125m

Question 15

What does “baseband” frequency typically refer to?

Answer 15

digital circuits producing the “digital information”

Baseband signals are propagated by modulating higher frequency signals (RF carriers)