2. âą The communication capacity or data volume in the downstream
direction (from servers-to-clients) is much greater than that in the
upstream direction (from clients to servers).
âą This is regardless of whether it is performed over a symmetric
channel such as the internet or over an asymmetric one, such as cable
television (CATV) network
âą Techniques and system architectures that can efficiently support
asymmetric applications will therefore be a requirement for future
use.
3. Mobile communication between a mobile
device and a static computer system
âą A device is allocated a limited bandwidth. This is because a large
number of devices access the network.
âą Bandwidth in the downstream from the server to the device is much
larger than the one in the upstream from the device to the server.
This is because mobile devices have limited power resources and also
due to the fact that faster data transmission rates for long intervals of
time need greater power dissipation from the devices.
âą In GSM networks data transmission rates go up to a maximum of 14.4
kbps for both uplink and downlink. The communication is symmetric
and this symmetry can be maintained because GSM is only used for
voice communication.
4. Shannonâs Law
âą Shannonâs Law describes the relationship between bandwidth, signal
power, and noise in determining the theoretical maximum Capacity in
bits per second of a particular communications channel. A close
approximation of Shannonâs famous formula is:
C = .332 * (Bandwidth) * (SNR) ,
where B=Bandwidth in Hz, and SNR is in dB (decibels)
5. Mathematical Relationship b/w Bandwidth
and Power
E = h * (c / lambda)
E = h * f
T = 1/f
F(frequency) increases, Time to transfer a bit decreases.
ï Bitrate increases
ï f ~ bandwidth
ï E ~ bandwidth
ïPower ~ bandwidth