ANALOG COMMUNICATION Lecture 03

Signal Transmission over

Communication Channel

Lesson 03

EE352 Analog Communication Systems

Mansoor Khan

Signal Transmission over a Linear

Channel

For an LTI, continuous time system the input output relation is given by:

where g(t) is the input(transmitted signal) on channel, h(t) is the impulse response of a LTI channel and y(t) is the convolution output of g(t) and h(t) as shown above. If

where H(w) is the system transfer function, the from the time convolution property:

Signal Distortion in Transmission

• During transmission the input signal changes

from g(t) to output signal

y(t)

as shown

before.

• The

equation

below

illustrates

the

modification of g(t):

Where G(w) and Y(w) are the spectra of input

output signals respectively.

• Spectral shaping of input signal by spectral response

of the system is given by(polar form):

• During transmission the spectrum of input signal changes:

amplitude changes from |G(w)| to |G(w)||H(w)| and

phase changes from θg to θg+θw.

• During transmission some frequency components of

signal are boosted and some are attenuated the

relative phases also vary. In general signal received at

the receiver side is different from transmitted one.

Distortionless Transmission

• Requirement :

output waveform be the replica

of input signal.

• Characteristics

of a distortionless channel:

I. The input and output waveform are identical within a multiplicative constant.

II. A delayed output retaining the input waveform.

Thus in a distortionless channel g(t) and y(t) should satisfy the

condition:

• This shows that for a distortionless channel the amplitude

response |H(w)| must be constant and phase response

θ

(w)

must be the linear function of w.

LTI sytem frequency response of a distortionless system. The slope

θ

If the slope remains constant over the band of interest then each frequency component of g(t) undergoes same time delay, but if

amplitude response and phase response vary over the w(freq) scale different frequency components(sinusoids) in g(t) will undergo

different attenuations and phase delays (varying with the frequncy) as a result the output signal will not be the exact replica of input.

Ideal and Practical Filters

Ideal filters(systems) allows distortionless transmission of input signals allowing certain band of frequencies and suppressing remaining frequencies. For example an ideal low pass filter below allows all frequency components below ω = W rad/s to pass through without attenuation and suppress all others above W rad/s. Phase slope θ(w) is linear (-td) over ω scale which results in a time delay of –td for all

frequency components below W rad/s.

Hence for an input signal g(t) bandlimited to W rad/s the output y(t) is g(t) delayed by td.

Since h(t) is the response to the impulse δ(t)

applied at t = 0. The response should be causal

i.e.

h(t) = 0 for t < 0.

The impulse response got previously clearly

shows that h(t) ≠ 0 for t < 0, making the filter

noncausal and not realizable.

• Practical filters have gradual characteristics

without any discontinuities or jumps as in non

causal filters.

• Well known is the butterworth filter for

example have the amplitude response of:

The amplitude response approaches ideal for

(order of filter

n

) n = ∞

A certain tradeoff exists between phase and

amplitude response if order of filter is increased the phase

response is distorted badly from ideal.

Signal Distortion over a

Communication Channel

• Signal distortion in LTI channels are caused by non ideal characteristics of amplitude or phase response or both. Suppose a pulse exist over an interval say (a , b) and is zero elsewhere, the components of its Fourier spectrum phase and magnitude will add in such a way that it is zero elsewhere of interval and exists in (a , b). For an ideal LTI channel frequency spectrum components are multiplied by same constant and frequency components delayed by the same interval resulting in the output replica of input. If for non idealities frequency components are delayed by different intervals and attenuated by different amounts due to non ideal phase or amp characteristics the pulse would spread outside the interval.

• This pulse spreading is highly undesirable in TDM systems where it causes interference with neighboring pulses and consequently with neighboring channel resulting in crosstalk.

Example of non ideal LTI Channel

A low pass filter with transfer function H(ω) shown below is given by:

Distortion caused by Non Linear

Channels

Consider an input g and its corresponding output y of a channel related by the following equation where f() is a nonlinear function:

y = f(g)

Expanding the right handside of above equation by Mclaurin’s series as:

Using the property if the bandwidth of input signal g(t) is B Hz then g^κ is kB Hz. Hence output y(t) in the above expression will have bandwidth kB Hz, thus output spectrum extend well beyond the input spectrum giving rise to new frequency components not contained in the input previously. If the signal is transmitted over a non linear channel it will cause serious interference

with other signals on the channel (spectral spreading). The problem is more severe in FDM systems(not in TDM)

Distortion Caused by Multipath Effects

• Arrival of transmitted signal at the receiver by

two or more paths with different delays.

• Transmission channel can be modeled as two or

more parallel channels over which the same

signal travels with varying delay and attenuations.

• For example reflections from hills, buildings and

other objects in the path of transmitter and

receiver, resulting in direct wave plus reflections

arriving at receiver end.

Consider a case of two paths one with the delay of

t

and

unity gain

and other with the

gain of α and delay of t

+ Δ

.

The transfer function of both channels are given by

• exp(-jωt

)

• α exp(-jω(t

+ Δ))

Overall Transfer function H(ω) of parallel channels is given by:

H(ω) = exp(-jωt

)+α exp(-jω(t

+ Δ))

The magnitude and phase response of H(ω) of the system are periodic in ω with the period of 2*pi/ Δt. The multipath transmission therefore causes non idealities in amplitude and phase characteristics of channel resulting in pulse dispersion(spectral spreading) of input signal.

If the gains of both channels are near to each other the received signal undergoes destructive interference where the phases are pi radians apart. These frequencies are

multipath null frequencies (n*pi/ Δt) n is odd. For even n there is a constructive

interference and gain is enhanced. Such channels cause frequency selective fading of transmitted signal.

Fading Channels

• Characteristics of channel vary with time practically

especially long range radio communication systems using

ionosphere for reflection of transmitted signal the channel

characteristics vary with the seasonal or weather

conditions heavily.

• Random changes in the propagation characteristics of

channel.

• Random changes in channel transfer function results in

random signal attenuation and frequency delay.

• Different

frequency

components

suffer

unequal

attenuation and phase delays such fading is known as

frequency selective fading. Multipath propagation can

cause frequency selective fading.