Stochastic processes and boundary value problems

In communications systems, a communication channel may change with time. Coherence time is the time duration over which the channel impulse response is considered to be not varying. Such channel variation is much more significant in wireless communications systems, due to Doppler effects.

Simple model

In a simple model, a signal ${\displaystyle x(t)}$ transmitted at time ${\displaystyle t_1}$ will be received as

${\displaystyle y_{t_1}(t)=x(t-t_1)*h_{t_1}(t),}$

where ${\displaystyle h_{t_1}(t)}$ is the channel impulse response (CIR) at time ${\displaystyle t_1}$. A signal transmitted at time ${\displaystyle t_2}$ will be received as

${\displaystyle y_{t_2}(t)=x(t-t_2)*h_{t_2}(t).}$

Now, if ${\displaystyle h_{t_1}(t)-h_{t_2}(t)}$ is relatively small, the channel may be considered constant within the interval ${\displaystyle t_1}$ to ${\displaystyle t_2}$.

Coherence time (${\displaystyle T_c}$) will therefore be given by

${\displaystyle T_c=t_2-t_1.}$

Relation with Doppler frequency

Using Clarke's model, from the maximum Doppler frequency ${\displaystyle f_d}$ we can obtain 50% coherence time ^[1][2]

${\displaystyle T_c=\sqrt{\frac{9}{16\pi f_d^2}}}$

Usually, we use the following relation^[2]

${\displaystyle T_c=\sqrt{\frac{9}{16\pi }}\frac{1}{f_d}\simeq \frac{0.423}{f_d}}$

References

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