Difference between revisions of "Gaussian channel"
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− | + | A [[Communication channel|communication channel]] whose transition function determines a conditional Gaussian distribution. More precisely, a communication channel $ ( Q , V ) $ | |
+ | is called a Gaussian channel on the finite interval $ [ 0 , T ] $ | ||
+ | if the following conditions hold: 1) the spaces of values of the input and output signals, $ ( {\mathcal Y} , {\mathcal S} _ {\mathcal Y} ) $ | ||
+ | and $ ( \widetilde {\mathcal Y} , {\mathcal S} _ {\widetilde {\mathcal Y} } ) $, | ||
+ | are spaces of real-valued functions $ y ( t) $ | ||
+ | and $ \widetilde{y} ( t) $, | ||
+ | $ t \in [ 0 , T ] $, | ||
+ | with the usual $ \sigma $- | ||
+ | algebras of measurable sets (that is, the input and output signals of a Gaussian channel are given by stochastic processes $ \eta = \{ {\eta ( t) } : {t \in [ 0 , T ] } \} $ | ||
+ | and $ \widetilde \eta = \{ {\widetilde \eta ( t) } : {t \in [ 0 , T ] } \} $, | ||
+ | respectively); 2) for any fixed $ y \in Y $ | ||
+ | the transition function $ Q ( y , \cdot ) $ | ||
+ | of the channel determines a conditional Gaussian distribution (one says that a collection of random variables has a conditional Gaussian distribution if every finite subfamily has a conditional finite-dimensional [[Normal distribution|normal distribution]] with second moments that are independent of the conditioning); and 3) the restriction $ V $ | ||
+ | is imposed only on the second moment of the random variable $ \eta $. | ||
− | + | An example of a Gaussian channel on $ ( - \infty , \infty ) $ | |
+ | is a channel whose input signal is given by a stationary random sequence $ \eta = (\dots, \eta _ {-} 1 , \eta _ {0} , \eta _ {1} ,\dots ) $ | ||
+ | and whose output signal is the stationary random sequence $ \widetilde \eta = ( \dots, \widetilde \eta _ {-} 1 , \widetilde \eta _ {0} , \widetilde \eta _ {1} ,\dots ) $, | ||
+ | obtained according to the formulas | ||
− | + | $$ | |
+ | \widetilde \eta _ {i} = \ | ||
+ | \sum _ {k = - \infty } ^ \infty | ||
+ | a _ {k} \eta _ {i-} k + \zeta _ {i} ,\ \ | ||
+ | i = 0 , \pm 1 , \pm 2 \dots | ||
+ | $$ | ||
− | where | + | where $ \zeta = ( \dots, \zeta _ {-} 1 , \zeta _ {0} , \zeta _ {1} ,\dots ) $ |
+ | is a stationary Gaussian random sequence independent of $ \eta $ | ||
+ | with $ {\mathsf E} \zeta _ {i} = 0 $, | ||
+ | $ i = \pm 1 , \pm 2 \dots $ | ||
+ | and with spectral density $ f _ \zeta ( \lambda ) $, | ||
+ | $ - 1 / 2 \leq \lambda \leq 1 / 2 $. | ||
+ | The restriction on the input signal has the form | ||
− | + | $$ | |
+ | \int\limits _ {- 1 / 2 } ^ { {1 } / 2 } | ||
+ | | \Phi ( \lambda ) | ^ {2} | ||
+ | f _ \eta ( \lambda ) d \lambda | ||
+ | \leq S , | ||
+ | $$ | ||
− | where | + | where $ f _ \eta ( \lambda ) $ |
+ | is the spectral density of $ \eta $, | ||
+ | $ \phi ( \lambda ) $ | ||
+ | is some function and $ S $ | ||
+ | is a constant. The capacity of such a channel is given by the formula | ||
− | + | $$ | |
+ | C = | ||
+ | \frac{1}{2} | ||
+ | |||
+ | \int\limits _ {- 1 / 2 } ^ { {1 } / 2 } | ||
+ | { \mathop{\rm log} \max } \ | ||
+ | \left [ \left | | ||
+ | |||
+ | \frac{a ( \lambda ) }{\Phi ( \lambda ) } | ||
+ | |||
+ | \right | ^ {2} \cdot | ||
+ | \frac \mu {f _ \zeta ( \lambda ) } | ||
+ | , 1 | ||
+ | \right ] \ | ||
+ | d \lambda = S , | ||
+ | $$ | ||
+ | |||
+ | where $ a ( \lambda ) = \sum _ {k = - \infty } ^ \infty e ^ {- 2 \pi i k \lambda } $ | ||
+ | and $ \mu $ | ||
+ | is determined by the equation | ||
+ | |||
+ | $$ | ||
+ | \int\limits _ { - } 1/2 ^ { 1/2 } | ||
+ | \max | ||
+ | \left [ | ||
+ | \mu - \left | | ||
+ | |||
+ | \frac{\Phi ( \lambda ) }{a ( \lambda ) } | ||
+ | \ | ||
+ | \right | ^ {2} | ||
+ | f _ \zeta ( \lambda ) , 0 | ||
+ | \right ] d \lambda = S . | ||
+ | $$ | ||
See also [[#References|[1]]], , | See also [[#References|[1]]], , |
Revision as of 19:41, 5 June 2020
A communication channel whose transition function determines a conditional Gaussian distribution. More precisely, a communication channel $ ( Q , V ) $
is called a Gaussian channel on the finite interval $ [ 0 , T ] $
if the following conditions hold: 1) the spaces of values of the input and output signals, $ ( {\mathcal Y} , {\mathcal S} _ {\mathcal Y} ) $
and $ ( \widetilde {\mathcal Y} , {\mathcal S} _ {\widetilde {\mathcal Y} } ) $,
are spaces of real-valued functions $ y ( t) $
and $ \widetilde{y} ( t) $,
$ t \in [ 0 , T ] $,
with the usual $ \sigma $-
algebras of measurable sets (that is, the input and output signals of a Gaussian channel are given by stochastic processes $ \eta = \{ {\eta ( t) } : {t \in [ 0 , T ] } \} $
and $ \widetilde \eta = \{ {\widetilde \eta ( t) } : {t \in [ 0 , T ] } \} $,
respectively); 2) for any fixed $ y \in Y $
the transition function $ Q ( y , \cdot ) $
of the channel determines a conditional Gaussian distribution (one says that a collection of random variables has a conditional Gaussian distribution if every finite subfamily has a conditional finite-dimensional normal distribution with second moments that are independent of the conditioning); and 3) the restriction $ V $
is imposed only on the second moment of the random variable $ \eta $.
An example of a Gaussian channel on $ ( - \infty , \infty ) $ is a channel whose input signal is given by a stationary random sequence $ \eta = (\dots, \eta _ {-} 1 , \eta _ {0} , \eta _ {1} ,\dots ) $ and whose output signal is the stationary random sequence $ \widetilde \eta = ( \dots, \widetilde \eta _ {-} 1 , \widetilde \eta _ {0} , \widetilde \eta _ {1} ,\dots ) $, obtained according to the formulas
$$ \widetilde \eta _ {i} = \ \sum _ {k = - \infty } ^ \infty a _ {k} \eta _ {i-} k + \zeta _ {i} ,\ \ i = 0 , \pm 1 , \pm 2 \dots $$
where $ \zeta = ( \dots, \zeta _ {-} 1 , \zeta _ {0} , \zeta _ {1} ,\dots ) $ is a stationary Gaussian random sequence independent of $ \eta $ with $ {\mathsf E} \zeta _ {i} = 0 $, $ i = \pm 1 , \pm 2 \dots $ and with spectral density $ f _ \zeta ( \lambda ) $, $ - 1 / 2 \leq \lambda \leq 1 / 2 $. The restriction on the input signal has the form
$$ \int\limits _ {- 1 / 2 } ^ { {1 } / 2 } | \Phi ( \lambda ) | ^ {2} f _ \eta ( \lambda ) d \lambda \leq S , $$
where $ f _ \eta ( \lambda ) $ is the spectral density of $ \eta $, $ \phi ( \lambda ) $ is some function and $ S $ is a constant. The capacity of such a channel is given by the formula
$$ C = \frac{1}{2} \int\limits _ {- 1 / 2 } ^ { {1 } / 2 } { \mathop{\rm log} \max } \ \left [ \left | \frac{a ( \lambda ) }{\Phi ( \lambda ) } \right | ^ {2} \cdot \frac \mu {f _ \zeta ( \lambda ) } , 1 \right ] \ d \lambda = S , $$
where $ a ( \lambda ) = \sum _ {k = - \infty } ^ \infty e ^ {- 2 \pi i k \lambda } $ and $ \mu $ is determined by the equation
$$ \int\limits _ { - } 1/2 ^ { 1/2 } \max \left [ \mu - \left | \frac{\Phi ( \lambda ) }{a ( \lambda ) } \ \right | ^ {2} f _ \zeta ( \lambda ) , 0 \right ] d \lambda = S . $$
See also [1], ,
cited in Communication channel.
References
[1] | J.M. Wozencraft, I.M. Jacobs, "Principles of communication engineering" , Wiley (1965) |
Gaussian channel. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Gaussian_channel&oldid=47054