Lectionary 60: Difference between revisions
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In [[Filtering problem (stochastic processes)|filtering theory]] the '''Kushner equation'''<ref>[[Harold J. Kushner|Kushner H.J.]] (1964) ''On the differential equations satisfied by conditional probability | |||
densities of Markov processes, with applications.''. J. SIAM Control Ser. A, 2(1), pp. 106-119.</ref> (after Harold Kushner) is an equation for the [[conditional probability]] [[probability density function|density]] of the state of a [[stochastic process|stochastic]] non-linear [[dynamical system]], given noisy measurements of the state. It therefore provides the solution of the [[nonlinear filter]]ing problem in [[estimation theory]]. The equation is sometimes referred to as the '''Stratonovich–Kushner'''<ref>[[Ruslan L. Stratonovich|Stratonovich, R.L.]] (1959). ''Optimum nonlinear systems which bring about a separation of a signal with constant parameters from noise''. Radiofizika, 2:6, pp. 892–901.</ref><ref>[[Ruslan L. Stratonovich|Stratonovich, R.L.]] (1959). ''On the theory of optimal non-linear filtering of random functions''. Theory of Probability and its Applications, 4, pp. 223–225.</ref><ref>[[Ruslan L. Stratonovich|Stratonovich, R.L.]] (1960) ''Application of the Markov processes theory to optimal filtering''. Radio Engineering and Electronic Physics, 5:11, pp. 1–19.</ref><ref>[[Ruslan L. Stratonovich|Stratonovich, R.L.]] (1960). ''Conditional Markov Processes''. Theory of Probability and its Applications, 5, pp. 156–178.</ref> (or Kushner–Stratonovich) '''equation'''. However, the correct equation in terms of [[Itō calculus]] was first derived by Kushner although a more heuristic Stratonovich version of it appeared already in Stratonovich's works in late fifties. However, the derivation in terms of Itō calculus is due to Bucy.<ref>[[Bucy, R. S.]] (1965) ''Nonlinear filtering theory''. IEEE Transactions on Automatic Control, | |||
10, pp. 198–198. [http://ieeexplore.ieee.org/xploreAssets/images/absImages/01098109.png]</ref> | |||
== Overview == | |||
Assume the state of the system evolves according to | |||
:<math>dx = f(x,t) \, dt + \sigma dw</math> | |||
and a noisy measurement of the system state is available: | |||
:<math>dz = h(x,t) \, dt + \eta dv</math> | |||
where ''w'', ''v'' are independent [[Wiener process]]es. Then the conditional probability density ''p''(''x'', ''t'') of the state at time ''t'' is given by the Kushner equation: | |||
:<math>dp(x,t) = L[p(x,t)] dt + p(x,t) [h(x,t)-E_t h(x,t) ]^T \eta^{-\top}\eta^{-1} [dz-E_t h(x,t) dt].</math> | |||
where <math>L p = -\sum \frac{\partial (f_i p)}{\partial x_i} + \frac{1}{2} \sum (\sigma \sigma^\top)_{i,j} \frac{\partial^2 p}{\partial x_i \partial x_j}</math> is the Kolmogorov Forward operator and <math>dp(x,t) = p(x,t + dt) - p(x,t)</math> is the variation of the conditional probability. | |||
The term <math>dz-E_t h(x,t) dt</math> is the [[innovation (signal processing)|innovation]] i.e. the difference between the measurement and its expected value. | |||
===Kalman-Bucy filter=== | |||
One can simply use the Kushner equation to derive the [[Kalman-Bucy filter]] for a linear diffusion process. Suppose we have <math> f(x,t) = a x</math> and <math> h(x,t) = c x </math>. The Kushner equation will be given by | |||
:<math> | |||
dp(x,t) = L[p(x,t)] dt + p(x,t) [c x- c \mu(t)]^T \eta^{-\top}\eta^{-1} [dz-c \mu(t) dt], | |||
</math> | |||
where <math> \mu(t) </math> is the mean of the conditional probability at time <math> t</math>. Multiplying by <math> x</math> and integrating over it, we obtain the variation of the mean | |||
:<math> | |||
d\mu(t) = a \mu(t) dt + \Sigma(t) c^\top \eta^{-\top}\eta^{-1} \left(dz - c\mu(t) dt\right). | |||
</math> | |||
Likewise, the variation of the variance <math>\Sigma(t)</math> is given by | |||
:<math> | |||
\frac{d\Sigma(t)}{dt} = a\Sigma(t) + \Sigma(t) a^\top + \sigma^\top \sigma-\Sigma(t) c^\top\eta^{-\top} \eta^{-1} c \Sigma(t). | |||
</math> | |||
The conditional probability is then given at every instant by a normal distribution <math>\mathcal{N}(\mu(t),\Sigma(t))</math>. | |||
== References == | |||
<references /> | |||
== See also == | |||
*[[Zakai equation]] | |||
[[Category:Signal processing]] | |||
[[Category:Estimation theory]] | |||
[[Category:Stochastic processes]] | |||
[[Category:Nonlinear filters]] | |||
Revision as of 16:04, 19 November 2013
In filtering theory the Kushner equation[1] (after Harold Kushner) is an equation for the conditional probability density of the state of a stochastic non-linear dynamical system, given noisy measurements of the state. It therefore provides the solution of the nonlinear filtering problem in estimation theory. The equation is sometimes referred to as the Stratonovich–Kushner[2][3][4][5] (or Kushner–Stratonovich) equation. However, the correct equation in terms of Itō calculus was first derived by Kushner although a more heuristic Stratonovich version of it appeared already in Stratonovich's works in late fifties. However, the derivation in terms of Itō calculus is due to Bucy.[6]
Overview
Assume the state of the system evolves according to
and a noisy measurement of the system state is available:
where w, v are independent Wiener processes. Then the conditional probability density p(x, t) of the state at time t is given by the Kushner equation:
![{\displaystyle dp(x,t)=L[p(x,t)]dt+p(x,t)[h(x,t)-E_{t}h(x,t)]^{T}\eta ^{-\top }\eta ^{-1}[dz-E_{t}h(x,t)dt].}](https://wikimedia.org/api/rest_v1/media/math/render/svg/4fef4ab4b20c1e4156af905378e06db39362b3c9)
where is the Kolmogorov Forward operator and is the variation of the conditional probability.
The term is the innovation i.e. the difference between the measurement and its expected value.
Kalman-Bucy filter
One can simply use the Kushner equation to derive the Kalman-Bucy filter for a linear diffusion process. Suppose we have and . The Kushner equation will be given by
![{\displaystyle dp(x,t)=L[p(x,t)]dt+p(x,t)[cx-c\mu (t)]^{T}\eta ^{-\top }\eta ^{-1}[dz-c\mu (t)dt],}](https://wikimedia.org/api/rest_v1/media/math/render/svg/b5868db92d3c577046330e5287736294c60e146e)
where is the mean of the conditional probability at time . Multiplying by and integrating over it, we obtain the variation of the mean
Likewise, the variation of the variance is given by
The conditional probability is then given at every instant by a normal distribution .
References
- ↑ Kushner H.J. (1964) On the differential equations satisfied by conditional probability densities of Markov processes, with applications.. J. SIAM Control Ser. A, 2(1), pp. 106-119.
- ↑ Stratonovich, R.L. (1959). Optimum nonlinear systems which bring about a separation of a signal with constant parameters from noise. Radiofizika, 2:6, pp. 892–901.
- ↑ Stratonovich, R.L. (1959). On the theory of optimal non-linear filtering of random functions. Theory of Probability and its Applications, 4, pp. 223–225.
- ↑ Stratonovich, R.L. (1960) Application of the Markov processes theory to optimal filtering. Radio Engineering and Electronic Physics, 5:11, pp. 1–19.
- ↑ Stratonovich, R.L. (1960). Conditional Markov Processes. Theory of Probability and its Applications, 5, pp. 156–178.
- ↑ Bucy, R. S. (1965) Nonlinear filtering theory. IEEE Transactions on Automatic Control, 10, pp. 198–198. [1]
![[1]](http://ieeexplore.ieee.org/xploreAssets/images/absImages/01098109.png){kind=link}