sosfilt: Second-order sections filtering
In gjmvanboxtel/gsignal: Signal Processing
sosfilt R Documentation
Second-order sections filtering
Description
One-dimensional second-order (biquadratic) sections IIR digital filtering.
Usage
sosfilt(sos, x, zi = NULL)
Arguments
sos
Second-order section representation, specified as an nrow-by-6
matrix, whose rows contain the numerator and denominator coefficients of
the second-order sections:
sos <- rbind(cbind(B1, A1), cbind(...),
cbind(Bn, An)), where B1 <- c(b0, b1, b2), and A1 <- c(a0,
a1, a2) for section 1, etc. The b0 entry must be nonzero for each section.
x
the input signal to be filtered, specified as a numeric or complex
vector or matrix. If x is a matrix, each column is filtered.
zi
If zi is provided, it is taken as the initial state of the
system and the final state is returned as zf. If x is a vector,
zi must be a matrix with nrow(sos) rows and 2 columns. If
x is a matrix, then zi must be a 3-dimensional array of size
(nrow(sos), 2, ncol(x)). Alternatively, zi may be the
character string "zf", which specifies to return the final state
vector even though the initial state vector is set to all zeros. Default:
NULL.
Details
The filter function is implemented as a series of second-order filters
with direct-form II transposed structure. It is designed to minimize
numerical precision errors for high-order filters [1].
Value
The filtered signal, of the same dimensions as the input signal. In
case the zi input argument was specified, a list with two elements
is returned containing the variables y, which represents the output
signal, and zf, which contains the final state vector or matrix.
Author(s)
Geert van Boxtel, G.J.M.vanBoxtel@gmail.com.
References
Smith III, J.O. (2012). Introduction to digital filters, with
audio applications (3rd Ed.). W3K Publishing.
See Also
filter, filtfilt, Sos
Examples
fs <- 1000
t <- seq(0, 1, 1/fs)
s <- sin(2* pi * t * 6)
x <- s + rnorm(length(t))
plot(t, x, type = "l", col="light gray")
lines(t, s, col="black")
sosg <- butter(3, 0.02, output = "Sos")
sos <- sosg$sos
sos[1, 1:3] <- sos[1, 1:3] * sosg$g
y <- sosfilt(matrix(sos, ncol=6), x)
lines(t, y, col="red")
## using 'filter' will handle the gain for you
y2 <- filter(sosg, x)
all.equal(y, y2)
## The following example is from Python scipy.signal.sosfilt
## It shows the instability that results from trying to do a
## 13th-order filter in a single stage (the numerical error
## pushes some poles outside of the unit circle)
arma <- ellip(13, 0.009, 80, 0.05, output='Arma')
sos <- ellip(13, 0.009, 80, 0.05, output='Sos')
x <- rep(0, 700); x[1] <- 1
y_arma <- filter(arma, x)
y_sos <- filter(sos, x)
plot(y_arma, type ="l")
lines (y_sos, col = 2)
legend("topleft", legend = c("Arma", "Sos"), lty = 1, col = 1:2)
gjmvanboxtel/gsignal documentation built on Nov. 22, 2023, 8:19 p.m.
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| sosfilt | R Documentation |
Second-order sections filtering
Description
One-dimensional second-order (biquadratic) sections IIR digital filtering.
Usage
sosfilt(sos, x, zi = NULL)
Arguments
sos |
Second-order section representation, specified as an nrow-by-6
matrix, whose rows contain the numerator and denominator coefficients of
the second-order sections: |
x |
the input signal to be filtered, specified as a numeric or complex
vector or matrix. If |
zi |
If |
Details
The filter function is implemented as a series of second-order filters with direct-form II transposed structure. It is designed to minimize numerical precision errors for high-order filters [1].
Value
The filtered signal, of the same dimensions as the input signal. In
case the zi input argument was specified, a list with two elements
is returned containing the variables y, which represents the output
signal, and zf, which contains the final state vector or matrix.
Author(s)
Geert van Boxtel, G.J.M.vanBoxtel@gmail.com.
References
Smith III, J.O. (2012). Introduction to digital filters, with audio applications (3rd Ed.). W3K Publishing.
See Also
filter, filtfilt, Sos
Examples
fs <- 1000
t <- seq(0, 1, 1/fs)
s <- sin(2* pi * t * 6)
x <- s + rnorm(length(t))
plot(t, x, type = "l", col="light gray")
lines(t, s, col="black")
sosg <- butter(3, 0.02, output = "Sos")
sos <- sosg$sos
sos[1, 1:3] <- sos[1, 1:3] * sosg$g
y <- sosfilt(matrix(sos, ncol=6), x)
lines(t, y, col="red")
## using 'filter' will handle the gain for you
y2 <- filter(sosg, x)
all.equal(y, y2)
## The following example is from Python scipy.signal.sosfilt
## It shows the instability that results from trying to do a
## 13th-order filter in a single stage (the numerical error
## pushes some poles outside of the unit circle)
arma <- ellip(13, 0.009, 80, 0.05, output='Arma')
sos <- ellip(13, 0.009, 80, 0.05, output='Sos')
x <- rep(0, 700); x[1] <- 1
y_arma <- filter(arma, x)
y_sos <- filter(sos, x)
plot(y_arma, type ="l")
lines (y_sos, col = 2)
legend("topleft", legend = c("Arma", "Sos"), lty = 1, col = 1:2)
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