xDcusum.arl: Compute ARLs of CUSUM control charts under drift
In spc: Statistical Process Control -- Calculation of ARL and Other Control Chart Performance Measures
xDcusum.arl R Documentation
Compute ARLs of CUSUM control charts under drift
Description
Computation of the (zero-state and other) Average Run Length (ARL)
under drift for one-sided CUSUM control charts monitoring normal mean.
Usage
xDcusum.arl(k, h, delta, hs = 0, sided = "one",
mode = "Gan", m = NULL, q = 1, r = 30, with0 = FALSE)
Arguments
k
reference value of the CUSUM control chart.
h
decision interval (alarm limit, threshold) of the CUSUM control chart.
delta
true drift parameter.
hs
so-called headstart (enables fast initial response).
sided
distinguishes between one- and two-sided CUSUM control chart
by choosing "one" and "two", respectively. Currentlly,
the two-sided scheme is not implemented.
mode
decide whether Gan's or Knoth's approach is used. Use
"Gan" and "Knoth", respectively.
m
parameter used if mode="Gan". m is design
parameter of Gan's approach. If m=NULL, then m
will increased until the resulting ARL does not change anymore.
q
change point position. For q=1 and
μ=μ_0 and μ=μ_1, the usual
zero-state ARLs for the in-control and out-of-control case, respectively,
are calculated. For q>1 and μ!=0 conditional delays, that is,
E_q(L-q+1|L≥q), will be determined.
Note that mu0=0 is implicitely fixed. Deploy large q to mimic
steady-state. It works only for mode="Knoth".
r
number of quadrature nodes, dimension of the resulting linear
equation system is equal to r+1 (one-sided) or r
(two-sided).
with0
defines whether the first observation used for the RL
calculation follows already 1*delta or still 0*delta.
With q additional flexibility is given.
Details
Based on Gan (1991) or Knoth (2003), the ARL is calculated for
one-sided CUSUM
control charts under drift. In case of Gan's framework, the usual
ARL function with mu=m*delta is determined and recursively via
m-1, m-2, ... 1 (or 0) the drift ARL determined. The framework
of Knoth allows to calculate ARLs for varying parameters, such as
control limits and distributional parameters.
For details see the cited papers. Note that two-sided CUSUM charts
under drift are difficult to treat.
Value
Returns a single value which resembles the ARL.
Author(s)
Sven Knoth
References
F. F. Gan (1992),
CUSUM control charts under linear drift,
Statistician 41, 71-84.
F. F. Gan (1996),
Average Run Lengths for Cumulative Sum control chart under linear trend,
Applied Statistics 45, 505-512.
S. Knoth (2003),
EWMA schemes with non-homogeneous transition kernels,
Sequential Analysis 22, 241-255.
S. Knoth (2012),
More on Control Charting under Drift,
in: Frontiers in Statistical Quality Control 10,
H.-J. Lenz, W. Schmid and P.-T. Wilrich (Eds.),
Physica Verlag, Heidelberg, Germany, 53-68.
C. Zou, Y. Liu and Z. Wang (2009),
Comparisons of control schemes for monitoring
the means of processes subject to drifts,
Metrika 70, 141-163.
See Also
xcusum.arl and xcusum.ad for zero-state and
steady-state ARL computation of CUSUM control charts
for the classical step change model.
Examples
## Gan (1992)
## Table 1
## original values are
# deltas arl
# 0.0001 475
# 0.0005 261
# 0.0010 187
# 0.0020 129
# 0.0050 76.3
# 0.0100 52.0
# 0.0200 35.2
# 0.0500 21.4
# 0.1000 15.0
# 0.5000 6.95
# 1.0000 5.16
# 3.0000 3.30
## Not run: k <- .25
h <- 8
r <- 50
DxDcusum.arl <- Vectorize(xDcusum.arl, "delta")
deltas <- c(0.0001, 0.0005, 0.001, 0.002, 0.005, 0.01, 0.02, 0.05, 0.1, 0.5, 1, 3)
arl.like.Gan <-
round(DxDcusum.arl(k, h, deltas, r=r, with0=TRUE), digits=2)
arl.like.Knoth <-
round(DxDcusum.arl(k, h, deltas, r=r, mode="Knoth", with0=TRUE), digits=2)
data.frame(deltas, arl.like.Gan, arl.like.Knoth)
## End(Not run)
## Zou et al. (2009)
## Table 1
## original values are
# delta arl1 arl2 arl3
# 0 ~ 1730
# 0.0005 345 412 470
# 0.001 231 275 317
# 0.005 86.6 98.6 112
# 0.01 56.9 61.8 69.3
# 0.05 22.6 21.6 22.7
# 0.1 15.4 14.7 14.2
# 0.5 6.60 5.54 5.17
# 1.0 4.63 3.80 3.45
# 2.0 3.17 2.67 2.32
# 3.0 2.79 2.04 1.96
# 4.0 2.10 1.98 1.74
## Not run:
k1 <- 0.25
k2 <- 0.5
k3 <- 0.75
h1 <- 9.660
h2 <- 5.620
h3 <- 3.904
deltas <- c(0.0005, 0.001, 0.005, 0.01, 0.05, 0.1, 0.5, 1:4)
arl1 <- c(round(xcusum.arl(k1, h1, 0, r=r), digits=2),
round(DxDcusum.arl(k1, h1, deltas, r=r), digits=2))
arl2 <- c(round(xcusum.arl(k2, h2, 0), digits=2),
round(DxDcusum.arl(k2, h2, deltas, r=r), digits=2))
arl3 <- c(round(xcusum.arl(k3, h3, 0, r=r), digits=2),
round(DxDcusum.arl(k3, h3, deltas, r=r), digits=2))
data.frame(delta=c(0, deltas), arl1, arl2, arl3)
## End(Not run)
spc documentation built on Oct. 24, 2022, 5:07 p.m.
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| xDcusum.arl | R Documentation |
Compute ARLs of CUSUM control charts under drift
Description
Computation of the (zero-state and other) Average Run Length (ARL) under drift for one-sided CUSUM control charts monitoring normal mean.
Usage
xDcusum.arl(k, h, delta, hs = 0, sided = "one",
mode = "Gan", m = NULL, q = 1, r = 30, with0 = FALSE)
Arguments
k |
reference value of the CUSUM control chart. |
h |
decision interval (alarm limit, threshold) of the CUSUM control chart. |
delta |
true drift parameter. |
hs |
so-called headstart (enables fast initial response). |
sided |
distinguishes between one- and two-sided CUSUM control chart
by choosing |
mode |
decide whether Gan's or Knoth's approach is used. Use
|
m |
parameter used if |
q |
change point position. For q=1 and
μ=μ_0 and μ=μ_1, the usual
zero-state ARLs for the in-control and out-of-control case, respectively,
are calculated. For q>1 and μ!=0 conditional delays, that is,
E_q(L-q+1|L≥q), will be determined.
Note that mu0=0 is implicitely fixed. Deploy large |
r |
number of quadrature nodes, dimension of the resulting linear
equation system is equal to |
with0 |
defines whether the first observation used for the RL
calculation follows already 1*delta or still 0*delta.
With |
Details
Based on Gan (1991) or Knoth (2003), the ARL is calculated for one-sided CUSUM control charts under drift. In case of Gan's framework, the usual ARL function with mu=m*delta is determined and recursively via m-1, m-2, ... 1 (or 0) the drift ARL determined. The framework of Knoth allows to calculate ARLs for varying parameters, such as control limits and distributional parameters. For details see the cited papers. Note that two-sided CUSUM charts under drift are difficult to treat.
Value
Returns a single value which resembles the ARL.
Author(s)
Sven Knoth
References
F. F. Gan (1992), CUSUM control charts under linear drift, Statistician 41, 71-84.
F. F. Gan (1996), Average Run Lengths for Cumulative Sum control chart under linear trend, Applied Statistics 45, 505-512.
S. Knoth (2003), EWMA schemes with non-homogeneous transition kernels, Sequential Analysis 22, 241-255.
S. Knoth (2012), More on Control Charting under Drift, in: Frontiers in Statistical Quality Control 10, H.-J. Lenz, W. Schmid and P.-T. Wilrich (Eds.), Physica Verlag, Heidelberg, Germany, 53-68.
C. Zou, Y. Liu and Z. Wang (2009), Comparisons of control schemes for monitoring the means of processes subject to drifts, Metrika 70, 141-163.
See Also
xcusum.arl and xcusum.ad for zero-state and
steady-state ARL computation of CUSUM control charts
for the classical step change model.
Examples
## Gan (1992)
## Table 1
## original values are
# deltas arl
# 0.0001 475
# 0.0005 261
# 0.0010 187
# 0.0020 129
# 0.0050 76.3
# 0.0100 52.0
# 0.0200 35.2
# 0.0500 21.4
# 0.1000 15.0
# 0.5000 6.95
# 1.0000 5.16
# 3.0000 3.30
## Not run: k <- .25
h <- 8
r <- 50
DxDcusum.arl <- Vectorize(xDcusum.arl, "delta")
deltas <- c(0.0001, 0.0005, 0.001, 0.002, 0.005, 0.01, 0.02, 0.05, 0.1, 0.5, 1, 3)
arl.like.Gan <-
round(DxDcusum.arl(k, h, deltas, r=r, with0=TRUE), digits=2)
arl.like.Knoth <-
round(DxDcusum.arl(k, h, deltas, r=r, mode="Knoth", with0=TRUE), digits=2)
data.frame(deltas, arl.like.Gan, arl.like.Knoth)
## End(Not run)
## Zou et al. (2009)
## Table 1
## original values are
# delta arl1 arl2 arl3
# 0 ~ 1730
# 0.0005 345 412 470
# 0.001 231 275 317
# 0.005 86.6 98.6 112
# 0.01 56.9 61.8 69.3
# 0.05 22.6 21.6 22.7
# 0.1 15.4 14.7 14.2
# 0.5 6.60 5.54 5.17
# 1.0 4.63 3.80 3.45
# 2.0 3.17 2.67 2.32
# 3.0 2.79 2.04 1.96
# 4.0 2.10 1.98 1.74
## Not run:
k1 <- 0.25
k2 <- 0.5
k3 <- 0.75
h1 <- 9.660
h2 <- 5.620
h3 <- 3.904
deltas <- c(0.0005, 0.001, 0.005, 0.01, 0.05, 0.1, 0.5, 1:4)
arl1 <- c(round(xcusum.arl(k1, h1, 0, r=r), digits=2),
round(DxDcusum.arl(k1, h1, deltas, r=r), digits=2))
arl2 <- c(round(xcusum.arl(k2, h2, 0), digits=2),
round(DxDcusum.arl(k2, h2, deltas, r=r), digits=2))
arl3 <- c(round(xcusum.arl(k3, h3, 0, r=r), digits=2),
round(DxDcusum.arl(k3, h3, deltas, r=r), digits=2))
data.frame(delta=c(0, deltas), arl1, arl2, arl3)
## End(Not run)
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