calibrationTest

calibrationTest.default

The implemented calibration tests for Poisson or negative binomial
 predictions of count data are based on proper scoring rules and
 described in detail in Wei and Held (2014).
 The following proper scoring rules are available:
 Dawid-Sebastiani score (<code>"dss"</code>),
 logarithmic score (<code>"logs"</code>),
 ranked probability score (<code>"rps"</code>).

htest

Statistical methods for the modeling and monitoring of time series
of counts, proportions and categorical data, as well as for the modeling
of continuous-time point processes of epidemic phenomena.
The monitoring methods focus on aberration detection in count data time
series from public health surveillance of communicable diseases, but
applications could just as well originate from environmetrics,
reliability engineering, econometrics, or social sciences. The package
implements many typical outbreak detection procedures such as the
(improved) Farrington algorithm, or the negative binomial GLR-CUSUM
method of Hoehle and Paul (2008) <doi:10.1016/j.csda.2008.02.015>.
A novel CUSUM approach combining logistic and multinomial logistic
modeling is also included. The package contains several real-world data
sets, the ability to simulate outbreak data, and to visualize the
results of the monitoring in a temporal, spatial or spatio-temporal
fashion. A recent overview of the available monitoring procedures is
given by Salmon et al. (2016) <doi:10.18637/jss.v070.i10>.
For the retrospective analysis of epidemic spread, the package provides
three endemic-epidemic modeling frameworks with tools for visualization,
likelihood inference, and simulation. hhh4() estimates models for
(multivariate) count time series following Paul and Held (2011)
<doi:10.1002/sim.4177> and Meyer and Held (2014) <doi:10.1214/14-AOAS743>.
twinSIR() models the susceptible-infectious-recovered (SIR) event
history of a fixed population, e.g, epidemics across farms or networks,
as a multivariate point process as proposed by Hoehle (2009)
<doi:10.1002/bimj.200900050>. twinstim() estimates self-exciting point
process models for a spatio-temporal point pattern of infective events,
e.g., time-stamped geo-referenced surveillance data, as proposed by
Meyer et al. (2012) <doi:10.1111/j.1541-0420.2011.01684.x>.
A recent overview of the implemented space-time modeling frameworks
for epidemic phenomena is given by Meyer et al. (2017)
<doi:10.18637/jss.v077.i11>.

Sebastian Meyer

surveillance

Temporal and Spatio-Temporal Modeling and Monitoring of Epidemic
Phenomena

Sophie Reichert

Andrea Riebler

Daniel Sabanes Bove

Stefan Steiner

Mikko Virtanen

Wei Wei

Valentin Wimmer

R Core Team 

Howard Burkom

Thais Correa

Mathias Hofmann

Christian Lang

Juliane Manitz

Dirk Schumacher

Leonhard Held

Michael Hoehle

Michaela Paul

Maelle Salmon

calibrationTest function

<dl> <dt>x</dt>
<dd>the observed counts.
 All involved functions are vectorized and also accept matrices or arrays.</dd> <dt>mu</dt>
<dd>the means of the predictive distributions for the
 observations <code>x</code>.</dd> <dt>size</dt>
<dd>either <code>NULL</code> (default), indicating Poisson predictions with mean
 <code>mu</code>, or dispersion parameters of
 negative binomial forecasts for the observations <code>x</code>,
 parametrized as in <code><a href="/link/dnbinom?package=surveillance&version=1.23.1" data-mini-rdoc="surveillance::dnbinom">dnbinom</a></code> with variance
 <code>mu*(1+mu/size)</code>.</dd> <dt>which</dt>
<dd>a character string indicating which proper scoring rule to apply.</dd> <dt>tolerance</dt>
<dd>absolute tolerance for the null expectation and variance of
 <code>"logs"</code> and <code>"rps"</code>. For the latter, see the note below.
 Unused for <code>which = "dss"</code> (closed form).</dd> <dt>method</dt>
<dd>selection of the \(z\)-statistic: <code>method = 2</code> refers to
 the alternative test statistic \(Z_s^*\) of Wei and Held (2014,
 Discussion), which has been recommended for low counts.
 <code>method = 1</code> corresponds to Equation 5 in Wei and Held (2014).</dd> <dt>...</dt>
<dd>unused (argument of the generic).</dd></dl>

Arguments

Author

Calibration Tests for Poisson or Negative Binomial Predictions — calibrationTest

<dl>

 <dt>x</dt>
<dd>the observed counts.
 All involved functions are vectorized and also accept matrices or arrays.</dd>

 <dt>mu</dt>
<dd>the means of the predictive distributions for the
 observations <code>x</code>.</dd>

 <dt>size</dt>
<dd>either <code>NULL</code> (default), indicating Poisson predictions with mean
 <code>mu</code>, or dispersion parameters of
 negative binomial forecasts for the observations <code>x</code>,
 parametrized as in <code><a href='https://rdrr.io/r/stats/NegBinomial.html'>dnbinom</a></code> with variance
 <code>mu*(1+mu/size)</code>.</dd>

 <dt>which</dt>
<dd>a character string indicating which proper scoring rule to apply.</dd>

 <dt>tolerance</dt>
<dd>absolute tolerance for the null expectation and variance of
 <code>"logs"</code> and <code>"rps"</code>. For the latter, see the note below.
 Unused for <code>which = "dss"</code> (closed form).</dd>

 <dt>method</dt>
<dd>selection of the \(z\)-statistic: <code>method = 2</code> refers to
 the alternative test statistic \(Z_s^*\) of Wei and Held (2014,
 Discussion), which has been recommended for low counts.
 <code>method = 1</code> corresponds to Equation 5 in Wei and Held (2014).</dd>

 <dt>...</dt>
<dd>unused (argument of the generic).</dd>

</dl>

Calibration Tests for Poisson or Negative Binomial Predictions

calibrationTest: Calibration Tests for Poisson or Negative Binomial Predictions

Description

Usage

Value

Arguments

Author

References

Examples