Mean squared prediction error in the spatial linear model with estimated covariance parameters

Zimmerman, Dale L.; Cressie, Noel

doi:10.1007/bf00048668

Cited by 117 publications

(63 citation statements)

References 31 publications

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“…The next process is to generate HEM and display the height error of the height model. Height error was made of a standard deviation or vertical error in the height model data (Zimmerman and Cressie, 1992). Height error can be made from its own data.…”

Section: Resultsmentioning

confidence: 99%

Height Model Integration Using Alos Palsar, X Sar, SRTM C, and Icesat/Glas

Julzarika

2017

IJReSES

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Abstract. The scarcity of height models is one of the important issues in Indonesia. ALOS PALSAR, X SAR, SRTM C, and ICESAT/GLAS are free available global height models. Four data can be integrated the height models. Integration takes advantage of each characteristic data. The spatial resolution uses ALOS PALSAR. ICESAT/GLAS has a minimal height error because it is DTM. SAR has advantages of minimal error in the highland and need a low pass filter on the lowland. DSM uses X SAR and DEM from ALOS PALSAR. Characteristics and penetration of vegetation objects can be seen from the wavelength type of SAR data. This research aims to make height model integration in order to get the vertical accuracy better than vertical accuracy of global height models and minimum height error. The study area is located in Karo Regency. The first process is to crop the height models into Karo Regency, geoid undulation correction using EGM 2008. The next step is to detect pits and spires by using radius value 1000 m and depth +1.96σ (+5 m) with uncertainty 95,45%. Then generate HEM and height model integration. To know the accuracy of this height model, 100 reference points measured using GNSS, altimeter, and similar point observed on the height model integration are selected. The accuracy test covers RMSE, accuracy (z), and height difference test. The result of this study shows that the height model integration has a vertical accuracy in 1.14 m. This height model integration can be used for mapping scale 1: 10.0000. Height models can be created from optical, radar, microwave, lidar, and sonar data (Bhardwaj et al., 2013): (Mitchell and MacNabb, 2010). Height model of the optical data using optical satellite imagery data, aerial photographs, video (Deilami and Hashim, 2011). In the optical data, height model using stereo models (Saldana et al., 2012) height model on the radar data using stereo models, interferometry, and depth cue perceptive. Height models are made by sonar can use data Interferometry Synhetic Aperture Sonar (IFSAS) data (Julzarika, 2011b). Height models or also known as 3D model is a view of a model with the 3D coordinate system (polar, geodetic, raster and cartesian) with field-defined reference to a specific projection and datum (Julzarika and Sudarsono, 2009). A height model can be created from radar and optical data. Height models can also be defined as a digital model that gives information about the earth surface shape (topography) in the form of raster or vector data (Freeden et al., 2010). Height models consist of two information, namely: height data and the data of such height position coordinates on the earth's surface (Honikel, 1998).

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Section: Resultsmentioning

confidence: 99%

Height Model Integration Using Alos Palsar, X Sar, SRTM C, and Icesat/Glas

Julzarika

2017

IJReSES

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“…A small sample size is not an issue in our example, in which n = 414 for the calibration time period. For spatially autocorrelated data, in addition to the assumptions necessary for equation (A3), Zimmerman and Cressie (1992) suggest using the Prasad-Rao MSE estimator when the spatial correlation is known or estimated to be weak, and when the estimated variance-covariance matrix of the observed data is known to be negatively biased. The estimated value of the first autoregressive parameter for our example is 0.996 (95% CI: 0.90, 1.09), which is consistent with values of strong autocorrelation as seen in Vijapurkar and Gotway (2001).…”

Section: Discussionmentioning

confidence: 99%

“…Given this unbiased estimator for y|x j and again that the variance and covariance parameters are known, the prediction mean-squared error (MSE) can be computed as Jeske 1992, Zimmerman andCressie 1992):…”

Section: Corrected Prediction Intervals For Change Detectionmentioning

confidence: 99%

“…A common method to obtain prediction variances, here after referred to as the plug-in estimator, has been to estimate the variance-covariance parameters, and simply plug-in these values to equation (8) as fixed and known (Das et al 2004, Schabenberger andGotway 2005), however, this estimator can be negatively biased (Kackar and Haarville 1984, Harville and Jeske 1992, Zimmerman and Cressie 1992, Schabenberger and Gotway 2005. The origin of this bias and the derivation leading to the .…”

Section: Corrected Prediction Intervals For Change Detectionmentioning

confidence: 99%

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Corrected prediction intervals for change detection in paired watershed studies

Som

Zégre

Ganio

et al. 2012

Hydrological Sciences Journal

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“…However, whgn 8 is also unknown and estimated by 8, the empirical Bayes predictor p(Y; 8) is typically no longer necessarily linear nor Bayes. (Sometimes, the empirical Bayes Using analogous arguments to Zimmerman and Cressie (1991), it is straightforward to show that E@(Y; 6)) = E ( Z ) = Xp , (30) rovided 6 i : even (that is, 6(-Y) = 6(Y)) and translation invariant (that is, &Y +Xw) = 8(Y) for every p x 1 vector w). Notice that the m.1.…”

Section: Properties Of the Empirical Bayes Predictor: Bias And Mean Smentioning

confidence: 99%