Multispectral remote sensing images are widely used in many environmental monitoring applications including landuse/landcover (LULC) classification and change detections. Remote sensing LULC classification can be conducted using various supervised or unsupervised classification techniques. Accuracies of classification results often are evaluated using the confusion matrix (or error matrix) derived from a set of training data which consists of training pixels of individual LULC classes. There are also applications that assessed classification accuracies based on the error matrix derived from an independent reference dataset. However, although widely accepted for classification accuracy assessment, uncertainties of the error matrix itself due to selection of training pixels (sampling uncertainties) have received little attention. In addition, the premise that training data are representative of the whole study area is not always valid. In this study, we aim to tackle both problems by a stochastic multispectral images simulation approach (SMISA). The SMISA considers multispectral images as a multivariate random field, or a random-vector field. Individual univariate random fields may be non-Gaussian and a covariance transformation algorithm was applied for transforming a non-Gaussian random-vector field to a corresponding Gaussian random-vector field. Cluster analysis was implemented to group all pixels into several clusters. All pixels of the same cluster are considered as a realization of a random-vector field. Principal component transformation was then applied to the Gaussian random-vector field and the resultant major principal components were evaluated. The major principal components were simulated independently and then scores of Gaussian random-vector were obtained through inversion of the principal components. By using rank series of the original multispectral remote sensing images, we were able to stochastically simulate a large number of multispectral images which preserve all the statistical properties of the original set of multispectral images. The proposed rank series based approach has been successfully tested using an AR(2) time series model. By decomposing a given AR(2) model into a rank series and an independent Gaussian distribution, we were able to simulate a large number of realizations which were identified are AR(2) time series with average parameters nearly identical to the parameters of the given AR(2) model. Finally, simulated images were used for assessing uncertainties of the error matrix.