@CONFERENCE\{IMM1998-03658, author = "A. A. Nielsen", title = "Linear Mixture Models and Partial Unmixing in Multi- and Hyperspectral Image Data", year = "1998", month = "oct", keywords = "matched filtering; orthogonal subspace projection, {OSP}; constrained energy minimization, {CEM}; generalized eigenvalue problem", pages = "165-172", booktitle = "First EARSeL Workshop on Imaging Spectroscopy", volume = "", series = "", editor = "Michael Schaepman, Daniel Schl{\"{a}}pfer, Klaus Itten", publisher = "", organization = "", address = "", url = "http://www2.compute.dtu.dk/pubdb/pubs/3658-full.html", abstract = "As a supplement or an alternative to classification of hyperspectral image data the linear mixture model is considered in order to obtain estimates of abundance of each class or end-member in pixels with mixed membership. Full unmixing and the partial unmixing methods orthogonal subspace projection (OSP), constrained energy minimization (CEM) and an eigenvalue formulation alternative are dealt with. The solution to the eigenvalue formulation alternative proves to be identical to the {CEM} solution. The matrix inversion involved in {CEM} can be avoided by working on (a subset of) orthogonally transformed data such as signal maximum autocorrelation factors, MAFs, or signal minimum noise fractions, MNFs. This will also cause the noise isolated in the {MAF}/MNFs not included in the analysis not to influence the partial unmixing result. {CEM} and the eigenvalue formulation alternative enable us to perform partial unmixing when we know the desired end-member spectra only and not the full set of end-member spectra. This is an advantage over full unmixing and {OSP}. An example with a simple simulated {2-}band image shows the ability of the {CEM} method to isolate the desired signal. A case study with a 30 bands subset of {AVIRIS} data from the Mojave Desert, California, {USA,} indicates the utility of {CEM} to more realistic data." }