Home News About Us Contact Contributors Disclaimer Privacy Policy Help FAQ

Home
Search
Quick Search
Advanced
Fulltext
Browse
Collections
Persons
My eDoc
Session History
Login
Name:
Password:
Documentation
Help
Support Wiki
Direct access to
document ID:


          Institute: MPI für biophysikalische Chemie     Collection: Molekulare Biologie (Dr. Thomas M. Jovin)     Display Documents



  history
ID: 225791.0, MPI für biophysikalische Chemie / Molekulare Biologie (Dr. Thomas M. Jovin)
Masking, photobleaching, and spreading effects in Hadamard transform imaging and spectroscopy systems
Authors:Hanley, Q. S.
Language:English
Date of Publication (YYYY-MM-DD):2001
Title of Journal:Applied Spectroscopy
Journal Abbrev.:Appl. Spectrosc.
Volume:55
Start Page:318
End Page:330
Copyright:Jahrbuch 2002, Copyright MPG 2002
Review Status:Peer-review
Audience:Not Specified
Intended Educational Use:No
Abstract / Description:In analyzing the behavior of a Hadamard transform imaging spectroscopic system in an optical sectioning microscope, a previously undescribed masking effect was observed. During the process of characterizing this artifact, it was noted that while many masking errors have been reported previously in the literature, no attempt has been made to classify them or to systematically treat their effects in a variety of imaging and spectroscopy arrangements. Previous reports have documented echo artifacts in one-dimensional Hadamard mask systems based on sequences of length 2n-1, for which the echoes are well defined. Other valid cyclic S-sequences, such as those of prime length 4m+3 1 2n-1, do not exhibit such behavior. Masking errors may be present with these sequences, but they do not appear as echoes. Recovered intensities are observed having both positive and negative magnitude distributed throughout the transform axis. These masking defects appear superficially to be "noise," making associated errors more difficult to diagnose. Masking effects in two-dimensional systems have not been previously reported. In these, the relationship between the original image and resulting "echoes" can be quite complicated. This paper treats a variety of masking effects theoretically and presents simulations based on that treatment. Mask errors are divided into first- and second-order effects depending on whether the encoding passes through a mask once or twice. Symmetric, asymmetric, and static masking errors in one-dimensional Hadamard transform systems are treated in both first and second-order arrangements. Where prior data exist, an attempt has been made to collect and categorize known mask related artifacts and where appropriate provide additional documentation. Mask errors may be spatially varying or spatially invariant over the mask or within a given pixel. In systems that are spatially variant, proper sampling of the image or spectrum by the elements composing the mask is a prerequisite for successful correction of the data. Corrections applied to data from masks with spatially variant errors may cause artifacts to appear and, in some instances, complete correction may be impossible. The effects of photobleaching and mask spreading due to processes such as diffraction or aberrations in both one- and two-dimensional mask systems are investigated. Photobleaching is relatively easy to correct when an exponential decay model is applicable. In second-order systems, mask spreading gives rise to echoes or distortion even in perfectly implemented masks. Mask spreading can, in many cases, be corrected by analyzing the observed "echoes" and building a correction matrix or by using knowledge of the point, line, or other spreading function of the system. Finally, in masks of length 2n-1, a few simple rules greatly assist in diagnosing masking effects.
Free Keywords:none available
Last Change of the Resource (YYYY-MM-DD):2005-08-18
External Publication Status:published
Document Type:Article
Communicated by:N. N.
Affiliations:MPI für biophysikalische Chemie/Abt. Thomas Jovin / 060
Identifiers:LOCALID:34675
The scope and number of records on eDoc is subject to the collection policies defined by each institute - see "info" button in the collection browse view.