1 / 12

ECE 638: Principles of Digital Color Imaging Systems

ECE 638: Principles of Digital Color Imaging Systems. Lecture 9: Discrete Wavelength Models Projection Operator. Synopsis. Review of discrete wavelength model. Discrete-wavelength trichomatic model. Stimulus Sensor response Response of the i -th channel Define

ppettway
Télécharger la présentation

ECE 638: Principles of Digital Color Imaging Systems

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. ECE 638: Principles ofDigital Color Imaging Systems Lecture 9: Discrete Wavelength Models Projection Operator

  2. Synopsis • Review of discrete wavelength model

  3. Discrete-wavelength trichomatic model • Stimulus • Sensor response • Response of the i-th channel • Define • Span(S) defines HVS subspace • Stack sensor outputs • Set of visually independent primaries • Color matching matrix for this set of visually independent primaries

  4. Review

  5. Definition of projection operator • Projection operator is a linear operator that extracts the fundamental component of the stimulus , i.e. • Since , we can write that • Following the earlier development of the fundamental component , we have that • Substituting (3) into (2), we obtain • Comparing (4) with (1), we get

  6. Alternate forms of projection operator • Based on fact that , we obtained • But for visually independent primaries. • Thus • Equations (5a), (5b), and (5c) are all equivalent.

  7. Projection of monochromatic stimuli onto the human visual subspace • Recall that a monochromatic stimulus at wavelength can be expressed as • So the identity matrix represents the complete set of monochromatic stimuli. • Consider that • Thus ; so the columns of are the fundamental components of the monochromatic stimuli.

  8. Relation between projection operator and fundamental component of primary mixtures for monochromatic stimuli • Recall that • Since is the fundamental component of , we also have that • So • Since the responses to and are identical, their fundamental components are also the same. But is the fundamental component of the monochromatic stimuli; so it already lies within the human visual subspace, i.e. • Thus, we have from Eq. (6) that

  9. Extraction of fundamental component of stimulus: an imaging systems interpretation • A complete imaging system, can be thought of as a capture device followed by a display device. • The process of extracting the fundamental component of the stimulus, as described by Eq. (7a) from the preceding slide can be viewed in this way • i.e. • We also have • Combining (8) and (9) yields Sensor Display

  10. Questions about the human visual subspace • Recall two earlier questions: • Question 1: Are there real stimuli that are invisible? • Answer: “No” • Question 2: Are there real stimuli for which ? • Not yet answered • Now introduce a third question: • Question 3: What colors in the fundamental space are physically realizable with the addition of a black space component, i.e. what colors have a physically realizable metamer?

  11. Characterization of subset of fundamental space with physically realizable metamers • Theorem: A stimulus has a physically realizable metamer its fundamental component can be written as a non-negative linear combination of the columns of • Proof: • Suppose is physically realizable. (Here is fixed; and is one possible metamer for .) but since is physically realizable, its components are all non-negative. Therefore, Eq. (11) shows that the fundamental component is a non-negative linear combination of the columns of .

  12. Characterization (cont.) • Theorem: A stimulus has a physically realizable metamer its fundamental component can be written as a non-negative linear combination of the columns of • Proof: • Suppose , where . This immediately leads to the conclusion that is a physically realizable metamer for . • This completes the proof of the theorem.

More Related