iPhoneAlle anzeigen
iPhone 11iPhone 11 ProiPhone 11 Pro MaxiPhone 12iPhone 12 ProiPhone 12 Pro MaxiPhone 12 miniiPhone 13iPhone 13 ProiPhone 13 Pro MaxiPhone 13 miniiPhone 14iPhone 14 PlusiPhone 14 ProiPhone 14 Pro MaxiPhone 15iPhone 15 PlusiPhone 15 ProiPhone 15 Pro MaxiPhone 16iPhone 16 PlusiPhone 16 ProiPhone 16 Pro MaxiPhone 16eiPhone 8iPhone 8 PlusiPhone SE 2020iPhone SE 2022iPhone XiPhone XRiPhone XSiPhone XS Max
Galaxy A-SerieAlle anzeigen
Galaxy A12Galaxy A13Galaxy A13 5GGalaxy A14Galaxy A15Galaxy A16Galaxy A17 5GGalaxy A20eGalaxy A21Galaxy A22Galaxy A23Galaxy A24Galaxy A25Galaxy A26 5GGalaxy A32Galaxy A33Galaxy A34Galaxy A35Galaxy A36 5GGalaxy A40Galaxy A41Galaxy A42Galaxy A50Galaxy A51Galaxy A52Galaxy A53Galaxy A54Galaxy A55Galaxy A56 5GGalaxy A70Galaxy A71Galaxy A72
Redmi SeriesAlle anzeigen
Redmi 10Redmi 13CRedmi 15 5GRedmi Note 10Redmi Note 10 ProRedmi Note 11Redmi Note 11 ProRedmi Note 11 Pro Plus 5GRedmi Note 11sRedmi Note 12Redmi Note 12 5GRedmi Note 12 ProRedmi Note 12 Pro 5GRedmi Note 12 Pro PlusRedmi Note 13Redmi Note 13 5GRedmi Note 13 ProRedmi Note 13 Pro PlusRedmi Note 14Redmi Note 14 Pro PlusRedmi Note 8Redmi Note 8 ProRedmi Note 9Redmi Note 9 Pro
- Startseite
Bücher Englische Bücher Wissen & Bildung Naturwissenschaft, Medizin, Informatik, Technik Physik & Astronomie Elektrizität, Magnetismus, Optik Quantification of Brain Oxygen based on Time and Space Optimization of Diffuse Optics: Monte-Carlo Inversion of Infrared Spectroscopy on Phantoms
Derzeit nicht verfügbar
Handgeprüfte Gebrauchtware
Bis zu 50 % günstiger als neu
Der Umwelt zuliebe
Quantification of Brain Oxygen based on Time and Space Optimization of Diffuse Optics: Monte-Carlo Inversion of Infrared Spectroscopy on Phantoms
Lin Yang (Broschiert, Englisch)
★★★★★
☆☆☆☆☆ Keine Bewertungen vorhanden
Optischer Zustand
Beschreibung
Optical spectroscopy techniques are frequently used for the quantitative analysis of substance
composition, physical properties, and the phenomena risen from energy-matter interactions.
Near-infrared absorption spectroscopy of human tissues is particularly of medical interests for
its ability to selectively acquire physiological and neurological information of certain
chromophores in the human… body, with the help of photons that are non-invasively propagated
through organs such as brain or kidney. The implementation of these techniques, despite many
research activities in this area, still encounters massive difficulties primarily due to one simple
fact: Light no longer travels in a straight line in tissues but rather spreads on stochastic
trajectories due to the strong scattering. The optical scattering effect dominates in these media
and to some extent is entangled with the optical absorption. While the optical absorption
spectroscopy is what most quantitative analyses rely on, the interpretation and analysis of the
results are difficult due to this entanglement with scattering and this problem has not yet been
satisfactorily solved. Biomedical applications of the techniques are further complex by the
geometry and heterogeneity of tissues at almost every length scale, which results in the illposedness
of solving the underlying inverse problem and thereafter usually the solution’s nonuniqueness
when retrieving the diagnostical information.
The present thesis is devoted to disentangle the effects from absorption and scattering in
human brain and purpose an innovative approach on quantifying the optical absorption and
scattering coefficients with improved accuracy. Especially, a new concept of integrating
disparate data types from various measurement domains is proposed and verified. The work is
based on a fundamental fact: The absorption and scattering, despite heavily entangled, are
essentially independent. And the complementarity encoded in the measurements of different
domains can be advantageously used to increase the retrieval accuracy of the unknowns and
reduce the complexity of the inversion.
The thesis realizes the concept in the term of spatial-enhanced time domain diffuse optics.
By deploying picosecond pulse laser and time-correlated single photon counting technique, the
approach is validated on homogeneous solid and two-layered liquid phantoms mimicking
human brain’s optical properties. Monte-Carlo simulations are applied to imitate photon
random transport in turbid media and are incorporated into the spatio-temporal optimization of
the inversion process. The estimation accuracy of absorption and scattering coefficients is
demonstrated at level of 5%. The examined and presented concept and computational method have the potential to overcome the challenges of the inverse problem in diffuse optics such as
solution’s non-uniqueness and deep scattering neutrality. Dieses Produkt haben wir gerade leider nicht auf Lager.
Handgeprüfte Gebrauchtware
Bis zu 50 % günstiger als neu
Der Umwelt zuliebe
Technische Daten
Erscheinungsdatum
17.03.2022
Sprache
Englisch
EAN
9783956066641
Herausgeber
Fachverlag NW in Carl Ed. Schünemann KG
Serien- oder Bandtitel
PTB-Berichte. Optik (Opt)
Sonderedition
Nein
Autor
Lin Yang
Seitenanzahl
150
Auflage
1
Einbandart
Broschiert
-.-
★★★★★
☆☆☆☆☆ Leider noch keine Bewertungen
Leider noch keine Bewertungen
Sicher bei rebuy kaufen
Schreib die erste Bewertung für dieses Produkt!
Wenn du eine Bewertung für dieses Produkt schreibst, hilfst du allen Kund:innen, die noch überlegen, ob sie das Produkt kaufen wollen. Vielen Dank, dass du mitmachst!
Sicher bei rebuy kaufen