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Krümmungsradius der Linse von Galileo Galileis Fernrohr

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Exercise

https://texercises.com/exercise/krummungsradius-der-linse-von-galileo-galileis-fernrohr/

Question

Solution

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The following quantities appear in the problem: Radius \(r\) / Brechzahl \(n\) / Brennweite \(f\) /

The following formulas must be used to solve the exercise: \(\frac{1}{f} = (n-1)\left(\dfrac{1}{r_1}-\dfrac{1}{r_2}\right) \quad \)

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Exercise:
Galileo Galilei hat für sein Fernrohr eine plankonvexe Glaslinse mit ca. fO Brennweite hergestellt. Das verwete Glas hatte nO Brechungsindex. Welchen Krümmungsradius musste die konvexe Seite der Linse erhalten?

Solution:
fracf n- left fracr_+fracr_ right fracn-r_ r_ n- f nO- f uulinesicm Bemerkung: /r_ /infty

Meta Information

\(\LaTeX\)-Code

Contained in these collections:

Brennweite einer dünnen Linse by TeXercises

4 | 6
Geometrische Optik : Linsen und Spiegel by Lie

1 | 8
Linsen by uz

3 | 11

Asked Quantity: Radius \(r\) in Meter \(\rm m\)

Attributes & Decorations

Tags	Galileo90cmLins
Content image
Difficulty	(1, default)
Points	0 (default)
Language	(Deutsch)
Type	Calculative / Quantity
Creator	Lie
Decoration
File
Link

Physical Quantity

Radius \(r\)

grösstmöglicher Abstand Mittelpunkt zu Kreislinie/Kugeloberfläche

Meter (\(\rm m\))

Seemeile (\(\rm NM\))

Unit

Meter (\(\rm m\))

Der Meter ist dadurch definiert, dass der Lichtgeschwindigkeit im Vakuum \(c\) ein fester Wert zugewiesen wurde und die Sekunde (\(\rm s\)) ebenfalls über eine Naturkonstante, die Schwingungsfrequenz definiert ist.

Radius (\(r\))

Umfang (\(u\))

Länge (\(\ell\))

Strecke (\(s\))

Durchmesser (\(d\))

Höhe (\(h\))

Amplitude (\(\hat y\))

Elongation (\(y_t\))

Dicke (\(d\))

Breite (\(b\))

Wellenlänge (\(\lambda\))

Impuls (\(p\))

Gitterkonstante (\(d\))

Brennweite (\(f\))

Bildweite (\(b\))

Gegenstandsweite (\(g\))

Gegenstandsgrösse (\(G\))

Bildgrösse (\(B\))

\(\rm 1\,Å=1\cdot 10^{-10}\,m\)

\(\rm 1\,in=2.54\cdot 10^{-2}\,m\)

\(\rm 1\,ft=0.3048\,m\)

\(\rm 1\,yd=0.9144\,m\)

\(\rm 1\,mi=1.609344\cdot 10^{3}\,m\)

\(\rm 1\,NM=1.852\cdot 10^{3}\,m\)

Base? SI? Metric? Coherent? Imperial?