Cardinal Points of an Optical System--and Other Basic Facts

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Cardinal Points of an Optical System--and Other Basic Facts The fundamental feature of any optical system is the aperture stop. Thus, the most fundamental optical system is the pinhole camera. The image of the aperture stop from the lenses on the object space side of the aperture stop is called the entrance pupil. The image of the aperture stop from the lenses on the image space side of the aperture stop is called the exit pupil. January 018 9

Focal and Principal Planes Rear Principal Plane Focal Length Back Focal Distance Front Principal Plane Rear Focal Plane 6/3/015 Total Axial Length: 6.96000 mm Layout Ruda-Cardinal, Inc. Tucson, AZ 8571 www.ruda-cardinal.com LENS.ZMX PROPRIETARY DESIGN January 018 10

Nodal Points Illustrated Rear Nodal Plane Angle Into Lens = 14.00 Degrees Angle Out Of Lens = 14.017 Degrees Delta = 0.017 Degrees, or 1 arc-min Front Nodal Plane 6/3/015 Total Axial Length: 7.96000 mm Layout Ruda-Cardinal, Inc. Tucson, AZ 8571 www.ruda-cardinal.com LENS.ZMX PROPRIETARY DESIGN January 018 11

Numerical Aperture and F-Number Numerical Aperture (N.A.): A measure of the converging light cones half angle N.A. = 1/F# F-Number (f#) = Note the F# sometimes refers to the cone at the actual working conjugate. For example, the F# at the center of curvature of a sphere is R/D, not f/d. Be Aware!! F# = f/d January 018 1

Illustration of F/# s Infinite conjugates y NA F/# = f/d D f As-used conjugates θ January 018 13

The Airy Disk The Airy disk The image of a point source is called the Airy disk, and is shown in the figure below: The first zero occurs at a diameter of:.44λ(f#) 84% of the energy occurs in the central core; 91% is contained in the core plus the first ring. January 018 14

The Airy Disk 84% of energy in central core, 91% to first ring January 018 15

Auto-reflection This is really important! (a) In collimated space (autocollimator) (b) With concave mirror (c) With convex mirror January 018 16

Retro-reflection -- Also Important Retro-reflection occurs when an image focuses on an optical surface. Interesting facts: Image and surface are in focus Image motion is tilt insensitive (displacement insensitive for flats Illumination varies with tilt Return image quality is very scratch/dig sensitive January 018 17

The CassegrainTelescope January 018 18

The Star Test Definition The star test is simply a visual inspection of a point image formed by an optical system. Qualitative and quantitative information can be obtained by: Observing the image Measuring its size Orientation of asymmetries Examining the through-focus appearance Note: Microscope NA must be > system NA or microscope F# must be faster than system F#! January 018 19

.0 Recognizing the Elementary Aberrations and their Role in Optical Alignment Wavefront error basics Wavefront and image errors vs. field and pupil position Focus error Longitudinal magnification Spherical aberration Coma Astigmatism Boresight error Determining the cause of aberration -- Misalignment or otherwise January 018 0

Recognizing the Elementary Aberrations Recognizing and understanding the elementary aberrations is a vital aid in optical alignment. Both the qualitative recognition and quantitative measurement of these aberrations provide powerful diagnostic tools for correcting misaligned systems There are three approaches we can take in understanding these aberrations: Mathematical understanding: For our purposes only a summary will be necessary Understanding how aberrations affect wavefront shape: This will clarify why interference fringes have specific patterns for each aberration How aberrations affect the image of a point source: This so-called "star test" can be an extremely powerful alignment tool January 018 1

Wavefront Error Basics Since we usually want light to converge to a perfect focus, a perfect wavefront is usually considered to be either a sphere or a plane. Optical path difference (OPD) is the difference between the actual and best fit reference wavefront. OPD is the yardstick for defining wavefront error. The types of wavefront errors that occur due to the normal aberrations in an optical design and those caused be misalignment are very similar, if not identical. Mathematically, design and misalignment errors are expressed by a polynomial expansion. Design errors are often carried out to higher order terms; however, misalignment errors, because they are generally small, are carried out to only the fourth order. January 018

Wavefront Error Basics For this expression of wavefront error in polynomial form, let: H = Field Height of Object X,Y = Cartesian Coordinates ρ, θ = Polar Coordinates Z = Optical Axis R REF = Reference Sphere Radius *W(X,Y) or W(ρ, θ) = Functional Description of Wavefront *Usually described as a polynomial expansion and includes the field dependence (H). Then, W (H, ρ,cos θ)=σa ijk H i ρ j cos k (θ) January 018 3

Wavefront Error Basics To 3 rd Error The spot size or image blur varies as the derivative of the above expression, and can be expressed as: January 018 4

A Quick Summary of the Field and Pupil Dependencies of Wavefront and Image Errors Wavefront Error Dependence Aberration Power of H (H m ) Power of ρ (ρ n ) Defocus (a 00 ) ---- Squared (n=) Spherical Aberration (a 040 ) ---- Fourth (n=4) Coma (a 131 ) Linear (m=1) Cubed (n=3) Astigmatism (a ) Squared (m=) Squared (n=) Spot size dependence Spot size W/ ρ Defocus ---- Linear Spherical Aberration ---- Cubed Coma Linear Squared Astigmatism Squared Linear January 018 5

Focus Error--Very Important Defocus is probably the most common misalignment error Mathematically: W = W 00 = a 00 ρ Field Independent--No Surprise Interferometrically: Concentric rings, the number increasing as ρ Star Test: Uniform blur on either side of focus (geometric regime). Black dot in the center of the airy disk for ±1λ defocus We will now derive a very useful formula and relate Wavefront Defocus Error to defocus of image plane January 018 6

Relationship Between Sag, Diameter, and Radius of Curvature S Y = Y R - S S - RS + Y = 0 S = R- R Y EXACT BUT, IF R >> S, THEN S Y R APPX. Surface of lens or mirror wavefront, exit pupil or wavefront January 018 7

A Warm-up to an Important Equation S = Y S = Y R 1 1 R 1 R S IS LIKE a 00 R IS LIKE f January 018 8

Derivation of the Defocus Equation From the previous page, let s substitute f S = y 1 f1 1 f (focal length) for R and f (1) for R, then : S = # of waves of S = a 00 sag difference (a 00 λ () ) length of a wavelength ( λ), i.e.: 1 f1 THEN 1 f = f f f f 1 1 f1 1 f 1 = f f f 1 f f, but since f << (3) f 1 or f, f 1 f = f Now, F# = f/d = f/y Thus, f /y = 4(F#) (4) January 018 9

Derivation of the Defocus Equation (continued) Substituting equations and 3 into 1, we get a 00 λ = y f f (5) Substituting 4 into 5 and solving for f: f = ± 8 λ a 00 F# The Defocus Equation Thus we have related focus error in the wavefrontto shift in focusat the image Remindera 00 is dimensionless and is the number of waves of defocus (sag departure of the wavefront). January 018 30

Three Handy Formulas General Expression f = ± 8 λ a 00 F# Rayleigh Criterion (a 00 = 1/4) f = ± λ F# In the visible (λ ~ 0.5 Microns): f = ± F# (In microns) January 018 31

Why is There a Black Dot when Defocus = 1λ? W = W 00 = a 00 ρ When a 00 = 1λ Sag of the wavefront at full aperture (ρ = 1) = 1λ Sag of the wavefront at ρ = 0.707 = 0.5λ Area of the pupil from ρ = 0 to ρ = 0.707 equals area of annular pupil from ρ = 0.707 to ρ = 1.0 Therefore, for every point within r = 0.707, there is a point in annulus that is λ/ out of phase Consequently, on-axis everything cancels! No light! Black Dot! January 018 3

The Black Dot When a perfect circular wavefront is defocused exactly 1λ, a black dot appears at the center of the spot Find the ±1λplanes, then split the difference for sharp focusing January 018 33

Longitudinal Magnification First what is transverse magnification? M = L /L 1 Longitudinal Magnification is simple. If we move the object along the axis by an amount, DZ, the image will move DZ' Longitudinal Magnification is defined as: M L = Z Z It can be shown that M L = M So what? It is useful for measuring despacing sensitivities of optical components. It is also why your nose looks so big on a doorknob! January 018 34

The Usefulness of Depth of Focus and Longitudinal Magnification Formulas (example) Problem: Find the spacing tolerance between the primary and secondary mirror of a diffraction limited, F/10 Cassegrain telescope. The primary mirror is F/, the telescope is used in the visible (λ = 0.5µ). M = F/10 F/ = 5 1. The diffraction limited (λ/4) depth of focus at the large image plane of the Cassegrain is given by f = ± F/# (in microns) (when λ = 0.5µ) = ± 100 microns. The secondary mirror converts an F/ beam into an F/10 beam. Thus, the magnification of the secondary mirror is 3. The longitudinal magnification M L = M = 5 = 5 4. A 100µ change in focus will occur if S changes by 100/5 = 4µ = spacing tolerance January 018 35

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