enafsqarhyazeubebgcazh-CNhrcsdanltlfifrdeeliwhihuisidgaitjakolvltmkmsmtnofaplptrorusrskslesswsvthtrukurvi
enafsqarhyazeubebgcazh-CNhrcsdanltlfifrdeeliwhihuisidgaitjakolvltmkmsmtnofaplptrorusrskslesswsvthtrukurvi

Tagged with: Point Source Microscope

Aligning a Parabola to an Autocollimating Flat Mirror (ABSTRACT)

ABSTRACT: An autostigmatic microscope is a perfect way of aligning an autocollimating flat mirror to a parabola. This notes descibes the simple two step process of positioning the PSM objective focus coincident with the focus of the parabola.

Alignment of 4-Mirror Wide Field Corrector for the Hobby-Eberly Telescope (ABSTRACT)

ABSTRACT: Paper by Oh describing the use of an autostigmatic microscope (PSM) to precisely position computer generated hologram (CGH) alignment targets on optical surfaces.

Alignment of Optical Systems (ABSTRACT)

ABSTRACT: Describes the advantages of aligning optical systems using a Point Source Microscope (PSM) where the optical axis of the system is folded in 2 or 3 dimensions  and shows how pseudo aberrations can be generated that show quantitatively the degree of precision of the alignment from the Star image seen in the PSM.

Centering Steep Aspheric Surfaces (ABSTRACT)

ABSTRACT: We describe a method of finding the optical axis of an aspheric surface by looking at an annulus of the surface as the surface is rotated in azimuth. The method uses either an autostigmatic microscope or an interferometer to view the annulus. Distinctive features of the reflected spot movement, or the changes in Zernike coefficients found with interferometry while the surface is rotated in azimuth permits the separation of decenter from tilt. The method appears to be suitable for use with any aspheric surface.

Measuring the Four Paraxial Lens Parameters using an Autostigmatic Microscope (ABSTRACT)

ABSTRACT: Describes using an autostigmatic microscope (PSM) to find the two radii, thickness and index of a singlet lens by making 4 distance measurements similar to those used to measure the radius of curvature of a concave mirror, and then using the 4 distances to iteratively calculate the 4 paraxial lens parameters using an Excel spreadsheet and its Solver application.

Method of Alignment using a Laser Tracker System (ABSTRACT)

ABSTRACT: Demonstrates a method of using a laser tracker, a simple special fixture and a Point Source Microscope (PSM) to create a virtual spherical mounted retroreflector (SMR) for situations where a SMR cannot be attached to the surface to be measured.

Non-Contact Probe for On-Machine Metrology (ABSTRACT)

ABSTRACT: On-machine metrology is particularly important for diamond turning and grinding as it is difficult to remount and align a part if it does not meet off-line inspection criteria. There is also the issue of tool wear; a process that started well may fail part way through the cut, and if tool replacement is needed, it is vital to know that before removing the part. A means of rapid, noncontact, in situ profiling and roughness measurement could improve the productivity of diamond tool machining.

Optical Alignment Using the Point Source Microscope (ABSTRACT)

ABSTRACT: A companion paper to "Alignment of an off-axis telescope and prism train" showing more detail of the mechanics involved in the telescope alignment and the multi-sensor instrument package.

Prism alignment using a Point Source Microscope (ABSTRACT)

ABSTRACT: The Point Source Microscope (PSM) is used to locate the apex of retroreflecting prisms in 3 degrees of translational freedom with a precision of less than 1 micron. The process is easily explained for right angle prisms, as will be done in this paper, but the explanation is valid for cube corner retroreflectors such as those mounted in spherical balls, spherically mounted retroreflectors, or SMRs, for use with laser trackers. With suitable, simple fixturing, the measurements for all 3 directions are made to a precision of < 1 μm in less than 1 minute.

Reverse Engineering Lens Elements (ABSTRACT)

ABSTRACT:  Describes using an autostigmatic microscope (PSM) to find the two radii, thickness and index of a singlet lens by making 4 distance measurements similar to those used to measure the radius of curvature of a concave mirror, and then using the 4 distances to iteratively calculate the 4 paraxial lens parameters using an Excel spreadsheet and its Solver application.

The Autostigmatic Microscope (ABSTRACT)

ABSTRACT: This relatively recent (1983) paper by W. H. Steel of CSIRO is the only paper found in the archival literature to describe an autostigmatic microscope (ASM) and its most common use, the measurement of radii of curvature, in this case, the radii of contact lenses. The Point Source Microscope (PSM) is a modern version of this classical instrument.

What is a Point Source Microscope? (ABSTRACT)

ABSTRACT: As opposed to a bright field, reflecting microscope that produces an image of a microscopic object, a point source, or autostigmatic, microscope uses pinhole illumination to produce a diffration limited spot at the objective focus and that spot diverges as a nearly perfect spherical wavefront. This note describes many useful applications of the Point Source Microscope (PSM), a modern version of the classic autostigmatic microscope, that also includes a bright field imaging option and is useful as an autocollimator.

Case Studies & Testimonials

  • "As always we are very much loving the instrument, I personally love the camera upgrade from what I'm used to!"

    Weslin Pullen
    Hart Scientific Consulting International, LLC
    Tucson, Arizona

     

  • The PSM is an ideal tool for finding the center of curvature of a ball or the axis of a cylinder. The question is for how small a ball or cylinder can the PSM do this?

    The smallest article that was readily available was a piece of monofilament 8 pound test fishing line that was 290 μm in diameter. There was no problem finding the axis of the fishline, and separating the Cat’s eye reflection from the surface from the confocal reflection of the axis. The experiment was done with a 5x objective, and the result would have been even more definitive using a 10x objective.

  • Here is a case of a very happy customer due to better optics.

    A few days ago an astronomer friend of mine commented that he had gotten the optics of his telescope improved and the improvement reduced the time it took to get data by a factor of 3. For an astronomer this is a dramatic improvement since observing time on large telescopes can cost thousands of dollars an hour.

    My friend did not say how the optics had been improved, but the important point is that better optics, whether due to figure errors, mounting or alignment mean more productive optics. I generally think of better optics as a better product leaving the manufacturing facility without thinking about how much the better optics mean to the productivity of the customer.

Worldwide Representatives

FOR SALES IN CHINA PLEASE CONTACT:

FOR SALES IN CHINA PLEASE CONTACT:
OPTurn Company Ltd
R607, Yingzhi Building, 49-3 Suzhoujie Str.
Beijing, China
+86-10 62527842
This email address is being protected from spambots. You need JavaScript enabled to view it.

More Info

FOR SALES IN ALL OTHER ASIAN COUNTRIES PLEASE CONTACT:

FOR SALES IN ALL OTHER ASIAN COUNTRIES PLEASE CONTACT:

上原 賢司   Kenji Uehara
清原光学 営業部   Kiyohara Optics / Sales
+81.80.6600.6702
This email address is being protected from spambots. You need JavaScript enabled to view it.

Kiyohara Optics Inc.
3-28-10 Funado Itabashi-Ku Tokyo, Japan 174-0041

More Info