Calculators + Utilities: Difference between revisions

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*Fast and very effective viewing of layer overlay, overlay multiple files, cell hierarchy etc.
*Fast and very effective viewing of layer overlay, overlay multiple files, cell hierarchy etc.
*‘Before’ starting your design, set the '''''Layout Properties > Database Unit''''' to something small eg. 0.0001 µm (0.1nm).
*‘Before’ starting your design, set the '''''Layout Properties > Database Unit''''' to something small eg. 0.0001 µm (0.1nm).
*Turn on the display of the Origin (0,0) in '''''Preferences > Display > Background > Axis''''' = choose an option apart from the default "invisible", eg. "'''''Lines with Ticks'''''".
*The only confusing part about KLayout is how to draw circles. You have to draw a square, and then apply the '''''Edit>Selection>Round Corners''''' function. This is for compatibility, because GDS files do not have a "circle" primitive built-in. Make sure you include enough polygon points, eg. 200. See the [https://www.klayout.de/forum/discussion/142/making-circles forum help pages] on this for more info.
*How to draw circles. You have to draw a square, and then apply the '''''Edit>Selection>Round Corners''''' function with '''''Outer Corner Radius''''' = the desired circle radius. This is for compatibility, because GDS files do not have a "circle" primitive built-in, so instead it creates a polygon. Make sure you include enough polygon points, eg. 100. See the [https://www.klayout.de/forum/discussion/142/making-circles forum help pages] on this for more info.


====CAD Design Tips====
====CAD Design Tips====
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==== Example CAD File ====
==== Example CAD File ====
Here is an example CAD file, showing the use of Layers and Cells, designed in KLayout. The device is fictional, for illustrative purposes only.
Here is an example CAD file, showing the use of Layers and Cells, designed in KLayout. The device is fictional, for illustrative purposes only.
* [[Media:CAD_Tutorial_for_ASML_Reticle_v1.OAS|CAD_Tutorial_for_ASML_Reticle_v1.OAS]] (Demis D. John)
* [//wiki.nanotech.ucsb.edu/w/images/a/ae/CAD_Tutorial_for_ASML_Reticle_v1.OAS CAD_Tutorial_for_ASML_Reticle_v1.OAS] (Demis D. John)
* Cell "'''Device_Layout'''" shows a single device, with each ''Layer'' overlaid as it would be in a fabricated device. Each Layer (eg. a "process step" such as Mesa etch, Pad Metal etc.) is placed into it's own Cell.
* Cell "'''Device_Layout'''" shows a single device, with each ''Layer'' overlaid as it would be in a fabricated device. Each Layer (eg. a "process step" such as Mesa etch, Pad Metal etc.) is placed into it's own Cell.
:[[File:CAD Tutorial for ASML Reticle v1 - screenshot Device Layout cell.png|alt=screenshot of KLayout view of Device_Layout|none|thumb|530px|"Device_Layout" Cell showing as the "top cell"]]
:[[File:CAD Tutorial for ASML Reticle v1 - screenshot Device Layout cell.png|alt=screenshot of KLayout view of Device_Layout|none|thumb|530px|"Device_Layout" Cell showing as the "top cell"]]
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** One way this can be accomplished is by selecting the objects/polygons you want to make into a new Cell, then use the function '''Edit >''' '''Selection > Make Cell''', and ''uncheck'' the "''Put Origin at...''" checkbox, so the new Cell maintains the same origin as the original view.
** One way this can be accomplished is by selecting the objects/polygons you want to make into a new Cell, then use the function '''Edit >''' '''Selection > Make Cell''', and ''uncheck'' the "''Put Origin at...''" checkbox, so the new Cell maintains the same origin as the original view.
* The Cell "'''Reticle_Layout'''" can be exported by itself (right-click the Cell name), for sending to the photomask manufacturer.
* The Cell "'''Reticle_Layout'''" can be exported by itself (right-click the Cell name), for sending to the photomask manufacturer.
** [[Media:DEMISJAN2020_-_Reticle_Layout_v1.GDS|Here is and example GDS file (download)]] for submission to the photomask manufacturer, with all objects moved to a single Layer.
** [//wiki.nanotech.ucsb.edu/w/images/3/34/DEMISJAN2020_-_Reticle_Layout_v1.GDS Here is and example GDS file (download)] for submission to the photomask manufacturer, with all objects moved to a single Layer.
* See the [[ASML 5500 Mask Making Guidelines#Example CAD File and Programming|ASML Mask Making Guidelines page]] for an example of how to program this Reticle into an ASML Stepper job.
* See the [[ASML 5500 Mask Making Guidelines#Example CAD File and Programming|ASML Mask Making Guidelines page]] for an example of how to program this Reticle into an ASML Stepper job.



Revision as of 16:25, 11 December 2020

This page lists a few online calculators and utilities that are useful to lab users.

Fabrication Processes & Converters

Material Parameters

Wet Etching

Refractive Indices

Optical constants of many common materials. Useful for Optical thin-film analysis (ellipsometry/spectroscopic fitting), laser etch monitoring, optical filter/mirror/anti-reflection coating design, photonic devices etc.

Scripts + Programs

Analysis Programs

  • AmScope Software - microscope image analysis software
    • AmScope Calibration File containing calibrations for all NanoFab microscopes: Download Here
    • Also available on Nanofiles-SFTP / Manuals / Amscope
  • FIJI - scientific image anaylsis software
  • Gwyddion - free analysis software for Atomic Force Microscopes (AFMs) and other 3D data.
    • Sophisticated leveling, slicing, roughness/particulate analysis functions etc.
    • Can open Bruker NanoScope files, from the AFM
  • ProfilmOnline.com (Filmetrics) - online analysis/storage/sharing of 3D topographical data and images.
    • You can share an interactive 3D render of your AFM or Profilm3D scans with this tool.
    • Example AFM Scan, taken with NanoFab equipment, shared online for interactive analysis (slice, flatten etc.).

CAD Layout Programs

Use these for designing your lithography mask plates.

L-Edit

Powerful multi-layer layout program. Sophisticated object instantiation and array layout, to reduce files sizes and easily push changes to multiple cells.

KLayout

A free, open-source, and fast/simple CAD tool for mask/reticle layout. Download at klayout.de.

  • Available on Windows, Mac or *Nix.
  • Easily scriptable with Python or Ruby, with decent tutorials.
  • Fast and very effective viewing of layer overlay, overlay multiple files, cell hierarchy etc.
  • ‘Before’ starting your design, set the Layout Properties > Database Unit to something small eg. 0.0001 µm (0.1nm).
  • Turn on the display of the Origin (0,0) in Preferences > Display > Background > Axis = choose an option apart from the default "invisible", eg. "Lines with Ticks".
  • How to draw circles. You have to draw a square, and then apply the Edit>Selection>Round Corners function with Outer Corner Radius = the desired circle radius. This is for compatibility, because GDS files do not have a "circle" primitive built-in, so instead it creates a polygon. Make sure you include enough polygon points, eg. 100. See the forum help pages on this for more info.

CAD Design Tips

It is highly recommended that you understand and use the concept of "Cells" in your design. This circumvents many problems with enormous file sizes (due to huge numbers of identical polygons), and if used properly, helps tremendously with programming the Stepper lithography machines. Links to documentation below:

OASIS files tend to be much smaller than GDS files, and they also save the Layer Names (not just number). Alternatively, in KLayout the function File > Save Session will save the entire view including layer styles and window/zoom locations will be saved. You can share this file, as the entire design file is embedded within it, but it may not be as robust between KLayout versions.

Example CAD File

Here is an example CAD file, showing the use of Layers and Cells, designed in KLayout. The device is fictional, for illustrative purposes only.

  • CAD_Tutorial_for_ASML_Reticle_v1.OAS (Demis D. John)
  • Cell "Device_Layout" shows a single device, with each Layer overlaid as it would be in a fabricated device. Each Layer (eg. a "process step" such as Mesa etch, Pad Metal etc.) is placed into it's own Cell.
screenshot of KLayout view of Device_Layout
"Device_Layout" Cell showing as the "top cell"
  • Every Cell's Origin (0,0) lies on top of one another in the final Device_Layout.
    • One way this can be accomplished is by selecting the objects/polygons you want to make into a new Cell, then use the function Edit > Selection > Make Cell, and uncheck the "Put Origin at..." checkbox, so the new Cell maintains the same origin as the original view.
  • The Cell "Reticle_Layout" can be exported by itself (right-click the Cell name), for sending to the photomask manufacturer.
  • See the ASML Mask Making Guidelines page for an example of how to program this Reticle into an ASML Stepper job.

General Calculators

  • Anaconda Python
    • A free Matlab-like IDE and GUI, using the Python language. The Spyder interface is modeled after Matlab.
    • Includes the scientific Python libraries needed for array math (numpy), plotting (matplotlib), data science (pandas) and many others. Many open-source packages are available to extend capabilities. The PyVisa module adds equipment control capabilities for automated measurements.
  • Wolfram Alpha
    • A versatile online interpreter/calculator, allowing calculations such as "Volume of 1.5g of Silicon", "melting point of SiO2" or "520°C in Fahrenheit".

Python Scripts

These scripts are best run in the Spyder IDE, which is easily installed via Anaconda, Python(X,Y), or by directly compiling Spyder using a command-line package manager.

  • Keithley I-V Sweep
    • Sweep voltage and plot current vs. voltage using a Keithley SMU.
    • Already installed at the Probe Station in Bay 4, and on the QFI Thermal Microscope (Use Python(X,Y) to run).
    • Requires the pyvisa python module.
  • QFIScope Thermal Analysis
    • Import 2D temperature data from the IR Thermal Microscope (QFI) and plot temperature profiles at user-specified locations.
    • Already installed on the QFI Infrared Microscope.
  • Laser Etch Monitor Simulation in Python
    • Simulate your laser endpoint signal as you dry-etch through a stack of thin-film layers, using an open-source electromagnetics module.
  • nk.py (Demis D. John)
    • Python functions for returning n (ref. idx.) & k (ext. coeff.) of various NanoFab thin-films at a specified wavelength (aka. dispersion models).