EDITSVG: Help and advice


Consult the reference manual and tutorials for more details and worked examples.
W.G.Bardsley, University of Manchester, U.K.

SVG graphics

In order to appreciate the nature and use of scalable vector graphics files (*.SVG) it is useful to review the two document types, namely bitmap and vector, that are used to archive graphs and include them into computer generated documents or web pages.

Bitmaps

These files (*.BMP) contain the raw information for every pixel captured by a digital photograph or displayed on a computer screen. They have the following properties.

  1. The larger the number of pixels then the greater the detail recorded.
  2. Such files are very easy to display, include in documents, or print but, unless there is a large number of pixels, then lines and curves will appear stepped and fonts will pixelate.
  3. For complicated portraits, landscapes, capture of microscope fields, or 3D display of molecules etc. requiring shading such files are indispensable.
  4. Where there are appreciable homogeneous patches such as blue sky in a landscape then considerable compression into formats such those of the joint photographic expert group (*.JPG) or portable network graphics (*.PNG) can result in smaller files, but compression is not lossless.
  5. Where a bitmap has been created using antialiasing to smooth out polygons and polylines as in text, curves, or lines then compression can lead to fuzzy curves or distorted characters. Traditional computer graphics hardly ever looked good on computer screens because hard edges at an angle would show as a series of steps (a distortion known as aliasing). This made even the simplest graph - such as a sine curve, look ugly. This problem has been largely eliminated by anti-aliasing (automatically employed by SIMFIT). However a bitmap of a specific size generated using anti-aliasing, never looks its best if it is ultimately displayed at another resolution. SVG completely sidesteps this problem because the necessary anti-aliasing is performed as an image is displayed (or printed), so that data are displayed correctly. This property of being device-independent is something that sets aside vector graphics from bitmap graphics.

Vector graphics

Scientific graphs largely consist of axes, curves, and plotting symbols, with small amounts of text, and vector graphic files simply contain the mathematical data such as coordinates necessary to reproduce the graph at any degree of magnification or compression without loss of information. Here is a summary of properties for the two main vector graphics files; encapsulated PostScript (*.EPS), and scalable vector graphics (*.SVG).

Bogus vector files

Note that many applications claim to transform bitmap and compressed bitmap files into vector files without loss of information but this is impossible.

Such applications usually just exploit a weakness in vector files that allows bitmaps to be inserted giving bogus vector files that are wrappers containing bitmaps. Similarly portable document files (*.PDF) were developed from PostScript and retain many PostScript features that can be exploited. For instance, using the SIMFIT interface to GhostScript to transform SIMFIT EPS files into PDF files yields PDF files that are effectively device independent, whereas using Windows to distil files into PDF merely creates bitmap files.

Using SVG files in SIMFIT

The SVG format is very comprehensive as it has been specifically developed to be versatile for web use. For that reason few applications implement the whole standard and SIMFIT is no exception, so it must be emphasized that SIMFIT will only accept and manipulate SVG files according to the graph plotting functionality provided by Silverfrost FTN95 Clearwin+. This interface was written by David Bailey and it provides the following SVG file functionality for SIMFIT users.

Editing SVG files in SIMFIT

The functionality provided by procedure EditSVG is now listed.

  1. The only file types that can be used in this program are:
    [(A)] *.SVG files created by SIMFIT, and
    [(B)] *.TEX files describing mathematical equations or chemical formulas.
    Such *.TEX files can be used to generate internal *.SVG files if latex.exe, dvips.exe, and dvisvgm.exe are on the path. For instance if users have a recent version of MikTeX available.
  2. Files can be input from the console, by drag and drop, or by using library files.
  3. Images can be enlarged or reduced.
  4. Images can be moved freely or positioned using a graticule with optional snap to nearest corner facility.
  5. After manipulating a file or a set of files the resulting composite image can be written out to a *.SVG, *.JPG, or *.PNG, file, or even to a *.ISVG rebuild-image file.
  6. It can be used to create strict collages where every image is snapped to the nearest grid point, freestyle collages where images can be arranged in arbitrary positions, or overlays where smaller images can be inserted into larger ones.

Examples

Some examples of how to use these procedures within the SIMFIT package from version 7.5.0 onwards using the test files provided follow. However the procedure used to create the SVG files using LaTeX should be noted.

LaTeX is designed to create documents and, because of this, care is needed to remove much of the header information in order to create simple images that can be imported into EditSVG. This is much the same as the steps required to create a *.EPS from from a *.PS file but using the following commands.

[To make DVI:] use the command ... latex myfile.tex (to create myfile.dvi).
[To make PS:] use the command ... dvips myfile.dvi (to create myfile.ps).
[To make SVG:] use the command ... dvisvgm -E --no-fonts myfile.ps (to create myfile.SVG).

The argument -E indicates that a PostScript file is to be input, while the argument --no-fonts directs dvisvgm to use Bezier font outlines. Note that white space can be trimmed from the resulting SVG file by EditSVG, or alternatively by using Inkscape or GSview (e.g. Version 5) to transform myfile.ps in to myfile.eps, where the BoundingBox will automatically remove white space.

Important differences between EPS and SVG files

From within any SIMFIT graph it is possible to create *.EPS files by first selecting [PS] then choosing [File], or to create *.SVG files by first selecting [Win] then choosing the [SVG] option. Any *.SVG file created in this way will be a fairly accurate representation of the display, as will any *.EPS files, except that there will be small but significant differences between them. That is unavoidable because the fonts used may differ slightly as the *.SVG file will use Windows fonts whereas the *EPS file will use PostScript fonts. In addition SIMFIT allows users to set different global line thickness for EPS and SVG files as line thickness do not scale in exactly the same way in EPS and SVG files. Nevertheless it is useful to know how to create a *.SVG file from a *.EPS file and vice versa.

Fortunately such transformations can readily be carried out due to the widespread availability of Open Source programs such as Inkscape and Cairo. The usefulness of such transformations are explained in related tutorial documents.

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