List of Figures

• 5.1. Linear transformation of coordinates
• 5.2. Logarithmic transformation of $x$-coordinates
• 5.3. Exponential or power transformation of $x$-coordinates
• 5.4. Linear transformation of map coordinates
• 5.5. Polar (Cylindrical) transformation of ($\theta , r$) coordinates
• 5.6. Albers equal-area conic map projection
• 5.7. Lambert conformal conic map projection
• 5.8. Equidistant conic map projection
• 5.9. Rectangular map using the Lambert azimuthal equal-area projection.
• 5.10. Hemisphere map using the Lambert azimuthal equal-area projection.
• 5.11. Equal-Area (Schmidt) and Equal-Angle (Wulff) stereo nets
• 5.12. Polar stereographic conformal projection.
• 5.13. Polar stereographic conformal projection with rectangular borders.
• 5.14. General stereographic conformal projection with rectangular borders.
• 5.15. Hemisphere map using the Orthographic projection.
• 5.16. World map using the equidistant azimuthal projection.
• 5.17. Gnomonic azimuthal projection.
• 5.18. Simple Mercator map
• 5.19. Rectangular Transverse Mercator map
• 5.20. A global Transverse Mercator map
• 5.21. Oblique Mercator map using -Joc
• 5.22. Cassini map over Sardinia
• 5.23. World map using the equidistant cylindrical projection
• 5.24. World map using the Behrman cylindrical projection
• 5.25. World map using the Miller cylindrical projection
• 5.26. World map using the Hammer projection
• 5.27. World map using the Mollweide projection
• 5.28. World map using the Winkel Tripel projection
• 5.29. World map using the Robinson projection
• 5.30. World map using the Eckert IV projection
• 5.31. World map using the Eckert VI projection
• 5.32. World map using the Sinusoidal projection
• 5.33. World map using the Interrupted Sinusoidal projection
• 5.34. World map using the Van der Grinten projection
• 6.1. Contour maps of gridded data
• 6.2. Color images from gridded data
• 6.3. Spectral estimation and $x/y$-plots
• 6.4. 3-D perspective mesh plot
• 6.5. 3-D illuminated surface
• 6.6. Two kinds of histograms
• 6.7. A typical location map
• 6.8. A 3-D histogram
• 6.9. Time-series as ``wiggles'' along a track
• 6.10. Geographical bar graph
• 6.11. The color cube
• 6.12. Optimal triangulation of data
• 6.13. Display of vector fields in GMT
• 6.14. Gridding of data and trend surfaces
• 6.15. Gridding, contouring, and masking of data
• 6.16. More ways to grid data
• 6.17. Clipping of images using coastlines
• 6.18. Volumes and geo-spatial selections
• 6.19. Using color patterns in illustrations
• 6.20. Making a new volcano symbol for GMT
• 6.21. Using custom symbols in GMT
• B.1. Grid line registration of data nodes
• B.2. Pixel registration of data nodes
• F.1. Octal codes and corresponding symbols for standard fonts
• F.2. Octal codes and corresponding symbols for the Symbol font
• F.3. Octal codes and corresponding symbols for ZapfDingbats font
• G.1. The standard 39 PostScript fonts recognized by GMT
• J.1. Impulse responses for GMT filters
• J.2. Transfer functions for 1-D GMT filters
• J.3. Transfer functions for 2-D (radial) GMT filters
• K.1. Map using the crude resolution coastline data
• K.2. Map using the low resolution coastline data
• K.3. Map using the intermediate resolution coastline data
• K.4. Map using the high resolution coastline data
• K.5. Map using the full resolution coastline data