1167:. Therefore, in functions that have large ranges of magnitude, changes in magnitude can sometimes be hard to differentiate when a very large change is also pictured in the graph. This can be remedied with a discontinuous color function which shows a repeating brightness pattern for the magnitude based on a given equation. This allows smaller changes to be easily seen as well as larger changes that "discontinuously jump" to a higher magnitude. In the graph on the right, these discontinuities occur in circles around the center, and show a dimming of the graph that can then start becoming brighter again. A similar color function has been used for the graph on top of the article.
257:
248:
1105:
20:
98:. By assigning points on the complex plane to different colors and brightness, domain coloring allows for a function from the complex plane to itself — whose graph would normally require four space dimensions — to be easily represented and understood. This provides insight to the fluidity of complex functions and shows natural geometric extensions of
1213:
Discontinuities may be placed where outputs have a certain property to highlight which parts of the graph have that property. For instance, a graph may, instead of showing the color cyan, jump from green to blue. This causes a discontinuity that is easy to spot, and can highlight lines such as where
284:
Representing a four dimensional complex mapping with only two variables is undesirable, as methods like projections can result in a loss of information. However, it is possible to add variables that keep the four-dimensional process without requiring a visualization of four dimensions. In this case,
285:
the two added variables are visual inputs such as color and brightness because they are naturally two variables easily processed and distinguished by the human eye. This assignment is called a "color function". There are many different color functions used. A common practice is to represent the
1091:
Many color graphs have discontinuities, where instead of evenly changing brightness and color, it suddenly changes, even when the function itself is still smooth. This is done for a variety of reasons such as showing more detail or highlighting certain aspects of a function, like
229:
used the method in the late 1980s. Dan
Kucerovsky used it in 1990. The technique of using continuous color to map points from domain to codomain or image plane was used in 1999 by George Abdo and Paul Godfrey and colored grids were used in graphics by
488:
1214:
the argument is zero. Discontinuities may also affect large portions of a graph, such as a graph where the color wheel divides the graph into quadrants. In this way, it is easy to show where each quadrant ends up with relations to others.
1052:
Since the HSL color space is not perceptually uniform, one can see streaks of perceived brightness at yellow, cyan, and magenta (even though their absolute values are the same as red, green, and blue) and a halo around
1230:. This issue can possibly be ameliorated by creating alternate versions using color maps that fit within the color space discernible to those with color blindness. For example, for use by those with total
709:
782:
1045:(hue, saturation, lightness) color model. Saturation is always set at the maximum of 100%. Vivid colors of the rainbow are rotating in a continuous way on the complex unit circle, so the sixth
203:
556:
366:
911:
642:
1009:
943:
1149:
1036:
808:
313:
217:
The term "domain coloring" was coined by Frank Farris, possibly around 1998. There were many earlier uses of color to visualize complex functions, typically mapping
1199:
977:
576:
834:
156:
136:
1669:
1263:
644:
such that the inverse of a function is exactly as light as the original function is dark (and the other way around). Possible choices include
226:
1613:
1518:
1608:
1577:
278:(right) using the same color function, showing the three zeros as well as the negative real numbers as pink rays starting at the zeros.
162:
are represented by two variables and therefore two dimensions; this means that representing a complex function (more precisely, a
1290:
650:
1528:
1450:
Poelke, K.; Polthier, K. (September 2012). "Domain
Coloring of Complex Functions: An Implementation-Oriented Introduction".
716:
1704:
1363:
1323:
172:
84:
1649:
1346:
Kucerovsky, Dan (October 1990). "An algorithm for the visual representation of a two-dimensional vector field".
1234:, a color map based on blue/grey/yellow may be more readable than the conventional map based on blue/green/red.
505:
271:, as per the simple color function example described in the text (left), and the graph of the complex function
851:
1618:
589:
286:
1388:
1548:
1699:
1267:
375:
982:
837:
483:{\displaystyle {\begin{cases}H&=\arg z+2\pi /3,\\S&=100\%,\\L&=\ell (|z|).\end{cases}}}
1389:"Plotting functions of a complex variable: Table of Conformal Mappings Using Continuous Coloring"
916:
324:
163:
1437:
1111:
1014:
1572:
1159:
Unlike the argument, which has finite range, the magnitude of a complex number can range from
1664:
1656:
1632:
787:
292:
1592:
1177:
948:
561:
344:
8:
813:
583:
111:
1587:
1582:
1475:
1369:
1250:
579:
141:
121:
495:
332:
1524:
1467:
1413:
1359:
1319:
231:
1479:
1373:
1459:
1351:
1279:
Lundmark refers to Farris' coining the term "domain coloring" in this 2004 article.
1093:
218:
205:) requires the visualization of four dimensions. One way to achieve that is with a
167:
87:
72:
1679:
1573:
High-quality, browser-based interactive complex function plotter by Ricky
Reusseur
1313:
1231:
1223:
1076:
1042:
206:
1567:
1493:
1348:
Conference Record of the 1990 IEEE Industry
Applications Society Annual Meeting
841:
159:
1417:
1170:
Equations that determine the discontinuities may be linear, such as for every
1693:
1108:
A discontinuous color function. In the graph, each discontinuity occurs when
1046:
222:
115:
99:
95:
1355:
256:
118:
can be drawn in two dimensions because there are two represented variables,
1471:
1226:
may have trouble interpreting such graphs when they are made with standard
247:
1623:
1463:
1227:
320:
1641:
1104:
328:
1598:
848:
A widespread choice which does not have this property is the function
499:
1083:, correct this, making the images more accurate and less saturated.
1049:(starting with 1) are: green, cyan, blue, magenta, red, and yellow.
1684:
1636:
1080:
1171:
360:
1661:
1653:
1645:
1628:
1602:
1520:
Creating
Symmetry: The Artful Mathematics of Wallpaper Patterns
19:
1386:
1315:
Visual
Complex Functions: An Introduction with Phase Portraits
1264:"Visualizing complex analytic functions using domain coloring"
352:
91:
1680:
Fractal Zoomer : Software that utilizes domain coloring
1438:
http://users.mai.liu.se/hanlu09/complex/domain_coloring.html
1392:
476:
1549:"Colour Maps for the Colour Blind, presented at IAMG 2017"
1174:
magnitude, exponential equations such as every magnitude
491:
316:
704:{\displaystyle \ell _{1}(r)={\frac {2}{\pi }}\arctan(r)}
1674:
1657:
routines with user interface and various color schemes
67:, using the structured color function described below.
1180:
1114:
1017:
985:
951:
919:
854:
816:
790:
777:{\displaystyle \ell _{2}(r)={\frac {r^{a}}{r^{a}+1}}}
719:
653:
592:
564:
508:
369:
295:
175:
144:
124:
1288:
1665:routines for 3D-visualization of complex functions
1583:Visualizing complex-valued functions in the plane.
1193:
1143:
1030:
1003:
971:
937:
905:
828:
802:
776:
703:
636:
570:
550:
482:
307:
197:
150:
130:
1648:implementation of domain coloring by E. Petrisor
1609:Open source C and Python domain coloring software
1412:
1251:Visualizing complex-valued functions in the plane
502:. There are a number of choices for the function
1691:
1295:Pixel: The Magazine of Scientific Visualization
1086:
1624:Java domain coloring software (In development)
1523:. Princeton University Press. pp. 36–37.
1449:
198:{\displaystyle f:\mathbb {C} \to \mathbb {C} }
1261:
1311:
315:, (also known as "phase" or "angle") with a
209:, but another method is by domain coloring.
1685:cplot, a domain-coloring package for Python
1637:Python script for GIMP by Michael J. Gruber
16:Technique for visualizing complex functions
1345:
1208:
551:{\displaystyle \ell :[0,\infty )\to [0,1)}
191:
183:
1103:
338:
18:
1452:IEEE Computer Graphics and Applications
1387:George Abdo & Paul Godfrey (1999).
1255:
1692:
1546:
1516:
1494:"CET Perceptually Uniform Colour Maps"
1406:
1291:"A Color Gallery of Complex Functions"
1205:is an integer, or any other equation.
906:{\displaystyle \ell _{3}(r)=1-a^{|r|}}
1542:
1540:
1301:(4). Pixel Communications: 42 et seq.
1075:. More modern color spaces, e.g, the
637:{\displaystyle \ell (1/r)=1-\ell (r)}
23:Domain coloring plot of the function
1380:
363:, and a point at infinity in white:
1099:
13:
1537:
524:
430:
14:
1716:
1578:Color Graphs of Complex Functions
1561:
343:The following example colors the
1517:Farris, Frank A. (2 June 2015).
586:. Another desirable property is
255:
246:
1510:
1486:
1418:"Graphics for complex analysis"
1443:
1430:
1339:
1318:. Springer Basel. p. 29.
1305:
1282:
1243:
1217:
1124:
1116:
897:
889:
871:
865:
736:
730:
698:
692:
670:
664:
631:
625:
610:
596:
545:
533:
530:
527:
515:
467:
463:
455:
451:
187:
1:
1675:Real-Time Zooming Math Engine
1619:Domain Coloring Method on GPU
1237:
1004:{\displaystyle 0\leq r\leq 1}
105:
1588:Gallery of Complex Functions
1568:Samuel Li's function plotter
1289:David A. Rabenhorst (1990).
1087:Discontinuous color changing
7:
1614:Enhanced 3D Domain coloring
1440:Retrieved 13 December 2018.
938:{\displaystyle 0<a<1}
10:
1721:
1705:Numerical function drawing
1605:script for domain coloring
836:, this corresponds to the
212:
1144:{\displaystyle |z|=2^{n}}
1031:{\displaystyle \ell _{1}}
237:
838:stereographic projection
327:by other means, such as
1356:10.1109/IAS.1990.152292
1209:Highlighting properties
1041:This approach uses the
234:that he dates to 1997.
164:complex-valued function
1547:Kovesi, Peter (2017).
1262:Hans Lundmark (2004).
1222:People who experience
1195:
1156:
1145:
1032:
1005:
973:
939:
907:
830:
804:
803:{\displaystyle a>0}
778:
705:
638:
572:
552:
484:
309:
308:{\displaystyle \arg z}
199:
152:
132:
68:
1312:Elias Wegert (2012).
1196:
1194:{\displaystyle 2^{n}}
1146:
1107:
1033:
1006:
974:
972:{\displaystyle a=1/2}
940:
913:(with some parameter
908:
831:
805:
784:(with some parameter
779:
706:
639:
573:
571:{\displaystyle \ell }
553:
485:
339:Simple color function
310:
200:
153:
133:
94:to each point of the
22:
1464:10.1109/MCG.2012.100
1350:. pp. 903–909.
1178:
1112:
1015:
983:
949:
917:
852:
814:
788:
717:
651:
590:
562:
506:
367:
293:
173:
142:
122:
1599:John Davis software
829:{\displaystyle a=2}
83:is a technique for
1670:Color wheel method
1595:by Alessandro Rosa
1191:
1157:
1141:
1028:
1001:
969:
935:
903:
826:
800:
774:
701:
634:
580:strictly monotonic
568:
548:
480:
475:
305:
195:
148:
128:
69:
1530:978-0-691-16173-0
1414:Douglas N. Arnold
1249:Frank A. Farris,
1011:is very close to
772:
684:
151:{\displaystyle y}
131:{\displaystyle x}
88:complex functions
81:color wheel graph
1712:
1700:Complex analysis
1556:
1555:
1553:
1544:
1535:
1534:
1514:
1508:
1507:
1505:
1504:
1490:
1484:
1483:
1447:
1441:
1434:
1428:
1427:
1425:
1424:
1410:
1404:
1403:
1401:
1400:
1391:. Archived from
1384:
1378:
1377:
1343:
1337:
1336:
1334:
1332:
1309:
1303:
1302:
1286:
1280:
1278:
1276:
1275:
1266:. Archived from
1259:
1253:
1247:
1200:
1198:
1197:
1192:
1190:
1189:
1166:
1162:
1150:
1148:
1147:
1142:
1140:
1139:
1127:
1119:
1100:Magnitude growth
1074:
1073:
1071:
1070:
1067:
1064:
1037:
1035:
1034:
1029:
1027:
1026:
1010:
1008:
1007:
1002:
978:
976:
975:
970:
965:
944:
942:
941:
936:
912:
910:
909:
904:
902:
901:
900:
892:
864:
863:
835:
833:
832:
827:
809:
807:
806:
801:
783:
781:
780:
775:
773:
771:
764:
763:
753:
752:
743:
729:
728:
710:
708:
707:
702:
685:
677:
663:
662:
643:
641:
640:
635:
606:
577:
575:
574:
569:
557:
555:
554:
549:
489:
487:
486:
481:
479:
478:
466:
458:
408:
358:
350:
314:
312:
311:
306:
287:complex argument
277:
270:
259:
250:
204:
202:
201:
196:
194:
186:
168:complex variable
157:
155:
154:
149:
137:
135:
134:
129:
73:complex analysis
66:
65:
63:
62:
53:
50:
1720:
1719:
1715:
1714:
1713:
1711:
1710:
1709:
1690:
1689:
1564:
1559:
1551:
1545:
1538:
1531:
1515:
1511:
1502:
1500:
1498:peterkovesi.com
1492:
1491:
1487:
1448:
1444:
1435:
1431:
1422:
1420:
1411:
1407:
1398:
1396:
1385:
1381:
1366:
1344:
1340:
1330:
1328:
1326:
1310:
1306:
1287:
1283:
1273:
1271:
1260:
1256:
1248:
1244:
1240:
1224:color blindness
1220:
1211:
1185:
1181:
1179:
1176:
1175:
1164:
1160:
1135:
1131:
1123:
1115:
1113:
1110:
1109:
1102:
1089:
1077:Lab color space
1068:
1065:
1062:
1061:
1059:
1054:
1022:
1018:
1016:
1013:
1012:
984:
981:
980:
961:
950:
947:
946:
918:
915:
914:
896:
888:
887:
883:
859:
855:
853:
850:
849:
815:
812:
811:
789:
786:
785:
759:
755:
754:
748:
744:
742:
724:
720:
718:
715:
714:
676:
658:
654:
652:
649:
648:
602:
591:
588:
587:
563:
560:
559:
507:
504:
503:
474:
473:
462:
454:
443:
437:
436:
422:
416:
415:
404:
381:
371:
370:
368:
365:
364:
356:
348:
341:
294:
291:
290:
282:
281:
280:
279:
272:
266:
262:
261:
260:
252:
251:
240:
215:
207:Riemann surface
190:
182:
174:
171:
170:
160:complex numbers
143:
140:
139:
123:
120:
119:
108:
90:by assigning a
77:domain coloring
54:
51:
36:
35:
33:
24:
17:
12:
11:
5:
1718:
1708:
1707:
1702:
1688:
1687:
1682:
1677:
1672:
1667:
1659:
1651:
1639:
1634:
1626:
1621:
1616:
1611:
1606:
1596:
1593:Complex Mapper
1590:
1585:
1580:
1575:
1570:
1563:
1562:External links
1560:
1558:
1557:
1536:
1529:
1509:
1485:
1442:
1429:
1405:
1379:
1364:
1338:
1324:
1304:
1281:
1254:
1241:
1239:
1236:
1219:
1216:
1210:
1207:
1188:
1184:
1138:
1134:
1130:
1126:
1122:
1118:
1101:
1098:
1088:
1085:
1047:roots of unity
1025:
1021:
1000:
997:
994:
991:
988:
968:
964:
960:
957:
954:
934:
931:
928:
925:
922:
899:
895:
891:
886:
882:
879:
876:
873:
870:
867:
862:
858:
846:
845:
842:Riemann sphere
825:
822:
819:
799:
796:
793:
770:
767:
762:
758:
751:
747:
741:
738:
735:
732:
727:
723:
712:
700:
697:
694:
691:
688:
683:
680:
675:
672:
669:
666:
661:
657:
633:
630:
627:
624:
621:
618:
615:
612:
609:
605:
601:
598:
595:
567:
547:
544:
541:
538:
535:
532:
529:
526:
523:
520:
517:
514:
511:
477:
472:
469:
465:
461:
457:
453:
450:
447:
444:
442:
439:
438:
435:
432:
429:
426:
423:
421:
418:
417:
414:
411:
407:
403:
400:
397:
394:
391:
388:
385:
382:
380:
377:
376:
374:
340:
337:
319:following the
304:
301:
298:
276: − 1
264:
263:
254:
253:
245:
244:
243:
242:
241:
239:
236:
214:
211:
193:
189:
185:
181:
178:
147:
127:
107:
104:
100:real functions
15:
9:
6:
4:
3:
2:
1717:
1706:
1703:
1701:
1698:
1697:
1695:
1686:
1683:
1681:
1678:
1676:
1673:
1671:
1668:
1666:
1663:
1660:
1658:
1655:
1652:
1650:
1647:
1643:
1640:
1638:
1635:
1633:
1630:
1627:
1625:
1622:
1620:
1617:
1615:
1612:
1610:
1607:
1604:
1600:
1597:
1594:
1591:
1589:
1586:
1584:
1581:
1579:
1576:
1574:
1571:
1569:
1566:
1565:
1550:
1543:
1541:
1532:
1526:
1522:
1521:
1513:
1499:
1495:
1489:
1481:
1477:
1473:
1469:
1465:
1461:
1457:
1453:
1446:
1439:
1433:
1419:
1415:
1409:
1395:on 2020-03-16
1394:
1390:
1383:
1375:
1371:
1367:
1365:0-87942-553-9
1361:
1357:
1353:
1349:
1342:
1327:
1325:9783034801799
1321:
1317:
1316:
1308:
1300:
1296:
1292:
1285:
1270:on 2006-05-02
1269:
1265:
1258:
1252:
1246:
1242:
1235:
1233:
1229:
1225:
1215:
1206:
1204:
1186:
1182:
1173:
1168:
1154:
1151:for integers
1136:
1132:
1128:
1120:
1106:
1097:
1095:
1084:
1082:
1078:
1057:
1050:
1048:
1044:
1039:
1023:
1019:
998:
995:
992:
989:
986:
966:
962:
958:
955:
952:
932:
929:
926:
923:
920:
893:
884:
880:
877:
874:
868:
860:
856:
843:
839:
823:
820:
817:
797:
794:
791:
768:
765:
760:
756:
749:
745:
739:
733:
725:
721:
713:
695:
689:
686:
681:
678:
673:
667:
659:
655:
647:
646:
645:
628:
622:
619:
616:
613:
607:
603:
599:
593:
585:
581:
565:
542:
539:
536:
521:
518:
512:
509:
501:
497:
493:
470:
459:
448:
445:
440:
433:
427:
424:
419:
412:
409:
405:
401:
398:
395:
392:
389:
386:
383:
378:
372:
362:
354:
346:
336:
334:
330:
326:
322:
318:
302:
299:
296:
288:
275:
269:
258:
249:
235:
233:
228:
224:
220:
210:
208:
179:
176:
169:
165:
161:
145:
125:
117:
116:real function
113:
103:
101:
97:
96:complex plane
93:
89:
86:
82:
78:
74:
61:
57:
48:
44:
40:
31:
27:
21:
1519:
1512:
1501:. Retrieved
1497:
1488:
1458:(5): 90–97.
1455:
1451:
1445:
1432:
1421:. Retrieved
1408:
1397:. Retrieved
1393:the original
1382:
1347:
1341:
1329:. Retrieved
1314:
1307:
1298:
1294:
1284:
1272:. Retrieved
1268:the original
1257:
1245:
1232:deuteranopia
1221:
1212:
1202:
1169:
1158:
1152:
1090:
1055:
1051:
1040:
945:) which for
847:
342:
283:
273:
267:
216:
109:
80:
76:
70:
59:
55:
46:
42:
38:
29:
25:
1218:Limitations
498:, and L is
490:Where H is
321:color wheel
265:HL plot of
232:Doug Arnold
227:Larry Crone
158:. However,
85:visualizing
1694:Categories
1642:Matplotlib
1503:2020-12-22
1436:May 2004.
1423:2008-05-17
1399:2008-05-17
1274:2006-05-25
1238:References
1228:color maps
1094:level sets
584:continuous
578:should be
496:saturation
347:in black,
333:saturation
329:brightness
323:, and the
225:) to hue.
106:Motivation
1631:routines
1331:6 January
1020:ℓ
996:≤
990:≤
881:−
857:ℓ
840:onto the
722:ℓ
690:
682:π
656:ℓ
623:ℓ
620:−
594:ℓ
566:ℓ
531:→
525:∞
510:ℓ
500:lightness
449:ℓ
431:%
402:π
390:
325:magnitude
300:
188:→
1480:19237225
1472:24806991
1416:(2008).
1374:34434375
1081:CIECAM02
810:). With
219:argument
1172:integer
1072:
1060:
494:, S is
361:magenta
213:History
166:of one
64:
58:+ 2 + 2
34:
1662:MATLAB
1654:MATLAB
1646:MayaVi
1629:MATLAB
1603:S-Lang
1527:
1478:
1470:
1372:
1362:
1322:
1201:where
687:arctan
345:origin
238:Method
45:− 2 −
1552:(PDF)
1476:S2CID
1370:S2CID
353:green
223:phase
114:of a
112:graph
92:color
79:or a
41:− 1)(
1644:and
1525:ISBN
1468:PMID
1360:ISBN
1333:2016
1320:ISBN
979:and
930:<
924:<
795:>
582:and
138:and
32:) =
1460:doi
1352:doi
1163:to
1079:or
1043:HSL
711:and
492:hue
428:100
387:arg
359:in
351:in
335:.
331:or
317:hue
297:arg
71:In
1696::
1601:,
1539:^
1496:.
1474:.
1466:.
1456:32
1454:.
1368:.
1358:.
1297:.
1293:.
1096:.
1058:=
1038:.
558:.
357:−1
355:,
289:,
110:A
102:.
75:,
1554:.
1533:.
1506:.
1482:.
1462::
1426:.
1402:.
1376:.
1354::
1335:.
1299:1
1277:.
1203:n
1187:n
1183:2
1165:∞
1161:0
1155:.
1153:n
1137:n
1133:2
1129:=
1125:|
1121:z
1117:|
1069:2
1066:/
1063:1
1056:L
1024:1
999:1
993:r
987:0
967:2
963:/
959:1
956:=
953:a
933:1
927:a
921:0
898:|
894:r
890:|
885:a
878:1
875:=
872:)
869:r
866:(
861:3
844:.
824:2
821:=
818:a
798:0
792:a
769:1
766:+
761:a
757:r
750:a
746:r
740:=
737:)
734:r
731:(
726:2
699:)
696:r
693:(
679:2
674:=
671:)
668:r
665:(
660:1
632:)
629:r
626:(
617:1
614:=
611:)
608:r
604:/
600:1
597:(
546:)
543:1
540:,
537:0
534:[
528:)
522:,
519:0
516:[
513::
471:.
468:)
464:|
460:z
456:|
452:(
446:=
441:L
434:,
425:=
420:S
413:,
410:3
406:/
399:2
396:+
393:z
384:=
379:H
373:{
349:1
303:z
274:z
268:z
221:(
192:C
184:C
180::
177:f
146:y
126:x
60:i
56:x
52:/
49:)
47:i
43:x
39:x
37:(
30:x
28:(
26:f
Text is available under the Creative Commons Attribution-ShareAlike License. Additional terms may apply.