%BEG NE83/10Q/Q83E00ZED Output Linearization (OL) LAB* -> cmyolvnw* 20060101 /sggray {setgray} bind def /sgrgbcolor {setrgbcolor} bind def /sgcmykcolor {setcmykcolor} bind def /sgtransfer {settransfer} bind def /sgcolortransfer {setcolortransfer} bind def /sgcolor {setcolor} bind def %FILE PREPARED FOR MIXED MODE, e. g. input ORS18 and output TLS00 /IMES 0 def %0=LAB* used, no reflection factor necessary %/IMES 1 def /Yre 2.52 def %1=XYZ measurement and standard device reflection %/i*ptrsc 0 def %LAB* setcolor to cmy0* / 000n* setcmykcolor /i*ptrsc 1 def %LAB* setcolor to olv* setrgbcolor / w* setgray %/i*ptrsc 2 def %LAB* setcolor to cmy0* / nnn0* setcmykcolor %/i*ptrsc 3 def %LAB* setcolor to olv* / www* setrgbcolor %/i*ptrsc 4 def %LAB* setcolor to lab* setcolor %/i*ptrsc 5 def %LAB* setcolor to LAB* setcolor %/i*ptrsc 6 def %LAB* setcolor to 000n* setcmykcolor %/i*ptrsc 7 def %LAB* setcolor to w* setgray %/ISIN*ioG 0 def %default input for Offset Reflective System (ORS18) %/ISOU*ioG 0 def %default output dto. /ISIN*ioG 1 def %input for Television Luminous System (TLS00) %/ISOU*ioG 1 def %output dto. %/ISIN*ioG 2 def %input for Device Reflective measurement system (DRSXX) %/ISOU*ioG 2 def %output dto. %/ISIN*ioG 3 def %input for Television Luminous Reflection System (TLS18) %/ISOU*ioG 3 def %output dto. %/ISIN*ioG 4 def %input for Natural Luminous System (NLS00) %/ISOU*ioG 4 def %output dto. %/ISIN*ioG 5 def %input for Natural Reflective System (NRS18) %/ISOU*ioG 5 def %output dto. %/ISIN*ioG 6 def %input for Standard Reflective System (SRS18) %/ISOU*ioG 6 def %output dto. %/ISIN*ioG 7 def %input for Standard Reflective System (TLS70) /ISOU*ioG 7 def %output dto. /iLAB 0 def /ISIO*ioG 0 def /ISRL*ioG 0 def % for io-System, only once %line 36*************************************************************** %line 38*************************************************************** /LAB*ioG {%BEG Procedure LAB*ioG (L=local) %requires ISRL*ioG=0,1,3 /RJGBLAB* 12 array def /RJGBLAB*[ 39.92 58.74 27.99 % r CIE No.09 elementary colours in LAB, D65 81.26 -2.89 71.56 % J CIE No.10 52.23 -42.42 13.60 % G CIE No.11 30.57 1.41 -46.47 % B CIE No.12 ] def /LAB* 36 array def /LAB*a 36 array def /LAB*00 24 array def /LAB*01 24 array def /LAB*02 24 array def /LAB*03 24 array def /LAB*04 24 array def /LAB*05 24 array def /LAB*06 24 array def /LAB*07 24 array def ISRL*ioG 0 eq { %ISRL*ioG=0 /LAB*00 [%D=Device OYLCVMO+NW %for Offset Reflective System (ORS18) 47.94 65.31 52.07 %O 0 90.37 -11.16 96.17 %Y 1 50.90 -62.97 36.71 %L 2 58.62 -30.63 -42.75 %C 3 %see TABle 1 of ISO/IEC 15775:1999-12 25.72 31.45 -44.36 %V 4 48.13 75.20 -6.80 %M 5 18.01 0.50 -0.47 %N 7 95.41 -0.99 4.76 %W 8 ] def %OYLCVMO+NW /LAB*01 [%D=Device OYLCVMO+NW %for Television Luminous System (TLS00) 50.50 76.92 64.55 %O 0 92.66 -20.70 90.75 %Y 1 83.63 -82.76 79.90 %L 2 86.88 -46.17 -13.56 %C 3 %see TABle 1 of ISO/IEC 15775:1999-12 30.39 76.06 -103.6 %V 4 corected 57.30 94.35 -58.42 %M 5 corected 00.01 0.00 0.00 %N 7 corected 95.41 0.00 0.00 %W 8 ] def %OYLCVMO+NW /LAB*02 [%D=Device OYLCVMO+NW %for Device Reflective System (DRSXX) 42.21 65.82 52.84 %O-W 0 cmy0* setcmykcolor 64 90.32 -16.74 106.88 %Y-W 1 cmy0* setcmykcolor 32 48.21 -76.54 32.93 %L-W 2 cmy0* setcmykcolor 80 53.44 -34.16 -45.19 %C-W 3 cmy0* setcmykcolor 0 actual printer 34.16 -2.06 -44.39 %V-W 4 cmy0* setcmykcolor 96 42.71 78.01 0.28 %M-W 5 cmy0* setcmykcolor 16 16.56 -1.42 2.07 %N-W 6 000n* setcmykcolor 48 96.31 -0.12 2.59 %A-W 7 ] def %OYLCVMO+NW /LAB*03 [%D=Device OYLCVMO+NW %for Television Luminous System (TLS18) 52.76 71.63 49.88 %O 0 92.74 -20.03 84.97 %Y 1 84.00 -78.99 73.94 %L 2 87.14 -44.42 -13.12 %C 3 %see TABle 1 of ISO/IEC 15775:1999-12 35.47 64.92 -95.07 %V 4 %see TABle X of ISO/IEC TR 24705:2005-10 59.01 89.33 -55.68 %M 5 %see Annex A, www.ps.bam.de/RLABE.PDF 18.01 0.00 0.00 %N 6 Yr=2.52 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW /LAB*04 [%Natural symmetric Luminous System OYLCVMO+NW (NLS00) 31.81 82.62 47.70 %O 0 95.40/2 = 47.70 63.61 00.00 95.40 %Y 1 C*ab = 95.40 31.81 -82.62 47.70 %L 2 0.866 C*ab = 0.866 * 95.40 = 82.62 63.61 -82.62 -47.70 %C 3 delta L*=25.8 31.81 00.00 -95.40 %V 4 43.81=00.01+31.80 63.61 82.62 -47.70 %M 5 69.61=00.01+2*31.80 00.01 0.00 0.00 %N 6 95.40/3 = 31.80 95.41 0.00 0.00 %W 7 95.40*(2/3) = 63.60 ] def %CVMOYLC+NW /LAB*05 [%Natural symmetric Luminous System OYLCVMO+NW (NLS18) 43.81 67.03 38.70 %O 0 77.40/2 = 38.70 69.61 00.00 77.40 %Y 1 C*ab = 77.40 43.81 -67.03 38.70 %L 2 0.866 C*ab = 67.03 69.61 -67.03 -38.70 %C 3 delta L*=25.8 43.81 00.00 -77.40 %V 4 43.81=18.01+25.80 69.61 67.03 -38.70 %M 5 69.61=18.01+2*25.80 18.01 0.00 0.00 %N 6 18.01+77.40/3 = 18.01+25.80=43.81 95.41 0.00 0.00 %W 7 18.01+77.40*(2/3) = 18.01+51.60=69.61 ] def %CVMOYLC+NW /LAB*06 [%Symmetric Reflective System OYLCVMO+NW (SRS18) 56.71 67.03 38.70 %O 0 18.01 + 77.40*0.5 = 18.01 + 38.70 = 56.71 56.71 00.00 77.40 %Y 1 C*ab = 77.40 56.71 -67.03 38.70 %L 2 0.866 C*ab = 67.03 56.71 -67.03 -38.70 %C 3 delta L*=25.8 56.71 00.00 -77.40 %V 4 43.81=18.01+25.80 56.71 67.03 -38.70 %M 5 69.61=18.01+2*25.80 18.01 0.00 0.00 %N 6 95.41 0.00 0.00 %W 7 95.41=18.01+3*25.80 ] def %CVMOYLC+NW /LAB*07 [%D=Device OYLCVMO+NW %for Television Luminous System (TLS70) 76.43 26.27 10.57 %O 0 93.93 -10.77 34.63 %Y 1 89.32 -35.81 27.64 %L 2 90.93 -21.96 -7.08 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 72.10 15.76 -35.64 %V 4 78.50 37.52 -25.24 %M 5 69.70 0.00 0.00 %N 6 Yr=40.32 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW } if %ISRL*ioG=0 ISRL*ioG 1 eq { %ISRL*ioG=1 /LAB*00 [%D=Device CVMOYLC+NW %for Television Luminous System (TLS00) 50.50 76.91 64.55 %O 0 92.66 -20.68 90.75 %Y 1 83.62 -82.74 79.90 %L 2 86.88 -46.15 -13.54 %C 3 %see TABle 1 of ISO/IEC 15775:1999-12 30.39 76.06 -103.6 %V 4 %see TABle X of ISO/IEC TR 24705:2005-10 57.31 94.35 -58.40 %M 5 %see Annex A, www.ps.bam.de/RLABE.PDF 00.01 0.00 0.00 %N 6 Yr=0.00 95.41 0.00 0.00 %W 7 ] def %CVMOYLC+NW /LAB*01 [%D=Device CVMOYLC+NW %for Television Luminous System (TLS06) 51.08 75.54 59.69 %O 0 92.68 -20.51 89.24 %Y 1 83.72 -81.79 78.32 %L 2 86.94 -45.72 -13.43 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 31.77 72.91 -101.3 %V 4 57.74 93.06 -57.71 %M 5 05.69 0.00 0.00 %N 6 Yr=0.63 95.41 0.00 0.00 %W 7 ] def %CVMOYLC+NW /LAB*02 [%D=Device CVMOYLC+NW %for Television Luminous System (TLS11) 51.65 74.20 55.83 %O 0 92.70 -20.35 87.77 %Y 1 83.81 -80.85 76.81 %L 2 87.01 -45.28 -13.33 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 33.06 70.03 -99.09 %V 4 58.17 91.80 -57.03 %M 5 10.99 0.00 0.00 %N 6 Yr=1.26 95.41 0.00 0.00 %W 7 ] def %CVMOYLC+NW /LAB*03 [%D=Device CVMOYLC+NW %for Television Luminous System (TLS18) 52.76 71.63 49.88 %O 0 92.74 -20.03 84.97 %Y 1 84.00 -78.99 73.94 %L 2 87.14 -44.42 -13.12 %C 3 %see TABle 1 of ISO/IEC 15775:1999-12 35.47 64.92 -95.07 %V 4 %see TABle X of ISO/IEC TR 24705:2005-10 59.01 89.33 -55.68 %M 5 %see Annex A, www.ps.bam.de/RLABE.PDF 18.01 0.00 0.00 %N 6 Yr=2.52 95.41 0.00 0.00 %W 7 ] def %CVMOYLC+NW /LAB*04 [%D=Device CVMOYLC+NW %for Television Luminous System (TLS27) 54.88 66.84 41.69 %O 0 92.82 -19.39 79.81 %Y 1 84.37 -75.39 68.76 %L 2 87.40 -42.72 -12.70 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 39.70 56.66 -88.02 %V 4 60.64 84.61 -53.08 %M 5 26.85 0.00 0.00 %N 6 Yr=5.04 95.41 0.00 0.00 %W 7 ] def %CVMOYLC+NW /LAB*05 [%D=Device CVMOYLC+NW %for Television Luminous System (TLS38) 58.77 58.45 31.73 %O 0 92.98 -18.11 70.81 %Y 1 85.11 -68.58 60.02 %L 2 87.92 -39.42 -11.87 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 46.64 44.93 -76.56 %V 4 63.71 75.92 -48.22 %M 5 37.99 0.00 0.00 %N 6 Yr=10.08 95.41 0.00 0.00 %W 7 ] def %CVMOYLC+NW /LAB*06 [%D=Device CVMOYLC+NW %for Television Luminous System (TLS52) 65.53 45.06 20.98 %O 0 93.30 -15.61 56.27 %Y 1 86.55 -56.31 46.52 %L 2 88.94 -33.19 -10.24 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 57.17 30.66 -59.40 %V 4 69.22 60.95 -39.57 %M 5 52.02 0.00 0.00 %N 6 Yr=20.16 95.41 0.00 0.00 %W 7 ] def %CVMOYLC+NW /LAB*07 [%D=Device CVMOYLC+NW %for Television Luminous System (TLS70) 76.43 26.27 10.57 %O 0 93.93 -10.77 34.63 %Y 1 89.32 -35.81 27.64 %L 2 90.93 -21.96 -7.08 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 72.10 15.76 -35.64 %V 4 78.50 37.52 -25.24 %M 5 69.70 0.00 0.00 %N 6 Yr=40.32 95.41 0.00 0.00 %W 7 ] def %CVMOYLC+NW } if %ISRL*ioG=1 ISRL*ioG 2 eq { %ISRL*ioG=2 /LAB*00 [%D=Device OYLCVMO+NW %for Offset Luminous System (OLS00) 45.14 71.37 75.54 %O 0 90.22 -10.60 99.51 %Y 1 48.45 -73.19 42.21 %L 2 56.88 -33.11 -47.41 %C 3 %see TABle 1 of ISO/IEC 15775:1999-12 16.48 45.84 -56.22 %V 4 %see TABle X of ISO/IEC TR 24705:2005-10 45.36 81.85 -9.29 %M 5 %see Annex A, www.ps.bam.de/RLABE.PDF 00.01 0.00 0.00 %N 6 Yr=0.00 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW /LAB*01 [%D=Device OYLCVMO+NW %for Offset Luminous System (OLS06) 45.87 69.79 66.99 %O 0 90.25 -10.51 97.42 %Y 1 49.08 -70.28 40.08 %L 2 57.33 -32.38 -46.80 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 19.26 40.73 -52.47 %V 4 46.07 80.12 -9.04 %M 5 05.69 0.00 0.00 %N 6 Yr=0.63 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW /LAB*02 [%D=Device OYLCVMO+NW %for Offset Luminous System (OLS11) 46.57 68.27 59.62 %O 0 90.29 -10.43 95.45 %Y 1 49.70 -67.60 38.19 %L 2 57.76 -31.68 -46.19 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 21.67 36.81 -49.37 %V 4 46.77 78.45 -8.80 %M 5 10.99 0.00 0.00 %N 6 Yr=1.26 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW /LAB*03 [%D=Device OYLCVMO+NW %for Offset Luminous System (OLS18) 47.94 65.39 50.52 %O 0 90.37 -10.26 91.75 %Y 1 50.90 -62.83 34.96 %L 2 58.62 -30.34 -45.01 %C 3 %see TABle 1 of ISO/IEC 15775:1999-12 25.72 31.10 -44.40 %V 4 %see TABle X of ISO/IEC TR 24705:2005-10 48.13 75.28 -8.36 %M 5 %see Annex A, www.ps.bam.de/RLABE.PDF 18.01 0.00 0.00 %N 6 Yr=2.52 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW /LAB*04 [%D=Device OYLCVMO+NW %for Offset Luminous System (OLS27) 50.51 60.17 40.13 %O 0 90.52 -9.92 85.20 %Y 1 53.18 -55.04 30.00 %L 2 60.28 -27.91 -42.75 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 32.06 24.02 -37.32 %V 4 50.68 69.50 -7.57 %M 5 26.85 0.00 0.00 %N 6 Yr=5.04 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW /LAB*05 [%D=Device OYLCVMO+NW %for Offset Luminous System (OLS38) 55.13 51.42 29.16 %O 0 90.83 -9.25 74.37 %Y 1 57.35 -43.84 23.35 %L 2 63.39 -23.83 -38.56 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 41.26 16.67 -28.49 %V 4 55.27 59.74 -6.32 %M 5 37.99 0.00 0.00 %N 6 Yr=10.08 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW /LAB*06 [%D=Device OYLCVMO+NW %for Offset Luminous System (OLS52) 62.90 38.38 18.55 %O 0 91.44 -7.95 57.91 %Y 1 64.49 -30.06 15.67 %L 2 68.98 -17.74 -31.24 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 53.87 10.09 -18.84 %V 4 63.00 44.96 -4.56 %M 5 52.02 0.00 0.00 %N 6 Yr=20.16 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW /LAB*07 [%D=Device OYLCVMO+NW %for Offset Luminous System (OLS70) 75.01 21.53 9.07 %O 0 92.64 -5.45 34.85 %Y 1 75.86 -15.50 7.96 %L 2 78.37 -9.90 -19.51 %C 3 %see Annex A, www.ps.bam.de/RLABE.PDF 70.54 4.74 -9.47 %V 4 75.07 25.47 -2.46 %M 5 69.70 0.00 0.00 %N 6 Yr=40.32 95.41 0.00 0.00 %W 7 ] def %OYLCVMO+NW } if %ISRL*ioG=2 0 1 11 {/sISO exch def /i30 sISO 3 mul def /i31 i30 1 add def /i32 i30 2 add def sISO 7 le { %sISO=0,7 ISIO*ioG 0 eq { %ORS18/TLS00/OLS00 LAB* i30 LAB*00 i30 get put LAB* i31 LAB*00 i31 get put LAB* i32 LAB*00 i32 get put } if ISIO*ioG 1 eq { %TLS00/TLS06/OLS06 LAB* i30 LAB*01 i30 get put LAB* i31 LAB*01 i31 get put LAB* i32 LAB*01 i32 get put } if ISIO*ioG 2 eq { %DRSXX/TLS11/OLS11 LAB* i30 LAB*02 i30 get put LAB* i31 LAB*02 i31 get put LAB* i32 LAB*02 i32 get put } if ISIO*ioG 3 eq { %TLS18/TLS18/OLS18 LAB* i30 LAB*03 i30 get put LAB* i31 LAB*03 i31 get put LAB* i32 LAB*03 i32 get put } if ISIO*ioG 4 eq { %NLS00/TSL28/OLS28 LAB* i30 LAB*04 i30 get put LAB* i31 LAB*04 i31 get put LAB* i32 LAB*04 i32 get put } if ISIO*ioG 5 eq { %NRS18/TLS38/OLS38 LAB* i30 LAB*05 i30 get put LAB* i31 LAB*05 i31 get put LAB* i32 LAB*05 i32 get put } if ISIO*ioG 6 eq { %SRS18/TLS50/OLS50 LAB* i30 LAB*06 i30 get put LAB* i31 LAB*06 i31 get put LAB* i32 LAB*06 i32 get put } if ISIO*ioG 7 eq { %TLS70/TLS70/OLS70 LAB* i30 LAB*07 i30 get put LAB* i31 LAB*07 i31 get put LAB* i32 LAB*07 i32 get put } if } %sISO=0,7 { %sISO=8,11 /jISO sISO 8 sub def /j30 jISO 3 mul def /j31 j30 1 add def /j32 j30 2 add def LAB* i30 RJGBLAB* j30 get put LAB* i31 RJGBLAB* j31 get put LAB* i32 RJGBLAB* j32 get put } ifelse %sISO=0,7 and 8,11 } for /L*Nio LAB* 18 get def /A*Nio LAB* 19 get def /B*Nio LAB* 20 get def /L*Wio LAB* 21 get def /A*Wio LAB* 22 get def /B*Wio LAB* 23 get def /A*Dio A*Wio A*Nio sub def /B*Dio B*Wio B*Nio sub def 0 1 11 {/sISO exch def /i30 sISO 3 mul def /i31 i30 1 add def /i32 i30 2 add def LAB*a i30 LAB* i30 get put /l*CIE LAB* i30 get L*Nio sub L*Wio L*Nio sub div def %system rel. lightn. /a*s A*Wio A*Nio sub l*CIE mul def /b*s B*Wio B*Nio sub l*CIE mul def LAB*a i31 LAB* i31 get A*Nio sub a*s sub put LAB*a i32 LAB* i32 get B*Nio sub b*s sub put } for /cLAB*s0 3 array def %C cyan blue /vLAB*s0 3 array def %V violet blue /mLAB*s0 3 array def %M magenta red /oLAB*s0 3 array def %O orange red /yLAB*s0 3 array def %Y yellow /lLAB*s0 3 array def %L leaf green /nLAB*s0 3 array def %N black /wLAB*s0 3 array def %W white /rLAB*s0 3 array def %R elementary red /jLAB*s0 3 array def %J elementary yellow /gLAB*s0 3 array def %G elementary green /bLAB*s0 3 array def %B elementary blue %Determine Matrix data input or output data oLAB*s0 0 LAB*a 0 get L*Nio sub put oLAB*s0 1 LAB*a 1 get put oLAB*s0 2 LAB*a 2 get put yLAB*s0 0 LAB*a 3 get L*Nio sub put yLAB*s0 1 LAB*a 4 get put yLAB*s0 2 LAB*a 5 get put lLAB*s0 0 LAB*a 6 get L*Nio sub put lLAB*s0 1 LAB*a 7 get put lLAB*s0 2 LAB*a 8 get put cLAB*s0 0 LAB*a 9 get L*Nio sub put cLAB*s0 1 LAB*a 10 get put cLAB*s0 2 LAB*a 11 get put vLAB*s0 0 LAB*a 12 get L*Nio sub put vLAB*s0 1 LAB*a 13 get put vLAB*s0 2 LAB*a 14 get put mLAB*s0 0 LAB*a 15 get L*Nio sub put mLAB*s0 1 LAB*a 16 get put mLAB*s0 2 LAB*a 17 get put nLAB*s0 0 LAB*a 18 get L*Nio sub put nLAB*s0 1 LAB*a 19 get put nLAB*s0 2 LAB*a 20 get put wLAB*s0 0 LAB*a 21 get L*Nio sub put wLAB*s0 1 LAB*a 22 get put wLAB*s0 2 LAB*a 23 get put rLAB*s0 0 LAB*a 24 get L*Nio sub put rLAB*s0 1 LAB*a 25 get put rLAB*s0 2 LAB*a 26 get put jLAB*s0 0 LAB*a 27 get L*Nio sub put jLAB*s0 1 LAB*a 28 get put jLAB*s0 2 LAB*a 29 get put gLAB*s0 0 LAB*a 30 get L*Nio sub put gLAB*s0 1 LAB*a 31 get put gLAB*s0 2 LAB*a 32 get put bLAB*s0 0 LAB*a 33 get L*Nio sub put bLAB*s0 1 LAB*a 34 get put bLAB*s0 2 LAB*a 35 get put % Determine the input or output angle in the A* B* plane % of each of the colours defined above /C*Ang cLAB*s0 2 get cLAB*s0 1 get 0.0001 add atan def /V*Ang vLAB*s0 2 get vLAB*s0 1 get 0.0001 add atan def /M*Ang mLAB*s0 2 get mLAB*s0 1 get 0.0001 add atan def /O*Ang oLAB*s0 2 get oLAB*s0 1 get 0.0001 add atan def /Y*Ang yLAB*s0 2 get yLAB*s0 1 get 0.0001 add atan def /L*Ang lLAB*s0 2 get mLAB*s0 1 get 0.0001 add atan def /N*Ang 0 def /W*Ang 0 def /R*Ang rLAB*s0 2 get rLAB*s0 1 get 0.0001 add atan def /J*Ang jLAB*s0 2 get jLAB*s0 1 get 0.0001 add atan def /G*Ang gLAB*s0 2 get gLAB*s0 1 get 0.0001 add atan def /B*Ang bLAB*s0 2 get bLAB*s0 1 get 0.0001 add atan def % The detprocL below finds the determinant of the Matrix: % | A1 B1 C1 D1 | % | A2 B2 C2 D2 | % | A3 B3 C3 D3 | % | A4 B4 C4 D4 | % /detprocL { %BEG procedure detprocL /term1 B2 C3 mul D4 mul C2 D3 mul B4 mul add D2 B3 mul C4 mul add B4 C3 mul D2 mul sub C4 D3 mul B2 mul sub D4 B3 mul C2 mul sub def /term2 A2 C3 mul D4 mul C2 D3 mul A4 mul add D2 A3 mul C4 mul add A4 C3 mul D2 mul sub C4 D3 mul A2 mul sub D4 A3 mul C2 mul sub def /term3 A2 B3 mul D4 mul B2 D3 mul A4 mul add D2 A3 mul B4 mul add A4 B3 mul D2 mul sub B4 D3 mul A2 mul sub D4 A3 mul B2 mul sub def /term4 A2 B3 mul C4 mul B2 C3 mul A4 mul add C2 A3 mul B4 mul add A4 B3 mul C2 mul sub B4 C3 mul A2 mul sub C4 A3 mul B2 mul sub def /det A1 term1 mul B1 term2 mul sub C1 term3 mul add D1 term4 mul sub def } bind def %END procedure detprocL % The CoeffprocL procedure solves for WhiteCoeff, black Coeff, Col1Coeff and % Col2Coeff in the matrix equation below. It takes as inputs A1->A4 B1->B4 % C1->C4 D1->D4 and s,y,z,t. It solves for these using Cramer's rule. % Note: Cramer's rule is valid only for non-singular matrices, ie |A| not % equal to 0. % % | A1 B1 C1 D1 | |WhiteCoeff| |x| % | A2 B2 C2 D2 | |BlackCoeff| = |y| % | A3 B3 C3 D3 | |Col1Coeff | |z| % | A4 B4 C4 D4 | |Col2Coeff | |t| % A B = C % /CoeffprocL { %BEG procedure CoeffprocL /t exch def /z exch def /y exch def /x exch def /D4 exch def /D3 exch def /D2 exch def /D1 exch def /C4 exch def /C3 exch def /C2 exch def /C1 exch def /B4 exch def /B3 exch def /B2 exch def /B1 exch def /A4 exch def /A3 exch def /A2 exch def /A1 exch def detprocL /den det def % determine white coefficient /temp1 A1 def /temp2 A2 def /temp3 A3 def /temp4 A4 def /A1 x def /A2 y def /A3 z def /A4 t def detprocL /numW det def /A1 temp1 def /A2 temp2 def /A3 temp3 def /A4 temp4 def % determine black coefficient /temp1 B1 def /temp2 B2 def /temp3 B3 def /temp4 B4 def /B1 x def /B2 y def /B3 z def /B4 t def detprocL /numB det def /B1 temp1 def /B2 temp2 def /B3 temp3 def /B4 temp4 def % determine colour1 coefficient /temp1 C1 def /temp2 C2 def /temp3 C3 def /temp4 C4 def /C1 x def /C2 y def /C3 z def /C4 t def detprocL /numCol1 det def /C1 temp1 def /C2 temp2 def /C3 temp3 def /C4 temp4 def % determine colour2 coefficient /temp1 D1 def /temp2 D2 def /temp3 D3 def /temp4 D4 def /D1 x def /D2 y def /D3 z def /D4 t def detprocL /numCol2 det def /D1 temp1 def /D2 temp2 def /D3 temp3 def /D4 temp4 def /WhiteCoeff numW den div def /BlackCoeff numB den div def /Col1Coeff numCol1 den div def /Col2Coeff numCol2 den div def WhiteCoeff BlackCoeff Col1Coeff Col2Coeff % returns these *color data } bind def %BEG procedure CoeffprocL } def %END Procedure LAB*ioG %*********************************************************** /cmyolv*io_to_LAB*ioG { %BEG Procedure transfer cmyolv*io_to_LAB*ioG %input olv* for IMODE=0 and cmy* for IMODE=1 %the following calculations based on olv* %Procedure LAB*inoutL is required in advance IMODE 1 eq {%IMODE=1, input cmy* /o* 1 c* sub def /l* 1 m* sub def /v* 1 y* sub def } if %skip of olv* data <0 and >1 o* 0 le {/o* 0.0001 def} if l* 0 le {/l* 0.0001 def} if v* 0 le {/v* 0.0001 def} if o* 1 ge {/o* 0.9999 def} if l* 1 ge {/l* 0.9999 def} if v* 1 ge {/v* 0.9999 def} if %output olv* and cmy* for both olv* and cmy* input %n*n: relative blackness %r*n: relative chromaticness %w*n: relative whiteness %L*F: CIE lightness L* %A*F: CIE chromaticness a* %B*F: CIE chromaticness b* %C*F: CIE radial chroma Cab* %x*F: x-position of colour F %y*F: y-position of colour F %e*w: eigencolour value of F o* 0 le {/o* 0.0001 def} if l* 0 le {/l* 0.0001 def} if v* 0 le {/v* 0.0001 def} if o* 1 ge {/o* 0.9999 def} if l* 1 ge {/l* 0.9999 def} if v* 1 ge {/v* 0.9999 def} if /tdel 0 def v* l* ge l* o* ge and tdel 0 eq and % v* >= l* >= o* equal y* <= m* <= c* %sector C-V of C-M, C>=M: i*p=0 {/w*n o* def /n*n 1 v* sub def /t*a v* l* sub def /array1 vLAB*s0 def % colour 1 is violet blue /t*b l* o* sub def /array2 cLAB*s0 def % colour 2 is cyan blue /i*p 0 def o* l* sub abs 0.001 le {/i*p 1 def} if /t*p l* l* v* add 0.0001 add div def /tdel 1 def } if % v* >= l* >= o* v* o* ge o* l* ge and tdel 0 eq and % v* >= o* >= l* equal y* <= c* <= m* %sector V-M of C-M, M>=C: i*p=1 {/w*n l* def /n*n 1 v* sub def /t*a v* o* sub def /array1 vLAB*s0 def % colour 1 is violet blue /t*b o* l* sub def /array2 mLAB*s0 def % colour 2 is magenta red /i*p 1 def v* o* sub abs 0.001 le {/i*p 2 def} if /t*p o* o* v* add 0.0001 add div def /tdel 1 def } if % v* >= o* >= l* o* v* ge v* l* ge and tdel 0 eq and % o* >= v* >= l* equal c* <= y* <= m* %sector M-O of M-Y, M>=Y: i*p=2 {/w*n l* def /n*n 1 o* sub def /t*a o* v* sub def /array1 oLAB*s0 def % colour 1 is orange /t*b v* l* sub def /array2 mLAB*s0 def % colour 2 is magenta red /i*p 2 def l* v* sub abs 0.001 le {/i*p 3 def} if /t*p v* v* o* add 0.0001 add div def /tdel 1 def } if % o* >= v* >= l* o* l* ge l* v* ge and tdel 0 eq and % o* >= l* >= v* equal c* <= m* <= y* %sector O-Y of M-Y, Y>=M: i*p=3 {/w*n v* def /n*n 1 o* sub def /t*a o* l* sub def /array1 oLAB*s0 def % colour 1 is orange red /t*b l* v* sub def /array2 yLAB*s0 def % colour 2 is yellow /i*p 3 def o* l* sub abs 0.001 le {/i*p 4 def} if /t*p l* l* o* add 0.0001 add div def /tdel 1 def } if % o* >= l* >= v* l* o* ge o* v* ge and tdel 0 eq and % l* >= o* >= v* equal m* <= c* <= y* %sector Y-L of Y-C, Y>=C: i*p=4 {/w*n v* def /n*n 1 l* sub def /t*a l* o* sub def /array1 lLAB*s0 def % colour 1 is leaf green /t*b o* v* sub def /array2 yLAB*s0 def % colour 2 is yellow /i*p 4 def o* v* sub abs 0.001 le {/i*p 5 def} if /t*p o* o* l* add 0.0001 add div def /tdel 1 def } if % l* >= o* >= v* l* v* ge v* o* ge and tdel 0 eq and % l* >= v* >= o* equal m* <= y* <= c* %sector L-C of Y-C, C>=Y: i*p=5 {/w*n o* def /n*n 1 l* sub def /t*a l* v* sub def /array1 lLAB*s0 def % colour 1 is leaf green /t*b v* o* sub def /array2 cLAB*s0 def % colour 2 is cyan blue /i*p 5 def l* v* sub abs 0.001 le {/i*p 0 def} if /t*p v* v* l* add 0.0001 add div def /tdel 1 def } if % l* >= v* >= o* %achromatic %W: o*, l*, v* = 1.00 1.0 o* sub abs 0.001 le 1.0 l* sub abs 0.001 le and 1.0 v* sub abs 0.001 le and %W special case {/i*p 6 def %W /e*w 0 def /n*n 0 def /w*n 1 def /t*a 0.0001 def /t*b 0.0001 def /t*p 0.0001 def } if %N: o*, l*, v* <= 0.001 o* abs 0.001 le l* abs 0.001 le and v* abs 0.001 le and %N special case {/i*p 6 def %N /e*w 0 def /n*n 1 def /w*n 0 def /t*a 0.0001 def /t*b 0.0001 def /t*p 0.0001 def } if %Achromatic o* l* sub abs 0.001 le l* v* sub abs 0.001 le and %Achromatic special case {/i*p 6 def %N /e*w 0 def /n*n 1 o* sub def /w*n o* def /t*a 0.0001 def /t*b 0.0001 def /t*p 0.0001 def } if /r*n 1 w*n sub n*n sub def /t*n 1 t*p sub def %w0-line of equal relative whiteness in colour triangle: y = 0.5 / h x + yw0 %n0-line of equal relative blackness in colour triangle: y = -0.5 / h x + yn0 %x*F = (yn0 - yw0) h %y*F = 0.5 (yn0 - yw0) + yw0 = 0.5 (yn0 + yw0) /h 0.75 sqrt def /yn0 1 n*n sub def /yw0 w*n def /x*F yn0 yw0 sub h mul def /y*F yn0 yw0 add 0.5 mul def /t*F y*F def /lab*tFa t*F def /lab*cFa r*n def /lab*wFa w*n def /lab*nFa n*n def %x*F / (1-y*F) = e*x / 1 %e*w = e*x /(2h) = [x*F / (1-y*F)]/(2h) %/e*w x*F 1 y*F sub div 2 h mul div def /e*w r*n n*n r*n add 0.0001 add div def %Eigencolor ratio r*n abs 0.001 le r*n abs 0.001 le and {/e*w 0.0001 def} if % with 0 for achromatic (c*n=0) and 1 for whitish colors (n*n=0) %cmyolv*_to_cmy* /c* 1 o* sub def /m* 1 l* sub def /y* 1 v* sub def %cmyolv*_to_LAB*LFs0 %L*Fs0 = w*n wLAB*s0 (0) + n*n nLAB*s0 (0) + t*a array1(0) + t*b array2(0) %A*Fs0 = w*n wLAB*s0 (1) + n*n nLAB*s0 (1) + t*a array1(1) + t*b array2(1) %B*Fs0 = w*n wLAB*s0 (2) + n*n nLAB*s0 (2) + t*a array1(2) + t*b array2(2) /L*Fs0 w*n wLAB*s0 0 get mul n*n nLAB*s0 0 get mul add t*a array1 0 get mul add t*b array2 0 get mul add def /A*Fs0 w*n wLAB*s0 1 get mul n*n nLAB*s0 1 get mul add t*a array1 1 get mul add t*b array2 1 get mul add def /B*Fs0 w*n wLAB*s0 2 get mul n*n nLAB*s0 2 get mul add t*a array1 2 get mul add t*b array2 2 get mul add def /L*Fsm t*a array1 0 get mul t*b array2 0 get mul add L*Nio add def %LAB*Fs0_to_LAB*F /L*F L*Fs0 L*Nio add def /l*CIE L*F L*Nio sub L*Wio L*Nio sub 0.0001 add div def /A*F A*Fs0 A*Nio add A*Dio l*CIE mul add def /B*F B*Fs0 B*Nio add B*Dio l*CIE mul add def /lab*lFa l*CIE def /LAB*LF L*F def /LAB*AF A*F def /LAB*BF B*F def /LAB*LFa L*F def /LAB*AFa A*Fs0 def /LAB*BFa B*Fs0 def %FOR CIELAB LCH /C*Fs0 A*Fs0 dup mul B*Fs0 dup mul add 0.000001 add sqrt def /H*Fs0 B*Fs0 A*Fs0 0.0001 add atan def /LAB*CFa C*Fs0 def /LAB*HFa H*Fs0 def /lab*hFa LAB*HFa 360 div def } bind def %END Procedure transfer cmyolv*io_to_LAB*ioG (L=local) /LAB*io_to_cmyolv*ioG {%BEG Procedure LAB*io_to_cmyolv*ioG (L=local) /B*F exch def /A*F exch def /L*F exch def %ISIO*ioG 0 eq ISOUP*ioG 3 eq and % {%achromatic transfer L*F,A*F,B*F (PR18) % % -> L*Fsa, A*Fsa, B*Fsa (PR18) % % -> L*F, A*F, B*F (TV18) % %LAB*F_to_LAB*Fsa % /l*CIE L*F L*Nio sub L*Wio L*Nio sub 0.0001 add div def % /A*Fs0 A*F A*Nio sub A*Dio l*CIE mul sub def % /B*Fs0 B*F B*Nio sub B*Dio l*CIE mul sub def % /A*F A*Fs0 def % /B*F B*Fs0 def % } if %achromatic transfer L*F,A*F,B*F (PR18) /l*CIE L*F L*Nio sub L*Wio L*Nio sub 0.0001 add div def /L*Fs0 L*F L*Nio sub def /A*Fs0 A*F A*Nio sub A*Dio l*CIE mul sub def /B*Fs0 B*F B*Nio sub B*Dio l*CIE mul sub def /C*Fs0 A*Fs0 dup mul B*Fs0 dup mul add 0.000001 add sqrt def /H*Fs0 B*Fs0 A*Fs0 0.0001 add atan def /LAB*LF L*F def /LAB*AF A*F def /LAB*BF B*F def /LAB*LFa L*F def /LAB*AFa A*Fs0 def /LAB*BFa B*Fs0 def % the angle formed by the input LAB* *color data in the A*B* plane /col_ang B*Fs0 A*Fs0 0.0001 add atan def %determine which two colours the LAB* *color data corresponds to %by testing the angles and solve the related four simultaneous equations %to find the olv *color data. % angle between magenta red and orange red, sector M-O of M-Y, M>=Y col_ang M*Ang ge col_ang O*Ang lt or {1 wLAB*s0 0 get wLAB*s0 1 get wLAB*s0 2 get 1 nLAB*s0 0 get nLAB*s0 1 get nLAB*s0 2 get 1 mLAB*s0 0 get mLAB*s0 1 get mLAB*s0 2 get 1 oLAB*s0 0 get oLAB*s0 1 get oLAB*s0 2 get 1 L*Fs0 A*Fs0 B*Fs0 CoeffprocL /c1*w exch def %O /c2*w exch def %M /n*w exch def /w*w exch def %magenta is a mixture of orange red and voilet blue, therefore leaf green(l) = white, %orange(o) = 1-black(n), voilet blue(v) = white + magenta red (c2*w) /v*n w*w c2*w add def % /l*n w*w def /o*n 1 n*w sub def /i*p 2 def /t*p v*n v*n o*n add 0.0001 add div def } if % angle between orange red and yellow, sector O-Y of M-Y, Y>=M col_ang O*Ang ge col_ang Y*Ang lt and {1 wLAB*s0 0 get wLAB*s0 1 get wLAB*s0 2 get 1 nLAB*s0 0 get nLAB*s0 1 get nLAB*s0 2 get 1 oLAB*s0 0 get oLAB*s0 1 get oLAB*s0 2 get 1 yLAB*s0 0 get yLAB*s0 1 get yLAB*s0 2 get 1 L*Fs0 A*Fs0 B*Fs0 CoeffprocL /c1*w exch def %Y /c2*w exch def %O /n*w exch def /w*w exch def %yellow is a mixture of orange red and leaf green, therefore voilet blue(v) = white, %orange(o) = 1-black(n), leaf green(l) = white + yellow (c1*w) /l*n w*w c1*w add def /v*n w*w def /o*n 1 n*w sub def /i*p 3 def /t*p l*n l*n o*n add 0.0001 add div def } if % angle between yellow and leaf green, sector Y-L of Y-C, Y>=C col_ang Y*Ang ge col_ang L*Ang lt and {1 wLAB*s0 0 get wLAB*s0 1 get wLAB*s0 2 get 1 nLAB*s0 0 get nLAB*s0 1 get nLAB*s0 2 get 1 yLAB*s0 0 get yLAB*s0 1 get yLAB*s0 2 get 1 lLAB*s0 0 get lLAB*s0 1 get lLAB*s0 2 get 1 L*Fs0 A*Fs0 B*Fs0 CoeffprocL /c1*w exch def %L /c2*w exch def %Y /n*w exch def /w*w exch def %yellow is a mixture of orange red and leaf green, therefore voilet blue(v) = white , %leaf green(l) = 1-black(n), orange red(o) = white + yellow (c2*w) /v*n w*w def /l*n 1 n*w sub def /o*n w*w c2*w add def /i*p 4 def /t*p o*n o*n l*n add 0.0001 add div def } if % angle between leaf green and cyan blue, sector L-C of Y-C, C>=Y col_ang L*Ang ge col_ang C*Ang lt and {1 wLAB*s0 0 get wLAB*s0 1 get wLAB*s0 2 get 1 nLAB*s0 0 get nLAB*s0 1 get nLAB*s0 2 get 1 lLAB*s0 0 get lLAB*s0 1 get lLAB*s0 2 get 1 cLAB*s0 0 get cLAB*s0 1 get cLAB*s0 2 get 1 L*Fs0 A*Fs0 B*Fs0 CoeffprocL /c1*w exch def %C /c2*w exch def %L /n*w exch def /w*w exch def %cyan is a mixture of leaf green and voilet blue, therefore orange red(o) = white, %leaf green(l) = 1-black(n), voilet blue(v) = white + cyan blue (c1*w) /v*n w*w c1*w add def /l*n 1 n*w sub def /o*n w*w def /i*p 5 def /t*p v*n v*n l*n add 0.0001 add div def } if % angle between cyan blue and voilet blue, sector C-V of C-M, C>=M col_ang C*Ang ge col_ang V*Ang lt and {1 wLAB*s0 0 get wLAB*s0 1 get wLAB*s0 2 get 1 nLAB*s0 0 get nLAB*s0 1 get nLAB*s0 2 get 1 cLAB*s0 0 get cLAB*s0 1 get cLAB*s0 2 get 1 vLAB*s0 0 get vLAB*s0 1 get vLAB*s0 2 get 1 L*Fs0 A*Fs0 B*Fs0 CoeffprocL /c1*w exch def %V /c2*w exch def %C /n*w exch def /w*w exch def %cyan is a mixture of leaf green and voilet blue, therefore orange red(o) = white, %violet blue(v) = 1-black(n), leaf green(l) = white + cyan blue (c2*w) /v*n 1 n*w sub def /l*n w*w c2*w add def /o*n w*w def /i*p 0 def /t*p l*n l*n v*n add 0.0001 add div def } if % angle between voilet blue and magenta red, sector V-M of C-M, M>=C col_ang V*Ang ge col_ang M*Ang lt and {1 wLAB*s0 0 get wLAB*s0 1 get wLAB*s0 2 get 1 nLAB*s0 0 get nLAB*s0 1 get nLAB*s0 2 get 1 vLAB*s0 0 get vLAB*s0 1 get vLAB*s0 2 get 1 mLAB*s0 0 get mLAB*s0 1 get mLAB*s0 2 get 1 L*Fs0 A*Fs0 B*Fs0 CoeffprocL /c1*w exch def %M /c2*w exch def %V /n*w exch def /w*w exch def %magenta is a mixture of orange red and voilet blue, therefore leaf green(l) = white, %violet(o) = 1-black(n), orange red(o) = white + magenta red (c1*w) /v*n 1 n*w sub def /l*n w*w def /o*n w*w c1*w add def /i*p 1 def /t*p o*n o*n v*n add 0.0001 add div def } if %achromatic %W: o*n, l*n, v*n = 1.00 1.0 o*n sub abs 0.001 le 1.0 l*n sub abs 0.001 le and 1.0 v*n sub abs 0.001 le and %W special case {/i*p 6 def %W /e*w 0 def /n*n 0 def /w*n 1 def /t*p 0.0001 def } if %N: o*n, l*n, v*n <= 0.01 o*n abs 0.001 le l*n abs 0.001 le and v*n abs 0.001 le and %N special case {/i*p 6 def %N /e*w 0 def /n*n 1 def /w*n 0 def /t*p 0.0001 def } if %Achromatic o*n l*n sub abs 0.001 le l*n v*n sub abs 0.001 le and %Achromatic special case {/i*p 6 def %N /e*w 0 def /n*n o*n def /w*n 1 o*n sub def /t*p 0.0001 def } if /c*w 1 o*n sub def /m*w 1 l*n sub def /y*w 1 v*n sub def /t*n 1 t*p sub def /r*w 1 n*w sub w*w sub def %Ostwald equation for radial chromaticness: %with r*w=radial chromaticness, n*w=blackness, w*w=whiteness /t*w 1 n*w sub r*w 0.5 mul add def %triangle lightness /e*w r*w n*w r*w add 0.0001 add div def %Eigencolor ratio r*w abs 0.001 le r*w abs 0.001 le and {/e*w 0.0001 def} if % with 0 for achromatic (c*w=0) and 1 for whitish colors (n*w=0) /lab*rFa r*w def %/lab*tFa t*w def /h1* (-) def /h2* (-) def /H 0 def /H1* (-) def /H2* (-) def /H 0 def /IEND 0 def col_ang R*Ang gt col_ang J*Ang le and {/H* col_ang R*Ang sub J*Ang R*Ang sub div def /p*F 0.00 H* 0.25 mul add def /h1* (r) def /h2* (j) def /H1* (R) def /H2* (J) def /HM* R*Ang def /HP* J*Ang def /IEND 1 def} if col_ang J*Ang gt col_ang G*Ang le and {/H* col_ang J*Ang sub G*Ang J*Ang sub div def /p*F 0.25 H* 0.25 mul add def /h1* (j) def /h2* (g) def /H1* (J) def /H2* (G) def /HM* J*Ang def /HP* G*Ang def /IEND 1 def} if col_ang G*Ang gt col_ang B*Ang le and {/H* col_ang G*Ang sub B*Ang G*Ang sub div def /p*F 0.50 H* 0.25 mul add def /h1* (g) def /h2* (b) def /H1* (G) def /H2* (B) def /HM* G*Ang def /HP* B*Ang def /IEND 1 def} if col_ang R*Ang le IEND 0 eq and {/Pcol_ang col_ang 360 add def} {/Pcol_ang col_ang def} ifelse Pcol_ang B*Ang gt Pcol_ang R*Ang 360 add le and {/H* Pcol_ang B*Ang sub R*Ang 360 add B*Ang sub div def /p*F 0.75 H* 0.25 mul add def /h1* (b) def /h2* (r) def /H1* (B) def /H2* (R) def /HM* B*Ang def /HP* R*Ang 360 add def} if /lab*e1Fa h1* def /lab*EFa H* def /lab*e2Fa h2* def /lab*eFa p*F def /CIEF 100 88.60 div def /X* {L*F 16 add 116 div A*Fs0 500 div add } bind def /Y* {L*F 16 add 116 div } bind def /Z* {L*F 16 add 116 div B*Fs0 200 div sub} bind def /DecodeXYZ* { dup 6 29 div ge { dup dup mul mul } { 4 29 div sub 108 841 div mul } ifelse } bind def /XCIE {X* DecodeXYZ* 0.9505 mul} bind def /YCIE {Y* DecodeXYZ* } bind def /ZCIE {Z* DecodeXYZ* 1.0890 mul} bind def /XCIE1 {X* DecodeXYZ* 0.9505 mul CIEF mul} bind def /YCIE1 {Y* DecodeXYZ* CIEF mul} bind def /ZCIE1 {Z* DecodeXYZ* 1.0890 mul CIEF mul} bind def %Transformation X Y Z to RsRGB, GsRGB, BsRGB /RsRGB XCIE1 3.2406 mul YCIE1 -1.5372 mul add ZCIE1 -0.4986 mul add def /GsRGB XCIE1 -0.9686 mul YCIE1 1.8758 mul add ZCIE1 0.0415 mul add def /BsRGB XCIE1 0.0557 mul YCIE1 -0.2040 mul add ZCIE1 1.0570 mul add def /Slope 1.0 2.4 div def RsRGB 0.00313008 le {/R'sRGB RsRGB 12.92 mul def} {/R'sRGB RsRGB Slope exp 1.055 mul 0.055 sub def} ifelse GsRGB 0.00313008 le {/G'sRGB GsRGB 12.92 mul def} {/G'sRGB GsRGB Slope exp 1.055 mul 0.055 sub def} ifelse BsRGB 0.00313008 le {/B'sRGB BsRGB 12.92 mul def} {/B'sRGB BsRGB Slope exp 1.055 mul 0.055 sub def} ifelse c*w m*w y*w 0 %default output data definition } bind def %END Procedure LAB*io_to_cmyolv*ioG (L=local) /ouTab*ioG {%BEG Procedure ouTab*ioG (L=local) /Fontsize 152 Tabfakt mul def /TN {Fontsize /Times-ISOL1 FS} def /TI {Fontsize /TimesI-ISOL1 FS} def /TB {Fontsize /TimesB-ISOL1 FS} def /TBI {Fontsize /TimesBI-ISOL1 FS} def 0 0 0 setrgbcolor /o* r def /l* g def /v* b def %olv*, cmy* /yTABm ya ys 0.81 mul add def /yTABd 132 Tabfakt mul def /yTABx yTABm yTABd 1 mul sub def /yTAB0 yTABm yTABd 2 mul sub def /yTAB1 yTABm yTABd 3 mul sub def /yTAB2 yTABm yTABd 4 mul sub def /yTAB3 yTABm yTABd 5.1 mul sub def /yTAB4 yTABm yTABd 6.1 mul sub def /yTABn yTABm yTABd 7.1 mul sub def /yTAB5 yTABm yTABd 8.1 mul sub def /yTAB6 yTABm yTABd 9.2 mul sub def /yTAB7 yTABm yTABd 10.2 mul sub def /yTAB8 yTABm yTABd 11.2 mul sub def /yTAB9 yTABm yTABd 12.2 mul sub def /yTAB10 yTABm yTABd 13.3 mul sub def /yTAB11 yTABm yTABd 14.3 mul sub def /yTAB12 yTABm yTABd 15.2 mul sub def /yTAB13 yTABm yTABd 16.1 mul sub def /xTABm xa xs 0.84 mul sub def /xTABd 500 Tabfakt mul def /xTAB10 xTABm xTABd 1.15 mul add def /xTAB20 xTABm xTABd 2.00 mul add def /xTAB30 xTABm xTABd 2.85 mul add def /xTAB40 xTABm xTABd 3.70 mul add def /xTAB1 xTABm xTABd 1.60 mul add def /xTAB2 xTABm xTABd 2.55 mul add def /xTAB3 xTABm xTABd 3.50 mul add def /o3*Fa o* def /l3*Fa l* def /v3*Fa v* def xTABm yTABm moveto TBI (relative ) show TB (Inform. Technology (IT)) show xTABm yTABx moveto TI (olvi3*) show TN xTAB10 yTABx moveto o3*Fa cvsshow3 xTAB20 yTABx moveto l3*Fa cvsshow3 xTAB30 yTABx moveto v3*Fa cvsshow3 xTAB40 yTABx moveto ((1.0)) show /c3*Fa 1 o3*Fa sub def /m3*Fa 1 l3*Fa sub def /y3*Fa 1 v3*Fa sub def xTABm yTAB0 moveto TI (cmyn3*) show TN xTAB10 yTAB0 moveto c3*Fa cvsshow3 xTAB20 yTAB0 moveto m3*Fa cvsshow3 xTAB30 yTAB0 moveto y3*Fa cvsshow3 xTAB40 yTAB0 moveto ((0.0)) show LAB*ioG /c* c3*Fa def /m* m3*Fa def /y* y3*Fa def /n* 0.0 def /o* 1 c* sub def /l* 1 m* sub def /v* 1 y* sub def cmyolv*io_to_LAB*ioG xTABm yTAB3 moveto TBI (standard ) show TB (and ) show TBI (adapted ) show TB (CIELAB) show xTABm yTAB4 moveto TI (LAB*LAB) show TN xTAB1 yTAB4 moveto LAB*LF cvsshow2 xTAB2 yTAB4 moveto LAB*AF cvsshow2 xTAB3 yTAB4 moveto LAB*BF cvsshow2 xTABm yTABn moveto TI (LAB*LABa) show TN xTAB1 yTABn moveto LAB*LFa cvsshow2 xTAB2 yTABn moveto LAB*AFa cvsshow2 xTAB3 yTABn moveto LAB*BFa cvsshow2 xTABm yTAB5 moveto TI (LAB*TCHa) show TN xTAB1 yTAB5 moveto lab*tFa 100 mul cvsshow2 xTAB2 yTAB5 moveto LAB*CFa cvsshow2 xTAB3 yTAB5 moveto LAB*CFa 1.0 ge {LAB*HFa cvsshow2} {( -) show} ifelse L*F A*F B*F LAB*io_to_cmyolv*ioG %lab relative CIELAB /c4*Fa c3*Fa lab*nFa sub def %at least one of cmy will be cero /m4*Fa m3*Fa lab*nFa sub def /y4*Fa y3*Fa lab*nFa sub def /n4*Fa lab*nFa def /o4*Fa 1 c4*Fa sub def /l4*Fa 1 m4*Fa sub def /v4*Fa 1 y4*Fa sub def /i4*Fa 1 n4*Fa sub def xTABm yTAB1 moveto TI (olvi4*) show TN xTAB10 yTAB1 moveto o4*Fa cvsshow3 xTAB20 yTAB1 moveto l4*Fa cvsshow3 xTAB30 yTAB1 moveto v4*Fa cvsshow3 xTAB40 yTAB1 moveto i4*Fa cvsshow3 xTABm yTAB2 moveto TI (cmyn4*) show TN xTAB10 yTAB2 moveto c4*Fa cvsshow3 xTAB20 yTAB2 moveto m4*Fa cvsshow3 xTAB30 yTAB2 moveto y4*Fa cvsshow3 xTAB40 yTAB2 moveto n4*Fa cvsshow3 xTABm yTAB6 moveto TBI (relative ) show TB (CIELAB ) show TBI (lab*) show xTABm yTAB7 moveto TI (lab*lab) show TN xTAB1 yTAB7 moveto lab*lFa cvsshow3 /lab*aFa lab*cFa LAB*HFa cos mul def /lab*bFa lab*cFa LAB*HFa sin mul def xTAB2 yTAB7 moveto lab*aFa cvsshow3 xTAB3 yTAB7 moveto lab*bFa cvsshow3 xTABm yTAB8 moveto TI (lab*tch) show TN xTAB1 yTAB8 moveto lab*tFa cvsshow3 xTAB2 yTAB8 moveto lab*cFa cvsshow3 xTAB3 yTAB8 moveto lab*cFa 0.01 ge {lab*hFa cvsshow3} {( -) show} ifelse xTABm yTAB9 moveto TI (lab*nch) show TN xTAB1 yTAB9 moveto lab*nFa cvsshow3 xTAB2 yTAB9 moveto lab*cFa cvsshow3 xTAB3 yTAB9 moveto lab*cFa 0.01 ge {lab*hFa cvsshow3} {( -) show} ifelse %lab*lrj,tce,ncE: similar to NCS xTABm yTAB10 moveto TBI (relative ) show TB (Natural Colour (NC)) show xTABm yTAB11 moveto TI (lab*lrj) show TN xTAB1 yTAB11 moveto lab*lFa cvsshow3 /lab*rFa lab*cFa lab*eFa 360 mul cos mul def /lab*jFa lab*cFa lab*eFa 360 mul sin mul def xTAB2 yTAB11 moveto lab*rFa cvsshow3 xTAB3 yTAB11 moveto lab*jFa cvsshow3 xTABm yTAB12 moveto TI (lab*tce) show TN xTAB1 yTAB12 moveto lab*tFa cvsshow3 xTAB2 yTAB12 moveto lab*cFa cvsshow3 xTAB3 yTAB12 moveto lab*cFa 0.01 ge {lab*eFa cvsshow3}{( -) show} ifelse xTABm yTAB13 moveto TI (lab*ncE) show TN xTAB1 yTAB13 moveto lab*nFa cvsshow3 xTAB2 yTAB13 moveto lab*cFa cvsshow3 xTAB3 yTAB13 moveto lab*cFa 0.01 ge {lab*e1Fa show lab*EFa 100 mul truncate cvi dup 10 lt {(0) show } if 6 string cvs show lab*e2Fa show} {( -) show} ifelse } bind def %END Procedure ouTab*ioG /ouCal*ioG {%BEG Procedure ouCal*ioG 0 0 0 setrgbcolor /o* r def /l* g def /v* b def /o3*Fa o* def /l3*Fa l* def /v3*Fa v* def /c3*Fa 1 o3*Fa sub def /m3*Fa 1 l3*Fa sub def /y3*Fa 1 v3*Fa sub def LAB*ioG /c* c3*Fa def /m* m3*Fa def /y* y3*Fa def /n* 0.0 def /o* 1 c* sub def /l* 1 m* sub def /v* 1 y* sub def cmyolv*io_to_LAB*ioG L*F A*F B*F LAB*io_to_cmyolv*ioG %lab relative CIELAB /c4*Fa c3*Fa lab*nFa sub def %at least one of cmy will be cero /m4*Fa m3*Fa lab*nFa sub def /y4*Fa y3*Fa lab*nFa sub def /n4*Fa lab*nFa def /o4*Fa 1 c4*Fa sub def /l4*Fa 1 m4*Fa sub def /v4*Fa 1 y4*Fa sub def /i4*Fa 1 n4*Fa sub def } bind def %END Procedure ouCal*ioG /proc_LAB*Fa_LAB*MaNTABl_olvi3*cmyn3*Ma*ioG { %BEG proc_LAB*Fa_LAB*MaNTABl_olvi3*cmyn3*Ma*ioG %only for calculation without hue tables %input LAB*Fa %input LAB*a (6 adapted colours OYLCVM) %input nLAB*s0 (colour white N for calculation of lab*l) %input wLAB*s0 (colour white W for achromatic axis) %output LAB*Ma %output olvi3*Ma %output cmyn3*Ma /UXF1a wLAB*s0 1 get B*Fa mul wLAB*s0 2 get A*Fa mul sub def /UXF2a wLAB*s0 2 get L*Fa mul wLAB*s0 0 get B*Fa mul sub def /UXF3a wLAB*s0 0 get A*Fa mul wLAB*s0 1 get L*Fa mul sub def /T1 0 def /T2 0 def 0 1 5 {/ia exch def /ia30 ia 3 mul def ia 5 eq {/ia31 0 def} {/ia31 ia30 3 add def} ifelse /T1 LAB*a ia30 get UXF1a mul LAB*a ia30 1 add get UXF2a mul add LAB*a ia30 2 add get UXF3a mul add def /T2 LAB*a ia31 get UXF1a mul LAB*a ia31 1 add get UXF2a mul add LAB*a ia31 2 add get UXF3a mul add def T1 0 le {/T1X (N) def} {/T1X (P) def} ifelse T2 0 gt {/T2X (P) def} {/T2X (N) def} ifelse T1 0 le T2 0 gt and {/ia3END ia30 def exit} if } for /L*11a LAB*a ia3END get def /A*11a LAB*a ia3END 1 add get def /B*11a LAB*a ia3END 2 add get def ia3END 15 ge {/ia3END -3 def} if /L*21a LAB*a ia3END 3 add get def /A*21a LAB*a ia3END 4 add get def /B*21a LAB*a ia3END 5 add get def /NENNER L*21a L*11a sub UXF1a mul A*21a A*11a sub UXF2a mul add B*21a B*11a sub UXF3a mul add def /ZAEHLE L*21a UXF1a mul A*21a UXF2a mul add B*21a UXF3a mul add def NENNER 0 ne {/ALPH ZAEHLE NENNER div def} {/ALPH 99999} ifelse /L*Ma ALPH L*11a mul 1 ALPH sub L*21a mul add def /A*Ma ALPH A*11a mul 1 ALPH sub A*21a mul add def /B*Ma ALPH B*11a mul 1 ALPH sub B*21a mul add def /C*Ma A*Ma dup mul B*Ma dup mul add 0.000001 add sqrt def /H*Ma B*Ma A*Ma 0.0001 add atan def /ia30 ia 3 mul def /iap 1 ALPH sub def /iam ALPH def ia 0 eq {/c3*Ma 0 def %L, c*=0, sector O->Y /m3*Ma iam def %L, m*=1->0 /y3*Ma 1 def %L, y*=1 } if ia 1 eq {/c3*Ma iap def %L, c*=0->1, sector Y->L /m3*Ma 0 def %L, m*=0 /y3*Ma 1 def %L, y*=1 } if ia 2 eq {/c3*Ma 1 def %L, c*=1, sector L->C /m3*Ma 0 def %L, m*=0 /y3*Ma iam def %L, y*=1->0 } if ia 3 eq {/c3*Ma 1 def %L, c*=1, sector C->V /m3*Ma iap def %L, m*=1->0 /y3*Ma 0 def %L, y*=0 } if ia 4 eq {/c3*Ma iam def %L, c*=1->0, sector V->M /m3*Ma 1 def %L, m*=1 /y3*Ma 0 def %L, y*=0 } if ia 5 eq {/c3*Ma 0 def %L, c*=0, sector M->O /m3*Ma 1 def %L, m*=1 /y3*Ma iap def %L, y*=0->1 } if /o3*Ma 1 c3*Ma sub def /l3*Ma 1 m3*Ma sub def /v3*Ma 1 y3*Ma sub def /i3*Ma 1 def /lab*nMa 0.00 def /lab*cMa 1.00 def /lab*wMa 0.00 def /lab*tMa 0.50 def /lab*hMa H*Ma 360 div def /lab*lMa L*Ma nLAB*s0 0 get sub wLAB*s0 0 get nLAB*s0 0 get sub 0.000001 add div def } bind def %END /proc_LAB*Fa_LAB*MaNTABl_olvi3*cmyn3*Ma*ioG %END NE83/10Q/Q83E00ZED Output Linearization (OL) LAB* -> cmyolvnw* 20060101 %BEG NE83/10Q/OUTLIN1XFP.PS MXYZ_to_LAB* 20060101 %BEG Procedure special input XYZ to be transferred to LAB* /MXYZ_to_LAB* {%BEG MXYZ_to_LAB* /XD65 95.05 def /YD65 100.00 def /ZD65 108.90 def /ymaxf 88.59 Yre sub 100 div def /Xref XD65 Yre 100 div mul def /Yref YD65 Yre 100 div mul def %2.52% /Zref ZD65 Yre 100 div mul def /Xwref XD65 ymaxf mul def /Ywref YD65 ymaxf mul def %88.59-2.52=%86.07 /Zwref ZD65 ymaxf mul def 0 16 240 {/j exch def %j=0,112,16 %Asumption END point "white" /i10 j 4 mul 1 add def /i20 i10 15 4 mul add def /Xfact 1.0 MISO_S1gXYZ i20 0 add get div Xwref mul def /Yfact 1.0 MISO_S1gXYZ i20 1 add get div Ywref mul def /Zfact 1.0 MISO_S1gXYZ i20 2 add get div Zwref mul def 0 1 15 {/i exch def %i=0,15 /i2i1 i10 i 4 mul add def /i2i2 i2i1 1 add def /i2i3 i2i1 2 add def /XQ MISO_S1gXYZ i2i1 get Xfact mul Xref add XD65 div def /YQ MISO_S1gXYZ i2i2 get Yfact mul Yref add YD65 div def /ZQ MISO_S1gXYZ i2i3 get Zfact mul Zref add ZD65 div def XQ 0 lt {/XQ 0.00000001 def} if YQ 0 lt {/YQ 0.00000001 def} if ZQ 0 lt {/ZQ 0.00000001 def} if MISO_S1g i2i1 YQ 0.008856 lt {903.3 YQ mul} {YQ 0.33333333 exp 116 mul 16 sub} ifelse put MISO_S1g i2i2 XQ 0.008856 lt {7.787 XQ mul 16 116 div add} {XQ 0.33333333 exp} ifelse YQ 0.008856 lt {7.787 YQ mul 16 116 div add} {YQ 0.33333333 exp} ifelse sub 500 mul put MISO_S1g i2i3 YQ 0.008856 lt {7.787 YQ mul 16 116 div add} {YQ 0.33333333 exp} ifelse ZQ 0.008856 lt {7.787 ZQ mul 16 116 div add} {ZQ 0.33333333 exp} ifelse sub 200 mul put } for %i=0,15 } for %j=0,240,16 } bind def %END Procedure MXYZ_to_LAB* %END NE83/10Q/OUTLIN1XFP.PS MXYZ_to_LAB* 20060101 %BEG DM00/CMISO_S1gLAB.DAT Output Linearization (OL), GLOBAL (G), 20011201 /MISO_S1g 1024 array def /CFilenameS1 %Start output Step S1 (www.ps.bam.de/NE83/10Q/Q83E00FP.PS) def %This file name /CDeviceS1 (Device: (Y); ) def %Device name and file measured /CMeasS1 (Meas.: NE83/10Q/Q83E00NP.PDF;S1) def %File name measured in step S1 /CDateS1 (Date: M010401) def %Date of calculation/measurement /MISO_S1g [%real LAB* measurement of output to be included %no. CIELAB D65 rc 0.00% w* n* col Q Q10001FP.DAT CMYOLV.FOR 0 58.62 -30.62 -42.74 %0.000 1.000 C-W Q cmy0* setcmykcolor 0 1 58.78 -30.49 -42.53 %0.004 0.996 C-W Q 2 59.27 -30.09 -41.90 %0.018 0.982 C-W Q 3 60.09 -29.43 -40.84 %0.040 0.960 C-W Q 4 61.24 -28.51 -39.36 %0.071 0.929 C-W Q 5 62.71 -27.33 -37.46 %0.111 0.889 C-W Q 6 64.51 -25.88 -35.14 %0.160 0.840 C-W Q 7 66.63 -24.17 -32.40 %0.218 0.782 C-W Q 8 69.08 -22.19 -29.23 %0.284 0.716 C-W Q 9 71.86 -19.95 -25.64 %0.360 0.640 C-W Q 10 74.97 -17.45 -21.63 %0.444 0.556 C-W Q 11 78.40 -14.69 -17.20 %0.538 0.462 C-W Q 12 82.17 -11.66 -12.34 %0.640 0.360 C-W Q 13 86.25 -8.36 -7.06 %0.751 0.249 C-W Q 14 90.67 -4.81 -1.36 %0.871 0.129 C-W Q 15 95.41 -0.99 4.76 %1.000 0.000 C-W Q 0 48.13 75.20 -6.79 %0.000 1.000 M-W Q cmy0* setcmykcolor 16 1 48.34 74.86 -6.74 %0.004 0.996 M-W Q 2 48.97 73.85 -6.58 %0.018 0.982 M-W Q 3 50.02 72.15 -6.33 %0.040 0.960 M-W Q 4 51.49 69.78 -5.97 %0.071 0.929 M-W Q 5 53.38 66.73 -5.51 %0.111 0.889 M-W Q 6 55.69 63.01 -4.94 %0.160 0.840 M-W Q 7 58.43 58.61 -4.27 %0.218 0.782 M-W Q 8 61.58 53.53 -3.50 %0.284 0.716 M-W Q 9 65.15 47.77 -2.63 %0.360 0.640 M-W Q 10 69.14 41.34 -1.66 %0.444 0.556 M-W Q 11 73.56 34.23 -0.58 %0.538 0.462 M-W Q 12 78.39 26.44 0.60 %0.640 0.360 M-W Q 13 83.64 17.97 1.89 %0.751 0.249 M-W Q 14 89.32 8.83 3.27 %0.871 0.129 M-W Q 15 95.41 -0.99 4.76 %1.000 0.000 M-W Q 0 90.37 -11.15 96.17 %0.000 1.000 Y-W Q cmy0* setcmykcolor 32 1 90.39 -11.10 95.76 %0.004 0.996 Y-W Q 2 90.46 -10.97 94.54 %0.018 0.982 Y-W Q 3 90.57 -10.74 92.51 %0.040 0.960 Y-W Q 4 90.73 -10.43 89.67 %0.071 0.929 Y-W Q 5 90.93 -10.02 86.01 %0.111 0.889 Y-W Q 6 91.18 -9.52 81.54 %0.160 0.840 Y-W Q 7 91.47 -8.94 76.26 %0.218 0.782 Y-W Q 8 91.80 -8.26 70.17 %0.284 0.716 Y-W Q 9 92.18 -7.49 63.26 %0.360 0.640 Y-W Q 10 92.61 -6.63 55.54 %0.444 0.556 Y-W Q 11 93.08 -5.69 47.01 %0.538 0.462 Y-W Q 12 93.60 -4.65 37.67 %0.640 0.360 Y-W Q 13 94.16 -3.52 27.51 %0.751 0.249 Y-W Q 14 94.76 -2.30 16.54 %0.871 0.129 Y-W Q 15 95.41 -0.99 4.76 %1.000 0.000 Y-W Q 0 18.01 0.50 -0.46 %0.000 1.000 N-W Q 000n* setcmykcolor 48 1 18.35 0.49 -0.44 %0.004 0.996 N-W Q 2 19.39 0.47 -0.37 %0.018 0.982 N-W Q 3 21.11 0.44 -0.25 %0.040 0.960 N-W Q 4 23.51 0.39 -0.09 %0.071 0.929 N-W Q 5 26.61 0.33 0.12 %0.111 0.889 N-W Q 6 30.39 0.26 0.38 %0.160 0.840 N-W Q 7 34.87 0.18 0.68 %0.218 0.782 N-W Q 8 40.03 0.08 1.02 %0.284 0.716 N-W Q 9 45.87 -0.04 1.42 %0.360 0.640 N-W Q 10 52.41 -0.16 1.86 %0.444 0.556 N-W Q 11 59.63 -0.30 2.35 %0.538 0.462 N-W Q 12 67.55 -0.45 2.88 %0.640 0.360 N-W Q 13 76.15 -0.62 3.46 %0.751 0.249 N-W Q 14 85.43 -0.80 4.09 %0.871 0.129 N-W Q 15 95.41 -0.99 4.76 %1.000 0.000 N-W Q 0 47.94 65.31 52.07 %0.000 1.000 O-W Q cmy0* setcmykcolor 64 1 48.15 65.02 51.86 %0.004 0.996 O-W Q 2 48.78 64.13 51.23 %0.018 0.982 O-W Q 3 49.84 62.66 50.18 %0.040 0.960 O-W Q 4 51.32 60.60 48.71 %0.071 0.929 O-W Q 5 53.21 57.94 46.81 %0.111 0.889 O-W Q 6 55.54 54.70 44.50 %0.160 0.840 O-W Q 7 58.28 50.87 41.77 %0.218 0.782 O-W Q 8 61.44 46.45 38.61 %0.284 0.716 O-W Q 9 65.03 41.44 35.04 %0.360 0.640 O-W Q 10 69.04 35.84 31.04 %0.444 0.556 O-W Q 11 73.47 29.66 26.63 %0.538 0.462 O-W Q 12 78.32 22.88 21.79 %0.640 0.360 O-W Q 13 83.60 15.51 16.53 %0.751 0.249 O-W Q 14 89.29 7.56 10.86 %0.871 0.129 O-W Q 15 95.41 -0.99 4.76 %1.000 0.000 O-W Q 0 50.90 -62.96 36.71 %0.000 1.000 L-W Q cmy0* setcmykcolor 80 1 51.10 -62.68 36.57 %0.004 0.996 L-W Q 2 51.69 -61.86 36.14 %0.018 0.982 L-W Q 3 52.68 -60.48 35.43 %0.040 0.960 L-W Q 4 54.07 -58.55 34.44 %0.071 0.929 L-W Q 5 55.85 -56.07 33.16 %0.111 0.889 L-W Q 6 58.02 -53.04 31.60 %0.160 0.840 L-W Q 7 60.59 -49.46 29.75 %0.218 0.782 L-W Q 8 63.56 -45.33 27.62 %0.284 0.716 L-W Q 9 66.92 -40.65 25.21 %0.360 0.640 L-W Q 10 70.68 -35.42 22.51 %0.444 0.556 L-W Q 11 74.84 -29.63 19.53 %0.538 0.462 L-W Q 12 79.39 -23.30 16.26 %0.640 0.360 L-W Q 13 84.33 -16.41 12.71 %0.751 0.249 L-W Q 14 89.67 -8.98 8.88 %0.871 0.129 L-W Q 15 95.41 -0.99 4.76 %1.000 0.000 L-W Q 0 25.72 31.45 -44.35 %0.000 1.000 V-W Q cmy0* setcmykcolor 96 1 26.03 31.31 -44.13 %0.004 0.996 V-W Q 2 26.96 30.87 -43.48 %0.018 0.982 V-W Q 3 28.51 30.15 -42.39 %0.040 0.960 V-W Q 4 30.68 29.14 -40.86 %0.071 0.929 V-W Q 5 33.46 27.85 -38.89 %0.111 0.889 V-W Q 6 36.87 26.26 -36.49 %0.160 0.840 V-W Q 7 40.90 24.39 -33.65 %0.218 0.782 V-W Q 8 45.54 22.22 -30.38 %0.284 0.716 V-W Q 9 50.81 19.77 -26.67 %0.360 0.640 V-W Q 10 56.69 17.03 -22.52 %0.444 0.556 V-W Q 11 63.20 14.00 -17.94 %0.538 0.462 V-W Q 12 70.32 10.69 -12.92 %0.640 0.360 V-W Q 13 78.06 7.08 -7.46 %0.751 0.249 V-W Q 14 86.43 3.19 -1.57 %0.871 0.129 V-W Q 15 95.41 -0.99 4.76 %1.000 0.000 V-W Q 0 18.01 0.50 -0.46 %0.000 1.000 A-W Q nnn0* setcmykcolor 112 1 18.35 0.49 -0.44 %0.004 0.996 A-W Q 2 19.39 0.47 -0.37 %0.018 0.982 A-W Q 3 21.11 0.44 -0.25 %0.040 0.960 A-W Q 4 23.51 0.39 -0.09 %0.071 0.929 A-W Q 5 26.61 0.33 0.12 %0.111 0.889 A-W Q 6 30.39 0.26 0.38 %0.160 0.840 A-W Q 7 34.87 0.18 0.68 %0.218 0.782 A-W Q 8 40.03 0.08 1.02 %0.284 0.716 A-W Q 9 45.87 -0.04 1.42 %0.360 0.640 A-W Q 10 52.41 -0.16 1.86 %0.444 0.556 A-W Q 11 59.63 -0.30 2.35 %0.538 0.462 A-W Q 12 67.55 -0.45 2.88 %0.640 0.360 A-W Q 13 76.15 -0.62 3.46 %0.751 0.249 A-W Q 14 85.43 -0.80 4.09 %0.871 0.129 A-W Q 15 95.41 -0.99 4.76 %1.000 0.000 A-W Q %no. CIELAB D65 rc 0.00% w* n* col Q Q10001FA.DAT CMYOLV.FOR 0 58.62 -30.62 -42.74 %0.000 1.000 C-W Q olv* setrgbcolor 128 1 58.78 -30.49 -42.53 %0.004 0.996 C-W Q 2 59.27 -30.09 -41.90 %0.018 0.982 C-W Q 3 60.09 -29.43 -40.84 %0.040 0.960 C-W Q 4 61.24 -28.51 -39.36 %0.071 0.929 C-W Q 5 62.71 -27.33 -37.46 %0.111 0.889 C-W Q 6 64.51 -25.88 -35.14 %0.160 0.840 C-W Q 7 66.63 -24.17 -32.40 %0.218 0.782 C-W Q 8 69.08 -22.19 -29.23 %0.284 0.716 C-W Q 9 71.86 -19.95 -25.64 %0.360 0.640 C-W Q 10 74.97 -17.45 -21.63 %0.444 0.556 C-W Q 11 78.40 -14.69 -17.20 %0.538 0.462 C-W Q 12 82.17 -11.66 -12.34 %0.640 0.360 C-W Q 13 86.25 -8.36 -7.06 %0.751 0.249 C-W Q 14 90.67 -4.81 -1.36 %0.871 0.129 C-W Q 15 95.41 -0.99 4.76 %1.000 0.000 C-W Q 0 48.13 75.20 -6.79 %0.000 1.000 M-W Q olv* setrgbcolor 144 1 48.34 74.86 -6.74 %0.004 0.996 M-W Q 2 48.97 73.85 -6.58 %0.018 0.982 M-W Q 3 50.02 72.15 -6.33 %0.040 0.960 M-W Q 4 51.49 69.78 -5.97 %0.071 0.929 M-W Q 5 53.38 66.73 -5.51 %0.111 0.889 M-W Q 6 55.69 63.01 -4.94 %0.160 0.840 M-W Q 7 58.43 58.61 -4.27 %0.218 0.782 M-W Q 8 61.58 53.53 -3.50 %0.284 0.716 M-W Q 9 65.15 47.77 -2.63 %0.360 0.640 M-W Q 10 69.14 41.34 -1.66 %0.444 0.556 M-W Q 11 73.56 34.23 -0.58 %0.538 0.462 M-W Q 12 78.39 26.44 0.60 %0.640 0.360 M-W Q 13 83.64 17.97 1.89 %0.751 0.249 M-W Q 14 89.32 8.83 3.27 %0.871 0.129 M-W Q 15 95.41 -0.99 4.76 %1.000 0.000 M-W Q 0 90.37 -11.15 96.17 %0.000 1.000 Y-W Q olv* setrgbcolor 160 1 90.39 -11.10 95.76 %0.004 0.996 Y-W Q 2 90.46 -10.97 94.54 %0.018 0.982 Y-W Q 3 90.57 -10.74 92.51 %0.040 0.960 Y-W Q 4 90.73 -10.43 89.67 %0.071 0.929 Y-W Q 5 90.93 -10.02 86.01 %0.111 0.889 Y-W Q 6 91.18 -9.52 81.54 %0.160 0.840 Y-W Q 7 91.47 -8.94 76.26 %0.218 0.782 Y-W Q 8 91.80 -8.26 70.17 %0.284 0.716 Y-W Q 9 92.18 -7.49 63.26 %0.360 0.640 Y-W Q 10 92.61 -6.63 55.54 %0.444 0.556 Y-W Q 11 93.08 -5.69 47.01 %0.538 0.462 Y-W Q 12 93.60 -4.65 37.67 %0.640 0.360 Y-W Q 13 94.16 -3.52 27.51 %0.751 0.249 Y-W Q 14 94.76 -2.30 16.54 %0.871 0.129 Y-W Q 15 95.41 -0.99 4.76 %1.000 0.000 Y-W Q 0 18.01 0.50 -0.46 %0.000 1.000 N-W Q w* setgray 176 1 18.35 0.49 -0.44 %0.004 0.996 N-W Q 2 19.39 0.47 -0.37 %0.018 0.982 N-W Q 3 21.11 0.44 -0.25 %0.040 0.960 N-W Q 4 23.51 0.39 -0.09 %0.071 0.929 N-W Q 5 26.61 0.33 0.12 %0.111 0.889 N-W Q 6 30.39 0.26 0.38 %0.160 0.840 N-W Q 7 34.87 0.18 0.68 %0.218 0.782 N-W Q 8 40.03 0.08 1.02 %0.284 0.716 N-W Q 9 45.87 -0.04 1.42 %0.360 0.640 N-W Q 10 52.41 -0.16 1.86 %0.444 0.556 N-W Q 11 59.63 -0.30 2.35 %0.538 0.462 N-W Q 12 67.55 -0.45 2.88 %0.640 0.360 N-W Q 13 76.15 -0.62 3.46 %0.751 0.249 N-W Q 14 85.43 -0.80 4.09 %0.871 0.129 N-W Q 15 95.41 -0.99 4.76 %1.000 0.000 N-W Q 0 47.94 65.31 52.07 %0.000 1.000 O-W Q olv* setrgbcolor 194 1 48.15 65.02 51.86 %0.004 0.996 O-W Q 2 48.78 64.13 51.23 %0.018 0.982 O-W Q 3 49.84 62.66 50.18 %0.040 0.960 O-W Q 4 51.32 60.60 48.71 %0.071 0.929 O-W Q 5 53.21 57.94 46.81 %0.111 0.889 O-W Q 6 55.54 54.70 44.50 %0.160 0.840 O-W Q 7 58.28 50.87 41.77 %0.218 0.782 O-W Q 8 61.44 46.45 38.61 %0.284 0.716 O-W Q 9 65.03 41.44 35.04 %0.360 0.640 O-W Q 10 69.04 35.84 31.04 %0.444 0.556 O-W Q 11 73.47 29.66 26.63 %0.538 0.462 O-W Q 12 78.32 22.88 21.79 %0.640 0.360 O-W Q 13 83.60 15.51 16.53 %0.751 0.249 O-W Q 14 89.29 7.56 10.86 %0.871 0.129 O-W Q 15 95.41 -0.99 4.76 %1.000 0.000 O-W Q 0 50.90 -62.96 36.71 %0.000 1.000 L-W Q olv* setrgbcolor 210 1 51.10 -62.68 36.57 %0.004 0.996 L-W Q 2 51.69 -61.86 36.14 %0.018 0.982 L-W Q 3 52.68 -60.48 35.43 %0.040 0.960 L-W Q 4 54.07 -58.55 34.44 %0.071 0.929 L-W Q 5 55.85 -56.07 33.16 %0.111 0.889 L-W Q 6 58.02 -53.04 31.60 %0.160 0.840 L-W Q 7 60.59 -49.46 29.75 %0.218 0.782 L-W Q 8 63.56 -45.33 27.62 %0.284 0.716 L-W Q 9 66.92 -40.65 25.21 %0.360 0.640 L-W Q 10 70.68 -35.42 22.51 %0.444 0.556 L-W Q 11 74.84 -29.63 19.53 %0.538 0.462 L-W Q 12 79.39 -23.30 16.26 %0.640 0.360 L-W Q 13 84.33 -16.41 12.71 %0.751 0.249 L-W Q 14 89.67 -8.98 8.88 %0.871 0.129 L-W Q 15 95.41 -0.99 4.76 %1.000 0.000 L-W Q 0 25.72 31.45 -44.35 %0.000 1.000 V-W Q olv* setrgbcolor 226 1 26.03 31.31 -44.13 %0.004 0.996 V-W Q 2 26.96 30.87 -43.48 %0.018 0.982 V-W Q 3 28.51 30.15 -42.39 %0.040 0.960 V-W Q 4 30.68 29.14 -40.86 %0.071 0.929 V-W Q 5 33.46 27.85 -38.89 %0.111 0.889 V-W Q 6 36.87 26.26 -36.49 %0.160 0.840 V-W Q 7 40.90 24.39 -33.65 %0.218 0.782 V-W Q 8 45.54 22.22 -30.38 %0.284 0.716 V-W Q 9 50.81 19.77 -26.67 %0.360 0.640 V-W Q 10 56.69 17.03 -22.52 %0.444 0.556 V-W Q 11 63.20 14.00 -17.94 %0.538 0.462 V-W Q 12 70.32 10.69 -12.92 %0.640 0.360 V-W Q 13 78.06 7.08 -7.46 %0.751 0.249 V-W Q 14 86.43 3.19 -1.57 %0.871 0.129 V-W Q 15 95.41 -0.99 4.76 %1.000 0.000 V-W Q 0 18.01 0.50 -0.46 %0.000 1.000 A-W Q nnn* setrgbcolor 242 1 18.35 0.49 -0.44 %0.004 0.996 A-W Q 2 19.39 0.47 -0.37 %0.018 0.982 A-W Q 3 21.11 0.44 -0.25 %0.040 0.960 A-W Q 4 23.51 0.39 -0.09 %0.071 0.929 A-W Q 5 26.61 0.33 0.12 %0.111 0.889 A-W Q 6 30.39 0.26 0.38 %0.160 0.840 A-W Q 7 34.87 0.18 0.68 %0.218 0.782 A-W Q 8 40.03 0.08 1.02 %0.284 0.716 A-W Q 9 45.87 -0.04 1.42 %0.360 0.640 A-W Q 10 52.41 -0.16 1.86 %0.444 0.556 A-W Q 11 59.63 -0.30 2.35 %0.538 0.462 A-W Q 12 67.55 -0.45 2.88 %0.640 0.360 A-W Q 13 76.15 -0.62 3.46 %0.751 0.249 A-W Q 14 85.43 -0.80 4.09 %0.871 0.129 A-W Q 15 95.41 -0.99 4.76 %1.000 0.000 A-W Q % 0 0.00 0.00 0.00 %0.000 X-W Dummy for visual estimation % 1 6.67 0.00 0.00 %0.067 X-W % 2 13.33 0.00 0.00 %0.133 X-W % 3 20.00 0.00 0.00 %0.200 X-W % 4 26.67 0.00 0.00 %0.267 X-W % 5 33.33 0.00 0.00 %0.333 X-W % 6 40.00 0.00 0.00 %0.400 X-W % 7 46.67 0.00 0.00 %0.467 X-W % 8 53.33 0.00 0.00 %0.533 X-W % 9 60.00 0.00 0.00 %0.600 X-W % 10 66.67 0.00 0.00 %0.667 X-W % 11 73.33 0.00 0.00 %0.733 X-W % 12 80.00 0.00 0.00 %0.800 X-W % 13 86.67 0.00 0.00 %0.867 X-W % 14 93.33 0.00 0.00 %0.933 X-W % 15 99.99 0.00 0.00 %1.000 X-W ] def %END DM00/CMISO_S1gLAB.DAT Output Linearization (OL), GLOBAL (G), 20011201 %BEG DM00/CMISO_S1gXYZ.DAT Output Linearization (OL), GLOBAL (G), 20011201 /MISO_S1gXYZ 1024 array def /CFilenameS1 %Start output Step S1 (www.ps.bam.de/NE83/10Q/Q83E00FP.PS) def %This file name /CDeviceS1 (Device: (Y); ) def %Device name and file measured /CMeasS1 (Meas.: NE83/10Q/Q83E00NP.PDF;S1) def %File name measured in step S1 /CDateS1 (Date: M010401) def %Date of calculation/measurement /MISO_S1gXYZ [%real XYZ measurement of output to be included %no. CIEXYZ D65 rc 0.00% w* n* col Q Q10011FP.DAT CMYOLV.FOR 0 18.74 26.62 68.54 %0.000 1.000 C-W Q cmy0* setcmykcolor 0 1 18.90 26.79 68.62 %0.004 0.996 C-W Q 2 19.40 27.33 68.88 %0.018 0.982 C-W Q 3 20.23 28.23 69.31 %0.040 0.960 C-W Q 4 21.45 29.52 69.91 %0.071 0.929 C-W Q 5 23.08 31.24 70.68 %0.111 0.889 C-W Q 6 25.18 33.43 71.64 %0.160 0.840 C-W Q 7 27.83 36.15 72.79 %0.218 0.782 C-W Q 8 31.10 39.46 74.12 %0.284 0.716 C-W Q 9 35.12 43.46 75.65 %0.360 0.640 C-W Q 10 39.99 48.23 77.39 %0.444 0.556 C-W Q 11 45.88 53.90 79.34 %0.538 0.462 C-W Q 12 52.97 60.60 81.51 %0.640 0.360 C-W Q 13 61.47 68.50 83.92 %0.751 0.249 C-W Q 14 71.61 77.76 86.57 %0.871 0.129 C-W Q 15 83.69 88.59 89.48 %1.000 0.000 C-W Q 0 33.06 16.90 22.00 %0.000 1.000 M-W Q cmy0* setcmykcolor 16 1 33.22 17.06 22.18 %0.004 0.996 M-W Q 2 33.70 17.57 22.71 %0.018 0.982 M-W Q 3 34.52 18.44 23.62 %0.040 0.960 M-W Q 4 35.68 19.70 24.92 %0.071 0.929 M-W Q 5 37.22 21.40 26.67 %0.111 0.889 M-W Q 6 39.16 23.61 28.92 %0.160 0.840 M-W Q 7 41.53 26.41 31.73 %0.218 0.782 M-W Q 8 44.39 29.91 35.20 %0.284 0.716 M-W Q 9 47.78 34.24 39.43 %0.360 0.640 M-W Q 10 51.77 39.54 44.54 %0.444 0.556 M-W Q 11 56.43 46.02 50.68 %0.538 0.462 M-W Q 12 61.85 53.88 58.02 %0.640 0.360 M-W Q 13 68.13 63.38 66.77 %0.751 0.249 M-W Q 14 75.36 74.84 77.17 %0.871 0.129 M-W Q 15 83.69 88.59 89.48 %1.000 0.000 M-W Q 0 68.07 77.11 9.03 %0.000 1.000 Y-W Q cmy0* setcmykcolor 32 1 68.14 77.15 9.17 %0.004 0.996 Y-W Q 2 68.33 77.30 9.60 %0.018 0.982 Y-W Q 3 68.65 77.54 10.34 %0.040 0.960 Y-W Q 4 69.11 77.89 11.43 %0.071 0.929 Y-W Q 5 69.70 78.33 12.95 %0.111 0.889 Y-W Q 6 70.43 78.87 14.98 %0.160 0.840 Y-W Q 7 71.29 79.52 17.64 %0.218 0.782 Y-W Q 8 72.30 80.26 21.08 %0.284 0.716 Y-W Q 9 73.45 81.12 25.49 %0.360 0.640 Y-W Q 10 74.75 82.08 31.11 %0.444 0.556 Y-W Q 11 76.20 83.15 38.21 %0.538 0.462 Y-W Q 12 77.82 84.33 47.14 %0.640 0.360 Y-W Q 13 79.60 85.63 58.32 %0.751 0.249 Y-W Q 14 81.55 87.05 72.24 %0.871 0.129 Y-W Q 15 83.69 88.59 89.48 %1.000 0.000 Y-W Q 0 2.42 2.52 2.81 %0.000 1.000 N-W Q 000n* setcmykcolor 48 1 2.49 2.60 2.89 %0.004 0.996 N-W Q 2 2.72 2.84 3.15 %0.018 0.982 N-W Q 3 3.14 3.27 3.61 %0.040 0.960 N-W Q 4 3.78 3.95 4.32 %0.071 0.929 N-W Q 5 4.74 4.96 5.37 %0.111 0.889 N-W Q 6 6.10 6.40 6.87 %0.160 0.840 N-W Q 7 8.03 8.43 8.97 %0.218 0.782 N-W Q 8 10.72 11.27 11.88 %0.284 0.716 N-W Q 9 14.42 15.18 15.88 %0.360 0.640 N-W Q 10 19.46 20.51 21.30 %0.444 0.556 N-W Q 11 26.27 27.72 28.59 %0.538 0.462 N-W Q 12 35.38 37.36 38.29 %0.640 0.360 N-W Q 13 47.42 50.13 51.10 %0.751 0.249 N-W Q 14 63.20 66.86 67.83 %0.871 0.129 N-W Q 15 83.69 88.59 89.48 %1.000 0.000 N-W Q 0 30.13 16.75 2.68 %0.000 1.000 O-W Q cmy0* setcmykcolor 64 1 30.29 16.91 2.76 %0.004 0.996 O-W Q 2 30.78 17.42 3.01 %0.018 0.982 O-W Q 3 31.62 18.28 3.46 %0.040 0.960 O-W Q 4 32.81 19.54 4.16 %0.071 0.929 O-W Q 5 34.39 21.24 5.19 %0.111 0.889 O-W Q 6 36.38 23.45 6.67 %0.160 0.840 O-W Q 7 38.84 26.25 8.75 %0.218 0.782 O-W Q 8 41.81 29.76 11.64 %0.284 0.716 O-W Q 9 45.35 34.08 15.61 %0.360 0.640 O-W Q 10 49.54 39.40 21.01 %0.444 0.556 O-W Q 11 54.46 45.88 28.30 %0.538 0.462 O-W Q 12 60.22 53.76 38.02 %0.640 0.360 O-W Q 13 66.92 63.29 50.87 %0.751 0.249 O-W Q 14 74.69 74.78 67.68 %0.871 0.129 O-W Q 15 83.69 88.59 89.48 %1.000 0.000 O-W Q 0 8.71 19.18 6.62 %0.000 1.000 L-W Q cmy0* setcmykcolor 80 1 8.84 19.35 6.74 %0.004 0.996 L-W Q 2 9.24 19.87 7.12 %0.018 0.982 L-W Q 3 9.94 20.76 7.78 %0.040 0.960 L-W Q 4 10.97 22.04 8.77 %0.071 0.929 L-W Q 5 12.40 23.76 10.16 %0.111 0.889 L-W Q 6 14.31 25.98 12.05 %0.160 0.840 L-W Q 7 16.81 28.79 14.58 %0.218 0.782 L-W Q 8 20.04 32.26 17.90 %0.284 0.716 L-W Q 9 24.17 36.53 22.23 %0.360 0.640 L-W Q 10 29.42 41.73 27.85 %0.444 0.556 L-W Q 11 36.04 48.02 35.07 %0.538 0.462 L-W Q 12 44.36 55.60 44.31 %0.640 0.360 L-W Q 13 54.76 64.71 56.04 %0.751 0.249 L-W Q 14 67.69 75.60 70.87 %0.871 0.129 L-W Q 15 83.69 88.59 89.48 %1.000 0.000 L-W Q 0 7.17 4.65 21.40 %0.000 1.000 V-W Q cmy0* setcmykcolor 96 1 7.29 4.76 21.58 %0.004 0.996 V-W Q 2 7.67 5.08 22.11 %0.018 0.982 V-W Q 3 8.32 5.65 23.01 %0.040 0.960 V-W Q 4 9.29 6.51 24.32 %0.071 0.929 V-W Q 5 10.65 7.75 26.06 %0.111 0.889 V-W Q 6 12.48 9.47 28.31 %0.160 0.840 V-W Q 7 14.91 11.80 31.13 %0.218 0.782 V-W Q 8 18.07 14.93 34.61 %0.284 0.716 V-W Q 9 22.16 19.10 38.86 %0.360 0.640 V-W Q 10 27.42 24.61 44.00 %0.444 0.556 V-W Q 11 34.13 31.82 50.19 %0.538 0.462 V-W Q 12 42.64 41.21 57.61 %0.640 0.360 V-W Q 13 53.39 53.32 66.46 %0.751 0.249 V-W Q 14 66.87 68.85 76.99 %0.871 0.129 V-W Q 15 83.69 88.59 89.48 %1.000 0.000 V-W Q 0 2.42 2.52 2.81 %0.000 1.000 A-W Q nnn0* setcmykcolor 112 1 2.49 2.60 2.89 %0.004 0.996 A-W Q 2 2.72 2.84 3.15 %0.018 0.982 A-W Q 3 3.14 3.27 3.61 %0.040 0.960 A-W Q 4 3.78 3.95 4.32 %0.071 0.929 A-W Q 5 4.74 4.96 5.37 %0.111 0.889 A-W Q 6 6.10 6.40 6.87 %0.160 0.840 A-W Q 7 8.03 8.43 8.97 %0.218 0.782 A-W Q 8 10.72 11.27 11.88 %0.284 0.716 A-W Q 9 14.42 15.18 15.88 %0.360 0.640 A-W Q 10 19.46 20.51 21.30 %0.444 0.556 A-W Q 11 26.27 27.72 28.59 %0.538 0.462 A-W Q 12 35.38 37.36 38.29 %0.640 0.360 A-W Q 13 47.42 50.13 51.10 %0.751 0.249 A-W Q 14 63.20 66.86 67.83 %0.871 0.129 A-W Q 15 83.69 88.59 89.48 %1.000 0.000 A-W Q %no. CIEXYZ D65 rc 0.00% w* n* col Q Q10011FA.DAT CMYOLV.FOR 0 18.74 26.62 68.54 %0.000 1.000 C-W Q olv* setrgbcolor 128 1 18.90 26.79 68.62 %0.004 0.996 C-W Q 2 19.40 27.33 68.88 %0.018 0.982 C-W Q 3 20.23 28.23 69.31 %0.040 0.960 C-W Q 4 21.45 29.52 69.91 %0.071 0.929 C-W Q 5 23.08 31.24 70.68 %0.111 0.889 C-W Q 6 25.18 33.43 71.64 %0.160 0.840 C-W Q 7 27.83 36.15 72.79 %0.218 0.782 C-W Q 8 31.10 39.46 74.12 %0.284 0.716 C-W Q 9 35.12 43.46 75.65 %0.360 0.640 C-W Q 10 39.99 48.23 77.39 %0.444 0.556 C-W Q 11 45.88 53.90 79.34 %0.538 0.462 C-W Q 12 52.97 60.60 81.51 %0.640 0.360 C-W Q 13 61.47 68.50 83.92 %0.751 0.249 C-W Q 14 71.61 77.76 86.57 %0.871 0.129 C-W Q 15 83.69 88.59 89.48 %1.000 0.000 C-W Q 0 33.06 16.90 22.00 %0.000 1.000 M-W Q olv* setrgbcolor 144 1 33.22 17.06 22.18 %0.004 0.996 M-W Q 2 33.70 17.57 22.71 %0.018 0.982 M-W Q 3 34.52 18.44 23.62 %0.040 0.960 M-W Q 4 35.68 19.70 24.92 %0.071 0.929 M-W Q 5 37.22 21.40 26.67 %0.111 0.889 M-W Q 6 39.16 23.61 28.92 %0.160 0.840 M-W Q 7 41.53 26.41 31.73 %0.218 0.782 M-W Q 8 44.39 29.91 35.20 %0.284 0.716 M-W Q 9 47.78 34.24 39.43 %0.360 0.640 M-W Q 10 51.77 39.54 44.54 %0.444 0.556 M-W Q 11 56.43 46.02 50.68 %0.538 0.462 M-W Q 12 61.85 53.88 58.02 %0.640 0.360 M-W Q 13 68.13 63.38 66.77 %0.751 0.249 M-W Q 14 75.36 74.84 77.17 %0.871 0.129 M-W Q 15 83.69 88.59 89.48 %1.000 0.000 M-W Q 0 68.07 77.11 9.03 %0.000 1.000 Y-W Q olv* setrgbcolor 160 1 68.14 77.15 9.17 %0.004 0.996 Y-W Q 2 68.33 77.30 9.60 %0.018 0.982 Y-W Q 3 68.65 77.54 10.34 %0.040 0.960 Y-W Q 4 69.11 77.89 11.43 %0.071 0.929 Y-W Q 5 69.70 78.33 12.95 %0.111 0.889 Y-W Q 6 70.43 78.87 14.98 %0.160 0.840 Y-W Q 7 71.29 79.52 17.64 %0.218 0.782 Y-W Q 8 72.30 80.26 21.08 %0.284 0.716 Y-W Q 9 73.45 81.12 25.49 %0.360 0.640 Y-W Q 10 74.75 82.08 31.11 %0.444 0.556 Y-W Q 11 76.20 83.15 38.21 %0.538 0.462 Y-W Q 12 77.82 84.33 47.14 %0.640 0.360 Y-W Q 13 79.60 85.63 58.32 %0.751 0.249 Y-W Q 14 81.55 87.05 72.24 %0.871 0.129 Y-W Q 15 83.69 88.59 89.48 %1.000 0.000 Y-W Q 0 2.42 2.52 2.81 %0.000 1.000 N-W Q w* setgray 176 1 2.49 2.60 2.89 %0.004 0.996 N-W Q 2 2.72 2.84 3.15 %0.018 0.982 N-W Q 3 3.14 3.27 3.61 %0.040 0.960 N-W Q 4 3.78 3.95 4.32 %0.071 0.929 N-W Q 5 4.74 4.96 5.37 %0.111 0.889 N-W Q 6 6.10 6.40 6.87 %0.160 0.840 N-W Q 7 8.03 8.43 8.97 %0.218 0.782 N-W Q 8 10.72 11.27 11.88 %0.284 0.716 N-W Q 9 14.42 15.18 15.88 %0.360 0.640 N-W Q 10 19.46 20.51 21.30 %0.444 0.556 N-W Q 11 26.27 27.72 28.59 %0.538 0.462 N-W Q 12 35.38 37.36 38.29 %0.640 0.360 N-W Q 13 47.42 50.13 51.10 %0.751 0.249 N-W Q 14 63.20 66.86 67.83 %0.871 0.129 N-W Q 15 83.69 88.59 89.48 %1.000 0.000 N-W Q 0 30.13 16.75 2.68 %0.000 1.000 O-W Q olv* setrgbcolor 194 1 30.29 16.91 2.76 %0.004 0.996 O-W Q 2 30.78 17.42 3.01 %0.018 0.982 O-W Q 3 31.62 18.28 3.46 %0.040 0.960 O-W Q 4 32.81 19.54 4.16 %0.071 0.929 O-W Q 5 34.39 21.24 5.19 %0.111 0.889 O-W Q 6 36.38 23.45 6.67 %0.160 0.840 O-W Q 7 38.84 26.25 8.75 %0.218 0.782 O-W Q 8 41.81 29.76 11.64 %0.284 0.716 O-W Q 9 45.35 34.08 15.61 %0.360 0.640 O-W Q 10 49.54 39.40 21.01 %0.444 0.556 O-W Q 11 54.46 45.88 28.30 %0.538 0.462 O-W Q 12 60.22 53.76 38.02 %0.640 0.360 O-W Q 13 66.92 63.29 50.87 %0.751 0.249 O-W Q 14 74.69 74.78 67.68 %0.871 0.129 O-W Q 15 83.69 88.59 89.48 %1.000 0.000 O-W Q 0 8.71 19.18 6.62 %0.000 1.000 L-W Q olv* setrgbcolor 210 1 8.84 19.35 6.74 %0.004 0.996 L-W Q 2 9.24 19.87 7.12 %0.018 0.982 L-W Q 3 9.94 20.76 7.78 %0.040 0.960 L-W Q 4 10.97 22.04 8.77 %0.071 0.929 L-W Q 5 12.40 23.76 10.16 %0.111 0.889 L-W Q 6 14.31 25.98 12.05 %0.160 0.840 L-W Q 7 16.81 28.79 14.58 %0.218 0.782 L-W Q 8 20.04 32.26 17.90 %0.284 0.716 L-W Q 9 24.17 36.53 22.23 %0.360 0.640 L-W Q 10 29.42 41.73 27.85 %0.444 0.556 L-W Q 11 36.04 48.02 35.07 %0.538 0.462 L-W Q 12 44.36 55.60 44.31 %0.640 0.360 L-W Q 13 54.76 64.71 56.04 %0.751 0.249 L-W Q 14 67.69 75.60 70.87 %0.871 0.129 L-W Q 15 83.69 88.59 89.48 %1.000 0.000 L-W Q 0 7.17 4.65 21.40 %0.000 1.000 V-W Q olv* setrgbcolor 226 1 7.29 4.76 21.58 %0.004 0.996 V-W Q 2 7.67 5.08 22.11 %0.018 0.982 V-W Q 3 8.32 5.65 23.01 %0.040 0.960 V-W Q 4 9.29 6.51 24.32 %0.071 0.929 V-W Q 5 10.65 7.75 26.06 %0.111 0.889 V-W Q 6 12.48 9.47 28.31 %0.160 0.840 V-W Q 7 14.91 11.80 31.13 %0.218 0.782 V-W Q 8 18.07 14.93 34.61 %0.284 0.716 V-W Q 9 22.16 19.10 38.86 %0.360 0.640 V-W Q 10 27.42 24.61 44.00 %0.444 0.556 V-W Q 11 34.13 31.82 50.19 %0.538 0.462 V-W Q 12 42.64 41.21 57.61 %0.640 0.360 V-W Q 13 53.39 53.32 66.46 %0.751 0.249 V-W Q 14 66.87 68.85 76.99 %0.871 0.129 V-W Q 15 83.69 88.59 89.48 %1.000 0.000 V-W Q 0 2.42 2.52 2.81 %0.000 1.000 A-W Q nnn* setrgbcolor 242 1 2.49 2.60 2.89 %0.004 0.996 A-W Q 2 2.72 2.84 3.15 %0.018 0.982 A-W Q 3 3.14 3.27 3.61 %0.040 0.960 A-W Q 4 3.78 3.95 4.32 %0.071 0.929 A-W Q 5 4.74 4.96 5.37 %0.111 0.889 A-W Q 6 6.10 6.40 6.87 %0.160 0.840 A-W Q 7 8.03 8.43 8.97 %0.218 0.782 A-W Q 8 10.72 11.27 11.88 %0.284 0.716 A-W Q 9 14.42 15.18 15.88 %0.360 0.640 A-W Q 10 19.46 20.51 21.30 %0.444 0.556 A-W Q 11 26.27 27.72 28.59 %0.538 0.462 A-W Q 12 35.38 37.36 38.29 %0.640 0.360 A-W Q 13 47.42 50.13 51.10 %0.751 0.249 A-W Q 14 63.20 66.86 67.83 %0.871 0.129 A-W Q 15 83.69 88.59 89.48 %1.000 0.000 A-W Q ] def %END DM00/CMISO_S1gXYZ.DAT Output Linearization (OL), GLOBAL (G), 20011201 %BEG DM00/CM_S1GCMYOS.DAT Output Linearization (OL), GLOBAL (G), 20010901 %CMYOLVNW4DL.PS 4dimensional series %INCLUDES STANDARD (S) relative series a: cmyn-w and b: olv(cmy)-w /tzaccmyo1g 64 array def /tzamcmyo1g 64 array def /tzaycmyo1g 64 array def /tzancmyo1g 64 array def /tzbocmyo1g 64 array def /tzblcmyo1g 64 array def /tzbvcmyo1g 64 array def /tzbncmyo1g 64 array def /tzaccmyo1g [ %Ccmyo1g01.dat 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 ] def /tzamcmyo1g [ %Mcmyo1g01.dat 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 ] def /tzaycmyo1g [ %Ycmyo1g01.dat 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 ] def /tzancmyo1g [ %Ncmyo1g01.dat 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 ] def /tzbocmyo1g [ %Ocmyo1g01.dat 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 ] def /tzblcmyo1g [ %Lcmyo1g01.dat 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 ] def /tzbvcmyo1g [ %Vcmyo1g01.dat 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 ] def /tzbncmyo1g [ %CMYcmyo1g01.dat 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 1.000 0.933 0.867 0.800 0.733 0.667 0.600 0.533 0.467 0.400 0.333 0.267 0.200 0.132 0.067 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 0.000 ] def %END DM00/CM_S1GCMYOS.DAT Output Linearization (OL), GLOBAL (G), 20010901 %BEG NE83/10Q/OUTLIN1YFP.PS Output Linearization, coordinate transfer 20060101 %BEG NE83/10Q/Q83E00FP.PS Linearization data in the File (F) for the device (Y) %File: www.ps.bam.de/NE83/10Q/Q83E00FP.PS %Output Linearization (OL) BY Linearization Method (LM) %CIELAB MEASUREMENT OF FIRST OUTPUT IS NECESSARY, e. g. File MISO_S1G.DAT % % 1. It is asumed that all Output Linearization (OL) data are % stored in this file NE83/10Q/Q83E00FP.PS for the device (Y). % 2. It is assumed that no Output Linearization (OL) data are % stored in the Distiller Startup (S) directory % for the device (Y) % 3. It is assumed that no Output Linearization (OL) data are % stored in the PostScript Device (D) memory of the device (Y) %possible Action: Delete the part %BEG NE83/OUTLIN11.PS ... until ...%END NE83:OUTLIN11.PS %of this file NE83/10Q/Q83E00FP.PS for the device (Y) %Result of this action: %Then in the file NE83/10Q/Q83E00FP.PS there are no Output Linearization (OL) data. %The PS output will be the same compared to the file %which includes no (N) Output Linearization (OL) data %Remark: % It is assumed that no Output Linearization (OL) data are % stored in the Distiller Startup (S) directory % or the PostScript Device (D) memory % for the device (Y) /inputarrayS1 16 array def /inputarrayS1 %8-bit equidistant units (default data) [0 17 34 51 68 85 102 119 136 153 170 187 204 221 238 255] bind def /outputarrayS1 256 array def /outputarrayS1 [%relative equidistamt CIELAB units (default data) 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %C-W cmy0* setcmykcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %C-W cmy0* setcmykcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %M-W cmy0* setcmykcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %M-W cmy0* setcmykcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %Y-W cmy0* setcmykcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %Y-W cmy0* setcmykcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %N-W 000n* setcmykcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %N-W 000n* setcmykcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %O-W cmy0* setcmykcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %O-W cmy0* setcmykcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %L-W cmy0* setcmykcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %L-W cmy0* setcmykcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %V-W cmy0* setcmykcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %V-W cmy0* setcmykcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %A-W nnn* setcmykcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %A-W nnn* setcmykcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %C-W olv* setrgbcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %C-W olv* setrgbcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %M-W olv* setrgbcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %M-W olv* setrgbcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %Y-W olv* setrgbcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %Y-W olv* setrgbcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %N-W w* setgray 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %N-W w* setgray 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %O-W olv* setrgbcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %O-W olv* setrgbcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %L-W olv* setrgbcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %L-W olv* setrgbcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %V-W olv* setrgbcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %V-W olv* setrgbcolor 0.0000 0.6667 0.1333 0.2000 0.2667 0.3333 0.4000 0.4667 %A-W www* setrgbcolor 0.5333 0.6000 0.6667 0.7333 0.8000 0.8667 0.9333 1.0000 %A-W www* setrgbcolor ] bind def % If the ith element of the inputarray is used the measured colour at % the ouput will be that given by the corresponding element in the % output array. % The ioFunction uses the input and output arrays to determine % which value is needed inorder to achieve the desired 'color' at the output. % If the ith element of the inputarray is used the measured colour at % the ouput will be that given by the corresponding element in the % output array. % The ioFunction uses the input and output arrays to determine % which value is needed inorder to achieve the desired 'color' at the output. /cmyw1g 1 def /ioA 0 def /ioFunction0 {%BEG search the outputarrayS1 using a for loop ioA 0 eq {%BEG ioA = 0 %*******************************BEG special transfer XYZ -> LAB* IMES 1 eq {MXYZ_to_LAB*} if %*******************************END special transfer XYZ -> LAB* /ioA 1 def %new value 0 16 240 {/jMISO exch def %j=0,112,16 /i10 jMISO 4 mul def /i20 i10 15 4 mul add def /DifAW {MISO_S1g i20 1 add get MISO_S1g i10 1 add get sub dup mul MISO_S1g i20 2 add get MISO_S1g i10 2 add get sub dup mul add MISO_S1g i20 3 add get MISO_S1g i10 3 add get sub dup mul add sqrt} bind def 0 1 15 {/iMISO exch def %outputarrayS1A Definition outputarrayS1 jMISO iMISO add /i2i i10 iMISO 4 mul add def MISO_S1g i2i 1 add get MISO_S1g i10 1 add get sub dup mul MISO_S1g i2i 2 add get MISO_S1g i10 2 add get sub dup mul add MISO_S1g i2i 3 add get MISO_S1g i10 3 add get sub dup mul add sqrt DifAW div put } for %outputarrayS1 Definition } for %j=0,240,16 } if %BEG ioA = 0 } bind def %END search the outputarrayS1 using a for loop /ioFunctiont {%BEG search the transferf using a for loop /L*Ng outputarrayS1 jx 0 add get 0.0005 add def /L*Wg outputarrayS1 jx 15 add get 0.0005 sub def %/L*Ng 18.01 def /L*Wg 95.41 def /L*NG L*Ng def /L*WG L*Wg def %transferf converts a value between 0 and 1 %to one between 18.01 and 95.41 /transferf {L*WG L*NG sub mul L*NG add} bind def } bind def %END search the transferf using a for loop /ioFunction { %BEG search the modcolor using a for loop 1 1 15 {/iMISO exch def %i=1,15 color outputarrayS1 jx iMISO add get lt color outputarrayS1 jx iMISO 1 sub add get ge and {/outmax outputarrayS1 jx iMISO add get def /inpmax inputarrayS1 iMISO get def /outmin outputarrayS1 jx iMISO 1 sub add get def /inpmin inputarrayS1 iMISO 1 sub get def exit } if } for %i=1,15 % Use a linear interpolation /modcolor color outmin sub outmax outmin sub div inpmax inpmin sub mul inpmin add def } bind def %END search the modcolor using a for loop /transn {/jx exch def i*ptrsca 1 eq {/jx jx 128 add def} if %olv* setrgbcolor output(128-255) i*ptrsca 3 eq {/jx jx 128 add def} if %w* setgray output (128-255) i*ptrsca 7 eq {/jx jx 128 add def} if %w* setgray output (128-255) ioFunction0 ioFunctiont /color exch 1 exch sub transferf def ioFunction modcolor 255 div 1 exch sub} def /transp {/jx exch def i*ptrsca 1 eq {/jx jx 128 add def} if %olv* setrgbcolor output(128-255) i*ptrsca 3 eq {/jx jx 128 add def} if %w* setgray output (128-255) i*ptrsca 7 eq {/jx jx 128 add def} if %w* setgray output (128-255) ioFunction0 ioFunctiont /color exch transferf def ioFunction modcolor 255 div} def /cmy*io_to_cmy'*ioG { %BEG Procedure cmy*io_to_cmy'*ioG /ncolor exch def /ycolor exch def /mcolor exch def /ccolor exch def /e*n 1 e*w sub def i*p 0 eq i*p 1 eq or {%sector C-V of C-M, C>=M, i*p=0; o:O-Y %sector V-M of C-M, M>=C, i*p=1, o:Y-L /c1color ccolor 0 transn def %C /c2color ccolor 96 transn def %V /c3color ccolor 112 transn def %N /m1color mcolor 16 transn def %M /m2color mcolor 96 transn def %V /m3color mcolor 112 transn def %N /y1color ycolor 32 transn def %Y /y2color ycolor i*p 0 eq {64} {80} ifelse transn def %O,L /y3color ycolor 112 transn def %N /c'*w c1color t*n mul c2color t*p mul add e*w mul c3color e*n mul add def /m'*w m1color t*n mul m2color t*p mul add e*w mul m3color e*n mul add def /y'*w y1color t*n mul y2color t*p mul add e*w mul y3color e*n mul add def /n'*w 0 def } if %sector C-M i*p 2 eq i*p 3 eq or {%sector M-O of M-Y, M>=Y, i*p=2; o:L-C %sector O-Y of M-Y, Y>=M, i*p=3: o:C-V /m1color mcolor 16 transn def %M /m2color mcolor 64 transn def %O /m3color mcolor 112 transn def %N /y1color ycolor 32 transn def %Y /y2color ycolor 64 transn def %O /y3color ycolor 112 transn def %N /c1color ccolor 0 transn def %C /c2color ccolor i*p 2 eq {80} {96} ifelse transn def %L,V /c3color ccolor 112 transn def %N /m'*w m1color t*n mul m2color t*p mul add e*w mul m3color e*n mul add def /y'*w y1color t*n mul y2color t*p mul add e*w mul y3color e*n mul add def /c'*w c1color t*n mul c2color t*p mul add e*w mul c3color e*n mul add def /n'*w 0 def } if %sector M-Y i*p 4 eq i*p 5 eq or {%sector Y-L of Y-C, Y>=C, i*p=4; o:V-M %sector L-C of Y-C, C>=Y, i*p=5; o:M-O /y1color ycolor 32 transn def %Y /y2color ycolor 80 transn def %L /y3color ycolor 112 transn def %N /c1color ccolor 0 transn def %C /c2color ccolor 80 transn def %L /c3color ccolor 112 transn def %N /m1color mcolor 16 transn def %M /m2color mcolor i*p 4 eq {96} {64} ifelse transn def %V,O /m3color mcolor 112 transn def %N /y'*w y1color t*n mul y2color t*p mul add e*w mul y3color e*n mul add def /c'*w c1color t*n mul c2color t*p mul add e*w mul c3color e*n mul add def /m'*w m1color t*n mul m2color t*p mul add e*w mul m3color e*n mul add def /n'*w 0 def } if %sector Y-C %special All achromatic colors N=CMY i*p 6 eq {%i*p=6 /c1color ccolor 112 transn def /m1color mcolor 112 transn def /y1color ycolor 112 transn def /e*w 0 def /t*p 0 def /t*n 1 def /t*n 0 def /c'*w c1color def /m'*w m1color def /y'*w y1color def /n'*w 0 def } if %All achromatic colors %special All achromatic colors only N i*p 7 eq {%i*p=7 /c1color 0 def /m1color 0 def /y1color 0 def /n1color ncolor 48 transn def /e*w 0 def /t*p 0 def /t*n 1 def /t*n 0 def /c'*w 0 def /m'*w 0 def /y'*w 0 def /n'*w n1color def } if %All achromatic colors c'*w m'*w y'*w n'*w } def %END Procedure cmy*io_to_cmy'*ioG /OLoutcmyn1G {%BEG Procedure OLoutcmyn1G: OL and output by setxy %BEG Change by Output Linearisation (OL) % only if device data different from linear /iLAB 0 def LAB*ioG /IMODE 1 def %cmy* /c* c*w def /m* m*w def /y* y*w def cmyolv*io_to_LAB*ioG /o*n 1 c*w sub def /l*n 1 m*w sub def /v*n 1 y*w sub def /white7 l*CIE def %NEW relative CIE lightness /black7 1 white7 sub def i*ptrsca 0 eq {c*w m*w sub abs 0.01 le c*w y*w sub abs 0.01 le and {/i*p 7 def 0 0 0 black7} {c*w m*w y*w 0} ifelse} if i*ptrsca 1 eq {c*w m*w sub abs 0.01 le c*w y*w sub abs 0.01 le and {/i*p 7 def 0 0 0 black7} {c*w m*w y*w 0} ifelse} if i*ptrsca 2 eq {c*w m*w y*w 0} if i*ptrsca 3 eq {c*w m*w y*w 0} if i*ptrsca 4 eq {c*w m*w y*w 0} if i*ptrsca 5 eq {c*w m*w y*w 0} if i*ptrsca 6 eq {/i*p 7 def 0 0 0 black7} if i*ptrsca 7 eq {/i*p 7 def 0 0 0 black7} if } def %END Procedure OLoutcmyn1G: OL and output by setxy /OLoutcmyn2G {%BEG Procedure OLoutcmyn2G: OL and output by setxy cmy*io_to_cmy'*ioG %END Change by Output Linearisation (OL) /n'*w exch def /y'*w exch def /m'*w exch def /c'*w exch def i*ptrsca 0 eq {i*p 7 eq {0 0 0 n'*w sgcmykcolor} {c'*w m'*w y'*w 0 sgcmykcolor} ifelse } if i*ptrsca 1 eq {i*p 7 eq {1 n'*w sub sggray} {1 c'*w sub 1 m'*w sub 1 y'*w sub sgrgbcolor} ifelse } if i*ptrsca 2 eq {c'*w m'*w y'*w 0 sgcmykcolor} if i*ptrsca 3 eq {1 c'*w sub 1 m'*w sub 1 y'*w sub sgrgbcolor} if i*ptrsca 4 eq i*ptrsca 5 eq or { %lab* relative or LAB* absolute [/CIEBasedABC << %Farbraum und Grenzen fuer D65 /RangeABC [0 100 -128 127 -128 127] /DecodeABC [{16 add 116 div} bind {500 div} bind {200 div} bind] /MatrixABC [1 1 1 1 0 0 0 0 -1] /DecodeLMN [{dup 6 29 div ge {dup dup mul mul} {4 29 div sub 108 841 div mul} ifelse 0.9505 mul} bind {dup 6 29 div ge {dup dup mul mul} {4 29 div sub 108 841 div mul} ifelse} bind {dup 6 29 div ge {dup dup mul mul} {4 29 div sub 108 841 div mul} ifelse 1.0890 mul} bind] /WhitePoint [0.9505 1 1.089] %CIEXYZ fuer D65 >>] setcolorspace } if %lab* relative or LAB* absolute i*ptrsca 4 eq { %lab L*F L*Ninp sub L*Winp L*Ninp sub div 100 mul A*F B*F sgcolor } if %lab i*ptrsca 5 eq { %LAB L*F A*F B*F sgcolor } if %LAB i*ptrsca 6 eq {0 0 0 n'*w sgcmykcolor} if i*ptrsca 7 eq {1 n'*w sub sggray} if } def %END Procedure OLoutcmyn2: OL and output by setxy /setcmykcolor {%BEG Procedure setcymkcolor /black exch def /y*w exch def /m*w exch def /c*w exch def black 0 gt c*w abs 0.01 le and m*w abs 0.01 le and y*w abs 0.01 le and {/black7 black def /c*w black7 def /m*w black7 def /y*w black7 def /n*w 0 def} if /i*ptrsca i*ptrsc def OLoutcmyn1G %Procedure OLoutcmyn1G: OL and output by setxy OLoutcmyn2G %Procedure OLoutcmyn2G: OL and output by setxy /i*ptrsca i*ptrsc def } def %END Procedure setcymkcolor /setgray {%BEG Procedure exchange of setgray by setxy /black7 exch 1 exch sub def /c*w black7 def /m*w black7 def /y*w black7 def /n*w 0 def /i*ptrsca i*ptrsc def OLoutcmyn1G %Procedure OLoutcmyn1G: OL and output by setxy OLoutcmyn2G %Procedure OLoutcmyn2G: OL and output by setxy /i*ptrsca i*ptrsc def } def %END Procedure exchange of setgray by setxy /setrgbcolor {%BEG Procedure exchange setrgbcolor by setxy /v*n exch def /l*n exch def /o*n exch def /c*w 1 o*n sub def /m*w 1 l*n sub def /y*w 1 v*n sub def /n*w 0 def /i*ptrsca i*ptrsc def OLoutcmyn1G %Procedure OLoutcmyn1G: OL and output by setxy OLoutcmyn2G %Procedure OLoutcmyn2G: OL and output by setxy /i*ptrsca i*ptrsc def } def %END Procedure exchange setrgbcolor by setxy /setcolor {%BEG Procedure exchange of setcolor by setxy %input data definition /iLAB 0 def LAB*ioG %default: ISIN*ioG=0 input data: the Offset Reflective System (ORS) %default: ISOU*ioG=0 output data: the Offset Reflective System (ORS) LAB*io_to_cmyolv*ioG %produces allways n*w=0 /n*w exch def /y*w exch def /m*w exch def /c*w exch def c*w m*w y*w 0 /black exch def /y*w exch def /m*w exch def /c*w exch def /i*ptrsca i*ptrsc def OLoutcmyn1G %Procedure OLoutcmyn1G: OL and output by setxy OLoutcmyn2G %Procedure OLoutcmyn2G: OL and output by setxy /i*ptrsca i*ptrsc def } def %END exchange of setcolor by setxy %END NE83/10Q/Q83E00FP.PS Linearization data in the File (F) for the device (Y) %END NE83/10Q/OUTLIN1YFP.PS Output Linearization, coordinate transfer 20060101 %BEG NE83/10Q/OUTLIN1IFP.PS olv* image input and output Linearization 20060101 %adg_olv* image input linearisation; ad = analog-digital %three separate coordinates olv* %assumption: 128 data /adg_olv*' within image % = 20 .. 240 for o*, = 30.. 230 for l*, = 15 ... 220 for v*: unequal spacing %assumption: 128 data /adg_olv* of standard original % equal to inpadg_arrayS1 (0, 17, ..., 255): equal spacing %in the following there are example data for %16 achromatic and 16 CIE-test colours of Fig. B4 of ISO/IEC-test chart no. 2 %which are replaced by the image data of Fig. B1 of ISO/IEC-test chart no. 2 %adg_olv* , adg_cmy* input image data (normaly equal spacing in olv*, cmy*) %adg_olv*', adg_cmy*' output image data (unequal spacing in olv*, cmy*) %line 19, data: line 20-157 /adg_olv*' [ %Begin adg_olv*'; L=Linear model data 16 grey and 16 CIE-TC 00 0.0 0.0 0.0 %L 0.0000 olv*PR18/TV18 01 17.0 17.0 17.0 %L 0.0667 olv*PR18/TV18 02 34.0 34.0 34.0 %L 0.1333 olv*PR18/TV18 03 51.0 51.0 51.0 %L 0.2000 olv*PR18/TV18 04 68.0 68.0 68.0 %L 0.2667 olv*PR18/TV18 05 85.0 85.0 85.0 %L 0.3333 olv*PR18/TV18 06 102.0 102.0 102.0 %L 0.4000 olv*PR18/TV18 07 117.0 119.0 119.0 %L 0.4667 olv*PR18/TV18 08 136.0 136.0 136.0 %L 0.5333 olv*PR18/TV18 09 153.0 153.0 153.0 %L 0.6000 olv*PR18/TV18 10 170.0 170.0 170.0 %L 0.6667 olv*PR18/TV18 11 187.0 187.0 187.0 %L 0.7333 olv*PR18/TV18 12 204.0 204.0 204.0 %L 0.8000 olv*PR18/TV18 13 221.0 221.0 221.0 %L 0.8667 olv*PR18/TV18 14 238.0 238.0 238.0 %L 0.9333 olv*PR18/TV18 15 255.0 255.0 255.0 %L 1.0000 olv*PR18/TV18 16 184.2 117.1 134.5 %L no. 01 olv*PR18/CIETC 17 152.4 140.3 73.3 %L no. 02 olv*PR18/CIETC 18 122.3 189.6 31.5 %L no. 03 olv*PR18/CIETC 19 80.9 221.9 95.9 %L no. 04 olv*PR18/CIETC 20 89.6 203.0 174.5 %L no. 05 olv*PR18/CIETC 21 87.9 177.0 263.9 %L no. 06 olv*PR18/CIETC 22 130.2 124.4 284.1 %L no. 07 olv*PR18/CIETC 23 176.2 115.8 257.8 %L no. 08 olv*PR18/CIETC 24 205.8 -12.2 58.0 %L no. 09 olv*PR18/CIETC 25 231.9 212.4 34.8 %L no. 10 olv*PR18/CIETC 26 24.4 220.9 72.8 %L no. 11 olv*PR18/CIETC 27 -40.6 89.8 226.5 %L no. 12 olv*PR18/CIETC 28 237.1 186.9 166.5 %L no. 13 olv*PR18/CIETC 29 57.2 105.9 11.4 %L no. 14 olv*PR18/CIETC 30 0.0 0.0 0.0 %L 0.0000 olv*PR18/N 31 255.0 255.0 255.0 %L 1.0000 olv*PR18/W ] def %End adg_olv*' /adg_cmy*' [ %Begin adg_cmy*'; L=Linear model data 16 grey and 16 CIE-TC 00 255.0 255.0 255.0 %L 0.0000 cmy*PR18/TV18 01 238.0 238.0 238.0 %L 0.0667 cmy*PR18/TV18 02 221.0 221.0 221.0 %L 0.1333 cmy*PR18/TV18 03 204.0 204.0 204.0 %L 0.2000 cmy*PR18/TV18 04 187.0 187.0 187.0 %L 0.2667 cmy*PR18/TV18 05 170.0 170.0 170.0 %L 0.3333 cmy*PR18/TV18 06 153.0 153.0 153.0 %L 0.4000 cmy*PR18/TV18 07 136.0 136.0 136.0 %L 0.4667 cmy*PR18/TV18 08 117.0 119.0 119.0 %L 0.5333 cmy*PR18/TV18 09 102.0 102.0 102.0 %L 0.6000 cmy*PR18/TV18 10 85.0 85.0 85.0 %L 0.6667 cmy*PR18/TV18 11 68.0 68.0 68.0 %L 0.7333 cmy*PR18/TV18 12 51.0 51.0 51.0 %L 0.8000 cmy*PR18/TV18 13 34.0 34.0 34.0 %L 0.8667 cmy*PR18/TV18 14 17.0 17.0 17.0 %L 0.9333 cmy*PR18/TV18 15 0.0 0.0 0.0 %L 1.0000 cmy*PR18/TV18 16 70.8 137.9 120.5 %L no. 01 cmy*PR18/CIETC 17 102.6 114.7 181.7 %L no. 02 cmy*PR18/CIETC 18 132.7 65.4 223.5 %L no. 03 cmy*PR18/CIETC 19 174.1 33.1 159.1 %L no. 04 cmy*PR18/CIETC 20 165.4 52.0 80.5 %L no. 05 cmy*PR18/CIETC 21 167.1 78.0 -8.8 %L no. 06 cmy*PR18/CIETC 22 124.8 130.6 -29.0 %L no. 07 cmy*PR18/CIETC 23 78.8 139.2 -2.7 %L no. 08 cmy*PR18/CIETC 24 49.2 267.3 197.0 %L no. 09 cmy*PR18/CIETC 25 23.1 42.6 220.2 %L no. 10 cmy*PR18/CIETC 26 230.6 34.1 182.2 %L no. 11 cmy*PR18/CIETC 27 295.7 165.2 28.5 %L no. 12 cmy*PR18/CIETC 28 17.9 68.1 88.5 %L no. 13 cmy*PR18/CIETC 29 197.8 149.1 243.6 %L no. 14 cmy*PR18/CIETC 30 255.0 255.0 255.0 %L 1.0000 cmy*PR18/N 31 0.0 0.0 0.0 %L 0.0000 cmy*PR18/W ] def %End adg_cmy*' /adg_olv* [ %Begin adg_olv*; L=Linear model data 16 grey and 16 CIE-TC 00 0.0 0.0 0.0 %L 0.0000 olv*PR18/TV18 01 17.0 17.0 17.0 %L 0.0667 olv*PR18/TV18 02 34.0 34.0 34.0 %L 0.1333 olv*PR18/TV18 03 51.0 51.0 51.0 %L 0.2000 olv*PR18/TV18 04 68.0 68.0 68.0 %L 0.2667 olv*PR18/TV18 05 85.0 85.0 85.0 %L 0.3333 olv*PR18/TV18 06 102.0 102.0 102.0 %L 0.4000 olv*PR18/TV18 07 117.0 119.0 119.0 %L 0.4667 olv*PR18/TV18 08 136.0 136.0 136.0 %L 0.5333 olv*PR18/TV18 09 153.0 153.0 153.0 %L 0.6000 olv*PR18/TV18 10 170.0 170.0 170.0 %L 0.6667 olv*PR18/TV18 11 187.0 187.0 187.0 %L 0.7333 olv*PR18/TV18 12 204.0 204.0 204.0 %L 0.8000 olv*PR18/TV18 13 221.0 221.0 221.0 %L 0.8667 olv*PR18/TV18 14 238.0 238.0 238.0 %L 0.9333 olv*PR18/TV18 15 255.0 255.0 255.0 %L 1.0000 olv*PR18/TV18 16 184.2 117.1 134.5 %L no. 01 olv*PR18/CIETC 17 152.4 140.3 73.3 %L no. 02 olv*PR18/CIETC 18 122.3 189.6 31.5 %L no. 03 olv*PR18/CIETC 19 80.9 221.9 95.9 %L no. 04 olv*PR18/CIETC 20 89.6 203.0 174.5 %L no. 05 olv*PR18/CIETC 21 87.9 177.0 263.9 %L no. 06 olv*PR18/CIETC 22 130.2 124.4 284.1 %L no. 07 olv*PR18/CIETC 23 176.2 115.8 257.8 %L no. 08 olv*PR18/CIETC 24 205.8 -12.2 58.0 %L no. 09 olv*PR18/CIETC 25 231.9 212.4 34.8 %L no. 10 olv*PR18/CIETC 26 24.4 220.9 72.8 %L no. 11 olv*PR18/CIETC 27 -40.6 89.8 226.5 %L no. 12 olv*PR18/CIETC 28 237.1 186.9 166.5 %L no. 13 olv*PR18/CIETC 29 57.2 105.9 11.4 %L no. 14 olv*PR18/CIETC 30 0.0 0.0 0.0 %L 0.0000 olv*PR18/N 31 255.0 255.0 255.0 %L 1.0000 olv*PR18/W ] def %End adg_olv* /adg_cmy* [ %Begin adg_cmy*; L=Linear model data 16 grey and 16 CIE-TC 00 255.0 255.0 255.0 %L 0.0000 cmy*PR18/TV18 01 238.0 238.0 238.0 %L 0.0667 cmy*PR18/TV18 02 221.0 221.0 221.0 %L 0.1333 cmy*PR18/TV18 03 204.0 204.0 204.0 %L 0.2000 cmy*PR18/TV18 04 187.0 187.0 187.0 %L 0.2667 cmy*PR18/TV18 05 170.0 170.0 170.0 %L 0.3333 cmy*PR18/TV18 06 153.0 153.0 153.0 %L 0.4000 cmy*PR18/TV18 07 136.0 136.0 136.0 %L 0.4667 cmy*PR18/TV18 08 117.0 119.0 119.0 %L 0.5333 cmy*PR18/TV18 09 102.0 102.0 102.0 %L 0.6000 cmy*PR18/TV18 10 85.0 85.0 85.0 %L 0.6667 cmy*PR18/TV18 11 68.0 68.0 68.0 %L 0.7333 cmy*PR18/TV18 12 51.0 51.0 51.0 %L 0.8000 cmy*PR18/TV18 13 34.0 34.0 34.0 %L 0.8667 cmy*PR18/TV18 14 17.0 17.0 17.0 %L 0.9333 cmy*PR18/TV18 15 0.0 0.0 0.0 %L 1.0000 cmy*PR18/TV18 16 70.8 137.9 120.5 %L no. 01 cmy*PR18/CIETC 17 102.6 114.7 181.7 %L no. 02 cmy*PR18/CIETC 18 132.7 65.4 223.5 %L no. 03 cmy*PR18/CIETC 19 174.1 33.1 159.1 %L no. 04 cmy*PR18/CIETC 20 165.4 52.0 80.5 %L no. 05 cmy*PR18/CIETC 21 167.1 78.0 -8.8 %L no. 06 cmy*PR18/CIETC 22 124.8 130.6 -29.0 %L no. 07 cmy*PR18/CIETC 23 78.8 139.2 -2.7 %L no. 08 cmy*PR18/CIETC 24 49.2 267.3 197.0 %L no. 09 cmy*PR18/CIETC 25 23.1 42.6 220.2 %L no. 10 cmy*PR18/CIETC 26 230.6 34.1 182.2 %L no. 11 cmy*PR18/CIETC 27 295.7 165.2 28.5 %L no. 12 cmy*PR18/CIETC 28 17.9 68.1 88.5 %L no. 13 cmy*PR18/CIETC 29 197.8 149.1 243.6 %L no. 14 cmy*PR18/CIETC 30 255.0 255.0 255.0 %L 1.0000 cmy*PR18/N 31 0.0 0.0 0.0 %L 0.0000 cmy*PR18/W ] def %End adg_cmy* /inpadg_arrayS1 [0 17 34 51 68 85 102 119 136 153 170 187 204 221 238 255] bind def %adg_o* /L*NgS1o adg_olv*' 1 get 0.01 add def /L*WgS1o adg_olv*' 61 get 0.01 sub def /L*NS1o L*NgS1o def /L*WS1o L*WgS1o def /L*difo L*WS1o L*NS1o sub def % transferfo converts a decimal value between 0 and 1 to one between 8 and 120. /transferfo {L*NS1o sub L*difo div} bind def % The ioFunctiono uses the input and output arrays to determine % which value is needed inorder to achieve the desired 'color' at the output. /outadg_arrayS1o 16 array def /ioendo 0 def /ioFunctiono {%beg ioFunctiono ioendo 0 eq {%ioend=0 0 1 15 {/i exch def %i=0,15 outadg_arrayS1o i adg_olv*' i 4 mul 1 add get L*NS1o sub L*difo div put } for %i=0,15 /ioendo 1 def } if %ioend=0 % search the outadg_arrayS1 using a for loop 1 1 15 {/i exch def /previndex i 1 sub def outcolo outadg_arrayS1o i get lt outcolo outadg_arrayS1o previndex get ge and { /outmax outadg_arrayS1o i get def /inpmax inpadg_arrayS1 i get def /outmin outadg_arrayS1o previndex get def /inpmin inpadg_arrayS1 previndex get def exit } if } for % Use a linear interpolation /inpcolo outcolo outmin sub outmax outmin sub div inpmax inpmin sub mul inpmin add def } bind def %end ioFunctiono %adg_l* /L*NgS1l adg_olv*' 2 get 0.01 add def /L*WgS1l adg_olv*' 62 get 0.01 sub def /L*NS1l L*NgS1l def /L*WS1l L*WgS1l def /L*difl L*WS1l L*NS1l sub def % transferfl converts a decimal value between 0 and 1 to one between 8 and 120. /transferfl {L*NS1l sub L*difl div} bind def % The ioFunctionl uses the input and output arrays to determine % which value is needed inorder to achieve the desired 'color' at the output. /outadg_arrayS1l 16 array def /ioendl 0 def /ioFunctionl {%beg ioFunctionl ioendl 0 eq {%ioend=0 0 1 15 {/i exch def %i=0,15 outadg_arrayS1l i adg_olv*' i 4 mul 2 add get L*NS1l sub L*difl div put } for %i=0,15 /ioendl 1 def } if %ioend=0 % search the outadg_arrayS1 using a for loop 1 1 15 {/i exch def /previndex i 1 sub def outcoll outadg_arrayS1l i get lt outcoll outadg_arrayS1l previndex get ge and { /outmax outadg_arrayS1l i get def /inpmax inpadg_arrayS1 i get def /outmin outadg_arrayS1l previndex get def /inpmin inpadg_arrayS1 previndex get def exit } if } for % Use a linear interpolation /inpcoll outcoll outmin sub outmax outmin sub div inpmax inpmin sub mul inpmin add def } bind def %end ioFunctionl %adg_v* /L*NgS1v adg_olv*' 3 get 0.01 add def /L*WgS1v adg_olv*' 63 get 0.01 sub def /L*NS1v L*NgS1v def /L*WS1v L*WgS1v def /L*difv L*WS1v L*NS1v sub def % transferfv converts a decimal value between 0 and 1 to one between 8 and 120. /transferfv {L*NS1v sub L*difv div} bind def % The ioFunctionv uses the input and output arrays to determine % which value is needed inorder to achieve the desired 'color' at the output. /outadg_arrayS1v 16 array def /ioendv 0 def /ioFunctionv {%beg ioFunctionv ioendv 0 eq {%ioend=0 0 1 15 {/i exch def %i=0,15 outadg_arrayS1v i adg_olv*' i 4 mul 3 add get L*NS1v sub L*difv div put } for %i=0,15 /ioendv 1 def } if %ioend=0 % search the outadg_arrayS1 using a for loop 1 1 15 {/i exch def /previndex i 1 sub def outcolv outadg_arrayS1v i get lt outcolv outadg_arrayS1v previndex get ge and { /outmax outadg_arrayS1v i get def /inpmax inpadg_arrayS1 i get def /outmin outadg_arrayS1v previndex get def /inpmin inpadg_arrayS1 previndex get def exit } if } for % Use a linear interpolation /inpcolv outcolv outmin sub outmax outmin sub div inpmax inpmin sub mul inpmin add def } bind def %end ioFunctionv /prozo*g {/adg_ocolor exch 255 mul def adg_ocolor L*NS1o le {/adg_ocolor L*NS1o 0.01 add def} if adg_ocolor L*WS1o ge {/adg_ocolor L*WS1o 0.01 sub def} if /outcolo adg_ocolor transferfo def ioFunctiono inpcolo 255 div } bind def /prozl*g {/adg_lcolor exch 255 mul def adg_lcolor L*NS1l le {/adg_lcolor L*NS1l 0.01 add def} if adg_lcolor L*WS1l ge {/adg_lcolor L*WS1l 0.01 sub def} if /outcoll adg_lcolor transferfl def ioFunctionl inpcoll 255 div } bind def /prozv*g {/adg_vcolor exch 255 mul def adg_vcolor L*NS1v le {/adg_vcolor L*NS1v 0.01 add def} if adg_vcolor L*WS1v ge {/adg_vcolor L*WS1v 0.01 sub def} if /outcolv adg_vcolor transferfv def ioFunctionv inpcolv 255 div } bind def %allways olv* image; grey output like olv* / www* setrgbcolor /settransfer {/i*ptrsca 3 def /ntransfer exch def {ntransfer 112 transp} sgtransfer /i*ptrsca i*ptrsc def} def %assumption: in olv* image file l=local or g=global setcolortransfer %/adl_olv*' where {pop 0 1 127 {/iadg exch def % adg_olv*' iadg adl_olv*' iadg get put} for % } if %{ } { } { } { } setcolortransfer /setcolortransfer {/i*ptrsca 3 def /n*transfer exch def /v*transfer exch def /l*transfer exch def /o*transfer exch def {o*transfer 064 transp} {v*transfer 080 transp} {l*transfer 096 transp} {n*transfer 112 transp} sgtransfer /i*ptrsca i*ptrsc def} def %END NE83/10Q/OUTLIN1IFP.PS olv* image input and output Linearization 20060101