Printing standardization trial for high-‐‑‒definition printing method utilizing Staccato-‐‑‒10 micron dots
1
Dr. SHIMIZU, HirokazuVice-‐‑‒President, WILL-‐‑‒POWER CONSULTING INC.
President, SHIMIZU PRINTING INC.Visiting Senior Researcher, Waseda University Environmental Research Institute
Expert, ISO TC130 (Graphic technology) WG11(Environmental impact of graphic technology)
Agenda
1.Purpose of printing analysis
2.High-‐‑‒definition printing method
3.Kodakʼ’s printing analyzer “ColorFlow”
4.Analysis of printing condition in practice
5.Summary
2
1. Purpose of printing analysis
3
✦Installation of “ColorFlow” (Kodak) for analysis1. Color-‐‑‒matching for Japan Color Standard •Ultimate goal is adaption for Japan Color which is compatible with ISO12647
2.Color-‐‑‒matching for Direct Digital Color Proof•Create color profile for DDCP to be checked as first proof to avoid printing proof by press
3.Color-‐‑‒matching for different presses•Secondary goal is perfect alignment of presses in our factory and other partner factories
2.High-‐‑‒definition printing method
4
✦Advanced screening tech. for high-‐‑‒end printingStaccato screening (high-‐‑‒definition)Kodak Staccato is advanced, second-‐‑‒order FM screening technology. Staccato screening produces high-‐‑‒fidelity, continuous tone images that exhibit fine detail and an extended color gamut, creating a photographic experience free of visible printing artifacts, such as subject moire and rosettes.(Reference: http://graphics.kodak.co.jp/KodakGCG/uploadedFiles/Products/Color_̲and_̲Screening/Staccato_̲Screening/Staccato%20Brochure%20ENG.pdf)
The angle and frequency of half tone dots in conventional AM screens can cause subject moire, screening moire and unstable rosette structures. Additionally, fewer and larger minimum dot sizes in highlights and shadows in AM screens can result in loss of detail and increase in graininess.(Reference: http://graphics.kodak.co.jp/KodakGCG/uploadedFiles/Products/Color_̲and_̲Screening/Staccato_̲Screening/Staccato%20Brochure%20ENG.pdf)
Normal AM screen
2.High-‐‑‒definition printing method
5
✦Advanced screening tech. for high-‐‑‒end printing
Staccato FM screeningNormal AM screening
2.High-‐‑‒definition printing method
6
✦Advanced screening tech. for high-‐‑‒end printing
175lpi (normal screening) printed by other printer
Staccato 10-‐‑‒micron screen printed by Shimizu Printing
Cyan 20%
Cyan 50%
Cyan 20%
Cyan 50%
2.High-‐‑‒definition printing method
7
✦Printing dots by electronic microscope
XX-‐‑‒XX by XXXXXXXX Sword XD by Kodak
175lpi
FM 10-‐‑‒micron FM 10-‐‑‒micron
175lpi
SQUA
RESPOT IMAG
ING technology can surge head
of com
petitors in term
s of printing dot q
uality
8
✦Color-‐‑‒chart analysis by “ColorFlow” 3.Kodakʼ’s printing analyzer “ColorFlow”
9
✦Color-‐‑‒chart analysis by “ColorFlow” 3.Kodakʼ’s printing analyzer “ColorFlow”
10
✦Configurations of presses at Shimizu Printing
R710-‐‑‒F_̲SP
R710-‐‑‒R_̲SP R707_̲SP R705_̲SP DDCP_̲SP
Primary Color
Output
Secondary Color
Output
3.Kodakʼ’s printing analyzer “ColorFlow”
Color-‐‑‒match among presses
Color-‐‑‒match between presses and DDCP
11
✦Basic knowledge about “color”
Magenta
Cyan
Yellow
Green
Red
Blue
a+(0〜~100)
a-‐‑‒(0〜~-‐‑‒100)
b+(0〜~100)
b-‐‑‒(0〜~-‐‑‒100)
4.Analysis of printing condition (contʼ’d)
12
✦Basic knowledge about “color”4.Analysis of printing condition (contʼ’d)
a+(0〜~100)
a-‐‑‒(0〜~-‐‑‒100)
b+(0〜~100)
b-‐‑‒(0〜~-‐‑‒100)
13
✦Printing condition and target to be achievedCompany Shimizu Printing (SP)
Press manroland R710 TLVP (40-‐‑‒inch, 10-‐‑‒color, +coating unit, +perfector)
Screening FM screening (10-‐‑‒micron)
Substrate OK Topcoat (coated paper, 127.9gsm)
Plate Kodak Sword XD+ (Made in Japan)
Ink Toyo ink (UV)
Dampening Nikken Astro Mark-‐‑‒3 (No IPA)
Target Lab value JapanColor<dE5 and ISO12647-‐‑‒2<dE5
Target dot gain 50%=14%+-‐‑‒1%, 20%/80%=9%+-‐‑‒1%
4.Analysis of printing condition (contʼ’d)
4.Analysis of printing condition (contʼ’d)
14
✦Absolute density of solid inks
SP
Avg. Min. Max. Dif. Dif./Avg.
K 1.74 1.71 1.76 0.05 2.9%
C 1.51 1.48 1.55 0.07 4.6%
M 1.41 1.37 1.45 0.08 5.7%
Y 1.02 1.00 1.05 0.05 4.9%
✦Absolute density of solid inks4.Analysis of printing condition (contʼ’d)
15
0.901.051.201.351.501.651.80
SP-‐‑‒K
Min. Max.
0.901.051.201.351.501.65
1.80
SP-‐‑‒C
Min. Max.
0.901.051.201.351.501.65
1.80
SP-‐‑‒M
Min. Max.
0.901.051.201.351.50
1.65
1.80
SP-‐‑‒Y
Min. Max.
Range of difference should be as minimum as possible
✦Variations of solid density4.Analysis of printing condition (contʼ’d)
16Variations of solid patches across the press sheet_̲SP
Color density of all colorsare within allowable range
✦Apparent Trap Density (%)4.Analysis of printing condition (contʼ’d)
17
SP
Target color
C
M
Y
Apparent Trap density 67.5% 74.2% 62.1%
A bit lower than expected values
✦Tonal value increase (dot gain) for all inks4.Analysis of printing condition (contʼ’d)
18
Cyyan Mageenta Yelllow Blaack
Measured value Dot gain Measured
value Dot gain Measured value Dot gain Measured
value Dot gain
5.0 8.0 3.0 7.4 2.4 7.3 2.3 8.2 3.210.0 15.4 5.4 14.6 4.6 14.5 4.5 15.9 5.915.0 22.3 7.3 21.7 6.7 21.4 6.4 23.1 8.120.0 28.9 8.9 28.5 8.5 28.1 8.1 29.9 9.925.0 35.1 10.1 35.1 10.1 34.6 9.6 36.4 11.430.0 41.1 11.1 41.4 11.4 40.9 10.9 42.7 12.735.0 46.9 11.9 47.5 12.5 46.9 11.9 48.7 13.740.0 52.5 12.5 53.3 13.3 52.7 12.7 54.4 14.445.0 57.9 12.9 58.8 13.8 58.3 13.3 59.9 14.950.0 63.1 13.1 64.0 14.0 63.7 13.7 65.2 15.255.0 68.0 13.0 68.9 13.9 68.8 13.8 70.1 15.160.0 72.7 12.7 73.4 13.4 73.7 13.7 74.6 14.665.0 77.1 12.1 77.7 12.7 78.3 13.3 78.8 13.870.0 81.2 11.2 81.7 11.7 82.7 12.7 82.7 12.775.0 85.1 10.1 85.3 10.3 86.8 11.8 86.2 11.280.0 88.6 8.6 88.7 8.7 90.5 10.5 89.3 9.385.0 91.8 6.8 91.8 6.8 93.8 8.8 92.2 7.290.0 94.7 4.7 94.7 4.7 96.6 6.6 94.8 4.895.0 97.5 2.5 97.4 2.4 98.7 3.7 97.4 2.4
✦Tonal value increase for all inks
4.Analysis of printing condition (contʼ’d)
19
Tonal value increase (TVI)_̲SP
Dot gains of all colors are fairly consistent
Tonal value increase %
Tint %
✦Spider plot of primary and overprint patches4.Analysis of printing condition (contʼ’d)
20Spider plots for key colors_̲SP
Differen
ce of M
Y an
d C ca
nnot be
adjusted
since
targ
et is
prin
ted by
175
lpi
✦Measured solid and overprints colors
4.Analysis of printing condition (contʼ’d)
21
Measured items SP
Average color difference (dE) of all patches in the chart 2.9
Max. Single color difference among all patches 7.0
Color difference between substrates 1.1
Average color difference between the primary solids 3.9
✦Color dif. distribution & cumulative frequency 4.Analysis of printing condition (contʼ’d)
22Color difference distributions/cumulative frequencies_̲SP
dE<5=91.9%
✦CIELAB measured values
4.Analysis of printing condition (contʼ’d)
23
Target SPSP
L a b C h L a b C h dE
Paper 94.1 0.5 -‐‑‒1.3 1.4 289.9 93.2 0.7 -‐‑‒0.7 1.0 311.5 1.1
3-‐‑‒C 25% Gray 75.6 0.2 -‐‑‒1.6 1.6 275.9 75.8 -‐‑‒0.5 -‐‑‒3.5 3.5 261.4 2.0
3-‐‑‒C 50% Gray 57.7 -‐‑‒1.0 -‐‑‒2.4 2.7 247.0 58.1 0.0 -‐‑‒3.1 3.1 269.1 1.2
3-‐‑‒C 75% Gray 39.5 -‐‑‒1.4 -‐‑‒1.1 1.8 218.7 41.3 -‐‑‒2.5 -‐‑‒5.0 5.6 243.8 4.4
3-‐‑‒C 100% Bk 20.9 -‐‑‒3.0 -‐‑‒3.5 4.6 229.5 21.7 -‐‑‒3.0 -‐‑‒6.3 6.9 244.3 2.9
100% Bk 16.6 1.6 2.7 3.1 58.2 14.4 1.6 0.5 1.7 16.6 3.1
All dEs are lower than 5.0
✦Gray balance, complete tonal range4.Analysis of printing condition (contʼ’d)
24
Gray balance_̲SP
Trap density % of Y influence in negative way
✦Gamut chart plots4.Analysis of printing condition (contʼ’d)
25
Gam
ut chart plots_̲SP
In fact, m
uch wider gam
ut is expected than actual value
26
5.Summary
✦Importance of printing quality analysis1. Continuous printing quality analysis•Periodical check for DDCP and printed sheet will be continued for all devices and presses
2.Continuous educational program •Empower experts in quality assurance team by continuous evaluation of printing condition
3.Continuous assistance by suppliers•Supported by Japanese printing materials (UV ink/varnish, Plates, Dampening solution, blankets)
27
Personal profileDr. Hirokazu Shimizu holds Doctorate in environmental impact assessment from Waseda University Graduate School of Environment and Energy Engineering (Japan), MBA in marketing research from University of Dallas (USA) and Bachelor of education from Waseda University (Japan). In 2012, Dr. Shimizu was assigned to be visiting senior researcher at his old school and play active role not only in business scene, but also in academic world.
Qualification:• Specialization in UV curing technology for graphics• Specialization in Life-‐‑‒cycle approach (LCA, LCC) for printing• Pioneering achievement:• Development of “UV Waterless High-‐‑‒definition Printing method” for paper and plastic• Schematization of “Printing service LCA” in the viewpoint of LCCO2 and Integrated LCAAward:• “UV Waterless High-‐‑‒definition Printing method”, Encouraging prize from Japanese Society of Printing Science and Technology in 2011• “Establishment of quantitative assessment for Printing Service”, Best paper from Japanese Society of Printing Science and Technology in 2010• “Establishment of Printing Service LCA to propose environmental-‐‑‒conscious solution”, Chairmanʼ’s award (2nd best) from 6th LCA Japan Forum in
2010Extra activities:• Visiting Senior Researcher, Waseda University Environmental Research Institute• Expert, ISO 130 (Graphic technology) WG11 (Environmental impact of graphics technology)• Committee, Energy Supply and Demand Verification Committee at Ministry of Economy, Trade and Industry• Policy adviser for SMEs, Japan Chamber of Commerce• Committee, Energy and Nuclear Committee at Japan Chamber of Commerce• Committee, Environment Committee at Tokyo Chamber of CommerceAcademic paper:• Hirokazu Shimizu, Katsuya Nagata, and Aran Hansuebsai. 2012. Comparisons of Paper-‐‑‒book and E-‐‑‒book by the scale of carbon footprint.
Proceedings of The Asian Symposium on Printing Technology: 39-‐‑‒44• Hirokazu Shimizu, Katsuya Nagata, and Aran Hansuebsai. 2011. Integrated Life cycle Assessment (LCA) for Printing Service in an emerging
country. Proceedings of EcoDesign 2011 International Symposium: 283-‐‑‒288• Hirokazu Shimizu, and Katsuya Nagata. 2010. Integrated Life cycle Assessment (LCA) Approach for Printing Service by Using Environmental Load
Point (ELP) Method. Journal of Printing Science and Technology 47 (3): 39-‐‑‒47• Hirokazu Shimizu, and Katsuya Nagata. 2010. Comparison of Life-‐‑‒cycle CO2 emissions for Paper-‐‑‒Based Books and Electronic Books. Journal of
Printing Science and Technology 47 (2): 19-‐‑‒29• Hirokazu Shimizu. 2009. Establishment of quantitative assessment for Printing Service. Journal of Printing Science and Technology 46 (6): 26-‐‑‒35
28
Thank you very much for your attention
You can have a look at part of presentation file:http://www.slideshare.net/ShimizuHiro/edit_̲my_̲uploads
Corporate web site:http://www.shzpp.co.jp
http://www.will-‐‑‒power.jp/en/