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Color circles

Color Mixing. The various types of dye powders used to make dye stains are blended to achieve the desired color. Most finishers purchase wood stains premixed to specified colors. In the wood-finishing industry, various shades of brown are the most common. These colors are usually blended from primary colors. Color-matching skills can be acquired only by practice, but the basic theory of color matching is relatively simple and easily understood. The basic theory of color matching can be demonstrated by using the color circle shown in Figure 1 (see Color). [Pg.337]

Figure 8.1 The results of IHC of two experiments using Dynabeads (Dynal, New York, NY) coated with biotinylated anti-mouse IgG (first experiment) and protein S-100 (second experiment), (a) Positive control showing red color (S-100) localized in the melanoma cells, (b) Strong positive red color circles all beads coated with biotinylated anti-mouse antibody after the heating AR treatment (first experiment), (c) Using the heating AR treatment, S-100-coated polymer beads show positive red color around the beads as circles (second experiment), (d) Negative control of the first experiment. No red color could be seen for polymer beads (arrows) that had been treated with exactly the same protocol as that of slide (b), but omitting the avidin-biotin-peroxidase (label). Bar = 50pm. Reproduced with permission from Shi et al., J. Histochem. Cytochem. 2005 53 1167-1170. See color insert. Figure 8.1 The results of IHC of two experiments using Dynabeads (Dynal, New York, NY) coated with biotinylated anti-mouse IgG (first experiment) and protein S-100 (second experiment), (a) Positive control showing red color (S-100) localized in the melanoma cells, (b) Strong positive red color circles all beads coated with biotinylated anti-mouse antibody after the heating AR treatment (first experiment), (c) Using the heating AR treatment, S-100-coated polymer beads show positive red color around the beads as circles (second experiment), (d) Negative control of the first experiment. No red color could be seen for polymer beads (arrows) that had been treated with exactly the same protocol as that of slide (b), but omitting the avidin-biotin-peroxidase (label). Bar = 50pm. Reproduced with permission from Shi et al., J. Histochem. Cytochem. 2005 53 1167-1170. See color insert.
Figure 15-14 Solid colored circles show the drift in apparent pH of a low-conductivity industrial water supply measured continuously by a single electrode. Individual measurements with a freshly calibrated electrode (black circles) demonstrate that the pH is not drifting. Drift is attributed to slow clogging of the electrode s porous plug with AgCI(s). When a cation-exchange resin was placed inside the reference electrode near the porous plug, Ag(l) was bound by the resin and did not precipitate. This electrode gave the drift-free, continuous reading shown by open diamonds. [From S. Ho, H. Hachlya. K. Baba. Y. Asano. and H. Wada, Improvement of the Ag I AgCt Reference Electrode and Its Application to pH Measurement," talonta 1995,42.1685.]... Figure 15-14 Solid colored circles show the drift in apparent pH of a low-conductivity industrial water supply measured continuously by a single electrode. Individual measurements with a freshly calibrated electrode (black circles) demonstrate that the pH is not drifting. Drift is attributed to slow clogging of the electrode s porous plug with AgCI(s). When a cation-exchange resin was placed inside the reference electrode near the porous plug, Ag(l) was bound by the resin and did not precipitate. This electrode gave the drift-free, continuous reading shown by open diamonds. [From S. Ho, H. Hachlya. K. Baba. Y. Asano. and H. Wada, Improvement of the Ag I AgCt Reference Electrode and Its Application to pH Measurement," talonta 1995,42.1685.]...
Note that the matrix U simply rotates vectors that are already in the plane defined by u to a standard coordinate system. Figure 7.30 shows the data points of a color circle transformed... [Pg.182]

What were the primary colors in Moses Harris s color circle ... [Pg.35]

Just about a century after Newton, about 1766, Moses Harris (1731-1785), an English engraver and authority on insects, published the first known example of a color circle in full hue. This circle had primaries in red, yellow, and blue, and secondaries in orange, green, and purple (or violet). Harris began a tradition for color order that is favored in art and color education today. (See Figure 1.5.)... [Pg.35]

Fig-4 L a b color space (a) and color circle and hue angle (b) shown on an a b chro-maticity diagram... [Pg.351]

Figure 32.27. Comparison of the Amino Acid Sequences of the Green and Red Photoreceptors. Open circles correspond to identical residues, whereas colored circles mark residues that are different. The differences in the three black positions are responsible for most of the difference in their absorption spectra. Figure 32.27. Comparison of the Amino Acid Sequences of the Green and Red Photoreceptors. Open circles correspond to identical residues, whereas colored circles mark residues that are different. The differences in the three black positions are responsible for most of the difference in their absorption spectra.
Draw Figure 14-1, but instead of using colored circles to represent the solvent and solute molecules, use Lewis formulas to represent water as the solvent and acetone, CH3COCH3, as the solute. Use dashed hues to show hydrogen bonds. Twelve water molecules and two acetone molecules should be sufficient to illustrate the interaction between these two kinds of molecules. [Pg.1184]

Figu re n.6 Schematic diagrams for (a) point mapping and (b) DuoScan mapping the same area at the same step size. The colored circles represent materials of interest, (a) Small circles represent laser focus (b) Small squares represent pixels. [Pg.387]

Fig. 8.8-1 A sine wave with added noise (colored circles), its first derivative (black circles) and its second derivative (black triangles), calculated using a five-point quadratic. Noise amplitude used, from top to bottom 0,0.0003,0.001, and 0.003. Fig. 8.8-1 A sine wave with added noise (colored circles), its first derivative (black circles) and its second derivative (black triangles), calculated using a five-point quadratic. Noise amplitude used, from top to bottom 0,0.0003,0.001, and 0.003.
In Munsell s system, hues are specified in a circular fashion with the same set of hues on the same level. As the value, i.e.- "lightness", changes, one Jumps to the next highest circle. The amount of color "deepness" is specified as chroma and becomes less as one approaches the edge of each color circle. [Pg.545]

FIGURE 18-9 Raman spectrometer with fiber-optic probe. In (a) a microscope objective focuses the laser radiation onto excitation fibers that transport the beam to the sample. The Raman scattering is collected by emission fibers and carried to the entrance slit of a monochromator or to the entrance of an interferometer. A radiation transducer, such as a photomultiplier tube, converts the scattered light Intensity to a proportional current or pulse rate (b) end view of the probe (c) end view of collection libers at entrance slit of monochromator. The colored circles represent the input fiber and the uncoiored circles the collection fibers. (Adapted from R. L. McCreery. [Pg.490]

Figure 16.5 Computed (TDDFT/PBE38) Cg dispersion coefficients (in Bohr°) for the whole periodic table (up to Pu), which are used in the DFT-D3 method- For each element the free atom value (lower value, light colored circle) and the coefficient (upper value, darker color) for the atom in a saturated chemical environment (with the highest coordination number according to the DFT-D3 scheme, e.g., four for carbon and three... Figure 16.5 Computed (TDDFT/PBE38) Cg dispersion coefficients (in Bohr°) for the whole periodic table (up to Pu), which are used in the DFT-D3 method- For each element the free atom value (lower value, light colored circle) and the coefficient (upper value, darker color) for the atom in a saturated chemical environment (with the highest coordination number according to the DFT-D3 scheme, e.g., four for carbon and three...
Figure 2 Nitrosyl macrocyclic ruthenium complexes structure. (A) frans-[RuCI [15]ane4) NO] " and (B) frans-[RuCI cyclam)NO]. The colored circles represent atoms in the chemical structure (cyan (light gray in the print version) carbon blue (black in the print version) nitrogen green (gray in the print version) chlorine red (dark gray in the print version) oxygen white hydrogen, and gray ruthenium). Figure 2 Nitrosyl macrocyclic ruthenium complexes structure. (A) frans-[RuCI [15]ane4) NO] " and (B) frans-[RuCI cyclam)NO]. The colored circles represent atoms in the chemical structure (cyan (light gray in the print version) carbon blue (black in the print version) nitrogen green (gray in the print version) chlorine red (dark gray in the print version) oxygen white hydrogen, and gray ruthenium).
Here, the colored circles represent neurons that have fired, and the arrows represent excitatory connections between the neurons, with the direction of excitation (and time) being the direction of the arrow. As Paul and Hall (2013) note. In this diagram, C fires, sending signals to B and D, both of which fire E fires upon receiving the signal from D. B does not cause E. But in a sense, B is both necessary and sufficient for E from a suitable specification of the circumstances, together with the relevant laws, it follows that B fires when it does ifFE fires when it does (for B fires iff C fires, iff D fires, iff E fires). So this is a cause of dual-effects of a common cause (p. 71). [Pg.98]

FIGURE 1 A representative sample of color centers in alkali halide crystals. The large and small circles represent negative and positive ions, respectively. Colored circles represent alkali impurities. [Pg.50]

By convention, oxidation states are represented as -i-n and -n, but Ionic charges are represented as n+ and n-. We shall circle oxidation states associated with formulas and show them In colored circles indicating positive (blue), negative (red), or neutral (gray) oxidation states. Both oxidation states and ionic charges can be combined algebraically. [Pg.189]

Recall that oxidation states are indicated by numbers in colored circles (blue for positive oxidation states, red for negative oxidations states, and gray forO). [Pg.199]

A Draw Figure 14-1, but instead of using colored circles to represent the solvent and solute molecules, draw... [Pg.549]

Fig. 2.10 Color circles of the subtractive primaries (a) and the additive primaries (b). M.V. Oma... Fig. 2.10 Color circles of the subtractive primaries (a) and the additive primaries (b). M.V. Oma...

See other pages where Color circles is mentioned: [Pg.337]    [Pg.348]    [Pg.476]    [Pg.320]    [Pg.311]    [Pg.179]    [Pg.36]    [Pg.351]    [Pg.337]    [Pg.6]    [Pg.245]    [Pg.77]    [Pg.337]    [Pg.567]    [Pg.724]    [Pg.2]    [Pg.63]    [Pg.383]    [Pg.701]    [Pg.25]    [Pg.26]    [Pg.26]   
See also in sourсe #XX -- [ Pg.25 , Pg.26 ]




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