[vc_row][vc_column][ish_headline tag_size=”h3″ color=”color7″ icon_align=”left” tag=”h” tooltip_color=”color1″]Let the colors bring light into your life[/ish_headline][ish_image image=”2469″ size=”theme-half” tooltip_color=”color1″ align=”left”][vc_column_text]Most light sources are mixtures of various wavelengths of light. Many such sources can still effectively produce a spectral color, as the eye cannot distinguish them from single-wavelength sources. For example, most computer displays reproduce the spectral color orange as a combination of red and green light; it appears orange because the red and green are mixed in the right proportions to allow the eye’s cones to respond the way they do to the spectral color orange.[/vc_column_text][vc_column_text]A useful concept in understanding the perceived color of a non-monochromatic light source is the dominant wavelength, which identifies the single wavelength of light that produces a sensation most similar to the light source. Dominant wavelength is roughly akin to hue.[/vc_column_text][vc_column_text]There are many color perceptions that by definition cannot be pure spectral colors due to desaturation or because they are purples (mixtures of red and violet light, from opposite ends of the spectrum). Some examples of necessarily non-spectral colors are the achromatic colors (black, gray, and white) and colors such as pink, tan, and magenta.[/vc_column_text][vc_column_text]Two different light spectra that have the same effect on the three color receptors in the human eye will be perceived as the same color. They are metamers of that color. This is exemplified by the white light emitted by fluorescent lamps, which typically has a spectrum of a few narrow bands, while daylight has a continuous spectrum. The human eye cannot tell the difference between such light spectra just by looking into the light source, although reflected colors from objects can look different. (This is often exploited; for example, to make fruit or tomatoes look more intensely red.)[/vc_column_text][/vc_column][/vc_row][vc_row][vc_column width=”1/1″][ish_headline tag_size=”h3″ color=”color7″ icon_align=”left” tag=”h” tooltip_color=”color1″]Human Color Perceptions[/ish_headline][ish_tabs color=”color7″ text_color=”color4″ layout=”vertical-right” tooltip_color=”color1″ vertical_layout=”3-1″ contents_color=”color13″ contents_text_color=”color1″][ish_tab tab_title=”Light Sources” icon_align=”left” tooltip_color=”color1″][vc_row_inner][vc_column_inner width=”1/1″][vc_column_text]Most light sources are mixtures of various wavelengths of light. Many such sources can still effectively produce a spectral color, as the eye cannot distinguish them from single-wavelength sources. For example, most computer displays reproduce the spectral color orange as a combination of red and green light; it appears orange because the red and green are mixed in the right proportions to allow the eye’s cones to respond the way they do to the spectral color orange.[/vc_column_text][/vc_column_inner][/vc_row_inner][/ish_tab][ish_tab tab_title=”Color Perceptions” icon_align=”left” tooltip_color=”color1″][vc_row_inner][vc_column_inner width=”1/1″][vc_column_text]Similarly, most human color perceptions can be generated by a mixture of three colors called primaries. This is used to reproduce color scenes in photography, printing, television, and other media. There are a number of methods or color spaces for specifying a color in terms of three particular primary colors. Each method has its advantages and disadvantages depending on the particular application.[/vc_column_text][/vc_column_inner][/vc_row_inner][/ish_tab][ish_tab tab_title=”Color Response” icon_align=”left” tooltip_color=”color1″][vc_row_inner][vc_column_inner width=”1/1″][vc_column_text]The different color response of different devices can be problematic if not properly managed. For color information stored and transferred in digital form, color management techniques, such as those based on ICC profiles, can help to avoid distortions of the reproduced colors.[/vc_column_text][/vc_column_inner][/vc_row_inner][/ish_tab][/ish_tabs][/vc_column][/vc_row][vc_row][vc_column width=”1/1″][vc_column_text]Similarly, most human color perceptions can be generated by a mixture of three colors called primaries. This is used to reproduce color scenes in photography, printing, television, and other media. There are a number of methods or color spaces for specifying a color in terms of three particular primary colors. Each method has its advantages and disadvantages depending on the particular application.[/vc_column_text][ish_headline tag_size=”h3″ color=”color7″ icon_align=”left” tag=”h” tooltip_color=”color1″]Mixing colors[/ish_headline][vc_column_text]No mixture of colors, however, can produce a response truly identical to that of a spectral color, although one can get close, especially for the longer wavelengths, where the CIE 1931 color space chromaticity diagram has a nearly straight edge. For example, mixing green light (530 nm) and blue light (460 nm) produces cyan light that is slightly desaturated, because response of the red color receptor would be greater to the green and blue light in the mixture than it would be to a pure cyan light at 485 nm that has the same intensity as the mixture of blue and green.[/vc_column_text][vc_column_text]Because of this, and because the primaries in color printing systems generally are not pure themselves, the colors reproduced are never perfectly saturated spectral colors, and so spectral colors cannot be matched exactly. However, natural scenes rarely contain fully saturated colors, thus such scenes can usually be approximated well by these systems. The range of colors that can be reproduced with a given color reproduction system is called the gamut. The CIE chromaticity diagram can be used to describe the gamut.[/vc_column_text][/vc_column][/vc_row][vc_row][vc_column width=”1/1″][ish_headline tag_size=”h3″ color=”color7″ icon_align=”left” tag=”h” tooltip_color=”color1″]Problems with color reproduction[/ish_headline][/vc_column][/vc_row][vc_row][vc_column width=”1/1″][vc_column_text]Another problem with color reproduction systems is connected with the acquisition devices, like cameras or scanners. The characteristics of the color sensors in the devices are often very far from the characteristics of the receptors in the human eye. In effect, acquisition of colors can be relatively poor if they have special, often very “jagged”, spectra caused for example by unusual lighting of the photographed scene. A color reproduction system “tuned” to a human with normal color vision may give very inaccurate results for other observers.[/vc_column_text][vc_row_inner][vc_column_inner width=”1/3″][ish_skills skill_color=”color6″ tooltip_color=”color1″ text_color=”color3″][ish_skill percent=”90″ tooltip_color=”color1″]Color Sensors[/ish_skill][ish_skill percent=”75″ tooltip_color=”color1″]ICC Profiles[/ish_skill][/ish_skills][/vc_column_inner][vc_column_inner width=”2/3″][vc_column_text]The different color response of different devices can be problematic if not properly managed. For color information stored and transferred in digital form, color management techniques, such as those based on ICC profiles, can help to avoid distortions of the reproduced colors. Color management does not circumvent the gamut limitations of particular output devices, but can assist in finding good mapping of input colors into the gamut that can be reproduced.[/vc_column_text][/vc_column_inner][/vc_row_inner][vc_column_text]Structural colors are colors caused by interference effects rather than by pigments. Color effects are produced when a material is scored with fine parallel lines, formed of one or more parallel thin layers, or otherwise composed of microstructures on the scale of the color’s wavelength. If the microstructures are spaced randomly, light of shorter wavelengths will be scattered preferentially to produce Tyndall effect colors: the blue of the sky (Rayleigh scattering, caused by structures much smaller than the wavelength of light, in this case air molecules), the luster of opals, and the blue of human irises. If the microstructures are aligned in arrays, for example the array of pits in a CD, they behave as a diffraction grating: the grating reflects different wavelengths in different directions due to interference phenomena, separating mixed “white” light into light of different wavelengths. If the structure is one or more thin layers then it will reflect some wavelengths and transmit others, depending on the layers’ thickness.[/vc_column_text][vc_column_text]Structural color is studied in the field of thin-film optics. A layman’s term that describes particularly the most ordered or the most changeable structural colors is iridescence. Structural color is responsible for the blues and greens of the feathers of many birds (the blue jay, for example), as well as certain butterfly wings and beetle shells. Variations in the pattern’s spacing often give rise to an iridescent effect, as seen in peacock feathers, soap bubbles, films of oil, and mother of pearl, because the reflected color depends upon the viewing angle. Numerous scientists have carried out research in butterfly wings and beetle shells, including Isaac Newton and Robert Hooke. Since 1942, electron micrography has been used, advancing the development of products that exploit structural color, such as “photonic” cosmetics.[/vc_column_text][/vc_column][/vc_row]
Time Off
TIME OFF IN THE NATURE
[vc_row][vc_column width=”1/1″][ish_blog_media tooltip_color=”color1″][vc_column_text]Yosemite is one of the largest and least fragmented habitat blocks in the Sierra Nevada, and the park supports a diversity of plants and animals. The park has an elevation range from 2,127 to 13,114 feet (648 to 3,997 m) and contains five major vegetation zones: chaparral/oak woodland, lower montane forest, upper montane forest, subalpine zone, and alpine. Of California’s 7,000 plant species, about 50% occur in the Sierra Nevada and more than 20% within Yosemite. There is suitable habitat or documentation for more than 160 rare plants in the park, with rare local geologic formations and unique soils characterizing the restricted ranges many of these plants occupy.[/vc_column_text][ish_headline tag_size=”h2″ color=”color8″ icon_align=”left” tag=”h” tooltip_color=”color1″]Yosemite Directions[/ish_headline][ish_map zoom=”10″ tooltip_color=”color1″][ish_location lat_lng=”37.745203, -119.598221″ title=”Location Title” color=”color8″ text_color=”color4″ headline=”Yosemite” tooltip_color=”color1″]Yosemite National Park[/ish_location][/ish_map][vc_column_text]The geology of the Yosemite area is characterized by granitic rocks and remnants of older rock. About 10 million years ago, the Sierra Nevada was uplifted and then tilted to form its relatively gentle western slopes and the more dramatic eastern slopes. The uplift increased the steepness of stream and river beds, resulting in formation of deep, narrow canyons. About 1 million years ago, snow and ice accumulated, forming glaciers at the higher alpine meadows that moved down the river valleys. Ice thickness in Yosemite Valley may have reached 4,000 feet (1,200 m) during the early glacial episode. The downslope movement of the ice masses cut and sculpted the U-shaped valley that attracts so many visitors to its scenic vistas today.[/vc_column_text][vc_column_text]This video is a collaboration between Sheldon Neill and Colin Delehanty. All timelapses were shot on the Canon 5D Mark II with a variety of Canon L and Zeiss CP.2 Lenses. Thanks to Dynamic Perception for their motion controlled dolly and continued support![/vc_column_text][ish_headline tag_size=”h2″ color=”color8″ icon_align=”left” tag=”h” tooltip_color=”color1″]Outdoor Activities in Yosemite[/ish_headline][vc_column_text]The administration of Yosemite National Park was transferred to the newly formed National Park Service in 1916, when W. B. Lewis was appointed as the park’s superintendent. Parsons Memorial Lodge and Tioga Pass Road, along with campgrounds at Tenaya and Merced lakes, were completed the same year; six hundred automobiles entered the east side of the park using Tioga Road that summer. The “All-Weather Highway” (now State Route 140) opened in 1926, ensuring year-long visitation and delivery of supplies under normal conditions. Completion of the 0.8-mile (1.3 km)-long Wawona Tunnel in 1933 significantly reduced travel time to Yosemite Valley from Wawona. The famous Tunnel View is on the valley side of the tunnel and Old Inspiration Point is above it. A flood, reduced lumber and mining extraction, and greatly increased automobile and bus use forced the Yosemite Valley Railway out of business in 1945. The present day Tioga Road, now part of California State Route 120, was dedicated in 1961.[/vc_column_text][ish_skills color=”color13″ skill_color=”color8″ text_color=”color4″ tooltip_color=”color1″][ish_skill percent=”75″ tooltip_color=”color1″]Camping[/ish_skill][ish_skill percent=”95″ tooltip_color=”color1″]Climbing[/ish_skill][ish_skill percent=”55″ tooltip_color=”color1″]Family Trips[/ish_skill][ish_skill percent=”85″ tooltip_color=”color1″]Hiking[/ish_skill][/ish_skills][vc_column_text]Interpretive programs and services for national parks were pioneered in Yosemite by Harold C. Bryant and Loye Holmes Miller in 1920. Ansel F. Hall became the first park naturalist in 1921 and served in that role for two years. Hall’s idea to have park museums act as public contact centers for interpretive programs became a model followed by other national parks in the United States and internationally. Yosemite Museum, the first permanent museum in the National Park System, was completed in 1926.[/vc_column_text][vc_column_text]The Ahwahnee Hotel, in Yosemite Valley, is a National Historic Landmark. Built in 1927, it is a luxury hotel designed by the architect Gilbert Stanley Underwood, decorated in Native American motifs. For many years it hosted an annual pageant produced by Ansel Adams. During World War II it was used as a rehabilitation hospital for soldiers.[/vc_column_text][/vc_column][/vc_row][vc_row][vc_column width=”1/2″][ish_embed tooltip_color=”color1″]http://vimeo.com/92688138[/ish_embed][/vc_column][vc_column width=”1/2″][ish_embed tooltip_color=”color1″]http://vimeo.com/40319099[/ish_embed][/vc_column][/vc_row][vc_row][vc_column width=”1/1″][vc_column_text]This whole project has been an amazing experience. The two of us became friends through Vimeo and explored a shared interest in timelapsing Yosemite National Park over an extended period of time. We’d like to expand this idea to other locations and would appreciate any suggestions for a future project.[/vc_column_text][vc_column_text]Our hearts go out to the families of Markus Praxmarer who lost his life while climbing Half Dome on September 19th, 2011 and Ranger Ryan Hiller, who was crushed by a tree January 22nd 2012. They will be missed. (A photo of Ranger Ryan Hiller can be found to the right, above the statistics counter)[/vc_column_text][/vc_column][/vc_row]