{ "title": { "media": { "url": "/controlled-visual-system/objects/controlled_visual_System_01_feature.png", "caption": "Controlled visual system diagram", "credit": "Controlled Visual Systems" }, "text": { "headline": "Controlled Visual Systems Timeline", "text": "CollectionBuilder-GH is a template for creating small digital collection exhibits on GitHub Pages designed for teaching digital library skills" } }, "events": [ { "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/controlled_visual_System_01_feature.png", "caption": "Controlled visual system diagram", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_001", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2026" }, "text": { "headline": "Controlled visual system diagram", "text": "Photograph of a white wall gallery with visual systems, theorists, and mathematics overlay" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/Foreword", "caption": "Foreword", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_002", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1905" }, "text": { "headline": "Foreword", "text": "Journal Article" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/Ireland-Labyrinth(DoubleHelix)-1969%20-%201993.jpg", "caption": "Labyrinth (Double Helix)", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_003", "credit": "Controlled Visual Systems" }, "start_date": { "month": " 1993", "day": "", "year": "1969 " }, "text": { "headline": "Labyrinth (Double Helix)", "text": "Photographer: Larry Qualls" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/Pi%20in%20the%20Mandelbrot%20set%20everywhere.pdf", "caption": "Pi in the Mandelbrot set everywhere", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_004", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2025" }, "text": { "headline": "Pi in the Mandelbrot set everywhere", "text": "The numerical phenomenon of appearing at parameters , and in the Mandelbrot set has been known for over 30 years. In 2001, the first proof was provided by Aaron Klebanoff for the parameter . Very recently in 2023, an even sharper result for was proved using holomorphic dynamics by Paul Siewert. This new proof also provided a conceptual understanding of the phenomenon. In this paper, we give, for the first time, a proof of the known phenomenon for the parameters and , which is also conceptual, and we provide a generalization of the phenomenon and the proof for all bifurcation points of the Mandelbrot set." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/large_haendel_320_themetimefruit_raw_800.jpg", "caption": "Karl Haendel – Theme Time – Fruit (drawing)", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_005", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2014" }, "text": { "headline": "Karl Haendel – Theme Time – Fruit (drawing)", "text": "Theme Time – Fruit, 2013. Tarpaper, matboard, pencil (35″x60″). Courtesy Susanne Vielmetter Los Angeles. (Photo by R. Wedemeyer); Haendel’s objective is to transform the stream of words, images, and brands that he encounters on a daily basis into a controlled visual system, or “Haendel language,” that he employs to explore timeless artistic themes through his own, twenty-first-century mode. " } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/install_pedestal.png", "caption": "cali-kurlan_iterative-sculpture-series_environmental-system", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_006", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2026" }, "text": { "headline": "cali-kurlan_iterative-sculpture-series_environmental-system" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/order_Feature.png", "caption": "Cali-kurlan_perception-system_installation_repetition-and-difference", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_007", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2026" }, "text": { "headline": "Cali-kurlan_perception-system_installation_repetition-and-difference", "text": "This series operates through a controlled digital system using the Photoshop stamp tool, where fragments of the white wall—light, shadow, and surface texture—are sampled and re-applied as a layered overlay. Sculpture emerges here as a perceptual effect rather than a physical object: forms are constructed through compositional placement on a pedestal, oscillating between presence and illusion. Each iteration produces a seemingly random variation, yet is generated through a repetitive, rule-bound process in which sampling and re-inscription create a continuous system of difference within constraint." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/overlay_01.png", "caption": "cali-kurlan-generative-object-form", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_008", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2026" }, "text": { "headline": "cali-kurlan-generative-object-form" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/ODoherty-Foreword-2011.pdf", "caption": "Brian O'Doherty Foreword-The White Cube", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_009", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2011" }, "text": { "headline": "Brian O'Doherty Foreword-The White Cube" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/film_Photogram.jpg", "caption": "Film photogram", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_010", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2019" }, "text": { "headline": "Film photogram", "text": "The photograms operate as a controlled visual system in which chance interactions of light and material produce variation within fixed constraints. Each image is bound to the dimensions and duration of a film frame, where degrees of transparency, shadow, and scale emerge through stochastic exposure while remaining structurally determined by the limits of the medium." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/226cd208-f147-4a7e-9583-0d95ab5738c7.png", "caption": "Mandelbrot set, drawn with own C program.", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_012", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2006" }, "text": { "headline": "Mandelbrot set, drawn with own C program.", "text": "Mandelbrot fractal (Image); It visualizes the classic fractal boundary of the Mandelbrot set, exemplifying “order; emerging from chaos” via infinite iteration. High – Direct primary fractal image, high-resolution, public domain\r\n. Accurately shows infinite-iteration structure (order/chaos) as queried." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/mandelbrot-fractal-16.width-990_NJfPq78.jpg", "caption": "A Radical Mind | NOVA | PBS", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_013", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1905" }, "text": { "headline": "A Radical Mind | NOVA | PBS" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/mandelbrot-fractal-11.width-990_SmcMrY7.jpg", "caption": "A Radical Mind | NOVA | PBS", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_014", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1905" }, "text": { "headline": "A Radical Mind | NOVA | PBS" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/Deleuze-ConcreteRulesAbstract-1984.pdf", "caption": "Concrete Rules and Abstract Machines", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_015", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1984" }, "text": { "headline": "Concrete Rules and Abstract Machines", "text": "A theoretical text by Gilles Deleuze and Félix Guattari outlining concepts of stratification, assemblages, and systems of organization, describing how structures of matter, meaning, and perception are formed, layered, and destabilized. An excerpt from A Thousand Plateaus introducing strata and assemblages as models for understanding how forms, meanings, and environments are constructed and transformed—serving as a conceptual framework for analyzing systems of display, control, and visual organization." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/PIA21971~large.jpg", "caption": "Jovian Tempest", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_017", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2017" }, "text": { "headline": "Jovian Tempest" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/enhanced_photogram_cali_kurlan_01.jpg", "caption": "cali-kurlan-analog-system-photogram-perception", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_018", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2017" }, "text": { "headline": "cali-kurlan-analog-system-photogram-perception", "text": "The photograms operate as a controlled visual system in which chance interactions of light and material produce variation within fixed constraints. Each image is bound to the dimensions and duration of a film frame, where degrees of transparency, shadow, and scale emerge through stochastic exposure while remaining structurally determined by the limits of the medium." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/photogram_film_cali_kurlan_02.jpg", "caption": "cali-kurlan-analog-system-photogram-perception", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_019", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2017" }, "text": { "headline": "cali-kurlan-analog-system-photogram-perception", "text": "The photograms operate as a controlled visual system in which chance interactions of light and material produce variation within fixed constraints. Each image is bound to the dimensions and duration of a film frame, where degrees of transparency, shadow, and scale emerge through stochastic exposure while remaining structurally determined by the limits of the medium." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/N00532_P_jmw_turner_painting.jpg", "caption": "Light and Colour (Goethe’s Theory) - the Morning after the Deluge - Moses Writing the Book of Genesis", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_020", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1843" }, "text": { "headline": "Light and Colour (Goethe’s Theory) - the Morning after the Deluge - Moses Writing the Book of Genesis", "text": "Light → Scientific Light: A painting like those produced by J. M. W. Turner around 1843 can be understood as an early analogue “controlled visual system,” in which light is not merely depicted but experimentally generated through layered color interactions. His use of atmospheric diffusion, spectral blending, and repeated gestural variation anticipates a quasi-scientific exploration of optics—where perception emerges from iterative manipulations of pigment, much like a bounded system producing endless visual variation through subtle shifts in parameters." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/N00531_P.jpg.1200x1200_q85.max-525x525_jmw_turner_painting.jpg", "caption": "Shade and Darkness - the Evening of the Deluge", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_021", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1843" }, "text": { "headline": "Shade and Darkness - the Evening of the Deluge", "text": "Light → Scientific Light: A painting like those produced by J. M. W. Turner around 1843 can be understood as an early analogue “controlled visual system,” in which light is not merely depicted but experimentally generated through layered color interactions. His use of atmospheric diffusion, spectral blending, and repeated gestural variation anticipates a quasi-scientific exploration of optics—where perception emerges from iterative manipulations of pigment, much like a bounded system producing endless visual variation through subtle shifts in parameters." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/photo-of-autumn-rhythm_jackson_pollock.jpg", "caption": "Autumn Rhythm (Number 30), Jackson Pollock (American, Cody, Wyoming 1912–1956 East Hampton, New York), Enamel on canvas\r\nDimensions: 8 ft. 10 1/4 in. × 17 ft. 4 in. × 2 5/8 in. (269.9 × 528.3 × 6.7 cm), Credit Line: George A. Hearn Fund, 1957, Object Number: 57.92", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_022", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1950" }, "text": { "headline": "Autumn Rhythm (Number 30), Jackson Pollock (American, Cody, Wyoming 1912–1956 East Hampton, New York), Enamel on canvas\r\nDimensions: 8 ft. 10 1/4 in. × 17 ft. 4 in. × 2 5/8 in. (269.9 × 528.3 × 6.7 cm), Credit Line: George A. Hearn Fund, 1957, Object Number: 57.92", "text": "Pollock stated, \"I can control the flow of paint: there is no accident.\"" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/man_ray_rayograph.jpg", "caption": "Untitled Rayograph (Kiki and Filmstrips)", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_023", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1922" }, "text": { "headline": "Untitled Rayograph (Kiki and Filmstrips)", "text": "Title\r\nRayograph\r\nArtist\r\nMan Ray\r\nDate\r\n1922\r\nMedium\r\nGelatin silver print\r\nDimensions\r\n9 3/8 × 7 in. (23.8 × 17.8 cm)\r\nCredit Line\r\nThe J. Paul Getty Museum, Los Angeles (84.XM.1000.173)\r\nObject No.\r\nMR.0089; The photograph gives the sense of filmstrips cascading from the top of the picture as if dropped by someone above. In the lower left-hand corner, a glass negative of Kiki appears to shatter as it hits the bottom of the composition. In this image, made the year he discovered the Rayograph technique, Man Ray symbolically discarded the more traditional methods of picture making represented by the filmstrips and glass negative." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/carter_p2008-2_o2_20_hy_hirsh.jpg", "caption": "Untitled", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_024", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1950" }, "text": { "headline": "Untitled", "text": "Object Type: Photographs\r\nMedium: Dye coupler print\r\nDimensions: 9 7/8 x 7 7/8 in.\r\nEdition: only known; Following World War I, light abstraction emerged as a central preoccupation of photographers and filmmakers who began using innovative methods of projecting, reflecting, and refracting rays of light to create non-traditional works of photographic art. (https://www.getty.edu/news/getty-presents-abstracted-light-experimental-photography/) " } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/installation-srgm-guggenheim-museum-art-of-this-century-dan-flavin-rotunda-1992-ph02-1024x576.jpg", "caption": "“The Guggenheim Museum and the Art of This Century” ", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_025", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1992" }, "text": { "headline": "“The Guggenheim Museum and the Art of This Century” ", "text": "The Guggenheim Museum and the Art of This Century” refers to a 1992 exhibition at the Solomon R. Guggenheim Museum that examined how the museum’s own history is intertwined with the radical artistic vision of Peggy Guggenheim’s Art of This Century gallery. The phrase signals a historical and conceptual link between:\r\n\r\nThe Guggenheim Museum (founded by Solomon R. Guggenheim and shaped by Hilla Rebay)\r\n\r\nArt of This Century (Peggy Guggenheim’s groundbreaking 1940s gallery that championed Surrealism and Abstract Expressionism)\r\n\r\nThe exhibition explored how these two institutions—both created by members of the Guggenheim family—helped define 20th‑century modern art, each in its own way. The exhibition positioned the Guggenheim not just as a museum of modern art, but as an institution shaped by the same experimental spirit that defined Peggy Guggenheim’s gallery." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/watts01.width-420_1Zmy1lb_stan_brakhage_tate_museum.jpg", "caption": null, "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_026", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2000" }, "text": { "headline": null, "text": "stills from The God of Day Had Gone Down Upon Him 2000,Stan Brakhage,2000,\"16mm film, 50min, colour, silent; pioneer of American visionary film Stan Brakhage made the silent 16mm The God of Day Had Gone Down Upon Him 2000. This work relishes varied oceanic light, dramatised by rhythmic camera movements and edits, attention to visual textures and forms, and their consequent moods" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/daniel_buren_eyestormworks.jpg", "caption": "The Eye of the Storm: works in situ ", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_027", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2005" }, "text": { "headline": "The Eye of the Storm: works in situ ", "text": " In Around the Corner, Buren transformed the way the Guggenheim building was seen through a site-specific, mirrored sculpture.; \"[The Guggenheim Museum] really kills a piece of art, primarily because it’s a work of art itself. —Daniel Buren\"" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/EyeStormworks-March%2025%20-%20June%208,%202005(1).jpg", "caption": "The Eye of the Storm: works in situ", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_028", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2005" }, "text": { "headline": "The Eye of the Storm: works in situ" } },{ "media": { "url": "https://www.youtube.com/watch?v=9MW8G_cBmQA", "caption": "Stellar Explosions and Jets Showcased in New Three Dimensional Visualizations", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_029", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2020" }, "text": { "headline": "Stellar Explosions and Jets Showcased in New Three Dimensional Visualizations", "text": "This visualization presents a six panel, a multi-object, three-dimensional representation of supernova remnants and stellar environments derived from Chandra X-ray Observatory data and computational modeling. The view is rich in structure: blebs, filaments, and hollow shells swirl in colors of orange, yellow, blue, red, and translucent gray, giving a sculptural sense of depth and layering. Some regions appear as spherical or shell-like cavities filled with hot gas, while others extend as wispy tendrils or protruding jets. Shadows and translucent layers allow an impression of internal geometry, as if one is viewing cross sections of cosmic debris fields. From upper left, clockwise, the objects include DGTau, Cassiopeia A, U Scorpii, Tycho's supernova remnant, Supernova 1987a and Supernova 1006. Overall, the image collection conveys the complexity and three-dimensional architecture of supernova remnants and their surrounding plasma, grounded in observational data rather than purely artistic abstraction." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/ma-459930-WEB_sol_lewitt_wall_drawing_.jpg", "caption": "Wall Drawing #295: Six Superimposed Geometric Figures", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_030", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1976" }, "text": { "headline": "Wall Drawing #295: Six Superimposed Geometric Figures", "text": "By the 1970s, Sol LeWitt had expanded his formal vocabulary (originally just a series of parallel, straight lines) to include geometric shapes. These were first limited to ‘primary shapes,’ which he defined as circle, square and triangle, but he soon added ‘secondary shapes,’ or rectangles, trapezoids, and parallelograms. Wall Drawing 295 depicts these six primary and secondary shapes. In the drawing the shapes are superimposed, or layered, within the square. This superimposition technique entered LeWitt’’s practice in his early line wall drawings; his wall drawings of the late 1960s and early 1970s consisted mostly of lines going in four basic directions (vertical, horizontal, diagonal left, and diagonal right.)These four types of lines were often layered on top of each other, allowing for more possibilities of line combinations and the creation of gradations in tone. In Wall Drawing 295, the draftsmen layer the shapes within the square, revealing structural commonalities. [https://massmoca.org/event/walldrawing295/] Purchased with matching funds from the National Endowment for the Arts and the Modern and Contemporary Art Council (M.76.103)" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/musical_score_variability_and_multiplicity.pdf", "caption": "Like a musical score: Variability and Multiplicity in Sol Lewitt's 1970s Wall Drawing", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_03", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2012" }, "text": { "headline": "Like a musical score: Variability and Multiplicity in Sol Lewitt's 1970s Wall Drawing", "text": "In Sol LeWitt’s wall drawings, seemingly open-ended or “random” visual outcomes are in fact governed by strict procedural systems—where “the idea becomes the machine that makes the art”—producing iterative, repeatable structures that behave like algorithmic sequences, comparable to fractal logics or the infinite, rule-based expansion of numbers like π. Each execution operates as a controlled variation within a bounded system (“like a musical score”), where multiplicity and difference emerge not from chance alone but from distributed authorship and rule-based permutations, generating endless series that mirror mathematical recursion and systematic growth." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/childress_butterfly_effect.jpg", "caption": "The Butterfly Effect on Baskets", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_032", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1992" }, "text": { "headline": "The Butterfly Effect on Baskets", "text": "arl Childress develops controlled visualization systems that translate fluid, quasi-random phenomena (e.g., smoke vortices and flow dynamics) into mapped, repeatable image structures through photography and computational modeling, producing works that appear chaotic but are generated through iterative, rule-based processes of capture, transformation, and reproduction. " } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/lorenz_attractor_graph_creenshot_8-4-2026_19555_.jpg", "caption": "The Lorenz attractor graph", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_033", "credit": "Controlled Visual Systems" }, "start_date": { "year": "1963" }, "text": { "headline": "The Lorenz attractor graph", "text": "Lorenz created his namesake graph by plotting the solutions to equations representing the movement of a heated gas. The linked oval-shaped figures resemble a butterfly's wings.; The weather model of meteorologist Edward LorenzThe x-, y-, and z-axes correspond to components of the weather, while the graph indicates feasible weather patterns. The graph is a function of time, which means, in theory, that tracing the curve in one direction reveals past weather patterns, while tracing the curve in the other direction predicts future weather patterns. However, practically indistinguishable points may lead to completely different weather epochs, indicated by the two distinct “lobes.” This phenomenon, known as sensitivity to initial conditions, is what prevents precise weather forecasts more than a few days into the future" } },{ "media": { "url": "https://www.youtube.com/watch?v=d0Z8wLLPNE0", "caption": "Double pendulum | Chaos | Butterfly effect | Computer simulation", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_034", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2017" }, "text": { "headline": "Double pendulum | Chaos | Butterfly effect | Computer simulation", "text": "A system is considered chaotic if it is highly sensitive on the initial conditions.\r\nIf a system is chaotic it doesn't mean that it is random. A chaotic system is completely deterministic. Given enough time and precise initial conditions of the system it would be possible to calculate precisely, how it will evolve. Given enough time, two identical setups, set to initial conditions that are as identical as possible, will look entirely different.Programs used: Cinema 4D (3D animation); Adobe Premiere Pro (Editing); Adobe Animate (Thumbnail)" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/damien-hirst-h5-4-claridges.jpg", "caption": "H5-4 Claridge's", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_035,,,,,,,,,,,,,,,,,,", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2018" }, "text": { "headline": "H5-4 Claridge's", "text": "This series of limited editions adhere to some of the formal rules established for the Spot Paintings, however, without the logic of the grid and the symmetry of the perfect circle. In comparison to the Spot Paintings these appear looser, more stochastic, and more open to incident. Here, Hirst’s imperfect discs overlap and jostle in a riot of colour, like so many particles under a microscope. Sold in original Heni packing in Mint condition. Please note these are sold on consignment." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/artemisiipath_screenshot_10-4-2026_191528_.jpeg", "caption": "Online, users can follow AROW to see where Orion and the Artemis II crew are in relation to the Earth and the Moon and follow Orion’s path during the mission.", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_036", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2026" }, "text": { "headline": "Online, users can follow AROW to see where Orion and the Artemis II crew are in relation to the Earth and the Moon and follow Orion’s path during the mission.", "text": "Online, users can follow AROW to see where Orion and the crew are in relation to the Earth and the Moon and follow Orion’s path during the mission. Users can view key mission milestones and characteristics on the Moon, including information about landing sites from the Apollo program. State vectors, or data that describes precisely where Orion is located and how it moves, also will be provided by AROW, following a proximity operations demonstration to evaluate the manual handling qualities of Orion. \r\n\r\nThese vectors can be used for data lovers, artists, and creatives to make their own tracking app or data visualization. Also available for download will be trajectory data from the flight, called an ephemeris, found at the bottom of this page, after the mission begins. The ephemeris data can be used to track Orion with your own spaceflight software application or telescope, or to create projects such as a physics model, animation, visualization, or tracking application.\r\n\r\nArtemis II, the agency’s first crewed mission in the Artemis campaign, is a key step in NASA’s path toward establishing a long-term presence at the Moon and confirming the systems needed to support future lunar surface exploration and paving the way for the first crewed mission to Mars. To learn more about NASA’s Artemis campaign, visit: https://www.nasa.gov/artemis\r\nThe mobile app includes similar features to the website, with the addition of augmented reality tracker. After a brief calibration sequence, on-screen indicators will direct users where to move their phone to see where Orion currently is relative to their position on Earth. Mobile app tracking will be available once Orion separates from the rocket’s upper stage, approximately three hours into the mission." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/artemisii_screenshot_10-4-2026_192328_.jpeg", "caption": "Artemis II Map", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_037", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2023" }, "text": { "headline": "Artemis II Map", "text": "Trajectory for Artemis II, NASA’s first flight with crew aboard SLS, Orion to pave the way for long-term return to the Moon, missions to Mars\r\nArtemis II will be the first flight with crew aboard NASA’s deep space exploration system: the Orion spacecraft, Space Launch System (SLS) rocket and the ground systems at Kennedy Space Center in Cape Canaveral, Florida. During their mission, four astronauts will confirm all of the spacecraft’s systems operate as designed with people aboard in the actual environment of deep space, over the course of about a 10-day mission. The Artemis II flight test will pave the way to land the first woman and next man on the Moon on Artemis III." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/artemisiii_screenshot_10-4-2026_192712_.jpeg", "caption": "Artemis III", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_038", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2027" }, "text": { "headline": "Artemis III", "text": "NASA's Artemis III mission in low Earth orbit will test integrated operations between the Orion spacecraft and one or both commercial landers from SpaceX and Blue Origin respectively." } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/chandraxrayobservatory_screenshot_11-4-2026_142516_.jpeg", "caption": "Where is Chandra is orbit?", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_039", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2026" }, "text": { "headline": "Where is Chandra is orbit?" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/glitch_art_cali_kurlan_.gif", "caption": "Glitch", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_041", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2026" }, "text": { "headline": "Glitch" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/installation-srgm-moholy-nagy-future-present-1.jpeg", "caption": "Moholy-Nagy: Future Present", "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_042", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2016" }, "text": { "headline": "Moholy-Nagy: Future Present", "text": "Installation view: László Moholy-Nagy, Dual Form with Chromium Rods, 1946" } },{ "media": { "url": "https://cdk-cloud-lab.github.io/controlled-visual-system/objects/Fine%20%20Arts%20%20on%20%20Film%20%20The%20%20Hand-Painted%20%20Work%20%20of%20Stan%20Brakhage", "caption": null, "link": "https://cdk-cloud-lab.github.io/controlled-visual-system/item.html?id=demo_043", "credit": "Controlled Visual Systems" }, "start_date": { "year": "2022" }, "text": { "headline": null, "text": "ABSTRACT This paper will approach the topic of color in cinema by examining the case of the hand-painted films made by experimental filmmaker Stan Brakhage. Specifically, I will present the example of some hand-colored pre-print elements belonging to the National Cinema Museum in Turin and preserved at the Haghefilm lab in Amsterdam in 2011. I will argue that these films challenge traditional understandings of cinema by belonging simultaneously to the realm of film and to that of the fine arts and will show the consequences of this liminal position both at a practical and a theoretical level. In particular, I will explore the challenges related to the preservation of some of these films, and will relate them to broader issues of originality, medium specificity, and philological recreation of experimental cinema practices." } } ] }