ADS:A Journal Week 05 Carl Madsen 357577
OBSERVING THE OPTIONS
A STUDY IN MOIRE
_05
After our analysis on the matrix of definitions in Grasshopper and looking into the perspective differences created by overlapping surfaces and their potential to satisfy our design intent, we deemed them very similar to a moiré pattern. A moiré pattern is an interference pattern that is created when two or more grids of lines (be them curved or straight) are overlaid in a non-regular fashion. This can be achieved through different shapes of lines (for example, a grid of circles overlapping a grid of straight lines), different mesh sizes or the rotation of one of the grids. The pattern is created at the intersections of the lines, where they appear thicker due to the higher density in the area. Such intersections form patterns with neighbouring intersections, creating a virtual line through the grids. The moiré effect (which creates the patterns) is typically an undesired effect of digitally created or altered images, but can also be used to advantages; it can be both a positive and negative effect, crafted or unwanted. Seemingly merely a visual phenomenon created by the juxtaposition of two patterned elements, a fair amount of mathematics is involved (differing throughout the shapes being patterned), reflecting the iconic direction approach we are looking to achieve with our design. Although the effect is visible on two unmoving grids, its more interesting qualities come from one or both of those two grids moving. However, with spacing between the two patterns, the eye moving shifts the panels relative to the viewer, recreating the effect on a still structure. This allows for a dynamic moiré pattern to be structured into the construction, changing the pattern it produces as the perspective differs (through both the relative speed and location of the viewer to the sculpture), resulting in a sculpture that is fast, directive, dynamic and experiential in design. One important factor to note is that if there is to be a space between the two grid elements that form the moiré pattern, then the perspective of the viewer could potentially change the initial pattern. That is, the lines further away from the viewer would appear smaller due to them being further away, when in reality they are actually the same size as the ones closer to the viewer. This could change the pattern away from what is desired, unless it is duly accounted for.
To start our experimentations with moirÊ patterning, we again instituted a breadth approach by creating a matrix of patterns that showcased some basic elements and how they interact with each other through changing variables. We didn’t just look at the shapes of the interacting lines, but also the thickness, angle and how far apart they were spaced. Once again we selected certain resulting patterns that both satisfied and avoided our design intent, critiquing them for further investigation.
thick lines into thick lines basic open/close, like shutters same width = full open, full close
thin lines into thick lines semi close/semi open never fully closed, never fully open, thinner lines moving between thicker
thin spaced lines into thick lines same as thin into thick, but with intermittent breaks
thin spaced lines into thin spaced lines open/close but with a large amount of time spent open as gap is larger relative to line thickness
thick lines into thick circles creates a repeating “opening� sector pattern perpendicular to the interfering lines thin lines into thick circles same deal, but pattern is much less pronounced as there is always a gap between the two geometries
15 degree thick lines into thick circles same as first circle pattern, but a bit slower as lines take longer to be placed in the same spot (at same horizontal speed)
45 degree thick lines into thick circles same same but slower once again
thick circles into thick circles
thin circles into thck circles
creates “opening” pattern in centre, reverberates around entire combined geometry
“opening” pattern not visible, but shapes made from the gaps are very pronounced
thin circles into thin circles same as first but hyper mode (faster, more, etc)
thin spaced circles into thin spaced circles same deal with lines, still there but little interference
128 line radial into same crazy intricate patterns all over the shop
64 line radial into same less patterns, but clearer
32 line radial into same
thin spaced circle into 16 line radial
again less patterns, too many to be pronounced it seems
some patterning, trumped by the difference in geometries
Our initial generalised views were that lines that were similar (but not necessarily an exact) thickness and distance apart seemed to produce more pronounced patterns within themselves, whilst lines that were exceedingly different thicknesses and distances apart had patterns that were very vague and hardly noticeable; on a high-speed highway these light patterns would be overlooked and lost. Rotation of lines into lines The rotation of a set of lines into a similar set of lines shows the shrinking of the moirĂŠ lines into themselves as the angle of rotation between the grids increases (or the stretching of lines as the angle decreases). Although an interesting concept, the rotation of one grid without the other cannot be plausibly achieved in a static structure. Lines into circles The introduction of a set of lines into a set of circles creates a very interesting opening/closing effect that runs horizontally against the vertical lines, matching the flow of the highway. The speed at which the moirĂŠ lines open and close is determined by the speed at which the grids pass each other (represented by the speed at which the motorist travels). Lines into lines The movement of lines between lines created a very simplistic shutter-like opening and closing, which we determined to although have relevance to the vectorial (created by speed and direction) qualities we were looking to achieve, its pattern was too basic and uninteresting to be developed beyond that. Radials in general Lines arranged in a radial fashion superimposing on each other produced very intricate and omnidirectional curves in their boundaries, but this effect was overshadowed by the extreme clutter that developed at their centres. This clutter looks out of place in relation to the cleanliness of the surrounding ellipses to the point where it almost overshadows the moirĂŠ pattern created, resulting in a very undesirable connection.
DEFINING A TYPE
A STUDY IN MOIRE
_05
Based on the horizontal directional and easily distinguishable patterning qualities of the moiré effect created by the juxtaposition of a group of circles of varying radii with a grid of lines moving into them, we decided to have a more in-depth look at why this particular effect is created, and what the altering of variables within it produces, finding some very interesting. Based on a pre-existing paper Research on the Moiré fringes formed by circular and linear grating (Chen et al 2011), we discerned that the spacing of the lines played an important role in the moiré patterning visible between circles and lines. A succinct summary of the paper is the focus on two variables, P and a, where P is the distance between the circles and a is the distance between the parallel lines (summarised visually below). Three distinct shapes were realised when changing the variable P (the distance between the parallel lines) against a static a. When the ratio P/a was greater than 1 (that is, when P > a), ellipses formed horizontally along the grids. When the ratio P/a was equal to 1 (that is, when P = a), parabolas formed, focusing to the centre of the circle. When the ratio P/a was less than 1 (that is, when P < a), hyperbolas formed, focusing to the centre of the circle. However, when the ratio P/a became too far away from 1, the patterns became difficult to distinguish, resulting in the need to care for the distances. This radical change in moiré patterning based solely on the distance between parallel lines prompted us to develop a parametric definition in Rhino3D and Grasshopper that would allow us greater control over the variables involved and the outcomes produced.
The definition we created in Grasshopper had six useful variables: P, the distance between the centres of the parallel lines, a, the distance between the centres of the circular lines, the thickness of the parallel lines, the thickness of the circular lines, the number of parallel lines and the number of circular lines. This enabled us to quickly test a large number of various iterations of the created patterns in real time by merely moving a slider. On reflection of the potential issue (brought up in the introduction to the moiré effect) that due to the viewer’s distance from each grid of lines they would see a different pattern than what was intended on a flat surface, our experimentation with the moiré grasshopper definition presented an exceptionally exciting solution. We noticed that as the parallel lines became closer together (that is, as P decreased); the moiré pattern would quickly turn from ellipses into parabolas. However, with calculated spacing between the parallel lines and the circular lines, the viewer’s perspective of how many parallel lines were attributed to how many circular lines would be relative to their position. Somebody standing on the side of the parallel lines would see many circular lines for every parallel line, as the circular lines would be further away, appearing smaller to the viewer in relation to the parallel lines. However, somebody standing on the side of the circular lines would see the opposite; more parallel lines for every circular line. With sensitive variables such as P and a, this effect compounds into a viewer on the circular side seeing hyperbolas, whilst at the same time a viewer on the parallel line side seeing ellipses. The way these two moiré patterns change as the viewer moves across horizontally relates perfectly into changing views depending on whether or not the sculpture is viewed coming into the city, or whether they are leaving the city. The sharpness of the moving hyperbolas would relate the driver coming into the fast-paced nature of Melbourne city, whereas opening ellipses would give a softer feeling, ideal for somebody travelling away from the commotion of the city. To visualise this idea, we rendered perspective views of the two different sides of the concept in Rhino, showing the dramatic change that occurs just by being on the other side of the sculpture.