Digital sundial

There are two basic types of digital sundials. One type uses optical waveguides, while the other is inspired by fractal geometry.

Sunlight enters into the device through a slit and moves as the sun advances. The sun's rays shine on ten linearly distributed sockets of optical waveguides that transport the light to a seven-segment display. Each socket fiber is connected to a few segments forming the digit corresponding to the position of the sun.[http://www.hineslab.com/digital-sundial/ US patent 4782472 (1988) belonged to HinesLab Inc. (USA)] ({{patent|US|4782472}})

File:Digital sundial.jpg layer.]]

The theoretical basis for the other construction comes from fractal geometry.{{cite book

| last = Falconer

| first = Kenneth

| title = Fractal Geometry: Mathematical Foundations and Applications

| publisher = John Wiley & Sons, Ltd.

| year = 2003

| isbn = 0-470-84862-6

| no-pp = true

| page = xxv}} For the sake of simplicity, we describe a two-dimensional (planar) version. Let {{math|L{{sub|θ}}}} denote a straight line passing through the origin of a Cartesian coordinate system and making angle {{math|θ ∈ [0,π)}} with the {{math|x}}-axis. For any {{math|F ⊂ ℝ{{sup|2}}}} define {{math|proj{{sub|θ}} F}} to be the perpendicular projection of {{math|F}} on the line {{math|L{{sub|θ}}}}.

Let {{math|G{{sub|θ}} ⊂ L{{sub|θ}}}}, {{math|θ ∈ [0,π)}} be a family of any sets such that $\backslash bigcup\_\backslash theta$ {{math|G{{sub|θ}}}} is a measurable set in the plane. Then there exists a set {{math|F ⊂ ℝ{{sup|2}}}} such that

• {{math|G{{sub|θ}} ⊂ proj{{sub|θ}} F}};
• the measure of the set {{math|proj{{sub|θ}} F \ G{{sub|θ}}}} is zero for almost all {{math|θ ∈ [0,π)}}.

There exists a set with prescribed projections in almost all directions. This theorem can be generalized to three-dimensional space. For a non-trivial choice of the family {{math|G{{sub|θ}}}}, the set {{math|F}} described above is a fractal.

Theoretically, it is possible to build a set of masks that produce shadows in the form of digits, such that the display changes as the sun moves. This is the fractal sundial.

The theorem was proved in 1987 by Kenneth Falconer. Four years later it was described in Scientific American by Ian Stewart.Ian Stewart, Scientific American, 1991, pages 104-106, Mathematical Recreations -- What in heaven is a digital sundial?. The first prototype of a digital sundial was constructed in 1994; it writes the numbers with light instead of shadow, as Falconer proved. In 1998 a digital sundial was installed for the first time in a public place (Genk, Belgium).[http://www.fransmaes.nl/genk/welcome-e.htm Sundial park in Genk, Belgium] There exist window and tabletop versions as well.[http://www.digitalsundial.com/patent.html US and German patents belonged to Digital Sundials International] ({{patent|US|5590093}}, {{patent|DE|4431817}}) Julldozer in October 2015 published an open-source 3D printed model sundial.[http://www.mojoptix.com/2015/10/25/mojoptix-001-digital-sundial/ Mojoptix 001: Digital Sundial]

{{Reflist}}

Category:Sundials