GMU:Habitats SS18/Physarum Polycephalum: Difference between revisions

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=== James Whitting, Ben De Lacy Costello, Andrew Adamatzky ===
=== James Whiting, Ben De Lacy Costello, Andrew Adamatzky ===
Sonification
Sonification


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3-5 min @ Heather Barnett: What humans can learn from semi-intelligent slime https://www.youtube.com/watch?v=2UxGrde1NDA
3-5 min @ Heather Barnett: What humans can learn from semi-intelligent slime https://www.youtube.com/watch?v=2UxGrde1NDA


==Physarum Polycefalum==
==Physarum Polycephalum==
“Slime mold is an informal name given to several kinds of unrelated eukaryotic organisms that can live freely as single cells, but aggregate together to form multicellular reproductive structures.”(Wikipedia a) Slime molds belong to Protista, that is neither animal, nor fungi nor bacteria. They feed on microorganisms. “When food is in short supply, many of these single-celled organisms will congregate and start moving as a single body. In this state they are sensitive to airborne chemicals and can detect food sources. They can readily change the shape and function of parts and may form stalks that produce fruiting bodies, releasing countless spores”(Wikipedia a)
“Slime mold is an informal name given to several kinds of unrelated eukaryotic organisms that can live freely as single cells, but aggregate together to form multicellular reproductive structures.”(Wikipedia a) Slime molds belong to Protista, that is neither animal, nor fungi nor bacteria. They feed on microorganisms. “When food is in short supply, many of these single-celled organisms will congregate and start moving as a single body. In this state they are sensitive to airborne chemicals and can detect food sources. They can readily change the shape and function of parts and may form stalks that produce fruiting bodies, releasing countless spores”(Wikipedia a)


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*1,7% agar plate
*1,7% agar plate
*oat flakes
*oat flakes
====Medium replacement====
Instead of oat flakes two other recipes: a) 2,5g agar, 200ml distilled water, 1,5g peptone (lactose) b) 1g agar, 5g cooked (for 2 min) oat flakes in 100ml water. Medium could be placed either on top of agar as droplets or instead of agar.


==Unconventional Computing and Physarum Machine ==
==Unconventional Computing and Physarum Machine ==
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* [http://arxiv.org/pdf/cs/0703128.pdf Implementation of a Kolmogorov–Uspensky machine on a biological substrate. (Adamatzky 2007)]
* [http://arxiv.org/pdf/cs/0703128.pdf Implementation of a Kolmogorov–Uspensky machine on a biological substrate. (Adamatzky 2007)]
* [http://arxiv.org/pdf/0901.4556v1.pdf Programmable reconfiguration of Physarum machines (Adamatzky 2009)]
* [http://arxiv.org/pdf/0901.4556v1.pdf Programmable reconfiguration of Physarum machines (Adamatzky 2009)]
=== Computable Discrete Elements in the Turing Machine ===
In a 1936 paper by Turing, the concept of the machine is proposed as the simple idea of an apparatus which is able to compute discrete values – zeros and ones. In the same paper, Turing introduces a computing machine with an infinite length of tape and a tape head acting upon seven commands: a) read the tape, b) move the tape left, c) move tape right, d) write “zero” on the tape, e) write “one” on the tape, f) jump to another command, and g) halt. The idea of these commands is to show that output B could be processed having an initial state and some input A. The position of the tape head on the proposed apparatus processing the information is dependent on the information stored on the tape: If the input information is defined, so is the output. The problem in such a computational model is any numerically undefined variable which would cause the machine to stop processing information, or to "halt." The halting state or, according to Turing, the “decision problem" (Enscheidungsproblem) is the problem of digital computation being defined by numerical variables. Thus, the Turing machine is limited to computing all input information and to solving all given problems (Turing 1936).
Turing Machines: https://www.youtube.com/watch?v=gJQTFhkhwPA
=== Markov chain ===
"A Markov chain (discrete-time Markov chain or DTMC[1]), named after Andrey Markov, is a random process that undergoes transitions from one state to another on a state space. It must possess a property that is usually characterized as "memorylessness": the probability distribution of the next state depends only on the current state and not on the sequence of events that preceded it. This specific kind of "memorylessness" is called the Markov property. Markov chains have many applications as statistical models of real-world processes."(wikipedia (b))
=== Kolmogorov Machine ===
"Kolmogorov, or Kolmogorov-Uspensky, machines [Ko1, KU, US] are similar to Turing machines except that the tape can change its topology."(Gurevich) Also, as far as I understand, Kolmogorov Machine isn't described by discrete 0 and 1 values. Also its functions could be updated in real time over the recursive method. On the other hand both Turing Machine and Kolmogorov machine, could emulate each other, so at the end the difference is just in the way how the machines compute their functions.
"Мы остановимся на следующих вариантах математического опреде­ ления вычислимой функции или алгоритма:
A) Определение вычислимой функции как функции, значения которой выводимы в некотором логическом исчислении (Гёдель [4], Чёрч [5]1)). Б) Определение вычислимой функции как функции, значения кото­
рой получаются при помощи исчисления Х-коиверсии Чёрча [5], [7].
B) Определение вычислимой функции как функции частично-рекур­ сивной (см. работу Клини [8])2) или —для случая всюду определенной функции —как общерекурсивной (Клини [10]). (Термины «частично-рекур­ сивная» и «общерекурсивная» понимаются здесь в смысле приложения I).
Г) Вычислительная машина Тьюринга [ И ] 3 ) .
Д) Финитный комбинаторный процесс Поста [13].
Е) Нормальный алгорифм А. А. Маркова [1], [2]." (Колмогоров & Успенский 1958)
"Kolmogorov machines tape similarly to Schönhage’s tape is a finite connected graph with a distinguished (active) node. They work upon partly recursive function, changing instructions in real time." (Gurevich)
"Instructions:
*1. add a new node together with a pair of edges of some colors between the active node and the new one,
*2. remove a node and the edges incident to it,
*3. add a pair of edges of some colors between two existing nodes,
*4. remove the two edges between two existing nodes,
*5. halt. "(Gurevich)
"Grigoriev [Gr] exhibited a function real-time computable by some KU machine but not real-time computable by any Turing machine."(Gurevich)


== References ==
== References ==
* Whiting, J. (2013) "Towards slime mould chemical sensor: Mapping chemical inputs onto electrical potential dynamics of Physarum Polycephalum." Available at https://arxiv.org/pdf/1312.4189.pdf (Accessed: 25 April 2018)
* Whiting, J. (2013). "Towards slime mould chemical sensor: Mapping chemical inputs onto electrical potential dynamics of Physarum Polycephalum." Available at https://arxiv.org/pdf/1312.4189.pdf (Accessed: 25 April 2018)
* Wikipedia (a). Slime mold. Available at: https://en.wikipedia.org/wiki/Slime_mold (Accessed 6 December 2016).
* Wikipedia (a). Slime mold. Available at: https://en.wikipedia.org/wiki/Slime_mold (Accessed 6 December 2016).
* Wikipedia (b). Physarum polycephalum. Available at: https://en.wikipedia.org/wiki/Physarum_polycephalum (Accessed 8 December 2015).
* Wikipedia (b). Physarum polycephalum. Available at: https://en.wikipedia.org/wiki/Physarum_polycephalum (Accessed 8 December 2015).

Latest revision as of 00:35, 8 February 2019

Gallery

Related Projects

Theresa Schubert

bodymetries, 2013

“In bodymetries visitors can experience virtual slime mould growth on their skin. Visitors enter a semi dark room with a bar table in the center. Some wobbling blobs appear on a small sections of the surface. Visitors are invited to lay their arms onto the desk. The system ‘scans’ it by taking and analysing a picture. The slime mould algorithm starts to grow from the darkest area it can find on the skin.”(http://theresaschubert.com/arts-experiments/art/bodymetries-mapping-the-human-body-through-amorphous-intelligence)


James Whiting, Ben De Lacy Costello, Andrew Adamatzky

Sonification

Towards slime mould chemical sensor: Mapping chemical inputs onto electrical potential dynamics of Physarum Polycephalum Sensors and Actuators B: Chemical. response to BenzylAlcohol https://www.youtube.com/watch?v=byTJEYHaIIM https://soundcloud.com/lessnullvoid/physarum-sonification

Toshiyuki Nakagaki

Experiments with Physarum polycefalum finding the shortest way to the food source through the maze

3-5 min @ Heather Barnett: What humans can learn from semi-intelligent slime https://www.youtube.com/watch?v=2UxGrde1NDA

Physarum Polycephalum

“Slime mold is an informal name given to several kinds of unrelated eukaryotic organisms that can live freely as single cells, but aggregate together to form multicellular reproductive structures.”(Wikipedia a) Slime molds belong to Protista, that is neither animal, nor fungi nor bacteria. They feed on microorganisms. “When food is in short supply, many of these single-celled organisms will congregate and start moving as a single body. In this state they are sensitive to airborne chemicals and can detect food sources. They can readily change the shape and function of parts and may form stalks that produce fruiting bodies, releasing countless spores”(Wikipedia a)

"Physarum polycephalum, literally the "many-headed slime", is a slime mold that inhabits shady, cool, moist areas, such as decaying leaves and logs. Like slime molds in general, it is sensitive to light; in particular, light can repel the slime mold and be a factor in triggering spore growth."(wikipedia b) It feeds on bacteria, spores and other microbial creatures.

chemotaxis

"..In the plasmodial phase of its life cycle consists of a large single celled mass of yellow plasmodium. The organism extends protoplasmic tubes which grow towards sources of food; flowing through these tubes is a cytoplasm, which oscillates back and forth by a process of protoplasmic streaming which forces the cytoplasm in the direction in which the organism is growing [1]. The movement and growth of P. polycephalum is predominantly controlled by favourable conditions, such as an abundance of food, warm temperature, darkness and moisture. It has been well documented that various substances trigger a chemotactic response in P. polycephalum, various carbohydrates such as glucose and maltose initiate positive chemotaxis while sucrose shows marginal but consistent negative chemotaxis [2, 3, 4, 5]." (Whiting 2013)

life cycle

  • Vegetative phase: plasmodium (consists of networks of protoplasmic veins, and many nuclei)
  • sclerotium (hardened multinucleated tissue)
  • sporangia

Medium

  • 1,7% agar plate
  • oat flakes

Medium replacement

Instead of oat flakes two other recipes: a) 2,5g agar, 200ml distilled water, 1,5g peptone (lactose) b) 1g agar, 5g cooked (for 2 min) oat flakes in 100ml water. Medium could be placed either on top of agar as droplets or instead of agar.

Unconventional Computing and Physarum Machine

"Unconventional computing is an interdisciplinary branch of science where computer scientists, physicists, mathematicians, apply principles of information processing in natural systems to design novel computer devices and architectures" (Adamatzky 2007)

“The plasmodium functions as a parallel amorphous computer with parallel inputs and parallel outputs. Data are represented by spatial configurations of sources of nutrients. A program of computation is coded via configurations of repellents and attractants. Results of computation are presented by the configuration of the protoplasmic network and the localisation of the plasmodium.”(Adamatzky 2010)

“.. plasmodium is unique biological substrate that mimics universal storage modification machines, namely the Kolmogorov-Uspensky machine. In the plasmodium implementation of the storage modification machine data are represented by sources of nutrients and memory structure by protoplasmic tubes connecting the sources. In laboratory experiments and simulation we demonstrate how the plasmodium-based storage modification machine can be programmed.”(Adamatzky & Jones 2009)

Implementations

References

Other References (Unconventional Computing and Physarum Machines)