Echolocation

This is my ultrasonic sensor, during the first days of the radar residency i have been doing some experiments with this to find out how it works – essentially i am hoping to use it as a way of creating a human echo-locating device. essentially it seems that this measures the distance between an ultra-sound pulse and its echo. we connected this up to a oscilloscope to see how obstacles looked in terms of the sound reflection…

Apparently, Shrews are the only terrestrial mammals known to echo-locate [and the Tenrecs of Madagascar]. The shrews emit series of ultrasonic squeaks.

“Human echolocation is the ability of humans to sense objects in their environment by hearing echoes from those objects. This ability is used by some blind people to navigate within their environment. They actively create sounds, such as by tapping their canes or by making clicking noises with their mouths. Human echolocation is similar in principle to active sonar and to the animal echolocation employed by some animals, including bats and dolphins….Some blind people have described the phenomenon not as a learned method of navigation, but as an inherent and intuitive extra sense. For example, a blind person could walk past a line of trees and feel a “pressure” at their side as they passed each tree. The cause of this would be the echo of the sound of their footsteps; however, they may not consciously be aware of this mechanism, only that the phenomenon exists and can often be relied upon to detect obstacles.”

Pauls experiment investigates how dolphins detect sound using the jaw bone – this box has metal rods inside in a line [aproximatly representing the allignment of teeth in a jawbone] – so as the sound wave travels through the channel, the rods act as a filtering device – or at least that is the hypothesis [very briefly]. Apparently dolphins use their jawbone as a way of honing in on the direction of certain sounds.

Experiment with electric fish

Here are some of the latest images from the Enki project…

The main view of the experiment chamber. The Enki installation at Cornerhouse is now up and running. There are experiments by appointment every 15mins, and all the data is being collected.

It has taken me ages to make these comms units, they contain16 interconnecting cables within a noise reducing or shielded structure.

The Table has two monitors one from the fish room and one from the human room. You can speak to the person in the experiment via a mic.

Inside the sound proofed room for the human there is a chair and the sensor interface.

There is a window into the fish room on the side of the chamber

The room containing the fish is electrically shielded.

Neuro stimulation

For a while i have been looking at Michael Persinger God helmet experiment, I think the discussion around this experiment was really interesting, and for me has been an opportunity to investigate the realm of psychology further. I got in touch with him to ask some questions about the technology and the experimental process. I decided to make a modified version of the god helmet to work with my Enki interface. here is a view Inside the neuro-stimulation device there are 4 coils which oscillate with magnetic frequencies, i have been using MAX MSP to drive these using electrical pulses. The magnetic coils are fitted to an elastic band which fits over the head, to the back of the head is a junction box, and the two coil arrays sit at the side of the head near the temporal lobes.

Vampyroteuthis “vampire squid from hell” – Planet Earth

air ray

Been doing some reserch into creating my own ROV type aquatic robot – found these excellent projects by FESTO a german company

Also there is an Air Jelly…
“FESTO AirJelly http://www.festo.com/cms/de_de/5890.htm This new concept of a jelly fish that flies through the air has been presented by Festo at the 2008 Hannover Messe in Germany. Please read out blogpost http://airshipworld.blogspot.com/2008/04/let-jelly-fish-…”

Forgotten nematode experiment

Rummaging through boxes in my studio i found a lunch box containing the nematode culture my sister gave me for Christmas. It was an unusual present – a tub of yellowish slime smelling of vinegar. These nematodes feed on yeast. The growth medium is porridge oats and a bit of yeast to get it going.

The microscopic worms form tree like patterns as they creep up the sides of the container; writhing masses of worms form super highways; (branches) either to escape the saturated lower regions of the culture or in seeking of new food – i dont know yet. these branchlets seem to persist for quite a while.

I mixed up 3 cultures to with varying amounts of oats and yeast and water unfortunately i lost my notes and forgot about this since Christmas. I was pleasantly surprised to see that they were still fermenting & wriggling away in this tub with excellent results…

The original Tub showed stubby branches which did not go very high in the container. (originally these branches spread all over the inner surfaces) worms were still invisible.

Tub A and C pictured below..
Nematodes form into evenly spaces spots, clusters of tiny worms, around the inner surface. The worms are less than 1mm long but fairly active – in tub C the worms are inactive and form faint irregular branchings

Tub B
Had very active complex branchings, and the worms had grown to about 2mm!
There is an interesting dynamic with the movement.

In the film (which was made in a bit of a rush) you will notice that when the worm moves across free space & meets another worm they move against each other the seem temporarily magnetize to each other & sometimes to deflect trajectories. This has to be partly to do with capillary build up of liquids around the worms bodies. Perhaps it is easier to collectively amass to hold fluid together, perhaps making it easier to move and feed. I plan to do some time lapse of this…

Tardigrades In Space (TARDIS)

A few years back I was trying to extract Tardigrades (Moss bear or Water piglet!)from old moss specimens at Manchester Museum – as it is reported that these animals can survive in a dehydrated state for over a hundred years. These are microscopic extremophiles that live in moss. I had no luck – but did find a multitude of other interesting microscopic artifacts. last night I found out that a satalite has been launched carrying a team of elite tardinauts into space to see if they are able to survive the solar radiation. “They also are resistant to levels of X-ray radiation that are hundreds of times more lethal to humans and other organisms. This resilience stems from the tardigrade’s ability to survive without water. ” If anything can survive the extreme conditions of open space – it will be Tardigrades- follow the link to this site to find out more…

Tardigrades In Space (TARDIS)

Tardigrades In Space or “TARDIS” is the first research project to evaluate the ability of tardigrades to survive under open space conditions. TARDIS is one of the projects within the Biopan-6 research platform provided by European Space Agency (ESA), and will be sent into space with the russian FOTON-M3 mission.

Non-living Dissipative Systems

Its too late at night to be writing anything meaningful about slime molds, I have read that its is quite common to find it in the woods Looking at this site I think I may have actually seen some. This bears some relevance the the BZ reaction we have been working on…

“The investigation of such self-organizing chemical systems is still going on. All these chemical systems, mainly variants of the BZ-reaction, strongly point in the direction of corresponding biochemical processes in Organisms, for example the aggregation patterns of the Slime Mold. This mold consists of amoebae (unicellular animals) living on the forest floor. When starved (i.e. finding themselves in unfavorable conditions) they aggregate into a multicellular body which can then move in search of a more favorable habitat. The aggregation is triggered by the release of the compound cyclic adenosine monophosphate (cAMP) from some of the amoebae”

http://waynesword.palomar.edu/slime1.htm /a>

Spiral waves in colonies of the mold Dictyostelium discoideum. These patterns are created when the mold forms aggregates in response to some external ‘ stress’, such as a lack of moisture or nutrients.