 So, it's kind of interesting because I can't see the screen here, but I can see there, so I have a little bit of weatherman action happening. But, okay, this is the telematic site. And my partner in this, so I'm not just some sort of guy wandering around, is, well, I am that too, but is Dr. Cameron Jones of the Swinburne University of Technology. He's the, he's the really the pioneer in this field. If you see the new light there swirling around, that is the, is that the one, the paper that started it at all. And what he's done, he's been doing this since really the early 90s. His PhD was a couple of years ago. He's the CD Spiral or the CD-ROM Computing Guru. In fact, he's the only person who's been really doing it. There's a project. We run around and scouted the other competition and there's a project at UCSD. And they posted they're going to be doing something in July. I don't know if they looked at our website and said, hey, we got to do something soon, but it's almost August. So the race is on for homebrew molecular biochips, which is what this ultimately is. But what Dr. Jones has done is you can specially mod these discs. And here's another shameless plug. We are going to be selling the discs next year. I'm going to be moving to Australia, New Zealand to work on it with him. And we're going to be selling basically their treated discs that you can lay bio-organic goo or mass or matter, whatever you want to call it over. And have it stick on the chip or have it stick on the disc, treat the disc as part of the mod process. But beyond that, you put it in a CD drive, which we also supply. But you can also hook it into your system so hackers can really use the tools to scan a biochip. And the CD-Rov scanners right now can read medical bacteria. If you're a human bacteria, you want to determine what kind of ailment you have. That's one of the main applications. This application here of special interest to people here is crypto. And curiously the patterns on a molecule, microbial molecule are fractalic and similar in nature to an MD5 hash data set. So if you go down here, this is the basic method we're using. You can see it bounces off the ROM. It goes through some processing. And then it reads out on the other end. I'm writing the Linux software for it right now and we're going to be selling it as a black box or a white box. But a lot of the crypto stuff is already functional. It's been functional for a while. So this is the hash and message digest function. Hash and message digest function. It's a one-way procedure. So you can read that. And what goes on is that function can actually be performed on the data that you lay it over. It can really be done at all input-output levels with all keys. What it does is it simulates that kind of crypt key. And those are the differences when you change the keys. So it'll, in fact, encrypt the data differently. Pretty interesting because of the speed. The speed of the encryption process is it's based on the hardware of laying over a microbial organic mass on a CD. So what's taking place are the light interactions between the optical head and the disk. And that's a lot faster than what takes place in a normal chip. A lot faster. So some people are doing it right now. But you need the treated disks and you need a modded CD-ROM drive that can sterilize your mass, your biomass. But other than that, our software is going to be fairly open-ended. And I'm setting up a P2P site so you can do computation using this technique on a distributed network. So everybody can run these little biochips that are on top of their disks off a distributed network. Now the key for all of this is, in case you don't know, a CD-ROM path or the track on a CD-ROM is an Archimedean spiral. It's several kilometers long, believe it or not. It's 22,000 revolutions approximately. 23,180 ages and some change like .604 something. Let's just show you that. I've been doing some of that. But when you burn a disk, it forms a shallow pit on the disk. A professional burner or a commercial burn disk will be a clean cut. If you use your CD-ROM burner, it'll have jagged edges along it. Jump back here. Okay. So that's the crypto stuff. And what happens is the mass is laid over those pits. The scanner is supposed to scan the pits. But instead what it does is it hits the organic matter. It hits cellular 3D molecules, 700 nanometers. Now, hydrogen molecule is under 1 nanometer, 0.5 nanometers, depending on the type of hydrogen. These are real atoms, not virtual atoms. It's not a PNP. It's an actual molecule with protons and neutrons inside it. So it hits that at 700 nanometers, but instead of reading the pit and bouncing off it and giving it a 0 or 1, when it runs through the checksum, there's a standard series of checksums that all the CD-ROM software uses. It gives a bunch of errors. So we get those errors and that's what we base our molecular reading scans on. So really what it is is an incredibly cheap microscope that can... right now discern bacteria and it can also encrypt data extremely fast. That's the site. I have some shots of the spiral because what we're going to do is we're turning all of this beyond the crypto. I'm turning the technology into a learning site for Australia really for the world. So you can go and poke around it and see what all you can do with a CD-ROM spiral. The next major innovation we're working on, if you're interested in really pushing the edge, is a cellular CCD cluster that sticks on the back end of a disk. I discovered this when I was working on this, but actually CD disks and DVD disks are semi-transparent. So you can actually see some of the light that passes through those disks. And CCDs can see some of the light that passes through those disks. So you put a CCD on the other end of the disk and your scanner on the top and the scanner shoots through the disk. And the CCDs beneath the disk read the light and read different levels of the light. But still your average CCD, the quantum efficiency of an average CCD is maybe in the tens of thousands. So the number of electrons it'll pick up is in like 10,000 range. That's not a single photon scanning CCD at three degrees Kelvin. You're not going to get quantum or molecular even precision off of it. But my other idea is clustering these CCD chips. They're really cheap ones. You can get off webcams. Putting some kind of cooling on them and running some more silencers on them and synthesizing the data. So that's what I mean when I say putting a cluster on the back of the disk. So you can actually read the light. That's a good sign. So these are not the pit groove maps, but these are some maps I made over the Convolver. This is actually Pauvery. It's not done with the 3D regular wireframe mesh modeler. But it looks like the internet's down. Is it? Okay. These little things here, this is just more stuff to show you the scale of the spiral. So you can see the scale that the spiral's happening at. And over on the right, that's some coordinate translation. The main thing is every time you read a coordinate off of the spiral, you have to translate that to the X, Y coordinate on the disk. So you can get a physical location. You're still getting a physical location when you get the point on the spiral. It's just you have to translate it out. So that's what the visualization is going to do. There's a technology called Ajax. It's really JavaScript, XML, and CSS. All these technologies fuse together. They're old technologies. But they're getting faster and faster. And some of the games are actually better in a lot of ways than applets because they don't crash your browser and they don't take forever to load, but they're so nice and smooth. So we're going to start producing a lot of the interactive images for this in Ajax and JavaScript interactive. So when you go in, you can actually... Google Maps is done that way. So you can move around the spiral like you can move around a big Google Map. And you can see real-time scans taking place on the spiral like you can move around a Google Map. So we'll map out the mesh of the 3D organic goo on the disk. And you can move around it because it's so huge. Let's see if the network's back up. So you can see the scale. You can move around it like you move around a Google Map. It's still down. So all this stuff is the size of the bit, the size of the bit size can vary. These bricks are actually not accurate representations of the spiral bit. They're more like spheres which are easier to render, but they're stretched out usually. Okay. All right. Well, we have no network, but at least we have this page. And one of the other areas, one of the other apps is something called Polyval Geospheres. It takes the molecular structures on the disk. And it's a attempt to pick up small energy signatures like you'd pick up large energy signatures with the collider. So really one of my goals is to tune small molecular configurations like Radialaria. There's a site called www.radialaria, r-a-d-i-o-l-a-r-i-a.org. And it has all these fantastic designs. They're a lot more intricate than Bucky Balls. They're slightly larger and organic, but they still are enclosures. So I'm looking at tuning those enclosures to pick up very subtle energy signatures. When you have a collider and a proton and an anti-proton hit, there are millions and millions of decays that occur. So in order to read those decays, you need a quantum-capable computer, but in order to get a quantum-capable computer, you need to read those decays. So it's a real paradox. So one of the, because this is molecular technology, the main, and basically what you'll have is the capability of making a molecular biochip for pennies on the dollar, which is orders of magnitude faster than a large optron AMD64 supercluster or even Blue Gene. If you have enough of these goo blobs spread out in your apartment, you're going to really get a much, much faster machine. One of the keys to accepting a lot of this is chaos computing, which is using genetic algorithms and really a massively parallel process because the interactions that take place within these goo masses, are semi-random. They're not entirely linear. There is an order and a linearity to these molecular structures, but it's not like something you'd read when you look at a blown-up diagram of a microchip where everything is a big grid and it's all taking place in 3D, so it's a lot more complex and you really can't do it with a linear programming approach. You need a chaos programming approach. I really only found a couple references to chaos computing and that's sort of picking out the subtle EM vibrations and tanning switching power from that. But anyways, so that's the chicken and the egg paradox. In order to get these quantum signatures and in order to get a quantum computer that powerful, you can start out at the molecular level and then sort of as the main app for all these molecular chips that we're looking at designing, it's tunneling in, obviously tunneling into smaller and smaller switching and smaller and smaller switching mechanisms to build a faster computer. So you have a regular maybe an opteron cluster as your outer shell and inside that shell you have molecular chips, inside that shell you have maybe atomic chips and inside that if your configurations work you have a subatomic realm and you can keep probing in a lot of the ways that people are discovering gravity or anti-gravity is to read particles decaying. All of those decays they usually don't read in these huge colliders because there's too many of them. But with powerful enough system one of the things that we want to look at are all these decays. It's a very generic basic problem and people who want to look at supercomputers look at the weather, they look at chips. Did you have a question there? Yeah, that is the case. That's what's currently functional. We're also able to do crypto and MD5 encryption with certain fractalic patterns. That is what I'm doing with a lot of the chaos computing technology is looking at what else they can do. There is a genetic algorithm so there's a bunch of books out on genetic algorithms but I really haven't seen too many functions that define a fitness of a switching process and basically throw things in the chaotic soup until they obtain the switching results. So that's one of the things that I want to do with chaos or that I'm working on with chaos computing and genetic algorithms to define a problem to find something like rendering something in 3D very fast so if you can have a biochip that does a 3D calculation extremely fast then I guess you've proven your case once again. It's all really slow because the IO is based off a DVD head or a CD head, it's 700 nanometers which is still good, you're going to get a lot of IO off that but it's only one head and then it's getting processed in your computer but if it's a very complex calculation that's taking place on the biochip like MD5 or like a scan even though that's technically not a switching function it's a breakthrough it's definitely something that is worthy of attention. So there's a lot of problems that can be solved this way mainly speed and cost you can make your own biochip you're ahead of everybody else in the computing game so I don't know if the network's back up I go down the list here what this does is the site is Telematics it's off magicgardenlabs.com molecular media project we are going to hook up the technology there and run it in real time and have these scans and switching functions running in real time on CD hardware there so you can go onto the website and see the CD bean scan and see the biomass bean scan on the website play with it one of the things that I'm working on are virtual filters that fit on top of the disk so you can sort of pretend filter the data you can also synthesize the filters with genetic algorithms so the filters are generated using a random mutation process and then they're synthesized using a random mutation process so all of it right now is at the code vet level so the functions aren't too complex nothing too complex happens they just sort of feed out and see how basic they can get so that's good I got that one on there oh it is okay so that's really the spiral generation code that's not going to be too much let's go back up here and this is the actual page and no I don't well they're down maybe this one isn't down okay I can't even read this on so anyways here's some links optical disk specifications this is some more graphic stuff at the bottom so the switching and the chaos and the idea of using genetic algorithms to speed things up is nothing new there's a kernel trap on kernel trap there's a Linux patch for tuning a Linux kernel with genetic algorithms I have a link to it I don't think it's on this page but it's on one of my link lists so it goes through and it guesses the fastest way to tune your Linux system and it gives usually a 10-20% performance improvement which is really significant since you spend a couple hundred bucks to get that much faster on your CPU but that's really sort of the base level of it there's a really really fast stuff and there's a couple other pages there's a switching page which is also a real big we're looking at doing models of the microbial structures to see how they bounce light around to see how they compute so I got about 10 minutes left are there any questions yeah the website is telescope3d. telescope3d.sourceforge.org um ccd it's really synthesis there's a guy Steve Chambers who has the QYAC club the quick cam imaging group out of the UK he's gone around and synthesized time-based he's done time-based synthesis but really all it is is basic interferometry between two ccd's that are closed together I just call it cellular interferometry so if you have two ccd chips like this combining the data on the chips to see if you can get a resolution improvement so you have a huge cluster it's making a large ccd chip out of a bunch of little ccd chips so that's much cheaper you can just go around and steal webcams and link them together and synthesize the data but I'm working on getting all the code in the first I have a list of experiments in the first experiment what I'm doing with the software is actually taking these filters, taking different it's reverse interferometry so it takes an optical disk head read at different points along the disk and then it synthesizes those reads into one image sourceforge.net right so a lot of the math is FFT, fast Fourier transform discrete cosine transform when we saw the box those graphs will come up in real time on the box it'll have a web-based interface I'm working on a touchscreen 1, 2 but you can see the data stream out from the scans so it can differentiate bacteria and then also the crypto is the other function if you want to learn more about the crypto you can go to this just do a search for the molecular media project and that's where all these links are for crypto and if you want to try it, there's information there on duplicating the experiment and like I said, we're going to be selling the disks next year the disks are specially treated biodisks but you can use them in a normal PC if you follow the process and we have a couple more things to sterilize the disk a couple more mods we're selling so it's going to be a white box that does the scanning and it's going to have hacker applications really to create your own switching to create your own biochip to beat the silicon guys to beat silicon that's one term I've never given this talk before I was called up, I had my frank the tank incidents last night I went to sleep barely and I live here luckily but I go to these things all the time I went to CCC two years ago and it was a great time and there was what the hack this weekend in Holland, I was like I wish I was there and then I saw all this the stuff here is much better than what I saw on the website so I worked down the road, it's the easiest thing to get to so I got a call around nine I was still trying to sleep, though I couldn't sleep at 9.30 in my apartment over in Henderson and I said oh can you come to talk and 9.30 is about 40 minutes ago I had never given this speech I sent Dr. Jones an email and I had my frank the tank incident and I got I got a spot and I didn't have any time to prepare it and then the internet went down so I had plenty of excuses for boring everyone to death but I would like to give a talk that goes into more detail about the MD5 and the crypto but I can't even read the PDF see where we're at but it is pretty cool and it does work these are the main links to look up the magic garden for free is this freeware it's basically a bunch of source code like mutation C code real basic C code functions that mutate code what I like to do is run it all into parent which believe it or not they've built parts of pearl with parent and parent is a very very low level language that can do really really assembly it looks like assembly when you read it so it can function as a meta assembly language so I'd like to code some of these biochips with parent so when you do the tunneling you don't have to change the software necessarily if you have the same assembly context it can sort of fit to the hardware and build itself all natively with genetic algorithms and with chaos computing and chaos switching there's all stuff that I want to do from the ground up with these chips my main personal interest for the molecular media project in my thesis and dissertation is a atomic structures or molecular structures for sensing subtle energy patterns to get around the chicken and the egg paradox of supplying more and more power whether it's energy or computing power to capturing subatomic decays so I'd like to run those into a PDP website distributed global computing website for the holy grail which is capturing gravity developing any gravity sensing any gravity particles using distributed global computing the website is still called the sleeping giant as awakening so I guess the sleeping giant is taking a while to awaken I think I'm almost out of time like I said I wish I had people here really wanted to hear more about the crypto are there any more questions about it or in general? right well there are a couple different ways their patents are pending if you look on the website you can sort of infer the process it basically is like a baking process that it goes through and there's also a sterilization like our sterilization process and that requires a lot of UV the mod that we're selling is a sterilization mod and the patents pending on it involves UV light some infrared light and even some aerosinators in the contraption so the main thing is if you're scanning bacteria if you're doing crypto you can use harmless bacteria but the example that we kind of laugh at is sort of somebody's gonorrhea that you're scanning flying all over your cd disc because that's not really the most I guess sterile environment to say the least so you want to contain that stuff as much as possible and that's the real trick of the mod the hardware mod we're selling is to contain all this bacteria even if there is a leak still contain it within the source and as you might imagine there's a lot of stuff that I probably shouldn't talk about here with the technology but we're very into scanning for safety and security so that's the other big application so ideally if you follow the instructions on the website they will show you how to grow bacteria in a petry disc and apply the swab to the disc it's on the molecular media site and actually it's on that pdf that I pulled up the petry disc with the treatment that took place and you can drop it right on the disc put a little drop but it's a stain on the disc the discs that we're selling are teeny sized they're like the 80 meg mini cds this big it's still a 450 to 700 nanometer range the blue light laser cds have a plus minus 5 nanometer so I want to see if I can pull something off that and the 5 nanometer scale what happens is the head reads the goo and starts to gyrate around like crazy and then it gives it anomalous air reading off the the bite strain that it's reading in the check some range check some area I think it's 2352 bites per frame or bites per sector, yeah no it will work better in fact that's the other piece of the software is to get it to scan when it hits the wrong way yeah there's a plastic layer there are a bunch of different, I have all these links there all the layers of all the grooves here I wish I could pull up but there's a plastic layer that is on top it's like an enamel on your tooth that's on top of everything it really won't affect anything but when you grow beyond that and you have more organic stuff on top of it that's when you can really get a real reading at that scale but you can't read it in a microscope even a really good microscope you need a scanning tunneling oh it's on microscope and what it does it allows your CD to perform that process but beyond that since it's on a computer you can do switching with it well that's interesting it's 1.6 typically 1.6 microns you'll say oh you're still not at 0.13 or 0.09 microns or whatever or 90 nanometers or whatever the latest intel dye is but you still have to remember this is not an EM silicon base this is an EM wave strictly and it's a molecular surface so you're still going way way faster than anything that's silicon base the process is completely different you're on the order of speed of an optical check this way I mean the tunneling, quantum tunneling will allow you to go faster 1.6 is the typical track pitch the depth of the bit is usually maybe it can go up to 3 microns or it can be as small as 0.8 microns I'm averaging it out around 1.5 microns your head is actually grooving the surface it looks like a dish or an impression of a ball that you sort of put into a flat disk surface and like I said at the beginning if you burn it on your own burner it'll have jagged edges if you buy one with a commercial burner it'll have smooth clean edges on it and then the JavaScript Google Maps interface you're going to be able to move around that whole disk and it's going to simulate where the biomass either with a sludge pattern ideally we take some photos and have those up there too in real time so we're going to have many many scans of this running in real time live next year as it goes on there anything else? is there any other one final question? I don't have any other conclusions like I said I wish I went into more detail about the encryption the handshake and how fractalic patterns emulate MD5 encryption that's basically the gist of it and it can go really in any direction on any of the keys but if you read the PDF you can see so I guess that is that it? no other last false? okay well let me see if I can pull this thing out finally oh well okay thanks