Thampsan wrote:

Good point, obviously favourable (or specifically set up) air currents would allow people to direct nanites. Things like the vortex ring gun. Also could you use directed magnetic fields to pull nanites toward something at a greater rate?

Right, control the environment and you can control the nanites. So if the nanites are ferromagnetic, or ionized, or are partly made of room temperature superconductors you could pull/push them with magnets. This could be exploited as a strength (to aid them) or a weakness (to hinder them), however.

LatwPIAT wrote:

[url=http://wise-nano.org/w/MM_nanofactory_architecture]This website[/url] gives a figure of 1 gram of product per kg of manufacturing volume per second for the Phonenix nanofactory design.

This analysis is based on a 1 micron block size, and is building 86.4 times its mass per day. If you constrained our 10 micron builders to "finger sized" bricks in hyperactive speed mode (presumably they'd need to slow down quite a bit to thread a needle) you're probably looking at a 1cm cube (finger thickness) for a 200cm tall human. So our "resolution" is 50 nanometers, or approximately 1/20th of this design. If you go for a longer length, we've already established you can achieve a higher top speed. So if you increase our 6.75 by a factor of 20, we get 135 per day. Actually a larger number. Also, this supposes a large factory that is much larger than our design size. You'd expect a factory the size of Paris to be able to build Eiffel Towers more efficiently than a "ground up" approach. This probably means my multipliers were too generous (10x for hyperactive rate, 4x for more efficient design).

Yes, it is bit silly to compare objects on a ballistic trajectory to nanites that are not on a ballistic trajectory. Are you proposing nanites being fired out of cannons as some sort of range extending solution? That would change the constraints. It's also silly to consider a rocket, with about a 2 minute endurance, as a viable comparison to a nanite swarm. 2 minutes just isn't long enough to be useful for nanites. Yes calculations for bullets aren't the same as rockets, as bullets don't carry their fuel with them. However, unfavorable scaling laws do apply to anything that carries their own fuel with them. Take a rocket with 1 unit of frontal area impinged on by the air. Lets suppose its top speed is limited by drag. Halve the length, width, and height of that rocket. You now have a frontal area 1/4 the size. Excellent, we've cut drag by 3/4! But your volume (and thus fuel) has now been cut to 1/8 the original amount. Your range has been cut. Would this apply to a chemically launched bullet? No, as the bullet was pushed out of the barrel based on the rearward area of the bullet (which scales the same as the front). So you can't escape this scaling problem if you carry your fuel with you (Compare the range of a SCUD to a Katyusha, for example). And yes, again, this doesn't apply to 9mm bullets. Are there other scale issues? Yes, drag changes qualitatively on very small scales. It actually gets [i]worse[/i] as you have to expend energy to deal with skin viscosity issues, not just pushing the air out of the way. It just makes flying nanites that much more infeasible. I'd avoided that issue as it is besides the point - flying nanites were infeasible even before considering this scaling issue. Also, Brownian motion becomes an issue. Once again, this is [i]worse[/i] the smaller you get. It's just more reason a flying micro-machine would have to expend more energy. There's no reason to bring it up if bigger problems exist on the macro scale. There's a reason the smallest wingspan you'll see among flying insects is about 1mm. It is because of these physics. But here's the crux of the body lengths per second issue - if you shrink a 2 meter tall human to 20 centimeters in perfect scale, and shrink the street he's about to cross on a similar scale, it will take them both the same amount of time to look both ways across the street and then walk across it. Other things being equal, you reduce body length by 10x, you reduce speed by 10x. P.S. Objects at the 1 micron scale don't have huge quantum noise issues. Things at the 1 nanometer scale are another story.

Here's another scaling problem: Processing power. A human has a 1200cc brain, with 100 billion neurons (and a bunch of other brain cells too). EP has something better - the cyberbrain. About 1cc in volume, it can match a biomorph brain, at probably something like less than 1 watt instead of 25 watts of power used. So lets shrink that cyberbrain down to 1 micron cubed. How many cyberbrain neuron equivalents can we fit into that? Not even a single one.

How do you propose the nanites communicate? Should I start a new thread "Nanite swarm communication is not hard sci-fi?" :) Or should we leave it in this thread?

Prophet710 wrote:

I would think it would be all one network, as in the swarm is one machine, operating with several moving parts to one end. without equipping each nanite to have a communications suite using LIDAR or even radio, you could just have a pre-programmed routine set in that could be adjusted by the user using the containment mechanism as a beacon. Maybe?

Are you saying they'd be physically connected? EDIT: Bringing up the viability of swarm communication was more in response to Jaberwo's topic of condensing/evaporating swarms.

OneTrikPony wrote:

It's true that your swarm, in mist or cloud form, isn't going to go chasing people around a habitat. But, in the first place, the swarm doesn't have to be mobile to eat faces because characters are mobile and a swarm is nearly impossible to detect until you're already in it.

I don't think that a swarm is nearly impossible to detect. 10 cubic centimeters of dust (one swarm) spread over the floor of a 10x10 meter area is going to be very visible. If you propose larger cooperatives, its going to be several 100s of cubic centimeters. On top of that, advanced sensors are very common in Eclipse Phase, and [i]especially[/i] among Eclipse Phase characters.

OneTrikPony wrote:

In the second place, it doesn't need to be a mist it can be a self propelled liquid.

I'm not sure what a self propelled liquid is? Could you point to some real world examples?

OneTrikPony wrote:

Consider coordinating an engineer or protean swarm with a disassembler, injector, or saboteur swarm. The engineer swarm fills a space with microscopic lattice tubules and vesicles that carry the aggressive nanites. A charter walks or runs through the space and gets infected. It would be nearly impossible to detect because none of the nanites are free floating. You don't even need an aggressive swarm. Ever walked through a spider web by mistake? Use the same engineer swarm to fill a floatway with microscopic fullerine "spiderwebs" and chase the character into it. Give them 5 - 10 meters before they become entangled by enough of these webs that they have to make a Som test to fight thier way out.

These would all have to be coordinated by hives, right? So that part is much easier to detect than the micro machines themselves. Micro machines would have to be harder to detect if they're "inside the walls" but here you seem to be proposing they're filling up open space with invisible webs. Well, most spider webs are actually invisible to the human eye in terms of thickness. What you are seeing when you see a spider web is an effect called fluorescence, and unfortunately carbon nanotubes fluoresce really really well into the infrared. So with a modicum of light (or even not if your vision is extremely sensitive), anybody with Enhanced Vision can see the fluorescence of nanoscale objects even thought the threads/objects would normally be too small to see due to their thickness.

OneTrikPony wrote:

Pack an aggressive swarm inside a condensed engineer or protean swarm with Chameleon capabilities. It can roll or flow anywhere it wants, (especially quickly in lunar or microgravity), because it's composed of nano-particles it will have awesome traction. It could disguise itself as any form that can be programmed. Your characters will NEVER trust another toilet seat.

Chameleon as described in the rulebook isn't going to work with micro-machines. The layer would be too thick to be practical.Invisibility cloak style metamaterials have the same problem. A cloak a millimeter thick isn't a big deal to something human sized - it's way too thick to be practical for a micro-machine. And a T-ray emitter would show that faux toilet seat right away.

OneTrikPony wrote:

As for the communication issue; Just have the swarm work like mesh inserts or the recording end of a cortical stack. It can form and break physical connections as quickly as needed to carry out distributed processing and should have processing power at least equivalent to an ecto.

They can not form and break physical connections as quickly as needed. They need real time (as in, this isn't combat speed) to form and modify those links - the nanites aren't that mobile. And even if they were super mobile, their vision doesn't go past beyond say one body length ( except for possible very basic light intensity senses depending on their size) and they're deaf. So they can only coordinate by touch, smell, and by vibrating messages through a solid or liquid. It is possible they can pick up broadcast messages from say a hive via an infrared broadcast, but two-way communication isn't feasible. And also I have a hard time believing that a network of nanites can add all their processing power together with no overhead. That's like saying I have 100 million transistors in a single CPU chip. Then I split them 1 million to each of a 100 nodes (1 million transistors each), and then wire them up with network cards - but of course the network cards have hardware of their own which take 100,000 transistors each. I've just increased my total transistor count by 10% for 100 nodes (and we're being kind here -realistically you'd need routers/switches too) *and* you've introduced latency. I doubt even with EP tech the photon fired out of my optical CPU can directly transmit itself down an optical cavity or cable and end up in the CPU of my neighbor. There is going to be translation overhead. If a 10 cubic centimeter swarm was composed of 10 micron sized micro-machines, then we would have [i]10 billion[/i] nodes. The added overhead and complexity would dwarf the resulting computing output, and make coordination essentially impossible.