Newsgroups: comp.robotics
From: Joe@stellar.demon.co.uk (Joseph Michael)
Path: brunix!sgiblab!swrinde!pipex!warwick!uknet!demon!stellar.demon.co.uk!Joe
Subject: Shape Changing Robotics
Organization: Stellar Drive
Reply-To: Joe@stellar.demon.co.uk
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Date: Mon, 30 May 1994 09:58:14 +0000
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                        SHAPE CHANGING ROBOTICS
			 ---------------------

There is going to be an exhibition at the Birmingham National Exhibition
Centre (NEC) called Electrotech 94 (20-24 June) which is all about electric
power generation. 

I hope to be exhibiting mock models of new and ultra advanced
shape changing robotics technology that could be used to cap a catastrophically
damaged nuclear reactor in hours saving billions and lives. The shape changing
robot can squeeze through narrow entrances by changing shape and take large
quantities of equipment with it to erect lead walls, ceiling supports, new
floors, lights and cameras etc. 

A patent has been filed on this shape changing robotics technology with
confirmation from the preliminary patent search that the product is unique.

This shape changing robotics technology titled 'Programmable Materials'
have wide industrial applications and below is a write up of this technology.

                        PROGRAMMABLE MATERIALS
                        ----------------------

Programmable materials is a celluar robotic mechanism. (Cellular as in
modular - not the biological term.) The cells are bricks that move under
computer control allowing the robot to change shape under computer control.
All the bricks are clones allowing them to be replaced by identical clones
when damaged, which means this robot is self repairing for operating in
very hostile conditions. Most of the cells are hollow empty shells with no
mechanisms resulting in low in manufacturing cost. The remainder (about 30 
in a minimum set) transport themselves as well as equipment, tools and
structural supports to erect larger superstructures.

The modular tools, and equipment transported include simple items
such as screwdrivers to complex sub assemblies such as diesel generators
for power. Anything can be modularised. For example pneumatic
and hydraulic power sources. These together with preterminated cut lengths of
hoses and pneumatic/hydraulic equipment can be assembled together and connected
up to build powerful hydraulic/pneumatic equipment. The shape changing
properties of the robot together with modularised tooling is used to
wire up machines with hydraulic, pneumatic and electrical cables. 

The tooling supplied by manufacturers can be operated by an operator
once installed or by the programmable material robot itself if the tool
manufacturer fits an interfaces used by the bricks and supply software
drivers to operate the tool either by a remote operator or through
complete automation.

All tools can be made compatible with programmable materials by cutting
simple slots into their body so that it can be picked up. Alternatively
it can be bolted to a plate pre-cut with these slots. To operate
the tools, the tool manufacturers fit electrical contacts inside the slots.
Whether the tool is large or small, the same rule applies and the tool
is picked up/operated by large/small bricks.

The robot changes shape by extending streamers on to which it transports
itself. Many streamers can be erected simultaneously allowing rapid
transportation of material - for example, when erecting a building,
many streamers can be used to erect the building from all sides.

Programmable materials can build heavy bases for supporting large structures
using simple buckets which when bolted together and filled with water provide
the necessary bulk for a solid foundation. Such heavy foundations are required
for example in erecting temporary bridges or in erecting supports
to support a collapsing tower block.

All these operations are carried out under total automation with the
operator specifying general instructions such as where to lay the foundation,
and how much weight to install.

Only one brick is ever 'manufactured'. The rest are cloned. Each brick
is about the same size as a cube shaped shoe box. Integer multiple
sizes are used heavier engineering tasks but are seamlessly integrated
with their smaller relatives.

Programmable materials can be built in a factory no bigger than about
4000 square feet. The factory assembly plant can itself be made of more
programmable materials. Since they can transport the parts needed for their
own assembly and subsequently transport it away from assembly to the warehouse
made from more programmable materials. The machinery for assembly can be
modular and thus the whole factory can be a machine made of programmable
materials for the production of programmable materials. This is the way
I plan to develop the technology.

Further down the line, similar production lines for making cars, biscuits,
television sets etc will emerge. The idea is that you make a self contained
factory which can be sold to other organisations cheapening the whole
business of making goods with a factory.

In the long term future, there will be no other ways of mass producing
goods other than through the use of programmable materials which are
far more flexible than anything seen ever before.

Programmable materials can be re-used for other applications simply by
changing the software. So one minute its a factory making cas, the next minute
its another factory assembling computers or electrical goods allowing
product portfolios to be greatly expanded and reduce costs.

Programmable materials is the hardware equivalent of computer software.
What you do with it is determined only by the software and custom tools fitted.
Unlike conventional machines, you can build greater varieties of machines
with it. It is much greener than conventional machines, because there is no
waste. Programmable materials are 'indestructable' and completely re-usable
across all its different applications. Therefore, you don't need to make
more than you need and what you don't need, you can re-use - saving the
planet from pollution and waste.

Programmable materials can be sent to space. Every launch of any vehicle
into space is fully loaded with programmble materials. The extra programmable
materials are put into parking orbits in space. When a need arises such as
the need to build a space station or a lunar base say, the programmble
materials are collated and instructed to turn into a space station.
If required, these vehicles can be sent to say the moon where they change
shape into a vehicle more suited to a lunar landing. On landing it turns into
a lunar base. No human intervention is required. It cheapens everything.
If the landing was rough, most of the programmable materials would survive.
You would have to kill all the cellular components to kill off the robot
and thus with extreme reliability (not currently known in space engineering)
you would set about erecting a lunar base. Whats more, its the same stuff
that is used on earth without any hugely different modifications.

Programmable materials are going to spread around the world as all industries
switch to this type of factory and methods of production. It may take
20 years but I suspect we will see much of what has been said in less than
five years because there is a lot of business to be generated in
making the chips for the controllers, writing the software and
making huge savings in the way production plants are run.

Joseph Michael
English Chit-Chat Limited
Tel (UK) +44 81-800 9914


