Difference between revisions of "Convergent assembly"

Revision as of 13:40, 22 February 2015

Note that it's not a necessity to have the topmost convergent assembly levels the same size as the product like shown here. - Devices can be made thin and flat.

Convergent assembly is the general process of taking small parts and putting them together to bigger parts and then taking those bigger parts and putting them together to even bigger parts and so on.

Convergent assembly must not be confused with exponential assembly (a concept for bootstrapping AP manufacturing).

Details

In a nanofactory the convergent assembly levels can be identified with the abstract assembly levels (including the more scale invariant ones lying further up). Stacking those levels to layers as a concrete configuration makes a system practical and easy to analyze.

• Convergent assembly is not a means to speed up production.
• Relation to recycling ...

motivations for convergent assembly

Specialisation

In today's non atomically precise production convergent assembly is the rule. In most cases it is just not fully automated. An example is the path from raw materials to electronic parts to printed circuit boards and finally to complete electronic devices. The reason for convergent assembly here is that for the separate parts there are many specialized production places necessary. The parts just can't be produced directly in the final product.

Usually one needs a welter of completely identical building components in a product - connection pins are a good example. Single atoms are completely identical but they lack in variety in their independent function. Putting together standard parts in place with a freely programmable general purpose manipulator amounts to a waste of space and time. General purpose manipulators are misused that way.

Even in general purpose computer architectures there are - if one takes a closer look - specially optimized areas for special tasks. Higher specialization is usually removed from the hardware and put into software.

In a physically producing personal fabricator there's a far wider palette of possibilities for physical specialization since there are so many possible diamondoid molecular elements that can be designed.

Bigger assembly groups provide more design freedom and for the better or the worse the freedom of format proliferation. Here the speed gain from specialisation drops and the space usage explodes exponenially because of the combinatoric possibilities. Out of this reason this is the place where to switch to software specialisation.

Thus In a personal fabricator the most if not all the specialization is distributed in the bottom-most layers. higher convergent assembly levels (layers) quickly loose their logistic importance (relative distance). The main distribution action takes place in the first three logistic layers.

Sidenote: In the obsolete assembler concept all parts of a product where thought to be mechanosynthesized right at their final place in the product.

Further motivations

• more simple construction of overhangs without the need for scaffolds
• the automated management of bigger logical assembly-groups
• the simpler decomposition is standard parts that can be put together again in completely different ways
• the possibility to keep everything in a vacuum till the final product release - this should not be necessary and may decrease the incentive for the creation of systems that are capable of recycling