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The goal of self-replication in space systems is to exploit large amounts of matter with a low launch mass.  For example, an autotrophic self-replicating machine could cover a moon or planet with solar cells, and beam the power to the Earth using microwaves.  Once in place, the same machinery that built itself could also produce raw materials or manufactured objects, including transportation systems to ship the products. Another model of self-replicating machine would copy itself through the galaxy and universe, sending information back.

The goal of self-replication in space systems is to exploit large amounts of matter with a low launch mass.  For example, an autotrophic self-replicating machine could cover a moon or planet with solar cells, and beam the power to the Earth using microwaves.  Once in place, the same machinery that built itself could also produce raw materials or manufactured objects, including transportation systems to ship the products. Another model of self-replicating machine would copy itself through the galaxy and universe, sending information back.

In general, since these systems are autotrophic, they are the most difficult and complex known replicators.  They are also thought to be the most hazardous, because they do not require any inputs from human beings in order to reproduce.

In general, since these systems are autotrophic, they are the most difficult and complex known replicators.  They are also thought to be the most hazardous, because they do not require any inputs from human beings in order to reproduce.

A classic theoretical study of replicators in space is the 1980 NASA study of autotrophic clanking replicators, edited by Robert Freitas.

A classic theoretical study of replicators in space is the 1980 NASA study of autotrophic clanking replicators, edited by Robert Freitas.

一个关于太空中复制因子的经典理论研究是1980年 NASA 关于自养叮当复制因子的研究，由 Robert Freitas 编辑。

一个关于太空中复制因子的经典理论研究是1980年 NASA 关于自养铿锵复制因子的研究，由罗伯特·弗雷塔斯(Robert Freitas)编辑。

 

 

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