可以捕捉苍蝇的植物
日期:2022-07-20 15:00

(单词翻译:单击)

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听力文本

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This is Scientific American’s 60-Second Science. I’m Karen Hopkin.

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这里是科学美国人——60秒科学系列,我是凯伦·霍普金-e(0_Tav2naIoDPV@

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They say you can catch more flies with honey than with vinegar.

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据说,用蜂蜜能比用醋捉到更多苍蝇l7~wf!W;;&EK

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But what if you had access to a remote-controlled carnivorous plant?

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但如果你能获得一株远程遥控的食肉植物呢?

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Because researchers have engineered a bio-inspired system, an artificial neuron, if you will, that can trigger the snap of a Venus fly trap.

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研究人员设计了一种仿生系统,或者称为一个人工神经元,如果你愿意的话,这可以触发捕蝇草的突然闭合zZrJS2U43,dLnQg

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Hi, my name is Simone Fabiano. I'm associate professor at Linkoping University in Sweden.

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你好,我是西蒙·法比亚诺zAjGgQV,sS=fdGSNm1c-。我是瑞典林科平大学的副教授*,5^bP9@&7

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Fabiano designed the trap-springing device using nerve cells as a kind of bio-based blueprint.

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法比亚诺以神经细胞为生物蓝图设计了一个诱捕弹性装置mqYC|zBp9xEm

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The way our biological neurons work is that they integrate information from different inputs over time, perform computation, and communicate the result to other neurons by means of voltage pulses.

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生物神经元的工作方式是,随着时间的推移,它们会整合不同的输入信息,执行计算,并通过电压脉冲将结果传达给其他神经元d)gd3bf[0jVl(%4V]l;h

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Now, standard, silicon-based systems can also deliver electrical pulses.

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现在,标准的硅基系统也可以传输电脉冲Aez]DIo,^ibVzoXKEOUX

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But if you want to couple them with something living to produce bionic prosthetics or engineer any kind of brain/machine interface.

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但如果你想把它们与活的生物结合起来,生产仿生假肢或设计任何类型的大脑/机器接口=Ma.n2lkilVwU

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Well, they suffer from several limitations.

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嗯,他们受到了几个限制[j[(501ZIpD0#8#G

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Such as rigidity, poor biocompatibility, complex circuit structures, and operation mechanisms that are fundamentally different from those of biological systems.

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比如硬度太高、生物相容性差、电路结构复杂、运行机制与生物系统也有根本上的不同Z0HZwI1R!lse|-

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To smooth biological integration, Fabiano built his system from polymers that conduct both electrons, like, everyday electronics, and ions, which is how neurons get things done.

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为了顺利地进行生物整合,法比亚诺用高分子建造了系统,这种高分子既能传导电子,也能传导日常电子和离子,而离子是神经元完成任务的方式f^+k=-1DjD

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It’s the ions that enable communication between biological and artificial neurons.

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正是这种离子使生物神经元和人造神经元之间能够进行交流3LwJ,cSG]66]W*c6

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Each part of the artificial neuron, which the researchers describe in the journal Nature, has a direct counterpart in its biological role model.

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研究人员在《自然》杂志上描述:人工神经元的每个部分,在其生物角色模型中都有一个直接的对应部分017o^1J!-J

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We have an input terminal that acts as the biological neuron’s dendrite.

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有一个输入端,可以充当生物神经元的树突e3*gNk~Mwy0o

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That dendrite collects the incoming electrical signals and sends them to a capacitor which, like a neuronal cell body, integrates the information.

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这个树突收集传入的电信号,并将它们发送到电容器,电容器就像神经元细胞体一样,整合信息efg2sl4Bla~8bp(

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Then, once the voltage reaches a specific threshold, a pulse is fired along organic amplifiers that mimic a nerve cell axon.

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一旦电压达到特定的阈值,就会沿着模仿神经细胞轴突的有机放大器发射脉冲(0k]|BFhh9

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We use the ionic concentration-dependent switching characteristics of our transistors to modulate the frequency of spiking, which is to a large extent analogous to biological systems.

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我们使用晶体管离子浓度依赖转换的特性来调节猛增频率,这在很大程度上类似于生物系统Qh_0w8qyzLB]*MR-

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So the ions control the current that flows from the faux neuron to its target, in this case, a live Venus flytrap, triggering the rapid-fire closure of its leafy appendages.

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离子控制着自人造神经元流向其目标的电流,在这种情况下,一个鲜活的捕蝇草会触发其枝叶急速闭合|@@^_4W)Ei7VqUrHM

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All in all, a dramatic demonstration of the potential of neuromorphic design that should give interested engineers, and interloping fruit flies, something to watch out for.

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总而言之,对引人注目的神经形态设计电位的展示,会给感兴趣的工程师和闯入他人领地的果蝇提个醒+U!rat#2gvTa9P+

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For Scientific American’s 60-Second Science, I’m Karen Hopkin.

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谢谢大家收听科学美国人——60秒科学B^-eUyw!aWBCk5+dYVF。我是凯伦·霍普金5o[kUJu@foUR0O^%4hL

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文章为可可英语翻译,未经授权请勿转载!

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