神经形态计算

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Neuromorphic engineering, also known as neuromorphic computing,[1][2][3] is the use of very-large-scale integration (VLSI) systems containing electronic analog circuits to mimic neuro-biological architectures present in the nervous system. A neuromorphic computer/chip is any device that uses physical artificial neurons (made from silicon) to do computations.[4][5] In recent times, the term neuromorphic has been used to describe analog, digital, mixed-mode analog/digital VLSI, and software systems that implement models of neural systems (for perception, motor control, or multisensory integration). The implementation of neuromorphic computing on the hardware level can be realized by oxide-based memristors,[6] spintronic memories, threshold switches, and transistors.[7][5] Training software-based neuromorphic systems of spiking neural networks can be achieved using error backpropagation, e.g., using Python based frameworks such as snnTorch,[8] or using canonical learning rules from the biological learning literature, e.g., using BindsNet.[9]


神经形态工程Neuromorphic engineering(也称为神经形态计算Neuromorphic computing)[1][2][3]是指使用包含电子模拟电路Analog circuit超大规模集成电路Very-large-scale integration系统来模拟神经系统中生理结构的研究方法。神经形态计算机或神经形态芯片包括任何使用由硅制成的人造神经元进行计算的设备。[4][5]近年来,神经形态学(neuromorphic)这个术语被用来描述能够实现神经系统Neural system模型功能(如感知Perception运动控制Motor control多感官整合Multisensory integration等)的模拟、数字、模拟/数字混合模式超大规模集成电路和软件系统。神经形态计算的硬件实现可以通过基于氧化物的记忆电阻器Memristor[6]自旋电子存储器、阈值开关和晶体管Transistor来实现。[7][5]对基于软件的脉冲神经网络系统的训练可以通过误差反向传播机制来实现,例如,使用snnTorch等基于Python的框架,[8]或使用BindsNet等典型的受生物启发的学习模式。[9]

A key aspect of neuromorphic engineering is understanding how the morphology of individual neurons, circuits, applications, and overall architectures creates desirable computations, affects how information is represented, influences robustness to damage, incorporates learning and development, adapts to local change (plasticity), and facilitates evolutionary change.


神经形态工程领域的一个关键问题,就是理解单个神经元形态、神经回路、应用和整体结构如何产生理想的计算,如何影响信息的表示和对破坏的鲁棒性,如何整合学习和发展,如何适应局部变化(可塑性) 并促进逐渐发展的变化。

Neuromorphic engineering is an interdisciplinary subject that takes inspiration from biology, physics, mathematics, computer science, and electronic engineering[5] to design artificial neural systems, such as vision systems, head-eye systems, auditory processors, and autonomous robots, whose physical architecture and design principles are based on those of biological nervous systems.[10] It was developed by Carver Mead[11] in the late 1980s.


神经形态工程是以生物学Biology物理学Physics数学Mathematics计算机科学Computer science电子工程Electronic engineering[5]等学科为基础,设计人工神经系统(如视觉系统Vision systems、头眼系统、听觉处理器以及物理结构和设计原则都受启发于生物神经系统的自主机器人)的一门交叉学科。[10]20世纪80年代后期,卡弗·米德极大地推动了神经形态工程领域的发展。[11]

Neurological inspiration

神经生物学启发

Neuromorphic engineering is set apart by the inspiration it takes from what we know about the structure and operations of the brain. Neuromorphic engineering translates what we know about the brain's function into computer systems. Work has mostly focused on replicating the analog nature of biological computation and the role of neurons in cognition.

Neuromorphic engineering is set apart by the inspiration it takes from what we know about the structure and operations of the brain. Neuromorphic engineering translates what we know about the brain's function into computer systems. Work has mostly focused on replicating the analog nature of biological computation and the role of neurons in cognition.

神经学灵感工程学是从我们对大脑结构和运作的了解中获得灵感而形成的。神经形态工程学将我们对大脑功能的了解转化为计算机系统。工作主要集中在复制生物计算的模拟特性和神经元在认知中的作用。

The biological processes of neurons and their synapses are dauntingly complex, and thus very difficult to artificially simulate. A key feature of biological brains is that all of the processing in neurons use analog chemical signals. This makes it hard to replicate brains in computers because the current generation of computers is completely digital. However, the characteristics of these parts can be abstracted into mathematical functions that closely capture the essence of the neuron's operations.

The biological processes of neurons and their synapses are dauntingly complex, and thus very difficult to artificially simulate. A key feature of biological brains is that all of the processing in neurons use analog chemical signals. This makes it hard to replicate brains in computers because the current generation of computers is completely digital. However, the characteristics of these parts can be abstracted into mathematical functions that closely capture the essence of the neuron's operations.

神经元及其突触的生物学过程极其复杂,难以人工模拟。生物大脑的一个关键特征是,神经元的所有处理过程都使用模拟化学信号。这使得很难在计算机中复制大脑,因为目前的计算机是完全数字化的。然而,这些部分的特征可以抽象为数学函数,这些函数紧密地抓住了神经元运行的本质。

The goal of neuromorphic computing is not to perfectly mimic the brain and all of its functions, but instead to extract what is known of its structure and operations to be used in a practical computing system. No neuromorphic system will claim nor attempt to reproduce every element of neurons and synapses, but all adhere to the idea that computation is highly distributed throughout a series of small computing elements analogous to a neuron. While this sentiment is standard, researchers chase this goal with different methods.[12]

The goal of neuromorphic computing is not to perfectly mimic the brain and all of its functions, but instead to extract what is known of its structure and operations to be used in a practical computing system. No neuromorphic system will claim nor attempt to reproduce every element of neurons and synapses, but all adhere to the idea that computation is highly distributed throughout a series of small computing elements analogous to a neuron. While this sentiment is standard, researchers chase this goal with different methods.

神经形态计算的目标不是完美地模拟大脑及其所有功能,而是提取已知的大脑结构和操作,用于实际的计算系统。没有哪个神经形态学系统会声称或试图复制神经元和突触的每一个元素,但所有人都坚持这样的观点,即计算是高度分布在一系列类似于神经元的小型计算元素中的。虽然这种情绪是标准的,但研究人员用不同的方法追求这一目标。

Examples

案例

As early as 2006, researchers at Georgia Tech published a field programmable neural array.[13] This chip was the first in a line of increasingly complex arrays of floating gate transistors that allowed programmability of charge on the gates of MOSFETs to model the channel-ion characteristics of neurons in the brain and was one of the first cases of a silicon programmable array of neurons.

As early as 2006, researchers at Georgia Tech published a field programmable neural array. This chip was the first in a line of increasingly complex arrays of floating gate transistors that allowed programmability of charge on the gates of MOSFETs to model the channel-ion characteristics of neurons in the brain and was one of the first cases of a silicon programmable array of neurons.

早在2006年,佐治亚理工学院的研究人员就发表了现场可编程神经阵列。这种芯片是一系列越来越复杂的浮栅晶体管阵列中的第一个,这些晶体管可以在 mosfet 的栅极上编程来模拟大脑中神经元的通道离子特性,这也是硅可编程神经元阵列的首批案例之一。

In November 2011, a group of MIT researchers created a computer chip that mimics the analog, ion-based communication in a synapse between two neurons using 400 transistors and standard CMOS manufacturing techniques.[14][15]

In November 2011, a group of MIT researchers created a computer chip that mimics the analog, ion-based communication in a synapse between two neurons using 400 transistors and standard CMOS manufacturing techniques.

2011年11月,麻省理工学院的一组研究人员发明了一种计算机芯片,该芯片使用400个晶体管和标准的 CMOS 制造技术,在两个神经元之间的突触中模拟模拟基于离子的通讯。

In June 2012, spintronic researchers at Purdue University presented a paper on the design of a neuromorphic chip using lateral spin valves and memristors. They argue that the architecture works similarly to neurons and can therefore be used to test methods of reproducing the brain's processing. In addition, these chips are significantly more energy-efficient than conventional ones.[16]

In June 2012, spintronic researchers at Purdue University presented a paper on the design of a neuromorphic chip using lateral spin valves and memristors. They argue that the architecture works similarly to neurons and can therefore be used to test methods of reproducing the brain's processing. In addition, these chips are significantly more energy-efficient than conventional ones.

2012年6月,普渡大学的自旋电子学研究人员发表了一篇关于利用侧向自旋阀和记忆电阻器设计神经形态芯片的论文。他们认为,这种结构的工作原理与神经元相似,因此可以用来测试复制大脑处理过程的方法。此外,这些芯片明显比传统芯片更节能。

Research at HP Labs on Mott memristors has shown that while they can be non-volatile, the volatile behavior exhibited at temperatures significantly below the phase transition temperature can be exploited to fabricate a neuristor,[17] a biologically-inspired device that mimics behavior found in neurons.[17] In September 2013, they presented models and simulations that show how the spiking behavior of these neuristors can be used to form the components required for a Turing machine.[18]

Research at HP Labs on Mott memristors has shown that while they can be non-volatile, the volatile behavior exhibited at temperatures significantly below the phase transition temperature can be exploited to fabricate a neuristor, a biologically-inspired device that mimics behavior found in neurons. In September 2013, they presented models and simulations that show how the spiking behavior of these neuristors can be used to form the components required for a Turing machine.

惠普实验室在莫特记忆电阻器上的研究表明,尽管它们可以是非挥发性的,但是在相变温度以下显示的挥发性行为可以被用来制造神经元电阻器,这是一种模仿神经元行为的生物设备。2013年9月,他们展示了模型和仿真,展示了这些神经元的尖峰行为是如何被用来形成图灵机所需的元件的。

Neurogrid, built by Brains in Silicon at Stanford University,[19] is an example of hardware designed using neuromorphic engineering principles. The circuit board is composed of 16 custom-designed chips, referred to as NeuroCores. Each NeuroCore's analog circuitry is designed to emulate neural elements for 65536 neurons, maximizing energy efficiency. The emulated neurons are connected using digital circuitry designed to maximize spiking throughput.[20][21]

Neurogrid, built by Brains in Silicon at Stanford University, is an example of hardware designed using neuromorphic engineering principles. The circuit board is composed of 16 custom-designed chips, referred to as NeuroCores. Each NeuroCore's analog circuitry is designed to emulate neural elements for 65536 neurons, maximizing energy efficiency. The emulated neurons are connected using digital circuitry designed to maximize spiking throughput.

神经网格是由斯坦福大学硅谷大脑公司建立的,是一个使用神经形态工程原理设计硬件的例子。该电路板由16个定制设计的芯片组成,称为 NeuroCores。每个 NeuroCore 的模拟电路被设计为模拟65536个神经元的神经元元件,最大限度地提高能量效率。模拟的神经元通过设计的数字电路连接,以最大化脉冲吞吐量。

A research project with implications for neuromorphic engineering is the Human Brain Project that is attempting to simulate a complete human brain in a supercomputer using biological data. It is made up of a group of researchers in neuroscience, medicine, and computing.[22] Henry Markram, the project's co-director, has stated that the project proposes to establish a foundation to explore and understand the brain and its diseases, and to use that knowledge to build new computing technologies. The three primary goals of the project are to better understand how the pieces of the brain fit and work together, to understand how to objectively diagnose and treat brain diseases, and to use the understanding of the human brain to develop neuromorphic computers. That the simulation of a complete human brain will require a supercomputer a thousand times more powerful than today's encourages the current focus on neuromorphic computers.[23] $1.3 billion has been allocated to the project by The European Commission.[24]

A research project with implications for neuromorphic engineering is the Human Brain Project that is attempting to simulate a complete human brain in a supercomputer using biological data. It is made up of a group of researchers in neuroscience, medicine, and computing. Henry Markram, the project's co-director, has stated that the project proposes to establish a foundation to explore and understand the brain and its diseases, and to use that knowledge to build new computing technologies. The three primary goals of the project are to better understand how the pieces of the brain fit and work together, to understand how to objectively diagnose and treat brain diseases, and to use the understanding of the human brain to develop neuromorphic computers. That the simulation of a complete human brain will require a supercomputer a thousand times more powerful than today's encourages the current focus on neuromorphic computers. $1.3 billion has been allocated to the project by The European Commission.

一个对神经形态工程有影响的研究项目是人脑项目,它试图用生物数据在超级计算机中模拟完整的人脑。它由一群神经科学、医学和计算机科学的研究人员组成。该项目的联合主管亨利•马克拉姆(Henry Markram)表示,该项目提议建立一个基础,以探索和了解大脑及其疾病,并利用这些知识构建新的计算机技术。这个项目的三个主要目标是: 更好地理解大脑的各个部分是如何相互匹配和协同工作的; 理解如何客观地诊断和治疗脑部疾病; 以及利用对人类大脑的理解来开发神经形态计算机。模拟一个完整的人类大脑需要一台比现在强大一千倍的超级计算机,这鼓励了当前对神经形态计算机的关注。欧洲委员会已经拨款13亿美元用于这个项目。

Other research with implications for neuromorphic engineering involves the BRAIN Initiative[25] and the TrueNorth chip from IBM.[26] Neuromorphic devices have also been demonstrated using nanocrystals, nanowires, and conducting polymers.[27]

Other research with implications for neuromorphic engineering involves the BRAIN InitiativeNeuromorphic computing: The machine of a new soul, The Economist, 2013-08-03 and the TrueNorth chip from IBM. Neuromorphic devices have also been demonstrated using nanocrystals, nanowires, and conducting polymers.

其他与神经形态工程有关的研究还包括 BRAIN initiativity/euromorphic computing: The machine of a new soul,The Economist,2013-08-03 and The TrueNorth chip from IBM。神经形态学设备也已经被证明使用纳米晶体、纳米线和导电聚合物。

Intel unveiled its neuromorphic research chip, called “Loihi”, in October 2017. The chip uses an asynchronous spiking neural network (SNN) to implement adaptive self-modifying event-driven fine-grained parallel computations used to implement learning and inference with high efficiency.[28][29]

Intel unveiled its neuromorphic research chip, called “Loihi”, in October 2017. The chip uses an asynchronous spiking neural network (SNN) to implement adaptive self-modifying event-driven fine-grained parallel computations used to implement learning and inference with high efficiency.

2017年10月,英特尔公布了其神经形态研究芯片“ Loihi”。该芯片采用异步脉冲神经网络(SNN)实现自适应自修改事件驱动的细粒度并行计算,实现了高效的学习和推理。

IMEC, a Belgium-based nanoelectronics research center, demonstrated the world's first self-learning neuromorphic chip. The brain-inspired chip, based on OxRAM technology, has the capability of self-learning and has been demonstrated to have the ability to compose music.[30] IMEC released the 30-second tune composed by the prototype. The chip was sequentially loaded with songs in the same time signature and style. The songs were old Belgian and French flute minuets, from which the chip learned the rules at play and then applied them.[31]

IMEC, a Belgium-based nanoelectronics research center, demonstrated the world's first self-learning neuromorphic chip. The brain-inspired chip, based on OxRAM technology, has the capability of self-learning and has been demonstrated to have the ability to compose music. IMEC released the 30-second tune composed by the prototype. The chip was sequentially loaded with songs in the same time signature and style. The songs were old Belgian and French flute minuets, from which the chip learned the rules at play and then applied them.

比利时的一个纳米电子学研究中心 IMEC 展示了世界上第一个自学习神经形态芯片。这种基于 OxRAM 技术的大脑启发芯片具有自学习能力,并已被证明具有创作音乐的能力。IMEC 发布了由原型机谱写的30秒曲调。芯片按顺序加载同时签名和风格的歌曲。歌曲是古老的比利时和法国长笛小步舞曲,筹码从中学习游戏规则,然后应用它们。

The Blue Brain Project, led by Henry Markram, aims to build biologically detailed digital reconstructions and simulations of the mouse brain. The Blue Brain Project has created in silico models of rodent brains, while attempting to replicate as many details about its biology as possible. The supercomputer-based simulations offer new perspectives on understanding the structure and functions of the brain.

The Blue Brain Project, led by Henry Markram, aims to build biologically detailed digital reconstructions and simulations of the mouse brain. The Blue Brain Project has created in silico models of rodent brains, while attempting to replicate as many details about its biology as possible. The supercomputer-based simulations offer new perspectives on understanding the structure and functions of the brain.

由亨利 · 马克拉姆领导的蓝脑计划旨在建立小鼠大脑的生物细节数字重建和模拟。蓝色大脑项目已经在啮齿动物大脑的电子模型中创建,同时试图尽可能多地复制其生物学细节。基于超级计算机的模拟为理解大脑的结构和功能提供了新的视角。

The European Union funded a series of projects at the University of Heidelberg, which led to the development of BrainScaleS (brain-inspired multiscale computation in neuromorphic hybrid systems), a hybrid analog neuromorphic supercomputer located at Heidelberg University, Germany. It was developed as part of the Human Brain Project neuromorphic computing platform and is the complement to the SpiNNaker supercomputer (which is based on digital technology). The architecture used in BrainScaleS mimics biological neurons and their connections on a physical level; additionally, since the components are made of silicon, these model neurons operate on average 864 times (24 hours of real time is 100 seconds in the machine simulation) that of their biological counterparts.[32]

The European Union funded a series of projects at the University of Heidelberg, which led to the development of BrainScaleS (brain-inspired multiscale computation in neuromorphic hybrid systems), a hybrid analog neuromorphic supercomputer located at Heidelberg University, Germany. It was developed as part of the Human Brain Project neuromorphic computing platform and is the complement to the SpiNNaker supercomputer (which is based on digital technology). The architecture used in BrainScaleS mimics biological neurons and their connections on a physical level; additionally, since the components are made of silicon, these model neurons operate on average 864 times (24 hours of real time is 100 seconds in the machine simulation) that of their biological counterparts.

欧盟资助了海德堡大学的一系列项目,这些项目导致了 BrainScaleS (神经形态混合系统中受大脑启发的多尺度计算)的发展,这是一台位于德国海德堡大学的混合模拟神经形态超级计算机。它是作为人脑计划神经形态计算平台的一部分而开发的,是 SpiNNaker 超级计算机(基于数字技术)的补充。大脑尺度中使用的体系结构模拟了生物神经元及其在物理层面上的连接; 此外,由于这些组件是由硅制成的,这些模型神经元平均运行864倍(在机器模拟中,24小时的实时时间是100秒)。

Neuromorphic sensors

神经形态传感器

The concept of neuromorphic systems can be extended to sensors (not just to computation). An example of this applied to detecting light is the retinomorphic sensor or, when employed in an array, the event camera.

The concept of neuromorphic systems can be extended to sensors (not just to computation). An example of this applied to detecting light is the retinomorphic sensor or, when employed in an array, the event camera.

神经形态系统的概念可以扩展到传感器(而不仅仅是计算)。用于检测光线的一个例子是视网膜变形传感器,或者在阵列中使用的事件摄像机。

Ethical considerations

伦理问题

While the interdisciplinary concept of neuromorphic engineering is relatively new, many of the same ethical considerations apply to neuromorphic systems as apply to human-like machines and artificial intelligence in general. However, the fact that neuromorphic systems are designed to mimic a human brain gives rise to unique ethical questions surrounding their usage.

While the interdisciplinary concept of neuromorphic engineering is relatively new, many of the same ethical considerations apply to neuromorphic systems as apply to human-like machines and artificial intelligence in general. However, the fact that neuromorphic systems are designed to mimic a human brain gives rise to unique ethical questions surrounding their usage.

虽然神经形态工程的跨学科概念相对较新,但许多同样的伦理考虑适用于神经形态系统,就像适用于类人机器和一般人工智能一样。然而,神经形态系统是为了模仿人类大脑而设计的这一事实引起了围绕其使用的独特的伦理问题。

However, the practical debate is that neuromorphic hardware as well as artificial "neural networks" are immensely simplified models of how the brain operates or processes information at a much lower complexity in terms of size and functional technology and a much more regular structure in terms of connectivity. Comparing neuromorphic chips to the brain is a very crude comparison similar to comparing a plane to a bird just because they both have wings and a tail. The fact is that neural cognitive systems are many orders of magnitude more energy- and compute-efficient than current state-of-the-art AI and neuromorphic engineering is an attempt to narrow this gap by inspiring from the brain's mechanism just like many engineering designs have bio-inspired features.

However, the practical debate is that neuromorphic hardware as well as artificial "neural networks" are immensely simplified models of how the brain operates or processes information at a much lower complexity in terms of size and functional technology and a much more regular structure in terms of connectivity. Comparing neuromorphic chips to the brain is a very crude comparison similar to comparing a plane to a bird just because they both have wings and a tail. The fact is that neural cognitive systems are many orders of magnitude more energy- and compute-efficient than current state-of-the-art AI and neuromorphic engineering is an attempt to narrow this gap by inspiring from the brain's mechanism just like many engineering designs have bio-inspired features.

然而,实际上的争论是,神经形态硬件和人工“神经网络”是大脑如何运作或处理信息的极其简化的模型,在大小和功能技术方面的复杂性要低得多,在连接方面的结构则更加规则。将神经形态芯片与大脑进行比较是一种非常粗糙的比较,类似于仅仅因为一架飞机有翅膀和一条尾巴就将它与一只鸟进行比较。事实上,神经认知系统比当前最先进的人工智能具有更多的能量和计算效率,而神经形态工程是一种通过从大脑机制中激发灵感来缩小这种差距的尝试,就像许多工程设计具有生物启发的特征一样。数量级。

Democratic concerns

公众担忧

Significant ethical limitations may be placed on neuromorphic engineering due to public perception.[33] Special Eurobarometer 382: Public Attitudes Towards Robots, a survey conducted by the European Commission, found that 60% of European Union citizens wanted a ban of robots in the care of children, the elderly, or the disabled. Furthermore, 34% were in favor of a ban on robots in education, 27% in healthcare, and 20% in leisure. The European Commission classifies these areas as notably “human.” The report cites increased public concern with robots that are able to mimic or replicate human functions. Neuromorphic engineering, by definition, is designed to replicate the function of the human brain.[34]

Significant ethical limitations may be placed on neuromorphic engineering due to public perception. Special Eurobarometer 382: Public Attitudes Towards Robots, a survey conducted by the European Commission, found that 60% of European Union citizens wanted a ban of robots in the care of children, the elderly, or the disabled. Furthermore, 34% were in favor of a ban on robots in education, 27% in healthcare, and 20% in leisure. The European Commission classifies these areas as notably “human.” The report cites increased public concern with robots that are able to mimic or replicate human functions. Neuromorphic engineering, by definition, is designed to replicate the function of the human brain.

由于公众的认知,神经形态工程学可能会受到严重的伦理限制。欧盟委员会进行的一项调查发现,60% 的欧盟公民希望禁止照顾儿童、老人或残疾人的机器人。此外,34% 的人支持禁止机器人用于教育,27% 的人支持医疗保健,20% 的人支持休闲。欧盟委员会将这些地区明显归类为“人类”报告指出,公众越来越关注能够模仿或复制人类功能的机器人。神经形态工程,顾名思义,是为了复制人脑的功能而设计的。

The democratic concerns surrounding neuromorphic engineering are likely to become even more profound in the future. The European Commission found that EU citizens between the ages of 15 and 24 are more likely to think of robots as human-like (as opposed to instrument-like) than EU citizens over the age of 55. When presented an image of a robot that had been defined as human-like, 75% of EU citizens aged 15–24 said it corresponded with the idea they had of robots while only 57% of EU citizens over the age of 55 responded the same way. The human-like nature of neuromorphic systems, therefore, could place them in the categories of robots many EU citizens would like to see banned in the future.[34]

The democratic concerns surrounding neuromorphic engineering are likely to become even more profound in the future. The European Commission found that EU citizens between the ages of 15 and 24 are more likely to think of robots as human-like (as opposed to instrument-like) than EU citizens over the age of 55. When presented an image of a robot that had been defined as human-like, 75% of EU citizens aged 15–24 said it corresponded with the idea they had of robots while only 57% of EU citizens over the age of 55 responded the same way. The human-like nature of neuromorphic systems, therefore, could place them in the categories of robots many EU citizens would like to see banned in the future.

围绕神经形态工程的民主关注可能在未来变得更加深刻。欧盟委员会(European Commission)发现,15至24岁的欧盟公民比55岁以上的欧盟公民更有可能认为机器人像人(而不是像仪器)。当看到一张被定义为“类人”的机器人图片时,年龄在15岁至24岁之间的欧盟公民中有75% 的人表示,这与他们对机器人的想法相符,而55岁以上的欧盟公民中只有57% 的人有同样的反应。因此,类似人类的神经形态系统,可以把它们归入许多欧盟公民希望在未来禁止使用的机器人类别。

Personhood

人格问题

As neuromorphic systems have become increasingly advanced, some scholars模板:Who have advocated for granting personhood rights to these systems. If the brain is what grants humans their personhood, to what extent does a neuromorphic system have to mimic the human brain to be granted personhood rights? Critics of technology development in the Human Brain Project, which aims to advance brain-inspired computing, have argued that advancement in neuromorphic computing could lead to machine consciousness or personhood.[35] If these systems are to be treated as people, critics argue, then many tasks humans perform using neuromorphic systems, including the act of termination of neuromorphic systems, may be morally impermissible as these acts would violate the autonomy of the neuromorphic systems.[36]

As neuromorphic systems have become increasingly advanced, some scholars have advocated for granting personhood rights to these systems. If the brain is what grants humans their personhood, to what extent does a neuromorphic system have to mimic the human brain to be granted personhood rights? Critics of technology development in the Human Brain Project, which aims to advance brain-inspired computing, have argued that advancement in neuromorphic computing could lead to machine consciousness or personhood. If these systems are to be treated as people, critics argue, then many tasks humans perform using neuromorphic systems, including the act of termination of neuromorphic systems, may be morally impermissible as these acts would violate the autonomy of the neuromorphic systems.

随着神经形态系统的日益发展,一些学者主张赋予这些系统人格权。如果是大脑赋予了人类人格,那么神经形态系统在多大程度上必须模仿人类大脑才能被赋予人格权利?“人脑计划”旨在推进以大脑为灵感的计算机技术发展,该计划的批评者认为,神经形态计算机技术的进步可能导致机器意识或人格的形成。批评家认为,如果这些系统被当作人来对待,那么人类使用神经形态系统执行的许多任务,包括终止神经形态系统的行为,可能在道德上是不允许的,因为这些行为将违反神经形态系统的自主性。

Dual use (military applications)

The Joint Artificial Intelligence Center, a branch of the U.S. military, is a center dedicated to the procurement and implementation of AI software and neuromorphic hardware for combat use. Specific applications include smart headsets/goggles and robots. JAIC intends to rely heavily on neuromorphic technology to connect "every fighter every shooter" within a network of neuromorphic-enabled units.

The Joint Artificial Intelligence Center, a branch of the U.S. military, is a center dedicated to the procurement and implementation of AI software and neuromorphic hardware for combat use. Specific applications include smart headsets/goggles and robots. JAIC intends to rely heavily on neuromorphic technology to connect "every fighter every shooter" within a network of neuromorphic-enabled units.

军民两用联合人工智能中心是美国军队的一个分支,专门从事采购和实施用于战斗的人工智能软件和神经形态硬件。具体应用包括智能耳机/护目镜和机器人。JAIC 打算严重依赖神经形态技术来连接神经形态单位网络中的“每个战士每个射手”。

Legal considerations

法律问题

Skeptics have argued that there is no way to apply the electronic personhood, the concept of personhood that would apply to neuromorphic technology, legally. In a letter signed by 285 experts in law, robotics, medicine, and ethics opposing a European Commission proposal to recognize “smart robots” as legal persons, the authors write, “A legal status for a robot can’t derive from the Natural Person model, since the robot would then hold human rights, such as the right to dignity, the right to its integrity, the right to remuneration or the right to citizenship, thus directly confronting the Human rights. This would be in contradiction with the Charter of Fundamental Rights of the European Union and the Convention for the Protection of Human Rights and Fundamental Freedoms.”[37]

Skeptics have argued that there is no way to apply the electronic personhood, the concept of personhood that would apply to neuromorphic technology, legally. In a letter signed by 285 experts in law, robotics, medicine, and ethics opposing a European Commission proposal to recognize “smart robots” as legal persons, the authors write, “A legal status for a robot can’t derive from the Natural Person model, since the robot would then hold human rights, such as the right to dignity, the right to its integrity, the right to remuneration or the right to citizenship, thus directly confronting the Human rights. This would be in contradiction with the Charter of Fundamental Rights of the European Union and the Convention for the Protection of Human Rights and Fundamental Freedoms.”

怀疑论者认为,在法律上没有办法应用电子人格,这个人格概念将适用于神经形态技术。在一封由285名法律、机器人、医学和伦理学专家签名的信中,作者们反对欧盟委员会承认“智能机器人”为法人的提议,他们写道,“机器人的法律地位不能从自然人模型中推导出来,因为机器人将拥有人权,如尊严权、完整权、报酬权或公民权,从而直接面对人权。这将有悖于《欧洲联盟基本权利宪章和《保护人权和基本自由公约》。”

Ownership and property rights

所有权及财产权问题

There is significant legal debate around property rights and artificial intelligence. In Acohs Pty Ltd v. Ucorp Pty Ltd, Justice Christopher Jessup of the Federal Court of Australia found that the source code for Material Safety Data Sheets could not be copyrighted as it was generated by a software interface rather than a human author.[38] The same question may apply to neuromorphic systems: if a neuromorphic system successfully mimics a human brain and produces a piece of original work, who, if anyone, should be able to claim ownership of the work?[39]

There is significant legal debate around property rights and artificial intelligence. In Acohs Pty Ltd v. Ucorp Pty Ltd, Justice Christopher Jessup of the Federal Court of Australia found that the source code for Material Safety Data Sheets could not be copyrighted as it was generated by a software interface rather than a human author. The same question may apply to neuromorphic systems: if a neuromorphic system successfully mimics a human brain and produces a piece of original work, who, if anyone, should be able to claim ownership of the work?

围绕财产权和人工智能有着重大的法律争论。在 Acohs Pty Ltd 诉 Ucorp Pty Ltd 一案中,澳大利亚联邦法院的克里斯托弗 · 杰瑟普法官发现,材料安全数据表的源代码不能受版权保护,因为它是由软件界面而不是人工作者生成的。同样的问题可能也适用于神经形态系统: 如果一个神经形态系统成功地模仿了人类的大脑并产生了一部原创作品,那么谁,如果有人,应该声称拥有这部作品的所有权?

Neuromemristive systems

神经记忆电阻系统

Neuromemristive systems are a subclass of neuromorphic computing systems that focus on the use of memristors to implement neuroplasticity. While neuromorphic engineering focuses on mimicking biological behavior, neuromemristive systems focus on abstraction.[40] For example, a neuromemristive system may replace the details of a cortical microcircuit's behavior with an abstract neural network model.[41]

Neuromemristive systems are a subclass of neuromorphic computing systems that focus on the use of memristors to implement neuroplasticity. While neuromorphic engineering focuses on mimicking biological behavior, neuromemristive systems focus on abstraction. For example, a neuromemristive system may replace the details of a cortical microcircuit's behavior with an abstract neural network model.C. Merkel and D. Kudithipudi, "Neuromemristive extreme learning machines for pattern classification," ISVLSI, 2014.

神经记忆电阻系统是神经形态计算系统的一个亚类,主要研究利用记忆电阻器实现神经可塑性。神经形态工程的重点是模拟生物行为,而神经记忆电阻系统的重点是提取。例如,一个神经记忆系统可以用一个抽象的神经网络模型取代皮层微电路的行为细节。默克尔和 d. Kudithipudi,“用于模式分类的神经记忆极端学习机器”,ISVLSI,2014。

There exist several neuron inspired threshold logic functions[6] implemented with memristors that have applications in high level pattern recognition applications. Some of the applications reported recently include speech recognition,[42] face recognition[43] and object recognition.[44] They also find applications in replacing conventional digital logic gates.[45][46]

There exist several neuron inspired threshold logic functions implemented with memristors that have applications in high level pattern recognition applications. Some of the applications reported recently include speech recognition, face recognition and object recognition. They also find applications in replacing conventional digital logic gates.

利用记忆电阻器实现的神经元启发阈值逻辑函数在高级模式识别中有着广泛的应用。最近报道的一些应用包括语音识别、人脸识别和物体识别。它们还可以用来取代传统的数字逻辑门。

For ideal passive memristive circuits there is an exact equation (Caravelli-Traversa-Di Ventra equation) for the internal memory of the circuit:[47]

For ideal passive memristive circuits there is an exact equation (Caravelli-Traversa-Di Ventra equation) for the internal memory of the circuit:

对于理想的无源记忆电路,电路的内部记忆有一个精确的方程(Caravelli-Traversa-Di Ventra 方程) :

[math]\displaystyle{ \frac{d}{dt} \vec{W} = \alpha \vec{W}-\frac{1}{\beta} (I+\xi \Omega W)^{-1} \Omega \vec S }[/math]
\frac{d}{dt} \vec{W} = \alpha \vec{W}-\frac{1}{\beta} (I+\xi \Omega W)^{-1} \Omega \vec S
\frac{d}{dt} \vec{W} = \alpha \vec{W}-\frac{1}{\beta} (I+\xi \Omega W)^{-1} \Omega \vec S

as a function of the properties of the physical memristive network and the external sources. In the equation above, [math]\displaystyle{ \alpha }[/math] is the "forgetting" time scale constant, [math]\displaystyle{ \xi=r-1 }[/math] and [math]\displaystyle{ r=\frac{R_\text{off}}{R_\text{on}} }[/math] is the ratio of off and on values of the limit resistances of the memristors, [math]\displaystyle{ \vec S }[/math] is the vector of the sources of the circuit and [math]\displaystyle{ \Omega }[/math] is a projector on the fundamental loops of the circuit. The constant [math]\displaystyle{ \beta }[/math] has the dimension of a voltage and is associated to the properties of the memristor; its physical origin is the charge mobility in the conductor. The diagonal matrix and vector [math]\displaystyle{ W=\operatorname{diag}(\vec W) }[/math] and [math]\displaystyle{ \vec W }[/math] respectively, are instead the internal value of the memristors, with values between 0 and 1. This equation thus requires adding extra constraints on the memory values in order to be reliable.

as a function of the properties of the physical memristive network and the external sources. In the equation above, \alpha is the "forgetting" time scale constant, \xi=r-1 and r=\frac{R_\text{off}}{R_\text{on}} is the ratio of off and on values of the limit resistances of the memristors, \vec S is the vector of the sources of the circuit and \Omega is a projector on the fundamental loops of the circuit. The constant \beta has the dimension of a voltage and is associated to the properties of the memristor; its physical origin is the charge mobility in the conductor. The diagonal matrix and vector W=\operatorname{diag}(\vec W) and \vec W respectively, are instead the internal value of the memristors, with values between 0 and 1. This equation thus requires adding extra constraints on the memory values in order to be reliable.

作为物理记忆网络和外部源的性质的函数。在上述方程中,α 是“遗忘”时间尺度常数,xi = r-1,r = frac { r _ text { off }{ on }{ r _ text { on }}是记忆电阻器极限电阻的开关和开关值之比,vec s 是电路源的矢量,Omega 是电路基本环路的投影仪。常数 β 具有电压的尺寸,与记忆电阻器的特性有关; 它的物理起源是导体中的电荷迁移率。对角矩阵和向量 w = 操作者名{ diag }(vec w)和 vec w 分别是记忆电阻器的内值,值在0到1之间。因此,这个等式需要在内存值上添加额外的约束,以保证可靠性。

See also

相关词条

模板:Portal bar

References

模板:Reflist

External links

模板:Commons category


  • Telluride Neuromorphic Engineering Workshop
  • CapoCaccia Cognitive Neuromorphic Engineering Workshop
  • Institute of Neuromorphic Engineering
  • INE news site.
  • Frontiers in Neuromorphic Engineering Journal
  • Computation and Neural Systems department at the California Institute of Technology.
  • Human Brain Project official site
  • Building a Silicon Brain: Computer chips based on biological neurons may help simulate larger and more-complex brain models. May 1, 2019. SANDEEP RAVINDRAN

= = 外部链接 =

  • 碲化物神经形态工程工作室
  • CapoCaccia 认知神经形态工程工作室
  • 神经形态工程研究所
  • INE 新闻站点。
  • 《神经形态工程学前沿》
  • 加州理工学院计算与神经系统系。
  • 人脑项目官方网站
  • 打造硅脑: 基于生物神经元的计算机芯片可能有助于模拟更大、更复杂的大脑模型。2019年5月1日。SANDEEP RAVINDRAN

模板:Differentiable computing 模板:Authority control

Category:Electrical engineering Category:Neuroscience

Category:Artificial intelligence Category:Robotics

类别: 电气工程类别: 神经科学 * 类别: 人工智能类别: 机器人


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