AERI's Military robot SOLDIERS
for
Chemical or Biological Battlefields
Military engagement of AERI's consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer in chemical or biological warfare is a key war economic and humanitarian strategy for localized warfare in next-generation warfare
AERI interviewed Professor Kamuro, who specializes in theoretical quantum physics and brain science, about the state-of-the-art brain implant-type state of art AERI's biocomputer that AERI scientists team is researching to weigh in
Quantum Brain Chipset Review
to Quantum Brain& biocomputer
(AERI Quantum Brain Science and Technologies)
Q uantum Physicist and Brain Scientist
Visiting Professor of Quantum Physics,
California Institute of Technology
IEEE-USA Fellow
American Physical Society-USA Fellow
PhD. & Dr. Kazuto Kamuro
AERI:Artificial Evolution Research Institute
Pasadena, California
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1.What are the next-generation weapons that can play a leading role in chemical or biological warfare?
The topic of chemical and biological warfare is highly sensitive and raises significant ethical and security concerns. It is important to approach this topic responsibly and note that the use of such weapons is universally condemned and prohibited under various international agreements and treaties. However, Professor Kamuro can provide information on some areas of scientific and technological advancements that could have implications for potential next-generation weapons in chemical or biological warfare, even though discussing specific weapons or capabilities should be approached with caution.
(1) Advanced Chemical Agents: Advances in chemistry and materials science could lead to the development of novel chemical agents with increased potency, enhanced persistence, or improved delivery mechanisms. These agents could potentially be more challenging to detect, treat, or neutralize. However, it is crucial to reiterate that the use of chemical weapons is strictly prohibited under the Chemical Weapons Convention.
(2) Enhanced Dissemination Methods: Innovations in delivery systems could enable more efficient and targeted dissemination of chemical or biological agents. This might involve technologies such as specialized aerosol devices, drones, or unmanned vehicles for controlled release in specific areas or against particular targets.
(3) Genetic Engineering and Synthetic Biology: Advances in genetic engineering and synthetic biology could potentially enable the modification or creation of highly virulent or drug-resistant strains of pathogens. This area of research raises concerns about the potential misuse of scientific knowledge and capabilities for the development of bio-agents with enhanced pathogenicity or altered characteristics.
(4) Dual-Use Technologies: Technologies developed for peaceful purposes, such as medical research, agriculture, or environmental monitoring, could potentially be misused for chemical or biological warfare. Dual-use technologies, which have legitimate civilian applications but can also be adapted for harmful purposes, present challenges in monitoring and controlling the potential misuse of these advancements.
(5) Biosecurity Risks: As scientific and technological knowledge expands, so does the need for robust biosecurity measures to prevent the illicit acquisition or theft of dangerous pathogens, toxins, or the necessary expertise. Ensuring strong security and effective control over high-containment laboratories and facilities is crucial to prevent unauthorized access to dangerous materials.
“It is important to emphasize that the international community is actively engaged in preventing the development, production, and use of chemical and biological weapons. Various international agreements and treaties, such as the Chemical Weapons Convention and the Biological Weapons Convention, aim to prevent the proliferation and use of such weapons. Additionally, efforts are underway to enhance biosecurity, strengthen disease surveillance, and develop countermeasures to mitigate the risks associated with chemical and biological warfare.
As a result of deep research on means to solve the above various problems, military engagement of AERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer in chemical or biological warfare is a key war economic and humanitarian strategy for localized warfare in next-generation warfare,” predicted Processor Kamuro.
2.Chemical weapons
(1) A chemical weapon (CW) is a specialized munition that uses chemicals formulated to inflict death or harm on humans. According to the Organisation for the Prohibition of Chemical Weapons (OPCW), this can be any chemical compound intended as a weapon "or its precursor that can cause death, injury, temporary incapacitation or sensory irritation through its chemical action. Munitions or other delivery devices designed to deliver chemical weapons, whether filled or unfilled, are also considered weapons themselves."
(2) Chemical weapons are classified as weapons of mass destruction (WMD), though they are distinct from nuclear weapons, biological weapons, and radiological weapons. All may be used in warfare and are known by the military acronym NBC (for nuclear, biological, and chemical warfare). Weapons of mass destruction are distinct from conventional weapons, which are primarily effective due to their explosive, kinetic, or incendiary potential. Chemical weapons can be widely dispersed in gas, liquid and solid forms, and may easily afflict others than the intended targets. Nerve gas, tear gas and pepper spray are three modern examples of chemical weapons.
(3) Lethal unitary chemical agents and munitions are extremely volatile and they constitute a class of hazardous chemical weapons that have been stockpiled by many nations. Unitary agents are effective on their own and do not require mixing with other agents. The most dangerous of these are nerve agents (GA, GB, GD, and VX) and vesicant (blister) agents, which include formulations of sulfur mustard such as H, HT, and HD. They all are liquids at normal room temperature, but become gaseous when released. Widely used during the World War I, the effects of so-called mustard gas, phosgene gas and others caused lung searing, blindness, death and maiming.
(4) During World War II the Nazi regime used a commercial hydrogen cyanide blood agent trade-named Zyklon B to commit industrialised genocide against Jews and other targeted populations in large gas chambers.[4] The Holocaust resulted in the largest death toll to chemical weapons in history.
(5) As of 2016, CS gas and pepper spray remain in common use for policing and riot control; CS and pepper spray are considered non-lethal weapons. Under the Chemical Weapons Convention (1993), there is a legally binding, worldwide ban on the production, stockpiling, and use of chemical weapons and their precursors. However, large stockpiles of chemical weapons continue to exist, usually justified as a precaution against possible use by an aggressor. Continued storage of these chemical weapons is a hazard, as many of the weapons are now more than 50 years old, raising risks significantly. The United States is now undergoing measures to dispose of their chemical weapons in a safe manner.
(6) Chemical warfare involves using the toxic properties of chemical substances as weapons. This type of warfare is distinct from nuclear warfare and biological warfare, which together make up NBC, the military initialism for Nuclear, Biological, and Chemical (warfare or weapons). None of these fall under the term conventional weapons, which are primarily effective because of their destructive potential. Chemical warfare does not depend upon explosive force to achieve an objective. It depends upon the unique properties of the chemical agent weaponized.
(7) A lethal agent is designed to injure, incapacitate, or kill an opposing force, or deny unhindered use of a particular area of terrain. Defoliants are used to quickly kill vegetation and deny its use for cover and concealment. Chemical warfare can also be used against agriculture and livestock to promote hunger and starvation. Chemical payloads can be delivered by remote controlled container release, aircraft, or rocket. Protection against chemical weapons includes proper equipment, training, and decontamination measures.
3.Biological weapons
Biological weapons, also known as bioweapons or bio-agents, are weapons that use pathogens (bacteria, viruses, or other microorganisms) or toxins derived from living organisms to intentionally cause harm to humans, animals, or plants. These weapons exploit the biological processes and vulnerabilities of living organisms to achieve their destructive effects. Here are some key points about biological weapons:
(1) Types of Biological Weapons: Biological weapons can be categorized into three main types: pathogenic microorganisms, toxins, and genetically modified organisms (GMOs). Pathogenic microorganisms include bacteria, viruses, and fungi that cause diseases. Toxins are substances produced by living organisms that are toxic to humans or animals. GMOs are genetically modified microorganisms that have been engineered to possess enhanced virulence or resistance to treatment.
(2) Characteristics and Effects: Biological weapons can have various characteristics and effects. They can be highly contagious, easily transmitted from person to person, and difficult to detect or control. They can cause a range of illnesses and symptoms, including respiratory, gastrointestinal, and neurological disorders. The effects of a biological attack can include illness, death, disruption of public health systems, economic damage, and psychological impact.
(3) Potential Agents: Various microorganisms and toxins have been investigated or used as potential biological weapons. Some examples include anthrax (Bacillus anthracis), botulinum toxin, smallpox virus, plague bacteria (Yersinia pestis), tularemia bacteria (Francisella tularensis), and viral hemorrhagic fevers like Ebola and Marburg viruses. However, it's important to note that discussing specific agents and their characteristics should be approached with caution due to their potential misuse.
(4) Deployment and Dissemination: Biological weapons can be deployed and disseminated through different methods, such as aerosol sprays, contaminated food or water supplies, contaminated vectors (insects or animals), or direct contact with infected individuals or materials. The choice of dissemination method depends on the desired effect, the characteristics of the agent, and the intended target population.
(5) International Prohibitions and Treaties: The use of biological weapons is universally condemned and prohibited under various international agreements and treaties. The Biological Weapons Convention (BWC), which entered into force in 1975, bans the development, production, acquisition, transfer, and stockpiling of biological weapons. The BWC has been ratified by a large number of countries, aiming to prevent the use of biological agents for warfare.
(6) Dual-Use Nature: One challenge with biological weapons is their dual-use nature. Many of the agents and techniques used in biological weapons research and development can also have legitimate civilian applications, such as in the fields of medicine, agriculture, or biotechnology. This dual-use aspect raises concerns about the potential misuse of materials, expertise, or technologies for illicit purposes.
(7) Biosecurity and Preparedness: To mitigate the risks associated with biological weapons, biosecurity measures, and preparedness efforts are crucial. These include strengthening disease surveillance, enhancing laboratory safety and security, improving public health systems, developing countermeasures (vaccines, antiviral drugs, etc.), and promoting international cooperation in monitoring and preventing the proliferation of biological weapons.
“It's important to emphasize that the use of biological weapons is universally considered unethical and illegal. International efforts focus on preventing the development, production, and use of these weapons, as well as enhancing preparedness to respond to potential biological threats,”' Professor Kamuro concludes.
4. Can the robot SOLDIERS be the mainstays i.e. weapons and firearms against a chemical or biological close combat or warfare in chemical or biological battlefield?
I n the context of a chemical or biological battlefield, the use of AERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer as weapons or firearms is highly speculative and raises significant ethical, legal, and technical considerations. It's important to note that the deployment of any form of autonomous robots in combat, including in chemical or biological warfare, raises complex questions and challenges. Here are some points to consider:
(1) Chemical or Biological Protection: robot SOLDIERS could potentially be designed to operate in environments contaminated by chemical or biological agents without risking human lives. Their lack of vulnerability to such agents could be an advantage, allowing them to perform tasks such as reconnaissance, decontamination, or handling hazardous materials.
(2) Remote Operations: the robot SOLDIERS can be controlled remotely, allowing operators to remain at a safe distance from the chemical or biological hazards. This could facilitate command and control functions while minimizing human exposure to potentially harmful substances.
(3) Sensor Integration: rthe obot SOLDIERS can be equipped with advanced sensor technologies to detect and identify chemical or biological agents. These sensors could help in monitoring, identifying contaminated areas, and providing valuable data for response and mitigation efforts.
(4) Decontamination Capabilities: Robots with specialized tools and equipment could be deployed for decontamination purposes in chemical or biological warfare scenarios. Their lack of susceptibility to the agents could enable them to perform tasks that might be hazardous to human personnel.
(5) Limitations and Challenges: Deploying the robot SOLDIERS in chemical or biological warfare would present significant challenges. Designing robots with the necessary capabilities to effectively operate in such environments, ensuring their safety and reliability, and addressing potential technological vulnerabilities would require extensive research and development.
“It's important to note that the use of chemical and biological weapons is universally condemned and strictly prohibited under international agreements. The focus of international efforts is on preventing the use of such weapons and ensuring their peaceful and beneficial applications.
Furthermore, the development and deployment of autonomous robots in combat, particularly in relation to chemical or biological warfare, would require careful ethical evaluation, adherence to legal frameworks, and consideration of the potential consequences for human lives and global security.
Please be aware that the use of chemical or biological weapons is highly unethical and illegal, and any discussions about their deployment should strictly be in the context of understanding the international efforts to prevent their use and promote global security,” concluded Professor Kamuro.
5. Various optional equipment required for AERI's consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer in chemical close combat or warfare in chemical battlefield
I n chemical close combat or warfare, the essential equipment for AERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS would need to prioritize protection and functionality in a chemically hazardous environment. Here are some key equipment considerations for the robot SOLDIERS operating in a chemical battlefield:
(1) Protective Enclosure System: the robot SOLDIERS equipped with a brain implant-type biocomputer would require a fully sealed and airtight protective enclosure to shield their internal components from chemical agents. The enclosure should be constructed from materials resistant to the specific chemical agents present in the battlefield.
(2) Chemical Detectors System: Integrated chemical detectors are crucial for the robot SOLDIERS to identify and analyze the types and concentrations of chemical agents in their surroundings. These detectors would enable the robots to assess the level of threat and take appropriate actions.
(3) Filtration System: A highly efficient filtration system is necessary to ensure the robot SOLDIERS have a supply of clean air within their protective enclosure. This system should be capable of removing or neutralizing chemical agents from the air, providing a safe breathing environment for the robot's internal components.
(4) Decontamination System: To maintain functionality and minimize contamination risks, robot SOLDIERS should have a built-in decontamination mechanism. This mechanism may involve various methods, such as high-pressure water jets, chemical neutralizers, or other decontamination agents specific to the encountered chemical agents.
(5) Hazardous Material Handling System: the robot SOLDIERS might need specialized tools and appendages designed to handle and manipulate hazardous materials encountered in a chemical battlefield. These tools could include robotic arms equipped with gripping mechanisms or chemical-resistant containers for containment and disposal of chemical substances.
(6) Enhanced Vision Systems: In a chemically obscured environment, robot SOLDIERS would require advanced vision systems, such as infrared cameras or LIDAR (Light Detection and Ranging), to navigate and locate targets effectively. These systems should be able to penetrate chemical smoke or fog and provide real-time situational awareness.
(7) Communication Equipment System: Reliable communication systems are essential for coordination and sharing information between robot SOLDIERS and human operators or other units. These systems should be resistant to chemical interference and capable of encrypted communication to maintain security.
(8) Power Supply and Redundancy System: A robust and redundant power supply is vital to ensure continuous operation of robot SOLDIERS in the field. Multiple power sources, such as batteries or fuel cells, along with efficient power management systems, would be necessary to support extended missions.
Note: It's important to note that the development and deployment of AERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS in chemical warfare scenarios raise ethical and legal concerns. The use of autonomous systems in such contexts requires careful consideration to minimize risks to civilians and ensure compliance with international humanitarian law.
6.Various optional equipment system required for AERI's consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer in biological close combat or warfare in biological battlefield
In a hypothetical scenario involving AERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer in a biological close combat or warfare environment, several essential equipment considerations would be relevant. Please keep in mind that the concept of "biological close combat" or warfare involving robots is purely speculative, and the use of such technology in actual conflict scenarios raises ethical and legal concerns. Nonetheless, here are some key equipment considerations for robot SOLDIERS in a biological battlefield:
(1) Protective Enclosure System: Similar to chemical warfare, AERI's consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer would require a sealed and airtight protective enclosure to safeguard their internal components from biological agents. The enclosure should be constructed from materials that provide a high level of biological protection.
(2) Biological Sensors System: Integrated biological sensors would be crucial for AERI's consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer to detect and identify biological agents present in the environment. These sensors would enable the robots to analyze the type and concentration of the agents, allowing for appropriate responses and measures to be taken.
(3) Filtration and Air Purification System: An advanced filtration and air purification system would be necessary to ensure a clean and safe internal environment for the robot SOLDIERS. The system should be capable of removing and neutralizing biological agents from the air supply within the protective enclosure.
(4) Decontamination System: To maintain functionality and minimize contamination risks, AERI's consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer would require a decontamination mechanism. This mechanism may involve various methods, such as chemical disinfection or heat treatment, to eliminate or neutralize biological agents that may have come into contact with the robot.
(5) Hazardous Material Handling Tools: AERI's consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer might need specialized tools and appendages designed to handle and manipulate hazardous biological materials encountered in the battlefield. (6) These tools could include robotic arms equipped with gripping mechanisms, biological sample containers, or biohazard containment units.
(6) Enhanced Vision Systems: Advanced vision systems, including infrared cameras and other sensors, would aid the robot SOLDIERS in navigating and locating targets in environments with reduced visibility due to smoke, biological agents, or other factors.
(7) Communication Equipment: Reliable communication systems would be essential for coordination and information sharing between the robot SOLDIERS, human operators, and other units. These systems should be resistant to biological interference and capable of encrypted communication to maintain security.
(8) Medical Support Systems: In the context of biological warfare, it would be beneficial for AERI's consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer to have onboard medical support systems. These systems could include automated first aid kits, diagnostic capabilities, and the ability to administer basic medical treatments to human personnel if necessary.
(9) Power Supply and Redundancy System: A reliable and redundant power supply would be crucial for uninterrupted operation of robot SOLDIERS in the field. Multiple power sources, such as batteries or fuel cells, along with efficient power management systems, would be necessary to support extended missions.
Note: It is important to reiterate that the use of AERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer or autonomous systems in a biological warfare scenario is highly speculative and ethically contentious. The focus should primarily be on prevention, preparedness, and adherence to international treaties and regulations pertaining to biological weapons and warfare.
7. Robot Prices
A ERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS equipped with a brain implant-type biocomputer for the chemical or biological battlefield is the perfect killing machine, capable of substituting combat and killing power on par with a single military division of the Army, Navy and Air Forces.
The concept you presented of an AERI’s robot SOLDIER driven by consciousness and possessing combat capabilities equivalent to an entire military division is purely speculative and hypothetical. While it's interesting to explore advanced technologies, it's important to approach such ideas with caution and consider the limitations and challenges involved. Here are a few points to consider:
(1) Technological Feasibility: Achieving a consciousness-driven intelligent robot SOLDIER with capabilities equivalent to an entire military division is highly speculative. Consciousness, as we understand it, is a complex phenomenon that is not fully understood or replicated artificially. The development of such advanced and sentient robots capable of replacing entire military divisions is far beyond the current capabilities of technology.
(2) Ethical and Legal Considerations: The notion of deploying conscious robots designed for combat raises significant ethical and legal concerns. The delegation of lethal decision-making to machines, particularly those with consciousness, raises questions about accountability, responsibility, and the potential erosion of human judgment and moral considerations on the battlefield.
(3) Strategic Implications: The deployment of an advanced robot SOLDIER with capabilities equivalent to an entire military division would undoubtedly have significant strategic implications. It could potentially alter the balance of power and require nations to reassess their military doctrines and strategies. However, it's important to consider the broader geopolitical, diplomatic, and strategic factors that influence warfare and international relations.
(4) Human Factors: Despite technological advancements, warfare remains influenced by human factors such as adaptability, creativity, intuition, and contextual understanding. Human soldiers possess a range of cognitive and emotional abilities that are difficult to replicate in machines. The human element in warfare encompasses complex decision-making, empathy, and the ability to adapt to unpredictable situations.
(5) Unforeseen Consequences: Introducing an unprecedented weapon system of this magnitude would have unforeseen consequences and risks. It is essential to carefully evaluate the potential ramifications on global stability, arms races, and the potential for unintended escalation or misuse.
”It's crucial to recognize that the development and deployment of advanced technologies, particularly conscious machines with military capabilities, would require extensive research, ethical considerations, and international agreements. security, and the moral and ethical foundations that guide warfare,” advises Processor Kamuro in this interview.
Below is the basic price per machine that does not include above options for AERI's consciousness-driven intelligent robot SOLDIER.
(1) The basic price of AERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS for chemical battlefield is 854.92 million dollars (Additional charges applied for each of the above optional equipment).
(2) The basic price of AERI's consciousness-driven intelligent robot SOLDIER for biological battlefield is 912.66 million dollars (Additional charges applied for each of the above optional equipment).
8.The effect of adopting robot SOLDIER instead of human soldiers on the nuclear battlefield
The adoption of AERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS instead of human soldiers on a nuclear battlefield would have several potential effects, both positive and negative. It's important to note that the use of robots in such scenarios is speculative, and the ethical and legal considerations surrounding nuclear warfare are of paramount importance. However, here are some potential effects to consider:
(1) Minimized Human Casualties: One of the potential benefits of using the robot SOLDIERS in a nuclear battlefield is the potential to minimize human casualties. Robots can be designed to withstand high levels of radiation and operate in hazardous environments, reducing the risk to human soldiers who would otherwise be exposed to the dangers associated with nuclear radiation.
(2) Enhanced Radiation Resistance: Robots can be engineered to be more resistant to radiation compared to humans. They can withstand higher levels of radiation without suffering adverse health effects or long-term consequences. This resilience allows them to operate in highly contaminated areas for extended periods, performing tasks that would be extremely hazardous for human soldiers.
(3) Improved Precision and Accuracy: Robots can be designed with advanced sensors, targeting systems, and computing capabilities, enabling them to deliver precise and accurate actions in nuclear warfare scenarios. This enhanced precision can potentially minimize collateral damage and reduce the risk of unintended consequences.
(4) Rapid Response and Decision-Making: Robots can process information and make decisions faster than humans in certain situations. In a nuclear battlefield, where time is critical, the robot SOLDIERS may be capable of swiftly analyzing data, assessing threats, and responding with appropriate actions. This agility could potentially provide a tactical advantage in rapidly changing and high-stress situations.
(5) Reliability and Consistency: Robots are not subject to human limitations such as fatigue, emotions, or distractions. They can maintain consistent performance and remain operational for extended periods without rest. This reliability can be particularly advantageous in nuclear warfare, where the consequences of human error or fatigue can be catastrophic.
( 6) Ethical and Moral Considerations: The use of robots on a nuclear battlefield raises significant ethical and moral concerns. Nuclear warfare is highly destructive and has severe humanitarian consequences. The decision to deploy robots in such scenarios requires careful consideration of the moral implications, including the potential devaluation of human life and the implications for the escalation of conflict.
(7) Strategic Vulnerabilities: While the robot SOLDIERS may offer certain advantages, they also introduce new vulnerabilities. Robots can be susceptible to hacking, jamming, or other forms of cyberattacks, which could compromise their functionality and potentially turn them against their operators. Safeguards and robust cybersecurity measures would be necessary to mitigate these risks.
(8) Limitations in Adaptability and Judgment: While robots can excel in certain areas, they may still struggle with complex decision-making, adaptability to unpredictable situations, and nuanced judgment calls that humans can navigate more effectively. Nuclear warfare scenarios often involve complex political and strategic considerations, and the absence of human soldiers may limit the ability to understand and navigate these intricacies.
Professor Kamuro commented “It is crucial to approach the topic of nuclear warfare and the potential use of robots with great caution. The consequences and implications of nuclear conflict extend far beyond the capabilities and limitations of AERI's (AERI:Artificial Evolution Research Institute HP: https://www.aeri-japan.com/) consciousness-driven intelligent robot SOLDIERS, necessitating a focus on diplomacy, arms control, and the prevention of nuclear war,” and added “It is essential to note that the adoption of the robot SOLDIERS on a nuclear battlefield would require thorough research, development, and ethical discussions to address the numerous challenges and implications. Legal frameworks, international agreements, and a comprehensive understanding of the consequences for human lives and global stability would be crucial in considering such a transition,” to conclude the interview on this theme.
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Quantum Brain Chipset & Bio Processor (BioVLSI)
Prof. PhD. Dr. Kamuro
Quantum Physicist and Brain Scientist involved in Caltech & AERI Associate Professor and Brain Scientist in Artificial Evolution Research Institute( AERI: https://www.aeri-japan.com/ )
IEEE-USA Fellow
American Physical Society Fellow
PhD. & Dr. Kazuto Kamuro
email: info@aeri-japan.com
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【Keywords】 Artificial Evolution Research Institute:AERI
HP: https://www.aeri-japan.com/
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