electronic bionics

简明释义

电子仿生学

英英释义

例句

1.The field of electronic bionics has revolutionized prosthetic limbs, allowing amputees to regain mobility and functionality.

电子仿生学electronic bionics领域已经彻底改变了假肢，使截肢者能够恢复移动能力和功能。

2.With advancements in electronic bionics, scientists are developing artificial organs that can mimic the functions of natural ones.

随着electronic bionics的进步，科学家们正在开发可以模拟自然器官功能的人工器官。

3.Athletes are beginning to use electronic bionics in their training to enhance performance and reduce injury risks.

运动员开始在训练中使用electronic bionics来提高表现并降低受伤风险。

4.The integration of electronic bionics into medical devices has improved patient care and treatment outcomes significantly.

将electronic bionics整合到医疗设备中显著改善了患者护理和治疗效果。

5.Researchers are exploring the use of electronic bionics in creating advanced hearing aids that can adapt to different sound environments.

研究人员正在探索使用electronic bionics技术来制造可以适应不同声音环境的高级助听器。

作文

In the rapidly advancing world of technology, the fusion of biology and electronics has given rise to a fascinating field known as electronic bionics. This innovative discipline combines the principles of biological systems with electronic engineering to create devices that can mimic or enhance biological functions. The concept of electronic bionics is not only about replicating human capabilities but also about improving the quality of life for individuals with disabilities or injuries. For instance, prosthetic limbs equipped with sensors and motors can provide users with more natural movement and control, effectively bridging the gap between man and machine.One of the most significant advancements in electronic bionics is the development of neural interfaces. These interfaces allow direct communication between the brain and electronic devices, enabling paralyzed individuals to control robotic limbs simply by thinking about the movements they want to make. This groundbreaking technology has the potential to revolutionize rehabilitation and assistive devices, offering new hope to those who have lost their mobility.Moreover, electronic bionics extends beyond human applications; it also plays a crucial role in environmental sustainability. Engineers are now designing bio-inspired robots that can perform tasks efficiently while consuming minimal energy. For example, drones modeled after birds can navigate complex environments with agility, reducing the need for excessive power consumption. This integration of biological concepts into robotics exemplifies how electronic bionics can lead to more sustainable technological solutions.The ethical implications of electronic bionics are also worth considering. As we develop technologies that enhance human abilities, questions arise about the definition of humanity and the potential for inequality. Will access to electronic bionics be available to everyone, or will it create a divide between those who can afford such enhancements and those who cannot? Society must navigate these challenges carefully to ensure that advancements in this field benefit all individuals, regardless of their socioeconomic status.In conclusion, electronic bionics represents a remarkable intersection of technology and biology, with the potential to transform lives and industries. From advanced prosthetics that restore mobility to bio-inspired robots that promote sustainability, the applications of this field are vast and varied. However, as we continue to push the boundaries of what is possible, it is essential to remain mindful of the ethical considerations that accompany these innovations. By doing so, we can harness the power of electronic bionics to create a future that is not only technologically advanced but also equitable and inclusive.

在快速发展的技术世界中，生物学与电子学的融合催生了一个引人入胜的领域，称为电子仿生学。这一创新学科将生物系统的原理与电子工程结合起来，创造出能够模仿或增强生物功能的设备。电子仿生学的概念不仅仅是复制人类能力，还旨在改善残疾人或受伤者的生活质量。例如，配备传感器和电机的假肢可以为用户提供更自然的运动和控制，有效地弥合人机之间的差距。电子仿生学中最重要的进展之一是神经接口的发展。这些接口允许大脑与电子设备之间进行直接通信，使瘫痪者能够仅通过思考他们想要进行的运动来控制机器人肢体。这项突破性技术有可能彻底改变康复和辅助设备，为失去行动能力的人们带来新的希望。此外，电子仿生学不仅限于人类应用；它在环境可持续性方面也发挥着至关重要的作用。工程师们现在正在设计生物启发的机器人，以高效地执行任务，同时消耗最少的能源。例如，模仿鸟类的无人机可以灵活地导航复杂的环境，减少过度能源消耗的需求。这种将生物概念融入机器人技术的整合，体现了电子仿生学如何导致更可持续的技术解决方案。电子仿生学的伦理影响同样值得考虑。随着我们开发增强人类能力的技术，关于人性的定义和不平等的潜在问题也随之而来。电子仿生学的获取是否会对每个人开放，还是会在那些能够负担得起这种增强的人与那些不能负担得起的人之间造成分裂？社会必须谨慎应对这些挑战，以确保这一领域的进步惠及所有人，无论其社会经济地位如何。总之，电子仿生学代表了技术与生物学的一个显著交汇点，具有改造生活和行业的潜力。从恢复行动能力的先进假肢到促进可持续发展的生物启发机器人，这一领域的应用广泛而多样。然而，随着我们不断推动可能性的边界，保持对伴随这些创新的伦理考虑的关注至关重要。通过这样做，我们可以利用电子仿生学的力量，创造一个不仅技术先进，而且公平和包容的未来。