self-propelled tethered system
简明释义
自航系留系统
英英释义
例句
1.The entertainment industry is experimenting with a self-propelled tethered system for aerial photography, providing stunning visuals while ensuring safety.
娱乐行业正在尝试使用自推进的系留系统进行空中摄影,提供惊艳的视觉效果,同时确保安全。
2.In agricultural applications, farmers use a self-propelled tethered system to monitor crop health with drones that can move autonomously while linked to a base station.
在农业应用中,农民使用自推进的系留系统来监测作物健康,配备可以自主移动并与基站连接的无人机。
3.The military deployed a self-propelled tethered system for surveillance purposes, enabling real-time data transmission while maintaining a stable position.
军方部署了一个自推进的系留系统用于监视目的,使其能够在保持稳定位置的同时进行实时数据传输。
4.Researchers are developing a self-propelled tethered system for environmental monitoring that can collect data from various altitudes without losing connectivity.
研究人员正在开发一个自推进的系留系统用于环境监测,该系统可以在不同高度收集数据而不失去连接。
5.The new underwater drone operates as a self-propelled tethered system, allowing it to explore deep sea environments while remaining connected to the surface.
这款新的水下无人机作为一个自推进的系留系统运作,能够在与水面保持连接的同时探索深海环境。
作文
In recent years, technology has advanced rapidly, leading to the development of innovative systems that enhance various aspects of our lives. One such innovation is the self-propelled tethered system, which has gained attention in multiple fields including robotics, telecommunications, and even entertainment. Understanding this concept can provide insights into its applications and benefits. A self-propelled tethered system refers to a mechanism that can move independently while being connected to a stationary source through a tether. This tether can be a cable or a wire that supplies power or data, allowing the system to operate without being completely autonomous. For instance, in the field of robotics, such systems can be deployed for tasks that require mobility but also need a constant power supply. This combination of self-propulsion and tethering allows for extended operational time compared to fully autonomous systems that rely solely on battery power.One of the most notable applications of the self-propelled tethered system is in aerial drones. These drones can be equipped with a tether that connects them to a ground station. This setup not only provides continuous power, extending flight time significantly but also enables real-time data transmission. In scenarios such as surveillance or search and rescue missions, this capability is crucial as it ensures that the drone can operate for longer periods without needing to return to recharge.Moreover, in the telecommunications industry, self-propelled tethered systems can be utilized for deploying antennas or communication devices in hard-to-reach areas. By using a tethered approach, these systems can maintain a stable position while providing connectivity over large distances. This is particularly useful in disaster recovery situations where traditional infrastructure may be damaged or non-existent.The entertainment industry has also seen the advantages of self-propelled tethered systems. For example, in live performances, these systems can be used to create dynamic visual effects by controlling lights and cameras that are tethered to a central power source. This allows for more creative freedom while ensuring that the equipment remains powered throughout the event.Despite the numerous advantages, there are challenges associated with self-propelled tethered systems. The reliance on a tether can limit the range of motion and flexibility, making it essential to design these systems thoughtfully. Engineers must consider the length and durability of the tether, as well as the potential for tangling or damage during operation. Additionally, safety protocols must be established to prevent accidents, especially in public spaces.In conclusion, the self-propelled tethered system represents a significant advancement in technology that merges mobility with stability. Its applications across various industries highlight its versatility and potential impact. As technology continues to evolve, we can expect to see even more innovative uses for these systems, further enhancing our capabilities in both professional and personal realms. Understanding and mastering the concept of self-propelled tethered systems will undoubtedly be beneficial for those looking to engage with modern technological advancements.
近年来,科技迅速发展,催生了多种创新系统,提升了我们生活的各个方面。其中一种创新便是自推进系留系统,在机器人技术、电信甚至娱乐等多个领域引起了关注。理解这一概念可以为我们提供对其应用和优势的深入见解。自推进系留系统指的是一种可以独立移动的机制,同时通过系留与固定源相连。这个系留可以是电缆或导线,为系统提供电力或数据,使其在不完全自主的情况下运行。例如,在机器人领域,这种系统可以用于需要移动但又需要持续电源的任务。自推进与系留的结合相比于完全依赖电池供电的自主系统,能够延长操作时间。自推进系留系统最显著的应用之一是在空中无人机中。这些无人机可以配备一个系留,与地面站连接。这样的设置不仅提供了持续的电力,显著延长了飞行时间,还能实现实时数据传输。在监视或搜救任务等场景中,这一能力至关重要,因为它确保无人机能够在无需返回充电的情况下长时间操作。此外,在电信行业,自推进系留系统可用于在难以到达的区域部署天线或通信设备。通过采用系留的方法,这些系统能够保持稳定的位置,同时在较大距离内提供连接。这在灾后恢复情况下尤其有用,因为传统基础设施可能受到损坏或根本不存在。娱乐行业也看到了自推进系留系统的优势。例如,在现场表演中,这些系统可以用于创造动态视觉效果,通过控制与中央电源相连的灯光和摄像机。这使得创作自由度更高,同时确保设备在整个活动中保持供电。尽管有诸多优点,但自推进系留系统也面临挑战。对系留的依赖可能限制运动范围和灵活性,因此设计这些系统时必须谨慎考虑。工程师必须考虑系留的长度和耐用性,以及在操作过程中可能发生的缠绕或损坏。此外,必须建立安全协议以防止事故,特别是在公共场所。总之,自推进系留系统代表了一项重要的技术进步,将移动性与稳定性结合在一起。它在各个行业的应用凸显了其多功能性和潜在影响。随着科技的不断发展,我们可以期待看到这些系统更多创新的使用,进一步提升我们在专业和个人领域的能力。理解和掌握自推进系留系统的概念无疑将对那些希望参与现代技术进步的人们有所裨益。
