steering command

简明释义

操纵指令

英英释义

例句

1.The pilot received a steering command from the control tower to adjust the flight path.

飞行员接收到来自控制塔的航向指令，以调整飞行路径。

2.The driver used a steering command to avoid an obstacle on the road.

司机使用了转向指令来避开路上的障碍物。

3.During the simulation, the steering command was tested under various weather conditions.

在模拟过程中，转向指令在各种天气条件下进行了测试。

4.In autonomous vehicles, the steering command is crucial for navigating turns safely.

在自动驾驶车辆中，转向指令对于安全导航转弯至关重要。

5.The robot's steering command allowed it to maneuver through tight spaces.

机器人的转向指令使其能够在狭小空间内灵活移动。

作文

In the realm of autonomous vehicles and robotics, the concept of steering command plays a crucial role in ensuring that machines navigate their environments effectively. The term steering command refers to the instructions given to a vehicle or robot that dictate its direction and movement. This can involve various inputs, such as the angle of the steering wheel in a car or the orientation of wheels in a robotic system. Understanding how steering command operates is essential for developers and engineers working in these fields, as it directly impacts the performance and safety of autonomous systems.One of the primary functions of a steering command is to enable precise navigation. For instance, when an autonomous vehicle encounters a turn, the steering command must be adjusted accordingly to ensure that the vehicle follows the correct path. This requires sophisticated algorithms that can process real-time data from sensors, such as cameras and LIDAR, to determine the optimal angle for turning. If the steering command is not executed accurately, the vehicle could veer off course, potentially leading to accidents or collisions.Moreover, the effectiveness of a steering command is influenced by various factors, including the speed of the vehicle, road conditions, and the presence of obstacles. For example, a vehicle traveling at high speeds may require a different steering command than one moving slowly, as the physics of motion dictate that sharper turns become more challenging at higher velocities. Engineers must take these variables into account when designing the systems that interpret and execute steering commands.In addition to physical navigation, steering command also encompasses the control mechanisms that allow for user interaction. In many cases, drivers can override automated systems, providing manual steering commands through traditional controls. This duality of control—between manual and automated steering command—is vital for the development of semi-autonomous vehicles, where human oversight is still necessary. Developers must create interfaces that allow for seamless transitions between automated and manual control, ensuring that drivers feel confident and safe while operating their vehicles.The implementation of steering command technology has far-reaching implications beyond just personal transportation. In the field of robotics, steering command systems are used in various applications, from warehouse automation to drone navigation. For instance, a warehouse robot must navigate through aisles filled with products, requiring complex steering command adjustments to avoid obstacles and optimize its route. Similarly, drones rely on steering command to maintain stable flight paths and execute precise maneuvers during delivery missions.As we look towards the future, advancements in artificial intelligence and machine learning will continue to enhance the capabilities of steering command systems. These technologies will enable vehicles and robots to learn from their environments, adapting their steering command strategies based on past experiences and real-time feedback. This evolution will lead to safer and more efficient navigation solutions, ultimately transforming how we interact with machines in our daily lives.In conclusion, the understanding of steering command is fundamental for anyone involved in the development of autonomous vehicles and robotics. It encompasses the principles of navigation, user interaction, and the integration of advanced technologies, all of which contribute to the effective operation of these systems. As innovation continues to drive progress in this field, the importance of mastering steering command will only grow, paving the way for a future where machines can navigate our world with unprecedented precision and safety.

在自动驾驶汽车和机器人领域，steering command（转向指令）这一概念在确保机器有效导航其环境方面发挥着至关重要的作用。steering command指的是给车辆或机器人发出的指令，这些指令决定了它的方向和运动。这可能涉及各种输入，例如汽车中方向盘的角度或机器人系统中轮子的方向。理解steering command的运作方式对于从事这些领域的开发者和工程师至关重要，因为它直接影响到自主系统的性能和安全性。steering command的主要功能之一是实现精确导航。例如，当一辆自动驾驶汽车遇到转弯时，steering command必须相应调整，以确保车辆沿着正确的路径行驶。这需要复杂的算法，可以处理来自传感器（如摄像头和激光雷达）的实时数据，以确定最佳的转弯角度。如果steering command未能准确执行，车辆可能会偏离路线，从而导致事故或碰撞。此外，steering command的有效性还受到多种因素的影响，包括车辆速度、道路条件和障碍物的存在。例如，快速行驶的车辆可能需要与慢速行驶的车辆不同的steering command，因为运动的物理学表明，在高速下进行急转弯变得更加困难。工程师在设计解释和执行steering command的系统时，必须考虑这些变量。除了物理导航，steering command还包括允许用户交互的控制机制。在许多情况下，司机可以覆盖自动化系统，通过传统控制提供手动steering command。这种控制的二元性——手动和自动steering command之间——对于半自动驾驶汽车的发展至关重要，在这种情况下，仍然需要人类监督。开发者必须创建允许自动控制与手动控制之间无缝切换的界面，以确保司机在操作车辆时感到自信和安全。steering command技术的实施在个人交通之外还有深远的影响。在机器人领域，steering command系统用于各种应用，从仓库自动化到无人机导航。例如，仓库机器人必须在充满产品的过道中导航，需要复杂的steering command调整以避免障碍物并优化其路线。同样，无人机依赖于steering command来保持稳定的飞行路径，并在交付任务中执行精确的机动。展望未来，人工智能和机器学习的进步将继续增强steering command系统的能力。这些技术将使车辆和机器人能够从其环境中学习，根据过去的经验和实时反馈调整其steering command策略。这种演变将导致更安全、更高效的导航解决方案，最终改变我们在日常生活中与机器互动的方式。总之，理解steering command对于任何参与自动驾驶汽车和机器人开发的人来说都是基础。它涵盖了导航原理、用户交互和先进技术的整合，这些都促进了这些系统的有效运行。随着创新继续推动这一领域的进步，掌握steering command的重要性只会增加，为未来铺平道路，使机器能够以前所未有的精确度和安全性导航我们的世界。