parallel excitation

简明释义

并励

英英释义

例句

1.The research team utilized parallel excitation to improve the efficiency of their signal processing algorithms.

研究团队利用平行激励提高了信号处理算法的效率。

2.In MRI technology, parallel excitation allows for faster image acquisition by simultaneously exciting multiple slices.

在MRI技术中，平行激励通过同时激励多个切片来实现更快的图像采集。

3.By implementing parallel excitation, researchers were able to reduce the time needed for experimental trials.

通过实施平行激励，研究人员能够减少实验试验所需的时间。

4.The new software features parallel excitation capabilities that allow for simultaneous processing of multiple signals.

新软件具有平行激励功能，可以同时处理多个信号。

5.In the context of wireless communications, parallel excitation can enhance data transmission rates.

在无线通信的背景下，平行激励可以增强数据传输速率。

作文

In the realm of physics and engineering, the concept of parallel excitation plays a crucial role in understanding how systems can be stimulated simultaneously to achieve desired outcomes. This phenomenon is particularly significant in fields such as electromagnetism, quantum mechanics, and signal processing. To grasp the importance of parallel excitation, we must first consider what it entails. Essentially, parallel excitation refers to the simultaneous activation of multiple components or systems, allowing them to operate in unison rather than sequentially. This can lead to enhanced efficiency and performance, as well as the ability to manage complex processes more effectively.One practical application of parallel excitation can be found in the design of modern electronic circuits. In these circuits, multiple pathways can be activated at the same time, enabling faster processing speeds and improved data handling. For instance, in a computer's CPU, parallel excitation allows for various operations to be executed concurrently, which significantly boosts overall performance. Without this capability, computers would be limited to performing one task at a time, leading to slower processing and reduced functionality.Moreover, the concept of parallel excitation extends beyond electronics into the field of quantum computing. Quantum computers utilize qubits that can exist in multiple states simultaneously, thanks to the principles of superposition and entanglement. This allows for parallel excitation of qubits, enabling quantum computers to perform complex calculations at unprecedented speeds. The ability to process vast amounts of information concurrently is what makes quantum computing a revolutionary technology with the potential to solve problems that are currently intractable for classical computers.In addition to its applications in technology, parallel excitation can also be observed in biological systems. For example, when a group of neurons fires together in the brain, they can create a stronger signal than if they were to fire individually. This phenomenon is akin to parallel excitation, where the collective activity of multiple neurons enhances the overall response of the neural network. Understanding this mechanism is vital for advancements in neuroscience and can lead to better treatments for neurological disorders.Furthermore, in the context of education and learning, parallel excitation can be applied to collaborative learning environments. When students work together on projects, they can share ideas and insights, stimulating each other's thinking processes. This collaborative effort can be seen as a form of parallel excitation, where the combined intellectual engagement leads to deeper understanding and creativity. By fostering environments that encourage parallel excitation, educators can enhance the learning experience and promote critical thinking skills among students.In conclusion, parallel excitation is a multifaceted concept that permeates various disciplines, from technology to biology and education. Its ability to facilitate simultaneous action and interaction has profound implications for efficiency, performance, and innovation. As we continue to explore and harness the power of parallel excitation, we open doors to new possibilities and advancements that can reshape our understanding of the world around us.

在物理和工程领域，并行激励的概念在理解如何同时刺激多个系统以实现预期结果方面发挥着至关重要的作用。这一现象在电磁学、量子力学和信号处理等领域尤为重要。要掌握并行激励的重要性，我们首先必须考虑它的含义。基本上，并行激励是指多个组件或系统的同时激活，使它们能够共同运作，而不是顺序执行。这可以提高效率和性能，并更有效地管理复杂过程。并行激励的一个实际应用可以在现代电子电路的设计中找到。在这些电路中，可以同时激活多条路径，从而实现更快的处理速度和更好的数据处理。例如，在计算机的中央处理器（CPU）中，并行激励允许各种操作同时执行，这显著提升了整体性能。如果没有这种能力，计算机将被限制为一次执行一个任务，导致处理速度变慢和功能降低。此外，并行激励的概念不仅限于电子学，还扩展到量子计算领域。量子计算机利用量子比特（qubit），这些量子比特能够同时存在于多种状态，这得益于叠加和纠缠的原理。这使得量子计算机能够对量子比特进行并行激励，从而以空前的速度执行复杂计算。并行处理大量信息的能力使量子计算成为一种革命性技术，具有解决目前经典计算机无法处理的问题的潜力。除了在技术上的应用，并行激励还可以在生物系统中观察到。例如，当一组神经元在大脑中同时放电时，它们能够产生比单独放电更强的信号。这种现象类似于并行激励，其中多个神经元的集体活动增强了神经网络的整体反应。理解这一机制对神经科学的进步至关重要，并可能导致对神经系统疾病的更好治疗。此外，在教育和学习的背景下，并行激励可以应用于协作学习环境。当学生在项目上共同工作时，他们可以分享想法和见解，刺激彼此的思维过程。这种协作努力可以看作是一种并行激励，其中多个学生的集体智力互动导致更深层次的理解和创造力。通过培养鼓励并行激励的环境，教育工作者可以增强学习体验，促进学生的批判性思维技能。总之，并行激励是一个多面的概念，渗透到技术、生物学和教育等各个学科。它促进同时行动和互动的能力对效率、性能和创新具有深远的影响。随着我们继续探索和利用并行激励的力量，我们为新可能性和进步打开了大门，这些进步可以重塑我们对周围世界的理解。