quantized
简明释义
adj. 量化的;量子化的
v. 使量子化(quantize 的过去分词)
英英释义
单词用法
量子化信号 | |
量子化测量 | |
量子化系统 | |
量子化时间 | |
量子化粒子 | |
量子化为离散级别 | |
量子化表示 | |
量子化近似 | |
量子场论 | |
量子化信息 |
同义词
| 离散的 | 数据以离散格式表示。 | ||
| 数字化的 | 音频信号已被数字化以便更好地处理。 | ||
| 可量化的 | The results of the experiment are quantifiable and can be analyzed statistically. | 实验结果是可量化的,可以进行统计分析。 |
反义词
| 连续的 | The signal is continuous, allowing for an infinite range of values. | 该信号是连续的,允许无限范围的值。 | |
| 未量化的 | In some applications, an unquantized representation may be preferred for accuracy. | 在某些应用中,可能更喜欢未量化的表示以提高准确性。 |
例句
1.A timestamp, quantized from the start of the sequence.
数字时间信息列,从序列的开始进行量化得到的。
2.Energy is quantized. Velocity is quantized.
能量被量子化,速度被量子化。
3.So far we have only demonstrated that the mean charge in electrolysis is quantized.
到目前为止,我们只验证了电解中的平均电行是量子化的。
4.All the content was quantized.
并对所调查内容给以量化。
5.That's the case whenever you have quantized levels.
在那种情况下,不论你的量子化能级在哪。
6.Out of that he concludes charge must be quantized.
出于此结论,他总结出电荷是量子化的。
7.That's why we can't have a continuum of energy, we actually have those quantized points.
这就是为什么,我们没有连续的能谱,而是,量子化的点。
8.The principles of quantized management is presented.
提出了量化管理的原则。
9.When electrons jump between orbits, they emit or absorb energy in quantized amounts.
当电子在轨道之间跳跃时,它们以量化的方式发射或吸收能量。
10.The quantized nature of light explains why we see distinct colors in a spectrum.
光的量子化特性解释了我们在光谱中看到不同颜色的原因。
11.In quantum mechanics, energy levels are often described as being quantized, meaning they can only take on specific values.
在量子力学中,能量级通常被描述为量化的,意味着它们只能取特定的值。
12.Digital audio files are quantized to represent sound waves in discrete steps.
数字音频文件被量化以将声波表示为离散的步骤。
13.The concept of quantized states is fundamental in understanding how atoms interact.
理解原子如何相互作用的基础是量化状态的概念。
作文
In the realm of physics and modern technology, the concept of quantized plays a crucial role in our understanding of the universe. The term quantized refers to the idea that certain properties, such as energy, can only take on discrete values rather than a continuous range. This principle is foundational in quantum mechanics, which describes the behavior of particles at the atomic and subatomic levels. To illustrate this concept, consider the example of an electron in an atom. According to classical physics, an electron could occupy any position around the nucleus and possess any amount of energy. However, quantum mechanics introduces the idea that these electrons exist in specific energy levels or orbitals. When an electron transitions from one energy level to another, it must absorb or emit a precise amount of energy, which is why we describe these energy levels as quantized. This means that the energy levels are not continuous; instead, they are like steps on a staircase, where the electron can only stand on certain steps (energy levels) and cannot exist between them.The implications of the quantized nature of energy are profound. For instance, when light interacts with matter, it can also be thought of as quantized, leading to the concept of photons, which are packets of light energy. Each photon carries a specific amount of energy that corresponds to its frequency. This relationship is described by the equation E = hf, where E is energy, h is Planck's constant, and f is the frequency of the light. Thus, light itself is quantized, and this quantized nature helps explain phenomena such as the photoelectric effect, where light can eject electrons from a material only if its frequency is above a certain threshold.Furthermore, the quantized nature of particles leads to the development of technologies such as semiconductors and lasers. In semiconductors, the energy bands are quantized, allowing for the control of electrical conductivity. This property is essential for creating integrated circuits and computer chips that power our modern electronics. Similarly, lasers operate on the principle of quantized energy levels, where electrons are excited to higher energy states and then release energy in a coherent light beam when they return to their lower energy states.The concept of quantized extends beyond physics into various fields, including chemistry and information technology. In chemistry, the quantized energy levels of electrons determine how atoms bond and interact with each other, influencing the formation of molecules and compounds. In information technology, the idea of quantized bits (qubits) in quantum computing represents a significant leap forward from classical bits, allowing for the processing of information in ways that were previously unimaginable.In conclusion, the term quantized encapsulates a fundamental aspect of our universe, revealing that many properties are not continuous but rather exist in discrete units. This understanding has transformed our approach to science and technology, leading to innovations that have reshaped our world. As we continue to explore the implications of quantized systems, we unlock new possibilities for the future, expanding our knowledge and capabilities in ways we are only beginning to comprehend.
在物理学和现代技术的领域中,quantized(量子化)的概念在我们理解宇宙方面发挥着至关重要的作用。这个术语quantized指的是某些属性,如能量,只能取离散值而不是连续范围的思想。这个原则是量子力学的基础,量子力学描述了原子和亚原子水平上粒子的行为。为了说明这一概念,考虑一个原子中电子的例子。根据经典物理学,电子可以占据核周围的任何位置并具有任何能量。然而,量子力学引入了这样的观点:这些电子存在于特定的能量水平或轨道中。当电子从一个能量水平跃迁到另一个能量水平时,它必须吸收或发出精确的能量,这就是为什么我们将这些能量水平描述为quantized的原因。这意味着能量水平不是连续的;相反,它们就像楼梯上的台阶,电子只能站在某些台阶(能量水平)上,而不能存在于它们之间。Quantized的能量性质的影响是深远的。例如,当光与物质相互作用时,它也可以被视为quantized,导致光子(光能量的包裹)的概念。每个光子携带的能量量对应于其频率。这个关系由方程E = hf描述,其中E是能量,h是普朗克常数,f是光的频率。因此,光本身是quantized的,这种quantized性质有助于解释诸如光电效应等现象,在这种现象中,光只能在其频率高于某个阈值时从材料中弹出电子。此外,粒子的quantized性质导致了半导体和激光等技术的发展。在半导体中,能量带是quantized的,从而允许对电导率的控制。这一特性对于创建集成电路和计算机芯片至关重要,这些芯片为我们现代电子产品提供动力。类似地,激光基于quantized能级的原理工作,其中电子被激发到更高的能量状态,然后在返回较低能量状态时释放能量形成相干光束。Quantized的概念超越了物理学,扩展到化学和信息技术等多个领域。在化学中,电子的quantized能级决定了原子如何结合和相互作用,从而影响分子和化合物的形成。在信息技术中,量子计算中的quantized比特(量子位)代表了从经典比特到信息处理的重大飞跃,使得以前无法想象的信息处理成为可能。总之,术语quantized概括了我们宇宙的一个基本方面,揭示了许多属性不是连续的,而是以离散单位存在。这种理解改变了我们对科学和技术的看法,导致了重塑我们世界的创新。随着我们继续探索quantized系统的影响,我们为未来解锁新的可能性,扩展我们的知识和能力,以我们刚刚开始理解的方式。
