entropic

简明释义

英[enˈtrɒpɪk;enˈtrəʊpɪk]美[enˈtrɑːpɪk]

adj. 熵的

英英释义

单词用法

同义词

反义词

例句

1.Besides, the entropic thresholding method is applied to improve the quality of image.

论文中还引入最大熵进行阈值处理，图像质量得到改进。

2.Orcus may use his Entropic Wave 11/day, dealing 19d12 points of damage.

奥库斯每天能够使用11次熵之巨浪，造成19D12点伤害。

3.There is an entropic margin, namely entropic potential energy, between complicated system and simple system if they have same property.

在同一性质的复杂系统和简单系统之间存在着熵值差——熵势。

4.People ask for less and contribute more; hence increase anti-entropic forces in the society.

人们索取的少，奉献的多，就能增强社会的反熵力。

5.Lastly two-dimensional entropic thresholding was applied to segmentation image, thus microcalcifications were detected and were marked in mammograms.

最后利用二维最大熵阈值分割对图像二值化，从而检测出微钙化点并在图像上标识出来。

6.Orcus' Entropic wave explodes in a radius of 190 feet; victims caught in the wave may attempt a Reflex save DC 42 for half damage.

奥库斯的熵之波浪破坏半径190英尺，受害者在波浪中可以通过一次DC42的反射豁免使伤害减半。

7.Moreover Law is an anti-entropy thought system. It helps to form a beneficial, productive and creative anti-entropic mind.

此外，法制是一种反熵的思想体系，它有助于形成有利的，生产性和创造性的反熵的理念。

8.In the chapter 2, 4 and 5, the entropic dynamics and the properties of entanglement are investigated in quantum system.

第二、四、五章运用量子熵理论研究了量子系统中的熵动力学性质与量子纠缠性质。

9.The universe is constantly moving towards a more entropic 熵增的 state, where energy becomes more dispersed.

宇宙不断朝着一个更加熵增的状态发展，能量变得更加分散。

10.In thermodynamics, the concept of entropic 熵增 processes helps us understand why certain reactions are irreversible.

在热力学中，熵增过程的概念帮助我们理解某些反应为何是不可逆的。

11.The entropic 熵增的 nature of a closed system leads to a gradual increase in disorder over time.

封闭系统的熵增的特性导致随时间推移无序程度逐渐增加。

12.The second law of thermodynamics states that the total entropy of an isolated system can never decrease, highlighting the entropic 熵增的 tendency of nature.

热力学第二定律指出，孤立系统的总熵永远不会减少，突显了自然界的熵增的趋势。

13.In information theory, the measure of uncertainty or information content is often described as entropic 熵增的 value.

在信息理论中，不确定性或信息内容的度量通常被描述为熵增的值。

作文

In the realm of thermodynamics and information theory, the concept of entropy plays a significant role in understanding the nature of systems and their behaviors. When we refer to something as entropic (熵的), we are often discussing the inherent disorder or randomness that exists within a system. This idea can be applied not only in physical sciences but also in various aspects of life, including economics, sociology, and even personal relationships. To illustrate the implications of entropic (熵的) systems, let us consider the example of a well-organized office space. Initially, everything is in its designated place: documents are filed, supplies are neatly arranged, and the workspace is clean. However, as time passes, the office begins to accumulate clutter. Papers may be left out, items might be misplaced, and the overall organization deteriorates. This gradual decline into chaos exemplifies how systems tend to become more entropic (熵的) over time, as energy is expended to maintain order, and without that energy, disorder increases. In contrast, we can observe the opposite phenomenon in certain natural processes. For instance, the formation of crystals from a solution is a process that decreases entropic (熵的) disorder. As the molecules come together to form a structured lattice, the system becomes more ordered. However, this decrease in entropy is only temporary; the overall universe still trends toward greater entropic (熵的) states due to the second law of thermodynamics, which states that the total entropy of an isolated system can never decrease over time. The implications of entropic (熵的) principles extend beyond physics and chemistry. In economics, for example, markets can be viewed through the lens of entropy. A market that is highly organized with clear regulations and transparency may experience lower entropic (熵的) activity, leading to stable prices and predictable behaviors. Conversely, a chaotic market, rife with misinformation and lack of regulation, exhibits high levels of entropic (熵的) behavior, resulting in volatility and uncertainty. Moreover, the concept of entropic (熵的) disorder can be applied to social structures. Societies that are well-organized with strong institutions tend to function more effectively, exhibiting low levels of entropic (熵的) behavior. However, when social cohesion breaks down, whether due to political unrest, economic instability, or cultural fragmentation, the society may descend into a state of higher entropic (熵的) disorder, leading to conflict and dysfunction. On a personal level, individuals also face entropic (熵的) challenges in their lives. Maintaining relationships, careers, and personal goals requires constant effort and energy. Without proactive measures to nurture these aspects of life, they can easily fall into disarray. For instance, friendships may weaken if not actively maintained, leading to an entropic (熵的) drift where connections fade and misunderstandings arise. In conclusion, the term entropic (熵的) encapsulates a fundamental principle that transcends disciplines. Whether in the context of physical systems, economic markets, social structures, or personal relationships, the tendency toward disorder and randomness is a pervasive force. Understanding and acknowledging the entropic (熵的) nature of our world can empower us to take proactive steps to maintain order, foster stability, and cultivate meaningful connections in our lives.

在热力学和信息理论的领域中，熵的概念在理解系统及其行为的性质方面发挥着重要作用。当我们提到某物是entropic（熵的）时，我们通常是在讨论系统内在的无序或随机性。这个概念不仅可以应用于物理科学，还可以应用于经济学、社会学，甚至个人关系的各个方面。 为了说明entropic（熵的）系统的影响，让我们考虑一个井然有序的办公室空间的例子。最初，一切都在指定的位置：文件被归档，用品整齐排列，工作区干净。然而，随着时间的推移，办公室开始积累杂物。文件可能被遗留，物品可能被放错地方，整体组织逐渐恶化。这种逐渐走向混乱的过程示范了系统如何随着时间的推移变得更加entropic（熵的），因为维持秩序需要耗费能量，而没有这种能量，混乱就会增加。 相反，我们可以观察到某些自然过程中相反的现象。例如，从溶液中形成晶体的过程是一个减少entropic（熵的）无序的过程。当分子聚集在一起形成结构化的晶格时，系统变得更加有序。然而，这种熵的减少只是暂时的；由于热力学第二定律，整个宇宙仍然趋向于更高的entropic（熵的）状态，该定律指出孤立系统的总熵永远不会随时间减少。 entropic（熵的）原则的影响超越了物理和化学。在经济学中，例如，市场可以通过熵的视角进行观察。一个高度组织化、法规明确且透明的市场可能会经历较低的entropic（熵的）活动，从而导致价格稳定和可预测的行为。相反，一个混乱的市场，充斥着错误信息和缺乏监管，则表现出高水平的entropic（熵的）行为，导致波动和不确定性。 此外，entropic（熵的）无序的概念也可以应用于社会结构。具有强大机构的良好组织的社会往往更有效地运作，表现出较低的entropic（熵的）行为。然而，当社会凝聚力崩溃，无论是由于政治动荡、经济不稳定还是文化分裂，社会可能会下降到更高的entropic（熵的）无序状态，导致冲突和功能失调。 在个人层面上，个体在生活中也面临entropic（熵的）挑战。维持人际关系、职业和个人目标需要不断的努力和能量。如果不采取积极措施来滋养这些生活方面，它们很容易陷入混乱。例如，如果不积极维护友谊，友谊可能会减弱，导致entropic（熵的）漂移，连接逐渐消退，误解随之而来。 总之，术语entropic（熵的）概括了一个超越学科的基本原则。无论是在物理系统、经济市场、社会结构还是个人关系的背景下，朝向无序和随机性的趋势都是一种普遍的力量。理解和承认我们世界的entropic（熵的）本质可以使我们能够采取积极措施来维持秩序、促进稳定并培养生活中的有意义的联系。