ultraprecise

简明释义

[ˌʌltrəprɪˈsaɪs][ˌʌltrəprɪˈsaɪs]

超精密的

英英释义

Extremely accurate or precise, often to a degree that is beyond normal precision.

极其准确或精确,通常超出正常精度的程度。

单词用法

ultraprecise measurement

超精确测量

ultraprecise technology

超精确技术

ultraprecise instruments

超精确仪器

ultraprecise calibration

超精确校准

ultraprecise data

超精确数据

ultraprecise control

超精确控制

同义词

exact

精确的

The measurements were exact to the millimeter.

这些测量精确到毫米。

precise

准确的

She gave a precise description of the event.

她对事件进行了准确的描述。

meticulous

一丝不苟的

His meticulous attention to detail impressed everyone.

他对细节的一丝不苟让所有人都印象深刻。

specific

特定的

We need specific data to support our findings.

我们需要特定的数据来支持我们的发现。

accurate

准确无误的

The report was accurate and well-researched.

这份报告准确且经过充分研究。

反义词

imprecise

不精确的

The measurements were imprecise, leading to inaccurate results.

这些测量不精确,导致了不准确的结果。

vague

模糊的

His explanation was vague and did not clarify the issue.

他的解释很模糊,没有澄清问题。

approximate

近似的

The approximate values were sufficient for our initial analysis.

这些近似值对于我们的初步分析是足够的。

例句

1.Scanning probe microscope (SPM) is used not only for measuring the micro profiles of surfaces, but also for nano ultraprecise machining and atom manipulation now.

扫描探针显微镜(SPM)现在不仅用于表面微观形貌的检测,同时也用于纳米超精密加工和原子操纵。

2.It has also discussed the machining mechanics and the possible machining equipments and the error compensation technique about the ultraprecise machining technique.

并对超精密加工设备以及误差补偿技术方面也作了阐述。

3.An error compensation control method which can improve contour tracing accuracy of aspherical surface ultraprecise machine is introduced.

介绍了一种可提高非球曲面超精密加工机床的轮廓跟踪精度的误差补偿控制方法。

4.In the paper, we apply the robust parameter analysis method based on the loss model to the structural optimization and design of a miniature and ultraprecise milling machine tool.

将基于损失模型的稳健性参数分析法应用于小型超精密铣床的结构优化设计过程中。

5.Researchers have used ultraprecise clocks to show that time flies faster for your nose than for your navel—an effect predicted by the famed physicist's theory of relativity.

研究者们用超精密的时钟表明与你的肚脐相比你的鼻子经历的时间更快。 这是由著名的相对论预测而来的结果。

6.In the paper, we apply the robust parameter analysis method based on the loss model to the structural optimization and design of a miniature and ultraprecise milling machine tool.

将基于损失模型的稳健性参数分析法应用于小型超精密铣床的结构优化设计过程中。

7.In the field of astronomy, measurements must be ultraprecise 超精确的 to accurately determine the distance to distant stars.

在天文学领域,测量必须是ultraprecise 超精确的,以准确确定遥远星星的距离。

8.The watchmaker uses ultraprecise 超精确的 tools to ensure that every component fits perfectly.

制表师使用ultraprecise 超精确的 工具,以确保每个组件都完美贴合。

9.Surgeons rely on ultraprecise 超精确的 instruments during operations to minimize risks and improve outcomes.

外科医生在手术中依赖ultraprecise 超精确的 工具,以最小化风险并改善结果。

10.The new laser cutting machine is known for its ultraprecise 超精确的 cuts, making it ideal for intricate designs.

这台新的激光切割机以其ultraprecise 超精确的 切割而闻名,非常适合复杂的设计。

11.Our research requires ultraprecise 超精确的 data collection methods to ensure reliable results.

我们的研究需要ultraprecise 超精确的 数据收集方法,以确保结果可靠。

作文

In the modern world, technology has advanced to a point where precision is not just desired but required. One of the most fascinating developments in this area is the concept of ultraprecise measurements. These measurements are essential in fields such as engineering, medicine, and scientific research, where even the slightest error can lead to significant consequences. The term ultraprecise refers to an accuracy that is far beyond what was previously possible, allowing for a new level of detail in data collection and analysis.For instance, in the field of engineering, the construction of bridges and buildings requires ultraprecise calculations to ensure safety and durability. Engineers use advanced tools and technologies to measure materials and dimensions with incredible accuracy. This meticulous approach not only helps in creating structures that can withstand natural disasters but also ensures that they meet the strict regulations set by governing bodies.Similarly, in the medical field, ultraprecise instruments are crucial for diagnosing and treating patients. For example, in surgeries, surgeons rely on ultraprecise imaging techniques to visualize the anatomy of the patient. This enables them to perform complex procedures with minimal invasiveness, reducing recovery time and improving patient outcomes. The development of robotic surgery, which allows for ultraprecise movements, has revolutionized the way surgeries are performed, leading to more successful results.Scientific research also benefits immensely from ultraprecise measurements. In experiments, scientists must ensure that their data is accurate and reliable. This is especially true in fields like physics and chemistry, where small variations can lead to different conclusions. By utilizing ultraprecise instruments, researchers can gather data that helps them make groundbreaking discoveries. For example, the detection of gravitational waves, which required ultraprecise measurements of space-time, has opened up new avenues in astrophysics.Moreover, the advent of technologies such as artificial intelligence and machine learning has further enhanced our ability to achieve ultraprecise results. These technologies can analyze vast amounts of data at speeds and accuracies that humans cannot match. They can identify patterns and anomalies that may go unnoticed, leading to innovations in various sectors, including finance, healthcare, and environmental science.However, it is important to note that achieving ultraprecise measurements comes with its challenges. The cost of ultraprecise instruments can be prohibitive, and the need for skilled professionals to operate and interpret these tools is essential. Additionally, as we push the boundaries of precision, we must also consider the ethical implications of our advancements. For instance, in genetic research, the ability to manipulate DNA with ultraprecise techniques raises questions about the potential consequences of such power.In conclusion, the pursuit of ultraprecise measurements is transforming various fields and enhancing our understanding of the world. Whether in engineering, medicine, or scientific research, the ability to achieve such high levels of accuracy is invaluable. As technology continues to evolve, the importance of ultraprecise measurements will only grow, driving innovation and progress in ways we have yet to imagine. It is crucial for us to embrace these advancements while being mindful of their implications, ensuring that we use our newfound capabilities responsibly and ethically.

在现代世界,技术已经发展到一个不仅仅是期望而是必需的精确度水平。这个领域中最迷人的发展之一就是“超精确”测量的概念。这些测量在工程、医学和科学研究等领域至关重要,因为即使是微小的错误也可能导致重大后果。“超精确”一词指的是超出先前可能性的精确度,使得数据收集和分析达到了新的细节水平。例如,在工程领域,桥梁和建筑的建设需要“超精确”的计算以确保安全性和耐久性。工程师使用先进的工具和技术,以令人难以置信的准确性测量材料和尺寸。这种细致入微的方法不仅有助于创建能够抵御自然灾害的结构,还确保它们符合监管机构设定的严格规定。同样,在医学领域,“超精确”的仪器对诊断和治疗患者至关重要。例如,在手术中,外科医生依赖“超精确”的成像技术来可视化患者的解剖结构。这使他们能够以最小的侵入性进行复杂的手术,缩短恢复时间并改善患者的结果。机器人手术的发展,使得“超精确”的运动成为可能,彻底改变了手术的方式,带来了更成功的结果。科学研究也从“超精确”测量中受益匪浅。在实验中,科学家必须确保他们的数据是准确和可靠的。尤其是在物理和化学等领域,微小的变化可能导致不同的结论。通过利用“超精确”的仪器,研究人员可以收集有助于他们做出突破性发现的数据。例如,探测引力波需要“超精确”的时空测量,开启了天体物理学的新领域。此外,人工智能和机器学习等技术的出现进一步增强了我们实现“超精确”结果的能力。这些技术可以以人类无法匹敌的速度和准确性分析大量数据。它们能够识别可能被忽视的模式和异常,从而在金融、医疗保健和环境科学等各个领域推动创新。然而,需要注意的是,实现“超精确”测量面临着挑战。“超精确”仪器的成本可能是禁止性的,而操作和解释这些工具所需的专业技能至关重要。此外,随着我们推动精确度的边界,我们还必须考虑我们进步的伦理影响。例如,在基因研究中,能够使用“超精确”技术操纵DNA引发了关于这种力量潜在后果的问题。总之,对“超精确”测量的追求正在改变各个领域,并增强我们对世界的理解。无论是在工程、医学还是科学研究中,达到如此高水平的准确性都是无价的。随着技术的不断发展,“超精确”测量的重要性将只会增加,以我们尚未想象的方式推动创新和进步。我们必须在拥抱这些进步的同时,关注其影响,确保我们负责任和道德地使用我们新获得的能力。