measurement range

简明释义

测量范围

英英释义

例句

1.The pH meter's measurement range 测量范围 is from 0 to 14, which covers most solutions.

pH计的测量范围 measurement range 是从0到14，覆盖了大多数溶液。

2.The measurement range 测量范围 of the pressure gauge must match the expected pressure in the system.

压力表的测量范围 measurement range 必须与系统中预期的压力匹配。

3.Make sure the measurement range 测量范围 of the multimeter is suitable for your application.

确保万用表的测量范围 measurement range 适合你的应用。

4.The thermometer has a wide measurement range 测量范围 from -50 to 150 degrees Celsius.

这个温度计的测量范围 measurement range 从-50到150摄氏度，非常广泛。

5.When selecting a scale, consider the measurement range 测量范围 you need for your specific tasks.

选择秤时，请考虑您特定任务所需的测量范围 measurement range 。

作文

In the field of science and engineering, accurate measurements are crucial for obtaining reliable data. One key concept that plays a significant role in this process is the measurement range. The measurement range refers to the span of values that an instrument can accurately measure. Understanding this concept is essential for anyone working with measuring devices, as it determines the limits within which the instrument can provide valid readings.For example, consider a digital thermometer designed to measure temperatures. If its measurement range is from -20°C to 100°C, this means that the thermometer can accurately measure any temperature within this range. However, if the temperature falls below -20°C or rises above 100°C, the readings may become unreliable or erroneous. This highlights the importance of selecting the right instrument for the specific application at hand.In practical applications, knowing the measurement range helps users avoid potential errors that could lead to incorrect conclusions. For instance, in a laboratory setting, researchers often need to measure the pH level of various solutions. If they use a pH meter with a measurement range of 0 to 14, they can accurately assess most common solutions. However, if they attempt to measure a solution with a pH outside this range, the meter may not provide meaningful results, which could compromise the integrity of their research.Moreover, the measurement range can vary significantly between different types of instruments. For instance, a voltmeter used to measure electrical voltage might have a measurement range of 0 to 600 volts, while a more specialized device, like a microvolt meter, may have a much narrower measurement range tailored for precise low-voltage measurements. Therefore, understanding the specifications of the instruments being used is vital for ensuring accurate data collection.Furthermore, the measurement range is not just a static value; it can also be influenced by environmental conditions. For example, temperature and humidity can affect the performance of certain measuring devices, potentially altering their measurement range. This is particularly relevant in fields such as meteorology, where instruments must function accurately under varying atmospheric conditions.In conclusion, the concept of measurement range is fundamental in the realm of measurement and instrumentation. It defines the limits within which an instrument can operate effectively and provides a framework for understanding the reliability of the data collected. By being aware of the measurement range of the instruments they use, professionals can ensure that their measurements are both accurate and meaningful, leading to better decision-making based on sound data. As technology continues to advance, the importance of understanding measurement range will only grow, making it an essential topic for anyone involved in scientific and technical fields.

在科学和工程领域，准确的测量对于获得可靠的数据至关重要。一个在这个过程中起着重要作用的关键概念是测量范围。测量范围指的是仪器能够准确测量的值的范围。理解这个概念对于任何使用测量设备的人来说都是必不可少的，因为它决定了仪器可以提供有效读数的限制。例如，考虑一个设计用于测量温度的数字温度计。如果它的测量范围是从-20°C到100°C，这意味着温度计可以准确测量这个范围内的任何温度。然而，如果温度低于-20°C或高于100°C，读数可能会变得不可靠或错误。这突显了为特定应用选择合适仪器的重要性。在实际应用中，了解测量范围有助于用户避免可能导致错误结论的潜在错误。例如，在实验室环境中，研究人员常常需要测量各种溶液的pH值。如果他们使用一个测量范围为0到14的pH计，他们可以准确评估大多数常见溶液。然而，如果他们试图测量超出此范围的溶液，仪器可能无法提供有意义的结果，这可能会损害他们研究的完整性。此外，测量范围在不同类型的仪器之间可能会有显著差异。例如，用于测量电压的伏特计可能具有0到600伏的测量范围，而更专业的设备，如微伏计，可能具有为精确低电压测量量身定制的更窄的测量范围。因此，了解所使用仪器的规格对于确保准确的数据收集至关重要。此外，测量范围不仅仅是一个静态值；它也可能受到环境条件的影响。例如，温度和湿度可以影响某些测量设备的性能，从而可能改变它们的测量范围。这一点在气象学等领域尤为相关，因为仪器必须在变化的气候条件下准确运行。总之，测量范围的概念在测量和仪器领域是基础性的。它定义了仪器可以有效操作的限制，并提供了理解所收集数据可靠性的框架。通过了解他们所使用仪器的测量范围，专业人员可以确保他们的测量既准确又有意义，从而基于可靠的数据做出更好的决策。随着技术的不断进步，理解测量范围的重要性只会增加，使其成为任何参与科学和技术领域的人的基本话题。