capacitive

简明释义

英[kəˈpæsətɪv]美[kəˈpæsətɪv]

adj. 电容性的

英英释义

单词用法

同义词

反义词

例句

1.Some on-line monitoring and fault diagnosis methods of capacitive equipment are introduced.

介绍了当前容性设备在线监测与故障诊断的几种方法。

2.These advantages have made the capacitive transducer a valuable device for measurement of engine cylinder pressures.

这些优点已使得电容式传感器成为测量发动机汽缸压力的有效的装置。

3.The two main buttons are not physical, but instead use capacitive touch sensors with a tiny speaker to provide audible feedback for each click.

它的两个主按键不是机械的，而是电容触摸传感器。它还有细微的扬声器，每当按击时都会有声音响应。鼠标还有一个滚球使用户能朝任意方向滚动页面。

4.Difficulty was known to get satisfactory measurement effect on precision in capacitive grain's moisture measurement due to many influencing factors.

由于电容式粮食水分检测中影响检测的因素较多，检测精度很难取得令人满意的测量效果。

5.Hrm. Well at least they're acknowledging the need for better gesture support, and the need to mimic the capability of capacitive touch.

嗯，至少他们明确了需要更好的手势支持，需要模拟电容屏的能力。

6.Crosstalk is the transfer of energy between adjacent circuit conductors, via capacitive and inductive coupling.

串扰是指相邻的电路导线间由容性耦合或者感性耦合引起能量的转移从而造成的干扰。

7.The SV-2400 LCD monitors are available with an anti-reflective, tempered glass protective overlay or an optional capacitive touchscreen sensor.

SV-2400LCD显示器采用抗反光的钢化玻璃保护屏，也可选用电容式触摸屏。

8.According to the DigiTimes story, the sample displays are projected capacitive touch panels.

据DigiTimes透露，和鑫公司送样的触屏面板采用的是投射电容式设计。

9.The capacitive 电容式 sensors in the device allow for touch-free operation.

设备中的电容式 电容式传感器允许无接触操作。

10.Many modern tablets use capacitive 电容式 technology for better sensitivity and accuracy.

许多现代平板电脑使用电容式 电容式技术，以获得更好的灵敏度和准确性。

11.Using capacitive 电容式 buttons can enhance the user experience in home appliances.

使用电容式 电容式按钮可以提升家用电器的用户体验。

12.The capacitive 电容式 touchpad on laptops provides a smooth navigation experience.

笔记本电脑上的电容式 电容式触控板提供了流畅的导航体验。

13.The new smartphone features a capacitive 电容式 touchscreen that responds quickly to finger gestures.

这款新智能手机配备了一个电容式 电容式触摸屏，能够快速响应手指手势。

作文

In today's digital age, technology has become an integral part of our lives. One of the most significant advancements in this field is the development of capacitive technology. This term refers to a type of sensing technology that detects touch and proximity based on the electrical properties of the human body. Unlike resistive touch screens, which require pressure to register a touch, capacitive screens work by measuring changes in capacitance when a conductive object, such as a finger, comes into contact with the screen. This innovation has revolutionized the way we interact with devices, making them more intuitive and user-friendly.The principle behind capacitive technology lies in its ability to store and measure electrical charge. When a finger approaches the screen, it creates an electrostatic field that alters the distribution of electrical charges on the surface of the screen. The device's sensors detect these changes and translate them into input commands. This seamless interaction is one of the reasons why capacitive screens are widely used in smartphones, tablets, and other modern electronic devices.Moreover, capacitive technology offers several advantages over traditional methods. For instance, capacitive screens are generally more sensitive and can register multiple touch points simultaneously, allowing for gestures like pinch-to-zoom or swipe. This capability enhances the overall user experience, making it easier to navigate applications and perform tasks efficiently.Another important aspect of capacitive technology is its durability. Since it does not rely on mechanical components, capacitive screens tend to be more resilient to wear and tear. They are also less susceptible to environmental factors such as dust and moisture, which can affect the performance of resistive screens. This durability makes capacitive technology an ideal choice for devices that are frequently used in various conditions.However, despite its many benefits, capacitive technology is not without its limitations. For example, it typically requires direct contact with a conductive object, which means that it may not work effectively with gloves or styluses that are not designed for capacitive use. Additionally, capacitive screens can sometimes be overly sensitive, leading to accidental touches or inputs, which can be frustrating for users.As technology continues to evolve, researchers are exploring new ways to enhance capacitive technology. Innovations such as capacitive sensing in wearable devices, smart home applications, and even automotive interfaces are on the rise. These developments promise to expand the possibilities of capacitive technology, making it an even more integral part of our daily lives.In conclusion, capacitive technology has transformed the way we interact with electronic devices. Its ability to detect touch through changes in capacitance has led to more responsive and durable screens, enhancing user experience across various platforms. While there are some challenges to overcome, the future of capacitive technology looks promising, with ongoing research and development paving the way for innovative applications that will continue to shape our digital landscape.

在当今数字时代，技术已成为我们生活中不可或缺的一部分。其中最重要的进展之一是电容式技术的发展。该术语指的是一种基于人体电气特性的触摸和接近检测技术。与需要施加压力以注册触摸的电阻式触摸屏不同，电容式屏幕通过测量当导电物体（如手指）接触屏幕时电容的变化来工作。这项创新彻底改变了我们与设备互动的方式，使其更加直观和用户友好。电容式技术背后的原理在于其存储和测量电荷的能力。当手指接近屏幕时，会产生一个静电场，改变屏幕表面电荷的分布。设备的传感器检测到这些变化，并将其转换为输入命令。这种无缝的交互正是电容式屏幕广泛应用于智能手机、平板电脑和其他现代电子设备的原因之一。此外，电容式技术还具有多种优点。例如，电容式屏幕通常更灵敏，可以同时注册多个触摸点，从而允许像捏合缩放或滑动这样的手势。这种能力增强了整体用户体验，使导航应用程序和高效执行任务变得更加容易。电容式技术的另一个重要方面是其耐用性。由于它不依赖机械部件，电容式屏幕通常比电阻屏幕更耐磨损。它们还不太容易受到灰尘和湿气等环境因素的影响，这可能会影响电阻屏幕的性能。这种耐用性使得电容式技术成为在各种条件下频繁使用的设备的理想选择。然而，尽管有许多好处，电容式技术也并非没有局限性。例如，它通常需要与导电物体直接接触，这意味着在使用手套或未设计用于电容式使用的触控笔时，可能效果不佳。此外，电容式屏幕有时可能过于敏感，导致意外触摸或输入，这可能会让用户感到沮丧。随着技术的不断发展，研究人员正在探索增强电容式技术的新方法。可穿戴设备、智能家居应用甚至汽车接口中的电容式传感创新正在上升。这些发展承诺扩展电容式技术的可能性，使其成为我们日常生活中更加不可或缺的一部分。总之，电容式技术改变了我们与电子设备互动的方式。它通过电容变化检测触摸的能力导致了更具响应性和耐用性的屏幕，增强了各个平台的用户体验。虽然仍有一些挑战需要克服，但电容式技术的未来看起来充满希望，持续的研究和开发为创新应用铺平了道路，这些应用将继续塑造我们的数字环境。