resistive

简明释义

英[rɪˈzɪstɪv]美[rɪˈzɪstɪv]

adj. 有抵抗力的；抗……的，耐……的；电阻的

英英释义

单词用法

同义词

反义词

例句

1.The very nature of resistive screens means that their top layer is soft, soft enough to press down and indent.

电阻屏的根本特性决定了它的顶部是柔软的，需要能够按下去。

2.The new iDECT iHome Phone is an Android powered cordless phone with a 2.8inch (320 x 240 pixels) resistive touch-screen.

这款最新的iDECTiHome Phone是一款基于Android的无绳电话，拥有一个2.8英寸的、分辨率320X240的电阻式触摸屏。

3.This control board applies to the 4wire Analog Resistive Film Input Panel.

此控制板适用于4线模拟式电阻输入屏。

4.We close this chapter on resistive circuits with a brief introduction to the subject of electrical measurements.

我们结束电阻电路这一章时，简短地介绍一下电气测量问题。

5.As most of us are aware, speakers are not pure resistive loads.

大部分人都知道，扬声器不是纯粹的电阻性负载。

6.Resistive touch screen.

电阻式触摸屏。

7.The earliest IC op amp OUTPUT stages were NPN emitter followers with NPN current sources or resistive pull-downs, as shown in Figure 1.6.

最初的集成运算放大器的输出级是NPN电流源的NPN放射追随器或通过电阻下拉，如图1.6所示。

8.The converter is therefore suited as a signal conditioner of a resistive sensor.

因此，此电路特别适用于电阻式传感元件的信号处理。

9.The new heating system uses a more efficient resistive 电阻性的 element to warm the room quickly.

新的供暖系统使用更高效的电阻性元件快速加热房间。

10.In electronics, a resistive 电阻性的 load can affect the overall performance of the circuit.

在电子学中，电阻性负载会影响电路的整体性能。

11.The resistive 电阻性的 touchscreen allows for precise control over the device.

这个电阻性触摸屏允许对设备进行精确控制。

12.Using resistive 电阻性的 materials can help reduce energy loss in electrical systems.

使用电阻性材料可以帮助减少电力系统中的能量损耗。

13.The resistive 电阻性的 heating element in the oven provides consistent temperature control.

烤箱中的电阻性加热元件提供一致的温度控制。

作文

In the world of electronics, understanding the properties of materials is crucial for designing efficient circuits and devices. One term that often comes up in this context is resistive, which refers to the opposition that a material offers to the flow of electric current. This property is fundamental in determining how well a component will perform in a circuit. For instance, resistive materials, such as resistors, are specifically designed to limit the amount of current that can pass through them. The ability to control current flow is essential in various applications, from simple household appliances to complex computer systems. When we talk about resistive materials, we usually refer to their resistance, which is measured in ohms. The higher the resistance, the less current will flow through the material when a voltage is applied. This characteristic allows engineers to design circuits that can safely handle specific amounts of current without overheating or causing damage. Additionally, resistive materials play a critical role in energy dissipation. When current flows through a resistor, electrical energy is converted into heat, which can be beneficial in some applications, such as heating elements, but detrimental in others, where excessive heat could lead to failure. The concept of resistive behavior is not limited to just resistors. Many materials exhibit resistive properties, including metals, semiconductors, and insulators. Metals, for example, typically have low resistance and are excellent conductors of electricity. On the other hand, insulators have high resistance and prevent electric current from flowing freely. Semiconductors, which lie between conductors and insulators, can have their resistive properties manipulated by adding impurities, a process known as doping. This versatility makes semiconductors essential for modern electronics, as they form the basis of transistors and diodes, which are fundamental components in digital circuits. Moreover, the resistive nature of materials can be utilized in various sensing applications. For example, temperature sensors often rely on the principle that the resistance of certain materials changes with temperature. By measuring this change in resistance, we can infer the temperature of the environment. Similarly, strain gauges use resistive properties to measure deformation in materials, providing valuable data in structural engineering and safety assessments. In conclusion, the term resistive encompasses a wide range of concepts and applications in the field of electronics and materials science. Understanding the resistive properties of materials allows engineers and scientists to innovate and improve the efficiency of electronic devices. From controlling current flow in circuits to developing sensitive sensors, resistive materials are at the heart of many technological advancements. As we continue to explore new materials and their properties, the significance of resistive behavior will undoubtedly remain a key focus in the quest for more efficient and effective electronic solutions.

在电子世界中，理解材料的特性对于设计高效的电路和设备至关重要。一个常常出现的术语是resistive，它指的是材料对电流流动的阻碍。这一特性在确定组件在电路中的性能时是基础性的。例如，resistive材料，如电阻器，专门设计用于限制通过它们的电流量。控制电流流动的能力在各种应用中都是必不可少的，从简单的家用电器到复杂的计算机系统。 当我们谈论resistive材料时，通常是指它们的电阻，单位是欧姆。电阻越高，当施加电压时，流过材料的电流就越少。这一特性使工程师能够设计出可以安全处理特定电流量而不会过热或造成损坏的电路。此外，resistive材料在能量耗散中也发挥着关键作用。当电流流过电阻器时，电能转化为热能，这在某些应用中是有益的，比如加热元件，但在其他应用中，过多的热量可能导致故障。 Resistive行为的概念并不仅限于电阻器。许多材料表现出resistive特性，包括金属、半导体和绝缘体。例如，金属通常具有低电阻，是电的优秀导体。另一方面，绝缘体具有高电阻，防止电流自由流动。半导体则介于导体和绝缘体之间，其resistive特性可以通过添加杂质来调节，这一过程称为掺杂。这种多样性使半导体成为现代电子学的核心，因为它们构成了晶体管和二极管的基础，这些都是数字电路中的基本组件。 此外，材料的resistive特性可以应用于各种传感器应用。例如，温度传感器通常依赖于某些材料的电阻随温度变化的原理。通过测量这种电阻的变化，我们可以推断环境温度。同样，应变计利用resistive特性来测量材料的变形，为结构工程和安全评估提供宝贵的数据。 总之，resistive一词涵盖了电子学和材料科学领域中的广泛概念和应用。理解材料的resistive特性使工程师和科学家能够创新和提高电子设备的效率。从控制电路中的电流流动到开发敏感传感器，resistive材料在许多技术进步的核心。随着我们继续探索新材料及其特性，resistive行为的重要性无疑将继续成为寻求更高效和有效电子解决方案的关键焦点。