synchronized multivibrator

简明释义

同步多谐振荡器

英英释义

例句

1.A synchronized multivibrator 同步多谐振荡器 can help prevent signal drift in communication systems.

在通信系统中，synchronized multivibrator 同步多谐振荡器 可以帮助防止信号漂移。

2.Engineers often use a synchronized multivibrator 同步多谐振荡器 to ensure that signals remain in phase.

工程师们常常使用 synchronized multivibrator 同步多谐振荡器 来确保信号保持相位一致。

3.Using a synchronized multivibrator 同步多谐振荡器 in your design can improve the reliability of the circuit.

在设计中使用 synchronized multivibrator 同步多谐振荡器 可以提高电路的可靠性。

4.In digital circuits, a synchronized multivibrator 同步多谐振荡器 can be used to generate precise timing signals.

在数字电路中，synchronized multivibrator 同步多谐振荡器 可用于生成精确的定时信号。

5.The synchronized multivibrator 同步多谐振荡器 is essential for clock pulse generation in microcontrollers.

在微控制器中，synchronized multivibrator 同步多谐振荡器 对于时钟脉冲的生成至关重要。

作文

In the realm of electronics, timing and synchronization are crucial for the proper functioning of circuits. One component that plays a significant role in achieving this synchronization is the synchronized multivibrator. A synchronized multivibrator is an electronic circuit designed to produce precise timing signals, which are essential in various applications such as oscillators, timers, and pulse generators. Understanding how a synchronized multivibrator operates can provide insights into its importance in modern electronics.The basic operation of a synchronized multivibrator involves two main states: stable and unstable. It typically consists of two or more active devices, such as transistors or operational amplifiers, along with passive components like resistors and capacitors. The circuit can switch between these states based on the input signals it receives. When a trigger signal is applied, the synchronized multivibrator transitions from one state to another, generating a square wave output. This output can be used to drive other electronic components, ensuring they operate in harmony with the timing provided by the synchronized multivibrator.One of the key features of a synchronized multivibrator is its ability to synchronize with external signals. This means that if an external clock signal is provided, the synchronized multivibrator can adjust its output to match the frequency and phase of that signal. This synchronization is particularly important in digital circuits where multiple components need to work together without timing errors. For instance, in a microprocessor system, the synchronized multivibrator ensures that data is processed at the right moments, preventing glitches and ensuring reliable performance.Moreover, synchronized multivibrators come in various types, including astable, monostable, and bistable configurations. Each type serves different purposes. The astable configuration continuously oscillates between its high and low states, making it ideal for applications such as clock pulses. The monostable configuration, on the other hand, produces a single output pulse in response to a trigger, which is useful for timing applications. Lastly, the bistable configuration can hold its state until triggered to change, functioning like a flip-flop in digital memory applications.In practical applications, synchronized multivibrators are found in many devices, from simple toys that make sounds to complex computer systems. They are integral to the design of timers in household appliances, signal generators in communication devices, and even in automotive electronics for controlling various functions. The versatility and reliability of the synchronized multivibrator make it a fundamental building block in electronic engineering.In conclusion, the synchronized multivibrator is a vital component in the field of electronics, providing essential timing and synchronization capabilities. Its ability to generate precise timing signals and synchronize with external inputs makes it invaluable in a wide range of applications. As technology continues to advance, understanding the principles behind the synchronized multivibrator will remain important for engineers and enthusiasts alike, ensuring that they can design and implement effective electronic systems that operate seamlessly together.

在电子学领域，定时和同步对于电路的正常运行至关重要。一个在实现这种同步中发挥重要作用的组件是synchronized multivibrator（同步多谐振荡器）。synchronized multivibrator是一种电子电路，旨在产生精确的定时信号，这在各种应用中都是必不可少的，例如振荡器、定时器和脉冲发生器。理解synchronized multivibrator的工作原理可以提供对其在现代电子学中重要性的洞察。synchronized multivibrator的基本操作涉及两个主要状态：稳定状态和不稳定状态。它通常由两个或多个有源器件（例如晶体管或运算放大器）以及被动元件（如电阻和电容）组成。电路可以根据接收到的输入信号在这些状态之间切换。当施加触发信号时，synchronized multivibrator会从一个状态过渡到另一个状态，生成方波输出。该输出可用于驱动其他电子组件，确保它们与synchronized multivibrator提供的定时信号协调工作。synchronized multivibrator的一个关键特性是其与外部信号同步的能力。这意味着，如果提供外部时钟信号，synchronized multivibrator可以调整其输出以匹配该信号的频率和相位。这种同步在数字电路中特别重要，因为多个组件需要无误差地协同工作。例如，在微处理器系统中，synchronized multivibrator确保数据在正确的时刻被处理，从而防止故障并确保可靠的性能。此外，synchronized multivibrators有多种类型，包括非稳态、单稳态和双稳态配置。每种类型服务于不同的目的。非稳态配置在高低状态之间不断振荡，适合用作时钟脉冲。单稳态配置则在触发时产生单个输出脉冲，适用于定时应用。最后，双稳态配置可以保持其状态，直到被触发更改，像数字存储器中的触发器一样工作。在实际应用中，synchronized multivibrators广泛存在于许多设备中，从发声的简单玩具到复杂的计算机系统。它们是家用电器定时器、通信设备信号发生器，甚至汽车电子控制各种功能的设计中不可或缺的一部分。synchronized multivibrator的多功能性和可靠性使其成为电子工程中的基本构件。总之，synchronized multivibrator是电子学领域的重要组成部分，提供了必要的定时和同步能力。它生成精确的定时信号并与外部输入同步的能力使其在广泛的应用中不可或缺。随着技术的不断进步，理解synchronized multivibrator背后的原理将继续对工程师和爱好者来说至关重要，确保他们能够设计和实施有效的电子系统，使其无缝协作。