logic design translator

简明释义

逻辑设计译码器

英英释义

例句

1.The logic design translator supports multiple input formats for greater flexibility.

该逻辑设计翻译器支持多种输入格式，以提高灵活性。

2.A logic design translator simplifies the process of moving from high-level design to implementation.

一个逻辑设计翻译器简化了从高级设计到实现的过程。

3.Using a logic design translator can reduce errors in the design process significantly.

使用逻辑设计翻译器可以显著减少设计过程中的错误。

4.The engineer used a logic design translator to convert the schematic into an HDL format.

工程师使用了一个逻辑设计翻译器将原理图转换为HDL格式。

5.With the help of a logic design translator, we can easily verify the functionality of our circuit designs.

借助逻辑设计翻译器，我们可以轻松验证电路设计的功能。

作文

In the realm of digital electronics and computer engineering, the term logic design translator plays a crucial role in bridging the gap between abstract design concepts and practical implementations. A logic design translator is essentially a tool or software that transforms high-level logic designs into a format that can be synthesized into hardware. This transformation is vital for engineers who aim to create functional circuits from their theoretical designs. The process begins with the creation of a logic design, which can be represented through various means such as Boolean algebra, truth tables, or schematic diagrams. Once the design is finalized, it needs to be translated into a form that can be understood by hardware description languages (HDLs) like VHDL or Verilog.The significance of a logic design translator cannot be overstated. It not only simplifies the design process but also enhances accuracy and efficiency. Without such a translator, engineers would have to manually convert their designs into HDL, a task that is prone to human error and can be incredibly time-consuming. By automating this translation process, a logic design translator allows engineers to focus on optimizing their designs rather than getting bogged down in the minutiae of syntax and formatting.Moreover, modern logic design translators often come equipped with features that allow for simulation and verification of designs before they are implemented in hardware. This capability is essential for identifying potential issues early in the design process, thereby saving time and resources. For instance, an engineer can test how their design behaves under various conditions using a simulator integrated with the logic design translator. This feedback loop is invaluable, as it enables rapid prototyping and iterative improvements.In addition to simulation capabilities, many logic design translators offer optimization tools that help improve the performance of the final hardware. These tools analyze the translated design for potential bottlenecks and suggest modifications that can lead to faster operation or reduced power consumption. As technology advances and the need for efficient, high-performance designs increases, the role of logic design translators becomes even more critical.Furthermore, the evolution of logic design translators reflects broader trends in the field of electronics. With the rise of complex systems-on-chip (SoCs) and the Internet of Things (IoT), the demand for sophisticated design tools has surged. Engineers are now tasked with integrating multiple functionalities into a single chip, which requires advanced design methodologies and robust translation capabilities. A reliable logic design translator is therefore indispensable in ensuring that these complex designs can be realized without compromising on quality or performance.In conclusion, the logic design translator is a pivotal component in the landscape of electronic design automation. By facilitating the transformation of abstract logic designs into synthesizable formats, it empowers engineers to innovate and create cutting-edge technologies. As the field continues to evolve, the importance of effective translation tools will only grow, underscoring the need for ongoing advancements in logic design translators and their associated technologies. The future of digital design relies heavily on these translators, making them an essential focus for both current and aspiring engineers in the field.

在数字电子和计算机工程领域，术语逻辑设计翻译器在抽象设计概念与实际实现之间架起了重要的桥梁。逻辑设计翻译器基本上是一个工具或软件，它将高级逻辑设计转换为可以合成到硬件中的格式。这一转化对于旨在从理论设计中创建功能电路的工程师至关重要。该过程始于逻辑设计的创建，可以通过布尔代数、真值表或原理图等多种方式表示。一旦设计最终确定，就需要将其转换为硬件描述语言（HDL）如VHDL或Verilog所能理解的形式。逻辑设计翻译器的重要性不容小觑。它不仅简化了设计过程，还提高了准确性和效率。如果没有这样的翻译器，工程师就必须手动将他们的设计转换为HDL，这是一项容易出错且极其耗时的任务。通过自动化这一翻译过程，逻辑设计翻译器使工程师能够专注于优化设计，而不是被语法和格式的细节所困扰。此外，现代的逻辑设计翻译器通常配备了在硬件实施之前对设计进行仿真和验证的功能。这一能力对于在设计过程中及早识别潜在问题至关重要，从而节省时间和资源。例如，工程师可以使用与逻辑设计翻译器集成的仿真器测试他们的设计在各种条件下的表现。这种反馈循环是无价的，因为它使快速原型制作和迭代改进成为可能。除了仿真能力，许多逻辑设计翻译器还提供优化工具，帮助提高最终硬件的性能。这些工具分析翻译后的设计以寻找潜在瓶颈，并建议可以导致更快操作或降低功耗的修改。随着技术的进步和对高效、高性能设计需求的增加，逻辑设计翻译器的角色变得更加关键。此外，逻辑设计翻译器的演变反映了电子领域的更广泛趋势。随着复杂系统芯片（SoC）和物联网（IoT）的兴起，对复杂设计工具的需求激增。工程师现在面临着将多种功能集成到单个芯片中的任务，这需要先进的设计方法和强大的翻译能力。因此，一个可靠的逻辑设计翻译器在确保这些复杂设计能够实现而不影响质量或性能方面是不可或缺的。总之，逻辑设计翻译器是电子设计自动化领域的关键组成部分。通过促进将抽象逻辑设计转换为可合成格式的过程，它赋予工程师创新和创造尖端技术的能力。随着该领域的不断发展，有效翻译工具的重要性只会增加，这突显了对逻辑设计翻译器及其相关技术持续进步的需求。数字设计的未来在很大程度上依赖于这些翻译器，使其成为当前和未来工程师在该领域的重点关注对象。