decryption

简明释义

英[diːˈkrɪpʃn]美[diːˈkrɪpʃn]

n. [通信] 解密；[计][通信] 译码（解释编码的数据）

英英释义

单词用法

同义词

反义词

例句

1.The target server receives the request and passes the deserialized token to the application server for decryption.

目标服务器接收请求，并将反序列化后的令牌传递给应用服务器进行解密。

2.Using various decryption tools we can identify these three coded phrases.

运用各种解密工具我们确定了这三个密码词语。

3.This version of SQL Server has built-in encryption/decryption so you do not need to modify your application code.

这个SQLServer版本内建有加密/解密，这样您就不用去修改您的应用代码。

4.The string manipulation functions in Listing 13 replace the lost formatting before the decryption command is called.

在调用解密命令之前，清单13中的字符串操作函数将替换丢失的格式。

5.Instead, the other key in the pair must be used for the decryption.

相反，这对密匙值的另外一个密匙必须用于解密。

6.The pass phrase is used only for client-side encryption and decryption of your browser data.

该短语仅用于客户端的浏览器数据加解密。

7.The process of decryption allows us to convert the encoded message back into its original form.

这个解密过程使我们能够将编码的信息转换回其原始形式。

8.After the decryption of the data, we were able to access the sensitive information.

在数据的解密之后，我们能够访问敏感信息。

9.The software uses advanced algorithms for decryption to ensure data security.

该软件使用先进的算法进行解密以确保数据安全。

10.In cybersecurity, decryption is crucial for recovering lost data.

在网络安全中，解密对于恢复丢失的数据至关重要。

11.We implemented a new system for decryption to enhance our communication security.

我们实施了一个新的解密系统，以增强我们的通信安全。

作文

In the digital age, where information is exchanged at lightning speed, the importance of data security cannot be overstated. One of the key processes in ensuring that sensitive information remains confidential is through the use of encryption and its counterpart, decryption. Decryption is the process of converting encrypted data back into its original form, making it readable and usable again. This is crucial for both individuals and organizations that rely on secure communication to protect their private information from unauthorized access. Encryption works by transforming plain text into a coded format using algorithms and keys, which makes it unreadable to anyone who does not possess the correct decryption key. For instance, when you send an email containing sensitive information, it is often encrypted to prevent hackers from intercepting and reading the content. Once the intended recipient receives the email, they can use their unique key to decrypt the message, restoring it to its original form so that it can be understood. The significance of decryption extends beyond personal communications. In the corporate world, businesses handle vast amounts of sensitive data, including customer information, financial records, and proprietary research. Without effective encryption and decryption methods, this data would be vulnerable to theft and misuse. For example, if a company’s database were to be hacked and the data stolen, the absence of proper encryption could lead to catastrophic consequences, including financial loss and damage to reputation. Moreover, the field of cybersecurity is constantly evolving, with new threats emerging daily. As hackers develop more sophisticated techniques to breach security systems, the methods of encryption and decryption must also advance. This ongoing battle between security measures and cyber threats highlights the need for continuous innovation in cryptographic practices. Researchers and developers are working tirelessly to create stronger encryption algorithms that can withstand potential attacks, while also ensuring that the decryption process remains efficient and accessible for authorized users. In addition to its technical aspects, decryption also raises ethical considerations. The balance between privacy and security is a contentious issue in today’s society. Governments and law enforcement agencies often argue for the ability to bypass encryption in order to investigate criminal activities. However, this poses a risk to individual privacy rights, as it could potentially allow unauthorized access to personal information. Finding a solution that satisfies both security needs and privacy concerns is an ongoing challenge. In conclusion, decryption plays a vital role in the realm of data security. It enables the retrieval of information that has been protected through encryption, safeguarding sensitive data from prying eyes. As technology continues to advance and cyber threats become increasingly complex, the processes of encryption and decryption will remain essential components of our digital lives. Understanding these concepts is crucial for anyone navigating the modern information landscape, whether for personal protection or professional responsibility. The future of data security hinges on our ability to effectively implement and manage these processes, ensuring that confidentiality and integrity are maintained in an ever-connected world.

在数字时代，信息以闪电般的速度交换，数据安全的重要性不容小觑。确保敏感信息保持机密的关键过程之一就是使用加密及其对应的解密。解密是将加密数据转换回其原始形式的过程，使其再次可读和可用。这对于依赖安全通信以保护私人信息免遭未授权访问的个人和组织至关重要。 加密通过使用算法和密钥将普通文本转换为编码格式，从而使其对没有正确解密密钥的人不可读。例如，当您发送一封包含敏感信息的电子邮件时，它通常会被加密，以防止黑客拦截并读取内容。一旦预期的收件人收到电子邮件，他们可以使用自己的唯一密钥来解密消息，将其恢复为原始形式，以便理解。 解密的重要性不仅限于个人通信。在企业界，企业处理大量敏感数据，包括客户信息、财务记录和专有研究。如果没有有效的加密和解密方法，这些数据将容易受到盗窃和滥用的威胁。例如，如果一家公司数据库被黑客攻击并窃取数据，缺乏适当的加密可能导致灾难性的后果，包括财务损失和声誉受损。 此外，网络安全领域正在不断发展，每天都有新的威胁出现。随着黑客开发出更复杂的技术来突破安全系统，加密和解密的方法也必须不断进步。这场安全措施与网络威胁之间的持续斗争突显了在密码学实践中不断创新的必要性。研究人员和开发人员正在不懈努力，创造更强大的加密算法，以抵御潜在攻击，同时确保解密过程对授权用户保持高效和可访问。 除了技术方面，解密还引发了伦理考虑。隐私与安全之间的平衡在当今社会是一个有争议的问题。政府和执法机构通常主张能够绕过加密，以调查犯罪活动。然而，这对个人隐私权构成了风险，因为它可能允许未经授权访问个人信息。找到满足安全需求和隐私关注的解决方案是一个持续的挑战。 总之，解密在数据安全领域发挥着至关重要的作用。它使得被加密保护的信息得以检索，保护敏感数据免受窥探。随着技术的不断进步和网络威胁日益复杂，加密和解密的过程将继续成为我们数字生活的重要组成部分。理解这些概念对于任何在现代信息环境中导航的人来说都是至关重要的，无论是为了个人保护还是职业责任。数据安全的未来取决于我们有效实施和管理这些过程的能力，确保在一个互联的世界中保持机密性和完整性。