Symmetric key cryptography (or symmetric encryption) is a type of encryption scheme in which the same key is used both to encrypt and decrypt messages. Such a method of encoding information has been largely used in the past decades to facilitate secret communication between governments and militaries. Nowadays, symmetric key algorithms are widely applied in various types of computer systems to enhance data security.
Symmetric encryption schemes rely on a single key that is shared between two or more users. The same key is used to encrypt and decrypt the so-called plaintext (which represents the message or piece of data that is being encoded). The process of encryption consists of running a plaintext (input) through an encryption algorithm called a cipher, which in turn generates a ciphertext (output).
If the encryption scheme is strong enough, the only way for a person to read or access the information contained in the ciphertext is by using the corresponding key to decrypt it. The process of decryption is basically converting the ciphertext back to plaintext.
The security of symmetric encryption systems is based on how difficult it randomly guess the corresponding key to brute force them. A 128-bit key, for example, would take billions of years to guess using common computer hardware. The longer the encryption key is, the harder it becomes to crack it. Keys that are 256-bits length are generally regarded as highly secure and theoretically resistant to quantum computer brute force attacks.
Two of the most common symmetric encryption schemes used today are based on block and stream ciphers. Block ciphers group data into blocks of predetermined size and each block is encrypted using the corresponding key and encryption algorithm (e.g., 128-bit plaintext is encrypted into 128-bit ciphertext). On the other hand, stream ciphers do not encrypt plaintext data by blocks, but rather by 1-bit increments (1-bit plaintext is encrypted into 1-bit ciphertext at a time).
Symmetric encryption is one of the two major methods of encrypting data in modern computer systems. The other is asymmetric encryption, which is the major application of public key cryptography. The main difference between these methods is the fact that asymmetric systems use two keys rather than the one employed by the symmetric schemes. One of the keys can be publicly shared (public key), while the other must be kept in private (private key).
The use of two keys instead of one also produces a variety of functional differences between symmetric and asymmetric encryption. Asymmetric algorithms are more complex and slower than the symmetric ones. Because the public and private keys employed in asymmetric encryption are to some degree mathematically related, the keys themselves must also be considerably longer to provide a similar level of security offered by shorter symmetric keys.
Symmetric encryption algorithms are employed in many modern computer systems to enhance data security and user privacy. The Advanced Encryption Standard (AES) that is widely used in both secure messaging applications and cloud storage is one prominent example of a symmetric cipher.
In addition to software implementations, AES can also be implemented directly in computer hardware. Hardware-based symmetric encryption schemes usually leverage the AES 256, which is a specific variant of the Advanced Encryption Standard that has a key size of 256 bits.
It is worth noting that Bitcoin’s blockchain does not make use of encryption like many tend to believe. Instead, it uses a specific kind of digital signatures algorithm (DSA) known as Elliptic Curve Digital Signature Algorithm (ECDSA) that generates digital signatures without using encryption.
A common point of confusion is that the ECDSA is based on elliptic-curve cryptography (ECC), which in turn may be applied for multiple tasks, including encryption, digital signatures, and pseudo-random generators. However, the ECDSA itself cannot be used for encryption at all.
Symmetric algorithms provide a fairly high level of security while at the same time allowing for messages to be encrypted and decrypted quickly. The relative simplicity of symmetric systems is also a logistical advantage, as they require less computing power than the asymmetric ones. In addition, the security provided by symmetric encryption can be scaled up simply by increasing key lengths. For every single bit added to the length of a symmetric key, the difficulty of cracking the encryption through a brute force attack increases exponentially.
While symmetric encryption offers a wide range of benefits, there is one major disadvantage associated with it: the inherent problem of transmitting the keys used to encrypt and decrypt data. When these keys are shared over an unsecured connection, they are vulnerable to being intercepted by malicious third parties. If an unauthorized user gains access to a particular symmetric key, the security of any data encrypted using that key is compromised. To solve this problem, many web protocols use a combination of symmetric and asymmetric encryption to establish secure connections. Among the most prominent examples of such a hybrid system is the Transport Layer Security (TLS) cryptographic protocol used to secure large portions of the modern internet.
It should also be noted that all types of computer encryption are subject to vulnerabilities due to improper implementation. While a sufficiently long key can make a brute force attack mathematically impossible, errors in implementation made by programmers often create weaknesses that open up the way for cyber attacks.
Thanks to its relative speed, simplicity, and security, symmetric encryption is used extensively in applications ranging from securing internet traffic to protecting data stored on cloud servers. Although it is frequently paired with asymmetric encryption in order to solve the problem of safely transferring keys, symmetric encryption schemes remain a critical component of modern computer security.