1. Introduction
Internet of things, an enormously focused topic for research which has reformed the human life by its capability to provide uncountable number of advanced computational provisions. In IoT, the ‘things’ denote a physical entity which has an exclusive identifier with automatic processing and data transmitting capacity for a particular task. It can seamlessly build an excellent and universal link with the physical matters surrounding the digital world and us. Tremendous leap in the advancement of IoT dispositions and solutions is the greatest good the globe is seeing nowadays. The present world is changing rapidly and is becoming smart with the blessing of IoT through various challenging areas of application like mobile edge computing [1], [2], intelligent vehicular transport [3], [4] intelligent automation in buildings and houses [5], intelligent agriculture and farming [6], intelligent energy and IoT enabled smart grids [7], power constrained systems [8], healthcare systems [9], [10] etc. IoT is growing at a very fast pace in the world of information and data but it’s sustained growth can suffer a lot due to the absence of sufficient privacy and security measures. Main function of IoT devices is to collect various kinds data sensed through different sensors among which few are very sensitive and confidential and should not be disclosed. According to survey of various industries, the most important concern is the data security in today’s IoT users [11]. Therefore, integration of many features in terms of security for hardware and software both is utmost important to enhance the security of IoT device and to make sure that the vital sensed data are protected. For this reason, applying the concept of cryptography is a good option for IoT device’s physical constraints. Before sending to the cloud server in the back end cryptographic algorithms are used in IoT devices by using authentication mechanisms like in [12] to maintain integrity of data and prevent hackers to sniff the data. Although data security based on cryptography is finding importance at a very increasing rate, but still it is more of a challenge to fit various cryptographic algorithms with huge power and area overheads in an IoT device. An efficient and suitable key management is required for encryption of IoT devices as security is compromised if the key management is poor. IoT devices are named so because they are meant to be designed with low storage. Also, IoT devices are run on battery and hence power requirement must be low. Hence symmetric key cryptography is preferred to design IoT devices because they take less power, space, bandwidth and complexity when compared to asymmetric key cryptography.
Over the past decade to achieve ease of implementation in hardware and software the block cipher which is a type of secret key cryptographic approach proved to be most useful due to high diffusion and error propagating property. In comparison with the stream cipher the block cipher uses very low hardware resources. The old block cipher for example the Advanced Encryption Standard (AES) requires about 3400 Gate Equivalent (GE) of area [13]. It is very hard for traditionally designed block ciphers for wireless equipment to be implanted in the device. Gate equivalent is a unit by which the complexity of manufacturing-technology- independent digital circuits is measured. In complementary metal oxide semiconductor (CMOS) technology of today, a gate equivalent is the covered area by silicon of a simple 2- input NAND gate which is the fundamental technology dependent unit area. In a particular circuit the gate equivalent count gives a measure of complexity with the help of which the corresponding area of the silicon can be calculated for a particular manufacturing process.
Traditional Feistel structured ciphers require huge amount of time and power when making block ciphers because they go through many numbers of round functions as compared to the substitution-permutation network (SPN). For this reason, Feistel structure and Substitution Permutation Network both are used combinedly in many studies. When combined together the structures yield small and simple round functions for less use of storage and energy with a fast diffusion process. With vulnerabilities and difficulties taken into account a light symmetrical key cryptography method is proposed here for light IoT devices overcoming all the shortcomings in previous works.
This new design discussed here exploits the joint benefits of Feistel and Substitution Combination Network (SPN) together to achieve a fast diffusion process. In addition, the circular key management strategy is also compatible with the encryption method. Additionally, an energy efficient hardware which uses recent technological advancements with less nodal power is developed, which uses more gate operations for providing sufficient protection with lower power usage. A FPGA board is used as a testing platform of the prototype model to verify its correctness of application. The proposed work will find it’s true potential when applied in the fields of smart agriculture and farming, healthcare systems and other domains too where encrypted and secure transmission of data is of top priority. Table 1 listed here contains the detailed information of some practical sensors mentioned in [56] with their area of application in which the designed LCB can be implanted for improved level of security in sensing capacity. If correctly configured, this LCB can find its application in IoT devices and wide range of sensors and will not be restricted in these mentioned sensors. Various analyses are shown here to support the strength and feasibility of the designed scheme.
Table 1. Details of some practical sensors [56]
The remaining paper is ordered as follows: Section 2 discusses relevant works in related fields in details. Section 4 contains a detailed explanation about the working and mechanism of the proposed light cryptography algorithm. Section 5 brings up a discussion about the results of different analyses performed in the test environment. Section 6 finally concludes the paper.
2. Key Challenges and Motivation
The main problems faced during implementation of standard cryptographic algorithms in IoT devices are given below [14]:
• Inadequate memory (ROM, RAM, registers)
• Minimized computational power
• Less physical area for implementation Little power of battery
• Response in real time
IoT devices like sensors and RFIDs mostly have limitation in size [15], memory, processing power [15] with the need of speedy, accurate results for real-time applications with necessary security becomes a very challenging task altogether [16]. Numerous risks are faced by the designers of IoT devices which includes protection of data [17] and energy capacity [18]. The above points are enough for finding motivation in pursuit of designing a new, robust lightweight block cipher. The design is attempted to make use of as less number of Gate equivalent area (GE) possible by minimizing the logical operations throughout the encryption rounds which make unnecessary propagation delays, larger area consumption and also least possible computing power yet maintaining decent security of data. All the other proposed widely used lightweight block ciphers use much greater number of logical operations like XOR along with many rounds which eventually increases the resource utilization.
Because of their simplicity, lightweight cryptography is vulnerable to attacks [19]. Different attacks like linear cryptanalysis [20], algebraic attack along with differential attack [21] and saturation attack [22] weakens PRESENT cipher mostly due to the use of small S- Boxes. This becomes a point for getting strong motivation for designing a new kind of light cipher block with increased security by introduction of strong F-function composed of 8-bit P-boxes and 16-bit L-boxes which overcomes the shortcomings of use of 4-bit S-boxes in PRESENT.
3. Literature Survey
Power, size of data and computational cost are the primary concerns which are to be taken care of by light cryptographic algorithm and reducing them to minimal levels. For this reason, the main objective to make it lightweight for specific small IoT devices the parameters like power usage, chip area, memory requirement etc. [23] should be in the designer’s focus. In spite of being lightweight, weak security led to the disposal of these algorithms. Few popular algorithms are still followed in various application areas like Tiny Encryption Algorithm (TEA) [24], HIGHT [25], mCRYPTON [26], CLEFIA [27], PRESENT [28], KTANTAN and KATAN [29], GOST [30], PICCOLO [31], SPONGENT [32], Light Encryption Device [33], PHOTON [34], KLEIN [35], PRINCE [36], Low power Encryption Algorithm (LEA) [37], MIDORI [38], PRIDE [39], SIMON and SPECK [40].
Few very common new lightweight ciphers blocks have been taken into discussion [41] which announced the Substitution Permutation Feistel Network (SFN) method of encryption by combining both Feistel structure and Substitution Permutation Network (SPN) together. The aforementioned method used 64-bit input with a key length of 96 bits where the last 32 bits of the key functioned as a control signal and the left 64 bits served the purpose of expansion of key and encryption process in round manner. In that control signal of 32 bits, every single bit is used for performing one round and to select the mode of working for two structures (Substitution Permutation Network and Feistel Network) like encryption and decryption and key expanding. Hardware implementation of Substitution Feistel Network took Gate Equivalent area of 1876.04. HIGHT [25] is an ultra-light weight block cipher intended to be used for low resource consuming devices like in sensors in USN or a RFID tag which use simple operations to be energy efficient with 3048 GEs on 0.25 μm technology. Another 64-bit block cipher introduced for tiny resource constrained devices named as mCRYPTON [26] which encrypts data in twelve rounds by nibble wise substitution, column wise bit permutation, transposition of column to row and addition of key. It takes 2420 GEs in hardware implementation. A very well-known Russian encryption algorithm GOST 28147-89 revisited by Poschmann et al. [30] optimizing its design by selecting only one S-box instead of eight different one to greatly reduce the area requirement constraint to 651 GE. Researchers invented a new member of the lightweight block cipher family for limited resourced devices like sensor nodes and RFIDs called as KLEIN [35] which used SPN structure for encryption and decryption and consumed 2629 gates of area. Some researchers suggested a collection of lightweight cipher block named as CHAM [42] that depended on a Feistel structure of four branch and containing Addition, Rotation and XOR (ARX) operation. This design used small area when implemented in hardware because of its simple key scheduling without updating the status of the key. To use the reduced set of keys of rounds in iteration repeatedly in this method the different round functions are designed in such a way. LiCi, a lightweight algorithm of block cipher design developed by Patil et al. [43] consisted of lightweight Substitution boxes of 4 × 4 dimension passed through 31 rounds successively. This design was for supporting 64-bits input as plaintext with key length of 128 bits. Gate Equivalent area, memory and power utilized by it was 1153 GEs, 1944 Bytes and 30mW. In 2017 a researcher [44] presented a light approach for cryptographic encryption based on SPN called BORON which had input as 64-bit plaintext and 128 or 80 bits of key length. This method comprised of 25 stages of encryption with 4 cross 4 substitution boxes and operations like round permutation, bit shifting and XOR making it resistant to differential and linear attacks. For 128-bit key and 80-bit key the area required for software and hardware implementation of BORON are 1939 GE and 1626 GE respectively. The architecture of PRESENT was revised by Banik et al. [45] and an improved version of block cipher based on SPN was proposed named as GIFT. This new method basically introduced cheaper and smaller S-Box by presenting bit permutation along with Linear Approximation Table (LAT) and Difference Distribution Table (DDT) of the substitution box resulting in less circuit complexity and faster computation. With a constant key size of 128 bits, the GIFT had two variations GIFT 64 and GIFT 128 with 28 and 40 encryption rounds respectively. A new algorithm of 64-bit block cipher called QTL which is introduced with the amalgamation of substitution permutation network and the regular Feistel network by researchers [46] for encryption. Moreover, this method could operate with both 64-bit key and 128 bits key. Same method was followed for decryption just like the encryption but taking round sub keys and round constants only in opposite manner. For the reduction of power and memory in hardware of QTL scheduling of key was omitted. On hardware for 128 bits and 64 bits keys this QTL takes 1206.52 GE area and 1025.52 GE area respectively. Main drawback of QTL [47] is its inability to protect against normal statistical attacks. RECTANGLE, a substitution permutation-based block cipher suggested by Zhang et al. [48] accepts input as 64-bit block and 80/128 bits keys for giving ciphertext (CT) of 64-bit. Power and area requirement for block cipher implementation are 74.31 μw and 1600 gate equivalents for 80-bit key case and 72.15 μw and 2064 gate equivalents for 128-bit key case. Few plus points of this method are speed and simple and friendly hardware design etc. A new architecture of lightweight block cipher was introduced by a group of researchers [49] which had integrated alternate key idea in regular Feistel structure. They also brought into effect again a software based lightweight block cipher featuring 80-bit input block and key of 80- bits length named ITUBEE. For improved security ITUBEE was made for 20 encryption rounds and whitening of key layers. Substitution box from the AES encryption technique was used in this architecture for the sake of reduction of memory, power and delay. ITUBEE proved its worth for its resistance against different key related attacks. The same authors of ITUBEE again introduced a new system of block cipher by altering the key in different rounds in Feistel structure called AKF [50]. A family of lightweight compact regular cipher block proposed by Yang et al. [51] by combining the benefits of SIMON and SPECK both known as SIMECK. The implementation in hardware was done on 130 nm and 65 nm CMOS process. SIMECK developed by Yang et al. [51] showed its weakness against random byte fault attack and bit flip fault attack [52]. A symmetric Substitution Permutation Network type of block cipher named as LED was designed by Guo et al. [33]. It had made use of 64 bits input and 64 bits or 128 bits key length for 64-bit LED and 128-bit LED respectively. Similar to the rounds in AES, LED also had a series of similar encryption rounds which was made up of three functions like Constant addition, Substitution of Cells, Row shifting and Column mixing. The researchers promised their scheme to be impervious to single key and related attack. Researchers made use of ECC (elliptic curve cryptography) for designing proxy re-encryption system for improving the security in lightweight devices [53]. But the scheme proved to be insignificant because of extra calculation in polynomial equation. A lightweight round cipher block of 36 rounds was proposed by Suzaki et al. [54] called TWINE which has its input as 64 bits and 80- or 128-bits key length. TWINE-80 was improved in terms of security by Wei et al. [55] to make it resistant against differential cryptographic analysis and by one round improvement against conventional differential attacks. Biswas et al. [56] had proposed a 16- bit key length cryptographic strategy with 24 rounds of operation by uniting the SPN and Feistel structure together for confirming a fast diffusion process which consumes 258.9 GE area on 65 nm process technology.
4. System model
Sensors can easily be deployable by lightweight cryptographic chips inside them for conversion of normal unmasked data to masked one helping to configure the encrypting mechanism of sensing layer. Fig. 1 shows a system model that depicts the importance of cryptographic circuitry in a sensor similar to the model built in [56]. The analog signal generated through the sensors needs to be converted to digital signal by a sensor compatible Analog to Digital Converter which becomes an input for the security chip. Then the digital sensed information is encrypted on the basis of the hardcoded cryptographic algorithms on the chip and is sent for storage in cloud server after passing through data analytics center. This encrypted data provided by cloud service provider can only be accessed by an authorized user from the cloud server. This type of light security chip design will be of great help for many security specific applications like home automation, smart healthcare system and smart agriculture etc. For this reason, a light cryptographic method called LCB has been proposed. Many related strategies have been inspected and for enhancing the system’s system a novel resource restricted lightweight block cipher is designed called LCB. This newly designed algorithm is an incorporation of Substitution Permutation Network and Feistel structure together with combination of key kept simple. Normally a regular Feistel structure makes use of huge number of encryptions rounds but performs operation on half of the block only. The substitution permutation network uses confusion and diffusion tactic to increase the plaintext’s redundancy ensuring a strong encrypted ciphertext. Hence, a combination of two structures has promised a more robust and protected system compared to when those structures are used individually. Speed, power, memory and storage are the key parameters to be kept in mind for the design of lightweight cryptographic system.
Fig. 1. System Model
5. Outline of LCB
The proposed algorithm presented here uses simple logical Ex-OR operations, bit scrambling and concatenation. Hence only an authorized user can decrypt the enciphered data for use. The proposed method operates with 32 bits of plaintext data keeping in mind to design lightest weight possible encryption system. For this reason, the lengthy block of data is divided into several blocks of 32 bits which in turn is treated by a data path and the process repeats for next blocks of data also. After processing all blocks of data, the encrypted data is obtained by merging the end results. Four subkeys each of 16 bits derived from the main key are used in different rounds of encryption. Thus, the proposed approach of enciphering uses less power, consumes less memory and storage space to achieve high performance for devices with tight resource budget which means it can achieve the solution without breaching all the constraints mentioned before and delivering better protection from different cryptanalysis techniques.
5.1 Key formation
Four subkeys each of 16-bit width ( K1, K2, K3 and K4 ) are derived from the main 64-bit key in the proposed method of encryption and decryption. The need for building a lightweight encryption process has led to build a strong but simple key generation tactic by feeding different subkeys in different F-functions of different rounds of encryption process. As mentioned earlier ten different rounds of encryption uses four different subkeys sequence generated from the main key which are used in different levels of round operations guarantees resilience against related key attacks. The subkey generation strategy is depicted in Key generation algorithm.
5.2 Encryption policy
Encryption is the process of conversion of readable data to unreadable form by adopting different confusion and diffusion strategies. Hence it is very important to make this approach more protective to different cryptanalyst’s attacks. The proposed LCB is well explained and its encryption process is depicted clearly in Algorithm 1 and for block diagram representation Fig. 2 is shown. The newly designed algorithm passes over repetitive number of steps which includes F-function and round transposition for ten successive rounds of operation. Intermediate ciphertext outputs are generated after each round which are fed immediately to the next round. The output generated after completion of ten consecutive rounds is the final ciphertext output (CT).
Fig. 2. Encryption Process of LCB
Algorithm 1: LCB Encryption
Algorithm 2: F-Function
S-Box Algorithm
P-Box Algorithm
L-Box Algorithm
Key Generation
5.2.1 F-function generation
According to the proposed method, each round consists of two F-functions which is again built up of three different functional boxes called S, P and L-Box. All these blocks perform different types of computations as described in the algorithm section. Inside the F-Block the incoming data is split up into four parts and each one fed to each of the four S-Boxes present inside which in turn gives the output to the next P-Box which again feeds its output as input to the L-Box. The exact operations going on inside these individual blocks is shown in Algorithm 2. A suitable example will make it understandable about the operations going on inside each box.
Fig. 3. Architecture of F-Block.
5.2.2 Round transposition
The data goes through round transposition after passing through F-function where the incoming data bits are swapped and fed as input to the next round which is demonstrated in Fig. 4. This process is to ensure an extra layer of security on the data. According to the figure shown the input for this transposition process is 16 bits. The resultant output of 16 bits obtained after transposition is made as input to the next round.
Fig. 4. Round transposition process of LCB
5.3 Decryption strategy
Designing an equally strong decryption algorithm is unquestionably important when developing an encryption process. Here as the structure of the algorithm is Feistel in nature so regularity is maintained in both encryption and decryption flow but the whole process is inverted for the decryption technique.
6. Design technique
6.1 F-Block
As previously said, input plaintext of 32 bits is split up into two blocks of 16 bits each. The components of light and secure designed proposed F-Box are S, P and L-Boxes. As seen in the literature the 8×8 S-Boxes use much more resource in hardware implementation while providing better security which is a challenge for lightweight devices. For this reason, four 4×4 S-Boxes are introduced in this algorithm for its low power consumption and less area requirement when compared with the 8×8 S-Box.
On the other hand, the P-Box doubles the data width by concatenating the input bits from previous S-Boxes in a particular manner as shown in Algorithm 2 thus producing an output of 8 bits. L-Block also does the same operation just like P-Block taking two inputs of 8 bits and producing output of 16 bits which is in turn XORed with the subkey produced and the final output of the F-Block is given as directed in the algorithm section. To make the design ultra lightweight for very low consumption of area and power in hardware and to achieve maximum speed of computation minimum number of logical operations are used and maximum focus was kept on bit jumbling and scrambling. The F-Block algorithm is made so simple that it uses only one 16-bit XOR gate in each F-Function. The block diagram of the proposed algorithm is shown in Fig. 2 and that of a single F-Block in Fig. 3. The whole algorithm is made up of twenty 16-bit XOR gates, data registers and key storage etc. Normally gate equivalent (GE) is the measure of area consumed which is equivalent to the area required by a NAND gate having two inputs. A 2:1 Multiplexer of 4 bits takes 0.5 gate equivalents of area and for 4-bit XOR operation it takes 7.075 GE area [46] as an example. The novel approach is designed by satisfying all possible necessary constraints.
6.2 Round swapping
The generated values of output from the F-Box of each stage like X1, X2 are sent to the next round inputs as Y2, Y1 respectively. The connections are done by simple wires as shown in Fig. 4 which are capable of transmitting 16 bits of data at a time.
7. Simulation, Synthesis and Implementation
The suggested lightweight cryptographic model is designed and written in Verilog and its rightness is verified in ModelSim 2020.1.1 by running the behavioral simulation taking one input as the 32-bit Plaintext another input as the 64 bits Key and getting 32-bit Ciphertext output as shown in the simulation window in Fig. 6.
As shown here in this figure eed4b55516 is taken as plaintext input and cdba38fb16 is the output with d622529ecc92d35316 as key. The plaintext represented here is ‘X’, the intermediate outputs are called ‘Yi’ and final output obtained after running ten rounds of algorithm is Y. After this the design is synthesized on (Virtex-7) XC7VX330T FPGA board on 28 nm process using Xilinx ISE 9.2i and Xilinx ISE 14.7 for verification of delay and area parameters. The proposed algorithm is proved to be extremely fast with a combinational path delay of 0.877ns and has a very low look up table (LUT) count as 32 only out of 20400 and consuming only 224 GE of area which is lesser than all previously reported algorithms. The area and resources consumed by the algorithm is directly proportional to the LUT count of the design. This design is made in such a way that it uses very minimal number of logical operations and gates to reduce the resources used to maximum extent. Only twenty 16-bit XOR gates are used in the entire design. The main confusion and diffusion for this algorithm depends on bit jumbling and scrambling. The number of rounds is also kept low to avoid unnecessary process delay as increase in the number of rounds only increase the critical path delay of the architecture. As the logic slices used here is significantly low so it can be told without any question that the power requirement should be dramatically low also. A power comparison is not given because different reported designs used different process technologies and it will not be justified to compare different algorithms implemented on different process technologies. A good Avalanche Effect is met after only ten rounds of operation so there stands no reason to increase the number of rounds for more security compromising the area, power and delay constraints.
Fig. 5 shows a comparison of LUT count and delay between the popular encryption algorithms introduced over the years. Table 2 and Table 3 shows the detailed test vectors taken to test the algorithm once by keeping key constant and once by keeping plaintext constant respectively. Five test cases are taken for each of different hamming distances (HD) and an average avalanche effect is shown.
Fig. 5. LUT count and delay comparison
Fig. 6. Simulation result in ModelSim 2020.1
Table 2. Test vectors taken keeping PT variable and Key constant with AE for each case
Table 3. Test vectors taken keeping Key variable and PT constant with AE for each case
8. Security analysis
Two different kinds of analyses are employed to evaluate the strength of security of the proposed algorithm namely: Attack analysis and Avalanche Effect analysis.
8.1 Avalanche effect
In cryptography avalanche effect plays a very important role when determining the degree of goodness of an encryption algorithm. It is the measure of the number of bits changed in a ciphertext if only one bit is changed in the plaintext or key. The greater the number of bits changed for very little change in plaintext or key the more secure that encryption technique is. Generally, if that change is 50% or half of the number of bits gets affected if only one bit is changed that avalanche effect is considered a good one [57]. The more that value of avalanche effect is tighter that security is. The following expression in Equation (1) expresses Avalanche effect.
\(\text { Avalanche Effect }(\mathrm{AE})=\frac{\text { Number of flipped bits in ciphertext }}{\text { Number of bits in plaintext }} \times 100 \% \) (1)
The study here on Avalanche effect is done by taking a fixed block of plaintext and by changing the hamming distance of the key randomly up to 5 bits in five different test cases. The same process of observation is done for variable plaintext and fixed key also. Fig. 7 displays a graphical interpretation of avalanche effect for different test cases for LCB keeping plaintext or key constant in each case and vice versa. Depending on this test a comparative analysis is done for LCB with previous state of art works which is shown in Fig. 8.
Fig. 7. Avalanche effect with respect to plaintext and key
Fig. 8. Comparison of Avalanche Effect of different Encryption Algorithms
It is found after in depth security analysis that the newly designed approach attains a decently high avalanche effect of 63.875 % with respect to plaintext and 63.125 % with respect to key which is much improved than any previously reported algorithms taken into consideration.
9. Attack analysis
The newly designed algorithm follows some simple but hard logical operating steps. The section below covers a clear explanation on how the proposed method is resistant to different types of cryptographic attacks. Some commonly used attacks are: Linear Attack, Differential Attack, Key related side channel attack, Impossible Differential Attack, Structural Attack, Algebraic Attack and Slide Attack.
9.1 Linear Attack
Known plaintext attack also known as Linear Attack is the type of cryptographic attack where the cryptanalyst knows some portion of the plaintext and ciphertext in which his main objective remains to find the key used to encrypt the data. In this type of attack the cryptanalyst tries to find a linear relation between plaintext and ciphertext using Equation (2) to find the possibility of the equation to be fulfilled [57][58].
\(x_{1} \oplus x_{2} \oplus \cdots \oplus x_{n} \oplus y_{1} \oplus y_{2} \oplus \cdots \oplus y_{n}=0\) (2)
where x1, x2...xn are the bit values of plaintext and y1, y2...yn are their corresponding bit values of ciphertext. The cipher is unsecured from this type of attack if the probability of satisfying Equation (2) is not equal to \(\frac{1}{2 n}\), where n is the number of bits in plaintext or ciphertext. The difference of probability with the value\(\frac{1}{2}\) is known as bias. The more the value of bias is closer to\(\frac{1}{2}\) the better the security is from linear attack. A linear probability analysis example for proposed S-Box taking five linear equations is shown in Table 4. From the table it is noted that for most linear expressions the value \(\frac{1}{2}\)is and the bias value is 0. Hence the proposed method of encryption is resistant to linear attacks or known plaintext attacks.
Table 4. Analysis of linear probability of S-Box of proposed algorithm
9.2 Differential Attack
Differential Attacks are also called chosen plaintext attacks as they stress mainly on high chance of occurrence of difference of output with respect to a given difference of input [58][57]. For an example, for the proposed S-Box X = [x1,x2,x3,......,xn] is the input and Y = [y1,y2,y3,......,yn] is the output. Difference between two different plaintexts is denoted by α = \(x_{1} \oplus x_{2}\) and difference between their ciphertext correspondingly is denoted by β = \(=y_{1} \oplus y_{2}\). A differential pair (α, β) is formed by a given difference of input α and its corresponding output difference β. For an α value, if the occurrence of β is large then the cipher is vulnerable to differential attacks. Commonly, it’s important to decrease the probability of difference pair to protect the cipher from chosen ciphertext attack or differential attack [56]. In this regard many different combinations of ‘α’ of 16 bits have been examined with different plaintexts of 16- bits for producing the corresponding β values. Accordingly, the difference pair (α, β) for this newly designed approach is noted. Highest differential probability noticed is \( \frac{9}{216}\) and most suitable differential probability obtained is \(\frac{2}{216}\) which is quite acceptable for all types of enciphering techniques. Therefore, the proposed algorithm can be said is secure from differential attacks.
9.3 Side channel Attack
This type of attack depends on data obtained when the encryption algorithm is realized [59]. This proposed algorithm can be said that it is side channel attack proof because the key used here is not dependent on the plaintext chosen and it uses random number for encryption process. The input and output dependency are negligible for this proposed algorithm. Again, the proposed technique provides security from other types of cryptanalyses. The two most weak parts in any cryptographic algorithm are the round functions and the key used as seen by an attacker. For this reason, the key generation technique and the round function design are to be done with sheer seriousness when designing any encryption scheme. Cryptanalysts try to recover the original key by closely observing the bit patterns of the output ciphertext when doing related key attacks. This can be possible only when a fixed key is being used in all the rounds of the algorithm [45][49]. The safety is maintained from this type of attack in this proposed method because it uses different subkeys in different rounds of operation. Thus, it can be said that this proposed method is well protected from side channel attacks as it becomes very hard for an intruder to determine the correct pattern of subkeys used in the proposed technique.
9.4 Impossible Differential Attack
One of the most used cryptanalytic techniques on lightweight block ciphers specifically fit for software platforms [60-65] is Impossible differential attack [66]. Because of the Feistel nature of the cipher structure the highest number of rounds on which impossible characteristics is seen is five [67] for which reason this kind of attack is not valid for this cipher as the number of rounds is ten.
9.5 Structural Attack
Like Bottleneck attack [68] and integral attack [69] structural attacks use word like structures in the encrypted text. The permutation used in LCB is bitwise which is the reason for its impermeability against structural attacks as word like structures cannot be derived in this case.
9.6 Algebraic Attack
LCB uses F-Box that is comprised of 4-bit S-Box, 8-bit P-Box and 16-bit L-Box. Although the 4-bit S-Boxes are attackable like in PRESENT [28] but the presence of 8-bit P-Box which can be described by eight algebraic equations of degree seven and 16-bit L-Box which is represented by sixteen algebraic equations with degree fifteen where the number of terms is far more than 8-bit S-Box used in HALKA [70]. The HALKA cipher is still more protective against algebraic attacks than PRESENT with number of terms ranging from 139 to 118 for its S-Box. This is not a system which uses small number of terms to describe itself. Therefore, a detailed analysis is not needed like PRESENT cipher to prove its security against algebraic attacks.
9.7 Slide Attack
Some limitations of key schedule are related-key [71] and Slide attacks [72]. The subkey generation mechanism of LCB is simple but because of the round function with high avalanche effect and strong non linearity it is very much frustrating to attack the cipher with this type of attack. The vulnerability of a cipher to slide attacks is when it uses similar structure and same subkey in the round functions, but since LCB makes use of dissimilar subkeys in each round it can be said to be resistant to slide attack.
10. Functional study
Some previously reported encryption algorithms are shown and compared with their performance measures and features in Table 5. Parameters like key length, block size, operational rounds, nature of the structure, process technology, frequency and Gate equivalent area are used to draw a fine comparison between previous state of art works and this proposed work. Most designed block cipher algorithms have 32 bit or 64-bit plaintext data having different key lengths with either Feistel or SPN like structure as shown in Table 5. QTL and LRBC are the only two which used mixed structure of Feistel and SPN.
Table 5. Functionality analysis of different Encryption Algorithms
After observation of the shown values, it can be said that the smaller the key and block size is the better and fast is the confusion and diffusion process giving better security. The novel contribution uses a mixed structure approach for exploiting both the benefits of SPN and Feistel structure like QTL and LRBC with ten consecutive rounds to build a more immune cipher. Additionally, the proposed system used 28 nm process technology in Virtex-7 FPGA board [73] which permitted a greater number of gates but occupying lesser area than others. Thus, LCB fulfilled every aspect of design constraint for achieving better performance than all others to become a worthy name for light-weight resource constrained device’s encryption system.
11. Conclusion
A novel light cipher block termed as LCB for resource restricted IoT devices is depicted and realized here in this work. The suggested work increases the security of data by combining the positive sides of both SPN and Feistel structure connected by the idea of linear box. LCB also produces a greater number of S-boxes which actively help to resist differential and linear attack. Use of 4-bit data for internal operation and enhanced design takes very less delay and area of the chip. The use of a smaller number of gates in the new design greatly improve the computational delay and security is maintained by bit jumbling and repeating. The proposed system promises security which is decently high with a reasonable time and area consumption after going through rigorous security checks.
Acknowledgement
Authors would like to acknowledge to the reviewers for their valuable feedback. This publication is an outcome of the R&D work undertaken project under the Ph.D. Scheme of Ministry of Human Resource and Development, Government of India, being implemented by Digital India Corporation.
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