COMPARISON OF POST-QUANTUM STANDARDS IN TERMS OF IMPLEMENTATION IN CLASSICAL ELECTRONIC SIGNATURE ALGORITHMS
DOI:
https://doi.org/10.17721/ISTS.2024.7.31-38Keywords:
electronic signature, post-quantum cryptography, cryptoflexibility, post-quantum standardsAbstract
Background. The work examines the development and promotion of post-quantum standards, as well as the analysis and improvement of existing algorithms, on the basis of which the functioning of standards in the field of electronic digital signature can be based. One of the main reasons was also the migration of classical cryptography to post-quantum cryptography. The robot is aligning three popular post-quantum standards: CRYSTALS-Dilithium, Falcon and SPHINCS+. As a result of the investigation, the most optimal standards were selected before implementation of classical electronic signature schemes. The article is dedicated to the development and promotion of post-quantum standards in the field of electronic digital signature. It is also necessary to analyze and level up existing algorithms, on the basis of which the functioning of such standards can be based. The research is considered relevant due to the growing interest in quantum technologies and the need for secure electronic communications in the upcoming quantum world. Мethods. Мigrating classical cryptography to post-quantum cryptography. However, power is important, because the power of quantum computers can be affected by certain cryptographic algorithms. An analysis of the feasibility of transitioning to new standards and their existing security capabilities is also carried out. In addition, three popular post-quantum standards are being updated: CRYSTALS-Dilithium, Falcon and SPHINCS+. This allows us to determine the most optimal and reliable standard for implementation of classical electronic signature schemes. The authors of the work carry out the selection of the optimal standard, ensuring the safety and security of its authorities. Results. Сontains important results from the study of post-quantum standards for electronic digital signatures, which may be useful for developers of cryptographic software and information security engineers. The power supply to the influences and changes in the advanced post-quantum standards, such as the complexity of implementation, the flexibility of infrastructure and power standardization, are thoroughly examined. The prospects for the future development of post quantum cryptography and its influx into modern electronic signature systems have also been highlighted. This will help readers to take away the more common sense and context of the importance and potential contributions in this area. Conclusions. Falcon and CRYSTALS-Dilithium have a high signing fluidity and a larger key size, making them practical for rich stagnation. SPHINCS+, regardless of its viscosity, has less fluidity and requires a larger key size. The choice between CRYSTALS-Dilithium, Falcon and SPHINCS+ will depend on the specific drying needs, as well as compromises between fluidity, key size and viscosity. This demonstrates the high speed of subscription, and this is one of its key advantages. It is intended for use in quick operations, for example, on servers and industrial systems.Downloads
References
Горбенко Ю., & Ганзя, Р. (2014). Аналіз шляхів розвитку криптографії після появи квантових комп'ютерів. CSN, 806. http://science.lpnu.ua/uk/csn/vsi-vypusky/nomer-806-2014/analiz-shlyahiv-rozvytku-kryptografiyi-pislya-poyavy-kvantovyh.
Горбенко, І., Качко, О., Єсіна, М., & Пономар, В. (2018). Методи, методика та результати порівняльного аналізу кандидатів на постквантовий стандарт електронного підпису. ХХ Ювілейна міжнародна науково-практична конференція "Безпека інформації в інформаційно-телекомунікаційних системах" (с. 96–97). м. Буча (Київська область), ГНЦ "Зелена Буча".
Горбенко, І., Кузнецов, О., Потій, О., Горбенко, Ю., Ганзя, Р., & Пономар, В. (2017). Модель зрілості можливостей системи кібербезпеки на об'єктах критичної інфраструктури енергетичного сектору ES-C2M2. Кібербезпека: освіта, наука, техніка, 2(10), 32–52.
Ducas, L., Lepoint, T., & Lyubachevsky, V. (2024). Crystals – Dilithium: Digital Signatures from Module Lattices. TCHES 2024. https://cryptojedi.org/papers/dilithium-20170617.pdf.
