{"id":478482,"date":"2023-08-09T09:33:31","date_gmt":"2023-08-09T09:33:31","guid":{"rendered":""},"modified":"2023-09-05T11:16:50","modified_gmt":"2023-09-05T11:16:50","slug":"post-quantum-cryptography","status":"publish","type":"wiki","link":"https:\/\/oneproxy.pro\/tr\/wiki\/post-quantum-cryptography\/","title":{"rendered":"Kuantum sonras\u0131 kriptografi"},"content":{"rendered":"<p>Kuantum sonras\u0131 kriptografi, benzersiz hesaplama g\u00fcc\u00fc vaat eden ve geleneksel kriptografik \u015femalar\u0131 k\u0131rma potansiyeline sahip yeni bir makine t\u00fcr\u00fc olan kuantum bilgisayarlardan gelen sald\u0131r\u0131lara dayanacak \u015fekilde tasarlanm\u0131\u015f geli\u015fmi\u015f bir kriptografik yakla\u015f\u0131md\u0131r. Kuantum bilgisayarlar\u0131 geli\u015fmeye devam ettik\u00e7e, kuantum tabanl\u0131 sald\u0131r\u0131lara kar\u015f\u0131 koyabilecek g\u00fcvenli \u015fifreleme y\u00f6ntemlerine duyulan ihtiya\u00e7 giderek daha kritik hale geliyor. Kuantum sonras\u0131 kriptografi, kuantum sonras\u0131 hesaplama \u00e7a\u011f\u0131nda hassas bilgi ve ileti\u015fim kanallar\u0131n\u0131 korumay\u0131 ama\u00e7lamaktad\u0131r.<\/p>\n<h2>Kuantum sonras\u0131 kriptografinin k\u00f6keninin tarihi ve ilk s\u00f6z\u00fc<\/h2>\n<p>Kuantum sonras\u0131 kriptografi kavram\u0131n\u0131n k\u00f6kleri, Peter Shor ve Lov Grover&#039;\u0131n ba\u011f\u0131ms\u0131z olarak, b\u00fcy\u00fck tamsay\u0131lar\u0131 \u00e7arpanlara ay\u0131rma ve pek \u00e7ok genel anahtarl\u0131 kriptografide merkezi olan s\u0131ralanmam\u0131\u015f veritabanlar\u0131n\u0131 arama dahil olmak \u00fczere belirli sorunlar\u0131 etkili bir \u015fekilde \u00e7\u00f6zebilecek kuantum algoritmalar\u0131n\u0131 ke\u015ffetti\u011fi 1990&#039;lar\u0131n ba\u015flar\u0131na kadar uzan\u0131r. sistemler. 1994 y\u0131l\u0131nda matematik\u00e7i Daniel Bernstein, kuantum sald\u0131r\u0131lar\u0131na direnebilecek kriptografik algoritmalar\u0131n ara\u015ft\u0131r\u0131lmas\u0131n\u0131 ba\u015flatt\u0131 ve bu, kuantum sonras\u0131 kriptografi ara\u015ft\u0131rmalar\u0131n\u0131n ba\u015flang\u0131c\u0131 oldu.<\/p>\n<h2>Kuantum sonras\u0131 kriptografi hakk\u0131nda detayl\u0131 bilgi<\/h2>\n<p>Kuantum sonras\u0131 kriptografi, kuantum d\u00fc\u015fmanlar\u0131na kar\u015f\u0131 g\u00fcvenli olacak \u015fekilde tasarlanm\u0131\u015f bir kriptografik algoritma ailesini ifade eder. B\u00fcy\u00fck say\u0131lar\u0131 \u00e7arpanlara ay\u0131rma ve ayr\u0131k logaritmalar gibi zor matematik problemlerine dayanan klasik \u015fifreleme algoritmalar\u0131n\u0131n aksine, kuantum sonras\u0131 \u015fifreleme \u015femalar\u0131 alternatif matematiksel ilkelere dayanmaktad\u0131r. Bu ilkeler genellikle kafes tabanl\u0131 kriptografiyi, kod tabanl\u0131 kriptografiyi, karma tabanl\u0131 kriptografiyi, \u00e7ok de\u011fi\u015fkenli polinom sistemlerini ve y\u00fcksek karma\u015f\u0131kl\u0131\u011fa ve kuantum sald\u0131r\u0131lar\u0131na kar\u015f\u0131 do\u011fal dirence sahip di\u011fer matematiksel yap\u0131lar\u0131 i\u00e7erir.<\/p>\n<h2>Kuantum sonras\u0131 kriptografinin i\u00e7 yap\u0131s\u0131 ve nas\u0131l \u00e7al\u0131\u015ft\u0131\u011f\u0131<\/h2>\n<p>Kuantum sonras\u0131 \u015fifreleme algoritmalar\u0131, kuantum bilgisayarlar i\u00e7in bile \u00e7\u00f6z\u00fclmesi zor olan matematiksel yap\u0131lar\u0131 kullan\u0131r. \u00d6rne\u011fin kafes tabanl\u0131 kriptografi, bir kafesteki en k\u0131sa vekt\u00f6r\u00fc bulman\u0131n karma\u015f\u0131kl\u0131\u011f\u0131na dayan\u0131r; bunun hem klasik hem de kuantum bilgisayarlar i\u00e7in hesaplama a\u00e7\u0131s\u0131ndan olanaks\u0131z oldu\u011funa inan\u0131l\u0131r. Benzer \u015fekilde kod tabanl\u0131 kriptografi, belirli hata d\u00fczeltme kodlar\u0131n\u0131n kodunun \u00e7\u00f6z\u00fclmesinin zorlu\u011funa dayan\u0131r ve bu da kuantum algoritmalar\u0131 i\u00e7in bir zorluk te\u015fkil eder.<\/p>\n<p>Veri g\u00fcvenli\u011fini sa\u011flamak i\u00e7in kuantum sonras\u0131 \u015fifreleme sistemleri, bu karma\u015f\u0131k matematiksel yap\u0131lardan yararlanan \u015fifreleme ve \u015fifre \u00e7\u00f6zme algoritmalar\u0131n\u0131 birle\u015ftirir. Verileri \u015fifrelerken, kuantum sonras\u0131 \u015fifreleme algoritmas\u0131, d\u00fcz metni \u015fifreli metne \u00f6yle bir d\u00f6n\u00fc\u015ft\u00fcr\u00fcr ki, ister klasik ister kuantum olsun, bir sald\u0131rgan\u0131n uygun \u015fifre \u00e7\u00f6zme anahtar\u0131 olmadan s\u00fcreci tersine \u00e7evirmesi son derece zor hale gelir.<\/p>\n<h2>Kuantum sonras\u0131 kriptografinin temel \u00f6zelliklerinin analizi<\/h2>\n<p>Kuantum sonras\u0131 kriptografi, onu gelecekteki veri g\u00fcvenli\u011fi i\u00e7in umut verici bir se\u00e7im haline getiren \u00e7e\u015fitli temel \u00f6zellikler sunar:<\/p>\n<ol>\n<li>\n<p><strong>Kuantum Direnci:<\/strong> Kuantum sonras\u0131 kriptografinin birincil avantaj\u0131 kuantum bilgisayarlardan gelen sald\u0131r\u0131lara kar\u015f\u0131 direncidir. Kuantum algoritmalar\u0131, klasik bilgisayarlar\u0131n u\u011fra\u015ft\u0131\u011f\u0131 sorunlar\u0131 verimli bir \u015fekilde \u00e7\u00f6zebildi\u011finden, geleneksel \u015fifreleme \u015femalar\u0131 savunmas\u0131z hale gelebilir. Kuantum sonras\u0131 kriptografik algoritmalar ise bu kuantum tabanl\u0131 sald\u0131r\u0131lara kar\u015f\u0131 g\u00fc\u00e7l\u00fc bir savunma sa\u011flar.<\/p>\n<\/li>\n<li>\n<p><strong>Uyumluluk:<\/strong> Kuantum sonras\u0131 kriptografi yeni algoritmalar sunarken, mevcut kriptografik sistemlerle bir arada var olacak \u015fekilde tasarlanm\u0131\u015ft\u0131r. Bu uyumluluk, mevcut g\u00fcvenlik standartlar\u0131ndan \u00f6d\u00fcn vermeden kuantum diren\u00e7li \u015fifreleme y\u00f6ntemlerine sorunsuz bir ge\u00e7i\u015f sa\u011flar.<\/p>\n<\/li>\n<li>\n<p><strong>Uzun Vadeli G\u00fcvenlik:<\/strong> Kuantum sonras\u0131 \u015fifreleme algoritmalar\u0131, kuantum hesaplama teknolojisi geli\u015firken bile g\u00fcvenli\u011fi korumay\u0131 ama\u00e7lamaktad\u0131r. Kuantum algoritmalar\u0131nda gelecekteki potansiyel geli\u015fmelere kar\u015f\u0131 uzun vadeli koruma sa\u011flarlar.<\/p>\n<\/li>\n<li>\n<p><strong>A\u00e7\u0131k Anahtarl\u0131 Kriptografi:<\/strong> Kuantum sonras\u0131 \u015fifreleme \u015femalar\u0131n\u0131n \u00e7o\u011fu, \u00e7e\u015fitli uygulamalarda g\u00fcvenli veri iletimi ve kimlik do\u011frulama i\u00e7in yayg\u0131n olarak kullan\u0131lan genel anahtar \u015fifrelemesini geli\u015ftirmeye odaklan\u0131r.<\/p>\n<\/li>\n<li>\n<p><strong>\u00c7e\u015fitli Matematiksel Temeller:<\/strong> Kuantum sonras\u0131 kriptografi, \u00e7e\u015fitli matematiksel temellerden yararlanarak farkl\u0131 gereksinimlere uyacak \u00e7ok \u00e7e\u015fitli g\u00fcvenlik se\u00e7enekleri sa\u011flar.<\/p>\n<\/li>\n<\/ol>\n<h2>Kuantum sonras\u0131 kriptografi t\u00fcrleri<\/h2>\n<p>Kuantum sonras\u0131 kriptografi, her biri kuantum direnci i\u00e7in farkl\u0131 matematiksel yap\u0131lara dayanan \u00e7e\u015fitli algoritma t\u00fcrlerini kapsar. Ba\u015fl\u0131ca t\u00fcrleri \u015funlar\u0131 i\u00e7erir:<\/p>\n<table>\n<thead>\n<tr>\n<th>Tip<\/th>\n<th>\u00d6rnek Algoritmalar<\/th>\n<\/tr>\n<\/thead>\n<tbody>\n<tr>\n<td>Kafes tabanl\u0131<\/td>\n<td>NTRU, Kyber, NewHope<\/td>\n<\/tr>\n<tr>\n<td>Kod tabanl\u0131<\/td>\n<td>McEliece, RQC<\/td>\n<\/tr>\n<tr>\n<td>Hash tabanl\u0131<\/td>\n<td>XMSS, SP\u0130NKS<\/td>\n<\/tr>\n<tr>\n<td>\u00c7ok De\u011fi\u015fkenli Polinom<\/td>\n<td>G\u00f6kku\u015fa\u011f\u0131, Dengesiz Ya\u011f ve Sirke (UOV)<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<p>Her t\u00fcr benzersiz g\u00fc\u00e7l\u00fc ve zay\u0131f y\u00f6nler sunar ve bunlar\u0131n uygunlu\u011fu, belirli kullan\u0131m senaryolar\u0131na ve g\u00fcvenlik gereksinimlerine ba\u011fl\u0131d\u0131r.<\/p>\n<h2>Kuantum sonras\u0131 kriptografiyi kullanma yollar\u0131, kullan\u0131mla ilgili sorunlar ve \u00e7\u00f6z\u00fcmleri<\/h2>\n<p>Kuantum sonras\u0131 kriptografi, veri g\u00fcvenli\u011fini sa\u011flamak i\u00e7in \u00e7e\u015fitli uygulama ve senaryolarda kullan\u0131labilir. Baz\u0131 yayg\u0131n kullan\u0131m durumlar\u0131 \u015funlar\u0131 i\u00e7erir:<\/p>\n<ol>\n<li>\n<p><strong>G\u00fcvenli \u0130leti\u015fim:<\/strong> Kuantum sonras\u0131 kriptografik algoritmalar, sunucular ve istemciler aras\u0131ndaki veri iletimini g\u00fcvence alt\u0131na almak ve hassas bilgileri aktar\u0131m s\u0131ras\u0131nda kuantum sald\u0131r\u0131lar\u0131ndan korumak i\u00e7in ileti\u015fim protokollerine (\u00f6rne\u011fin, TLS) entegre edilebilir.<\/p>\n<\/li>\n<li>\n<p><strong>Dijital imzalar:<\/strong> Kuantum sonras\u0131 imza \u015femalar\u0131, dijital belgelerin ger\u00e7ekli\u011fini ve b\u00fct\u00fcnl\u00fc\u011f\u00fcn\u00fc do\u011frulamak ve bunlar\u0131n tahrif edilmedi\u011finden veya sahtecilik yap\u0131lmad\u0131\u011f\u0131ndan emin olmak i\u00e7in kullan\u0131labilir.<\/p>\n<\/li>\n<li>\n<p><strong>Anahtar De\u011fi\u015fimi:<\/strong> Kuantuma dayan\u0131kl\u0131 anahtar de\u011fi\u015fim algoritmalar\u0131, bir ileti\u015fim oturumunda taraflar aras\u0131nda payla\u015f\u0131lan \u015fifreleme anahtarlar\u0131n\u0131n g\u00fcvenli bir \u015fekilde olu\u015fturulmas\u0131n\u0131 kolayla\u015ft\u0131r\u0131r.<\/p>\n<\/li>\n<\/ol>\n<p>Ancak kuantum sonras\u0131 kriptografinin benimsenmesi baz\u0131 zorluklar\u0131 da beraberinde getiriyor:<\/p>\n<ul>\n<li>\n<p><strong>Verim:<\/strong> Kuantum sonras\u0131 kriptografik algoritmalar, klasik muadillerine g\u00f6re hesaplama a\u00e7\u0131s\u0131ndan daha yo\u011fun olabilir ve bu da kaynak k\u0131s\u0131tl\u0131 cihazlarda potansiyel performans sorunlar\u0131na yol a\u00e7abilir.<\/p>\n<\/li>\n<li>\n<p><strong>Standardizasyon ve Birlikte \u00c7al\u0131\u015fabilirlik:<\/strong> Pek \u00e7ok kuantum sonras\u0131 algoritma geli\u015ftirilmekte oldu\u011fundan, standardizasyonun sa\u011flanmas\u0131 ve farkl\u0131 sistemler aras\u0131nda birlikte \u00e7al\u0131\u015fabilirli\u011fin sa\u011flanmas\u0131, yayg\u0131n olarak benimsenme a\u00e7\u0131s\u0131ndan kritik hale gelmektedir.<\/p>\n<\/li>\n<li>\n<p><strong>Ge\u00e7i\u015f ve Anahtar Y\u00f6netimi:<\/strong> Klasikten kuantum sonras\u0131 kriptografiye ge\u00e7i\u015f, ge\u00e7i\u015f s\u00fcreci s\u0131ras\u0131nda g\u00fcvenli\u011fi korumak i\u00e7in dikkatli planlama ve anahtar y\u00f6netiminin dikkate al\u0131nmas\u0131n\u0131 gerektirir.<\/p>\n<\/li>\n<\/ul>\n<h2>Ana \u00f6zellikler ve benzer terimlerle di\u011fer kar\u015f\u0131la\u015ft\u0131rmalar<\/h2>\n<p>Kuantum sonras\u0131 kriptografiyi ve ilgili terimlerden farklar\u0131n\u0131 daha iyi anlamak i\u00e7in a\u015fa\u011f\u0131daki kar\u015f\u0131la\u015ft\u0131rmalar\u0131 g\u00f6z \u00f6n\u00fcnde bulundurun:<\/p>\n<ol>\n<li>\n<p><strong>Kuantum Kriptografi ve Kuantum Sonras\u0131 Kriptografi:<\/strong> Genellikle kuantum anahtar da\u011f\u0131t\u0131m\u0131 (QKD) olarak adland\u0131r\u0131lan kuantum kriptografisi, kuantum ilkelerini kullanarak g\u00fcvenli ileti\u015fime odaklanan bir ara\u015ft\u0131rma alan\u0131d\u0131r. Kuantum kriptografisi, anahtar de\u011fi\u015fimi i\u00e7in ko\u015fulsuz g\u00fcvenlik sa\u011flarken, do\u011fas\u0131 gere\u011fi kuantum sonras\u0131 g\u00fcvenlik endi\u015felerini gidermez. \u00d6te yandan kuantum sonras\u0131 kriptografi, kuantum sald\u0131r\u0131lar\u0131na direnmek i\u00e7in \u00f6zel olarak tasarlanm\u0131\u015ft\u0131r.<\/p>\n<\/li>\n<li>\n<p><strong>Simetrik ve Asimetrik Kriptografi:<\/strong> Simetrik kriptografi, hem \u015fifreleme hem de \u015fifre \u00e7\u00f6zme i\u00e7in ayn\u0131 anahtar\u0131 kullan\u0131r, bu da onu verimli k\u0131lar ancak g\u00fcvenli anahtar da\u011f\u0131t\u0131m\u0131 gerektirir. A\u00e7\u0131k anahtarl\u0131 \u015fifreleme olarak da bilinen asimetrik \u015fifreleme, \u015fifreleme ve \u015fifre \u00e7\u00f6zme i\u00e7in farkl\u0131 anahtarlar kullanarak geli\u015fmi\u015f g\u00fcvenlik sa\u011flar. Kuantum sonras\u0131 kriptografi esas olarak kuantum diren\u00e7li asimetrik kriptografik \u015femalarla ilgilidir.<\/p>\n<\/li>\n<\/ol>\n<h2>Kuantum sonras\u0131 kriptografiyle ilgili gelece\u011fin perspektifleri ve teknolojileri<\/h2>\n<p>Kuantum hesaplama teknolojisi ilerledik\u00e7e kuantum sonras\u0131 kriptografinin benimsenmesinin de artmas\u0131 bekleniyor. Devam eden ara\u015ft\u0131rma ve geli\u015ftirme, mevcut algoritmalar\u0131 iyile\u015ftirmeyi ve kuantum diren\u00e7li sa\u011flam g\u00fcvenlik sa\u011flamak i\u00e7in yeni yakla\u015f\u0131mlar ke\u015ffetmeyi ama\u00e7lamaktad\u0131r. NIST gibi standardizasyon kurumlar\u0131, kuantum sonras\u0131 kriptografik algoritmalar\u0131 aktif olarak de\u011ferlendiriyor ve onayl\u0131yor; bu algoritmalar, bunlar\u0131n \u00e7e\u015fitli sistemlere entegrasyonunu sa\u011flayacak.<\/p>\n<h2>Proxy sunucular\u0131 kuantum sonras\u0131 \u015fifrelemeyle nas\u0131l kullan\u0131labilir veya ili\u015fkilendirilebilir?<\/h2>\n<p>Proxy sunucular\u0131 internet trafi\u011finin g\u00fcvenli\u011finin sa\u011flanmas\u0131nda ve anonimle\u015ftirilmesinde \u00e7ok \u00f6nemli bir rol oynar. Kuantum sonras\u0131 \u015fifrelemeyle birlikte kullan\u0131ld\u0131\u011f\u0131nda proxy sunucular, kuantum diren\u00e7li algoritmalar kullanarak verileri \u015fifreleyerek ve \u015fifrelerini \u00e7\u00f6zerek ekstra bir g\u00fcvenlik katman\u0131 ekleyebilir. Bu geli\u015fmi\u015f g\u00fcvenlik, kullan\u0131c\u0131lar ve proxy sunucular aras\u0131ndaki ileti\u015fim kanallar\u0131n\u0131n potansiyel kuantum rakiplerinin varl\u0131\u011f\u0131nda bile korunmas\u0131n\u0131 sa\u011flar.<\/p>\n<h2>\u0130lgili Ba\u011flant\u0131lar<\/h2>\n<p>Kuantum sonras\u0131 kriptografi hakk\u0131nda daha fazla bilgi i\u00e7in a\u015fa\u011f\u0131daki kaynaklara ba\u015fvurabilirsiniz:<\/p>\n<ul>\n<li><a href=\"https:\/\/csrc.nist.gov\/Projects\/Post-Quantum-Cryptography\" target=\"_new\" rel=\"noopener nofollow\">NIST Kuantum Sonras\u0131 Kriptografi Standardizasyonu<\/a><\/li>\n<li><a href=\"https:\/\/en.wikipedia.org\/wiki\/Post-quantum_cryptography\" target=\"_new\" rel=\"noopener nofollow\">Wikipedia&#039;da Kuantum Sonras\u0131 Kriptografi<\/a><\/li>\n<li><a href=\"https:\/\/pqcrypto.org\/\" target=\"_new\" rel=\"noopener nofollow\">Kuantum Sonras\u0131 D\u00fcnya Konferans\u0131<\/a><\/li>\n<\/ul>\n<p>Kuantum sonras\u0131 kriptografi alan\u0131 geli\u015fmeye devam ederken, en son geli\u015fmeler ve en iyi uygulamalar hakk\u0131nda bilgi sahibi olmak, kuantum odakl\u0131 bir gelecekte veri g\u00fcvenli\u011fini sa\u011flamak i\u00e7in hayati \u00f6nem ta\u015f\u0131yor.<\/p>","protected":false},"featured_media":478483,"menu_order":0,"template":"","meta":{"_acf_changed":false,"content-type":"","inline_featured_image":false,"footnotes":""},"class_list":["post-478482","wiki","type-wiki","status-publish","has-post-thumbnail","hentry"],"acf":{"faq_title":"Frequently Asked Questions about <mark>Post-Quantum Cryptography: Safeguarding the Future of Data Security<\/mark>","faq_items":[{"question":"What is Post-quantum cryptography?","answer":"<p>Post-quantum cryptography is an advanced cryptographic approach designed to protect sensitive information and communication channels from attacks by quantum computers. Unlike traditional cryptographic schemes, post-quantum cryptography utilizes mathematical structures that remain secure even in the presence of powerful quantum algorithms.<\/p>"},{"question":"When did the concept of Post-quantum cryptography originate?","answer":"<p>The concept of post-quantum cryptography emerged in the early 1990s when researchers discovered quantum algorithms that could efficiently solve certain cryptographic problems. Mathematician Daniel Bernstein initiated the exploration of cryptographic algorithms that could resist quantum attacks, leading to the development of post-quantum cryptography.<\/p>"},{"question":"How does Post-quantum cryptography work?","answer":"<p>Post-quantum cryptographic algorithms leverage complex mathematical structures, such as lattice-based cryptography and code-based cryptography, to achieve data security. These algorithms transform plaintext into ciphertext in a way that is extremely difficult for attackers, both classical and quantum, to reverse without the proper decryption key.<\/p>"},{"question":"What are the key features of Post-quantum cryptography?","answer":"<p>Post-quantum cryptography offers several key features, including quantum resistance, compatibility with existing cryptographic systems, long-term security, enhanced public-key cryptography, and a diverse range of mathematical foundations for different security requirements.<\/p>"},{"question":"What types of Post-quantum cryptography exist?","answer":"<p>Post-quantum cryptography includes various types of algorithms, such as lattice-based (e.g., NTRU, Kyber), code-based (e.g., McEliece, RQC), hash-based (e.g., XMSS, SPHINCS), and multivariate polynomial (e.g., Rainbow, UOV) cryptographic schemes. Each type has distinct strengths and applications.<\/p>"},{"question":"How can Post-quantum cryptography be used?","answer":"<p>Post-quantum cryptography can be used to secure communication channels, provide digital signatures for document authentication, and facilitate secure key exchange between parties. It ensures data security in the face of quantum attacks.<\/p>"},{"question":"What challenges are associated with using Post-quantum cryptography?","answer":"<p>The adoption of post-quantum cryptography may present challenges such as potential performance issues, standardization, and key management during migration from classical to post-quantum cryptographic systems.<\/p>"},{"question":"How does Post-quantum cryptography compare to Quantum Cryptography?","answer":"<p>Quantum cryptography, also known as quantum key distribution (QKD), focuses on secure communication using quantum principles. While quantum cryptography provides unconditional security for key exchange, post-quantum cryptography is designed to resist quantum attacks.<\/p>"},{"question":"What is the future of Post-quantum cryptography?","answer":"<p>As quantum computing technology advances, the adoption of post-quantum cryptography is expected to grow. Ongoing research and development aim to refine existing algorithms and explore new approaches to ensure robust quantum-resistant security.<\/p>"},{"question":"How can proxy servers be associated with Post-quantum cryptography?","answer":"<p>Proxy servers can work alongside post-quantum cryptography to enhance online security. By encrypting and decrypting data using quantum-resistant algorithms, proxy servers add an extra layer of protection to communication channels, safeguarding sensitive information from potential quantum adversaries.<\/p>"}]},"_links":{"self":[{"href":"https:\/\/oneproxy.pro\/tr\/wp-json\/wp\/v2\/wiki\/478482","targetHints":{"allow":["GET"]}}],"collection":[{"href":"https:\/\/oneproxy.pro\/tr\/wp-json\/wp\/v2\/wiki"}],"about":[{"href":"https:\/\/oneproxy.pro\/tr\/wp-json\/wp\/v2\/types\/wiki"}],"version-history":[{"count":0,"href":"https:\/\/oneproxy.pro\/tr\/wp-json\/wp\/v2\/wiki\/478482\/revisions"}],"wp:featuredmedia":[{"embeddable":true,"href":"https:\/\/oneproxy.pro\/tr\/wp-json\/wp\/v2\/media\/478483"}],"wp:attachment":[{"href":"https:\/\/oneproxy.pro\/tr\/wp-json\/wp\/v2\/media?parent=478482"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}