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1. 发明授权

US10348704B2 Method for a dynamic perpetual encryption cryptosystem 有权
公开(公告)号：US10348704B2
公开(公告)日：2019-07-09
申请号：US15224492
申请日：2016-07-29
申请人： Helder Silvestre Paiva Figueira
发明人： Helder Silvestre Paiva Figueira
IPC分类号： H04L29/06
摘要： A dynamic computer communication security encryption method or system using an initial seed key and multiple random number generators of a specific design, whereby a sequence of independent random entropy values is produced by one set of random number generators and encrypted along with the message stream using the initial seed key, or the output of a second set of random number generators initialized with the initial seed key, and following the subsequent transmission of the variable encrypted entropy/message block, the entropy values are used to symmetrically or identically augment or increase the current uncertainty or entropy of the cryptosystem at both the sender and the receiver, prior to the next encryption block operation. The encryption process effectively entailing the use of multiple encryption ciphers, and the entropy augmentation process entailing the encryption or application of various logical mathematical operations on the already dynamic but deterministic internal state values of the second set of random number generators, effectively altering their deterministic outputs in a random probabilistic manner.Random length message value sequences from one or more data sources is combined with one or more random length entropy value sequences from an independent source, following which the entropy “updates” may also be used to alter, or change any cryptosystem variable, value or component in a randomly determined manner. In addition, while ensuring synchronization, the random entropy sequences also serve to “pollute” the cipher-stream and thereby hinder most current forms of cryptanalysis, while simultaneously injecting additional entropy into the cryptographic system and allowing for its propagation to affect any connected system nodes, and thereby introducing unpredictable entropy into the system pseudorandom number generator outputs, and thereby ensuring the perpetual generation of unpredictable random numbers.Super-encryption mechanics are independent of the user data, simple, fast and efficient, and can incorporate compression, error correction and asymmetric encryption authentication routines. But most importantly, super-encryption ensures resistance to brute force attacks (not possible to verify if a message was even sent), an ability to exceed “perfect secrecy” requirements, and an improvement on previous super-encipherment design, since overhead can be dramatically reduced from 100% overhead.Communication links previously established by system nodes with central authorities may be used for secure node authentication and registration, while allowing the central authority to broker and synchronize communication channels and providing mutual authentication and other security functions between the system nodes.

2. 发明申请

US20170034167A1 Method for a Dynamic Perpetual Encryption Cryptosystem 审中-公开
标题翻译：动态永久加密密码系统的方法
公开(公告)号：US20170034167A1
公开(公告)日：2017-02-02
申请号：US15224492
申请日：2016-07-29
申请人： Helder Silvestre Paiva Figueira
发明人： Helder Silvestre Paiva Figueira
IPC分类号： H04L29/06
CPC分类号： H04L63/061 , H04L63/0428
摘要： A dynamic computer communication security encryption method or system using an initial seed key and multiple random number generators of a specific design, whereby a sequence of independent random entropy values is produced by one set of random number generators and encrypted along with the message stream using the initial seed key, or the output of a second set of random number generators initialized with the initial seed key, and following the subsequent transmission of the variable encrypted entropy/message block, the entropy values are used to symmetrically or identically augment or increase the current uncertainty or entropy of the cryptosystem at both the sender and the receiver, prior to the next encryption block operation. The encryption process effectively entailing the use of multiple encryption ciphers, and the entropy augmentation process entailing the encryption or application of various logical mathematical operations on the already dynamic but deterministic internal state values of the second set of random number generators, effectively altering their deterministic outputs in a random probabilistic manner.Random length message value sequences from one or more data sources is combined with one or more random length entropy value sequences from an independent source, following which the entropy “updates” may also be used to alter, or change any cryptosystem variable, value or component in a randomly determined manner. In addition, whilst ensuring synchronization, the random entropy sequences also serve to “pollute” the cipher-stream and thereby hinder most current forms of cryptanalysis, whilst simultaneously injecting additional entropy into the cryptographic system and allowing for its propagation to affect any connected system nodes, and thereby introducing unpredictable entropy into the system pseudorandom number generator outputs, and thereby ensuring the perpetual generation of unpredictable random numbers.Super-encryption mechanics are independent of the user data, simple, fast and efficient, and can incorporate compression, error correction and asymmetric encryption authentication routines. But most importantly, super-encryption ensures resistance to brute force attacks (not possible to verify if a message was even sent), an ability to exceed “perfect secrecy” requirements, and an improvement on previous super-encipherment design, since overhead can be dramatically reduced from 100% overhead.Communication links previously established by system nodes with central authorities may be used for secure node authentication and registration, whilst allowing the central authority to broker and synchronize communication channels and providing mutual authentication and other security functions between the system nodes.
摘要翻译：先前由中央机构建立的系统节点的通信链路可用于安全节点认证和注册，同时允许中央管理机构在通信信道之间进行代理和同步，并在系统节点之间提供相互认证和其他安全功能。

3. 发明授权

US11233628B2 Equivocation augmentation dynamic secrecy system 有权
公开(公告)号：US11233628B2
公开(公告)日：2022-01-25
申请号：US16472423
申请日：2016-12-27
申请人： Helder Silvestre Paiva Figueira
发明人： Helder Silvestre Paiva Figueira
IPC分类号： H04L9/06 , H04L9/08 , H04L9/14 , H04L9/16
摘要： Shannon's equivocation, the conditional entropy of key or message with respect to a specific ciphertext, is the primary indicator of the security of any secrecy system, in that when key equivocation H E (K) or message equivocation H E (M) attain log 0 (or 1) under a brute-force attack, the system is compromised and has no security. We propose a simplistic equivocation definition of security which distinguishes between “secure/unsolvable” and “insecure/solvable” encipherments. Whilst equivocation may be used practically in a passive manner to cryptanalyse finite-length key “insecure/solvable” secrecy systems to determine the length of ciphertext required to compromise the secrecy system, the invention in this patent offers a cryptographic design framework which allows for the equivocation of finite-length key systems to be actively engineered using equivocation augmentation, such that the residual key and message equivocation of any cryptosystem may be continuously augmented at a faster rate than it is lost, effectively ensuring that equivocation can never attain log 0. In short, it allows for the encryption of any length of message with any finite length key into a ciphertext with “secure/unsolvable” security characteristics. Alternatively, it allows for the cryptographic engineering of information theoretic security in all finite length key systems. The invention is primarily aimed at solving two major problems: (a) a viable practical security solution against future quantum computing/artificial intelligence threats (the QC/AI problem), and (b) a viable practical security solution to the privacy/national interest dichotomy problem, in that it allows for the engineering of security systems which are capable of simultaneously supporting both the absolute privacy of individual users and the security interests of the user group at large. Various methods, apparatuses, and systems are described which allow for the implementation of a “secure/unsolvable” secrecy system which is fast, extensible, simple to implement in hardware and software, and able to be incorporated by or with any existing security solution or cryptographic primitives.

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