This invention relates generally to distributed ledger technology (including blockchain related technologies), particularly a method and corresponding system for providing a blockchain transaction comprising a redeem script for an output that comprises: i) a plurality of public keys, each associated with a corresponding private key, wherein each public key is uniquely associated with a potential state of at least one data source; and ii) logic arranged to provide a result based on: A) a determination of which of the plurality of associated private key(s) is/are used to sign the unlocking script, so as to provide an interim result: and B) a comparison of a parameter supplied via the unlocking script against the interim result, and further attempting to spend the transaction output more than once, each attempt supplying a different parameter.

Various embodiments are generally directed to improving card security by providing a user a contactless card with no sensitive card information, such as card number, card verification value, and expiration date, printed thereon, and displaying the sensitive card information relative to the card in augmented reality (AR) based on successful NFC-based user authentication. According to examples, the NFC-based user authentication may be performed by one-tapping or single tapping the contactless card to user mobile device. One or more portions of the sensitive card information may be obfuscated to further enhance card security. Moreover, the user can interact with AR elements including the sensitive card information to perform various actions.

A method for offline transmission of blockchain details includes: storing, in a computing device, a first private key and a currency amount; receiving a first destination address associated with a blockchain network and a transaction amount; generating a second private key; generating a second destination address associated with the blockchain network using the second private key; generating a blockchain transaction including at least the first destination address, the transaction amount, the second destination address, and a remainder amount based on at least the currency amount and the transaction amount; signing the generated blockchain transaction using the first private key; executing a query to replace the first private key with the second private key, wherein replacement of the first private key includes deletion of the first private key from the computing device; and transmitting the generated blockchain transaction.

A system uses a keyboard application to encrypt and decrypt e-mail, messages, and other digital data. By using quantum random number generators, the system has improved data security. Using a quantum random number, an agent (at a sender side) generates an encryption key which is used to automatically encrypt a message. The encryption key is stored at a key server. The encrypted message will be sent by an application using its standard transmission means such as SMTP, SMS, and others. The encrypted message can be automatically unencrypted by using an agent (at a recipient side) and retrieving the key from the key server. The system also provides an optional double encryption, where the message is encrypted with a user-generated password before being encrypted using the encryption key.

A storage system and method for command execution ordering by security key are provided. In one example, the storage system has a non-volatile memory, a volatile memory storing a plurality of keys, and a controller with a cache storing a subset of the plurality of keys. The storage system gives priority to a command whose key is stored in the cache in the controller over commands whose keys are stored only in the volatile memory. This avoids transferring a key from the volatile memory to the cache in the controller, thereby improving efficiency of the storage system.

Methods, apparatus and computer program product for protecting a confidential integrated circuit design process. The computer-implemented method includes receiving a design specification dataset from a first untrusted computing device; extracting confidential design specification data from the design specification dataset; encrypting the confidential design specification data to produce encrypted confidential design specification data; generate a first encryption key to be associated with the encrypted confidential design specification data; retrieving a confidential design specification data subset for replacing a design element subset with a security hard macro (SHM) placeholder design element set; generating a security hard macro (SHM) placeholder feature set comprising those security hard macro (SHM) placeholder features representing mappings from the confidential design specification data subset to the SHM placeholder design element set; and transmitting, to the first untrusted computing device, the encrypted confidential design specification data, the first encryption key, and the SHM placeholder feature set.

Techniques for encrypting data using a key generated by a physical unclonable function (PUF) are described. An apparatus according to the present disclosure may include decoder circuitry to decode an instruction and generate a decoded instruction. The decoded instruction includes operands and an opcode. The opcode indicates that execution circuitry is to encrypt data using a key generated by a PUF. The apparatus may further include execution circuitry to execute the decoded instruction according to the opcode to encrypt the data to generate encrypted data using the key generated by the PUF.

A data processing method includes: determining, in response to a request of an access terminal for writing target data to a blockchain, a target node role with a read permission for the target data, an access terminal connected with each node device having a permission of a node role corresponding to the node device; acquiring an encryption key corresponding to the target node role; performing encryption processing on the target data according to the encryption key to obtain a cipher text corresponding to the target data, the cipher text corresponding to the target data being decryptable for an access terminal corresponding to the target node role; and storing the cipher text corresponding to the target data to the blockchain.

Aspects of the subject disclosure may include, for example, a non-transitory, machine-readable medium, comprising executable instructions that, when executed by a processing system including a processor, facilitate performance of operations including receiving a call; selecting a next carrier to handoff the call; generating a call data record (CDR) for the handoff to the next carrier; encrypting the CDR using a call encryption key, thereby creating an encrypted CDR; encrypting the encrypted CDR using a committee encryption key, thereby creating a double encrypted CDR; recording the double encrypted CDR to a blockchain; and sending the call encryption key to the next carrier. Other embodiments are disclosed.

One-to-many cryptographic systems and methods are disclosed, and a network employing the same, including numerous industry applications. The embodiments of the present invention can generate and regenerate the same symmetric key from a random token. The one-to-many cryptographic systems and methods include a central location and a cryptographic module being in communication with each other. The cryptographic module is configured to encrypt and/or decrypt data received a remote location and output encrypted and/or decrypted data. The cryptographic module includes a key generator configured to use two or more inputs to reproducibly generate the symmetric key and a cryptographic engine configured to use the symmetric key for encrypting and decrypting data. Corresponding methods, and network employing the same, are also provided.