A method for collecting data from a group of entitled members. The method may include receiving, by a collection unit, a message and a message signature; validating, by the collection unit, whether the message was received from any of the entitled members of the group, without identifying the entitled member that sent the message; wherein the validating comprises applying a second plurality of mathematical operations on a first group of secrets, a second group of secrets, and a first part of the message signature; and rejecting, by the collection unit, the message when validating that the message was not received from any entitled member of the group.

In one embodiment, a tunnel to be affected by configuration of a service in a network is identified and key information for the identified tunnel is obtained from a corresponding router. The tunnel is assigned to a key group based on the key information, and provisioning information associated with the tunnel on the router is updated based on the assigned key group in conjunction with configuration of the service. The updating of the provisioning information may comprise altering the key information on the router to include a key associated with the assigned key group. Also, one or more keys not associated with the assigned key group may be deleted from the router and from a management entity of the network.

Methods, systems, and apparatus, including medium-encoded computer program products, for secure storage and retrieval of information, such as private keys, useable to control access to a blockchain, include, in at least one aspect, a method including: identifying for an action an associated private-keys group out of different private-keys groups, each having an associated cryptographic group key; decrypting, at a first computer, a first level of encryption of a private key associated with the action using the associated cryptographic group key; decrypting, at a second computer distinct from the first computer, a second level of encryption of the private key associated with the action using a hardware-based cryptographic key used by the second computer; using, at the second computer, the private key associated with the action in a process of digitally signing data to authorize the action; and sending the digitally signed data to a third computer to effect the action.

Methods, systems, and devices for virtualized authentication device are described. A virtual device (such as a virtual machine) may be permitted to access secured data within a memory device by an authentication process. The memory device may generate cryptographic keys in portions of the memory device and assign the cryptographic keys to the virtual machines. The virtual machine may use an authentication process using the cryptographic keys to access the secure data in the memory device. The authentication process may include authenticating the identity of the virtual machine and the code operating on the virtual machine based upon comparing cryptographic keys received from the virtual machines to the assigned cryptographic keys in the partitions of the memory device. Once both the identity of the virtual machine is authenticated, the virtual machine may be permitted to access the secure data in the memory device.

A system for supporting Enhanced Privacy Identification (EPID) is provided. The system may include a host processor operable to communicate with a remote requestor, where the host processor needs to perform signature revocation checking in accordance with EPID. To perform signature revocation checking, the host processor has to perform either a sign or verify operation. The host processor may offload the sign/verify operation onto one or more associated hardware acceleration coprocessors. A programmable coprocessor may be dynamically configured to perform the desired number of sign/verify functions in accordance with the requirements of the current workload.

A method of improving data security or privacy in a computing environment includes providing a group identifier value to at least a first user of one or more users and associating a first pseudonym with the first user. The method further includes encrypting a first data set according to a private key and marking the encrypted first data set according to the group identifier and the first pseudonym. The method also includes performing a first operation on the encrypted first data set and transforming the encrypted first data set into an encrypted second data set according to the first operation performed and the first pseudonym, decrypting the encrypted second data set using the private key, and analyzing the decrypted second data set.

Technologies for key management of internet-of-things (IoT) devices include an IoT device, an authority center server, and a group management server. The IoT device is configured to authenticate with an authority center server via an offline communication channel, receive a group member private key as a function of the authentication with the authority center server, and authenticate with a group management server via a secure online communication channel using the group member private key. The IoT device is further configured to receive a group shared key as a function of the authentication with the group management server, encrypt secret data with the group shared key, and transmit the encrypted secret data to the group management server. Other embodiments are described herein.

A method, system, and computer program product generate, with a payment network, a first value (a) and a second value (ga), the second value (ga) generated based on the first value (a) and a generator value (g); generate, with the payment network, a plurality of random merchant numbers (mi) for a respective plurality of merchant banks; determine, with the payment network, a merchant product (M) based on a product of the plurality of random merchant numbers (mi); generate, with the payment network, a public key (pki) based on the second value (ga), the merchant product (M), and the random merchant number (mi) and a random key (rki) based on the merchant product (M) and the random merchant number (mi) for each respective merchant bank; and communicate, with the payment network, the public key (pki) and the random key (rki) to at least one respective merchant bank.

A method of improving data security or privacy in a computing environment includes providing a group identifier value to at least a first user of one or more users and associating a first pseudonym with the first user. The method further includes encrypting a first data set according to a private key and marking the encrypted first data set according to the group identifier and the first pseudonym. The method also includes performing a first operation on the encrypted first data set and transforming the encrypted first data set into an encrypted second data set according to the first operation performed and the first pseudonym, decrypting the encrypted second data set using the private key, and analyzing the decrypted second data set.

Plurality of users share a common key while permitting change of members sharing the common key and computational complexity required for key exchange is reduced. R.sub.i and c.sub.i are computed based on a twisted pseudo-random function in a first key generation step. sid is generated based on a target-collision resistant hash function and (sid, R.sub.α, R.sub.β) is transmitted to communication devices U.sub.i in a session ID generation step. T.sub.1 and T′ are computed based on a pseudo-random function in a representative second key generation step. T.sub.j is computed based on the pseudo-random function in a general second key generation step. k′ is computed based on the twisted pseudo-random function and T′.sub.j is computed with respect to each j in a third key generation step. K.sub.1.sup.1 and k.sub.1 are computed in a first session key generation step. A common key K.sub.2 is generated based on the pseudo-random function in a second session key generation step.