An access control system includes a processor configured to provide a trusted execution environment isolated from a rich execution environment. A rich OS operates in the rich execution environment while a trusted OS operates in the trusted execution environment. An access monitoring module operates within the kernel of the rich OS and a trusted application operates in the trusted OS. The access monitoring module intercepts file requests directed at the file systems of the rich OS, and forwards the file requests to the trusted application. The trusted application then evaluates whether the file request is permitted and provides the access monitoring module with a response. The access monitoring module forwards the request to the file system only if the trusted application approves the request.

An active attestation apparatus verifies at runtime the integrity of untrusted machine code of an embedded system residing in a memory device while it is being run/used with while slowing the processing time less than other methods. The apparatus uses an integrated circuit chip containing a microcontroller and a reprogrammable logic device, such as a field programmable gate array (FPGA), to implement software attestation at runtime and in less time than is typically possible with comparable attestation approaches, while not requiring any halt of the processor in the microcontroller. The reprogrammable logic device includes functionality to load an encrypted version of its configuration and operating code, perform a checksum computation, and communicate with a verifier. The checksum algorithm is preferably time optimized to execute computations in the reprogrammable logic device in the minimum possible time.

A multifunction device includes: a non-volatile memory storing encrypted information, which is information that is encrypted; a TPM for decrypting the encrypted information; and a main board communicating with the non-volatile memory and the TPM. The non-volatile memory and the TPM are attachable to and removable from the main board, as a single body. More specifically, the multifunction device includes: a first sub board which has the non-volatile memory attached thereto and is attachable to and removable from the main board; and a chip board which has the TPM attached thereto and is attachable and removable from the first sub board.

A client computing device may obtain access to protected resources with a proof-of-possession (Pop) token. The client computing device may request an access token from an authorization server via an application server. The request may include key material (e.g., token binding type, key, and key parameters) that the client computing device possesses or has access to, such as a public key of an asymmetric public/private key pair. In some embodiments, the public key may be a confirmation (CNF) key, which may be added to the access token and JWT signed by the authorization server. The private key may be retained by the client, who may then use the PoP token to prove possession of the private key.

In one example an apparatus comprises a computer readable memory, a signing facility comprising a plurality of hardware security modules, and a state synchronization manager comprising processing circuitry to select, from the plurality of hardware security modules, a set of hardware security modules to be assigned to a digital signature process, the set of hardware security modules comprising at least a first hardware security module and a second hardware module, and assign a set of unique state synchronization counter sequences to the respective set of hardware security modules, the set of state synchronization counter sequences comprising at least a first state synchronization counter sequence and a second state synchronization counter sequence. Other examples may be described.

An active attestation apparatus verifies at runtime the integrity of untrusted machine code of an embedded system residing in a memory device while it is being run/used with while slowing the processing time less than other methods. The apparatus uses an integrated circuit chip containing a microcontroller and a reprogrammable logic device, such as a field programmable gate array (FPGA), to implement software attestation at runtime and in less time than is typically possible with comparable attestation approaches, while not requiring any halt of the processor in the microcontroller. The reprogrammable logic device includes functionality to load an encrypted version of its configuration and operating code, perform a checksum computation, and communicate with a verifier. The checksum algorithm is preferably time optimized to execute computations in the reprogrammable logic device in the minimum possible time.

A method for authenticating an origin of a network device. The method includes reading one or more encrypted parameters from a memory of the network device, decoding the one or more encrypted parameters, and determining whether one or more of the decoded parameters match parameters obtained from a trusted platform module (TPM) installed in the network device and/or a read only memory (ROM) of the network device. In response to a mismatch between the decoded parameters and the parameters obtained from the TPM or the ROM, at least one of suspending operation of the device or transmitting a report of an authentication failure across a network on which the device is operating.

Example implementations relate to attestation. For example, in an implementation, a target device attestation request is transmitted to a target device, where the target device attestation request includes an identity-based encryption (IBE) ciphertext and a retrieval index. The ciphertext is a nonce encrypted using a trusted platform module (TPM) public key together with an IBE public key. The TPM public key is retrieved from a TPM of the target device, and the IBE public key is an expected value presumed to be stored at the TPM.

The invention relates to distributed processing systems that involve the distribution of computational tasks to one or more untrusted worker computer systems. When an untrusted worker computer system performs a calculation on behalf of a requesting computer system, the requesting computer system (or other verifying computer system) is provided with information that allows the requesting computer system to cryptographically verify that that task has been correctly completed. After completing the calculation, the worker computer system provides information to the requester that includes a proof and I/O data. The requesting computer system may use a set of public verification key parameters, the proof, and the I/O data to verify that the computation performed by an untrusted worker computer system is correct. In some examples, the calculation performed by the worker is associated with the verification of a blockchain transaction. For example, the verification of the computation performed by the untrusted worker computer system may occur as part of validating a transaction on a blockchain node.

Embodiments of the present invention are directed to an improved system and method of producing, recording and reporting boot integrity measurements of an Internet of Things (“IoT”) computing device to resource (such as an on-chip software module, an external software module, a printer, a network router, or a server), so the resource can confirm that the IoT computing device can be trusted before access to the resource is granted. Embodiments provide a new and less expensive architecture for reliably collecting and relaying device state information to support trust-sensitive applications. Embodiments leverage crypto-acceleration modules found on many existing microprocessors and microcontroller-based IoT devices, while introducing little additional overhead or additional circuitry. Embodiments provide a Root of Trust module comprising integrated internal control logic that functions as a secure on-chip wrapper for cryptographic primitive modules, which provide secure storage and reporting of the host's platform integrity measurements.