A system and method for providing multifactor authentication. A disclosed method includes receiving a request at a server to launch a new session for an application on a client device, generating a plurality of codes, each of the plurality of codes associated with a respective identifier, and forwarding the plurality of codes via a short messaging service (SMS) message to a user associated with the client device. The method further includes sending the respective identifier associated with a given code of the plurality of codes to the application and receiving a submitted code entered into the application from the client device. Once received, the method compares the submitted code with the given code associated with the respective identifier and authenticates the user in response to the submitted code matching the given code.

Disclosed are various embodiments for providing access to a recovery key of a managed device and rotating the recovery key after it has been accessed. In one example, among others, a system includes a computing device and program instructions. The program instructions can cause the computing device to store a first recovery key for a first managed computing device. The first recovery key is configured to access an encrypted data store of the first managed computing device. A request is received for the first recovery key from a second managed computing device. The first recovery key is transmitted for display on the second managed computing device. A key rotation command is generated for a command queue of the first managed computing device to rotate the first recovery key after transmitting the first recovery key. The second recovery key is received from the second computing device.

Disclosed is a surgical system that includes a first modular device and aa surgical hub, including a control circuit configured to receive first perioperative data from a second modular device; anonymize the first perioperative data; receives second perioperative data from a third modular device; anonymize the second perioperative data; and adjust at least one setting of the first modular device based on contextual information derived from the anonymized first and second perioperative data.

Provided are an access control method and device, and a storage medium. The method includes that: a collected image to be recognized is recognized to obtain a recognition result, where the image to be recognized includes a present graphic code; in condition that the recognition result indicates that the present graphic code is a target graphic code, the present graphic code is parsed to obtain user information and generation time contained in the present graphic code; and an access control device is controlled to be opened according to the user information and generation time in the present graphic code.

The technology presented herein enables a new network element to be authenticated to other network elements automatically. In a particular embodiment, a method provides determining a current time relative to a first time. The first time is known to the new network element and a provisioning network element. The method further provides generating first beacon data using seed data stored on the new network element and the current time and generating keying data using the first beacon data and identification information associated with the new network element. The method also provides identifying a first one-time pad (OTP) from the keying data and using the first OTP to encrypt an authentication request for transfer from the new network element to the provisioning network element.

Provided is a network security system including a communication interface that transmits a request for a preset option field value to a Dynamic Host Configuration Protocol (DHCP) server, receives a preset option field value corresponding to the request for the preset option field value from the DHCP server, transmits a request for a preset file to a Trivial File Transfer Protocol (TFTP) server, and receives a preset file corresponding to the request for the preset file from the TFTP server, and a processor that designates a preset location and the preset file of the TFTP server based on the preset option field value, wherein the preset file includes a file different from a file specified in the preset option field value by the DHCP.

A security platform employs a variety techniques and mechanisms to detect security related anomalies and threats in a computer network environment. The security platform is “big data” driven and employs machine learning to perform security analytics. The security platform performs user/entity behavioral analytics (UEBA) to detect the security related anomalies and threats, regardless of whether such anomalies/threats were previously known. The security platform can include both real-time and batch paths/modes for detecting anomalies and threats. By visually presenting analytical results scored with risk ratings and supporting evidence, the security platform enables network security administrators to respond to a detected anomaly or threat, and to take action promptly.

Systems and methods for preventing fraud are disclosed. The system includes, for example, a front end device that is operatively coupled to a back end device. The front end device is configured to generate a first dynamic device identification based on dynamic device characteristics of the front end device. The back end device is configured to generate a second dynamic device identification based on the dynamic device characteristics of the front end device to authenticate the front end device. The front end device can also authenticate itself through an Internet of Things (IoT) device that has a trusted connection to the back end device.

In one embodiment, the present disclosure is directed to a system for digital authentication, the system including a server and a device. The device includes a first processor and a second processor separate and distinct from the first processor and dedicated solely to security functionality. The second processor is programmed to generate a public key and a private key, and to use the private key and to-be-signed signature data to generate digital signatures, including a first digital signature. The device transmits the public key and the first digital signature to the server. The server stores the public key to uniquely identify the device or a user of the device in subsequent communications between the server and device.

Systems and methods for token processing are disclosed. An access device can provide access device data to a mobile communication device. The communication device generates a token request including the access device data and communication device data and sends the token request to a server computer. The server computer returns a token and a token cryptogram to the mobile communication device. The token and the cryptogram may be used in a transaction.