Abstract: A system for transmitting data is disclosed that includes a file distribution system operating on a processor that is configured to identify one or more files for distribution to a device, forward error correction data for the one or more files, and a cryptographic key associated with the device. A Merkle tree system operating on the processor is configured to receive the forward error correction data and to generate an encrypted root hash. A data transmission system operating on the processor is configured to transmit the one or more files and the encrypted root hash to a predetermined device.

Abstract: Methods and systems for synchronizing state information amongst monitoring nodes for DDoS attack mitigation are disclosed. Embodiments of the present technology may include a method for synchronizing state information amongst monitoring nodes, the method including identifying a packet as a state-related packet by inspecting the packet below a TCP/IP stack in a monitoring node and implementing state synchronization operations below the TCP/IP stack of the monitoring node in response to identifying the packet as a state-related packet, wherein the state synchronization operations include updating an allowlist stored as a key-value map in the monitoring node based on the identified packet and generating a state update packet based on the identified packet.

Abstract: The invention relates to a process for chemically etching the surface of a metal halide perovskite, the process comprising treating the metal halide perovskite with one or more multidentate ligands, wherein the one or more multidentate ligands comprise an organic compound or a salt thereof, which organic compound comprises three or more binding groups. A chemically etched metal halide perovskite, a process for producing a semiconductor device, a composition and a semiconductor device are also described.

Abstract: The invention provides a body-worn monitor featuring a processing system that receives a digital data stream from an ECG system. A cable houses the ECG system at one terminal end, and plugs into the processing system, which is worn on the patient's wrist like a conventional wristwatch. The ECG system features: i) a connecting portion connected to multiple electrodes worn by the patient; ii) a differential amplifier that receives electrical signals from each electrode and process them to generate an analog ECG waveform; iii) an analog-to-digital converter that converts the analog ECG waveform into a digital ECG waveform; and iv) a transceiver that transmits a digital data stream representing the digital ECG waveform (or information calculated from the waveform) through the cable and to the processing system. Different ECG systems, typically featuring three, five, or twelve electrodes, can be interchanged with one another.

Abstract: An information handling system may include a circuit board; a processor disposed on the circuit board, wherein the processor includes a media access control (MAC) address and a hidden root key (HRK) encoded therein; and a memory not disposed on the circuit board. The information handling system may be configured to: determine a customer public key (CPK); create a data structure comprising the CPK and the MAC address; encrypt the data structure using the HRK to generate an encrypted structure; and store the encrypted structure in the memory.

Abstract: A BMC firmware security system includes a BMC coupled to a programmable circuit device and a first storage subsystem. In response to BMC initialization, the BMC uses a system identifier to verify that a license in the first storage subsystem authorizes the BMC to use BMC firmware in the BMC, uses branding identity information in the BMC to verify that the BMC is branded for the BMC firmware, determines that the programmable circuit device identifies the BMC firmware and, in response, the performs BMC initialization operations using the BMC firmware. A BIOS is coupled to the programmable circuit device and a second storage system. In response to BIOS initialization, the BIOS uses the branding identity information in the second storage subsystem to identify the BMC firmware, determines that the programmable circuit device identifies the BMC firmware and, in response, performs BIOS initialization operations.

Abstract: A wearable medical treatment device for monitoring a patient's ECG and treating a cardiac condition is disclosed. The device includes a patient vest portion having cardiac sensing electrodes to obtain an ECG signal of a patient, therapy electrodes for external placement proximate to skin of the patient for delivering electrotherapy to treat the cardiac condition, and, a monitor coupled to the cardiac sensing electrodes and the therapy electrodes via at least one cable. The monitor includes a system computer disposed in the monitor. The system computer is configured to receive the ECG signals of the patient and to execute at least one arrhythmia detection algorithm to determine whether the patient is experiencing a cardiac condition in need of treatment, and a mechanical shock detector disposed on the monitor and configured to detect at least one of a force or acceleration indicative of a mechanical shock to the monitor.

Abstract: A method for estimating blood pressure of a care recipient includes establishing a pre-maneuver reference value of blood pressure and a companion nonreference value of blood pressure, subjecting the care recipient to a maneuver, establishing a post-maneuver reference value of blood pressure and a companion post-manuever nonreference value of blood pressure, establishing an operational post-maneuver nonreference value of blood pressure, and adjusting the operational value as a function of the pre-maneuver and post-maneuver values. An associated apparatus includes a sensor, a processor and a memory which contains instructions.

Abstract: An information handling system may include a circuit board; a processor disposed on the circuit board, wherein the processor includes a media access control (MAC) address and a hidden root key (HRK) encoded therein; and a memory not disposed on the circuit board. The information handling system may be configured to: determine a customer public key (CPK); create a data structure comprising the CPK and the MAC address; encrypt the data structure using the HRK to generate an encrypted structure; and store the encrypted structure in the memory.

Abstract: An information handling system may include a host system comprising a processor and a management controller comprising a main processor and a trusted integrated processor configured to perform secured boot services and run-time security functions of the management controller. The information handling system may also include a legacy communications bus interfaced between the host system and the main processor and a secure communications bus interfaced between the host system and the main processor. The trusted integrated processor is further configured to implement a secure attestation channel to the host system via the secure communications bus in order to provide access by the host system to security services owned by the management controller.

Abstract: Various embodiments provide methods for validating hardware modifications of an IHS (Information Handling System) by confirming that a hardware modification corresponds to a hardware component supplied for installation in the IHS by a trusted entity. During factory provisioning of an IHS, an inventory certificate that specifies the factory installed IHS hardware is uploaded to the IHS and is also stored for ongoing support of the IHS. Upon a hardware component being supplied for installation in the IHS by a trusted entity, the inventory of the stored inventory certificate is updated to identify the supplied component and the updated certificate is transmitted to the IHS. An inventory of detected hardware components of the IHS is compared against the inventory from the updated inventory certificate in order to validate the detected hardware of the IHS includes the component, supplied by the trusted entity, that is identified in the updated inventory certificate.

Abstract: Various embodiments provide methods for validating secure assembly and delivery of an IHS (Information Handling System) by confirming that the detected hardware components of the IHS include only factory installed hardware components. During factory provisioning of an IHS, an inventory certificate is uploaded to the IHS, where the inventory certificate includes an inventory that identifies the hardware components installed during factory assembly of the IHS. An inventory is collected of the detected hardware components of the IHS. The collected inventory is compared against the inventory from the inventory certificate in order to validate the detected hardware components of the IHS as the same hardware components that were installed during factory assembly of the IHS. Embodiments provide a customer receiving an IHS with a capability of validating that a delivered IHS includes only factory installed hardware components.

Abstract: Embodiments support secure booting of an IHS (Information Handling System) based on validation of the secure assembly and delivery of the IHS. A validation process of the IHS is initialized that delays further booting of the IHS until detected hardware components of the IHS are validated. An inventory certificate is retrieved that was uploaded to the IHS during factory provisioning of the IHS. The inventory certificate includes an inventory that identifies hardware components installed during factory assembly of the IHS. A collected inventory of detected hardware components of the IHS is compared against the inventory from the inventory certificate in order to validate the detected hardware components of the IHS as the same hardware components installed during factory assembly of the IHS. When the comparison validates the detected hardware components of the IHS as only including factory assembled hardware, further booting of the IHS is allowed.

Abstract: Embodiments support remote validation of the secure assembly and delivery of an IHS (Information Handling System). A validation process of the IHS initiates a remote management connection with a remote management console. The remote management console retrieves an inventory certificate generated during factory provisioning of the IHS and stored to the IHS and/or to a remote location. The inventory certificate includes an inventory identifying a plurality of hardware components installed during factory assembly of the IHS. The remote management console retrieves an inventory of detected hardware components of the IHS and compares the inventory of detected hardware components against the inventory from the inventory certificate in order to validate the detected hardware components of the IHS as the same hardware components installed during factory assembly of the IHS.

Abstract: Embodiments provide methods for validating secure delivery of an IHS (Information Handling System) by confirming that the packages by which the IHS was delivered include only the packages used to ship the IHS from a factory or other trusted entity. During factory provisioning of the IHS, a shipping certificate is uploaded to the IHS, where the certificate includes shipping identifiers that are each associated with a package used to ship the IHS. Upon receiving packages by which the IHS has been shipped, shipping identifiers, such as bar codes and RFID codes, are collected from the received packages. The shipping identifiers collected from the received packages are compared against the shipping identifiers from the shipping certificate in order to validate the plurality of received packages as the same packages that were used to ship the IHS.

Abstract: Embodiments validate the secure assembly and delivery of IHSs (Information Handling Systems) that are installed in a shared chassis, such as two 1RU (rack unit) servers installed in a shared 2RU chassis. An inventory certificate is retrieved that was uploaded to a first IHS of the IHSs installed in the shared chassis during factory provisioning of the first IHS. The inventory certificate specifies factory installed hardware components installed in each of the IHSs of the shared chassis. A validation process of the first IHS collects an inventory of hardware components detected by each of the IHSs of the shared chassis. The validation process compares the collected inventory of detected hardware components of the IHSs against the factory installed hardware components specified in the inventory certificate in order to validate the detected hardware components as the same hardware components installed during factory assembly of each of the IHSs.

Abstract: The invention provides a neck-worn sensor that is a single, body-worn system that measures the following parameters from an ambulatory patient: heart rate, pulse rate, pulse oximetry, respiratory rate, temperature, thoracic fluid levels, stroke volume, cardiac output, and a parameter sensitive to blood pressure called pulse transit time. From stroke volume, a first algorithm employing a linear model can estimate the patient's pulse pressure. And from pulse pressure and pulse transit time, a second algorithm, also employing a linear algorithm, can estimate systolic blood pressure and diastolic blood pressure. Thus, the sensor can measure all five vital signs along with hemodynamic parameters. It also includes a motion-detecting accelerometer, from which it can determine motion-related parameters such as posture, degree of motion, activity level, respiratory-induced heaving of the chest, and falls.

Abstract: The present invention provides a technique for continuous measurement of blood pressure based on pulse transit time and which does not require any external calibration. This technique, referred to herein as the ‘Composite Method’, is carried out with a body-worn monitor that measures blood pressure and other vital signs, and wirelessly transmits them to a remote monitor. A network of body-worn sensors, typically placed on the patient's right arm and chest, connect to the body-worn monitor and measure time-dependent ECG, PPG, accelerometer, and pressure waveforms. The disposable sensors can include a cuff that features an inflatable bladder coupled to a pressure sensor, three or more electrical sensors (e.g. electrodes), three or more accelerometers, a temperature sensor, and an optical sensor (e.g., a light source and photodiode) attached to the patient's thumb.