Various examples described herein provide for monitoring a peripheral device by data imported from the peripheral device. The peripheral data may comprise a script associated with monitoring or managing the peripheral device, or descriptive data describing a set of monitor values on the peripheral device.

A method for dynamically providing a status of a hardware thread/hardware resource independent of the operation of the hardware thread/hardware resource using an inter-thread communication protocol. A master hardware thread may be configured to communicate status requests to associated slave hardware threads and/or hardware resources. Each slave hardware thread/hardware resource may be configured with hardware logic configured to automatically determine status information for the slave hardware thread/hardware resource and communicate a status response to the master hardware thread without interrupting processing of the slave hardware thread/hardware resource.

A circuit arrangement and program product for dynamically providing a status of a hardware thread/hardware resource independent of the operation of the hardware thread/hardware resource using an inter-thread communication protocol. A master hardware thread may be configured to communicate status requests to associated slave hardware threads and/or hardware resources. Each slave hardware thread/hardware resource may be configured with hardware logic configured to automatically determine status information for the slave hardware thread/hardware resource and communicate a status response to the master hardware thread without interrupting processing of the slave hardware thread/hardware resource.

Methods and apparatus to communicatively coupled field devices to a remote terminal unit are disclosed. The example apparatus includes a base rack for a remote terminal unit in a process control system. The example apparatus further includes a first termination module to be inserted in a first termination slot of the base rack. Wires communicatively coupled to a field device are to be terminated on the first termination module. The example apparatus also includes a first control module separate from the first termination module to be inserted in a first control slot of the base rack. The first control module is to be communicatively coupled with the first termination module via a backplane of the base rack. The first control module is to control communications with the field device.

A method of periodically recording for events is disclosed. The method includes the following steps: accessing a register of a power supply by a baseboard management controller to obtain a message related to the power supply; confirming a logical sensor status of the power supply according to the message by the baseboard management controller so as to determine whether a predicted failure status of the power supply is detected, and monitoring a predetermined logical variable by the baseboard management controller; generating an event log when the predicted failure status of the power supply is detected by the baseboard management controller; performing a timing task selectively according to a result of monitoring related to the predetermined logical variable by the baseboard management controller so as to determine whether to generate a control command; generating another event log according to the control command by the baseboard management controller.

A method for dynamically providing a status of a hardware thread/hardware resource independent of the operation of the hardware thread/hardware resource using an inter-thread communication protocol. A master hardware thread may be configured to communicate status requests to associated slave hardware threads and/or hardware resources. Each slave hardware thread/hardware resource may be configured with hardware logic configured to automatically determine status information for the slave hardware thread/hardware resource and communicate a status response to the master hardware thread without interrupting processing of the slave hardware thread/hardware resource.

In a chassis including a plurality of nodes, a network switch, and a programmable device configured to manage a shared resource of the chassis, a method includes establishing, using the network switch, a dedicated network among baseboard management controllers of respective nodes in the plurality of nodes; and using the dedicated network, automatically selecting a given node from the plurality of nodes to function as a master node to program the programmable device on behalf of all nodes in the plurality of nodes to manage the shared resource of the chassis on behalf of all the nodes in the plurality of nodes.

A circuit arrangement and program product for dynamically providing a status of a hardware thread/hardware resource independent of the operation of the hardware thread/hardware resource using an inter-thread communication protocol. A master hardware thread may be configured to communicate status requests to associated slave hardware threads and/or hardware resources. Each slave hardware thread/hardware resource may be configured with hardware logic configured to automatically determine status information for the slave hardware thread/hardware resource and communicate a status response to the master hardware thread without interrupting processing of the slave hardware thread/hardware resource.

The system for automatic signal measurement includes a device under test, a control circuit, a data processing circuit, and a display device. The device under test includes a test pad area, which has multiple exposed test pads coupled to multiple circuit nodes in the device under test. The control circuit is coupled to the exposed test pads through a clamping fixture. The control circuit receives multiple test signals from the exposed test pads, stores multiple test signals in the memory, and controls a power on/off operation applied to the device under test through the exposed test pads. The data processing circuit is configured to receive the test signals stored in the memory, and determine whether the test signals meet a set of predetermined criteria to generate a verification result. The display device displays a signal waveform of the test signals and the verification result.

The device for testing a motherboard includes a power adapter, a first DC-DC converter, and a microcontroller. The power adapter converts an AC input voltage to a DC supply voltage. The DC-DC converter converts the DC supply voltage to a DC voltage at a channel coupled to the motherboard, and adjusts a voltage level of the DC voltage in response to a control signal. The DC-DC converter is enabled according to an enable signal. The microcontroller is configured to provide the control signal and the enable signal, and to determine whether a power on/off operation of the motherboard is normal. The microcontroller is configured to perform a test procedure on the motherboard to obtain a workable voltage range of the motherboard. The voltage level of the DC voltage in the test procedure is dynamically adjusted within a predetermined range around a nominal voltage value of the DC voltage.