The present invention provides a smart overclocking method for a computer device with a multi-core CPU and abasic input/output system (BIOS) where an overclocking database is stored therein, which comprises: booting the computer device, logging in the BIOS and performing an overclocking function; acquiring overclocking parameters from the overclocking database; conducting adjustment/settlement of the clock rate and the voltage of the multi-core CPU based on the overclocking parameters; conducting a Heavy Load Testing (HLT) on the multi-core CPU; reading out working results data of the multi-core CPU and determining whether any of them have exceeded limits. Hence, overclocking can be completed within 10 min. or less, without causing shut down of the computer device, and without causing working temperature or working voltage of multi-core CPU to be higher than 90° C. or 1500 mV during Heavy Load Testing (HLT).

A stand-alone bridging test method is provided, which is applied to a stand-alone bridging device. The stand-alone bridging device is coupled to a storage device. The stand-alone bridging device includes a bridging controller. The storage device includes a device controller and a device memory. The stand-alone bridging test method includes the bridging controller generates a handshaking test signal and transmits the handshaking test signal to the device controller. The device controller generates a confirmation test signal according to the handshaking test signal and transmits the confirmation test signal to the bridging controller. The bridging controller generates a test data according to the confirmation test signal and transmits a write command to the device controller to write the test data into the device memory. The bridging controller transmits a read command to the device controller to read a stored data of the device memory.

A configuration device in a test and measurement system including an event generator and a Device Under Test (DUT) to receive one or more events generated by the event generator includes an output display structured to graphically illustrate a first event timeline that includes source event markers for a first test channel for a second test channel, in which the first event timeline and the second event timeline appear on the output display as separate timelines vertically separated from one another. The position of the event delay indicator or a position of the event width indicator may be movable by a user, and moving the position of the event delay indicator or moving the position of the event width indicator causes the event generator to change one or more event generation parameters of the first event based on such movement. Methods are also disclosed.

A configuration device in a test and measurement system including an event generator and a Device Under Test (DUT) to receive one or more events generated by the event generator includes an output display structured to graphically illustrate a first event timeline that includes source event markers for a first test channel for a second test channel, in which the first event timeline and the second event timeline appear on the output display as separate timelines vertically separated from one another. The position of the event delay indicator or a position of the event width indicator may be movable by a user, and moving the position of the event delay indicator or moving the position of the event width indicator causes the event generator to change one or more event generation parameters of the first event based on such movement. Methods are also disclosed.

Detecting execution hazards in offloaded operations is disclosed. A second offload operation is compared to a first offload operation that precedes the second offload operation. It is determined whether the second offload operation creates an execution hazard on an offload target device based on the comparison of the second offload operation to the first offload operation. If the execution hazard is detected, an error handling operation may be performed. In some examples, the offload operations are processing-in-memory operations.

Detecting execution hazards in offloaded operations is disclosed. A second offload operation is compared to a first offload operation that precedes the second offload operation. It is determined whether the second offload operation creates an execution hazard on an offload target device based on the comparison of the second offload operation to the first offload operation. If the execution hazard is detected, an error handling operation may be performed. In some examples, the offload operations are processing-in-memory operations.

Power reduction and voltage adjustment techniques for computing systems and processing devices are presented herein. In one example, a method includes receiving a voltage characterization service over a communication interface of the computing apparatus as transferred by a deployment platform remote from the computing apparatus. The method includes executing the voltage characterization service for a processing device of the computing apparatus to determine at least one input voltage for the processing device lower than a manufacturer specified operating voltage, the voltage characterization service comprising a functional test that exercises the processing device at iteratively adjusted voltages in context with associated system elements of the computing apparatus. During execution of the voltage characterization service, the method includes monitoring for operational failures of at least the processing device, and responsive to the operational failures, restarting the processing device using a recovery voltage higher than a current value of the iteratively adjusted voltages.

Voltage adjustment techniques for computing systems and processing devices are presented herein. In one example, a method of determining operating voltages for a processing device includes executing a voltage adjustment process to determine at least one input voltage for the processing device lower than a manufacturer specified operating voltage. During the voltage adjustment process, the method includes applying incrementally adjusted input voltages to the processing device, operating the processing device according to a functional test that exercises the processing device in context with associated system elements of a computing assembly, and monitoring for operational failures of at least the processing device during application of each of the incrementally adjusted input voltages. Responsive to the operational failures, the method includes determining corresponding values of the incrementally adjusted input voltages and establishing an input voltage based at least in part on the corresponding values of the incrementally adjusted input voltages.

Aspects of the embodiments are directed to systems, methods, and apparatuses to determine transmission equalization coefficients (TxEQs) for one or more lanes of a high speed serial link. Embodiments include determining a jitter tolerance for each TxEQ of a plurality of TxEQs for a lane of the link. The jitter tolerance for each TxEQ for the lane is based on a level of jitter induced on the lane to detect a number of errors on the lane; determining a voltage (VOC) margin for each TxEQ for the lane, wherein the voltage margin for the lane is based on a voltage corners test applied to the lane to detect a number of errors on the lane at a high voltage point and a low voltage point; determining a TxEQ that provides maximum jitter tolerance and based on the determined lowest voltage margin; and using the TxEQ for the lane during operation.

A disk drive thermal performance testing device includes a drive housing, an electrical connector and an adjustable power loading device. The drive housing is at least partially made of a thermally conductive material. The electrical connector is in the drive housing and provides an external connection. The adjustable power loading device is located in the drive housing, is coupled to the electrical connector, and is thermally coupled to the drive housing.