A direct-attach cable data transmission visual indicator system includes a networking device having a port, and a direct-attach cable that includes a direct-attach cable connector that is located on an end of the direct-attach cable and that couples the direct-attach cable to the port, and a visual indicator device that is included on the direct-attach cable adjacent to and spaced apart from the direct-attach cable connector. The visual indicator device receives, from the networking device via the port and the direct-attach cable connector, data transmission information that is associated with the transmission of data via the port, and provides a visual indication that is based on the first data transmission information.

An error rate measuring apparatus includes an operation unit that sets one Codeword length and one FEC Symbol length of FEC according to a communication standard of a device under test, data division means for dividing symbol string data obtained by converting a signal received from the device under test into MSB data and LSB data, a data comparison unit that compares each of the divided MSB data and LSB data with error data to detect MSB errors and LSB errors of each one Codeword length, and detects FEC Symbol Errors of each of the MSB data and the LSB data at one FEC Symbol interval, and error counting means for counting the detected MSB errors and LSB errors, and counting the FEC Symbol Errors.

The present technology relates to a display apparatus, a display control method, a portable terminal apparatus, and a program capable of representing various states of an apparatus in a limited region.

A television receiver includes a display unit that displays a predetermined image, a communication unit that performs communication of image data with another image display apparatus, an indicator unit that is disposed at at least a part of surroundings of the display unit and includes an indicator which is turned on with predetermined luminance, and a control unit that turns on the indicator so as to correspond to a transmission operation of the image data in another image display apparatus. The present invention is applicable to, for example, a display apparatus such as a television receiver.

The present subject matter relates to techniques for storing POST codes in electronic tags. In an example, a POST code corresponding to each test of a Power ON Self-Test (POST) process may be stored in a Complementary Metal-Oxide Semiconductor (CMOS) chip of a motherboard. The POST code may be indicative of a status of a respective test of the POST process. The POST code corresponding to each test of the POST process is simultaneously stored in a memory of an electronic tag. The electronic tag may be communicatively coupled to the motherboard and the CMOS chip. The POST codes are retrievable from the memory of the electronic tag by an end user of the computing device when the motherboard is powered OFF.

Methods, systems, and devices for a memory device with status feedback for error correction are described. For example, during a read operation, a memory device may perform an error correction operation on first data read from a memory array of the memory device. The error correction operation may generate second data and an indicator of a state of error corresponding to the second data. In one example, the indicator may indicate one of multiple possible states of error. In another example, the indicator may indicate a corrected error or no detectable error. The memory device may output the first or second data and the indicator of the state of error during a same burst interval. The memory device may output the data on a first channel and the indicator of the state of error on a second channel.

A system includes a processing device and a memory device coupled to the processing device. The memory device can include a cyclic buffer portion and a snapshot portion. The processing device can store time based telemetric sensor data in the cyclic buffer portion, copy an amount of the telemetric sensor data from the cyclic buffer portion to the snapshot portion in response to a trigger event, operate the cyclic buffer portion with a first trim tailored to a performance target of the cyclic buffer portion, and operate the snapshot portion with a second trim tailored to a performance target of the snapshot portion.

A system includes a processing device and a memory device coupled to the processing device. The memory device can include a cyclic buffer portion and a snapshot portion. The processing device can store time based telemetric sensor data in the cyclic buffer portion, copy an amount of the telemetric sensor data from the cyclic buffer portion to the snapshot portion in response to a trigger event, operate the cyclic buffer portion with a first trim tailored to a performance target of the cyclic buffer portion, and operate the snapshot portion with a second trim tailored to a performance target of the snapshot portion.

Embodiments include cognitive control of runtime resource monitoring scope. Aspects include obtaining historical data for each of a plurality of metrics for a computer system and calculating, based on the historical data, an anomaly relationship score for each of the plurality of metrics. Aspects also include calculating, based on the historical data, a sensitivity score for each of the plurality of metrics and determining a priority score for each of the plurality of metrics based upon a weighted combination of the anomaly relationship score and the priority score. Aspects further include receiving real-time data for each of the plurality of metrics and presenting a subset of the real-time data to a user, the subset created by selecting one or more of the plurality of metrics based on the priority score of each of the plurality of metrics.

An error notification system includes a plurality of data production systems in communication with a monitoring server. Each data production system has a data processor configured to receive input data from a first set of data production systems, process the input data to produce output data, and make the output data accessible to a second set of data production systems. The monitoring server is configured to monitor data transmissions between the data production systems and to identify, for each data transmission, originating and receiving systems. The monitoring server is further configured to map data flow from each originating source system to identify all downstream data production systems. Upon identification of a data error in the originating source system, the monitoring server obtains data error information, assembles a data error notification, and transmits the data error notification to data production systems meeting system notification criteria.

An in-vehicle system performs wireless communication with electric power supplied from a battery mounted on a vehicle. The in-vehicle system includes a wireless communication unit configured to perform the wireless communication, a counting unit configured to count the number of resets that have occurred in the wireless communication unit; and an operation limiting unit configured to, when a predetermined power supply of the vehicle is off, limit the number of resets that occur in the wireless communication unit.