A method/system for managing experimental data, a computer readable storage medium, and a device are provided. The method includes: recording the managing experimental data, and preprocessing the experimental data, to obtain at least two preprocessed experimental arrays; selecting one element from each of two selected preprocessed experimental arrays according to an analysis requirement, and combining the elements to form a cyclic experimental database, the cyclic experimental database including several combination data; performing cyclic statistical analysis on the combination data in the cyclic experimental database, to obtain a cyclic statistical result corresponding to retrieved combination data.

Vehicle operation safety related indicia (VSRI) displaying apparatus(es) disclosed display, adjacent or proximate a vehicle surface at least generally vehicle operator facing, VSRI on a vehicle operator facing surface of a VSRI display member, slidably positionable between a VSRI non-revealed and a VSRI revealed state displaying VSRI extended outwardly from a side of the apparatus. VSRI subject-matter, optionally-illuminated and/or electro-mechanically positioned, depicts one or more objects extending outwardly from at least one side of a vehicle having an in-use VSRI display apparatus, or from a vehicle rack or towed device. VSRI display apparatus variants include a housing or body appearing and/or shaped like the vehicle, or side(s) thereof, having an in-use apparatus. Secondary indicia displaying surface-areas also provided, concurrently display additional VSRI and/or advertising, promotional or cross-promotional content associated with a maker, proprietor or service-provider of VSRI depicted subject matter, wherein all VSRI is repeatedly visually perceptible and viewable at-a-glance.

A system for “horizontal” salting of database tables, text files, and data feeds utilizes a key field and character position within that field (the “Key Character”) and a Salting Field, which contains content that can legitimately be in one of at least two states without impacting the usefulness of the data. A unique identifier, which is assigned to the recipient of the data, is hidden within the data by using the variations of the states in the Salting Field, with the value of the Key Character identifying the position within the unique identifier. This type of salting is invisible to the recipient of the data file, does not alter the accuracy of the data, and can be made unique for a particular party receiving data files or unique for each data file.

A system for “horizontal” salting of database tables, text files, and data feeds utilizes a key field and character position within that field (the “Key Character”) and a Salting Field, which contains content that can legitimately be in one of at least two states without impacting the usefulness of the data. A unique identifier, which is assigned to the recipient of the data, is hidden within the data by using the variations of the states in the Salting Field, with the value of the Key Character identifying the position within the unique identifier. This type of salting is invisible to the recipient of the data file, does not alter the accuracy of the data, and can be made unique for a particular party receiving data files or unique for each data file.

In one embodiment, a computer-implemented method is disclosed. The method includes operating a downhole tool by transmitting first data to one or more surface processors in a telemetry sequence. The first data may include a flex word having a first identifier identifying a first payload, and the first data is transmitted using a synchronized time sequence. The method includes detecting, by the downhole tool, an operating condition that occurs while the downhole tool is downhole. Based on the operating condition, the method includes dynamically changing the flex word to comprise a second identifier identifying a second payload transmitted in second data in the telemetry sequence to the one or more surface processors, and the second data is transmitted in the telemetry sequence using the synchronized time sequence.

In one embodiment, a computer-implemented method is disclosed. The method includes operating a downhole tool by transmitting first data to one or more surface processors in a telemetry sequence. The first data may include a flex word having a first identifier identifying a first payload, and the first data is transmitted using a synchronized time sequence. The method includes detecting, by the downhole tool, an operating condition that occurs while the downhole tool is downhole. Based on the operating condition, the method includes dynamically changing the flex word to comprise a second identifier identifying a second payload transmitted in second data in the telemetry sequence to the one or more surface processors, and the second data is transmitted in the telemetry sequence using the synchronized time sequence.

A system for “horizontal” salting of database tables, text files, and data feeds utilizes a key field and character position within that field (the “Key Character”) and a Salting Field, which contains content that can legitimately be in one of at least two states without impacting the usefulness of the data. A unique identifier, which is assigned to the recipient of the data, is hidden within the data by using the variations of the states in the Salting Field to represent a binary 0 or 1, with the value of the Key Character identifying the bit position of the binary 0 or 1 within the unique identifier. This type of salting is invisible to the recipient of the data file, does not alter the accuracy of the data, and can be made unique for a particular party receiving data files or unique for each data file.

A system for “horizontal” salting of database tables, text files, and data feeds utilizes a key field and character position within that field (the “Key Character”) and a Salting Field, which contains content that can legitimately be in one of at least two states without impacting the usefulness of the data. A unique identifier, which is assigned to the recipient of the data, is hidden within the data by using the variations of the states in the Salting Field to represent a binary 0 or 1, with the value of the Key Character identifying the bit position of the binary 0 or 1 within the unique identifier. This type of salting is invisible to the recipient of the data file, does not alter the accuracy of the data, and can be made unique for a particular party receiving data files or unique for each data file.

Methods, systems, and devices for multiple concurrent modulation schemes in a memory system are described. Techniques are provided herein to communicate data using a modulation scheme having at least three levels and using a modulation scheme having at least two levels within a common system or memory device. Such communication with multiple modulation schemes may be concurrent. The modulated data may be communicated to a memory die through distinct signal paths that may correspond to a particular modulation scheme. An example of a modulation scheme having at least three levels may be pulse amplitude modulation (PAM) and an example of a modulation scheme having at least two levels may be non-return-to-zero (NRZ).

Methods, systems, and apparatus, including computer programs encoded on computer storage media, for neural translation systems with rare word processing. One of the methods is a method training a neural network translation system to track the source in source sentences of unknown words in target sentences, in a source language and a target language, respectively and includes deriving alignment data from a parallel corpus, the alignment data identifying, in each pair of source and target language sentences in the parallel corpus, aligned source and target words; annotating the sentences in the parallel corpus according to the alignment data and a rare word model to generate a training dataset of paired source and target language sentences; and training a neural network translation model on the training dataset.