Abstract: Disclosed are novel bioremediation formulations and inocula for formulation of bioremediation formulations. The formulations of the present disclosure comprise viable microorganisms of the species Paenibacillus xylanexedens, Pseudomonas fluorescens, Bacillus safensis, Streptomyces griseus, Micrococcus luteus, and Bacillus megaterium and can be used to degrade glyphosate residue associated with a substrate contaminated with glyphosate, and thereby remedially treat the substrate. Related methods are also disclosed.

Abstract: Apparatuses and methods for performing a data bus inversion operation (DBI) are described. An example apparatus includes a DBI circuit configured to, in parallel, determine preliminary DBI bits based on a block of data. Individual preliminary DBI bits are associated with respective sub-blocks of the block of data. The DBI circuit is further configured to serially determine DBI bits based on the preliminary DBI bits. Individual ones of the DBI bits are associated with respective ones of the sub-blocks. The DBI circuit is further configured to invert bits of individual sub-blocks responsive to the respective associated DBI bits having a particular logical value to provide DBI data. The apparatus further includes data outputs configured to serially output sub-blocks of the DBI data and the DBI bits.

Abstract: Apparatuses and methods for performing a data bus inversion operation (DBI) are described. An example apparatus includes a DBI circuit configured to, in parallel, determine preliminary DBI bits based on a block of data. Individual preliminary DBI bits are associated with respective sub-blocks of the block of data. The DBI circuit is further configured to serially determine DBI bits based on the preliminary DBI bits. Individual ones of the DBI bits are associated with respective ones of the sub-blocks. The DBI circuit is further configured to invert bits of individual sub-blocks responsive to the respective associated DBI bits having a particular logical value to provide DBI data. The apparatus further includes data outputs configured to serially output sub-blocks of the DBI data and the DBI bits.

Abstract: Examples of command latency systems and methods are described. In some examples, phase information associated with a received command signal is stored, a received command signal is propagated through a reduced clock flip-flop pipeline and the delayed command signal is combined with the stored phase information. The reduced clock flip-flop pipeline may use a clock having a lower frequency than that used to issue the command signal. Accordingly, fewer flip-flops may be required.

Abstract: Examples of command latency systems and methods are described. In some examples, phase information associated with a received command signal is stored, a received command signal is propagated through a reduced clock flip-flop pipeline and the delayed command signal is combined with the stored phase information. The reduced clock flip-flop pipeline may use a clock having a lower frequency than that used to issue the command signal. Accordingly, fewer flip-flops may be required.

Abstract: Examples of command latency systems and methods are described. In some examples, phase information associated with a received command signal is stored, a received command signal is propagated through a reduced clock flip-flop pipeline and the delayed command signal is combined with the stored phase information. The reduced clock flip-flop pipeline may use a clock having a lower frequency than that used to issue the command signal. Accordingly, fewer flip-flops may be required.

Abstract: Examples of command latency systems and methods are described. In some examples, phase information associated with a received command signal is stored, a received command signal is propagated through a reduced clock flip-flop pipeline and the delayed command signal is combined with the stored phase information. The reduced clock flip-flop pipeline may use a clock having a lower frequency than that used to issue the command signal. Accordingly, fewer flip-flops may be required.

Abstract: An improved helmet padding includes a multi-layered liner including an innermost layer consisting of a comfort liner designed to engage the head of the user, and having an outer surface covered by an inner surface of a relatively low density foam layer. The relatively low density foam layer consists of a first region of relatively uniform thickness with an outer area from which a multiplicity of protuberances extend radially outwardly. The radially outward layer of the inventive padding consists of a layer of relatively high density foam. The outer layer includes a plurality of recesses corresponding to the protuberances of the inner layer and sized to snugly receive the conical protuberances therewithin. The outer surface of the outer foam layer is shaped and configured to engage the outer shell of a helmet in which it is installed.