1,905 research outputs found
Compact graphene mode-locked wavelength-tunable erbium-doped fiber lasers: from all anomalous dispersion towards all normal dispersion
Soliton operation and soliton wavelength tuning of erbium-doped fiber lasers
mode locked with atomic layer graphene was experimentally investigated under
various cavity dispersion conditions. It was shown that not only wide range
soliton wavelength tuning but also soltion pulse width variation could be
obtained in the fiber lasers. Our results show that the graphene mode locked
erbium-doped fiber lasers provide a compact, user friendly and low cost
wavelength tunable ultrahsort pulse source
Bitsliced Implementations of the PRINCE, LED and RECTANGLE Block Ciphers on AVR 8-bit Microcontrollers
Due to the demand for low-cost cryptosystems from industry, there spring up a lot of lightweight block ciphers which are excellent for some different implementation features. An innovative design is the block cipher PRINCE. To meet the requirement for low-latency and instantaneously encryption, NXP Semiconductors and its academic partners cooperate and design the low-latency block cipher PRINCE. Another good example is the block cipher LED which is very compact in hardware, and whose designers also aim to maintain a reasonable software performance. In this paper, we demonstrate how to achieve high software performance of these two ciphers on the AVR 8-bit microcontrollers using bitslice technique. Our bitsliced implementations speed up the execution of these two ciphers several times with less memory usage than previous work. In addition to these two nibble-oriented ciphers, we also evaluate the software performance of a newly proposed lightweight block cipher RECTANGLE, whose design takes bitslicing into consider. Our results show that RECTANGLE has very high performance ranks among the existing block ciphers on 8-bit microcontrollers in the real-world usage scenarios
(Acetato-κO)(2-{[2-(dimethylamino)ethylimino](phenyl)methyl}-5-methoxyphenolato-κ3 N,N′,O 1)copper(II)
The CuII atom in the title complex, [Cu(C18H21N2O2)(C2H3O2)], is tetracoordinated by two N atoms and two O atoms, of which one O atom is attributed to the acetate group and the other atoms are from the tridentate salicylideneiminate ligand, forming a slight distorted square-planar environment. The other acetate O atom exhibits a very weak intramolecular interaction toward the Cu atom, the Cu—O distance of 2.771 (2) Å being shorter than the van der Waals radii for Cu and O atoms (2.92 Å). Furthermore, there are weak intermolecular interactions, in which the bonding O atom of the acetate group can bridge to the Cu atom of another complex, and the distance of 2.523 (2) Å is about 0.4 Å shorter than the van der Waals Cu—O distance in other crystal structures
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Modulating Linker Composition of Haptens Resulted in Improved Immunoassay for Histamine.
Histamine (HA) is an important food contaminant generated during food fermentation or spoilage. However, an immunoassay for direct (derivatization free) determination of HA has rarely been reported due to its small size to induce the desired antibodies by its current hapten-protein conjugates. In this work, despite violating the classical hapten design criteria which recommend introducing a linear aliphatic (phenyl free) linker into the immunizing hapten, a novel haptens, HA-245 designed and synthesized with a phenyl-contained linker, exhibited significantly enhanced immunological properties. Thus, a quality-improved monoclonal antibody (Mab) against HA was elicited by its hapten-carrier conjugates. Then, as the linear aliphatic linker contained haptens, Hapten B was used as linker-heterologous coating haptens to eliminate the recognition of linker antibodies. Indirect competitive ELISA (ic-ELISA) was developed with a 50% inhibition concentration (IC50) of 0.21 mg/L and a limit of detection (LOD) of 0.06 mg/L in buffer solution. The average recoveries of HA from spiked food samples for this ic-ELISA ranged from 84.1% and 108.5%, and the analysis results agreed well with those of referenced LC-MS/MS. This investigation not only realized derivatization-free immunoassay for HA, but also provided a valuable guidance for hapten design and development of immunoassay for small molecules
Point-Voxel Absorbing Graph Representation Learning for Event Stream based Recognition
Considering the balance of performance and efficiency, sampled point and
voxel methods are usually employed to down-sample dense events into sparse
ones. After that, one popular way is to leverage a graph model which treats the
sparse points/voxels as nodes and adopts graph neural networks (GNNs) to learn
the representation for event data. Although good performance can be obtained,
however, their results are still limited mainly due to two issues. (1) Existing
event GNNs generally adopt the additional max (or mean) pooling layer to
summarize all node embeddings into a single graph-level representation for the
whole event data representation. However, this approach fails to capture the
importance of graph nodes and also fails to be fully aware of the node
representations. (2) Existing methods generally employ either a sparse point or
voxel graph representation model which thus lacks consideration of the
complementary between these two types of representation models. To address
these issues, in this paper, we propose a novel dual point-voxel absorbing
graph representation learning for event stream data representation. To be
specific, given the input event stream, we first transform it into the sparse
event cloud and voxel grids and build dual absorbing graph models for them
respectively. Then, we design a novel absorbing graph convolutional network
(AGCN) for our dual absorbing graph representation and learning. The key aspect
of the proposed AGCN is its ability to effectively capture the importance of
nodes and thus be fully aware of node representations in summarizing all node
representations through the introduced absorbing nodes. Finally, the event
representations of dual learning branches are concatenated together to extract
the complementary information of two cues. The output is then fed into a linear
layer for event data classification
Behavioral/Cognitive Acute and Long-Term Suppression of Feeding Behavior by POMC Neurons in the Brainstem and Hypothalamus, Respectively
POMC-derived melanocortins inhibit food intake. In the adult rodent brain, POMC-expressing neurons are located in the arcuate nucleus (ARC) and the nucleus tractus solitarius (NTS), but it remains unclear how POMC neurons in these two brain nuclei regulate feeding behavior and metabolism differentially. Using pharmacogenetic methods to activate or deplete neuron groups in separate brain areas, in the present study, we show that POMC neurons in the ARC and NTS suppress feeding behavior at different time scales. Neurons were activated using the DREADD (designer receptors exclusively activated by designer drugs) method. The evolved human M3-muscarinic receptor was expressed in a selective population of POMC neurons by stereotaxic infusion of Cre-recombinase–dependent, adenoassociated virus vectors into the ARC or NTS of POMC-Cre mice. After injection of the human M3-muscarinic receptor ligand clozapine-N-oxide (1 mg/kg, i.p.), acute activation of NTS POMC neurons produced an immediate inhibition of feeding behavior. In contrast, chronic stimulation was required for ARC POMC neurons to suppress food intake. Using adeno-associated virus delivery of the diphtheria toxin receptor gene, we found that diphtheria toxin–induced ablation of POMC neurons in the ARC but not the NTS, increased food intake, reduced energy expenditure, and ultimately resulted in obesity and metabolic and endocrine disorders. Our results reveal different behavioral functions of POMC neurons in the ARC and NTS, suggesting that POMC neurons regulate feeding and energy homeostasis by integrating long-term adiposity signals from the hypothalamus and short-term satiety signals from the brainstem
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