157 research outputs found
A Method for SINS Alignment with Large Initial Misalignment Angles Based on Kalman Filter with Parameters Resetting
In the initial alignment process of strapdown inertial navigation system (SINS), large initial misalignment angles always bring nonlinear problem, which causes alignment failure when the classical linear error model and standard Kalman filter are used. In this paper, the problem of large misalignment angles in SINS initial alignment is investigated, and the key reason for alignment failure is given as the state covariance from Kalman filter cannot represent the true one during the steady filtering process. According to the analysis, an alignment method for SINS based on multiresetting the state covariance matrix of Kalman filter is designed to deal with large initial misalignment angles, in which classical linear error model and standard Kalman filter are used, but the state covariance matrix should be multireset before the steady process until large misalignment angles are decreased to small ones. The performance of the proposed method is evaluated by simulation and car test, and the results indicate that the proposed method can fulfill initial alignment with large misalignment angles effectively and the alignment accuracy of the proposed method is as precise as that of alignment with small misalignment angles
H∞ filter for flexure deformation and lever arm effect compensation in M/S INS integration
ABSTRACTOn ship, especially on large ship, the flexure deformation between Master (M)/Slave (S) Inertial Navigation System (INS) is a key factor which determines the accuracy of the integrated system of M/S INS. In engineering this flexure deformation will be increased with the added ship size. In the M/S INS integrated system, the attitude error between MINS and SINS cannot really reflect the misalignment angle change of SINS due to the flexure deformation. At the same time, the flexure deformation will bring the change of the lever arm size, which further induces the uncertainty of lever arm velocity, resulting in the velocity matching error. To solve this problem, a H∞ algorithm is proposed, in which the attitude and velocity matching error caused by deformation is considered as measurement noise with limited energy, and measurement noise will be restrained by the robustness of H∞ filter. Based on the classical “attitude plus velocity” matching method, the progress of M/S INS information fusion is simulated and compared by using three kinds of schemes, which are known and unknown flexure deformation with standard Kalman filter, and unknown flexure deformation with H∞ filter, respectively. Simulation results indicate that H∞ filter can effectively improve the accuracy of information fusion when flexure deformation is unknown but non-ignorable
Ionically-Driven Synthesis and Exchange Bias in MnN/MnN Heterostructures
Ferrimagnets have received renewed attention as a promising platform for
spintronic applications. Of particular interest is the Mn4N from the
-phase of the manganese nitride as an emergent rare-earth-free
spintronic material due to its perpendicular magnetic anisotropy, small
saturation magnetization, high thermal stability, and large domain wall
velocity. We have achieved high-quality (001)-ordered MnN thin film by
sputtering Mn onto -phase MnN seed layers on Si substrates.
As the deposited Mn thickness varies, nitrogen ion migration across the
MnN/Mn layers leads to a continuous evolution of the layers to
MnN/MnN/MnN, MnN/MnN, and eventually
MnN alone. The ferrimagnetic MnN indeed exhibits perpendicular
magnetic anisotropy, and forms via a nucleation-and-growth mechanism. The
nitrogen ion migration is also manifested in a significant exchange bias, up to
0.3 T at 5 K, due to the interactions between ferrimagnetic MnN and
antiferromagnetic MnN and MnN. These results demonstrate a
promising all-nitride magneto-ionic platform with remarkable tunability for
device applications.Comment: 21 pages, 5 figures, 7 pages of supplementary material with 5 figure
Two amide glycosides from Portulaca oleracea L. and its bioactivities
International audienc
Hydroxide-based magneto-ionics: electric-field control of reversible paramagnetic-to-ferromagnetic switch in -Co(OH) films
Magneto-ionics has emerged as a promising approach to manipulate magnetic
properties, not only by drastically reducing power consumption associated with
electric current based devices but also by enabling novel functionalities. To
date, magneto-ionics have been mostly explored in oxygen-based systems, while
there is a surge of interests in alternative ionic systems. Here we demonstrate
highly effective hydroxide-based magneto-ionics in electrodeposited
-Co(OH) films. The -Co(OH), which is a room
temperature paramagnet, is switched to ferromagnetic after electrolyte gating
with a negative voltage. The system is fully, magnetically reversible upon
positive voltage application. The origin of the reversible
paramagnetic-to-ferromagnetic transition is attributed to the ionic diffusion
of hydroxyl groups, promoting the formation of metallic cobalt ferromagnetic
regions. Our findings demonstrate one of the lowest turn-on voltages reported
for propylene carbonate gated experiments. By tuning the voltage magnitude and
sample area we demonstrate that the speed of the induced ionic effect can be
drastically enhanced.Comment: 27 pages, 4 figures. Supplementary Information: 6 pages with 3
figure
Aromatic Glucosinolate Biosynthesis Pathway in Barbarea vulgaris and its Response to Plutella xylostella Infestation
The inducibility of the glucosinolate resistance mechanism is an energy-saving strategy for plants, but whether induction would still be triggered by glucosinolate-tolerant Plutella xylostella (diamondback moth, DBM) after a plant had evolved a new resistance mechanism (e.g. saponins in Barbara vulgaris) was unknown. In B. vulgaris, aromatic glucosinolates derived from homo-phenylalanine are the dominate glucosinolates, but their biosynthesis pathway are unclear in this plant. In this study, we used G-type (pest-resistant) and P-type (pest-susceptible) B. vulgaris to compare glucosinolate levels and the expression profiles of their biosynthesis genes before and after infestation by DBM larvae. Two different stereoisomers of hydroxylated aromatic glucosinolates are dominant in G- and P-type B. vulgaris, respectively, and are induced by DBM. The transcripts of genes in the glucosinolate biosynthesis pathway and their corresponding transcription factors were identified from an Illumina dataset of G- and P-type B. vulgaris. Many genes involved or potentially involved in glucosinolate biosynthesis were induced in both plant types. The expression patterns of six DBM induced genes were validated by quantitative PCR (qPCR), while six long-fragment genes were validated by molecular cloning. The core structure biosynthetic genes showed high sequence similarities between the two genotypes. In contrast, the sequence identity of two apparent side chain modification genes, the SHO gene in the G-type and the RHO in P-type plants, showed only 77.50% identity in coding DNA sequences and 65.48% identity in deduced amino acid sequences. The homology to GS-OH in Arabidopsis, DBM induction of the transcript and a series of qPCR and glucosinolate analyses of G-type, P-type and F1 plants indicated that these genes control the production of S and R isomers of 2-hydroxy-2-phenylethyl glucosinolate. These glucosinolates were significantly induced by P. xylostella larvae in both the susceptiple P-type and the resistant G-type, even though saponins are the main DBM-resistance causing metabolites in G-type plants. Indol-3-ylmethylglucosinolate was induced in the G-type only. These data will aid our understanding of the biosynthesis and induction of aromatic glucosinolates at the molecular level and also increase our knowledge of the complex mechanisms underpinning defense induction in plants
Develop a 3D Neurological Disease Model of Human Cortical Glutamatergic Neurons Using Micropillar-Based Scaffolds
Establishing an effective three-dimensional (3D) in vitro culture system to better model human neurological diseases is desirable, since the human brain is a 3D structure. Here, we demonstrated the development of a polydimethylsiloxane (PDMS) pillar-based 3D scaffold that mimicked the 3D microenvironment of the brain. We utilized this scaffold for the growth of human cortical glutamatergic neurons that were differentiated from human pluripotent stem cells. In comparison with the 2D culture, we demonstrated that the developed 3D culture promoted the maturation of human cortical glutamatergic neurons by showing significantly more MAP2 and less Ki67 expression. Based on this 3D culture system, we further developed an in vitro disease-like model of traumatic brain injury (TBI), which showed a robust increase of glutamate-release from the neurons, in response to mechanical impacts, recapitulating the critical pathology of TBI. The increased glutamate-release from our 3D culture model was attenuated by the treatment of neural protective drugs, memantine or nimodipine. The established 3D in vitro human neural culture system and TBI-like model may be used to facilitate mechanistic studies and drug screening for neurotrauma or other neurological diseases
Nitrogen-Based Magneto-Ionic Manipulation of Exchange Bias in CoFe/MnN Heterostructures
Electric field control of the exchange bias effect across
ferromagnet/antiferromagnet (FM/AF) interfaces has offered exciting potentials
for low-energy-dissipation spintronics. In particular, the solid state
magneto-ionic means is highly appealing as it may allow reconfigurable
electronics by transforming the all-important FM/AF interfaces through ionic
migration. In this work, we demonstrate an approach that combines the
chemically induced magneto-ionic effect with the electric field driving of
nitrogen in the Ta/CoFe/MnN/Ta structure to electrically
manipulate exchange bias. Upon field-cooling the heterostructure, ionic
diffusion of nitrogen from MnN into the Ta layers occurs. A significant
exchange bias of 618 Oe at 300 K and 1484 Oe at 10 K is observed, which can be
further enhanced after a voltage conditioning by 5% and 19%, respectively. This
enhancement can be reversed by voltage conditioning with an opposite polarity.
Nitrogen migration within the MnN layer and into the Ta capping layer cause the
enhancement in exchange bias, which is observed in polarized neutron
reflectometry studies. These results demonstrate an effective nitrogen-ion
based magneto-ionic manipulation of exchange bias in solid-state devices.Comment: 28 pages, 4 figures; supporting information: 17 pages, 11 figure
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