about
Lifetime of Surface Features and Stellar Rotation: A Wavelet Time-Frequency ApproachWavelet-based correlations of skin temperature and blood flow oscillations.Quantifying the correlation between photoplethysmography and laser Doppler flowmetry microvascular low-frequency oscillations.Skin blood flow and temperature oscillations during cold pressor test.Relationship of oscillating and average components of laser Doppler flowmetry signal.Local Heating Test for Detection of Microcirculation Abnormalities in Patients with Diabetes-Related Foot Complications.The screw dynamo in a thick torusInduction, helicity, and alpha effect in a toroidal screw flow of liquid gallium.Screw dynamo in a time-dependent pipe flow.Lymphocyte Nucleus Reconstruction via Wavelet Tomography.Detection of Endothelial Dysfunction Using Skin Temperature Oscillations Analysis During Local Heating in Patients With Peripheral Arterial Disease.Wavelet Analysis of Stellar Chromospheric Activity VariationsMulti-scale radio-infrared correlations in M 31 and M 33: The role of magnetic fields and star formationCombining Faraday Tomography and Wavelet AnalysisInductive System for Reliable Magnesium Level Detection in a Titanium Reduction ReactorNumerical simulations of convection in the titanium reduction reactorThermal convection of liquid metal in the titanium reduction reactorMagnetic arms of NGC 6946 traced in Faraday cubes at low radio frequenciesJoint inverse cascade of magnetic energy and magnetic helicity in MHD turbulenceWavelet analysis of solar activity recorded by sunspot groupsMagnetic field structures of galaxies derived from analysis of Faraday rotation measures, and perspectives for the SKAMagnetic and optical spiral arms in the galaxy NGC 6946Structures in the rotation measure skyScaling and correlation analysis of galactic imagesAnharmonic and standing dynamo waves: theory and observation of stellar magnetic activityTime-spectra of chromospheric activity of old solar-type stars: detection of rotational signals from double wavelet analysisWavelet tomography of the Galactic magnetic field. I. The methodAnalysis of spiral arms using anisotropic wavelets: gas, dust and magnetic fields in M 51Wavelet-based Faraday rotation measure synthesisFaraday rotation measure synthesis for magnetic fields of galaxiesRecognizing magnetic structures by present and future radio telescopes with Faraday rotation measure synthesisMagnetic and gaseous spiral arms in M83Statistical mechanics of shell models for two-dimensional turbulenceScaling properties of a class of shell modelsScaling properties of numerical two-dimensional turbulenceLarge- and small-scale interactions and quenching in an alpha2-dynamoDirect measurement of effective magnetic diffusivity in turbulent flow of liquid sodiumTurbulent viscosity and turbulent magnetic diffusivity in a decaying spin-down flow of liquid sodiumHindered Energy Cascade in Highly Helical Isotropic TurbulenceEarly differential diagnosis of the severity of acute pancreatitis
P50
Q29028914-51C22EC5-E09D-422E-9CA2-E83C34BD4BC3Q33344812-4DB3DBE2-3988-4A27-B772-40B90F6B75D1Q35575787-DC06142D-5E9C-4DAE-9A7C-377B02CF87CFQ35887214-D10B7AA2-37E3-4CCB-AF90-7EA7812DED09Q36109322-57557E21-CF16-4518-8C58-BC120789BC16Q38903317-77B78484-C77B-4A91-880D-16084CD510EDQ42883329-60FC22FB-BC74-4D03-8219-2FE1BCB5E7A2Q51198089-7B91CDEE-22F4-4A1D-BF07-CAAF855918A4Q52015073-8408697f-40a7-4ec0-4de6-1d3c90a7a3d3Q52210449-42FA5A13-16C2-4B0F-B68F-D9EF0FF22CE7Q53101379-469C6403-C3F4-4442-ACC7-71FAEB3962C7Q55880297-71C2AEA3-2C4C-4E09-B92D-2BFBC49ED829Q58915925-05B20F43-0CDB-4139-AB65-7B8E8ED93D37Q59094786-C4AD19F3-4A49-4F22-BEE6-FFA2032DCA67Q61953784-172E54F0-1C2C-4334-8050-71CB507663B0Q61953805-5F811F4B-3699-4846-87A1-9DBEE9955A87Q61953831-FE4FEA9A-6C2C-4338-AC82-529B186BA06EQ62779760-b49e5a91-485b-ba29-8dfd-d3a8e830d512Q68174424-D60AD161-9F3C-488C-B9A3-86043003CA84Q68500772-F041D5F5-4CE8-479E-9F92-5FC6221BD009Q68672142-670FE87C-C294-4137-B6BB-E348E38F82EBQ68695474-B0D69C3E-6D8B-4265-A7E3-8238986A75D8Q68697079-4417F712-72D4-45B4-BD79-1F07794984F7Q68698013-266ED041-F08D-4192-89A4-835E945ACFBBQ68711486-8FFBE567-6FE6-4073-AEA7-D95C4C67A0A7Q68786784-DB309304-FD5E-4FE3-AC66-E22D0F30E5E2Q68844258-60EBCCDA-D9FE-4D3E-9110-EB0A1A7F880EQ68853530-22723412-66AC-4975-A678-E1DA9888CFE8Q68989620-A3D34EAA-B4BA-40F7-9F24-326A38AB401CQ69018954-30CDDA3A-8AA4-4965-A037-D7954E5C26A2Q69026436-B762D1EE-0988-47C1-9B35-61FD3342FE53Q69111410-242998B2-D4AF-4701-86BE-FEDF0D032589Q78066501-19886B99-B52A-4295-9C77-37F642626805Q78069952-0526A0F3-0096-4B05-AEE9-07120B8E04E6Q78072763-08AC6275-58AA-484E-BF5E-C5028D383C51Q79723833-9CCBEE2C-700A-478D-A982-83A30F2CA45AQ83187604-172DC2E4-7072-4678-9672-E68C91C0512CQ83596898-CB8F161B-E2E1-42CC-A264-230528CFD1C1Q86939262-3878E7B1-A03D-42EB-82E3-CC5361B5BE06Q88846794-B43BCA76-7E92-493F-8516-BADD4B4592F8
P50
description
Russian physicist
@en
Russisch natuurkundige
@nl
fisiceoir Rúiseach
@ga
russischer Astrophysiker und Physiker
@de
российский физик
@ru
name
Peter Frick
@ast
Peter Frick
@de
Peter Frick
@en
Peter Frick
@es
Peter Frick
@nl
Пётр Готлобович Фрик
@ru
type
label
Peter Frick
@ast
Peter Frick
@de
Peter Frick
@en
Peter Frick
@es
Peter Frick
@nl
Пётр Готлобович Фрик
@ru
altLabel
Pjotr Frik
@de
Pjotr Gotlobowitsch Frik
@de
Pyotr Frik
@en
Pyotr Gotlobovich Frik
@en
Петр Фрик
@ru
Пётр Фрик
@ru
Фрик, Пётр Готлобович
@ru
prefLabel
Peter Frick
@ast
Peter Frick
@de
Peter Frick
@en
Peter Frick
@es
Peter Frick
@nl
Пётр Готлобович Фрик
@ru
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7102834014
P1559
Пётр Готлобович Фрик
@ru