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Type de document
Collection spécifique
Auteur
- Carrano, Matthew, T. (5)
- Hutchinson, John R. (3)
- Moreno, Karen (3)
- Valderrabano, Victor (3)
- Bourauel, Christoph (2)
- Currie, Philip J (2)
- Eliades, Theodore (2)
- Jäger, Andreas (2)
- Keilig, Ludger (2)
- Lockley, Martin G (2)
- Matsukawa, Masaki (2)
- Norman, David (2)
- Papadopoulou, Konstantina (2)
- Wilson, Jeffrey A. (2)
- Albayrak, Ismail (1)
- Alexander, R. McNeill (1)
- Allen, Vivian (1)
- Armbruster, G. (1)
- Arndt, Anton (1)
- Asgeirsson, Daphne (1)
- Averianov, Alexander O. (1)
- Baur, B. (1)
- Bennett, Matthew R (1)
- Binggeli, Tatjana (1)
- Bloesch, Michael (1)
- Bochaton-Piallat, Marie-Luce (1)
- Boesiger, Peter (1)
- Boulic, Ronan (1)
- Brei-Thoma, Pascale (1)
- Broschinski, Annette (1) Plus Moins
Domaine
Mot clé
- Biomechanics (3)
- Atomic force microscopy (2)
- Gait (2)
- Locomotion (2)
- Parkinson's disease (2)
- $$C_{d - FPL}$$ C d - F P L : Drag coefficient of laminar flat plate flow (1)
- $$C_{d - FPT}$$ C d - F P T : Drag coefficient of turbulent flat plate flow (1)
- $$C_{xy}$$ C x y : Covariance function (1)
- $$F_{m}$$ F m : Total mean drag force (i.e., tip+leaf) (1)
- $$F_{t}$$ F t : Mean drag force acting on the rod tip (1)
- $$MR_{{\hat{F}_{m} u_{d} }}$$ M R F ^ m u d : Average of maximum cross-correlation coefficients between drag force and downstream velocity (1)
- $$MR_{{u_{a} \hat{F}_{m} }}$$ M R u a F ^ m : Average of maximum cross-correlation coefficients between approach velocity and drag force (1)
- $$MR_{{u_{a} u_{d} }}$$ M R u a u d : Average of maximum cross-correlation coefficients between approach velocity and downstream velocity (1)
- $$R_{xy}$$ R x y : Cross-correlation function (1)
- $$R_{{\hat{F}_{m} U_{d} }}$$ R F ^ m U d : Cross-correlation function between drag force and downstream velocity (1)
- $$R_{{u_{a} \hat{F}_{m} }}$$ R u a F ^ m : Cross-correlation function between approach velocity and drag force (1)
- $$R_{{u_{a} u_{d} }}$$ R u a u d : Cross-correlation function between approach and downstream velocities (1)
- $$S_{{\hat{F}_{m} }}$$ S F ^ m : Power spectral density of drag force (1)
- $$S_{{u_{a} }}$$ S u a : Power spectral density of approach velocity (1)
- $$S_{{u_{d} }}$$ S u d : Power spectral density of downstream velocity (1)
- $$\Delta z$$ Δ z : Leaf ridge height (1)
- $$\delta$$ δ : Viscous sublayer height (1)
- $$\delta^{ + }$$ δ + : Normalised height of the viscous sublayer (1)
- $$\hat{F}_{m}$$ F ^ m : Instantaneous total drag force (i.e., tip+leaf) (1)
- $$\hat{F}_{t}$$ F ^ t : Instantaneous drag force acting at the rod tip (1)
- $$\overline{{z^{ + } }}$$ z + ¯ : Average $$z^{ + }$$ z + (1)
- $$\rho$$ ρ : Fluid density (1)
- $$\sigma_{d}$$ σ d : Standard deviation of drag force (1)
- $$\sigma_{m}^{2}$$ σ m 2 : Total variance of drag force (1)
- $$\sigma_{t}^{2}$$ σ t 2 : Variance related to the rod tip (1) Plus Moins