| P50 | author | Lisa Fauci | Q20979251 |
| P2093 | author name string | Chia-Yu Hsu | |
| | Eric D Tytell | |
| P2860 | cites work | The motor infrastructure: from ion channels to neuronal networks | Q21147050 |
| | Neuronal control of swimming behavior: Comparison of vertebrate and invertebrate model systems | Q30428624 |
| | Sensory feedback mechanism underlying entrainment of central pattern generator to mechanical resonance | Q30439197 |
| | Formal analysis of resonance entrainment by central pattern generator | Q30445341 |
| | Interactions between internal forces, body stiffness, and fluid environment in a neuromechanical model of lamprey swimming | Q30497489 |
| | Nonlinear muscles, passive viscoelasticity and body taper conspire to create neuromechanical phase lags in anguilliform swimmers | Q33366581 |
| | Dynamic sensorimotor interactions in locomotion | Q34478772 |
| | Rather than resonance, flapping wing flyers may play on aerodynamics to improve performance | Q34794314 |
| | Wake structures behind a swimming robotic lamprey with a passively flexible tail | Q35669662 |
| | Complexities and uncertainties of neuronal network function | Q36428334 |
| | Built for rowing: frog muscle is tuned to limb morphology to power swimming | Q36904268 |
| | Organisation of the spinal central pattern generators for locomotion in the salamander: biology and modelling. | Q36963266 |
| | On the evolution of the wake structure produced by a low-aspect-ratio pitching panel | Q37336573 |
| | The notochord of hagfish Myxine glutinosa: visco-elastic properties and mechanical functions during steady swimming | Q39188145 |
| | Advantages of rhythmic movements at resonance: minimal active degrees of freedom, minimal noise, and maximal predictability | Q40745783 |
| | Effects of three-dimensionality on thrust production by a pitching panel | Q42122372 |
| | Synaptic effects of intraspinal stretch receptor neurons mediating movement-related feedback during locomotion | Q43595222 |
| | X-ray motion analysis of the vertebral column during the startle response in striped bass, Morone saxatilis | Q43682808 |
| | Rostral versus caudal differences in mechanical entrainment of the lamprey central pattern generator for locomotion | Q46767806 |
| | Intraspinal stretch receptor neurons mediate different motor responses along the body in lamprey | Q46776077 |
| | Resonant hopping of a robot controlled by an artificial neural oscillator | Q47815693 |
| | Eel migration to the Sargasso: remarkably high swimming efficiency and low energy costs. | Q48952767 |
| | A comparison of resonance tuning with positive versus negative sensory feedback. | Q51032865 |
| | Energy efficient and robust rhythmic limb movement by central pattern generators. | Q51304940 |
| | Building a robotic link between muscle dynamics and hydrodynamics. | Q51555205 |
| | Functions of fish skin: flexural stiffness and steady swimming of longnose gar, Lepisosteus osseus | Q51580375 |
| | Predicting force generation by lamprey muscle during applied sinusoidal movement using a simple dynamic model. | Q52245348 |
| | DYNAMICS OF TRANSVERSELY VIBRATING BEAMS USING FOUR ENGINEERING THEORIES | Q56067382 |
| | A collisional model of the energetic cost of support work qualitatively explains leg sequencing in walking and galloping, pseudo-elastic leg behavior in running and the walk-to-run transition | Q57525665 |
| | The immersed boundary method | Q59619665 |
| | Marginal Cells in the Spinal Cord of Four Elasmobranchs(Torpedo marmorata, T. torpedo, Raja undulataandScyliorhinus canicula):Evidence for Homology with Lamprey lntraspinal Stretch Receptor Neurons | Q59649776 |
| | Marginal neurons in the urodele spinal cord and the associated denticulate ligaments | Q67684689 |
| | An ultrastructural study of the marginal nucleus, the intrinsic mechanoreceptor of the snake's spinal cord | Q69736253 |
| | Features of entrainment of spinal pattern generators for locomotor activity in the lamprey spinal cord | Q69816903 |
| | Activities of identified interneurons, motoneurons, and muscle fibers during fictive swimming in the lamprey and effects of reticulospinal and dorsal cell stimulation | Q70375362 |
| | The edge cell, a possible intraspinal mechanoreceptor | Q71253465 |
| | Coupling the neural and physical dynamics in rhythmic movements | Q71679660 |
| | Neural control of rhythmic arm movements | Q73186417 |
| | Fine structural evidence of mechanoreception in spinal lumbosacral accessory lobes of pigeons | Q73731783 |
| | Dynamics and energetics of scallop locomotion | Q73753415 |
| | Mechanical control of swimming speed: stiffness and axial wave form in undulating fish models | Q73754179 |
| | Muscle strain histories in swimming milkfish in steady and sprinting gaits | Q77939079 |
| | Force transmission via axial tendons in undulating fish: a dynamic analysis | Q78673538 |
| | Resonance Tuning in Rhythmic Arm Movements | Q78798931 |
| | Frequency tuning in animal locomotion | Q82223224 |
| P433 | issue | 1 | |
| P304 | page(s) | 48-56 | |
| P577 | publication date | 2013-12-21 | |
| P1433 | published in | Zoology | Q8074125 |
| P1476 | title | The role of mechanical resonance in the neural control of swimming in fishes | |
| P478 | volume | 117 | |