Hüftmuskulatur
Abbildung 1: Anatomical scheme of Mm. coxae (flexors, extensors)


Keywords: Anatomie,  Extensor,  Flexor,  Graphische Darstellung,  Hüfte,  Mineralstoffwechsel,  Muskulatur

Hüftmuskulatur
Abbildung 2: Biomechanical scheme of force resolution in muscular balance: Q = the force vector, which simulates the action of the weight of the upper part of the body on articulatio and mm. coxae. Force Q resolutes into force F1 acting on flexors and F2 acting on extensors. F1 = the force vector transfered into flexors. F2 = the force vector transfered into extensors.


Keywords: Anatomie,  Extensor,  Flexor,  Graphische Darstellung,  Hüfte,  Kraft,  Mineralstoffwechsel,  Muskulatur,  Vektor

Hüftmuskulatur
Abbildung 3: Biomechanical scheme of force resolution in muscular dysbalance. Tone of flexors is greater than of extensors. F1' = the force vector transfered into flexors. F2' = the force vector transfered into extensors.


Keywords: Anatomie,  Extensor,  Flexor,  Graphische Darstellung,  Hüfte,  Kraft,  Mineralstoffwechsel,  Muskulatur,  Vektor

Hüftmuskulatur
Abbildung 4: Simulation of the influence of life load (blow, impact, fall) on resultant force in muscular dysbalance. P1 = the force vector of life load (blow, impact, fall). R = the resultant force of a vector of Q force and P1 force. F1'' = the force vector transfered into flexors. F2'' = the force vector transfered into extensors.


Keywords: Anatomie,  Extensor,  Flexor,  Graphische Darstellung,  Hüfte,  Kraft,  Mineralstoffwechsel,  Muskulatur,  Vektor

Hüftmuskulatur
Abbildung 5: Influence of different direction of application of impact forces P1, P2 and P3 on the resolution of forces (F1'', F2'') in dysbalanced flexors and extensors.


Keywords: Anatomie,  Extensor,  Flexor,  Graphische Darstellung,  Hüfte,  Kraft,  Mineralstoffwechsel,  Muskulatur,  Vektor