I. I. Chapitre, . Matériel, and I. I. Méthodes, A Les instruments de mesure de la dose absorbée

, Chambre d'ionisation à cavité d'air

. .. Diode-en-silicium,

.. .. Le,

. .. L'électromètre,

. .. Incertitudes-de-mesure,

. .. Le-film-radiochromique,

. .. Caractéristiques-générales,

.. .. Le-scanner-À-plat,

, Étude de l'influence du scanner

, Transport des électrons et positons : diffusion multiple

.. .. Méthodes-d'échantillonnage,

.. .. Incertitude-d'un-code-de-monte-carlo,

, Dose absorbée simulée dans l'eau vs dose absorbée simulée dans le milieu, p.66

. C. Ii and P. .. Le-code-monte-carlo,

.. .. Le-choix-du-code,

L. Fichiers-d'entrées and .. .. ,

.. .. Modèles,

. .. Temps-de-calcul,

. Iv and .. .. La-radiothérapie-stéréotaxique,

. A. Iv,

.. .. Occlusion-d'une-partie-de-la-source,

, Manque d'équilibre électronique latéral et détecteurs non équivalents eau, vol.122

, Variation du spectre en énergie et détecteurs non équivalents eau

. .. Positionnement-du-détecteur,

. A. Iv, 3 Le formalisme AIEA pour la mesure du débit de référence

. Iv, . Matériels, and . .. Méthodes,

. B. Iv,

. B. Iv,

. B. Iv, 3 Conditions d'irradiations et de mesures

.. .. Mesure,

.. .. Iv.b-;-monte-carlo, , vol.4

. C. Iv,

, Chambres d'ionisation à cavité d'air

.. .. Diodes,

.. .. Microdiamond,

E. .. Film-radiochromique,

V. Résultats and .. .. ,

V. C. ,

.. .. Peneasy-vs-film-radiochromique,

. .. Peneasy-vs-emc,

.. .. Peneasy-vs-film-radiochromique,

. .. Peneasy-vs-emc,

V. .. Conclusion,

, Comme expliqué ci-dessus, l'électron est arrêté d'un voxel uniquement si le rapport des pouvoirs d'arrêt linéiques entre voxels voisins dépasse 1,5. Varian annonce une précision du modèle de transport (MMC)

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