Proceedings of the International School of Physics "Enrico Fermi.", Volume 76N. Zanichelli, 1981 - Nuclear physics |
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Page 107
... equation with a time - dependent forcing function . Formula ( 26 ) then complicates to ( 31 ) 1 Co εμ + rar dr Ev + Q In addition , the arterial wall is elastic and pulsates under the arterial pressure pulse giving a more complicated ...
... equation with a time - dependent forcing function . Formula ( 26 ) then complicates to ( 31 ) 1 Co εμ + rar dr Ev + Q In addition , the arterial wall is elastic and pulsates under the arterial pressure pulse giving a more complicated ...
Page 116
... Equation ( 42 ) is the longitudinal equation , ( 43 ) is the transversal equation . Given the length of the segment , 1 , and the cross - sectional area , A , we can write ( 44 ) L = gl / A , R = yR ( Poise ) = 7 · 8ïnl / A2 . The ...
... Equation ( 42 ) is the longitudinal equation , ( 43 ) is the transversal equation . Given the length of the segment , 1 , and the cross - sectional area , A , we can write ( 44 ) L = gl / A , R = yR ( Poise ) = 7 · 8ïnl / A2 . The ...
Page 281
... equations are themselves gross simplifications , since oxygen reacts with heaemoglobin in blood , and general equations must take into account reaction velocity terms [ 2 ] . Just as the Schrödinger wave equation is central to classical ...
... equations are themselves gross simplifications , since oxygen reacts with heaemoglobin in blood , and general equations must take into account reaction velocity terms [ 2 ] . Just as the Schrödinger wave equation is central to classical ...
Contents
A R D THORNTON | 1 |
Physicists and clinicians | 5 |
The Fourier transform properties of an image | 12 |
Copyright | |
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alveolar amplitude analysis aorta aortic approximately arterial pressure arterial system attenuation value basilar membrane beam blood flow blood pressure C₁ capillary cardiac output circulation clinical cm³ CO₂ cochlea cochlear compartment compliance components computed tomography concentration constant counting rate cross-section cuff decrease detector diameter diastolic distribution effect elastin electrode energy equation filter fluid Fourier transform frame frequency function haemoglobin hair cells halothane heart rate impulse response increase left heart linear linear-attenuation coefficient lung manometer measured medical physics membrane method mmHg muscle normal obtained oxygen P₁ P₂ pacemaker patient peripheral resistance photons physicist physiological pulmonary pulsatile pulse ratio region Rendiconti S.I.F. sample scan scanner segment shown in fig shows signal stroke volume systolic techniques tissues transducer transmural pressure tube ultrasonic V₁ velocity venous system ventilation ventricle ventricular vessel viscoelastic volume wall wave form Windkessel X-ray zero