Section P.4 Linear Equations in Two Variables Important Vocabulary
... Slope The number of units a nonvertical line rises (or falls) vertically for each unit of horizontal change from left to right. Parallel Two distinct nonvertical lines are parallel if and only if their slopes are equal. That is, m1 = m2. Perpendicular Two nonvertical lines are perpendicular if and o ...
... Slope The number of units a nonvertical line rises (or falls) vertically for each unit of horizontal change from left to right. Parallel Two distinct nonvertical lines are parallel if and only if their slopes are equal. That is, m1 = m2. Perpendicular Two nonvertical lines are perpendicular if and o ...
Chapter V. Part IV. Elliptically Loaded Wings
... This component of drag is just the inviscid component of drag, to which viscous contributions (due to skin friction, separated flow, stall effects) must be added to get the total wing drag. Notice that the smaller the aspect ratio, the higher the induced drag. Why did we study elliptically loaded wi ...
... This component of drag is just the inviscid component of drag, to which viscous contributions (due to skin friction, separated flow, stall effects) must be added to get the total wing drag. Notice that the smaller the aspect ratio, the higher the induced drag. Why did we study elliptically loaded wi ...
Math 3113, Quiz II
... If the differential equation is given by M dx + N dy = 0 then it is an exact differential equation if it satisfies My = Nx . In this case M = cos x + ln y and N = xy + ey . Hence ...
... If the differential equation is given by M dx + N dy = 0 then it is an exact differential equation if it satisfies My = Nx . In this case M = cos x + ln y and N = xy + ey . Hence ...
3 Linear viscoelasticity
... where γ is the shear, ω the frequency and α the amplitude. In reality α must be kept small to ensure the material is kept within its linear régime; but if we are dealing with an ideal linear viscoelastic material, α can be any size. Note that the shear rate of the fluid, γ̇(t), will be γ̇(t) = αω c ...
... where γ is the shear, ω the frequency and α the amplitude. In reality α must be kept small to ensure the material is kept within its linear régime; but if we are dealing with an ideal linear viscoelastic material, α can be any size. Note that the shear rate of the fluid, γ̇(t), will be γ̇(t) = αω c ...