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Longer titles found: Line integral convolution (view)

searching for Line integral 41 found (264 total)

alternate case: line integral

GEM character set (652 words) [view diff] exact match in snippet view article find links to article

and other symbols, and exchanging code point 236 with the symbol for line integral. However, GEM is more similar to code page 865, because the codepoints

exchanging code points 158, 236 and 254–255 with the symbols for sharp S, line integral, cubed and macron. The Atari ST family of computers contained this font

desirable when interpolating the electric field, for instance, since the line integral gives the electric potential difference at the endpoints of the integration

the total phase change in the loop is given by (with Eq. (15)) The line integral is over the contact from one side to the other in such a way that the

that if S {\displaystyle \mathbf {S} } is a closed surface, then the line integral tends to zero, leading to the result, ∫ S ( x × n ) ∇ ⋅ n   d S = 0

{0} =\nabla \times (R\,\mathbf {u} )} . Then by Stokes' theorem the line integral of R u {\displaystyle R\,\mathbf {u} } over every closed loop vanishes

ψ may be defined by a line integral. The integrability condition and Stokes' theorem implies that the value of the line integral connecting two points

density and H is the magnetic field intensity, the second integral is a line integral around a closed loop C {\displaystyle C} with line element l {\displaystyle

equation (for γ 13 {\displaystyle \gamma _{13}} ) becomes an ordinary (line) integral: ∇ γ 13 = ( cos ⁡ γ 23 ) − 1 ( − F 13 cos ⁡ γ 12 + F 23 sin ⁡ γ 12 )

derivative, which is reflected in Green's theorem, which equates a line integral of a function on a (1-dimensional) contour to the (2-dimensional) integral

that case the induced topology may not be the standard one of the real line. Integral curve One-parameter semigroup Noether's theorem The Wikibook Abstract

pressure – Kinetic energy per unit volume of a fluid Electric potential – Line integral of the electric field Electron degeneracy pressure – Repulsive force

\end{aligned}}} The vorticity is also related to the flow's circulation (line integral of the velocity) along a closed path by the (classical) Stokes' theorem

{E} \cdot \mathrm {d} \mathbf {s} } When the curl ∇ × E is zero, the line integral above does not depend on the specific path C chosen but only on its

vector potential A ( r ) {\displaystyle A(r)} inside the annulus with a line integral ∮ C A ⋅ d l = Φ {\textstyle \oint _{C}A\cdot dl=\Phi } along any path

gradient theorem asserts that a 1-form is exact if and only if the line integral of the form depends only on the endpoints of the curve, or equivalently

(4). That p θ ( s ) {\displaystyle p_{\theta }(s)} is equal to the line integral of μ(x,y) along l [ θ , s ] ( t ) {\displaystyle {l}_{[\theta ,s]}(t)}

Gauss curvature to the Euler characteristic of the surface and the line integral of the geodesic curvature of its boundary; this result is now known

method area contiguous with distortion Yes 1993 Gusein-Zade, Tikunov Line Integral method area contiguous with distortion Yes 1996 Dorling Circular cartogram

stress concentration can be characterised using a path-independent line integral, as shown by Eshelby for dislocations considering the contribution from

Vortex Lens: Interactive Vortex Core Line Extraction using Observed Line Integral Convolution: Peter Rautek, Xingdi Zhang, Bernhard Woschizka, Thomas

can be generalized to give the modern vector form of Ørsted's law The line integral of the magnetic field B ( x ) {\displaystyle \mathbf {B} (\mathbf {x}

calculation of the relative surface heights of the line on the object using a line integral, if we assume a continuous surface. If the object is not cylindrical

transform the confidence rating to a statistical tolerance, the following line integral can be applied to an isoline retrieval for which the true isoline is

fields are interpreted as a transformation of a surface integral into a line integral – an independent and slightly different derivation from that done in

balanced coil that measures current by electronically evaluating the line integral around a current. High-frequency, small-signal, passive current probes

electromagnetic wave traveling through the medium is related to the line-integral of the wavenumber along the propagation line.[citation needed] For a

T = 0 {\displaystyle \oint {\frac {\delta Q}{T}}=0} That means the line integral ∫ L δ Q T {\displaystyle \int _{L}{\frac {\delta Q}{T}}} is path independent

coordinates. A differential 1-form is integrated along an oriented curve as a line integral. The expressions dxi ∧ dxj, where i < j can be used as a basis at every

reversible transfer of heat energy into that system. That means the line integral ∫ L δ Q T {\textstyle \int _{L}{\frac {\delta Q}{T}}} is path-independent

the difference of stream function values across a 2D channel, or the line integral of the tangential component of the vector potential around the channel

force applied to an element between point A and point B is equal to the line integral through the component of the magnetic field strength, H {\displaystyle

gradient operator maps a scalar field to a vector field such that the line integral between any two points in the vector field is equal to the difference

{\textstyle \mathbf {v} ={\boldsymbol {\omega }}\times \mathbf {x} } and the line integral can be computed in terms of the area of the loop: ∮ v ⋅ d x = ∮ ω ×

remains to be done numerically. For a particular angle one must solve the line integral for the ray with origin at the intersection point of the line P0P1 with

continuously deformed to the constant curve a {\displaystyle a} . So the line integral of f d z {\displaystyle f\,\mathrm {d} z} over the curve is 0 {\displaystyle

{K}{2\pi }}\theta .} For the closed curve enclosing origin, circulation (line integral of velocity field) Γ = K {\displaystyle \Gamma =K} and for any other

the circulation around the airfoil. The circulation is defined as the line integral around a closed-loop enclosing the airfoil of the component of the velocity

{\frac {DA_{e}}{Dt}}} . Here C {\displaystyle C} is the circulation, the line integral of the velocity along a closed contour. Also, D / D t {\displaystyle

coordinates, the equation of the involute is transcendental; doing a line integral there is hardly feasible. A more felicitous approach is to use polar

boson. The circulation Γ {\displaystyle \Gamma } is defined to be the line integral along a simple closed path C {\displaystyle C} within the fluid Γ =