The use of electrostatic charge to study glass surfaces /

Shonebarger, Francis Joseph

January 1961

No description available.

Engineering

Glass

Surfaces

Macroscopic oscillatory behavior and the momentum distribution function of a normal Fermion system /

Steginsky, Bernard

January 1969

No description available.

Physics

Fermi surfaces

Diffraction by doubly curved convex surfaces /

Voltmer, David Russell

January 1970

No description available.

Engineering

Convex surfaces

Diffraction

Theory of superfluid fermi systems /

Prabhu, Rashmiraj Balkrishna

January 1970

No description available.

Physics

Fermi surfaces

Properties of surfaces whose asymptotic curves belong to linear complexes.

Sullivan, Charles T.

January 1917

No description available.

Curves on surfaces.

Complexes.

Mathantics.

Some relations between the Riemann zeta-function and certain number theoretic functions

Robinson, Valerie (Valerie Ruth)

January 1969

No description available.

Functions, Zeta.

Riemann surfaces.

The Riemann-Roch theorem for function fields in one variable /

Kennedy, Alec (Alec Henry)

January 1970

No description available.

Functions.

Riemann surfaces.

The classification of ruled surfaces and rank 2 vector bundles over a curve of genus O or 1 /

Malard, Joël.

January 1983

No description available.

Surfaces, Ruled.

Vector bundles.

Giant quantum ultrasonic attenuation in semiconductors.

Reiss, Michael Levi.

January 1969

No description available.

Ultrasonic waves

Fermi surfaces

Cyclic animation using Partial differential Equations

Gonzalez Castro, Gabriela, Athanasopoulos, Michael, Ugail, Hassan, Willis, P., Sheng, Y

January 2010

Yes / This work presents an efficient and fast method for achieving cyclic animation using Partial Differential Equations (PDEs). The boundary-value nature associ- ated with elliptic PDEs offers a fast analytic solution technique for setting up a framework for this type of animation. The surface of a given character is thus cre- ated from a set of pre-determined curves, which are used as boundary conditions so that a number of PDEs can be solved. Two different approaches to cyclic ani- mation are presented here. The first consists of using attaching the set of curves to a skeletal system hold- ing the animation for cyclic motions linked to a set mathematical expressions, the second one exploits the spine associated with the analytic solution of the PDE as a driving mechanism to achieve cyclic animation, which is also manipulated mathematically. The first of these approaches is implemented within a framework related to cyclic motions inherent to human-like char- acters, whereas the spine-based approach is focused on modelling the undulatory movement observed in fish when swimming. The proposed method is fast and ac- curate. Additionally, the animation can be either used in the PDE-based surface representation of the model or transferred to the original mesh model by means of a point to point map. Thus, the user is offered with the choice of using either of these two animation repre- sentations of the same object, the selection depends on the computing resources such as storage and memory capacity associated with each particular application.

Cyclic animation

PDE surfaces