Software:Phyz

From HandWiki
Phyz (Dax Phyz)
Phyz Logo.gif
File:Phyz Yoda.ogv
Phyz video capture
Developer(s)Firma Stache
Stable release
3.34 / January 15, 2020; 4 years ago (2020-01-15)
Operating systemMicrosoft Windows
TypeGame engine
LicensePublic domain
Websitephyz.ath.cx

Phyz (Dax Phyz) is a public domain,[1] 2.5D physics engine with built-in editor and DirectX graphics and sound. In contrast to most other real-time physics engines, it is vertex based and stochastic. Its integrator is based on a SIMD-enabled assembly version of the Mersenne Twister random number generator, instead of traditional LCP or iterative methods, allowing simulation of large numbers of micro objects[2] with Brownian motion and macro effects such as object resonance[3] and deformation.

Description

Purpose

Dax Phyz is used to model and simulate physical phenomena, to animate static graphics, and to create videos, GUI front-ends and games. There is no specified correlation between Phyz and reality.[4]

Features[5]

  • Deformable and breakable objects (soft body dynamics).
  • N-body particle simulation.
  • Rod, stick, pin, slot, rocket, charge, magnet, heat, actuator and custom constraints.
  • Turing complete, real-time logic components (Phyz Logics).
  • Explosives.
  • Collision and break sound effects.
  • Message-based application programming interface.
  • Real-time, constraint-aware editing.
  • Metaballics effects.
  • Bitmap import.
  • OpenMP 2.0 support.

Platform availability

Phyz requires Windows with DirectX 9.0c or later, a display adapter with hardware support for DirectX 9, a CPU with full SSE2 support, and 1 GB of free RAM.[6] The metaballics effects require a GPGPU-capable display adapter.[7]

PhyzLizp

PhyzLizp, included with Phyz, is an external application based on the Lisp programming language (Lizp 4). It can be used to measure and control events in Phyz, and to create Phyz extensions such as graphical interfaces, network gateways, non-linear constraints or games.[8]

Screenshots

Dax Phyz scene screenshots

  1. Hammer scene (upper left; deformable objects): The hammer's centre of mass is displaced from its rotational axis, creating a torque which keeps the ruler from rotating.
  2. Wedge scene (upper right; breakable objects): How to make an impression.
  3. Yoda scene (lower left; bitmap import, metaballics): 3.446 vertices and 13.336 rods; the vertices form metaballs with colour information from a photograph of a clay model.
  4. Balloon scene (lower right; heat constraints): "Why am I lighter in the water?" Dax asked after a recent swimming lesson. Dax, like balloons, floats since there are more particles pushing on the bottom than on the top, as in buoyancy.

File:DaxPhyz AirBurstContained.ogv

  1. Contained Air Burst (N-body particle system, soft body dynamics): 32.068 vertices, 35.283 constraints. After a brief mushroom formation, the semi-spherical shockwaves propagate to the rectangular container walls, where they are reflected, eventually forming a wedge shape in the middle, quickly degrading to a half-sphere under the influence of gravity.

See also

References

  1. Phyz public domain release statement
  2. Vladislav Popkov et al., 2002, J. Phys. A, Math. Gen. 35 7187-7204: A sufficient criterion for integrability of stochastic many-body dynamics. ISBN:978-5-901548-12-7
  3. Jan A. Freund (Humboldt-University, Germany) et al., ORAL session C32, 2006-03-12, Washington: Stochastic Resonance and Noise-Induced Phase Synchronization
  4. Phyz scale FAQ
  5. Dax Phyz features overview
  6. Phyz platform requirements
  7. Metaballics FAQ
  8. PhyzLizp description

External links

de:Physik-Engine#Physik-Engines fr:Moteur physique#Moteurs propriétaires sv:Phyz