someonewholikesstuff said:
physical realizability and dynamical completeness within a model.
See this discussion -
https://www.physicsforums.com/threads/physical-realization-of-a-system.789471/post-4961600 - concerning the term "realizable".
someonewholikesstuff said:
physical realizability and dynamical completeness within a model.
What does one understand the quote phrase to mean?
Many systems are complex, and we develop simple models to represent the behavior of such a system. We cannont model every atom, or electron, so we develop simple mathematical models to model or simulation the observed behavior of the system. Such system could be simple electronic device, e.g., a resistor, capacitor, inductor, transistor, thermocouple, thermoelectric device, a circuit, or complex combination of aforementioned devices and circuits. Mechanically, one could simulation a single crystal of a pure metal, an alloy, an intermetallic compound, a ceramic, or some combination in a single crystal (same grain orientation) or a population of grains/crystals (over a range of nanometers to microns to mm to cm to m). We often refer to atomistic or nanoscale, mesoscale (intermediate) to engineering scale. One might model an interface of an electronic device, e.g., a gate, or a corrosion layer that evolves over time.
Within each system one is faced with a choice of how detailed a model must be to replicate whatever behavior is of interest. Models must be consistent. We apply continuity equations, conservation of mass, momentum and energy, i.e., we account for energy in, energy out, and energy present within a system's boundary,
We can divide a system into blocks or elements, and apply the same set of equations within each element. We run a simuation, then compare the mathemeatical results (values ) to meansurements (or observations) we make to see if the results are consistent.
We model dynamic behavior over short or long term time scales. One might model turbulence in a flow over (around) a wing/foil or body of an aricraft, ship or car, and calculate the forces on the structure in order to understand the behavior/performance of the object of interest, which may include fluid-structure interaction. One might be interested in lift and/or drag, but also fatigue of the structure or corrosion of the surface. Calculations (mathematical models) may be conducted on a variety of scales simultaneously (over the same time step) in order to reproduce the observed behavior.
In a solid model, one will need mathematical (or numerical) models of thermophysical properties (e.g., thermal conductivity, density) and thermomechanical properties (e.g., elastic modulus, tensile strength, etc), all of which are function of temperature and composition of the material, all of which may change with time. With each preoperty (variable), there is some undertainty (one cannot know precisely what a given property/variable is at a given time), but over time, if one's numerical simulation produces an observation (measurement), then that's a reasonable outcome.
Numerical modeling has become more sophisticated with improvements in computation hardware and software, as well as more measurements and better data, but we are far from having modeled everyting we could. On the other hand, some programs have been very successful (Voyager spacecraft), while at the same time, there have been some spectacular failures.
