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Differentiability exact

PANELIST SCHMID In all of our economics, we have calculated the required selling price for the total Btu output of the plant and presented the economics this way. This is admittedly an oversimplification, because it does not take into consideration any possible price differential between the gas and the liquids. However, we feel that a differential is justifiable. The gas is undoubtedly more of a premium product than the liquid, and without a controlled market there certainly would be a price differential. Exactly what this would be is open to question. This is really yet to be tackled. There are some ways of trying to... [Pg.122]

Cartesian coordinates, 4 definition of, 4 spherical polar coordinates, 6 Differentials exact, definition of, 84 significance of, 86 inexact, definition of, 84 partial, 38 of a cylinder, 39 total. 37-39 Differentiation definition of, 31... [Pg.115]

The work depends on the detailed path, so Dn is an inexact differential as symbolized by the capitalization. (There is no established convention about tliis symbolism some books—and all mathematicians—use the same symbol for all differentials some use 6 for an inexact differential others use a bar tln-ough the d still others—as in this article—use D.) The difference between an exact and an inexact differential is crucial in thennodynamics. In general, the integral of a differential depends on the path taken from the initial to the final state. Flowever, for some special but important cases, the integral is independent of the path then and only then can one write... [Pg.325]

One way of verifying the exactness of a differential is to check the validity of expressions like that above. [Pg.326]

If the adiabatic work is independent of the path, it is the integral of an exact differential and suffices to define a change in a function of the state of the system, the energy U. (Some themiodynamicists call this the internal energy , so as to exclude any kinetic energy of the motion of the system as a whole.)... [Pg.330]

In the example of the previous section, the release of the stop always leads to the motion of the piston in one direction, to a final state in which the pressures are equal, never in the other direction. This obvious experimental observation turns out to be related to a mathematical problem, the integrability of differentials in themiodynamics. The differential Dq, even is inexact, but in mathematics many such expressions can be converted into exact differentials with the aid of an integrating factor. [Pg.333]

The factor in wavy brackets is obviously an exact differential because the coefficient of d9 is a fiinction only of 9 and the coefficient of dVis a fiinction only of V. (The cross-derivatives vanish.) Manifestly then... [Pg.336]

Equation (A2.1.26) is equivalent to equation (A2.1.25) and serves to identify T, p, and p. as appropriate partial derivatives of tire energy U, a result that also follows directly from equation (A2.1.23) and the fact that dt/ is an exact differential. [Pg.344]

All of these quantities are state fiinctions, i.e. the differentials are exact, so each of the coefficients is a partial derivative. For example, from equation (A2.1.35) p = —while from equation (A2.1.36)... [Pg.348]

We further discuss how quantities typically measured in the experiment (such as a rate constant) can be computed with the new formalism. The computations are based on stochastic path integral formulation [6]. Two different sources for stochasticity are considered. The first (A) is randomness that is part of the mathematical modeling and is built into the differential equations of motion (e.g. the Langevin equation, or Brownian dynamics). The second (B) is the uncertainty in the approximate numerical solution of the exact equations of motion. [Pg.264]

We have in mind trajectory calculations in which the time step At is large and therefore the computed trajectory is unlikely to be the exact solution. Let Xnum. t) be the numerical solution as opposed to the true solution Xexact t)- A plausible estimate of the errors in X um t) can be obtained by plugging it back into the differential equation. [Pg.268]

They represent the generalization of our earlier equations (11.12) and include an additional equation for the pressure, since this can no longer be assumed to take the constant value p throughout the pellet. The differential equation relating X to f is derived exactly as before and has the same form, except that p cannot be replaced by p In the present case. Thus we have... [Pg.118]

Some of the integral or differential constitutive equations presented in this and the previous section have an exact equivalent in the other group. There are, however, equations in both groups that have no equivalent in the other category. [Pg.14]

It is a property of linear, homogeneous differential equations, of which the Schroedinger equation is one. that a solution multiplied by a constant is a solution and a solution added to or subtracted from a solution is also a solution. If the solutions Pi and p2 in Eq. set (6-13) were exact molecular orbitals, id v would also be exact. Orbitals p[ and p2 are not exact molecular orbitals they are exact atomic orbitals therefore. j is not exact for the ethylene molecule. [Pg.177]

As m increases, At becomes progressively smaller (compare the difference between the square roots of 1 and 2 (= 0.4) with the difference between 100 and 101 (= 0.05). Thus, the difference in arrival times of ions arriving at the detector become increasingly smaller and more difficult to differentiate as mass increases. This inherent problem is a severe restriction even without the second difficulty, which is that not all ions of any one given m/z value reach the same velocity after acceleration nor are they all formed at exactly the same point in the ion source. Therefore, even for any one m/z value, ions at each m/z reach the detector over an interval of time instead of all at one time. Clearly, where separation of flight times is very short, as with TOF instruments, the spread for individual ion m/z values means there will be overlap in arrival times between ions of closely similar m/z values. This effect (Figure 26.2) decreases available (theoretical) resolution, but it can be ameliorated by modifying the instrument to include a reflectron. [Pg.191]

Since G is a state variable and forms exact differentials, an alternative expression for dG is... [Pg.140]

See other pages where Differentiability exact is mentioned: [Pg.68]    [Pg.48]    [Pg.361]    [Pg.264]    [Pg.201]    [Pg.749]    [Pg.68]    [Pg.48]    [Pg.361]    [Pg.264]    [Pg.201]    [Pg.749]    [Pg.326]    [Pg.333]    [Pg.620]    [Pg.666]    [Pg.698]    [Pg.784]    [Pg.792]    [Pg.1205]    [Pg.319]    [Pg.421]    [Pg.362]    [Pg.381]    [Pg.118]    [Pg.41]    [Pg.41]    [Pg.224]    [Pg.206]    [Pg.109]   
See also in sourсe #XX -- [ Pg.202 ]

See also in sourсe #XX -- [ Pg.202 ]



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