Time Scale Parameter Research Articles

Dynamical phase transitions and self-organized criticality in a theoretical spring-block model.

We numerically and analytically study the self-organized criticality of a nonconservative and globally coupled spring-block model. With a spring parameter and a time-scale parameter, this model displays the dynamical states of two types which are different from each other in three aspects: the stick-slip processes, the strain distribution functions, and the power laws of shock-size distributions. Over a range of parameter space these two states may coexist. The transitions between these two states as well as the phenomenon of hysteresis are first observed in the context of spring-block models. A phase diagram is roughly sketched.

Greenhouse warming over Indian sub-continent

A hierarchy of climate models have been developed and applied to the problem of doubling the CO2 concentration in the atmosphere. Currently available general circulation models include the most complete treatment of the global wanning and are capable of providing changes in several of the meteorological parameters in time scales of half a century or even more. Much skill is gradually being achieved now for future climate simulations. In this paper, we have attempted to describe the response of the National Center for Atmospheric Research Climate Community Model (NCAR CCM), whose performance for northern hemispheric climate simulations was reported to be very satisfactory to Indian region. The seasonal (winter and summer) changes in surface temperature, rainfall and soil moisture expected over the Indian sub-continent due to doubling of CO2 in the atmosphere as inferred from model output statistics are discussed. A probable scenario for sea level rise along the Indian coastline by the year 2030 AD as a result of ocean water’s expansion due to global warming is outlined. These projections should not be treated as predictions of what is going to happen over the Indian sub-continent. Rather, they merely illustrate to what extent we might be affected by the future climate change.

Time-implicit fluid simulation of collisional plasmas

A one-dimensional algorithm for fluid simulation of interpenetrating multi-component plasmas, developed earlier for the collisionless case [1], is extended to include collisions between species. The finite-differenced fluid equations, including collision forces, are coupled with the Poisson equation to give time-implicit solutions, which are stable and accurate over a wide range of the time scale parameters ω p Δt and v c Δt ( ω p is the plasma frequency, v c is a typical collision frequency, and Δt is the time step). In regions where ω p Δt ⪡ 1 and v c Δt ⪡ 1, electron dynamics and space-charge effects are resolved, while in regions where ω p Δt ⪢ 1 and/or v c Δt ⪢ 1, the ambipolar and/or diffusion models are recovered. Results of tests are presented, including ohmic heating, shocks with an interface between different fluids, colliding plasmas in which a region of interpenetrating fluids is created, and plasma shocks with separate electron and ion fluids.

Higher correlation functions of chaotic dynamical systems-a graph theoretical approach

For dynamical systems conjugated to the Bernoulli shift and their higher-dimensional extensions of Kaplan-Yorke type the author calculates higher-order correlation functions by means of a graph theoretical method. The graphs relevant to this problem are forests of incomplete double binary trees. His method has similarities with the Feynman graph approach in quantum field theory: the 'free field' corresponds to a Gaussian random dynamics, the 'interacting field' to a chaotic process with non-trivial higher-order correlations. The 'coupling constant' tau 1/2 is a time scale parameter that measures how much the chaotic process differs from a Gaussian process. He develops a perturbation theory around the Gaussian limit case for sums of iterates of the fully developed logistic map with arbitrary coefficients.

Time-scaling and crystallization kinetics of three Fe-B-based metallic glasses

Time-scaling properties of the isothermal transformation kinetics have been tested for three Fe-B-based metallic glasses exhibiting two crystallization stages. The time scale was defined as the time at which crystallization has reached half completion and is derived from calorimetric (DSC) data. The temperature dependence of the time-scaling parameter shows a lowtemperature freezing behaviour and can be described by empirical functions based on free-volume considerations.

A comparison of multiple time-scale analysis and overlapping decompositions

Two-level hierarchical systems are considered, and two different design methodologies, multiple-time-scale analysis and overlapping decompositions, are compared. The comparison is based on quadratic performance indices. It is demonstrated that, in general, the multiple-time-scale approach, produces better results whenever the time-scale parameter is small. However, the overlapping decompositions approach usually yields better controller designs as the time-scale parameter gets larger. An example of a mass-spring system is presented to illustrate the practical applications of the theoretical details discussed. >

Relaxation parameters to simulate the changes in magnetostriction in amorphous magnetic alloys

We propose a method for deducing the parameters of the non-linear relaxation distribution model from isothermal measurements. Following this thermodynamic theory, isothermal relaxations can be described as isokinetic processes over a reduced time scale, taking into account non-linear effects, i.e. integrating the sample history. The proposed method leads to the definition of three characteristic parameters of this new time scale. In addition, the model predicts a universal shape of relaxation spectrum for frozen-in fluctuations. Applying this method to magnetostriction changes in Vitrovac® 6025 (Co 67Fe 4Mo 1.5Si 16.5B 11), we are able to simulate various thermal histories starting from high temperature equilibrium in the liquid state. We found good agreement with experiments. Free-energy spectra are determined.

Solar-wind flow past a cometary ionosphere

An axisymmetric gasdynamical model of an interaction between the solar wind and comet atmospheres is formulated. Photoionization of the cometary neutral particles as well as their resonance charge-exchange are taken into account to determine the flow in the distured region containing three discontinuity surfaces (two shocks and the contact discontinuity). It is shown that these two processes are significant for many comets. The problem so formulated is solved numerically. A dependence of the obtained solutions on comets gas production, charge-exchange cross-section, photoionization time scale and other parameters is studied. The numerical solutions are in good agreement with the experimental data obtained during the spacecraft missions to the comet Halley in March 1986.

Crystallization kinetics of an amorphous magnet

The crystallization of an amorphous Fe-Ni-P alloy during isothermal annealing has been studied using a method that relies on the magnetism of the crystalline product. By rescaling the time axis for each annealing temperature, the data fall on a universal curve of the Johnson–Mehl–Avrami form, with parameters indicative of linear growth of a fixed number of crystallites. The time scaling parameter can be fitted to a Vogel–Fulcher or a Williams–Landel–Ferry temperature dependence, suggesting that dynamic processes in the glass phase are the rate-limiting steps in crystallization.

AN INVESTIGATION OF THE SPECTRAL PROPERTIES OF PRIMARY REFLECTION COEFFICIENTS*

ABSTRACTThis paper investigates the form of the nonwhiteness found in the reflection coefficients from a wide variety of rock sequences around the world. In all but one case densities are taken as constant due to the paucity of suitable density data. The reflection sequences are pseudo‐white only above a corner frequency, below which their power spectrum falls away according to a power law fβ, where β is between 0.5 and 1.5. This spectrum can be adequately modelled in practice very simply with an ARMA (1, 1) process which acts on a white innovation sequence. The corollary of this is that before wavelet estimation methods are applied (all of which‐except those based on synthetic seismograms—presuppose white reflection sequences) or deconvolution filters estimated, seismic traces should be filtered with the inverse of this process.Interestingly, the estimated ARMA processes group themselves into two clearly differentiated categories, having very different indices of predictability (or, strictly, indices of linear determinism). The two categories apparently correlate precisely with two kinds of sedimentation: one which consists largely of sequences of rocks with repeating properties, called “repetitive” in this paper but perhaps loosely describable as “cyclic”, and the other which is randomly bedded with no apparent pattern of components. The former has indices of predictability which are two to four times as great as those of the latter. Another, probably related, property is that β for the repetitive sequences tends to be greater than that for non‐repetitive rock columns.The observed power spectra are shown to be consistent with a simple model for the logarithm of acoustic impedance consisting of a mixture of processes where the distribution of (time) scale parameters is reciprocal.Detailed effects of block‐averaging and sampling the logs are shown to depend on the type of sequence under examination.

Petroleum generation by laboratory-scale pyrolysis over six years simulating conditions in a subsiding basin

Many researchers have attempted to duplicate under laboratory conditions the geochemical reactions that lead to economic deposits of liquid and gaseous hydrocarbons1–4. Experiments lasting from a few5,6 to several hundred7 days, usually at constant temperatures, have been devised. The differences in time scale and other parameters between geological processes and laboratory experiments are so great that the relevance of labora tory results is often questioned8,9. Consequently, we have heated potential source material from 100 to 400 °C over six years, increasing the temperature by 1 °C per week. This was done in an attempt to simulate the thermal history of a sample being buried in a continuously subsiding basin with a constant geothermal gradient. After four years, a product indistinguish able from a paraffinic crude oil was generated from a torbanite, while a brown coal gave a product distribution that could be related to a wet natural gas. Of great significance is the absence of olefins and carbon monoxide in all products. We believe the present experiments, which are possibly as slow as can be realistically planned within a human time scale, have for the first time successfully duplicated hydrocarbon generation in a continuously subsiding sedimentary basin.

A model for unsteady transonic indicial responses

A method of characterizing the indicial curve for the response frequencies of flutter in the transonic regime by means of a time scale parameter is illustrated. Time linearization of the unsteady potential equation is assumed adequate and the perturbed potential about a steady flow is defined with appropriate boundary conditions. An indicial motion can then be obtained for a given mode, with the lift and drag coefficients which result from a step change in incidence or control surface deflection available to describe any kind of motion. The lift and drag coefficients are shown to result analytically by addition of the multiplicand involving the time scale parameter. If the coefficients are maximized, then at reduced frequencies only two parameters are necessary to form the indicial response curve.

Measurements of characteristic time scales of the turbulent boundary layer with mass transfer

The results of an experimental survey on the transpired turbulent boundary layer with constant pressure and blowing fraction are reported in the present paper. The working fluid was air at atmospheric pressure. Characteristic time scales of the near-wall region were measured as well as mean velocity profiles and turbulence parameters using constant temperature hot-wire anemometry. Integral parameters of the boundary layer and local friction factors are also presented. Comparisons are made with earlier studies.The outer portion of the mean velocity profiles U+(y+) seems to be more affected with blowing than the near-wall portion. The region of maximum turbulence fluctuations moves away from the wall with blowing, indicating that the length scale and thus the time scale of fluctuations near the wall are increased. This is consistent with the findings on the characteristic time scale TB. The characteristic time scale parameter T̄B is found to correlate well with the mass-transfer parameter V+w.

Kinetics of co-operative ligand binding in proteins: The effects of organic phosphates on hemoglobin oxygenation

A master equation approach to the kinetics of co-operative ligand binding reactions in proteins is developed. As a specific example, equations based on the Perutz description are applied to several reactions of hemoglobin, both in the absence and in the presence of organic phosphates. The observed time dependence of O 2 binding to stripped hemoglobin is fitted with a total of four parameters, of which two are held fixed at values determined from the experimentally measured rate constants for the last step of ligand binding. An analysis of Gibson's data (1970a) for oxygen-binding kinetics of unstripped hemoglobin shows that phosphate binding not only stabilizes the deoxy quaternary conformation of hemoglobin but also increases both the strength of the quaternary conformational constraints and the kinetic time scaling parameter for the deoxy quaternary conformation. A single set of five parameters is used to fit the deoxygenation data of Salhany et al. (1970) in the presence of varying concentrations of P 2Glyc § § Abbreviations used: P in2Glyc, 2,3-diphosphoglycerate; IHP, inositol hexaphosphate; HPT, 8-hydroxy-l,3,6-pyrenetrisulfonate; Hb, hemoglobin. . The five parameters are determined by fitting the theory to the data in the absence of P 2Glyc and at a single concentration of P 2Glyc. The predictive ability of the model is then tested by using these same parameter values to calculate the curves for intermediate P 2Glyc concentrations, and then comparing the predicted curves with experimental data. Whereas deoxygenation data in the presence of P 2Glyc can be fitted with the subunits considered as equivalent, we find that α, β subunit inequivalence is particularly important in interpreting deoxygenation data in the presence of the inhibitor, IHP. Since the phosphate dependence of the reaction is explicitly included, the model can also describe biphasic deoxygenation, as observed by Gray & Gibson (1971) for the deoxygenation reaction in the presence of IHP. In the deoxygenation reaction, the quaternary conformation is found to change from oxy to deoxy just prior to the release of the second oxygen molecule; the switch occurs somewhat earlier in the presence of organic phosphates. As a consequence of this switch, the release of oxygen lags behind the binding of organic phosphates; the lag is more pronounced for IHP than for P 2Glyc. The analogous result of MacQuarrie & Gibson (1972) concerning the lag between the release of HPT and binding of CO is well reproduced; the fractional saturation of hemoglobin with CO and the fraction of HPT released are both fitted with a single set of five parameters. The dependence of the Adair (1925a,b) rate constants (for α = β) and Olson-Gibson (1972) rate constants (for α ≠ β) on the concentration of organic phosphate is calculated. It is found that (i) the experimentally observed increase in the overall deoxygenation rate with increasing organic phosphate concentration is primarily due to the increase in the rate of dissociation of the second oxygen molecule, (ii) the “on” rate constants most affected by organic phosphate are k 1′ and k 2′ the rate constants for the binding of the first and second oxygen molecules, (iii) the “off” rate constants, k j , are affected more than the “on” rate constants, k j ′ (iv) the rate constants for the reactions of the β subunits are affected more by IHP than those of the α subunits, and (v) the rate constants involving the intermediate species with two β subunits and one α subunit liganded are influenced the most by the binding of phosphates.

A numerical method for solving optimal control problems with unspecified terminal time†

This paper presents a numerical technique which automatically computes the unspecified terminal-time of an optimal control problem as a systematic part of the whole procedure for finding the optimal control inputs. In the proposed technique, a given unspecified terminal-time problem is transformed into a fixed terminal-time problem by a time-sealing method. Then, by considering the time-scaling parameter as either an extra control input or as an additional variable, and by applying the necessary conditions of optimality, a fixed terminal-time two-point boundary-value problem is obtained. Three algorithms are proposed to solve such a class of two-point boundary-value problems : two of them are based on the gradient methods, and one on the Newton-Raphson method in function space. Several numerical examples are included. A comparison of the rate of convergence of different algorithms used in the solution of each example problem is given.

Random wear models in reliability theory

Gaver (1963) and Antelman and Savage (1965) have proposed models for the distribution of the time to failure of a simple device exposed to a randomly varying environment. Each model represents cumulative wear as a specified function of a non-negative stochastic process with independent increments, and assumes that the reliability of the device is conditioned upon realizations of this process. From these models are derived the corresponding unconditional joint distributions for the random failure time vector of n independent, identical devices exposed to the same realization of the wear process. It is shown that the identical failure time distribution for one component can arise from each model. In the Gaver model simultaneous failure times occur with positive probability. The probabilities of specific tie configurations are developed.For an interesting class of Gaver models involving a time scale parameter, the maximum likelihood estimates from several devices in one environment are examined. In that case the tie configuration probability does not depend on the parameter. For the corresponding Antelman-Savage models a consistent sequence of estimators is obtained; the maximum likelihood theory did not appear tractable.

Random wear models in reliability theory

Gaver (1963) and Antelman and Savage (1965) have proposed models for the distribution of the time to failure of a simple device exposed to a randomly varying environment. Each model represents cumulative wear as a specified function of a non-negative stochastic process with independent increments, and assumes that the reliability of the device is conditioned upon realizations of this process. From these models are derived the corresponding unconditional joint distributions for the random failure time vector of n independent, identical devices exposed to the same realization of the wear process. It is shown that the identical failure time distribution for one component can arise from each model. In the Gaver model simultaneous failure times occur with positive probability. The probabilities of specific tie configurations are developed. For an interesting class of Gaver models involving a time scale parameter, the maximum likelihood estimates from several devices in one environment are examined. In that case the tie configuration probability does not depend on the parameter. For the corresponding Antelman-Savage models a consistent sequence of estimators is obtained; the maximum likelihood theory did not appear tractable.

The time-scale of atmospheric diffusion considered in relation to the universal diffusion function, ƒ 1

A formula for the ƒ 1- function in Pasquill's well-known diffusion equation, σ y(t) = σ vtƒ 1(t/t L) , is derived from the ‘random-force’ model (RFM) of long-range, horizontal diffusion proposed by Gifford (1982a, Atmospheric Environment 16, 505–512). When historical and recent plume diffusion data are used to determine ƒ 1 from the empirical formula proposed by Draxler (1976, Atmospheric Environment 10, 99–105), which assumes a fully averaged form for the diffusion, i.e. a constant σ v, the time-scale parameter of that formula is found to vary by a factor of more than an order of magnitude over the range of the data. Application of the RFM to these data shows that the diffusive motions were only partially averaged over the experimental sampling times, so that the σ v describing these plumes is a function of both the diffusion time and the experimental sampling time. When a Lagrangian time-scale of 10 4 s, as required by the RFM, is used, the free parameter of the RFM-equation for ƒ 1 is found to be practically constant over the data range, in contrast to the large parameter variation required to fit the empirical ƒ 1- formula to these data.