Abstract:
A method for analyzing a turbulent fluid flow field includes the steps of: creating a mathematical model of a physical object; simulating a flow field around said model, wherein said flow field is at least partially turbulent; generating time series flow data output data representative of said flow field; and identifying repeating turbulent flow patterns in said flow data. These features are identified by selecting at least one frequency range of interest; filtering the flow data based on the frequency range; and observing coherent structure in the filtered data. The method may be implemented as a software program running on a computer.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS  
       [0001]     This application claims the benefit of U.S. Provisional Application No. 60/519,101, Filed Nov. 12, 2003. 
     
    
     BACKGROUND OF THE INVENTION  
       [0002]     This invention relates generally to computer analysis and more particularly to CFD analysis of aeroacoustic properties. Computational Fluid Dynamics (CFD) is a branch of fluid dynamics in which the physics of motion of particles of gases or liquids are simulated using computers. The physical volume of fluid and bounding surfaces are represented using a finite set of discrete elements, and mathematical equations relating the motion of particles are computed at each element. Commercial CFD software is currently used in industry for a broad range of applications, including internal flow of liquids and gases in pipes, machinery, ventilation ducts, etc., as well as external flow of air or water for application to land, air and sea vehicles.  
         [0003]     A common thread to uses of CFD in applications is the presence of turbulence in the results. Turbulence occurs naturally in fluids as a result of the complex non-linearities in the physical relationship between inertia of moving fluid particles, and the resistance to motion provided by friction (also called viscosity or viscous force). A fluid dynamic parameter called the Reynolds number is the ratio between inertial and viscous force. Every flow configuration has a critical Reynolds number above which the flow becomes turbulent, and below which the flow is smooth and ordered, or laminar. One definition of turbulence is flow that contains a range of spatial and temporal scales extending from the largest physical scales of the problem, represented by the size of the geometry and time scale of any forcing or motion, to the smallest possible scale allowed by fluid dynamics, which is called the Komolgorov scale, and is determined by the viscosity of the fluid. In physical applications, one sees large-scale fluid dynamic variations, superimposed by “eddies” of various sizes down to the smallest measurable scale. One representation of this superposition is a spectrum, computed from the kinetic energy of the flow at a single point in space as a function of time. This spectrum shows high energy contributions at some low frequency related to the scale of the physical problem, and then a “cascade” of energy to smaller and smaller scales (higher frequencies on the spectrum), with lower and lower energy levels.  
         [0004]     Some prior art CFD software attempts to represent turbulence in terms of its mean contribution to the flow using an aggregate “turbulence model”. In these software programs, the actual turbulence phenomenon is not visible in the results, and the results typically only show the flow time-averaged over long segments of time relative to the temporal scale of turbulence. However, modern commercial software is moving toward more intensive simulations of the physical phenomena involved in fluid dynamics, and including a significant portion of the turbulent energy spectrum in the resulting data. This means that the flow data contains spatial and temporal scales extending down to the smallest scales that can be resolved using the computational model of the fluid particles, while smaller scales yet beyond that level are considered only using a mathematical average effect.  
         [0005]     While current CFD software can produce this enormous wealth of data, tools to understand this data are lacking. In fact, the CFD software is still relatively young and improvements to the physical models are still underway to simply improve the aggregate predictions using these software tools. Meanwhile, users have available to them this turbulent data, and have interest in understanding the important flow features which have some bearing on performance of their products. Some particular areas of interest in which turbulent flow features at various scales are important are wakes, mixing, combustion, vibration and noise. Examples are the turbulent wake of an aircraft, vibration of rotating disk drives, and wind noise on an automobile. Accordingly, there is a need for software which provides analysis and visualization of turbulent CFD computational results.  
       BRIEF SUMMARY OF THE INVENTION  
       [0006]     The type of analysis that is needed for CFD measurement data fits in the category called “time-series analysis,” and also called “digital signal processing,” and is the processing of discrete time signals to quantify the fluctuations in those signals. This analysis can include time signals corresponding to an array of spatial locations so that the time signal at one point is related to the time signal at other (probably near-by) points. An example of digital signal processing is the processing of video signals: the color at each pixel is a signal that varies with time to represent a moving image.  
         [0007]     The inventor has discovered that repetitive or periodic flow features can be identified in a turbulent flow field, making it amenable to time-series analysis. Even though the exact same flow feature will not appear repeatedly on some interval, the flow structure occurs over and over in a similar fashion such that it can be described mathematically using periodic (repeating) functions. The energy at each point can be described as a Fourier series, which is a sum of sines and cosines in a series with increasing frequencies. The amplitude at each frequency forms an energy spectrum, and this energy spectrum is descriptive of the turbulence. This type of time-series analysis is called “spectral analysis.” It is aided by a computational algorithm called the Fast Fourier Transform, or FFT, and its inverse (the inverse FFT). The FFT algorithm converts a time-series into contributions at a discrete set of frequencies, with the inverse FFT converting the result back into a time-series. Understanding the contribution at each frequency is one useful approach to quantifying the fluctuations in the original time series. For convenience in analysis, the contributions can be grouped by dividing the spectrum into frequency bands, where each band contains multiple discrete frequencies computed from the FFT. In particular, “proportional bands” are often used, in which the ratio of maximum to minimum bounds of each band is some constant factor. For example, “octave bands” use a factor of 2 and “decade bands” use a factor of 10.  
         [0008]     The method and associated software described herein uses spectral analysis techniques to better understand turbulent flow data by dissecting it into various frequency bands. Then, visualization techniques are used to present the data to the user in order to reveal the nature of flow structures in each frequency band.  
         [0009]     According to one preferred embodiment of the invention, a method for analyzing a turbulent fluid flow field includes the steps of creating a mathematical model of a physical object simulating a flow field which is at least partially turbulent around the model; generating time series flow data output data representative of the flow field; and identifying repeating turbulent flow patterns in the flow data. These flow patterns are identified by selecting at least one frequency range of interest; filtering the flow data based on the frequency range; and observing coherent structure in the filtered data.  
         [0010]     According to another preferred embodiment of the invention, the flow patterns are flow patterns which cause aerodynamic noise.  
         [0011]     According to another preferred embodiment of the invention, the step of creating the model includes storing geometric data representing at least one surface of the physical object.  
         [0012]     According to another preferred embodiment of the invention, the surface is divided into a mesh of individual surface elements.  
         [0013]     According to another preferred embodiment of the invention, the step of simulating the flow field includes using a computational fluid dynamics software program to generate the flow data based upon preselected flow conditions.  
         [0014]     According to another preferred embodiment of the invention, the flow data contains a representation of time-dependent turbulent eddies. 
        the flow data comprises surface measurement elements and volume measurement elements, and each of the surface measurement elements represents a plurality of the surface elements.        
 
         [0016]     According to another preferred embodiment of the invention, the step of identifying the repeating turbulent flow patterns further includes computing a Fourier transform of the flow data to produce frequency domain data; applying a selected filter to the frequency domain data, based on the selected frequency range; and computing the inverse Fourier transform of the frequency domain data to produce output data at a range of time values. The output data contains coherent flow structure.  
         [0017]     According to another preferred embodiment of the invention, the repeating flow patterns are displayed in a human-readable format.  
         [0018]     According to another preferred embodiment of the invention, the human-readable format comprises a sequence of images representing the flow data at different time values.  
         [0019]     According to another preferred embodiment of the invention, the method steps are implemented by a software program including: a spectral analysis module for performing calculations on the flow data; a job server module adapted to maintain a list of pending calculation tasks and to forward the tasks to the spectral analysis module; and a project manager module operable to receive user commands and transmit instructions so the job server module.  
         [0020]     According to another preferred embodiment of the invention, a system for analyzing a turbulent fluid flow field includes: means for creating a geometric model of a physical object; means for applying a mesh pattern to the model; means for creating a simulated fluid flow field around the model, at least a portion of the flow field being turbulent; means for generating flow data representative of the flow field; and means for identifying repeating turbulent flow features in the flow data. The turbulent flow features are identified by filtering the flow data based on a selected frequency range and displaying the filtered data, whereby coherent structure may be observed therein.  
         [0021]     According to another preferred embodiment of the invention, the means for creating the geometric model includes a computer aided design software program.  
         [0022]     According to another preferred embodiment of the invention, the means for creating the simulated flow field comprises a computational fluid dynamics software program.  
         [0023]     According to another preferred embodiment of the invention, the means for identifying the repeating turbulent flow features includes a post-processing software program adapted to receive the flow data from the means for creating the simulated flow field.  
         [0024]     According to another preferred embodiment of the invention, the system further includes means for displaying the periodic flow features in a human-readable format.  
         [0025]     According to another preferred embodiment of the invention, a computer-readable medium includes program instructions executing on a computer for analyzing a fluid flow field. The program instructions perform the steps of: reading data comprising a model of a physical object; reading flow data representative of a flow field which is at least partially turbulent over the plurality of surface elements; and identifying repeating turbulent flow patterns in the flow data. The turbulent flow patterns are identified by filtering the flow data based on a selected frequency range and displaying the filtered data, whereby coherent structure may be observed therein.  
         [0026]     According to another preferred embodiment of the invention, the model includes geometric data representing at least one surface of the physical object. The surface is divided into a plurality of individual surface elements.  
         [0027]     According to another preferred embodiment of the invention, the flow data represents the effect of the surface on the simulated flow field.  
         [0028]     According to another preferred embodiment of the invention, the flow data is formatted as a plurality of surface measurement elements and volume measurement elements, each of the surface measurement elements representing a plurality of the surface elements.  
         [0029]     According to another preferred embodiment of the invention, the flow data contains a representation of time-dependent turbulent eddies.  
         [0030]     According to another preferred embodiment of the invention, the step of identifying the repeating flow patterns includes: selecting at least one frequency range of interest; computing a Fourier transform of the flow data to produce frequency domain data; applying a selected filter to the frequency domain data, based on the selected frequency range; and computing the inverse Fourier transform of the frequency domain data to produce output data at a range of time values. The output data contains coherent flow structure.  
         [0031]     According to another preferred embodiment of the invention, the program instructions include: a spectral analysis module for performing calculations on the flow data; a job server module adapted to maintain a list of pending calculation tasks and to forward the tasks to the spectral analysis module; and a project manager module operable to receive user commands and transmit instructions so the job server module. 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0032]     The subject matter that is regarded as the invention may be best understood by reference to the following description taken in conjunction with the accompanying drawing figures in which:  
         [0033]      FIG. 1  is a schematic view of a computer model of a vehicle for use in CFD analysis;  
         [0034]      FIG. 2  is block diagram showing the overall process of analyzing CFD data in accordance with the present invention;  
         [0035]      FIG. 3  is a schematic diagram showing the structure of post-processing software constructed in accordance with the present invention;  
         [0036]      FIG. 4  shows a project manager on-screen display window;  
         [0037]      FIG. 5  shows an on-screen representation of a job server window box;  
         [0038]      FIG. 6  shows a spectral analysis on-screen dialog box;  
         [0039]      FIG. 7  shows an “open project” on-screen dialog box;  
         [0040]      FIG. 8A  shows an “add file” on-screen dialog box;  
         [0041]      FIG. 8B  shows a detail screen of the “add file” on-screen dialog box of  FIG. 8A ;  
         [0042]      FIG. 9  shows a “modify node” on-screen dialog box:  
         [0043]      FIG. 10  shows a “view graph” module on-screen dialog box;  
         [0044]      FIG. 11  shows a process details on-screen dialog box;  
         [0045]      FIG. 12  is a block diagram showing the data flow from a job server and through a spectral analyzer module;  
         [0046]      FIG. 13  shows an input tab of a spectral analysis on-screen dialog box;  
         [0047]      FIG. 14  shows a calculation parameters tab of a spectral analysis on-screen dialog box;  
         [0048]      FIG. 15  shows a spectrum parameters tab of a spectral analysis on-screen dialog box;  
         [0049]      FIG. 16  shows a frequency band selection parameters tab of a spectral analysis on-screen dialog box;  
         [0050]      FIG. 17  is a block diagram showing the work flow through a calculation object;  
         [0051]      FIG. 18  is a block diagram showing a main software calculation loop;  
         [0052]      FIG. 19  is an example of a 2-D output graph produced by the post-processing software of the present invention;  
         [0053]      FIG. 20  is an example of graphic flow visualization results produced by the post-processing software of the present invention; and  
         [0054]      FIG. 21  is an example of graphic flow visualization results produced by the post-processing software of the present invention using filtering techniques. 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0055]      FIG. 1  illustrates a computer model  10  of a vehicle for use with known CFD software. CFD simulations are performed by importing the geometry relevant to the simulation into the CFD software and setting the various options for describing the imported geometry as fixed walls, inflow/outflow regions, porous regions, etc. In this process, the volume of fluid represented by the simulation is described, as well as the surfaces of any objects around or through which the fluid will flow. User input is also required to specify how to “discretize” the fluid volume and object surfaces. Discretizing the volume replaces the continuous 3-D region of space with a finite set of small volume elements  12 , each of which will be used to represent the average state of particles of fluid in that element. Depending on the CFD software, the discretization of the fluid volume may either require import of a mesh of volume elements, or specification of parameters for automatic meshing of the volume. Simple 3-D shapes such as cubes or pyramids are often used with automatic meshing schemes, while more complex curved elements are typically used with imported meshes. Similarly, discretizing the object surfaces replaces the surfaces with sets of small surface elements, typically flat polygons including triangles and arbitrary N-sided polygons. The state of surface conditions such as force and temperature are represented on each surface element. The model  10  shown in  FIG. 1  depicts a mesh pattern  14  of these discrete elements  10 .  
         [0056]     CFD simulation consists of computing values at all the discrete volume and surface elements at discrete increments in time called time steps. In one time step, motion of particles from one volume element to another, as well as interactions between particles and surface elements, are used to compute the state at the next time step. A number of time steps are simulated until the flow develops from some initially-prescribed state through a transient period until it reaches a representation of the actual flow phenomena of interest. Then, the simulation is continued and data is recorded for a period of time to obtain the final results.  
         [0057]     The user has control over how much data is captured by specifying how to average the simulation data. CFD calculations can contain tens of thousands of time steps, and the user typically desires to reduce this data into several hundred or thousand measurement frames, depending on the application, by averaging time steps together. Also, results are not typically output at each volume and surface element, but are averaged into “measurement” elements to reduce the size of the output. Each measurement element contains the data needed to compute the flow quantities of interest, such as pressure, density, temperature and velocity, and on the surface also contains the fluid forces on that surface measurement element. The fluid forces can be integrated over the surface of objects in the fluid to find the total forces and moments induced on the object by the fluid. Thus, the end result of a simulation is a set of measurement “frames”, each with fluid data at each volume and surface data at each surface measurement element.  
         [0058]     The present invention uses spectral analysis, digital signal processing, and Fourier Transforms to perform analysis of turbulent flow fields. These techniques are generally known in the art and will be briefly reviewed before describing the method of the present invention in detail.  
         [0059]     A Fourier series represents the time series using a summation of sines and cosines preceded by complex-valued coefficients. Each “mode” of the Fourier series represents a sine/cosine pair of a particular frequency. Using complex arithmetic, this can be shown as: 
 
 M   k ( t )= F    k   e   i 2πk t , where  F   k =real( F   k )+ i imag ( F   k ) and e ikt =cos(2 πkt )+ i  sin(2 πkt )  (1) 
 
         [0060]     In addition, since a time series consists of real values (not complex ones), there is a relationship between the negative frequency modes and positive frequency nodes for any Fourier series representing a time series: 
 
 M   k ( t )= F   -k   *   e   i 2πk t , where F k   *  is called the complex conjugate of  F   k  and is defined by  F   k   * =real( F   k )− i imag ( F   k )  (2) 
 
         [0061]     That is, 
 
F k =F -k   *   (3) 
        for a real-valued time series. The “temporal frequency”, f, of any Fourier mode is directly related to its mode index, k, as well as the time increment, Δt, between elements of the time series, and the total number of elements, N. The period, P, is calculated as: P=NΔt.        
 
         [0063]     The frequency, f, in units of “cycles per second”, or Hertz, Hz, is calculated as:  
             f   =       k   P     =     k     N   ⁢           ⁢   Δ   ⁢           ⁢   t                 (   4   )             
 
         [0064]     Using this description, a Fourier series is defined as a sum of N modes:  
             Fourier  series:                               ∑     k   =       N   /   2     +   1         N   /   2       ⁢       M   k     ⁡     (   t   )         =       ∑     k   =         -   N     /   2     +   1         N   /   2       ⁢       F   k     ⁢     ⅇ     ⅈ   ⁢           ⁢   2   ⁢           ⁢   π   ⁢           ⁢   kt                   (   5   )             
 
         [0065]     In this above series, N is assumed to be even, and the lower and upper limits on k are determined to produce a total of N modes (formulas for odd values of N are not shown here). A Fourier series represents a function of time, t, where the properties of this function are determined completely by the Fourier coefficients, F k . For any Fourier series, it is useful to define the minimum and maximum positive frequency values, as well as the bandwidth:  
               Minimum   ⁢           ⁢   frequency     ,       f   min     =     1     N   ⁢           ⁢   Δ   ⁢           ⁢   t         ,       for   ⁢           ⁢   k     =   1             (   6   )                 Maximum   ⁢           ⁢   frequency     ,       f   max     =     1     2   ⁢           ⁢   Δ   ⁢           ⁢   t         ,           (   7   )                 this   ⁢           ⁢   is   ⁢           ⁢   called   ⁢           ⁢   the   ⁢           ⁢   Nyquist   ⁢           ⁢   frequency     ,       for   ⁢           ⁢   k     =     N   2                             
 
 Bandwidth, Δf, is the difference between any two adjacent frequency values:  
               Δ   ⁢           ⁢   f     =       f   min     =     1     N   ⁢           ⁢   Δ   ⁢           ⁢   t                 (   8   )             
 
         [0066]     A Fourier series is defined as the Fourier transform of a time series if the complex Fourier coefficients, F k , are calculated from the time series values A(t j ) using:  
               F   k     =       ∑     j   =   0       N   -   1       ⁢       A   ⁡     (     t   j     )       ⁢     ⅇ       -   ⅈ     ⁢           ⁢   2   ⁢           ⁢   π   ⁢           ⁢     kt   j                     (   9   )             
 
         [0067]     These coefficients can be efficiently calculated using the popular “Fast Fourier Transform” algorithm.  
         [0068]     It is often required to represent a time series A(t j ), containing N values, with a smaller number of modes, K, where K&lt;N. The purpose of this representation is to provide a smoother, or averaged, representation of the time series. This is accomplished by simply averaging the Fourier transform over a series of “windows” of length K, from the time series. Typically, the windows are overlapped by 50% to remove certain biases in the results. This can be shown mathematically as a double summation:  
               F   k     =       1   B     ⁢       ∑     b   =   0       B   -   1       ⁢       ∑     j   =   0       K   -   1       ⁢       A   ⁡     (     t     j   +     bK   /   2         )       ⁢     ⅇ       -   ⅈ2     ⁢           ⁢   π   ⁢           ⁢     kt   j                         (   10   )             
        where in this summation, b is the “window number” and B is the number of windows. This summation shows that for each window the time series is shifted by b half-windows, by using the index j+bK/2 instead of j. The Fourier series is then represented in the same manner as described above, except that the number of modes is K rather than N:  
             Windowed  Fourier  series:                               ∑     k   =         -   K     /   2     +   1         K   /   2       ⁢       M   k     ⁡     (   t   )         =       ∑     k   =         -   K     /   2     +   1         K   /   2       ⁢       F   k     ⁢     ⅇ     ⅈ   ⁢           ⁢   2   ⁢           ⁢   π   ⁢           ⁢   kt                   (   11   )             
       
 
         [0070]     There are two additional signal-processing techniques used in conjunction with windowing. The first is called “trend removal”. The simplest form of trend removal is used here, in which the mean value of each window is removed, and the mean of the entire signal is reinstated in the F 0  coefficient at the end of the calculation. This procedure helps to account for slow drifts in the signal that could have a detrimental effect on the Fourier coefficients. To implement trend removal, the mean of each window is calculated. The “overbar” is used to represent the mean value:  
                 A   _     b     =       1   K     ⁢       ∑     j   =   0       K   -   1       ⁢     A   ⁡     (     t     j   +     bK   /   2         )                   (   12   )             
 
         [0071]     Then the Fourier coefficients are calculated using:  
                 F   k     =       1   B     ⁢       ∑     b   =   0       B   -   1       ⁢       ∑     j   =   0       K   -   1       ⁢       [       A   ⁡     (     t     j   +     bK   /   2         )       -       A   _     b       ]     ⁢     ⅇ       -   ⅈ     ⁢           ⁢     kt   j                   ,       for   ⁢           ⁢   k     ≠     0   ⁢           ⁢   and               (   13   )                   F   0     =       1   N     ⁢       ∑     j   =   0       N   -   1       ⁢     A   ⁡     (     t   j     )             ,       with   ⁢           ⁢   imaginary   ⁢           ⁢   part     =   0                           
 
         [0072]     The second signal processing technique greatly enhances the smoothing accomplished using windowing. In this method, a “window function” is used to taper the time series values down to zero at the beginning and end of each window segment. First, a window function is defined as:  
                 w   j     =     f   ⁡     (     j   K     )         ,       for   ⁢           ⁢   j     =   0     ,   1   ,   2   ,   …   ⁢           ,     K   -   1             (   15   )                 and  where       ⁢     f   ⁡     (   x   )       ⁢           ⁢     is  some  continuous  function  defined  for                               0   ≤   x   ≤   1     ,         such  that       ⁢     f   ⁡     (   0   )         =       f   ⁡     (   1   )       =   0                             
 
 where the values w j  are called the “weight” values. Finally, employing both trend removal and window functions, the Fourier coefficients are calculated using:  
                 F   k     =       1   B     ⁢       ∑     b   =   0       B   -   1       ⁢       ∑     j   =   0       K   -   1       ⁢         w   j     ⁡     [       A   ⁡     (     t     j   +     bK   /   2         )       -       A   _     b       ]       ⁢     ⅇ       -   ⅈ     ⁢           ⁢   2   ⁢           ⁢   π   ⁢           ⁢     kt   j                   ,       for   ⁢           ⁢   k     ≠     0   ⁢           ⁢   and               (   16   )                 F   0     =       1   n     ⁢       ∑     j   =   0       N   -   1       ⁢     A   ⁡     (     t   j     )                                 
 
         [0073]     In practice, several common and simple window functions are used, and there are two basic categories. The first category is used primarily for “spectral estimation,” in which the resulting Fourier series will be used primarily for producing a graph of amplitude of each mode vs. frequency using the power-spectral density function (see below). For this purpose, a great deal of smoothing may be used to wash out the details of the time signal and to just represent the overall frequency dependence. In technical terms, the phase information can be lost while the energy in each mode is retained. The class of window functions (described as f(x) on a range of x from 0 to 1) used for this application vary smoothly from a value of 0 at the ends (x=0 and 1) to a value of 1 at the center (x=0.5). These functions are named supposedly according to the first researcher to use them:  
             Bartlett  (saw-tooth  function):           (   17   )                 f   ⁡     (   x   )       =     1   -            2   ⁢   x     -   1                                    Welch  (parabola):           (   18   )                 f   ⁡     (   x   )       =     1   -              2   ⁢   x     -   1          2                               Hanning  (cosine):           (   19   )                 f   ⁡     (   x   )       =       1   2     ⁢     (     1   -     cos   ⁡     (     2   ⁢   π   ⁢           ⁢   x     )         )                             
 
         [0074]     The second class of window functions is intended to minimize smoothing while removing so-called “end effects” in the Fourier transform. End effects, also called Gibbs phenomenon, or aliasing error, occurs when there is a mismatch between the series values at the beginning and end of some of the windows. Since a Fourier series can represent only periodic functions, it produces a discontinuity between the beginning and end of the signal (if they are not matched) in order to force the signal to be periodic. This shows up as artificially high transform coefficients for the highest frequency modes. A window function alleviates the problem by tapering the ends of the window to zero, removing the mismatch. This can be accomplished with minimal smoothing by tapering to 0 only at the ends without changing the central part of the signal. In this application, one simple window function of this type is used:  
             End  taper  (trapezoidal):           (   20   )                 f   ⁡     (   x   )       =     {             x   /   p     ,       for   ⁢           ⁢   0     ≤   x   ≤   p                 1   ,       for   ⁢           ⁢   p     ≤   x   ≤     (     1   -   p     )                       (     1   -   x     )     /   p     ,       for   ⁢           ⁢     (     1   -   p     )       ≤   x   ≤   1                                     
 
         [0075]     Where p is a small number representing the fraction of the window to taper. For example, a 5% taper is accomplished using p=0.05. Also, the user can specify that no window function will be used, in which case the weights, w j , are all set to 1.  
         [0076]     The Fourier transform, without any smoothing, retains the total variation of the time series. The total variation of the signal is represented by its “variance”, described above as the function var(A). The following identity shows how the variance is related to the Fourier transform coefficients:  
                 var   ⁡     (     A   ⁡     (     t   j     )       )       =       [       ∑     k   =       N   /   2     -   1         N   /   2       ⁢       F   k     ⁢     F   k   *         ]     -     F   0   2         ,           (   21   )               where   ⁢           ⁢     F   k   *     ⁢           ⁢   is   ⁢           ⁢   the   ⁢           ⁢   complex   ⁢           ⁢   conjugate   ⁢           ⁢   of   ⁢           ⁢     F   k                           
 
         [0077]     This identity is commonly called “Parseval&#39;s relation”. The k=0 mode contribution is subtracted because it represents the mean value of the signal and does not contribute to the variance.  
         [0078]     Applying window functions can reduce the variation in the resulting Fourier series representation of the time series. Thus, a scaling factor correction is applied to retain the total power identity. The scaling factor is calculated as the sum of squares of the weight values:  
             W   =       1   K     ⁢       ∑     j   =   0       K   -   1       ⁢     w   j   2                 (   22   )             
 
         [0079]     Then the total power identity when using window functions is represented as:  
               var   ⁡     (     A   ⁡     (     t   j     )       )       =       1   W     ⁢       ∑     k   =       K   /   2     -   1         K   /   2       ⁢       F   k     ⁢     F   k   *                   (   23   )             
 
         [0080]     A time series can be decomposed into parts which sum to the total signal using the concept of frequency bands. A frequency band is defined using minimum and maximum positive mode indices, k min   +  and k max   + , where the “+” indicates the positive mode index. However, both the positive and corresponding negative modes are used together to represent the frequency band. The Fourier series for the portion of a signal belonging to a frequency band defined by indices k min   +  and k max   +  is: 
        Fourier series for a frequency band:  
                 ∑     k   =     k   min   +         k   max   +       ⁢     [         M   k     ⁡     (   t   )       +       M     -   k       ⁡     (   t   )         ]       =       ∑     k   =     k   min   +         k   max   +       ⁢     [         F   k     ⁢     ⅇ     ⅈ2π   ⁢           ⁢   kt         +       F     -   k       ⁢     ⅇ       -   ⅈ2π     ⁢           ⁢   kt           ]               (   24   )                 for   ⁢           ⁢     k   min   +       &gt;   0                           OR   ,       if   ⁢           ⁢     k   min   +       =   0     ,     the   ⁢           ⁢   Fourier   ⁢           ⁢   series   ⁢           ⁢     is:                                   F   0     +       ∑     k   =   1       k   max   +       ⁢     [         M   k     ⁡     (   t   )       +       M     -   k       ⁡     (   t   )         ]         =       F   0     +       ∑     k   =   1       k   max   +       ⁢     [         F   k     ⁢     ⅇ     ⅈ2π   ⁢           ⁢   kt         +       F     -   k       ⁢     ⅇ       -   ⅈ2π     ⁢           ⁢   kt           ]                               
       
 
         [0082]     This formula shows that setting k min   +  to 0 requires the Fourier series to include the mean value. Otherwise, for k min   + &gt;0, the mean value of the Fourier series will be 0.  
         [0083]     Due to the mathematical properties of sines and cosines, the total power identity applies equally well to any frequency range. This means that the total power for the range k min   +  to k max   + , where k min   + &gt;0, can be calculated using:  
               var   ⁡     (       A   ⁡     (     t   j     )       ,     from   ⁢           ⁢     k   min   +     ⁢           ⁢   to   ⁢           ⁢     k   max   +         )       =       1   W     ⁢       ∑     k   =     k   min   +         k   max   +       ⁢     [         F   k     ⁢     F   k   *       +       F     -   k       ⁢     F     -   k     *         ]                 (   25   )                       ⁢     =       2   W     ⁢       ∑     k   =     k   min   +         k   max   +       ⁢       F   k     ⁢     F   k   *                                         where  it  has  been  observed  that       ⁢     F   k   *       =     F     -   k                             
 
         [0084]     The result of this calculation is the variance of a part of the signal represented by a range of frequency modes. This variance is the same as for a different time series for which the Fourier coefficients for modes outside of this frequency range are all identically zero.  
         [0085]     The standard deviation for a frequency band is the square root of the variance, computed as above.  
         [0086]     The concept of power also applies on a mode-by-mode basis. The statistical variance due to a single mode is typically called the “power-spectral density”, psd, and is defined in such a way that it includes both the positive and negative modes:  
                 psd   k     =       2   W     ⁢     F   k     ⁢     F   k   *         ,       for   ⁢           ⁢   0     &lt;   k   &lt;     K   2       ,   and           (   26   )                   psd   k     =       1   W     ⁢     F   k     ⁢     F   k   *         ,       for   ⁢           ⁢   k     =       K   2     ⁢           ⁢   and                                 psd   0     =   0                         
        when K is even.        
 
         [0088]     Clearly, the total power identity can be expressed in terms of the power-spectral density:  
               var   ⁡     (     A   ⁡     (     t   j     )       )       =       ∑     k   =   0       K   /   2       ⁢     psd   k               (   27   )             
 
         [0089]     The power-spectral density for all positive values of k is typically shown in a plot vs. frequency (k is converted to frequency, in Hz, using f=k/KΔt).  
         [0090]     The power-spectral density for a given frequency range k min   +  to k max   + , where k min   + &gt;0, can be computed to represent the statistical variance in that frequency range, as above, by totaling the power-spectral density values for each mode:  
               total   ⁢           ⁢   psd     ,       from   ⁢           ⁢     k   min   +     ⁢           ⁢   to   ⁢           ⁢     k   max   +       =       ∑     k   =     k   min   +         k   max   +       ⁢     psd   k                 (   28   )             
 
         [0091]     Another useful definition of the power-spectral density for a frequency band is the mean value, rather than the total:  
               mean   ⁢           ⁢   psd     ,       from   ⁢           ⁢     k   min   +     ⁢           ⁢   to   ⁢           ⁢     k   max   +       =       1       k   max   +     -     k   min   +     +   1       ⁢       ∑     k   =     k   min   +         k   max   +       ⁢     psd   k                   (   29   )             
 
         [0092]     This definition is useful when overlaying plots of spectra that use different frequency band divisions—the mean psd values will overlay, while the total psd values will be shifted based on how many frequency values are combined into each band.  
         [0093]     It is common to apply a conversion to the power-spectral density into a logarithmic scale called the decibel scale, denoted dB. In this conversion, a reference value is needed, with the same units as the original time series. If the reference value is called A ref , the conversion to dB is computed as:  
               psd   ⁢           ⁢     (   dB   )       =     10   ⁢           ⁢       log   10     ⁡     (     psd     A   ref   2       )                 (   30   )             
 
         [0094]     The common application of this conversion is when the time series represents pressure values, p, in Pascals, Pa, as a function of time, t, in seconds. In this case, the time series can represent audible sound, if the pressure variation as a function of time, is of sufficient amplitude and in the appropriate frequency range for the human ear to perceive it as sound. The decibel scale was designed with this application in mind, and uses a reference value of pressure intended to be the lowest level of pressure variation that the human ear can perceive (in air), A ref =0.00002 Pa, when the time series represents pressure. In this application, psd(dB) is called the sound pressure level, or SPL.  
         [0095]     As seen above, the Fourier transform of a time series provides a convenient way to decompose the series into frequency bands, and to identify the contribution of each band to the total variance of the series. It is straight-forward to calculate the Fourier series for each frequency band as a function of time representing a portion of the original time series, that is limited in frequency range. This is also called a “band-pass filter”, because the Fourier series in that range can be interpreted as a signal which has been filtered to remove any frequencies lower than k min   +  and higher than k max   + . The same formula is used as for the Fourier series in a frequency band.  
         [0096]     To use the Fast Fourier transform algorithm to compute a band-pass filtered signal, first the Fourier transform coefficients, F k , are computed using the Fast Fourier transform. Then, the coefficients for k&lt;k min   +  and k&gt;k max   +  are set to zero. Then, the inverse Fast Fourier transform is used to reconstruct the component of the time signal at the same time values as the original signal, i.e., t j =jΔt. This process makes use of the Fast Fourier transform algorithm twice (transform, then inverse) to filter the signal.  
         [0097]     Alternatively, the same Fourier series can be calculated at arbitrary time values rather than at the original time values. The Fourier series is re-evaluated at a sequence of arbitrary time values by summing the contributions of each mode between k min   +  and k max   +  using direct computation of the series. This process takes significantly longer because the inverse Fast Fourier transform is not utilized. This direct approach to band-pass filtering is called “re-sampling”. Some reasons for using re-sampling rather than the inverse FFT method are to use much smaller time intervals to better show the effects of high frequency contributions smoothly, and to match comparison data points which are available at a different set of time values.  
         [0098]     The analytical technique described above may be applied to a model in a number of ways. For example, the necessary calculations could be executed manually. They could also be done with a known computer spreadsheet program or with a standard mathematics software package. However, the inventor has provided a unique CFD post-processing program for performing this analysis.  FIG. 2  illustrates the overall information flow through a post-processing software application representative of the present invention. A CFD application  16  of a known type is used to produce a flow simulation on a model of a physical structure, such as the computer model  10  depicted in  FIG. 1 . The data from the flow simulation is then passed to the post-processing software  18  in the form of a plurality of measurement frames, which are described in more detail below. The post-processing software  18  is used to process sets of measurement frames using various mathematical calculations. The post-processed results are then passed to an output module  20 , which can be used to produce graphs, images and movies showing flow features represented in the data. The CFD application  16 , the post-processing software  18  and the output module  20  may be separate, stand-alone software products, or they may all be incorporated into a single software package.  
         [0099]     Referring now to  FIG. 3 , the basic components of the post-processing software  18  include a project manager  22 , a spectral analyzer module  24 , a job server  26 , a view module  28 , an export text module  30 , and an export visualizer module  32 . These various components may be implemented as program subroutines within a larger integrated application.  
         [0100]     The job server  26  is a separate component in the post-processing software  18  that runs in the background alongside the project manager  22  to process jobs. The job server  26  maintains separate lists of jobs that have a status of “running,” “queued,” or “held.” When the list of “running” jobs becomes empty, the first job in the “queued” list is transferred to the “running” list and executed. Jobs in the “held” list remain there until activated by a user input signal, at which time they are transferred to the “queued” list. The job server  26  and the project manager  22  communicate with one another by the reading and writing of signal files and job files at a specified location on a file system  34 , which may be any type of data storage system. This way, the project manager  22  can display a list of running jobs, and provide user interface options for controlling which jobs are submitted and for sending signals to the job server  26 . The project manager  22  and job server  26  are designed using a simple client/server model, which can be extended to move the job server  26  to a remote computer if desired.  
         [0101]     When a job is started by the job server  26 , a separate process is started by the appropriate module, each of which is a separate component of the post-processing software  18 , and is started by specifying a job file with all of the user input parameters needed to perform the operation provided by the module. Calculations are performed by the spectral analyzer module  24 , which is the core computational kernel of the post-processing software  18 . The spectral analyzer module  24  is described in detail below. Calculation jobs can be time consuming for large input data sets, and the client/server approach facilitates the creation of a large set of calculation jobs to be performed one after the other in a job queue with no further user interaction.  
         [0102]     The project manager  22  is the user interface component of the post-processing software  18 . It may be used on various graphical computing platforms, for example Microsoft WINDOWS, LINUX and various forms of UNIX. Using the project manager  22 , the user creates project files by adding measurement files to a project list, and then for each measurement file, adding calculations to perform, as well as view and export files to create. The project manager  22  delegates all the calculations, view operations, and export operations to the job server  26 , which provides a job queue for processing all requests. A window in the user interface of the project manager  22  (described below) shows all jobs that are active in the job server  26 .  
         [0103]     The post-processing software user interface is enabled by running the project manager window  36 . As shown in  FIG. 4 , this window  36  contains three sections: the project browser  38  on the left pane, the job window  40  in the upper right pane, and the module window  42  in the lower right pane. The project manager window  36  also includes a main menu  44  and a toolbar  46 , with the look and feel of commonly-used, user-friendly software applications.  
         [0104]     The project browser  38  contains a multi-column tree list display  48 , showing a list of all files associated with the project in the left-most column, and additional information about each file in the other columns—the file path, type and status are shown. The files are organized in a 3-level tree. The first level is used for CFD measurement files, which are input files for calculations. The second level is shown as “branches” off the first level files, and represents calculation output files generated from each input file. The third level branches off of these calculation files, showing an additional layer of output files, which are files representing views or exported data. The user can select any file and perform operations by either right-clicking on the file using a mouse or other pointing device to produce a menu of actions related to that file, or by selecting a menu action from the main menu or toolbar. Using these menu actions, the user can add input files to the project and then specify how to run post-processing jobs that can create calculation output.  
         [0105]     The job window  40  shows a real-time list of calculation jobs that are running on the background job server  26 . The job server  26  starts whenever the project manager  22  is started, but is not closed until explicitly closed by the user, for example by hitting a “Close” button on a separate “Job Server” popup box  50 , (see  FIG. 5 ). As noted above, the job server  26  allows jobs to be run in a queue, one after the other until all are completed, without any further user intervention. Each “job” shows up as an item in the job window  40 . The user can select any job and perform menu actions related to that job, for example to terminate the job or to change its status in the queue.  
         [0106]     Finally, the module window  42  provides a convenient listing of all available post-processing tasks, divided into three categories, “Calculate”, “View” and “Export”, each represented by using a tab  52  in the module window  42  (see  FIG. 4 ). Each post-processing task activates the appropriate “module”, for example by double-clicking with a mouse or other pointing device on a task. The module provides a popup dialog box, with tabbed windows containing all of the needed user parameters for performing the post-processing task.  FIG. 6  shows an example of such a dialog box  54  generated by the spectral analyzer module  24 . Then, when the job is submitted, the appropriate module process is executed to perform the task, using the input parameter set from the dialog box, as described.  
         [0107]     The project manager window  36  (see  FIG. 4 ) includes the following user menus: File, Edit, Calculate, View, Export and Job. Menu actions are listed below. There are also toolbar buttons and right-click menus available, which contain the same actions as listed on the main menu. Each of the available menu actions is described individually according to the order presented to the user in the main menu, along with any dialog boxes that are activated with the action, in the following tables 1-6.  
                         TABLE 1                       FILE MENU COMMANDS                                Open   This action provides a standard file dialog box 56       Project   (see  FIG. 7 ) for selection of a project file, with           extension “.proj”. Opening a project file           populates the project browser window with a tree           listing of all files in the project, along with           information about each file. Each element in the           listing is also called a “node”. It also           stores in memory all of the user input parameters           associated with each node. The user can view those           input parameters by selecting the file and using           the “Edit | Modify Parameters” menu action.       Close/New   This action closes the current project and resets       Project   the project browser window 38 to an empty list,           ready for adding input files. If a modified project           is already open, the user is prompted to save the           project before closing.       Save   This menu action saves the current project with its       Project   current project file name. If the project was created           as a new project and has not yet been given a file           name, then the “Save Project As...” action           is called instead.       Save   “Save Project As” opens a common file dialog       Project   to select a directory and file name for saving the       As   project file.       Add File   Opens a custom “Add File” dialog 58, shown in             FIG. 8A , for selection of a CFD input file to add to           the project. The project browser is designed to           handle user input regardless of whether the actual           input files are available at the time of setting up           the post-processing jobs. Therefore, the user can           specify files and even directories that do not exist.           Also, the user has control over the storage of the           directory name of the file as an “absolute path”,           or as-a “relative path”, relative to the           directory in which the project file is stored. This           allows the same project file to be used in different           working directories to perform similar post-           processing.           The “Add File” dialog allows both the           file name and the path to be typed in directly.           It also contains a check-box for specifying whether           the absolute or relative path should be stored. If the           user checks or unchecks this box, the path field is           converted appropriately to an absolute or relative           path. Finally, if the user wants to select a file           using a standard file dialog, the “Select”           button opens a dialog box and then fills in the values           of the “file name” and “path” fields           when a file is selected.       Delete   When jobs are run from user parameter sets, output       Output   files are created that correspond to the nodes listed       File   on the project browser tree list. This menu action           is used to delete the output file so that the           calculation can be re-run with different parameters.       Exit   This action exits the project manager 22, leaving the           job server running. If the project has been modified,           the user is prompted to save it before closing.                  
 
         [0108]    
       
         
               
             
               
               
             
           
               
                 TABLE 2 
               
               
                   
               
               
                   
               
               
                 EDIT MENU COMMANDS 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 Modify 
                 This action allows the user to modify the file 
               
               
                 Node 
                 name and path for any node on the project browser 
               
               
                   
                 listing. It opens a dialog called the “Modify 
               
               
                   
                 Node” dialog 60 (see  FIG. 9 ), which is similar 
               
               
                   
                 to the “Add File” dialog but also has a button 
               
               
                   
                 labeled “Parameters,” only when the node 
               
               
                   
                 represents an output file and not an input file. 
               
               
                   
                 The Parameters button allows the user to open 
               
               
                   
                 the dialog corresponding to the Calculate, View 
               
               
                   
                 or Export module used to create this output file. 
               
               
                   
                 The user can then modify the parameter set 
               
               
                   
                 describing the post-processing operation. 
               
               
                 Modify 
                 This menu action also opens the dialog for the 
               
               
                 Parameters 
                 appropriate Calculate, View or Export module. 
               
               
                   
                 Choosing this action is the same as hitting the 
               
               
                   
                 “Parameters” button on the “Modify Node” 
               
               
                   
                 dialog. 
               
               
                 Copy 
                 Since each node represents either the selection 
               
               
                   
                 of an input file, or a post-processing action on 
               
               
                   
                 that input file, it can greatly speed up the 
               
               
                   
                 user&#39;s work to provide copying of nodes. If the 
               
               
                   
                 user selects a node and then the Copy action, 
               
               
                   
                 then that node, along with any dependent higher- 
               
               
                   
                 level nodes (called child nodes) are copied into 
               
               
                   
                 memory where they can be retrieved using the 
               
               
                   
                 Paste action. 
               
               
                 Paste 
                 “Paste” creates new nodes on the project browser 
               
               
                   
                 tree using the nodes copied using the Copy action. 
               
               
                   
                 If possible, the new nodes are created in the 
               
               
                   
                 location currently selected by the user, and file 
               
               
                   
                 names are automatically modified so that there 
               
               
                   
                 are no two identical files listed in the project 
               
               
                   
                 browser. In this way, the user can easily duplicate 
               
               
                   
                 the entry of parameters for similar post- 
               
               
                   
                 processing tasks. 
               
               
                 Remove 
                 This action removes the selected node, along with 
               
               
                 Node 
                 any child nodes. It prompts the user with a message 
               
               
                   
                 “Are you sure you want to delete this node and any 
               
               
                   
                 child nodes” before continuing. 
               
               
                 Remove 
                 This action removes only the child nodes of the 
               
               
                 Child 
                 currently selected nodes, after prompting the user 
               
               
                 Nodes 
                 for confirmation. This is useful for removing all 
               
               
                   
                 of the post-processing tasks for a specific input 
               
               
                   
                 file, while leaving the input file on the project 
               
               
                   
                 list. 
               
               
                   
               
             
          
         
       
     
         [0109]    
       
         
               
             
               
               
             
           
               
                 TABLE 3 
               
               
                   
               
               
                   
               
               
                 CALCULATE MENU COMMANDS 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 Spectral Analyzer | 
                 This action creates a new calculation file node, 
               
               
                 New Calculation 
                 as a level 2 node under the currently selected 
               
               
                   
                 input file (if none is selected, it simply 
               
               
                   
                 informs the user that an input node must be 
               
               
                   
                 selected first). Then, it opens the spectral 
               
               
                   
                 analyzer dialog 62 (see  FIG. 14 ). After the 
               
               
                   
                 dialog is closed, it stores all of the user 
               
               
                   
                 parameters in memory, associated with the node 
               
               
                   
                 on the project tree list. 
               
               
                 Spectral Analyzer | 
                 Like the previous function, this action opens 
               
               
                 Copy Last Calculation 
                 the spectral analyzer dialog 62. However, it 
               
               
                   
                 first sets the default values of all fields to 
               
               
                   
                 match the previous calculation, to speed user 
               
               
                   
                 entry for similar post-processing tasks. 
               
               
                   
               
             
          
         
       
     
         [0110]    
       
         
               
             
               
               
             
           
               
                 TABLE 4 
               
               
                   
               
               
                   
               
               
                 VIEW MENU COMMANDS 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 Open Viewer 
                 For level 3 output files created using a “View” 
               
               
                   
                 module. A separate window can be opened to view 
               
               
                   
                 the results using this command. A separate 
               
               
                   
                 viewing program will be opened with options for 
               
               
                   
                 viewing all types of “view” files created 
               
               
                   
                 by the post-processing software 18. For example, 
               
               
                   
                 for the “Graph Data” module, this command 
               
               
                   
                 will actually display the graph in a window, 
               
               
                   
                 whereas running a job with this module only creates 
               
               
                   
                 the “view” file. 
               
               
                 Graph Data | 
                 The “New Graph” command opens the dialog box 
               
               
                 New Graph 
                 64 (see  FIG. 10 ) for the “graph data” module, 
               
               
                   
                 then stores the user parameters from the dialog in 
               
               
                   
                 memory with the project, corresponding to a newly 
               
               
                   
                 created level 3 node. 
               
               
                 Graph Data | 
                 This command also opens the “graph data” module, 
               
               
                 Copy Last 
                 and it first sets the default values of all fields 
               
               
                 Graph 
                 to match the previous “Graph Data” task, to speed 
               
               
                   
                 user entry for similar post-processing tasks. 
               
               
                   
               
             
          
         
       
     
         [0111]    
       
         
               
             
               
               
             
           
               
                 TABLE 5 
               
               
                   
               
               
                   
               
               
                 EXPORT MENU COMMANDS 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 Text File | New 
                 This menu action opens a module (not shown) that 
               
               
                 Export File 
                 can export data from a “.calc” file into a text 
               
               
                   
                 file format for use by other applications or 
               
               
                   
                 custom graphing. 
               
               
                 Text File | Copy 
                 This menu action opens the same module, but fills 
               
               
                 Last Export 
                 in the parameter values using the previous 
               
               
                   
                 invocation of this module. 
               
               
                 CFD Meas. File | 
                 This action is used to create output from a “.calc” 
               
               
                 New Export File 
                 file for visualization. An export file that can be 
               
               
                   
                 read by the CFD visualization software is created 
               
               
                   
                 after the user specifies which results to visualize. 
               
               
                 CFD Meas. File | 
                 This command also exports data for visualization, 
               
               
                 Copy Last Export 
                 and uses the parameters from the last invocation 
               
               
                   
                 of this module to speed user input. 
               
               
                   
               
             
          
         
       
     
         [0112]    
       
         
               
             
               
               
             
           
               
                 TABLE 6 
               
               
                   
               
               
                   
               
               
                 JOB MENU COMMANDS 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 View Log 
                 The “View Log” command opens a scrollable text 
               
               
                   
                 window that shows the log file for any output file. 
               
               
                   
                 Log files are text files created when a job is 
               
               
                   
                 executed to create an output file. It also shows 
               
               
                   
                 the current status of a job (like “running” or 
               
               
                   
                 “queued”). The user can view the log file for 
               
               
                   
                 any level 2 or 3 project node, or for any job in 
               
               
                   
                 the Job Window. 
               
               
                 View 
                 This command opens a dialog box 65 (see  FIG. 11 ) 
               
               
                 Process 
                 for any selected job in the Job Window. It lists 
               
               
                 Details 
                 important information about the job, including the 
               
               
                   
                 current status, process id number, and file and path 
               
               
                   
                 names for the input file and output file. 
               
               
                 Cancel 
                 A job in the Job Window can have status of either 
               
               
                   
                 “running”, “queued”, or “held”. Queued 
               
               
                   
                 jobs will run one-by-one based on “first-in-first- 
               
               
                   
                 out” order. Held jobs will not run, but will 
               
               
                   
                 remain in the job queue until activated by the user, 
               
               
                   
                 using the “Jobs | Activate” command. The 
               
               
                   
                 “Cancel” command can be used to remove any 
               
               
                   
                 queued or held job from the job window. It can not 
               
               
                   
                 be used to stop a running job 
               
               
                 Hold 
                 This command changes the status on any queued to 
               
               
                   
                 job to “held”. 
               
               
                 Activate 
                 This command changes the status on any held job 
               
               
                   
                 to “queued”. 
               
               
                 Start Job | 
                 This command is used to start jobs after entering 
               
               
                 Current 
                 parameters for a post-processing module. The node is 
               
               
                 Node 
                 selected on the project tree list, and then this 
               
               
                   
                 command is used to start a job to generate the output 
               
               
                   
                 file for that node. When the job is started, it is 
               
               
                   
                 placed into the job queue (with status “queued”). 
               
               
                   
                 Since the job server is running as a separate process, 
               
               
                   
                 the job will remain in the queue until it runs, even 
               
               
                   
                 if the originating project is closed. 
               
               
                 Start Job | 
                 This command submits a batch of jobs for the 
               
               
                 All Node 
                 currently selected node and any dependent child 
               
               
                 Jobs 
                 nodes. For each node that does not have an 
               
               
                   
                 existing output file, a job is started to create 
               
               
                   
                 the output file. The user is informed, in a dialog, 
               
               
                   
                 of how many jobs were started, and then the jobs 
               
               
                   
                 are all listed with “queued” status in the 
               
               
                   
                 Job Window. 
               
               
                 Start Job | 
                 This command is similar to the previous one, except 
               
               
                 All Jobs 
                 that it searches the entire project tree for any 
               
               
                   
                 output nodes for which the output file does not 
               
               
                   
                 exist, and then it starts jobs for each of these 
               
               
                   
                 nodes. Note that it always starts jobs for level 2 
               
               
                   
                 jobs before starting any dependent level 3 jobs, 
               
               
                   
                 so the level 2 file will be available for further 
               
               
                   
                 processing. 
               
               
                 Terminate 
                 Finally, this command can be used to stop a running 
               
               
                   
                 job. The job is selected in the Job Window, and then 
               
               
                   
                 the “Terminate” action is selected. After prompting 
               
               
                   
                 for confirmation, the job is killed and removed from 
               
               
                   
                 the job queue. 
               
               
                   
               
             
          
         
       
     
         [0113]     The spectral analyzer module  24  (See  FIG. 3 ) is the technical core of the post-processing software  18 . The spectral analyzer module  24  is designed using an object-oriented model, and is best described, with reference to  FIG. 12 , in terms of the individual concepts represented by each object and the data flow between objects. First, user input parameters are obtained through a tabbed spectral analyzer dialog box  54  (see  FIG. 6 ) in the project manager window  36 , and those user parameters are stored in a project tree as a ParameterSet object  66  until a job is submitted to the job server  26 . Then, the job server  26  starts a new process for each job. For spectral analyzer jobs, the job server  26  starts the spectral analyzer module  24 , passing it a file containing the ParameterSet data. The spectral analyzer module  24  process creates a calculation object  68 , passing it the ParameterSet object  66 , and then executing the Calculation. The Calculation performs the requested operation and produces a CalcFile object  70 .  
         [0114]     User parameters for spectral analyzer calculations are obtained using the tabbed spectral analyzer dialog  54  (see  FIG. 6 ) in the project manager window  36 . The spectral analyzer dialog  54  contains tabs for input, calculation parameters, and volume mode output, as shown in  FIGS. 13, 6 , and  15 , respectively. A table for surface mode output parameters (not shown) is similar to that for the volume mode output parameters. Some of the parameters require specification of units, particularly units of length. The spectral analyzer module  24  supports CFD measurement file formats which provide conversion factors to convert all units into (at least) two units systems: meter-kilogram-second (MKS) and dimensionless. The MKS units are the standard metric dimensional units, with meters used for length. Dimensionless units are problem-dependent, and the measurement file must specify conversion factors to normalize quantities by an appropriate reference value. Most of the parameters are available for both measurement files representing fluid volume elements, and for measurement files representing surface elements. However, the output file parameters tab  72  (see  FIG. 6 ) has two different modes, one for each file type, since the type of output is slightly different for surface files than for volume files. The various input, output, and calculation parameters shown on the spectral analyzer dialog tabs are described in the following tables 7-10.  
                         TABLE 7                       INPUT PARAMETERS TAB                                InputFileName   The file name of the CFD measurement file           to post-process. The file name and path           are set by the user before the spectral           analyzer dialog 54 is opened, and are           shown in the spectral analyzer dialog 54           for reference.       InputFilePath   The directory path of the CFD measurement           file.       InputFrameFirst   The first frame of the measurement file           to use in the calculation.       InputFrameLast   The last frame of the measurement file to           use in the calculation.       InputFrameSkip   Increment value when looping from first           to last frame. Setting skip to 1 uses all           frames between first and last, setting to           2 skips every other frame, etc.       InputFrameAuto   If checked, then the values for           InputFrameFirst, InputFrameLast and           InputFrameSkip are set to 0, the last           frame available, and 1, respectively.       InputFrameTotal   Shows the total number of frames selected.       InputSubsample   Reduce the number of spatial points in the           measurement file by averaging adjacent           volume or surface elements together.           The reduction level is specified as the           Subsample value, where 0 means no reduction.       InputFileCrop   If checked, the measurement file region will           be cropped to the box generated by the Min           and Max (X, Y, Z) points (described/           specified below). Measurement elements           outside the cropping box will not be used.       InputFileCropUnits   unit of length used in specifying the Min and           Max (X, Y, Z) values. The values selectable           are “m” (meters) and “dimless”           (dimensionless).       InputFileXMin   X-coordinate of minimum corner of cropping box       InputFileXMax   X-coordinate of maximum corner of cropping box       InputFileXLength   XMax - XMin is shown in this field       InputFileYMin   Y-coordinate of minimum corner of cropping box       InputFileYMax   Y-coordinate of maximum corner of cropping box       InputFileYLength   YMax - YMin is shown in this field       InputFileZMin   Z-coordinate of minimum corner of cropping box       InputFileZMax   Z-coordinate of maximum corner of cropping box       InputFileZLength   ZMax - ZMin is shown in this field                  
 
         [0115]    
       
         
               
             
               
               
             
               
             
               
               
             
           
               
                 TABLE 8 
               
               
                   
               
               
                   
               
               
                 FLUID VOLUME MODE OUTPUT PARAMETERS TAB 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 OutputFileName 
                 The file name of the calculation file to create. 
               
               
                   
                 The file name and path are set by the user 
               
               
                   
                 before the spectral analyzer dialog 54 is 
               
               
                   
                 opened, and are shown in the spectral analyzer 
               
               
                   
                 dialog 54 for reference. 
               
               
                 OuputFilePath 
                 The directory path of the calculation file to 
               
               
                   
                 create. 
               
               
                 OutputFormat 
                 This is a parameter that determines how the 
               
               
                   
                 selected input measurement elements will be 
               
               
                   
                 used to create output points. The user 
               
               
                   
                 choices are as follows: 
               
             
          
           
               
                 “Field”: Create output points corresponding to all the 
               
               
                 selected input measurement elements. This selection is used for 
               
               
                 visualization rather than graphs, in that visualization requires 
               
               
                 values at all points. 
               
               
                 “3-D Rake”: Create output points in an evenly-spaced 
               
               
                 3-D grid arrangement, between the minimum and maximum (X, Y, Z) 
               
               
                 points specified below. This selection is used for graphs of 
               
               
                 calculated results vs. X, Y, Z, time or frequency. 
               
               
                 “Linear Rake”: Create output points evenly-spaced along 
               
               
                 a line between the minimum and maximum (X, Y, Z) points specified 
               
               
                 below. Also useful for graphs. 
               
               
                 “Profile”: Create output points at all measurement 
               
               
                 elements which lie on a straight line between the minimum and 
               
               
                 maximum (X, Y, Z) points specified below. Most useful for graphs 
               
               
                 vs. X, Y, Z or distance along the profile. 
               
               
                 “Probe”: Create a single output point by combining all 
               
               
                 input measurement elements using a volume-weighted average. This 
               
               
                 is useful when the measurement file includes the data from only 
               
               
                 a small spatial region, and is used to make graphs of calculated 
               
               
                 results vs. time or frequency at a single point in the volume. 
               
               
                 For a measurement file with a large spatial region, “Probe” 
               
               
                 can be used in conjunction with cropping the file to a small 
               
               
                 region to extract a single output point out of the measurement file. 
               
             
          
           
               
                 OutputRakeBoundingBox 
                 When specifying the value of OutputFormat 
               
               
                   
                 to be a 3-D or linear rake, this parameter 
               
               
                   
                 may be set to “yes” to cause the 
               
               
                   
                 post-processing software 18 to use the 
               
               
                   
                 entire exterior bounding box of the 
               
               
                   
                 measurement volume instead of the specified 
               
               
                   
                 (X, Y, Z) points. Also replaces the minimum 
               
               
                   
                 and maximum (X, Y, Z) points with the 
               
               
                   
                 values representing the exterior bounding 
               
               
                   
                 box. This option simplifies specification of 
               
               
                   
                 the rake bounds by filling in the bounds of 
               
               
                   
                 the original data. 
               
               
                 OutputRakeUnits 
                 Units of minimum and maximum (X, Y, Z) values. 
               
               
                   
                 Choices are “m” (meters) and “dimless” 
               
               
                   
                 (dimensionless). 
               
               
                 OutputRakeXMin 
                 X-coordinate of minimum rake point 
               
               
                 OutputRakeXMax 
                 X-coordinate of maximum rake point 
               
               
                 OutputRakeXLength 
                 XMax - XMin is shown in this field. 
               
               
                 OutputRakeXNum 
                 The number of rake points to use in 
               
               
                   
                 the X direction for 3-D rakes. 
               
               
                 OutputRakeYMin 
                 X-coordinate of minimum rake point. 
               
               
                 OutputRakeYMax 
                 X-coordinate of maximum rake point. 
               
               
                 OutputRakeYLength 
                 XMax - XMin is shown in this field. 
               
               
                 OutputRakeYNum 
                 The number of rake points to use in 
               
               
                   
                 the Y direction for 3-D rakes. 
               
               
                 OutputRakeZMin 
                 X-coordinate of minimum rake point. 
               
               
                 OutputRakeZMax 
                 X-coordinate of maximum rake point. 
               
               
                 OutputRakeZLength 
                 XMax - XMin is shown in this field. 
               
               
                 OutputRakeZNum 
                 The number of rake points to use in 
               
               
                   
                 the Z direction for 3-D rakes. 
               
               
                 OutputRakeLinearNum 
                 The number of rake points to use along 
               
               
                   
                 a line between the minimum and maximum 
               
               
                   
                 points for Linear rakes. 
               
               
                 OutputRakeProbeSize 
                 Distance from specified rake points 
               
               
                   
                 within which measurement element is 
               
               
                   
                 used, as defined by its center point. 
               
               
                 OutputRakeProbeUnits 
                 Units of probe size. Choices are “m” 
               
               
                   
                 (meters) and “dimless” (dimensionless). 
               
               
                 OutputRakeUseNearest 
                 If this box is checked, then probe size 
               
               
                   
                 is set to zero. 
               
               
                   
               
             
          
         
       
     
         [0116]    
       
         
               
             
               
               
             
               
             
               
               
             
           
               
                 TABLE 9 
               
               
                   
               
               
                   
               
               
                 SURFACE MODE OUTPUT PARAMETERS TAB 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 OutputFileName 
                 The file name of the calculation file to 
               
               
                   
                 create. The file name and path are set 
               
               
                   
                 by the user before the spectral analyzer 
               
               
                   
                 dialog is opened, and are shown in the 
               
               
                   
                 dialog for reference. 
               
               
                 OuputFilePath 
                 The directory path of the calculation 
               
               
                   
                 file to create. 
               
               
                 OutputFormat 
                 The output format is a parameter that 
               
               
                   
                 determines how the selected input 
               
               
                   
                 measurement surface elements will be 
               
               
                   
                 used to create output surface points. 
               
               
                   
                 The user choices are as follows: 
               
             
          
           
               
                 “Field”: Create output points corresponding to all the 
               
               
                 selected input measurement surface elements. This selection is used 
               
               
                 for surface visualization rather than graphs, in that visualization 
               
               
                 requires values at all surface points. 
               
               
                 “2-D Rake”: Create output points using a 2-D rake 
               
               
                 projected onto the surface. Each surface measurement file contains 
               
               
                 elements which represent surfaces in 3-D space. An algorithm is 
               
               
                 used to project specified rake points onto the surface. The 2-D 
               
               
                 rake is specified using the (X, Y, Z) coordinates of 3 corners of 
               
               
                 the rake region. The 3 corners define a planar parallelogram (the 
               
               
                 fourth corner is inferred from the first 3). The projection 
               
               
                 direction from the parallelogram to the surface is taken as the 
               
               
                 plus or minus normal vector to the plane of the parallelogram. The 
               
               
                 nearest surface point in either direction is used as the projected 
               
               
                 point. This selection is used for graphs of calculated results vs. 
               
               
                 X, Y, Z, time or frequency. 
               
               
                 “Linear Rake”: Same as 2-D Rake but generate points only 
               
               
                 along the diagonal of the parallelogram between points 1 and 3. 
               
               
                 “Profile”: Use corners 1, 2 and 3 to define a cutting 
               
               
                 plane, and select all surface elements cut by this plane. Output 
               
               
                 points are ordered so that graphs can be made of calculated values 
               
               
                 vs. X, Y or Z. 
               
               
                 “Probe”: Create a single output point by combining all 
               
               
                 input measurement elements using an area-weighted average. This is 
               
               
                 only useful when the measurement file includes the data from only 
               
               
                 a small surface region, and is used to make graphs of calculated 
               
               
                 results vs. time or frequency at a single point on the surface. 
               
             
          
           
               
                 OutputRakeUnits 
                 Units of corner 1, 2 and 3 (X, Y, Z) 
               
               
                   
                 values. The choices are “m” 
               
               
                   
                 (meters) or “dimless” (dimensionless). 
               
               
                 OutputRakeCorner1X 
                 X-coordinate of corner 1 
               
               
                 OutputRakeCorner1Y 
                 Y-coordinate of corner 1 
               
               
                 OutputRakeCorner1Z 
                 Z-coordinate of corner 1 
               
               
                 OutputRakeCorner2X 
                 X-coordinate of corner 2 
               
               
                 OutputRakeCorner2Y 
                 Y-coordinate of corner 2 
               
               
                 OutputRakeCorner2Z 
                 Z-coordinate of corner 2 
               
               
                 OutputRakeCorner3X 
                 X-coordinate of corner 3 
               
               
                 OutputRakeCorner3Y 
                 Y-coordinate of corner 3 
               
               
                 OutputRakeCorner3 
                 Z-coordinate of corner 3 
               
               
                 OutputRakeSide12Num 
                 The number of rake points to use between 
               
               
                   
                 corners 1 and 2 for a 2-D rake. 
               
               
                 OutputRakeSide23Num 
                 The number of rake points to use between 
               
               
                   
                 corners 2 and 3 for a 2-D rake. 
               
               
                 OutputRakeLinearNum 
                 The number of rake points to use along a 
               
               
                   
                 line between corners 1 and 3 for a Linear 
               
               
                   
                 rake. 
               
               
                 OutputRakeProbeSize 
                 Distance from projected surface points 
               
               
                   
                 within which surface elements can be 
               
               
                   
                 included in that point using an area- 
               
               
                   
                 weighted average. If this distance is 
               
               
                   
                 zero or smaller than the size of a 
               
               
                   
                 measurement element, then only the 
               
               
                   
                 nearest measurement element is used, as 
               
               
                   
                 defined by its center point. 
               
               
                 OutputRakeProbeUnits 
                 Units of probe size. Choices are “m” 
               
               
                   
                 (meters) and “dimless” (dimensionless). 
               
               
                   
                 OutputRakeUseNearest: If this box is 
               
               
                   
                 checked, then probe size is set to zero. 
               
               
                   
               
             
          
         
       
     
         [0117]    
       
         
               
             
               
               
             
               
             
               
               
             
               
             
               
               
             
               
             
               
               
             
               
             
               
               
             
               
             
               
               
             
           
               
                 TABLE 10 
               
               
                   
               
               
                   
               
               
                 CALCULATION PARAMTERS 
               
               
                   
               
             
             
               
                   
               
             
          
           
               
                 CalcFunction: 
                 One of the calculation types is selected by the 
               
               
                   
                 user in a tree list box. The spectral analyzer 
               
               
                   
                 module 24 performs a single calculation on the 
               
               
                   
                 input data for each calculation file, but can 
               
               
                   
                 record any number of variables and frequency bands 
               
               
                   
                 in each calculation file. The categorized 
               
               
                   
                 calculations available are as follows: 
               
             
          
           
               
                 (Extract calculations) 
               
             
          
           
               
                 Sample: 
                 create output signal matching input signal at each 
               
               
                   
                 measurement point 
               
               
                 Sample and remove 
                 remove mean from input signal 
               
               
                 mean: 
               
             
          
           
               
                 (Statistics calculations) 
               
             
          
           
               
                 Mean: 
                 compute the mean of the signal 
               
               
                 Standard deviation: 
                 compute the standard deviation of the signal 
               
               
                 Variance: 
                 compute the variance of the signal (same as 
               
               
                   
                 standard deviation squared) 
               
             
          
           
               
                 (Frequency band statistics calculations) 
               
             
          
           
               
                 Standard deviation: 
                 divide the input signal into separate signals for 
               
               
                   
                 each frequency band, and report the standard 
               
               
                   
                 deviation of each band 
               
               
                 Variance: 
                 same as standard deviation, but report the 
               
               
                   
                 variance of each band. 
               
             
          
           
               
                 (Spectrum Calculations) 
               
             
          
           
               
                 Power-spectral 
                 compute the power-spectral density directly from 
               
               
                 density (PSD): 
                 the FFT (see formulas), and then combine values 
               
               
                   
                 together into frequency bands and report a value 
               
               
                   
                 for each band. 
               
               
                 Complex Fourier 
                 output the real and imaginary values of the 
               
               
                 transform: 
                 computed FFT directly. 
               
             
          
           
               
                 (Filter calculations) 
               
             
          
           
               
                 Band-pass filter: 
                 divide the input signal into separate signals for 
               
               
                   
                 each frequency band, and output those signals 
               
               
                   
                 using an inverse Fourier transform, possibly 
               
               
                   
                 resampling the signals at specified time values 
               
               
                 CalcVariables: 
                 The fluid and surface variables stored in the 
               
               
                   
                 input file for each measurement element are listed 
               
               
                   
                 in the upper list box. The command buttons Add, 
               
               
                   
                 Remove, Up and Down allow the user to build a list 
               
               
                   
                 of variables in the lower box, and to specify the 
               
               
                   
                 order of the variables. 
               
               
                 CalcVariableUnits: 
                 Units of fluid the surface variable to add to the 
               
               
                   
                 lower list box. With this selection, the user can 
               
               
                   
                 add variables in either MKS or dimensionless units 
               
               
                   
                 to the calculation in any order. 
               
               
                   
               
             
          
         
       
     
         [0118]     The spectrum analysis dialog  54  also includes a spectrum parameters tab  74  (see  FIG. 15 ). This tab  74  is only activated for calculations in the frequency band statistics, spectrum or filter calculation categories, all of which require Fast Fourier Transforms (FFT&#39;s) in the calculation.  
         [0119]     The post-processing software  18  utilizes “windowing”. This is a known method of computing FFT&#39;s for the purpose of estimating a spectrum from a discrete number of points. In this method, the time signal is divided into smaller “windows” of specified size, each overlapping by 50%. The FFT is computed for each window separately and then averaged to smooth out random errors in the spectrum due to finite signal length. In addition, each window segment is optionally multiplied by a window function which tapers to zero at the beginning and end values, with some function with maximum value one in between. Using a window function that tapers smoothly to zero at each end greatly enhances the smoothing of the spectrum. The spectrum parameters tab  74  (see  FIG. 15 ) includes specification of both the window width and the window function, as described in the following Table 11.  
                                               TABLE 11                       SPECTRUM PARAMETERS                                SpectrumWindowWidthMethod:   The window width can be determined in           several ways depending on user selection:            Maximum:       If the user selects this option, a single window of width equal to the       number of available frames is used. Only a single FFT is performed at       each output point.       Maximum Optimal:       This option is similar to Maximum in that only a single FFT window is       used. However, FFT calculations are more efficient for a window width       equal to the product of small numbers, like 2, 3, 4 and 5. If Maximum       Optimal is selected, the nearest smaller value than the maximum that       is a product of powers of 2, 3, 4 and 5 is selected to improve the       efficiency of the FFT calculation.       Smoothing Optimal:       For this option, a window width is selected which is approximately       25% of the number of available frames and is also a product of powers       of 2, 3, 4 and 5. Since each window overlaps by 50%, this will       produce (at least) seven overlapping windows in the calculation.       Custom:       The user can also directly specify the window width by selecting this       option and filling in the window width in the SpectrumWindowWidth       field.            SpectrumWindowWidth:   activated when SpectrumWindowWidthMethod           is set to “custom”, for specifying the           custom window width.       SpectrumFramesAvailable:   shows the number of frames available, equal           to InputFrameTotal.       SpectrumWindowType:   This option allows selection of one of several           standard window functions used for smoothing           spectral calculations. The functions, w(x) are           specified on the range x = [0, 1], and           have a maximum value of 1.       None:   no window function is used. that is, the weight           function is equal to 1 everywhere       Hanning:   cosine window function: w(x) =           0.5*(1 + cos(2*pi*x))       Welch:   parabolic window function: w(x) = 1 − (2x − 1){circumflex over ( )}2       Bartlett:   saw-tooth window function:           w(x) = 2x for x = [0, 0.5]           w(x) = 2(1 − x) for x = [0.5, 1]       End taper 5%:   trapezoidal window function:           w(x) = 20x for x = [0, 0.05]           w(x) = 1 for x = [0.05, 0.95]           w(x) = 20(1 − x) for x = [0.95, 1]       SpectrumValueType:   This selection is activated only for a power-           spectral density calculation. The power-           spectral density (PSD) is usually reported in           decibels (dB), but this group allows other           options for creating output starting with the raw           PSD value:            Value: report the raw PSD value       Log10: report the log, base 10, of the PSD value       Fraction of total power: normalize PSD by the total power of the       signal, which equals both the statistical variance, and the sum of       all PSD values.       dB: convert the PSD value into decibels using dB = 10 log       (PSD/ref{circumflex over ( )}2), where “ref” is an appropriate reference value for       the fluid variable represented in the input signal. In practice, a       reference value is only needed when pressure in Pascals (MKS units)       is used as the input signal, as pressure has a physical meaning in       acoustics. In this case, the standard pressure reference value of       0.00002 Pa is used, as a pressure fluctuation of this amplitude is       considered to be the threshold of human hearing. In all other cases,       a reference value of 1 is used.       dBA: A-weighted decibels. Multiply the PSD by a standard function       called the “A-contour” which is a function of frequency, and       weights the PSD according to human perception of loudness       (see formulas). Then convert to decibels.                  
 
         [0120]     The FFT includes values for a discrete set of frequencies, f k =k*bandwidth (in Hertz), for k=0, 1, 2, . . . ,K, where K=N/2 if N is even and K=(N+1)/2 if N is odd, and where N is the window width. The bandwidth is computed from the input signal&#39;s total time interval, P, in seconds. That is, bandwidth=1/P. The frequency f 0 =0 represents the mean of the signal. The frequency f 1  is equal to the bandwidth, 1/P, and represents the minimum frequency that can be represented in the FFT window. The frequency f K  is equal to P/(2N)=1/(2*time interval between frames). This is the so-called Nyquist criterion for the maximum frequency represented in a time series.  
         [0121]     The frequency band selection parameters are chosen by the user on the frequency band selection tab  76  (see  FIG. 16 ). The parameters are as shown in the following Table 12.  
                             TABLE 6                       FREQUENCY BAND SELECTION PARAMETERS                                    BandsFreqMin   report only frequency values higher than the               specified minimum.           BandsFreqMinAuto   fill in the BandsFreqMin field with the               k = 1 frequency from the FFT.           BandsFreqMax   report only frequency values lower than the               specified maximum.           BandsFreqMaxAuto   fill in the BandsFreqMax field with the               k = K frequency from the FFT.           BandsDeltaF   shows the bandwidth value in Hertz.           BandsDivisionsType   This option determines how the output is               divided into frequency bands. For spectrum               plots it is common to use a large number of               frequencies, and combining results into               coarser frequency bands is not necessary               (though it can be useful). However, for               visualization and other ways of viewing the               data, the results must be represented using               a limited number of bands. In the field of               acoustics it is common to divide the               frequency range into “octaves” in               which the range covered by each band               doubles relative to the previous band.               The formula for this is: f i+1  = alpha*f i ,               where f i  is the minimum frequency of the               “i”th output band, and where alpha =               2 for octave bands. Finer divisions are               obtained by dividing octaves into thirds               or twelfths, using alpha = 2 1/3  and               alpha = 2 1/12 , respectively. In the present               post-processing software 18, decade and               one-tenth decade bands are also provided,               for which alpha = 10 and alpha = 10 1/10 ,               respectively. The user choices for this               option are as follows:           Single band   Combine results from all FFT frequency bands               between the specified minimum and maximum               into one result.           Every FFT   Report separate results for each FFT           band   frequency band between the specified minimum               and maximum values.           Octave   Combine FFT frequency bands into octave bands               between the specified minimum and maximum               values.           One-third   Combine FFT frequency bands into one-third           octave   octave bands between the specified minimum               and maximum values.           One-twelfth   Combine FFT frequency bands into one-twelfth           octave   octave bands between the specified minimum               and maximum values.           Decade:   Combine FFT frequency bands into decade bands               between the specified minimum and maximum               values.           One-tenth   Combine FFT frequency bands into one-tenth           decade:   decade bands between the specified minimum               and maximum values.           Custom   Combine FFT frequency bands into arbitrary               list of bands, specified using min and               max values.           BandsCustomMinValues   The buttons Add Range, Clear All, Add New,           and   Remove, Up and Down allow the user to           BandsCustomMaxValues   create and edit a list of frequency band               minimum and maximum values. Those values are               stored as two vectors in the ParameterSet               object.           BandsSummationType   This option is only activated for a power-               spectral density calculation (PSD). For               PSD, the value reported for each frequency               band can be computed several ways:           Total   commonly called energy scaling, the PSD               values are summed from each FFT band and               reported as a total in each output band. In               this method, the total PSD for the entire               spectrum remains constant.           Mean   also called amplitude scaling, the PSD               values from the FFT bands are averaged to               combine them into output bands. Using this               method, the shape and height of the spectrum               curve will remain constant with different               ways of dividing the output frequency bands.           Square root   by definition, the PSD represents the           of total   statistical variance in each FFT band, and               when totaled into output bands, also               represents the statistical variance in those               bands. The square root of the total therefore               represents the standard deviation of the               signal in each band.                      
 
         [0122]     Referring to Table 13 below, the filtering parameters are set in the filtering parameters tab  78  in the spectrum analysis dialog  54 . This tab  78  provides options for the band-pass filter calculation. Results are produced at each frequency band by reconstructing the portion of the time signal corresponding to that band. The reconstructed flow is output at a series of time frames, and can be used for animated visualizations of the flow structure in each frequency band. However, the input signal often has many more frames than needed for animations. Accordingly, the options in this tab help the user to limit the number of output frames to the desired number.  
         [0123]     There are two ways to calculate the reconstructed flow for each frequency band. In the first method, the frequencies outside of the desired band are set to zero and an inverse FFT is used to produce a new time series representing the filtered signal at the same time values as the original signal. Then, the desired values can be extracted from the filtered signal and written to the output file. This is the method used if the FilterResampleType option is set to “use original time values.” The number of output frames can be limited by specifying First, Last and Skip values for the output frames. When the “use original time values” option is selected, the real number fields below the “Re-sample . . . ” option are used to provide useful feedback about the resulting time signal. The filtered signal start time, frame time step, and number of frames, and minimum and maximum frequencies represented using those frames, are displayed as read-only fields. For reference those values are also shown for the original input signal.  
         [0124]     On the other hand, if the user prefers to generate results at specified time values that might be different than the input time values, the “Re-sample . . . ” option provides a different method of reconstructing the flow. In this method, a direct summation of the contribution of each frequency is calculated at arbitrary time levels. This method is much slower than that the previous method because it does not take advantage of the inverse Fast Fourier Transform. When this option is selected, the fields for the filtered signal start time, frame time step, and number of frames, are used as input fields to specify the selected frames. The minimum and maximum frequencies represented using the specified time values are still reported in those fields.  
                             TABLE 13                       FILTERING PARAMETERS OPTIONS TAB                                    FilterResampleType   User selects either “Use original               time values,” or “Re-sample at               new time values (Fourier reconstruction).”           FilterOriginalFirst   Specifies which frame of the input signal               to use as the first frame for output.           FilterOriginalLast   Specifies which frame of the input signal               to use as the last frame for output.           FilterOriginalSkip   Increment value when looping from first               to last frame.           FilterResampleStart   If “Use original time values” is               selected, this value is computed to show               the time value of the first selected               output frame. Otherwise, can be edited               to specify an arbitrary start time.           FilterResampleFrameStep   If “Use original time values” is               selected, this value is computed to show               the time increment between selected               output frames based on the specified               Skip value. Otherwise, this value can be               edited to specify an arbitrary time               increment.           FilterResampleNumFrames   If “Use original time values” is               selected, this value is computed to show               the number of frames selected using the               First, Last and Skip values. Otherwise,               can be edited to specify an arbitrary               number of frames           FilterResampleFreqMin   Shows the minimum frequency that can be               represented by the selected output time               values. This is calculated as FreqMin =               1/(total time represented) =               1/(FrameStep*NumFrames).           FilterResampleFreqMax   Shows the maximum frequency that can be               represented by the selected output time               values. This is calculated as FreqMax =               1/(2*FrameStep). This is the so-called               Nyquist criterion.           FilterInputSignalStart   Shows the start time of the input signal               starting at the start frame specified in               the Input File tab.           FilterInputSignalFrameStep   Shows the time increment between input               frames, using the skip value specified               in the Input File tab.           FilterInputSignalNumFrames   Shows the total number of frames               available from the Input File tab.           FilterInputSignalFreqMin   Shows the minimum frequency that can be               represented by the input signal.               Calculated as FreqMin = 1/(total time               represented) = 1/(FrameStep*NumFrames).           FilterInputSignalFreqMax   Shows the maximum frequency that can be               represented by the input signal.               Calculated as FreqMax = 1/(2*FrameStep).               This is the so-called Nyquist criterion.                      
 
         [0125]     After the parameters described above are entered, the calculation is invoked as follows. User input parameters from the spectral analyzer dialog  54  are stored in a generic ParameterSet object, which stores a list of name-value pairs called “Attributes”, each representing an input parameter. Each attribute has a name represented by an arbitrary string. For example, for the input parameter InputFrameFirst, the name “input_frame_first” is used. The value of each attribute is stored as a string, and so can represent parameters of any type. Numeric values are converted into text, like “2” or “0.01234”, for storage as attributes, and vector values are converted using the format “{ 1 ,  2 ,  3 ,  4 }”. Yes/no values from check-boxes are stored as “true” or “false”, and button selections and drop-down list selections are stored as integers starting with 0, representing the selected item. The ParameterSet object is written to a file to be used as the input file for the spectral analyzer module  24 . The attribute list for each ParameterSet is also added to the project file in the project manager  22 .  
         [0126]     Within the spectral analyzer module  24 , the ParameterSet object is read from the input file. Then, a Calculation object is initialized with the ParameterSet, and then executed by the module. The workflow within the Calculation object is described below with reference to  FIG. 17 .  
         [0127]     The user parameters, which are set in the spectral analyzer dialog  54  and then passed to the Calculation object as a ParameterSet object, are all used by the Calculation object in the course of performing the requested calculation. Many user options are implemented in the main objects used by the Calculation, and these are described in more detail below. The process flow within the Calculation object is the same for each type of calculation, except that the first two categories of calculations, “Extract” and “Statistics”, do not require the FFT, and do not use division into frequency bands. The process flow and the execution of each calculation type are described below. First, all of the needed objects are initialized, then the calculation loop is initiated. Finally, the results are written to a calculation file. A log file is written during the calculation process to provide information to the user about the calculation that was performed. It also records the “percent completed” as the calculation progresses.  
         [0128]     First, at block  99  the CFD measurement file specified by the InputFileName and InputFilePath parameters is opened by creating a MeasFile object  100  and calling the “open” operation for that object. This object handles the user options for setting the desired input frames using First, Last and Skip values. Each measurement element in the file is represented by a point number, which is an integer from 0 to the total number of points, minus 1. The MeasFile object provides data for the Calculation object using the concept of a time series, represented by the TimeSeries object. This object contains a vector of values representing a time signal at a single measurement point, and the additional data members, StartTime, FrameStep and NumFrames which allow computation of the time value in seconds for each frame. The TimeSeries object is the basic data structure used by the Calculation both for input from the measurement file and for performing the calculation. The MeasFile object provides an operation called “getTimeSeries” which requires the point number as an argument, as well as an object representing which fluid or surface variable is desired, and returns a TimeSeries object with the time signal for that variable at the specified point. Since CFD results are stored “frame-by-frame” in measurement files, reading a complete time series out of a measurement file requires reading the entire file. To make this more efficient, the MeasFile object buffers raw data from a large number of measurement points in memory, so that most calls to “getTimeSeries” will be performed without need for reading the measurement file, assuming that points are read in order.  
         [0129]     Next, the output points are determined. The Calculation object does not use the MeasFile object directly. Instead of working with “input” points from the measurement file, the calculation only needs time signals for each “output” point based on the user options for crop, subsample and output format in the spectral analyzer dialog  54 . The crop and subsample options reduce the number of points in the measurement field. The output format determines whether a rake of points, a profile, or the entire field will be used. All of these options are handled by the OutputFormat object  110 , which is described below. This object is created and passed the MeasFile object  100 . Then, the OutputFormat object  110  provides the “numOutputPoints” function as well as a “getTimeSeries” function that operates exactly like the MeasFile function of the same name, but returns a TimeSeries for each output point to be included in the calculation. It also requires specification of the fluid or surface variable.  
         [0130]     For the three calculation categories that require FFT&#39;s, “Band Statistics,” “Spectrum,” and “Filter,” the FFTCalculator and FreqBands objects  112  and  114  are created according to the user options, as described below. The FFTCalculator determines the number of frequencies that will be used in the FFT, based on the user specification of the FFT window, and this value is available using the “numModes” function. After creation, the FFTCalculator object provides the “transform” operation which takes a TimeSeries object as a parameter. The FFT transform function converts a time series, which is a set of real values, into an array of complex values that is a function of the frequency index, k (also called the mode number) rather than time. After the “transform” operation has been called in the calculation, the results needed for the calculation are readily available using the functions provided by FFTCalculator. These are summarized in the following Table 14.  
                         TABLE 14                       FFTCALCULATOR FUNCTIONS                                “getPSD”,   returns the PSD at the given frequency,       argument integer k   represented by index k.       “getFT”,   returns a complex number representing       argument integer k   the Fourier transform at the given           frequency.       “getTotalPSD”,   returns the power-spectral density       two integer arguments,   summed over the frequencies from k min         k min  and k max     to (and including) k max .       “invert”,   returns a TimeSeries which contains       two integer arguments,   the inverse FFT obtained by including       k min  and k max     only frequencies from k min  to (and           including) k max , but with all others           set to zero.       “evaluateInverse”,   returns a single value which is the       one real number argument,   inverse Fourier transform evaluated       t, representing a time value,   only at the specified time value, and       and two integer arguments,   including only frequencies from k min  to       k min  and k max     (and including) k max .                  
 
         [0131]     Once the FFTCalculator object  112  is created, the number of frequencies used in the FFT is known. This value, along with user parameters specifying how to divide the frequency range, is used to create a FreqBands object  114 . This object simply provides three functions which allow looping through the selected frequency bands, which are as follows: “numBands”: returns the number of frequency bands selected by the user; “getModeStart”, argument is the band index, from 0 to numBands, minus 1, returns the frequency index, k, for the first FFT frequency which is included in the specified band; and “getModeEnd”, argument is the band index, from 0 to numBands, minus 1, returns the frequency index, k, for the last FFT frequency which is included in the specified band.  
         [0132]     For all calculation types, the final object to be created in the initialization phase is the CalcBuffer  116 . This object creates a temporary output file that stores results as a set of TimeSeries arrays. The TimeSeries are indexed by three indices in the CalcBuffer object  116 : point number, variable number, and frequency band number. As each TimeSeries is processed in the calculation, the result is written into the CalcBuffer object  116 , which then stores it in the temporary output file, rather than in memory. For calculations that produce a single value from a TimeSeries (like the power-spectral density), an output TimeSeries is still used, with only a single frame.  
         [0133]     After initialization, the calculation proceeds using a main loop  118  with two levels. The calculation is illustrated in  FIGS. 17 and 18 . The OutputFormat object  110  is used to define the outer loop through all of the output points. The “numOutputPoints” function provides the number of points, and the point index is used to obtain the TimeSeries for each point. In the spectral analyzer dialog  54 , the user selects any number of fluid or surface variables to use for the calculation. The second-level loop in the calculation loops through all the selected variables, using a variable index starting at 0. Since the MeasFile stores raw data from the measurement file, any number of variables can be obtained at a given point with only a single read operation. Inside the second-level loop, the call to “getTimeSeries” produces the time series for each output point and input variable. The calculation flow splits according to calculation category at this point in the execution. For the extract and statistics calculation categories, the result is computed directly from the time series. For the other calculation categories, a third loop is needed through the selected frequency bands. Each calculation category is described below.  
         [0134]     The two extract functions are “Sample” and “Sample and remove mean.” For the former, the TimeSeries object read from the OutputFormat object  110  is written directly into the CalcBuffer object for the current output point and variable index (the frequency band index is set to 0). This is the simplest calculation and helps to illustrate the basic data flow for the other more complicated calculations—basically each calculation converts an input signal, obtained from OutputFormat, to an output signal, written to CalcBuffer. For the “Sample and remove mean” function, the mean value of the input signal is computed. The output signal is then computed as the input signal, minus the mean value.  
         [0135]     The three statistics functions are “mean,” “standard deviation,” and “variance.” These three functions are also extremely simple. The input time signal is used to produce a single value representing the requested statistical value according to the formulas described above. An output signal comprised of a single frame is created using the result, and this is written to the CalcBuffer for each output point and variable (again, the frequency band index is set to 0).  
         [0136]     For the remaining calculation categories, the Fourier transform of the TimeSeries for each output point and variable is needed. Inside the main loop, the FFTCalculator “transform” function is called on the current TimeSeries. Then, the third-level, innermost loop  122  iterates through the selected frequency bands, from band index 0 to the total number of bands provided by the FreqBands object, minus 1. For each band, the minimum and maximum frequencies, k min  and k max , for that band are obtained from FreqBands using the “getModeStart” and “getModeEnd” functions. All of the FFT-based calculation functions use the functions provided by FFTCalculator to compute the results, so little actual computation is done within the Calculation object.  
         [0137]     The band statistics category provides the “standard deviation” and “variance” calculations for each frequency band. The variance of a signal is the mean-squared deviation of the signal from its mean value, and the standard deviation is the square root of the variance. Similarly, the variance of a time series between a minimum and maximum frequency is defined as the variance of the inverse Fourier transform, with frequencies outside the specified minimum and maximum set to zero. Due to the definition of the power-spectral density, the variance of any single frequency value is identical to the power-spectral density at that frequency. Furthermore, the variance for a sum of frequency components is also equal to the sum of the power-spectral densities (see formulas). Thus, for the band statistics category, the power-spectral density is obtained using the getTotalPSD function of the FFTCalculator. For “variance,” this value is reported as the result, and for the “standard deviation,” the square root of this value is used. Thus, the “variance” calculation is identical to the “Power-spectral density” function in the “Spectrum” category, if the user selects to report the spectrum with the right options (using energy scaling, not converted to dB).  
         [0138]     The spectrum functions category includes two options: “Power-spectral density (PSD)”, and “Complex Fourier transform.” For the PSD function, first the total value of PSD is computed using the getTotalPSD function of the FFTCalculator, specifying the current frequency band&#39;s minimum and maximum frequencies. The user has three options for how to total the PSD across the range of frequencies in each frequency band, based on the parameter BandsSummationType. When this parameter is set to “Total”, the PSD is the value reported by getTotalPSD. When set to “Mean”, this value is divided by the number of frequencies in the band, k max -k min +1. When set to “Square root of total,” the square root of the total value is computed. For all three options, the result is considered as the “band PSD value”.  
         [0139]     Then, depending on the choice of SpectrumValueType, the final result is computed from the band PSD value as follows (except for the A-weighted decibels option-see below). Value: report the band PSD value. Log10: report the log, base  10 , of the band PSD value. Fraction of total power (only valid for BandsSummationType equal “Total”): the total band PSD value is divided by the total variance of the signal. dB (only valid for BandsSummationType equal “Total” or “Mean”): the band PSD value is converted to dB using dB=10 log (PSD/ref 2 ). The correct reference value is passed to the Calculation object as an attribute in the ParameterSet object (though not available as a user parameter).  
         [0140]     If the output is requested in A-weighted decibels, then the PSD for each individual frequency is obtained using getPSD, and then multiplied by a weight value from the so-called A-weighting function, which is available in tabular form from the ISO (International Standards Organization). This function weights each frequency in the human audible range according to perceived loudness. Then, the final result is reported as the sum of the A-weighted values. The BandsSummationType parameter is ignored for A-weighted decibels.  
         [0141]     The second calculation function in the Spectrum category is “Complex Fourier transform”. For this function, the user will typically not combine individual frequency bands into larger bands (i.e., BandsDivisionsType will be set to “Every FFT band,”) and the complex Fourier transform value obtained from the “getFT” function of FFTCalculator for each frequency is written to a TimeSeries object by setting the number of frames to 2, setting the first frame to the real part of the complex Fourier transform value, and setting the second frame to the imaginary part. If the user does not select “Every FFT band” for BandsDivisionsType, the complex Fourier transform will be averaged across the band, though this has limited significance mathematically.  
         [0142]     The filter calculation category contains a single function, “band-pass filter.” This function produces an output time signal consisting of the number of frames specified by the user in the “Filter” tab of the spectral analyzer dialog  62 , and utilizes either the “invert” or “evaluateInverse” function of the FFTCalculator, both of which take the frequency band minimum and maximum as function arguments.  
         [0143]     If the user selects “Use original time values” (in parameter FilterResampleType), the inverse FFT (the “invert” function) is used to produce a time signal at every frame. But the user can limit the number of frames output in the results by selecting First, Last and Skip values. These values are used to extract the specified number of frames from the inverse Fourier transform into a new TimeSeries object, which is then written to the CalcBuffer.  
         [0144]     On the other hand, if the user selects “Re-sample”, then the entire inverse FFT is not used. Instead, a loop iterates through each selected time value (time starts at specified start value, then increments by frame step for the specified number of frames). For each time value, “evaluateInverse” is called and the value is stored in a TimeSeries object. When all the values are computed, the TimeSeries is written to the CalcBuffer. Since each call to evaluateInverse can be a sum of many frequency values, this calculation takes significantly longer than the previous method, but provides more flexibility to the user to produce results at particular time values.  
         [0145]     After the main calculation loop, the final step is to create the output file (see block  124 ). This is done by first initializing a CalcFile object. This object can read and write to a binary file, and so can be used by the other modules in the post-processing software  18  to read the calculation files created with the spectral analyzer module  24 . The file contains the following information: a file header indicating the file type and version (version numbers can be used to provide backward compatibility if the format changes in a later release of the post-processing software  18 ); the complete ParameterSet, written in binary format; the 3-D coordinates of each output point in the OutputFormat object (the OutputFormat object has a function to produce this information); frequency bands; and the calculated results, stored frame-by-frame on the outer level, and then by variable-band-point.  
         [0146]     The CalcBuffer object stores the data in a binary file in a different order than it is needed for the CalcFile object. For the CalcBuffer object, the time frame varies on the inner loop since the data is stored as a set of TimeSeries objects, while in the CalcFile object, the data is stored with time frame on the outer level, to facilitate visualization. To transfer data efficiently from the CalcBuffer to the CalcFile, the CalcBuffer reads through the entire file, storing a large number of frames in a memory buffer, and then provides frame-by-frame access to the data. After the CalcFile is written successfully, the calculation is complete, and the module process exits.  
         [0147]     The Implementation of Output Formats will now be described. The OutputFormat object handles all logic for selection of output points. There are many options for this object, because much of the flexibility of the post-processing software  18  comes from using different methods to extract data out of CFD measurement files. For visualization of calculated results, entire fields are needed, but the amount of computational resources needed to perform a calculation can be greatly reduced by cropping the spatial extent to the region of interest. For visualization of a single plane of data, cropping can be used to extract that plane. Subsampling also produces field data, but with many less measurement points, by averaging together adjacent measurement elements to combine them into a single element.  
         [0148]     The other options for selection of output points facilitate the generation of many types of graphs. Graphs vs. time or frequency require a small number of output points. A rake or probe can be used to extract data from a large data set to make these types of graphs. Graphs vs. spatial dimensions are particularly important. For example, the power-spectral density value in a range of frequency bands can be plotted vs. X, Y or Z along a line in space or a surface contour (cut by a plane). All of these types of graphs are regularly used in analysis and in technical reports, and the post-processing software  18  provides a highly automated method of producing these graphs.  
         [0149]     The OutputFormat object has a set of operations for initialization which implement the user options for setting up output points. Those are described in the following Table 15.  
                         TABLE 15                       USER OUTPUT OPTIONS                                “setMeasFile”:   argument is MeasFile object. This operation links           a MeasFile with the OutputFormat object, so it can           provide all data access to the MeasFile. It also           sets the number and location of all the input           points, which are used in the determining the           output points.       “setFieldOutput”:   arguments are minimum and maximum           coordinates of crop region, and integer           representing subsample value. To implement           subsampling efficiently, when subsample &gt; 0 a           cubic-tree sort algorithm is used to group and sort           all of the input points that lie inside the crop           bounding box. Each output point in the           OutputFormat object is represented by an           OutputRegion object, which stores a list of all           points which are to be averaged together, along           with the sizes of the fluid or surface elements they           represent. For Field output with subsample &gt; 0,           OutputRegions are used to average together           adjacent points to coarsen the grid by a factor           equal to the two to the power of s, where s is the           subsample value.       “setFluidRakeOutput”:   arguments are minimum and maximum           coordinates of the rake region, integers           representing the number of rake points to generate           in the X, Y and Z directions, and finally a real           number representing the probe size. A probe size           of zero represents the option to use only the           nearest element with no averaging. To efficiently           find all of the input points that are near the           specified rake points, again a cubic-tree sort           algorithm is used, and OutputRegion objects are           used to store the points that are to be averaged for           each rake point.       “setFluidLinearRakeOutput”:   arguments are minimum and maximum           coordinates of the rake region, an integer           representing the number of rake points to generate           along a line between the minimum and maximum           coordinates, and a real number representing the           probe size. The same process is used as in the           previous function.       “setFluidProfileOutput”:   arguments are coordinates of two end points of the           profile line. The same cubic-tree algorithm is used           to organize all of the input points between the two           specified end points. Then, starting with the first           end point, the nearest adjacent point along the           direction toward the second end point is           determined from the cubic tree, along with all of its           neighbors. Interpolation is required to determine           the value at a point on the profile line in order to           produce a smooth profile. For this, points are           added to an OutputRegion for each profile point,           but in addition, a weight factor is included based           on how close the measurement point is to the           profile line. The weighted average produces an           interpolated value.       “setSurfaceRakeOutput”:   arguments are the coordinates of 3 corner points           of a parallelogram in space near the surface, 2           integers representing how many rake points to           generate in a 2-D grid, projected onto the surface,           a real number for the surface probe size, and           finally the coordinates of minimum and maximum           corners of a crop region to crop the surface before           projecting the rake. The 3 corners are used to           define a plane, with the normal to the plane being           the projection direction (plus or minus). The rake           points on the plane are determined by defining a           parallelogram with the first side connecting points           1 and 2, and the second side connection points 2           and 3. The specified number of rake points is           determined along each side and used to define a           grid of points. Then, each point is projected onto           the surface (using just a simple search algorithm           for the nearest surface element). Cropping the           surface can significantly improve the search           efficiency if there are a large number of surface           elements.       “setSurfaceProfileOutput”:   arguments are the coordinates of 3 points defining           a cut plane, and the coordinates of minimum and           maximum corners of a crop region to crop the           surface before computing the profile. A simple           search is used to determine all surface elements           cut by the plane, and their neighbors. Then,           values are interpolated to a line where the cut           plane intersects the surface element, by creating           an OutputRegion with weight values assigned to           the points used in the interpolation.       “setProbeOutput”:   arguments are minimum and maximum           coordinates of the crop region. All of the points           between the minimum and maximum coordinates           specified are included in a single OutputRegion,           which averages all points into a single output           point.                  
 
         [0150]     After the output points are setup, the function “getTimeSeries” is used to obtain the time signal at each output point. This function retrieves a TimeSeries object for each input point needed to compute the output point, and the results are averaged.  
         [0151]     The implementation of FFT options is as follows. The FFTCalculator object is responsible for transforming the time series data into its Fourier transform, using a standard FFT algorithm. It also uses a standard overlapping window approach, and standard “window functions,” in which the FFT is performed on smaller segments of the time series, where the segment size is specified as the “window length,” and each segment overlaps 50% with the previous one. Then the Fourier transform is averaged over all the windows. If a “windowing function” is used, the signal in each segment is multiplied by a function which tapers to zero at each end. Windowing in this manner smoothes the spectrum as a way of correcting for the short length of the time series in comparison to the real world signal of arbitrarily long length. The FFT algorithm adapts to the signal length, and so is able to process signals with length equal to the product of powers of small numbers (like 2, 3, 5) more efficiently than signals with length with large prime factors.  
         [0152]     The FFTCalculator object is set up by specifying the windowing parameters: the window width and the window type. The FFTCalculator provides a function for automatically calculating an efficient window width that is a product of powers of 2, 3 and 5, and is less than some specified value. The FFTCalculator initialization functions are as follows:  
                         TABLE 16                       FFTCALCUATOR INITIALIZATION FUNCTIONS                                “setWindowLength”:   integer argument, initializes the FFT to a           specified window segment length       “setWindowFunction”:   integer argument representing the user option           “SpectrumWindowType”, initializes a vector           of weight values using the specified function.       “getAutoLength”:   integer argument representing user option           “SpectrumWindowWidthMethod”, other than           “Custom,” and an integer representing           the input signal length. Based on the option           selected, calculates the window width to use           in the FFT. For the “Smoothing optimal”           option, the signal length is divided by four,           and then the next lowest value that is a           product of powers of 2, 3 and 5 is found.                  
 
         [0153]     The Implementation of Frequency Banding options is now described. The FreqBands object determines how to divide the frequency range based on the user input parameter “BandsDivisionsType.” This object is initialized using the following functions (Table 17).  
                         TABLE 17                       FREQUENCY BANDING OPTIONS                                “setAutoBandsDivisions”:   integer argument representing parameter           “BandsDivisionsType” for values other than           “Custom”, as well as real number arguments for           the time step, minimum frequency, and maximum           frequency, and an integer argument for the FFT           window length. The function sets up the minimum           and maximum frequency values for each band,           and sets the value for the total number of bands.           The bands are divided as follows:           For “Single band”, a single band is generated           between the input values of minimum and           maximum frequency.           For “Every FFT band,” the FFT bandwidth is           computed from the input parameters, and           constant-spaced bands are created using the           bandwidth from the minimum to the maximum           values.           For the remaining options other than “Custom”,           proportionally spaced bands are generated. Each           option determines a scale factor that is the ratio           between the maximum and minimum frequencies           for each band. For example, for third-octave, the           scale factor is 2 1/3 , and is about 1.26. In addition           to the scale factor, some starting point is needed           for calculating the band divisions. A standard           approach is taken to match frequency spectra           used in the acoustics community, in that a           standard value of 1000 Hz is always used as the           center frequency for one of the bands, where the           “center frequency” is defined as sqrt(min*max)           rather than the mean, according to convention. A           simple loop is used to compute the possible bands           using the specified scale factor option, and the           bands between the minimum and maximum           values are included in the spectrum. Also if the           minimum range is specified too low, it is corrected           so that each band will contain at least one FFT           band.       “setCustomBandDivisions”:   arguments are two vectors containing the           minimum and maximum frequencies of each band.           The bands are set using the input vectors, and no           further checking is performed.       “assignModes”:   argument is integer representing the window           width. After the band divisions have been set, this           function is used to assign FFT frequency modes to           the bands. After this function is called, then           “getModeStart” and “getModeEnd” can be used to           return k min  and k max , which are the start and end           frequency mode indices for each band.                  
 
         [0154]     For spectral analysis of fluid data, visualization is very important. The contribution of each frequency band can be represented as an average amplitude in that band for each measurement element in the fluid volume and on the surface. Then, that amplitude can be used to generate a color image, either on a planar cut through the fluid volume or on a shaded 3-D image of the surface object. This helps software users to identify where peak amplitudes are occurring in the flow or on the surface, on a band-by-band basis.  
         [0155]     Accordingly, once the frame-by-frame data has been processed as a set of time signals as described above, the results can be output into a format that can be viewed. The simplest method of viewing this data is in the form of a graph. Computed quantities can be graphed versus time, frequency, or spatial location. Graphs are used to quantify and compare levels of specific quantities. The graphing module uses known techniques to allow the user to read the desired data from a calculation file and generate a graph of the data (for example, a two-dimensional X-Y graph). An example of such a graph  126  is depicted in  FIG. 19 . The graph  126  is not displayed immediately but is stored in a custom view file which contains user parameters and data representing a graph. A separate graph viewer component  28  (see  FIG. 3 ) is included in the post-processing software  18  for viewing these files, as described below.  
         [0156]     The software includes a graph viewer module  28  for the viewing of graphs created by the graphing module described above. The graph viewer module  28  is available both as an integrated component available from the project manager menu, and as a stand-alone application which can be activated, for example, by “double-clicking” on a view file. The graph viewer module  28  allows printing, graphical copy and paste into other programs, and export of the graph image to various image formats.  
         [0157]     The export modules  32  (described above) read data from calculation files and use it to create new file types. The first file type that is supported is text—the user can specify what data to extract, and it is written to a text file using columnar output. Secondly, 3-D data sets can be written to file formats supported by third-party commercial CFD packages for visualization of data. Preferably, this is done by exporting the (output) data back into the format used for measurement files, however any desired data set format may be used. Since jobs representing view and export operations can be queued along with calculations, the user can set up an entire analysis project starting with measurement files as input and resulting in a set of graphs and exported visualization files. This model allows the software to extend the types of output to, for example, image and movie files.  
         [0158]     Using the export files created by the post-processing software  18 , visualization software of a known type can provide methods of examining the data using color maps, lines and vectors, 3-D surfaces, etc. These images can be computed for each measurement frame and combined to form an animation using known software techniques.  
         [0159]     Examples of graphical flow visualizations created from output of the post-processing software are shown in  FIGS. 23 and 24 .  FIG. 23  is a set of three 2D views (top, side, and rear) of a flow pattern around a model. These views may be displayed on a computer monitor of a known type. The turbulent pressure level in the flow is represented as varying shades of gray or as different colors in a known fashion.  FIG. 21  illustrates a similar flow visualization in which the filtering techniques (described above) have been applied to the output. In this case, the fluctuation pressure coefficient Cp for a frequency band spanning 1-10 KHz is illustrated. The periodic, repeating flow features can clearly be seen as the spaced-apart dark and light areas in the wake of the model.  
         [0160]     Animations are also useful in conjunction with spectral analysis. Isolating contributions from each frequency band using an FFT, the flow features in that band can be reconstructed separate from features in other frequency bands. This procedure is called a “band-pass filter”. This type of filter shows the fluctuations occurring in each frequency band at a series of time levels, and color image visualization can be used to create an animation sequence. For example, turbulent flow structures can produce acoustic waves when they impinge on a surface. Spectral analysis of the pressure field in the turbulent flow region surrounding the surface can be used to show the frequency content of these turbulent structures. When visualizing these results, a single image could convey the amplitude of the turbulent structures in a particular frequency band, for example 100-200 Hz. However, a band-pass filter in the 100-200 Hz frequency band could produce an animation of pressure in that frequency band. This animation would actually show the generation and propagation of turbulent structures (such as those shown in  FIG. 21 ) and would help identify the spatial size of those structures, the direction of propagation, and the mechanism for producing acoustic waves-all of which would be lost in the visualization of amplitude alone.  
         [0161]     The foregoing has described a method and software for analysis of turbulent fluid flows. While specific embodiments of the present invention have been described, it will be apparent to those skilled in the art that various modifications thereto can be made without departing from the spirit and scope of the invention. Accordingly, the foregoing description of the preferred embodiment of the invention and the best mode for practicing the invention are provided for the purpose of illustration only and not for the purpose of limitation.