methods
Module¶
All method cards are defined in this file. This includes:
EIGB
EIGC
EIGR
EIGP
EIGRL
All cards are Method objects.
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class
pyNastran.bdf.cards.methods.
EIGB
(sid, method, L1, L2, nep, ndp, ndn, norm, G, C, comment='')[source]¶ Bases:
pyNastran.bdf.cards.methods.Method
Defines data needed to perform buckling analysis
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L1
= None¶ Eigenvalue range of interest. (Real, L1 < L2)
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classmethod
add_card
(card, comment='')[source]¶ Adds an EIGB card from
BDF.add_card(...)
- Parameters
- cardBDFCard()
a BDFCard object
- commentstr; default=’’
a comment for the card
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method
= None¶ Method of eigenvalue extraction. (Character: ‘INV’ for inverse power method or ‘SINV’ for enhanced inverse power method.) apparently it can also be blank…
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ndp
= None¶ Desired number of positive and negative roots. (Integer>0; Default = 3*NEP)
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nep
= None¶ Estimate of number of roots in positive range not used for METHOD = ‘SINV’. (Integer > 0)
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norm
= None¶ Method for normalizing eigenvectors. (‘MAX’ or ‘POINT’;Default=’MAX’)
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repr_fields
()[source]¶ Gets the fields in their simplified form
- Returns
- fieldsList[varies]
the fields that define the card
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sid
= None¶ Set identification number. (Unique Integer > 0)
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type
= 'EIGB'¶
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class
pyNastran.bdf.cards.methods.
EIGC
(sid, method, grid, component, epsilon, neigenvalues, norm='MAX', mblkszs=None, iblkszs=None, ksteps=None, NJIs=None, alphaAjs=None, omegaAjs=None, alphaBjs=None, omegaBjs=None, LJs=None, NEJs=None, NDJs=None, shift_r1=None, shift_i1=None, isrr_flag=None, nd1=None, comment='')[source]¶ Bases:
pyNastran.bdf.cards.methods.Method
Defines data needed to perform complex eigenvalue analysis .. todo: not done
inverse power
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EIGC
SID
METHOD
EPS
ND0
ALPHAAj
OMEGAAj
ALPHABj
OMEGABj
Lj
NEj
NDj
complex Lanczos
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SHIFTRj
SHIFTIj
MBLKSZj
IBLKSZj
KSTEPSj
NDj
iterative Schur-Rayleigh-Ritz
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SHIFTR1
SHIFTI1
ISRRFLG
ND1
Creates a EIGC card, which is required for a SOL 107 analysis
- Parameters
- sidint
CMETHOD id in the case control deck
- methodstr
- Method of complex eigenvalue extraction
MSC 2014 = [INV, HESS, CLAN, IRAM] NX 8.5 = [INV, HESS, CLAN, ISRR] Autodesk 2015 = [ARNO, HESS, CLAN] INV : Inverse Power IRAM : Implicitly Restarted Arnoldi method ISRR : Iterative Schur-Rayleigh-Ritz method CLAN : Complex Lanczos. For linear perturbation of ANALYSIS=DCEIG
with large displacement, CLAN is recommended.
- HESSUpper Hessenberg. For linear perturbation of ANALYSIS=DCEIG
with large displacement, please don’t use HESS.
ARNO: ???
- normstr; default=’MAX’
Method for normalizing eigenvectors valid_norm = {MAX, POINT}
- gridint
GRID/SPOINT id Required if norm=’POINT’
- componentint
Required if norm=’POINT’
- epsilonfloat
- neigenvaluesint
Number of Eigenvalues
- mblkszsList[float]; default=None
used by CLAN
- iblkszsList[int]; default=None
used by CLAN
- kstepsList[int]; default=None
used by CLAN
- NJIsList[int]; default=None
used by CLAN
- alphaAjsList[float]; default=None
used by HESS/INV
- omegaAjsList[float]; default=None
used by HESS/INV
- alphaBjsList[float]; default=None
used by HESS/INV
- omegaBjsList[float]; default=None
used by HESS/INV
- LJsList[float]; default=None
used by HESS/INV
- NEJsList[int]; default=None
used by HESS/INV
- NDJsList[int]; default=None
used by HESS/INV
- shift_r1List[float]; default=None
used by ISSR
- shift_i1List[float]; default=None
used by ISSR
- isrr_flagList[int]; default=None
used by ISSR
- nd1List[int]; default=None
used by ISSR
- commentstr; default=’’
a comment for the card
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C
= None¶ Component number. Required only if NORM=’POINT’ and G is a geometric grid point. (1<Integer<6)
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G
= None¶ Grid or scalar point identification number. Required only if NORM=’POINT’. (Integer>0)
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classmethod
add_card
(card, comment='')[source]¶ Adds an EIGC card from
BDF.add_card(...)
- Parameters
- cardBDFCard()
a BDFCard object
- commentstr; default=’’
a comment for the card
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epsilon
= None¶ Convergence criterion. (Real > 0.0. Default values are: 10^-4 for METHOD = “INV”, 10^-8 for METHOD = “CLAN”, 10^-8 for METHOD = “ISRR”, 10^-15 for METHOD = “HESS”, E is machine dependent for METHOD = “CLAN”.)
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method
= None¶ Method of complex eigenvalue extraction MSC 2014 = [INV, HESS, CLAN, IRAM] NX 8.5 = [INV, HESS, CLAN, ISRR] Autodesk 2015 = [ARNO, HESS, CLAN]
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norm
= None¶ Method for normalizing eigenvectors
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repr_fields
()[source]¶ Gets the fields in their simplified form
- Returns
- fieldsList[varies]
the fields that define the card
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sid
= None¶ Set identification number. (Unique Integer > 0)
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type
= 'EIGC'¶
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class
pyNastran.bdf.cards.methods.
EIGP
(sid, alpha1, omega1, m1, alpha2, omega2, m2, comment='')[source]¶ Bases:
pyNastran.bdf.cards.methods.Method
Defines poles that are used in complex eigenvalue extraction by the Determinant method.
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EIGP
SID
ALPHA1
OMEGA1
M1
ALPHA2
OMEGA2
M2
EIGP
15
-5.2
0.0
2
6.3
5.5
3
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classmethod
add_card
(card, comment='')[source]¶ Adds an EIGPX card from
BDF.add_card(...)
- Parameters
- cardBDFCard()
a BDFCard object
- commentstr; default=’’
a comment for the card
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alpha1
= None¶ Coordinates of point in complex plane. (Real)
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alpha2
= None¶ Coordinates of point in complex plane. (Real)
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m1
= None¶ Multiplicity of complex root at pole defined by point at ALPHAi and OMEGAi
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m2
= None¶ Multiplicity of complex root at pole defined by point at ALPHAi and OMEGAi
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omega1
= None¶ Coordinates of point in complex plane. (Real)
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omega2
= None¶ Coordinates of point in complex plane. (Real)
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repr_fields
()[source]¶ Gets the fields in their simplified form
- Returns
- fieldsList[varies]
the fields that define the card
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sid
= None¶ Set identification number. (Unique Integer > 0)
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type
= 'EIGP'¶
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classmethod
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class
pyNastran.bdf.cards.methods.
EIGR
(sid, method='LAN', f1=None, f2=None, ne=None, nd=None, norm='MASS', G=None, C=None, comment='')[source]¶ Bases:
pyNastran.bdf.cards.methods.Method
Defines data needed to perform real eigenvalue analysis
# msc/nx | EIGR | SID | METH| F1 | F2 | NE | ND | | | | | NORM | G | C | | | | | |
Adds a EIGR card
- Parameters
- sidint
method id
- methodstr; default=’LAN’
eigenvalue method recommended: {LAN, AHOU} obsolete : {INV, SINV, GIV, MGIV, HOU, MHOU, AGIV}
- f1 / f2float; default=None
lower/upper bound eigenvalue
- f2float; default=None
upper bound eigenvalue
- neint; default=None
estimate of number of roots (used for INV)
- ndint; default=None
desired number of roots
- msglvlint; default=0
debug level; 0-4
- maxsetint; default=None
Number of vectors in block or set
- shfsclfloat; default=None
estimate of first flexible mode natural frequency
- normstr; default=None
{MAX, MASS, AF, POINT} default=MASS (NX)
- Gint; default=None
node id for normalization; only for POINT
- Cint; default=None
component for normalization (1-6); only for POINT
- commentstr; default=’’
a comment for the card
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C
= None¶ Component number. Required only if NORM=’POINT’ and G is a geometric grid point. (1<Integer<6)
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G
= None¶ Grid or scalar point identification number. Required only if NORM=’POINT’. (Integer>0)
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classmethod
add_card
(card, comment='')[source]¶ Adds an EIGR card from
BDF.add_card(...)
- Parameters
- cardBDFCard()
a BDFCard object
- commentstr; default=’’
a comment for the card
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allowed_methods
= ['LAN', 'AHOU', 'INV', 'SINV', 'GIV', 'MGIV', 'HOU', 'MHOU', 'AGIV']¶
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f1
= None¶ Frequency range of interest
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method
= None¶ Method of eigenvalue extraction. (Character: ‘INV’ for inverse power method or ‘SINV’ for enhanced inverse power method.)
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nd
= None¶ Desired number of roots (default=600 for SINV 3*ne for INV)
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ne
= None¶ Estimate of number of roots in range (Required for METHOD = ‘INV’). Not used by ‘SINV’ method.
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norm
= None¶ Method for normalizing eigenvectors. (‘MAX’ or ‘POINT’; Default=’MAX’)
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repr_fields
()[source]¶ Gets the fields in their simplified form
- Returns
- fieldsList[varies]
the fields that define the card
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sid
= None¶ Set identification number. (Unique Integer > 0)
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type
= 'EIGR'¶
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class
pyNastran.bdf.cards.methods.
EIGRL
(sid, v1=None, v2=None, nd=None, msglvl=0, maxset=None, shfscl=None, norm=None, options=None, values=None, comment='')[source]¶ Bases:
pyNastran.bdf.cards.methods.Method
Defines data needed to perform real eigenvalue (vibration or buckling) analysis with the Lanczos method
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EIGRL
SID
V1
V2
ND
MSGLVL
MAXSET
SHFSCL
NORM
option_1 = value_1 option_2 = value_2, etc.
Adds an EIGRL card
- Parameters
- sidint
method id
- v1float; default=None
lower bound eigenvalue
- v2float; default=None
upper bound eigenvalue
- ndint
number of roots
- msglvlint; default=0
debug level; 0-4
- maxsetint; default=None
Number of vectors in block or set
- shfsclfloat; default=None
estimate of first flexible mode natural frequency
- normstr; default=None
{MAX, MASS, AF}
- options???; default=None -> []
???
- values???; default=None -> []
???
- commentstr; default=’’
a comment for the card
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classmethod
add_card
(card, comment='')[source]¶ Adds an EIGRL card from
BDF.add_card(...)
- Parameters
- cardBDFCard()
a BDFCard object
- commentstr; default=’’
a comment for the card
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maxset
= None¶ Number of vectors in block or set. Default is machine dependent
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msglvl
= None¶ Diagnostic level. (0 < Integer < 4; Default = 0)
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nd
= None¶ Number of roots desired
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norm
= None¶ Method for normalizing eigenvectors (Character: ‘MASS’ or ‘MAX’)
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repr_fields
()[source]¶ Gets the fields in their simplified form
- Returns
- fieldsList[varies]
the fields that define the card
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shfscl
= None¶ Estimate of the first flexible mode natural frequency (Real or blank)
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sid
= None¶ Set identification number. (Unique Integer > 0)
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type
= 'EIGRL'¶
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v1
= None¶ For vibration analysis: frequency range of interest. For buckling analysis: eigenvalue range of interest. See Remark 4. (Real or blank, -5 10e16 <= V1 < V2 <= 5.10e16)
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class
pyNastran.bdf.cards.methods.
MODTRAK
(sid, low_range, high_range, mt_filter, comment='')[source]¶ Bases:
pyNastran.bdf.cards.base_card.BaseCard
MODTRAK SID LOWRNG HIGHRNG MTFILTER MODTRAK 100 1 26 0.80
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class
pyNastran.bdf.cards.methods.
Method
[source]¶ Bases:
pyNastran.bdf.cards.base_card.BaseCard
Generic class for all methods. Part of self.methods