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==goals== | ==goals== | ||
− | although the basic concepts of continuum mechanics have been established more than five decades ago, the 21st century faces many new and exciting potential applications of continuum mechanics that go way beyond the standard classical theory. when applying continuum mechanics to these challenging new phenomena, it is important to understand the main three ingredients of continuum mechanics: the kinematic equations, the balance equations and the constitutive equations. after a brief repetition of the relevant equations in tensor algebra and analysis, this class will introduce the basic concepts of small strain kinematics. | + | although the basic concepts of continuum mechanics have been established more than five decades ago, the 21st century faces many new and exciting potential applications of continuum mechanics that go way beyond the standard classical theory. when applying continuum mechanics to these challenging new phenomena, it is important to understand the main three ingredients of continuum mechanics: the kinematic equations, the balance equations and the constitutive equations. after a brief repetition of the relevant equations in tensor algebra and analysis, this class will introduce the basic concepts of small strain kinematics. we will then discuss the balance equations for mass, momentum, moment of momentum, energy and entropy. while all these equations are general and valid for any kind of material, the last set of equations, the constitutive equations, specifies particular subclasses of materials. in particular, we will focus on isotropic and anisotropic hyperelasticity. finally, we will briefly address variational principles that characterize the governing equations. throughout this class, we will discuss the mechanics of the heart with its strains, fiber stretches, stresses, forces, and constitutive equations, to illustrate how continuum mechanics can be applied to relevant clinical problems. |
− | == | + | ==continuum mechanics of the heart== |
+ | |||
+ | special thanks to wolf, john, and neil for the hands on wet lab as introduction to [http://biomechanics.stanford.edu/me338_09/me338_h02.pdf homework 02] | ||
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| tue || jan || 27 || balance equations I - contact fluxes || [http://biomechanics.stanford.edu/me338_09/me338_n07.pdf n07] || | | tue || jan || 27 || balance equations I - contact fluxes || [http://biomechanics.stanford.edu/me338_09/me338_n07.pdf n07] || | ||
|- | |- | ||
− | | thu || jan || 29 || balance equations II - concept of stress || [http://biomechanics.stanford.edu/me338_09/me338_n08.pdf n08] || | + | | thu || jan || 29 || balance equations II - concept of stress || [http://biomechanics.stanford.edu/me338_09/me338_n08.pdf n08] || |
|- | |- | ||
− | | tue || feb || 03 || balance equations III - mass, momentum || [http://biomechanics.stanford.edu/me338_09/me338_n09.pdf n09] || | + | | tue || feb || 03 || balance equations III - mass, momentum || [http://biomechanics.stanford.edu/me338_09/me338_n09.pdf n09] || [http://biomechanics.stanford.edu/me338_09/me338_h02.pdf h02] |
|- | |- | ||
| thu || feb || 05 || balance equations IV - angular momentum, energy || [http://biomechanics.stanford.edu/me338_09/me338_n10.pdf n10] || | | thu || feb || 05 || balance equations IV - angular momentum, energy || [http://biomechanics.stanford.edu/me338_09/me338_n10.pdf n10] || | ||
|- | |- | ||
− | | tue || feb || 10 || balance equations V - entropy, master balance law || [http://biomechanics.stanford.edu/me338_09/me338_n11.pdf n11] || | + | | tue || feb || 10 || balance equations V - entropy, master balance law || [http://biomechanics.stanford.edu/me338_09/me338_n11.pdf n11] || |
|- | |- | ||
| thu || feb || 12 || constitutive equations I - linear equations || [http://biomechanics.stanford.edu/me338_09/me338_n12.pdf n12] || | | thu || feb || 12 || constitutive equations I - linear equations || [http://biomechanics.stanford.edu/me338_09/me338_n12.pdf n12] || | ||
|- | |- | ||
− | | tue || feb || 17 || constitutive equations II - hyperelasticity || [http://biomechanics.stanford.edu/me338_09/me338_n13.pdf n13] || | + | | tue || feb || 17 || constitutive equations II - hyperelasticity || [http://biomechanics.stanford.edu/me338_09/me338_n13.pdf n13] || [http://biomechanics.stanford.edu/me338_09/me338_h03.pdf h03] |
|- | |- | ||
− | | thu || feb || 19 || constitutive equations III - isotropic elasticity|| [http://biomechanics.stanford.edu/me338_09/me338_n14.pdf n14] || [http://biomechanics.stanford.edu/ | + | | thu || feb || 19 || constitutive equations III - isotropic elasticity|| [http://biomechanics.stanford.edu/me338_09/me338_n14.pdf n14] || [http://biomechanics.stanford.edu/me338_09/me338_h04.pdf project] |
|- | |- | ||
| tue || feb || 24 || midterm prep || || | | tue || feb || 24 || midterm prep || || | ||
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| thu || feb || 26 || midterm || || | | thu || feb || 26 || midterm || || | ||
|- | |- | ||
− | | tue || mar || 03 || intro nonlinear continuum mechanics - finite strain kinematics || | + | | tue || mar || 03 || intro nonlinear continuum mechanics - finite strain kinematics || [http://biomechanics.stanford.edu/me338_09/me338_n15.pdf n15] || |
|- | |- | ||
− | | thu || mar || 05 || intro nonlinear continuum mechanics - stress measures || | + | | thu || mar || 05 || intro nonlinear continuum mechanics - stress measures || [http://biomechanics.stanford.edu/me338_09/me338_n16.pdf n16] || |
|- | |- | ||
− | | tue || mar || 10 || intro nonlinear continuum mechanics - constitutive equations || | + | | tue || mar || 10 || intro nonlinear continuum mechanics - constitutive equations ||[http://biomechanics.stanford.edu/me338_09/me338_n17.pdf n17] || |
|- | |- | ||
− | | thu || mar || 12 || journal club - final project discussion || | + | | thu || mar || 12 || journal club - final project discussion || [http://biomechanics.stanford.edu/me338_09/me338_h04.pdf n18] || |
|} | |} | ||
==final project== | ==final project== | ||
− | + | the [http://biomechanics.stanford.edu/me338_09/me338_h04.pdf final project] of this class is the review of a recently submitted manuscript that introduces a new constitutive model for passive cardiac muscle tissue <br> | |
− | + | holzapfel ga, ogden rw: constitutive modelling of passive myocardium. a structurally-based framework for material characterization, philosophical transactions of the royal society a, accepted for publication, 2009 | |
− | + | ||
− | + | ||
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==suggested reading== | ==suggested reading== | ||
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liu is: continuum mechanics, springer, 2002 <br> | liu is: continuum mechanics, springer, 2002 <br> | ||
reddy jn: an introduction to continuum mechanics, cambridge university press, 2007 <br> | reddy jn: an introduction to continuum mechanics, cambridge university press, 2007 <br> | ||
+ | ... |
Latest revision as of 20:20, 9 March 2010
Contents |
[edit] me338A - continuum mechanics
ellen kuhl,
serdar goktepe, winter 2009 syllabus and set of notes |
[edit] goals
although the basic concepts of continuum mechanics have been established more than five decades ago, the 21st century faces many new and exciting potential applications of continuum mechanics that go way beyond the standard classical theory. when applying continuum mechanics to these challenging new phenomena, it is important to understand the main three ingredients of continuum mechanics: the kinematic equations, the balance equations and the constitutive equations. after a brief repetition of the relevant equations in tensor algebra and analysis, this class will introduce the basic concepts of small strain kinematics. we will then discuss the balance equations for mass, momentum, moment of momentum, energy and entropy. while all these equations are general and valid for any kind of material, the last set of equations, the constitutive equations, specifies particular subclasses of materials. in particular, we will focus on isotropic and anisotropic hyperelasticity. finally, we will briefly address variational principles that characterize the governing equations. throughout this class, we will discuss the mechanics of the heart with its strains, fiber stretches, stresses, forces, and constitutive equations, to illustrate how continuum mechanics can be applied to relevant clinical problems.
[edit] continuum mechanics of the heart
special thanks to wolf, john, and neil for the hands on wet lab as introduction to homework 02
[edit] grading
- 30 % homework - 3 homework assignments, 10% each
- 40 % midterm - closed book, closed notes, one single letter format page of notes
- 30 % final project - written evaluation of a manuscript and its discussion in class
[edit] syllabus
day | date | topic | notes | hw | |
---|---|---|---|---|---|
tue | jan | 06 | tensor calculus I - vector algebra | n01 | |
thu | jan | 08 | tensor calculus II - tensor algebra | n02 | |
tue | jan | 13 | tensor calculus III - tensor analysis | n03 | |
thu | jan | 15 | tensor calculus IV - tensor analysis | n04 | |
tue | jan | 20 | kinematics I - motion | n05 | h01 |
thu | jan | 22 | kinematics II - strain | n06 | |
tue | jan | 27 | balance equations I - contact fluxes | n07 | |
thu | jan | 29 | balance equations II - concept of stress | n08 | |
tue | feb | 03 | balance equations III - mass, momentum | n09 | h02 |
thu | feb | 05 | balance equations IV - angular momentum, energy | n10 | |
tue | feb | 10 | balance equations V - entropy, master balance law | n11 | |
thu | feb | 12 | constitutive equations I - linear equations | n12 | |
tue | feb | 17 | constitutive equations II - hyperelasticity | n13 | h03 |
thu | feb | 19 | constitutive equations III - isotropic elasticity | n14 | project |
tue | feb | 24 | midterm prep | ||
thu | feb | 26 | midterm | ||
tue | mar | 03 | intro nonlinear continuum mechanics - finite strain kinematics | n15 | |
thu | mar | 05 | intro nonlinear continuum mechanics - stress measures | n16 | |
tue | mar | 10 | intro nonlinear continuum mechanics - constitutive equations | n17 | |
thu | mar | 12 | journal club - final project discussion | n18 |
[edit] final project
the final project of this class is the review of a recently submitted manuscript that introduces a new constitutive model for passive cardiac muscle tissue
holzapfel ga, ogden rw: constitutive modelling of passive myocardium. a structurally-based framework for material characterization, philosophical transactions of the royal society a, accepted for publication, 2009
[edit] suggested reading
... this is the book we will use in class...
holzapfel ga: nonlinear solid mechanics, a continuum approach for engineering, john wiley & sons, 2000
... and here are some other cool books for additional reading...
murnaghan fd: finite deformation of an elastic solid, john wiley & sons, 1951
eringen ac: nonlinear theory of continuous media, mc graw-hill, 1962
truesdell c, noll, w: the non-linear field theories of mechanics, springer, 1965
eringen ac: mechanics of continua, john wiley & sons, 1967
malvern le: introduction to the mechanics of a continuous medium, prentice hall, 1969
oden jt: finite elements of nonlinear continua, dover reprint, 1972
chadwick p: continuum mechanics - concise theory and problems, dover reprint, 1976
ogden, rw: non-linear elastic deformations, dover reprint, 1984
maugin ga: the thermodynamics of plasticity and fracture, cambridge university press, 1992
spencer ajm: continuum mechanics, dover reprint, 1992
robers aj: one-dimensional introduction to continuum mechanics, world scientific, 1994
bonet j, wood rd: nonlinear continuum mechanics for fe analysis, cambridge university press, 1997
silhavy m: the mechanics and thermodynamics of continuous media, springer, 1997
haupt p: continuum mechanics and theory of materials, springer, 2000
podio-guidugli p: a primer in elasticity, kluwer academic press, 2000
liu is: continuum mechanics, springer, 2002
reddy jn: an introduction to continuum mechanics, cambridge university press, 2007