Solid Mechanics. While textbooks define Solid Mechanics as the study of the motion, deformation, or fracture of solid materials to external and internal forces -- the breadth of this field is enormous. Solid Mechanics has implications for manufacturing, biomedicine, and much more. Faculty members in the Solid Mechanics area study fundamentals of continuum mechanics, …
1.050 is a sophomore-level engineering mechanics course, commonly labelled "Statics and Strength of Materials" or "Solid Mechanics I." This course introduces students to the fundamental principles and methods of structural mechanics. Topics covered include: static equilibrium, force resultants, support conditions, analysis of determinate planar structures (beams, trusses, …
Mechanics of Materials is mathematically fairly easy, but the problems can be tricky. I would go with Dynamics for most people since most mechanical engineers are not drawn to the math the way a physicist is. Dynamics is generally harder for most.
Dynamics is a 4 hr class with a ton of HW. As with any class its only as hard as it's teacher. But I am very surprised dynamics was even an option for a summer school course. Your average dynamics class would be near impossible to compress into 6 weeks.Aug 26, 2015
So the dynamics part of your background should help. But, in fluid mechanics, you are also going to be dealing with materials that are deforming, and you are going to make the acquaintance of the stress tensor.Apr 30, 2013
I honestly find dynamics to be easier than statics. Although this probably isn't because of the difficulty of either topic, but more because dynamics isn't so mind numbingly boring. As minger stated, all you need to know is f = ma (or as I prefer f = dp/dt).Dec 27, 2009
The 5 Hardest Engineering MajorElectrical Engineering. Most people agree that electrical engineering is easily among the hardest majors. ... Computer Engineering. ... Aerospace Engineering. ... Chemical Engineering. ... Biomedical Engineering.
Generally Thermodynamics is harder than Dynamics, simply because Dynamics involves the foundation of Physics such as displacement, velocity, acceleration, forces, projectile motion, work and energy but additionally topics not learned during pre-university course like Dependent pulley system and Rigid planar kinematics.
The concept of solid mechanics provides the analytical methods of designing solid engineering systems with adequate strength, stiffness, stability, and integrity.
Of all math classes engineers have to take, Differential Equations is the toughest. It requires both great memory and math skill.
dynamics, branch of physical science and subdivision of mechanics that is concerned with the motion of material objects in relation to the physical factors that affect them: force, mass, momentum, energy.
This course is an introduction to the dynamics and vibrations of lumped-parameter models of mechanical systems. Topics covered include kinematics, force-momentum formulation for systems of particles and rigid bodies in planar motion, work-energy concepts, virtual displacements and virtual work.
These different OCW versions provide complementary materials, including lecture videos, detailed lecture notes, and many sample problems.
J. Vandiver, and David Gossard. 2.003SC Engineering Dynamics. Fall 2011. Massachusetts Institute of Technology: MIT OpenCourseWare, https://ocw.mit.edu. License: Creative Commons BY-NC-SA.
Predictive, multi-scale modeling and simulation of microstructure evolution in confined granular systems, with an emphasis in manufacturing processes and the relationship between product fabrication and performance.
Thermal stresses, thermal fracture and fatigue of advanced materials, in particular high temperature materials, ceramic coatings.
1.050 is a sophomore-level engineering mechanics course, commonly labelled "Statics and Strength of Materials" or "Solid Mechanics I .". This course introduces students to the fundamental principles and methods of structural mechanics.
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Had the most stressful semester. Hardly applied for jobs most the semester because i basically fell into a micro depression. almost failed a core class, yet still I was able to graduate. Applied for a job. 2 weeks later I get an offer. Six figures. Flexible work schedule/location. Cool office. Fun and casual atmosphere.
Since I was 8 years old doing long division in my head while simultaneously failing 3rd grade reading comprehension tests, my father (the 2nd in command Federal government computer electrical engineer for the D.O.D.) has been drilling in my head “you’re naturally great at math, you ask more questions than anyone I know, and most importantly you’re a girl.
I passed Thermodynamics! Hell yeah! This is my second course of studies, after i failed Laws, because of boredom. Now i am a new person, and i like engineering a lot! I started my mandatory internship at Miele this month and can‘t be happier!
This course covers fundamental issues from the field of particle and rigid-body kinematics and kinetics . The course combines high-level mathematics (calculus and differential equations), physics and basic engineering concepts. These are applied to investigate common problems in the dynamics of rigid-body mechanics utilizing fundamental principles involving forces and motion. Both theoretical development and applied problem solving are emphasized.
Properties of pure substances. Concepts of work and heat, fundamental laws of thermodynamics; closed and open systems. Entropy and entropy production. Basic gas and vapor cycles, basic refrigeration cycles.
This course will be constructed of nine modules: 1 Introduction 2 Working with the MATLAB user interface - entering commands and creating variables 3 Analyzing vectors and matrices - visualizing vector and matrix data 4 Working with data files and data types 5 Automating commands with scripts 6 Advanced plotting 7 Writing programs with logic and flow control 8 Writing functions 9 Symbolic computations