1. Being able to follow the basic principles of mechanics to conduct correct force analysis of engineering objects, such as components and mechanisms, draw free-body diagrams, and solve constraint reactions.
2. Using static equilibrium conditions to complete equilibrium calculations for structures such as bar systems and rigid-body systems, and determine their stability and static determinacy.
3. Mastering kinematic analysis methods to describe the trajectory, velocity, and acceleration of a point, and analyze the motion characteristics of rigid-body translation, fixed-axis rotation, and plane motion.
4. Using the general theorems of dynamics to establish differential equations of motion for systems of particles and solve dynamics problems in engineering.
5. Being able to identify the types of constraints and mechanical models in mechanisms, and use D’Alembert’s principle to complete modeling and calculation for kinetostatic and equilibrium problems.
6. Developing the ability to abstract and simplify practical engineering problems with mechanical thinking, establish reasonable theoretical mechanics models, and select appropriate analytical or geometric methods for solution and verification.