Basic Physics 1

  • Cours (CM) -
  • Cours intégrés (CI) 39h
  • Travaux dirigés (TD) -
  • Travaux pratiques (TP) -
  • Travail étudiant (TE) 63h

Langue de l'enseignement : Anglais

Enseignement proposé en : en présence

Niveau de l'enseignement : B2-Avancé - Utilisateur indépendant

Description du contenu de l'enseignement

1. Units-vectors We present the units of space, length, surface, volume, time, temperature, mass…. Conversions of units. Coordinates of vectors, norms, manipulation of vectors (sum, difference), drawing vectors in a cartesian plane.
2. Kinematics Average velocity and average acceleration. Instantaneous velocity and acceleration in cartesian coordinates. Presentation of polar basis, relation between time-derivative of radial and othoradial vectors, derivation of velocity and acceleration.
3. Dynamics Newton laws. Static equlibrium. Free Fall. Inclined plane. Pendulum. (the projection of vectors onto axis using Newton laws and obtention of motion equations). Conservation of energy and momentum (including on a rotating sphere), Coriolis forces, Orbital mechanics, Tides.
4. Energy. Harmonic Oscillator Kinetic, Potential and Total energy. Presentation of cosine and sine functions an its parameters (amplitude, frequency, phase). Obtention of second order equation in oscillator systems : spring and pendulum (small oscillations). Conservation of energy and exchange of energy between kinetic and potential energies.
5. Geometrical Optics : Notion of optical ray and its propagation in material media (reflection/refraction). Basics of conjugate systems (image-object- thin lens) and optical schemes, Snell's law
6. Electricity : Kirchoff laws in series and parallel for currents and voltages. Resistor. Ohm’s law. Equivalent resistor in series and parallel circuits.

Compétences à acquérir

  • Discovering the basic vocabulary in English related to the topics listed below.
  • Mastering the notion of vectors and their manipulations : projection, sum, norm calculation.
  • Knowing the cartesian and polar coordinates systems leading to the calculation of velocity and acceleration of a material point.
  • Mastering the motion equations in the free fall problem and being able to use them to make predictions about the mobile trajectory.
  • Understanding the concept of harmonic oscillator in mechanics: obtaining the motion equation, knowing the mathematical solution and understanding the influence played by the system parameters on the oscillator period.

Contact

Faculté de physique et ingénierie

3-5, rue de l'Université
67084 STRASBOURG CEDEX

Formulaire de contact

Responsable

Gulyaz Najafova