4.1 Determination of material density
Scope of work: Mechanics Determine the density of different materials and estimate measurement errors. Attachment: 4.1.pdf (LT) |
4.3 Determining the moment of inertia with a bifilar pendulum
Scope of work: Mechanics The work is aimed at determining the moments of inertia of the two coils of a bifilar pendulum and verifying the Huygens-Steiner theorem. Attachment: 4.3.pdf (LT) |
4.4 Study of gyroscopic phenomena
Scope of work: Mechanics The work is aimed at determining the moment of inertia, precession and nutation period of a gyroscope as a function of the rotational frequency of the disc. Attachment: 4.4.pdf (LT) |
4.5 Determining the speed of sound in air using the standing wave method
Scope of work: Mechanics The work is aimed at determining the speed of sound in air using the standing wave method. Attachment: 4.5.pdf (LT) |
4.6 Determining the threshold of hearing sensation with a computer audiometer
Scope of work: Mechanics The work is aimed at determining the spectral dependence of the hearing threshold of the ear. Attachment: 4.6.pdf (LT) |
4.7 Study of tethered pendulums
Scope of work: Mechanics The work is aimed at determining the temporal dynamics and parameters of free and constrained oscillations. Attachment: 4.7.pdf (LT) |
4.8 Testing the law of the reciprocating motion
Scope of work: Mechanics The purpose of this work is to verify the law of quantity of motion of a two-ball system for elastic and plastic impact. Attachment: 4.8.pdf (LT) |
4.9 Determining the acceleration of free fall with a universal pendulum
Scope of work: Mechanics The work is aimed at determining the acceleration of free fall using a mathematical and inverted pendulum. Attachment: 4.9.pdf (LT) |
4.11 Study of damping oscillations
Scope of work: Mechanics The work is aimed at determining the rolling friction coefficient of a ball and the dependence of the damping period of an inclined pendulum on its angle of inclination. Attachment: 4.11.pdf (LT) |
4.12 Investigating a mathematical pendulum model
Scope of work: Mechanics The work is aimed at modelling a mathematical pendulum and assessing the influence of thread tension and air resistance on the period of oscillation of the pendulum. Attachment: 4.12.pdf (LT) |
4.13. Determining the moment of inertia of a Maxwell pendulum
Scope of work: Mechanics The work is aimed at determining the moment of inertia of Maxwell's pendulum. Attachment: 4.13.pdf (LT) |
4.14 Determining the moment of inertia of rectangular bodies
Scope of work: Mechanics The work is aimed at determining the moments of inertia of homogeneous orthogonal bodies in relation to various axes passing through the centre of mass of the body. Attachment: 4.14.pdf (LT) |
4.15 Study of rectilinear motion
Scope of work: Mechanics The work is designed to investigate rectilinear motion in an Atwood machine and determine the acceleration of bodies. Attachment: 4.15.pdf (LT) |
4.16 Ultrasonic wave speed determination
Scope of work: Mechanics The work is to investigate the properties of ultrasound in air. Attachment: 4.16a.pdf (LT) |
4.17 Examination of various samples by ultrasonic echoscopy
Scope of work: Mechanics The work is designed to investigate the basic characteristics of ultrasonic waves, to determine the dimensions and positions of the models used. Attachment: 4.17.pdf (LT) |
4.18 Acoustic Doppler effect study
Scope of work: Mechanics This work is to investigate the acoustic Doppler effect. . Attachment: 4.18.pdf (LT) |