1. Hydraulics, fluid properties, hydrostatic, pressure forces on plane and curved surfaces, floatation.

2. Hydrodynamics, continuity and momentum equation, Bernoulli equation, application of impulse theorem.

3. Water flow in pressure pipeline systems, laminar and turbulent flow.

4. Calculation of hydraulic long and short pipes and combined pipes. Inverted siphon, sucker, pump design.

5. Steady uniform flow with free surface in open channels.

6. Energetic head of profile. Critical flow. Supercritical and subcritical flow.

7. Overflow of water on overfalls. Orifice discharge and overfalls with reservoirs.

8. Hydraulic jump with bottom regime. Connection of water surface of two pools, design of rectangle stilling basin.

9. Hydraulic computation of typical communication objects, bridges and culverts.

10. Basics of groundwater flow (Darcy’s formula, filtration velocity, filtration coefficient, Dupuit theorem, groundwater flow in surrounding of a well).

11. Hydrology: occurrence of water and water cycle, hydrological balance, definition and characteristics of watershed, precipitation, evaporation, measurement of hydrological variables.

12. Surface runoff from watershed and its determination. Flow regimes in open channels. Maximum and minimum discharges, m-day and N-year discharges, winter regime, influence on runoff regime, influence of reservoirs on regulation of outflow from watershed, etc.

1.–2. Calculations of communicating vessels and pressure forces on plane and curved surfaces.

3.–4. Fluid flow calculations using the Bernoulli equation and the continuity equation.

5.–6. Calculations of steady uniform flow with free surface in open channels and critical depth calculations.

7.–8. Calculations of orifice discharge and overflow.

9.–10. Calculations of hydraulic jump and design of a rectangular stilling basin. The calculations of water flow in bridges and culverts.

11.–12. Basic calculations of groundwater flow – wells. Calculation of runoff from the watershed. Estimates of m-day discharges.