Buoyancy is the upward force exerted by a fluid on an object that is immersed in it. For an object to float, the buoyant force must be equal to the weight of the object. The buoyant force is given by Archimedes' principle, which states that the buoyant force is equal to the weight of the fluid displaced by the object. Since ice floats on water, we know that its density is less than that of water. If we take the density of ice as \(\rho_{\text{ice}}\) and the density of water as \(\rho_{\text{water}}\), we can see that \(\rho_{\text{ice}} < \rho_{\text{water}}\).

When the ice melts, it turns into water, so its overall mass remains constant. We need to analyze the effect of the ice melting on the water level inside the glass. Let's say the volume of the water in the glass initially is \(V_{\text{water}}\), and the volume of the ice in the glass is \(V_{\text{ice}}\). The total volume of the ice and water inside the glass initially is \(V_{\text{total}} = V_{\text{water}} + V_{\text{ice}}\). When the ice melts, it becomes water, and its mass is conserved. Let's say the volume of the melted ice is \(V_{\text{melted\_ice}}\). We can find the relationship between the volumes of melted ice and the initial ice using the densities of ice and water. Since mass is conserved, we have: \(\rho_{\text{ice}} V_{\text{ice}} = \rho_{\text{water}} V_{\text{melted\_ice}}\) Solving for \(V_{\text{melted\_ice}}\), we get: \(V_{\text{melted\_ice}} = \frac{\rho_{\text{ice}}}{\rho_{\text{water}}}V_{\text{ice}}