Final answer:
The NAND latch operates based on two inputs, S and R. When S is high and R is low, the latch sets, resulting in Q being high and Q' being low. Conversely, when S is low and R is high, the latch resets, with Q becoming low and Q' becoming high. If both S and R are low, the latch maintains its previous state.
Step-by-step explanation:
The question concerns the determination of the radiation resistance, Ohmic resistance, and total inductance of a circular loop antenna at a specific frequency. To find the radiation resistance, we can use formulas derived from electromagnetic theory that relate the antenna's dimensions to its electrical characteristics.
The Ohmic resistance can be found using the resistivity of copper and the physical dimensions of the wire. The total inductance can be calculated using formulas that take into account the number of turns in the coil and the physical dimensions of the loop.
For example, to estimate the Ohmic resistance, we use the formula R = ρ⋅L/A, where ρ is the resistivity of copper, L is the length of wire, and A is the cross-sectional area of the wire. The inductance of a single loop can be estimated with an approximation formula like L = μ_0 * radius, considering factors like the permeability of free space (μ_0) and the loop radius.
However, precise formulas for radiation resistance are more complex and often require the use of integral calculus and electromagnetic theory, which go beyond the scope of a simple explanation.