Explanation: Slotted waveguide arrays fed from one end operate as traveling-wave antennas. As the radio frequency changes, the wavelength of the signal propagating inside the waveguide also changes. This alteration in wavelength directly affects the phase relationship between the electromagnetic waves radiating from each successive slot along the waveguide. Since the beam direction of an array antenna is determined by the phase difference between its radiating elements, a change in frequency—and thus a change in the inter-slot phase relationship—causes the main lobe of the antenna's radiation pattern to shift or "scan" in angle. This phenomenon is known as frequency scan or beam squint. * **B) High VSWR:** A well-designed traveling-wave array, typically terminated with a matched load, aims for a low VSWR to efficiently radiate power. High VSWR is not an inherent characteristic of its frequency-dependent beam behavior. * **C) Poor performance in rain:** While all microwave signals can be attenuated by rain, slotted waveguide arrays themselves are generally robust and can be easily protected by a radome, making them less susceptible to *physical* performance issues due to rain compared to, for example, uncovered dish feeds. * **D) A narrow elevation beam:** The beamwidth depends on the array's length and number of elements, not directly on being fed from one end as a *consequence* linked to frequency. Many antenna types can produce narrow beams.