The low-frequency output, signal and noise, is determined following a general νth-law (ν/>0) half-wave rectification of a sinusoidally modulated carrier. The spectral width of the noise before rectification is assumed to be much narrower than its mean frequency f0, the normal condition for reception. Attention is focused on one of the harmonics of the rectified signal, generally the first, whose modulation frequency is small compared to the if frequency f0and to the width of the noise band. Special attention is given to the important cases of linear (ν=1) and quadratic (ν=2) detection, and audio signal-to-noise ratios sa/naare calculated for them. The noise passed by the audio filter is found to depend on the spectral shape of the if; for the three types of if filter specifically considered, namely, rectangular, gaussian, and "optical," the optical yields the least, the rectangular the most noise; provided, of course, that the mean input signal-to-noise power p is of the order of unity or less, the customary region of interest. When p1), and for very large signals, p→∞, sa/nais directly proportional to the input carrier amplitude, is independent of if filter width, and is only slightly dependent on filter shape. The best if filter is one whose response is the modulus of the Fourier transform of the signal, as in the radar case of pulsed signals.