GO In Fig. 16-42, a string, tied to a sinusoidal oscillator at P and running over a support at Q , is stretched by a block of mass m. Separation L = 1.20 m, linear density µ = 1.6 g/m, and the oscillator frequency f = 120 Hz. The amplitude of the motion at P is small enough for that point to be considered a node. A node also exists at Q. (a) What mass m allows the oscillator to set up the fourth harmonic on the string? (b) What standing wave mode, if any, can be set up if m = 1.00 kg? Figure 16-42 Problems 58 and 60.
GO In Fig. 16-42, a string, tied to a sinusoidal oscillator at P and running over a support at Q , is stretched by a block of mass m. Separation L = 1.20 m, linear density µ = 1.6 g/m, and the oscillator frequency f = 120 Hz. The amplitude of the motion at P is small enough for that point to be considered a node. A node also exists at Q. (a) What mass m allows the oscillator to set up the fourth harmonic on the string? (b) What standing wave mode, if any, can be set up if m = 1.00 kg? Figure 16-42 Problems 58 and 60.
GO In Fig. 16-42, a string, tied to a sinusoidal oscillator at P and running over a support at Q, is stretched by a block of mass m. Separation L = 1.20 m, linear density µ = 1.6 g/m, and the oscillator frequency f = 120 Hz. The amplitude of the motion at P is small enough for that point to be considered a node. A node also exists at Q. (a) What mass m allows the oscillator to set up the fourth harmonic on the string? (b) What standing wave mode, if any, can be set up if m = 1.00 kg?
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