tch the first three standing waves that can be produced in an open-open tube. 2. Sketch the first three standing waves that can be produced in a closed-open tub
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1. Sketch the first three standing waves that can be produced in an open-open tube.
2. Sketch the first three standing waves that can be produced in a closed-open tube.
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- Two rocks are simultaneously dropped into a pond, creating the ripples shown. As they overlap, the ripples interfere. At the point marked with a dot, A. The interference is constructive. B. The interference is destructive. C. The interference is somewhere between constructive and destructive. D. There's not enough information to tell about the interference. What is the extra distance As traveled by one wave to the dot compared to the other? Α. Ο C. A 31 D. F. 4 5A B. E. 21 R, R, R I2 I3 Select all loop rules that apply to this circuit. SELECT ALL THAT APPLY A. 0 = -V +1,R2 – 1R1 B. 0 = V2 – 13R3- lR2 – Vị C. 0 = 4R1 – V2 – I3R3 D. 0 = -V – 1R2 + I¼R1 E. 0 = -V2 – I3R3 + 1½R2 +V1 F. 0 = 1, R, +V2 + I,R3 G. 0 = -V +I,R2 + I,Rq H. 0 = V2 + I3R3 + 1,R2 – V1 I. 0 = 1,R1 - V2 + I3R3 J. 0 = -V- I½R2 + I, R1 K. 0 = -V2 + I3R3 + 12R2 - V2 L. 0 = -1,R – V½ – 13R3 wwT ww1. A standing wave is created in a musical instrument as shown below. The frequency of the sound is 280 Hz. What is the fundamental frequency of this instrument? а. 70 Hz. b. 40 Hz. XXXX с. 172 Hz. d. 140 Hz. е. 280 Hz.Select all of the following statements which are true about transverse and longitudinal wave (Select all that apply) A. Transverse waves can move through solid, liquids and gasses. B. Longitudinal waves can move through solid, liquids and gasses. C. Transverse waves can only move through solids D. Longitudinal waves can only move through solids. E. Transverse waves can only move through liquids. F. Longitudinal waves can only move through liquids. G. Transverse waves can only move through gasses. H. Longitudinal waves can only move through gasses.
- 4. A telephone cable is stretched between two poles with a tension force of 3000 N. The cable has a linear mass density of 7.5 kg/m. What is the maximum speed of a wave on the cable? Using the speed from Question 4, what is the wavelength of the wave if it resonates at a frequency of 1.2 Hz?3.Which graph shows a linear relationship? The frequency is linear when plotted as a function of inverse length (ff vs. 1/L1/L). The frequency is linear when plotted as a function of length (ff vs. LL). 4.Draw a best-fit line through the linear graph’s data, and use the slope of this line to determine the wave speed. Express your answer in meters per second to two significant figures.5. On a day when the speed of sound in air is 345 m/s, the fundamental frequency of an open-ended organ pipe is 690 Hz. If the second harmonic of this pipe has the same wavelength as the second overtone (third harmonic) of a closed-end pipe, what is the length of each pipe?