5. Whenever a wave is used as a probe (e.g. ultrasound), it is difficult to detect target details that is smaller than the wave's wavelength, 2. Higher frequency ultrasound would allow greater detail, but it lessen the penetration depth compared to lower frequencies. The acceptable effective scan depth is about 5002 into a tissue. (A) Calculate the minimum frequency of ultrasound that will allow you to see details as small as 0.250 mm in human tissue given the speed of sound in tissue is about 1540 m/s. (B) What is the effective depth to which this sound is effective as a diagnostic probe? Review: A = where v: speed of sound in a medium, f: frequency.

5. Whenever a wave is used as a probe (e.g. ultrasound), it is difficult to detect target details that is smaller than the wave's wavelength, 2. Higher frequency ultrasound would allow greater detail, but it lessen the penetration depth compared to lower frequencies. The acceptable effective scan depth is about 5002 into a tissue. (A) Calculate the minimum frequency of ultrasound that will allow you to see details as small as 0.250 mm in human tissue given the speed of sound in tissue is about 1540 m/s. (B) What is the effective depth to which this sound is effective as a diagnostic probe? Review: A = where v: speed of sound in a medium, f: frequency.

College Physics

1st Edition

ISBN:9781938168000

Author:Paul Peter Urone, Roger Hinrichs

Publisher:Paul Peter Urone, Roger Hinrichs

Chapter17: Physics Of Hearing

Section: Chapter Questions

Problem 27PE: (a) Ear trumpets were never very common, but they did aid people with hearing losses by gathering...

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