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Exam and Assignment Dates. Midterm 1 Feb 3 rd and 4 th Midterm 2 March 9 th and 10 th Final April 20 th and 21 st Idea journal assignment is due on last day of class. Textbooks. Sensation and Perception Fundamentals of Sensation Cognition – Useful in a few weeks
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Exam and Assignment Dates • Midterm 1 Feb 3rd and 4th • Midterm 2 March 9th and 10th • Final April 20th and 21st • Idea journal assignment is due on last day of class
Textbooks • Sensation and Perception • Fundamentals of Sensation • Cognition – Useful in a few weeks • Course Pack – Will start in a couple weeks. Useful Now
Hearing • Detection • Loudness • Localization • Scene Analysis • Music • Speech
Detection and Loudness • Sound level is measured in decibels (dB) - a measure of the amplitude of air pressure fluctuations
Detection and Loudness • Sound level is measured in decibels (dB) - a measure of the amplitude of air pressure fluctuations • dB is a log scale - small increases in dB mean large increases in sound energy
Detection and Loudness • Sound level is measured in decibels (dB) - a measure of the amplitude of air pressure fluctuations • dB is a log scale - small increases in dB mean large increases in sound energy • We have a dynamic range that is a factor of 7.5 million!
Detection and Loudness • minimum sound level necessary to be heard is the detection threshold
Detection and Loudness • detection threshold depends on frequency of sound: • very high and very low frequencies must have more energy (higher dB) to be heard • greatest sensitivity (lowest detection threshold) is between 1000 hz to 5000hz
Detection and Loudness • Detection can be compromised by a masking sound • even masking sounds that are not simultaneous with the target can cause masking (forward and backward masking)
Detection and Loudness • Loudness is the subjective impression of sound level (and not identical to it!)
Detection and Loudness • For example, tones of different frequencies that are judged to be equally loud have different SPLs (dB)
Detection and Loudness • Hearing loss due to exposure to high-intensity sounds (greater than 100 dB) is frequency-specific and can last many hours
Detection and Loudness • Incidence of noise-related hearing loss is increasing dramatically • iPods and other “earbud” music players are thought to be partly responsible • How loud is an iPod? • maximum volume is approximate but is somewhere between 100 dB (hearing damage in about 2 hours) to 115 dB (hearing damage in about 15 minutes) • Consequences: difficulty understanding speech, tinnitus, deafness • Your perception of loudness adapts so it’s hard to tell how loud your iPod is - LOCK THE VOLUME ON YOUR iPOD!
Auditory Scene Analysis • recall the lake analogy: task is to • localize the positions of the boats on a lake using the pattern of ripples at two points on the shore • Identify the sources of those ripples • Ignore non-relevant ripples
Localization • All you have is a pair of instruments (basilar membranes) that measure air pressure fluctuations over time
Localization • There are several clues you could use:
Localization Left Ear Right Ear Compression Waves
Localization • There are several clues you could use: • arrival time - sound arrives first at ear closest to source
Localization Left Ear Right Ear Compression Waves
Localization • There are several clues you could use: • arrival time • phase lag (waves are out of sync) - wave at ear farthest from sound source lags wave at ear nearest to source
Localization Left Ear Right Ear Compression Waves
Localization • What are some problems or limitations?
Localization • Low frequency sounds aren’t attenuated by head shadow Sound is the same SPL at both ears Left Ear Right Ear Compression Waves
Localization • High frequency sounds have ambiguous phase lag Left Ear Left Ear Right Ear Right Ear Two locations, same phase information!
Localization • These cues only provide azimuth (left/right) angle, not altitude (up/down) and not distance Left Ear Right Ear Azimuth
Localization Additional cues:
Localization Additional cues: Head Related Transfer Function: Pinnae modify the frequency components differently depending on sound location
Localization Additional cues: Room Echoes: For each sound, there are 6 “copies” (in a simple rectanguluar room!). Different arrival times of these copies provide cues to location of sound relative to the acoustic space
Localization • What would be the “worst case” scenario for localizing a sound?