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1 Multimedia Systems 1 Dr Paul Newbury School of Engineering and Information Technology ENGG II - 3A11 Ext: 2615
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2 Introduction Audio Systems The Physics of Sound Java Sound API Input Transducers Output Transducers Manipulating Audio Manipulating Digital Audio Storing Digital Audio Digital Audio Formats PC Audio Audio Issues
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3 Course Aims ‘The course aims to give the student a broad introduction to audio systems and in particular digital audio’ The course covers the principles of audio capture manipulation and output using a computer based system
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4 Course Objectives ‘The student will understand the components and processes necessary to capture, manipulate and output audio. Along with an understanding of the wider issues involved with audio production and distribution’ They will be required to understand the principles of audio processing, the need for, and the main features of audio systems
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5 Structure Three single lectures per week: Monday 11.30 AS2 Tuesday 10.15 AS2 Friday9.15 AS2 One, 2 hour lab per week See lab timetable One problem sheet per week Fragments of exam style questions To be handed in to the post box in the photocopier room by 11.15 the following Friday
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6 Course Web Page All support materials for this course are available at: www.mtllive.com This includes All Lecture slides in.pdf and.ppt format All Problem sheets in.doc and.pdf format All Lab sheets in.html.doc and.pdf format Links to support information on particular topics.
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7 Lab Work Two lab activities Cool Edit 2000 Java Sound API
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8 Course Assessment Unseen exam 70% Lab work 30% (Cool Edit and Java Sound API)
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9 Reading Material Look at the web pages for useful links. Books: Principles of Digital Audio, 4 th edition Ken C. Pohlmann McGraw-Hill (2000) This is a non-introductory text which covers the whole course. Only worth considering if you wish to find out more detail about the topics covered in the course
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10 Introduction Physics of Sound
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11 Acoustics Study of sound Generation Transmission Reception Sound is the rapid change in air pressure Speed at which air moves (and thus the sound travelling through it) depends on its density
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12 Sound Waves
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13 Sound Waves
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14 The distance that sound travels through one complete cycle of pressure change The time this takes is know as the period of the wave and is the reciprocal of frequency Wavelength v = Velocity of sound (344m/s) f = frequency 20KHz =16.5mm 20Hz = 16.5 meters Wavelength
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15 Frequency The number of vibration cycles that pass a particular point each second Measured in Hertz (Hz) cycles per second The pitch of a sound is dependant on its frequency Human ear can hear between 20Hz –20KHz (bandwidth) Low frequency – Bass High frequency – Treble
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16 Bandwidth The difference between the maximum rate of oscillation (or highest frequency) and the minimum rate of oscillation (or lowest frequency) of the sine waves making up the signal is known as the bandwidth of the signal
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17 Bandwidth Telephone bandwidth approx 400Hz to 3.4KHz Voice on a telephone Normal voice
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18 Bass Long wavelengths (middle bass 3 meters) Easily bend around objects Human hearing is not directionally sensitive to low frequency sound A single low frequency speaker (subwoofer) can be used
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19 Treble Short wavelength (centimetres) Easily blocked or reflected by objects Human hearing is very sensitive to location
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20 Timbre Listening to a flute, violin or tuning fork each producing the same note (pitch) we can distinguish between them It is the number of overtones (harmonic or not) and their relative amplitudes that determine timbre
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21 Amplitude Strength or power of the sound Describes the sound pressure displacement above and below the equilibrium atmospheric level The amplitude of sound travelling through air is usually expressed as sound pressure level SPL Sound pressure is very small Threshold of hearing 0.0002 microbar Human ears have a large dynamic range
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22 Decibels A Bel is the relationship between two powers (ratio) expressed as a logarithm Sound source P 1 = 1W Sound source P 2 = 1mW Ratio 1,000:1 or 3B or 30dB Approximately coincides with the way we hear sounds
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23 Decibels In acoustic measurements the reference level is often set to the threshold of hearing 10 -12 W/m 2 Thus the intensity level of a band producing 10W/m 2 130 dB SPL(sound pressure level)
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24 Harmonics
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25 Harmonics Fundamental Frequency
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26 Superposition
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27 Fourier Any waveform can be decomposed into harmonic components.
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28 Multiple Sound Channels Stereo – the use of two separate sound signals to produces the effect that sound is coming from a spatial position between the two speakers Binaural - uses special microphones placed inside a dummy head to make a recording Quadraphonic – four channels, two front, two back Surround sound – multiple speakers (e.g. 5.1)
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29 Fin
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