Unit 7: Graphics and Multimedia



            (2 to the 8th power). Sampling at 16-bits divides the voltage into 65,536 parts (2 to the 16th power).   Notes
            Using a higher sampling resolution creates cleaner recordings with less background noise. Higher
            sampling resolutions also capture a wider dynamic range. For example an 8-bit digitizer will only
            capture sounds up to 48 decibels (DB). Any portion of the sound that is louder than48 DB will be
            clipped and the resulting sample will sound distorted. 16-bit digitizers, however, capture up to
            96 DB of volume. The dynamic range of the human ear extends to 120 DB.
            Quantization is the term that describes the process of measuring the amplitude of a sound and
            rounding off the measurements according to the sampling resolution. For example, an 8-bit sound
            digitizer will assign integer values of between 0 and 255 for the amplitude of each sample. The
            result is that the original smooth waveform is reconstructed as a staircase shape with only 256
            discrete levels of amplitude and noise is introduced into the signal. 16-bit digitizers, on the other
            hand, assign amplitude values on a scale of 0 to 65,535. At that level of precision, the reconstructed
            waveform is almost identical to the original and almost no noise is introduced.

                          Figure 7.6: Original Waveform and Quantized Waveform

















            All of these measurements are made by an analog-to-digital converter. The measurements can
            then be stored as binary numbers in a file on a computer’s hard disk. To play back the sound,
            the computer sends the information in the file to a digital-to-analog converter which reproduces
            the original electrical signal. That signal is then sent to a speaker which produces the sound as
            described earlier.
            Maximum precision per measurement combined with maximum sampling rates produces
            the highest quality recordings. To describe a digital recording of a sound, therefore, one
            can speak of the sampling rate and resolution. For example, sound recorded at a sampling
            rate  of  22  kHz  with  8-bit  resolution  is  considered  to  be  of  a  quality  similar  to  that  of  a
            telephone call. Sound recorded at 44 kHz and 16-bits is considered the minimum quality for
            compact disc recordings because it captures the full range of human hearing. In multimedia
            production work, 11 kHz, 8-bit sound is sometimes acceptable for speech recordings
            and 22 kHz, 8-bit resolution or 11 KHz, 16-bit resolution is often considered acceptable
            for music. For the highest-level multimedia work, however, nothing short of 44 kHz,
            16-bit sound is acceptable.
            When sound waves strike a microphone, they are converted to an electrical signal which
            is measured many thousand times per second by an analog-to-digital converter chip. The
            measurements are stored in the computer as binary numbers.
            The higher the quality of sound, the more space it takes to store the sound. A compact disc can
            store about 74 minutes of stereo sound at 44 kHz, 16-bit. If you reduce the quality to 22 kHz, 8-bit
            stereo sound, however, you can store approximately 300 minutes of audio on the same disc. In
            other words, one minute of stereo sound takes 10 megabytes of storage at 44 kHz, 16-bit quality,
            and only 2.5 megabytes of storage at 22 kHz, 8-bit quality. When producing sound for multimedia,
            therefore, one must consider not only sound quality, but also how the sound will be distributed.
            If your multimedia program will be distributed on CD then you may have enough storage space



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