Download - Basics of Audio Signal Processing
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Basics of Audio Signal Processing
Sudhir K
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Summary Slide
Digital Representation of Audio Psycho-Acoustic principles Lossy Compression of Audio (MP3 and AAC) Lossless compression of Audio (general principles with example)
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Digital Representation of Audio
PCM Data Sampling audio input at discrete intervals and quantizing into discrete
number of evenly spaced levels. Sampling Frequency Bits per sample Number of Channels Interleaved and block format
Audio CD 44.1 KHz, 2 channels , data-rate is 1.4 Mbits per second
ADCDigital
ProcessingDAC speakers
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Psycho-Acoustic Principles
Sound Pressure Level Perceptual and Statistical redundancy Absolute Threshold of Hearing Critical Bands Masking in Time domain Masking in Frequency domain Perceptual Entropy Pre-echo Effect Psycho-Acoustic Model 1 Psycho-Acoustic Model 2 Filter Banks and Transforms
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Sound Pressure Level
Standard metric to quantify intensity of acoustical stimulus
Measured in decibels (dB) relative to an internationally defined reference level
LSPL is the SPL of stimulus p
P0 is the standard reference level at 20 µPa
150-dB SPL is the dynamic range of human auditory system
140-dB SPL is typically the threshold of pain Human auditory system can hear frequencies
ranging from 20 Hz to 20 KHz frequency
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Absolute Threshold of Hearing Characterizes the amount of energy needed in a pure tone such that
it can be detected by a listener in a noiseless environment This can be interpreted naively as a maximum allowable energy
level for coding distortions introduced in frequency domain
Note that the absolute threshold of hearing is a function of frequency Response of a human ear for a pure tone is dependant on the frequency
of the tone Sensation Level : intensity level difference for stimultus relative to
detection threshold (quantifies listener’s audibility) Equal SL components can have different SPL’s
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Absolute Threshold of Hearing
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Human Ear Model
Frequency to place transformation
Sound wave moves the eardrum and attached bones
The eardrum and the bones transfer mechanical vibrations to Cochlea
Oval window of cochlear membrane induces traveling waves along length of basilar membrane.
Traveling waves generate peak responses at frequency specific membrane positions
Specific positions of membrane provide peak responses for specific frequency band
Cochlea can be considered as a set of highly
overlapped band-pass filters.
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Critical Bands Cochlea can be considered as a set of
highly overlapped band-pass filters. Critical bandwidth is a function of
frequency that quantifies the cochlear bandwidth
Loudness (percieved intensity) remains same when the noise energy in present within a critical band
One bark corresponds to distance of one critical band
Critical bandwidth tends to remain constant up to 500Hz and then increases to 20% of center frequency above 500 Hz
Frequency (KHz)
0 2 4 6 8 10 12 14 16 18 20
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Simultaneous Masking Process where one sound is rendered inaudible by presence of another sound Frequency domain masking
Masker
Maskee
Tone masking Noise (TMN) Noise Masking Tone Noise Masking Noise In-band Phenomenon (occurs within same critical band)
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Simultaneous Masking SMR (signal to mask ratio)
smallest difference between intensity of masking signal and the intensity of masked signal
SMR for NMN is 26dB, TMN is 24dB and NMT is 5dB
Noise is a better masker than tone
Spread of Masking Inter-band Masking Triangular spreading function
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Temporal (Non-simultaneous) masking Masking in time-domain Pre-Masking : Masking occurs prior to the signal Post-Masking: Masking following the occurrence of signal Pre-masking is usually less (approx 1-2 ms) Post-masking is of longer duration (50 to 300ms)
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Just Noticeable Difference (JND) Also called as global masking threshold Global Masking threshold is a combinaton of individual masking
thresholds (threshold due to NMT, TMN and absolute threshold) Quantization noise should be kept below the JND to keep it
inaudible.
Masking curve
Noise
Signal
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Perceptual Entropy Measure of perceptually relevant information Expressed in bits per sample Represents a theoretical limit on compressibility of a particular
signal
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Pre-Echo
Pre-echoes occur when a signal with sharp attack begins near end of a transform block immediately following a region of low energy
Inverse quantization spreads evenly throughout the reconstructed block
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Pre-Echo control
Bit-reservoir Store surplus bits, which can be used during periods of attack
Window Switching Switch between long and short time-window Short window for transients to minimize spread of noise. Long window for normal case to increase compression efficiency
Gain Modification Smoothes transient peaks by changing gain of signal prior to the
transient
Temporal Noise Masking Linear prediction on frequency domain spectrum Flattened residual and quantization noise. The quantization noise is suchthat it follows original signal enveope
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Stereo coding
MS-Stereo (Middle/Side Stereo) One channel to encode information identical between left and right
channel One channel to encode differences between left and right channel Transmit sum and difference of the original signals in left and right
channels
Intensity Stereo Lossy Coding technique Replace left and right channel with a single representing signal plus
directional information Usually used only in higher frequencies (since human ear is less
sensitive to signal phase at these frequencies) Used only at low bit-rates
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Psycho Acoustic Model11. Spectral analysis and SPL normalization
Normalize input samples and segment into blocks
2. Identification of Tonal and Noise maskers Energy from 3 adjacent spectral components combined to form single
tonal masker Energy of all other spectral lines not within a range of Δ combined to
form noise masker
Decimation and reorganization of maskers Any tonal or noise threshold below absolute threshold are discarded Adjacent pair of maskers are compared and is replaced by stronger of
the two.
Calculation of individual Masking Threshold Calcullate threshold due to tonal and noise maskers
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Pyscho Acoustic Model 1
Threshold due to tonal maskers
Threshold due to noise maskers
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Psycho Acoustic Model 1 Calcullation of global masking threshold
Individual masking threshold are combined to estimate global masking threshold
Assumes masking effects are additive Sum of absolute threshold of hearing, threshold from tonal masker and
threshold from noise masker
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Filter Bank Characteristics Lossless (analysis and synthesis should be invertible) Aliasing errors should cancel for perfect or near-perfect
reconstruction Low computational complexity Bandwidth should replicate critical bands of human ear.
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QMF Filters
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Pseudo-QMF
Cosine Modulation of low-pass prototype filter to implement parallel M-channel filter banks with nearly perfect reconstruction
Overall linear phase and hence constant group delay Complexity = one filter + modulation Critical sampling
Analysis & synthesis filters satisfy mirror image conditions to eliminate phase distortion
Analysis filter
Synthesis filter
MPEG1 uses a 32-channel PQMF bank for spectral decomposition in layer I and Layer II
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MDCT (TDAC)
De-correlate signal by mapping to an orthogonal basis functions Lapped orthogonal block transform Successive transform block overlap each other Overall linear phase Forward MDCT
50% Overlap between blocks Block transform of 2M samples and block advance of M samples Basis functions extend across 2 blocks (blocking artifacts elimination) Critically sampled M samples output for 2M input samples
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Lossy Audio Compression techniques Decoded output is not bit-exact with original input Decoded output is perceptually same as original input More compression achieved Extensive use of psycho-acoustic model to discard perceptually
irrelevant audio data Examples : MP3 and AAC
Time to Frequency Filter Bank
Allocate bits &
Quantize
FormatBitstream
Psycho-Acoustics
Model
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Audio Decoder
Usually Encoder Complex and Decoder less complex
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MPEG Compression ISO 11172-3 ISO (MPEG 1) Mainly specifies the bit-stream and hence leaves the flexibility of Encoder
design to individual developers Lossy and perceptually transparent Sampling frequencies of 32, 44.1 KHz and 48 KHz supported Various bit-rates from 32-192 kbps per channel supported Supports following channel modes
Mono, Stereo, Dual Mono, Joint Stereo Based on complexity 3 independent layers of compression
Layer 1 (around 192 kbps per channel) Layer 2 (around 128 kbps per channel) Layer 3 (MP3) (around 64 kbps per channel)
Complexity increases as we go from Layer 1 to Layer 3 CRC (optional) for error checking Ancillary Data support
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MPEG 1 layer1 and layer 2
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MPEG Layer 1 and Layer 2 Sub-band filtering
Polyphase filter bank Decompose input signal into 32 sub-bands Sub-bands are equally spaced (for ex : 48KHz signal, each subband is
750 Hz) Critically sampled (output of each sub-band is down sampled such that
the number of input and output samples are the same) sub-bands do not reflect the human ear’s critical band Prototype filter chosen such that high side lobe attenuation (96 dB) is
achieved Not perfectly Lossless (error is small)
FFT Done for psycho-acoustic analysis and determination of JND thresholds Done in parallel with the sub-band filtering Layer 1 : 512 and Layer 2 : 1024 point
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MPEG 1 Layer 1 and Layer 2 Block companding
Sub-band filtering output is block-companded (normalized by a scale factor) such that the maximum sample amplitude in each block is unity.
This operation is done on a block of 12 samples (8 ms at 48 KHz) Psycho-Acoustic analysis
Output of the FFT block is input to the psycho-acoustic block This block outputs the masking threshold for each band
Quantization and bit-allocation This procedure is iterative Bit-allocation applies JND threshold to select an optimal quantizer
from a pre-determined set Quantization should satisfy both masking and bit-rate requirements Scale factors and quantizer selections are also coded and sent in the
bitstream
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MPEG Layer 1 and Layer 2 Psycho-Acoustic Model
Separate spectral values into tonal and non-tonal components or calcullate tonality index
Apply spreading function Set lower bound for threshold values Find masking threshold for each sub-band Calculate Signal to Mask Ratio and pass it to the bit-allocation block.
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MPEG 1 Layer 1 and Layer 2
MPEG1 Layer 1 Frame length of 384 samples 32 sub-bands of length 12. Each group of 12 samples gets a bit-allocation and a scale-factor
MPEG 1 Layer 2 Enhancement of Layer 1 More compact code for representing scale-factors, quantized samples
and bit-allocation Frame length of 1152 samples Each sub-band = 3 groups of 12 samples each Each sub-band has a bit-allocation and upto 3 scale-factors
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MPEG 1 Layer 1 and Layer 2
Bitstream
SCFSI : Scale factor Selection information. Number of scale factors for each sub-band.
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MPEG 1 Layer 3
Diag from fhg site
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MPEG 1 Layer 3
Main blocks Filter Bank Perceptual acoustic model Quantization and Coding Encoding of bit-stream
Features Mono and stereo support Bit-rates upto 320 kbps Sampling frequencies => 32 KHz, 44.1 KHz and 48 KHz CBR and VBR coding MS-stereo and IS-stereo coding
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Enhancements over Layer 1 and Layer 2
Higher frequency resolution due to MDCT Non-uniform quantization Uses scale-factor bands, which resemble human ear model (unlike
sub-bands used in Layer 1 and Layer 2) Entropy Coding (Variable length Huffman codes) Better Handling of Pre-echo artifacts Use of Bit-reservoir
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Hybrid Filter BankFilterBank
Hybrid filter bank Better approximation of critical
bands of human ear Poly-phase filter followed by
MDCT filter bank Poly-phase filter bank
Compatible to Layer 1 and Layer 2
MDCT filter bank Each poly-phase frequency band
into 18 finer sub-bands Higher frequency resolution Pre-echo control Better Alias reduction Block Switching
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for i=31 downto 0 do X[i]=next_input_audio_sample
for i=511 downto 32 do X[i]=X[i-32]
BEGIN
Partial Calculation
Zi + 64j
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j=0
Window by 512 Coefficients Produce Vector Z
for i=0 to 511 do Zi=Ci*X i
Calculate 32 Samples by Matrixing
END
Output 32 Subband Samples
M63
k=0
ik * Yk
for i=0 do 63 do Yi =
for i=0 do 31 do Si =
Sub-band Filtering
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Window SwitchingWindow Switching
Short and long windows Adaptive MDCT block sizes of 6 and 18 points Short windows to prevent pre-echo (pre-masking to hide pre-echoes) Long window of length 1152 samples Short window of length 384 samples
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Quantization and Coding Uses Bit-reservoir
Bits saved from one frame are used for encoding other frame
Non-linear quantization
Huffman encoding 32 different huffman code tables available for coding Each table caters for different Max value that can be coded and the
signal statistics Different code books for each sub-region
ix(i) = nint(( xr(i)
24 qquant+quantanf
)0.75
- 0.0946)
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RETURN
ny
Inner Iteration Loop
Calculate the distortion for each critical band
Save scaling factors of the critical bands
Preemphasis
Amplify critical bands with more than the allowed distortion
ny
ny
All critical bands amplified ?
Amplification of all bands below upper limit ?
At least one band with more than the allowed distortion ?
Layer III Outer Iteration Loop
Restore scaling factors
BEGINQuantization and
Coding Inner iteration loop
Rate control loop Assigns shorter code to more frequently
used values Does huffman coding and quantization Keeps increasing global gain till
quantization values are small enough to be encoded by available number of bits
Outer Iteration loop Noise Control loop If quantization noise exceeds masking
threshold in any band then it increases the scale factor for that band
Executed till noise is less than masking threshold
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Bit-reservoir and Back-frames
Encoder can donate bits to bit-reservoir and can borrow bits from the bit-reservoir
9-bit pointer for pointing to main data begin (starting byte of audio data for that frame)
Theoretically the main data begin cannot be greater than 7680 bits (frame length for frame of 320 kbps at 48 KHz)
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Advanced Audio Coding (AAC)
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AAC Features Sampling Rate (8 kHz to 96 kHz) Bit Rates (8 kbps to 576kbps) Mono, Stereo and multi-channel (Upto 48 channels) Supports both CBR and VBR Multiple profiles or Object Types
Low Complexity (LC) SSR HE (High Efficiency) HEv2 (High Efficiency with Parametric Stereo)
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AAC-Basic Features and Modules High frequency resolution transform coder (1024 lines MDCT with
50% overlap) Non-uniform quantizer Noise shaping in scale factor bands Huffman Coding Temporal Noise Shaping (TNS) Perceptual Noise Substitution (PNS) Modules
FilterBank Perceptual Model Quantization and Coding Optional tools like TNS, PNS, prediction etc
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Improvements over MP3 Higher efficiency and simpler filter bank
Only MDCT vs hybrid filter bank of MP3 Higher Frequency Resolution (1024 vs 576 of MP3) Improved Huffman Coding table Window Shape adaptation (Sine and KBD) Enhanced Block Switching
The window length is dynamically changed between 2048 and 256 samples (Against 1152 and 384 of MP3). This leads to better coding efficiency for long blocks and less pre-echo artifacts for short blocks.
Use of following tools only in AAC Temporal Noise Shaping Perceptual Noise Substitution Long Term Prediction
More flexible joint stereo (separate for every scale band)
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Filter Bank MDCT supporting block lengths of 2048 and 256 points Dynamic switching between long and short blocks 50 % overlap between blocks Windows are of two types
Kaiser Bessel Window (KBD) Sine shaped Window
In case of short blocks 8 short transforms are performed in a row to maintain synchronicity
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Temporal Noise Shaping (TNS) Forward Prediction
Correlation between subsequent input samples exploited by quantizing the prediction error based on unquantized input samples
Quantization error in the final decoded signal is adapted to PSD (Power Spectral Density) of the input signal
Forward prediction done on spectral data over frequency. The temporal shape of the quantization error signal will appear adapted to the temporal shape of input signal at output of the decoder.
Temporal shape of Quantization noise of a filter bank is adapted to the envelope of the input signal by TNS and in case of No TNS the quantization noise is distributed almost uniformly over time.
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Temporal Noise Shaping (TNS) Tool for handling transient and pitched input signals Duality between time and frequency domains
Un-flat spectrum can be coded efficiently by coding spectral values or by applying predictive coding methods to time-domain signal
Duality : Efficient coding of transient signals (un-flat in time-domain) is efficient in time-domain or by applying predictive methods to the spectral data
TNS uses a prediction approach in the frequency domain to shape the quantization noise over time
Quantized filter coefficients transmitted TNS tool can be dynamically switched on and off in the stream
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Perceptual Noise Substitution (PNS)
Available only in MPEG-4 and not in MPEG-2 Based on the fact that the fine structure of a noise signal is of minor
importance for the subjective perception of signal. Instead of transmitting actual spectrum transmit the following
Information that this frequency region is noise-like. Total power in that frequency band
PNS can be switched on and off on a scale-factor basis. In decoder when a region is coded using PNS, then the decoder
inserts randomly generated noise.
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Spectral Band Replication (SBR)
Recreate High-frequencies from decoded base-band signal. Enhancement Technology (needs a base audio codec) Base codec operates at half the sampling frequency of SBR The bit-stream of the basic encoder + control parameters
transmitted.
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SBR Decoder
1. Decoded low-band Signal analyzed using QMF
2. High Frequency Reconstruction from Lower bands
3. Reconstructed signal adaptively filtered to ensure spectral characteristics of each sub-band
4. Envelope adjustment
5. Addition of low-band signals with envelope adjusted high-band signals
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Parametric Stereo (PS)
Mono Signal is encoded along with stereo Parameters as side information in the encoded bit-stream
3 types of parameters are employed in parametric stereo Inter-Channel Intensity Difference (IID) Inter-Channel Cross Coherence (ICC) Inter-Channel Phase Difference (IPD)
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Lossless Audio Compression
Sudhir K
Multimedia Codecs
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Main Features
No Loss in Quality Perfect Reconstruction Less Compression No Psycho-Acoustic Model required Applications
High-end Audio Home-Theatre DVD Audio
Examples MLP, WMA Lossless, OptimFrog, Real Lossless, Monkey’s audio,
FLAC, LTAC, Apple Lossless, TTA Lossless audio, MPEG4 lossless Coding (ALC)
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Types of Lossless Coding
Time domain lossless Coding Audio data in time-domain Most of the current lossless compression techniques are of this type
Frequency domain lossless Coding Operate on audio data in Frequency domain Very few schemes like LTAC
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Time Domain Lossless compression
Block Decomposition Inter-Channel Decorrelation Signal Modelling Entropy Coding
BlockDecomposition
Inter-ChannelDecorrelation
SignalModelling
EntropyCoding
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Inter-Channel Coding
Redundancy between various channels Various Techniques
Difference Channel Coding Mid-Side Stereo Coding Intensity Stereo Coding Inter-Channel Matrixing
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Signal Modeling and Prediction
Model input audio signal Difference between original and predicted audio signal minimal Model parameters and error coefficients transmitted Computationally most complex block Various Techniques
Linear Prediction LMS Filter or Adaptive filter Polynomial Curve fitting techniques
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Entropy Coding
Remove redundancy between bits in the bit-stream To compress residue or error signal further Many schemes
Huffman coding Run length Coding Golomb Rice coding
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References TED PAINTER, ANDREAS SPANIAS, “Perceptual Coding of Digital Audio”, in Proc IEEE Vol 88, No
4, April 2000 Davis Yen Pan, “Digital Audio Compression”, Digital Technical Journal, Vol 5, No 2, Spring 1993 Heiko Purnhagen, “Low Complexity Parametric Stereo Coding in MPEG-4”, Proc of 7 th Int Conference on
Digital Audio Effects, Naples Italy, Oct 5-8, 2004 TED PAINTER, ANDREAS SPANIAS, “A review of Algorithms for Perceptual Coding of Digital Audio
Signals”, Davis Pan, “A Tutorial on MPEG/ Audio Compression” Seymour Shlien, “Guide to MPEG-1 Audio Standard” ISO 11172-3, Information Technology- Coding of moving pictures and associated audio for digital storage
media Part-3 ISO 13818-3 ISO 14496-3 Jurgen Herre, “Temporal Noise Shaping, Quantization and Coding methods in Perceptual Audio Coding: A
Tutorial Introduction”, AES 17th International conference on high quality audio coding.
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Deleted Slides
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Filter Banks
Time-frequency analysis block Parallel bank of bandpass filters covering entire spectrum Divide signal spectrum into frequency sub-bands
Band-pass analysis output
Decimation by factor M
Critically sampled or maximally decimated
Upsampling in Decoder
Output is identical to input with delay
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Parametric Stereo Encoder Decoder
C= 10IID/20
α= arccos(ICC/2)