doc/06-floor0.tex - platform/external/libvorbis - Git at Google

 % -*- mode: latex; TeX-master: "Vorbis_I_spec"; -*-
 %!TEX root = Vorbis_I_spec.tex
 % $Id$
 \section{Floor type 0 setup and decode} \label{vorbis:spec:floor0}

 \subsection{Overview}

 Vorbis floor type zero uses Line Spectral Pair (LSP, also alternately
 known as Line Spectral Frequency or LSF) representation to encode a
 smooth spectral envelope curve as the frequency response of the LSP
 filter.  This representation is equivalent to a traditional all-pole
 infinite impulse response filter as would be used in linear predictive
 coding; LSP representation may be converted to LPC representation and
 vice-versa.


 \subsection{Floor 0 format}

 Floor zero configuration consists of six integer fields and a list of
 VQ codebooks for use in coding/decoding the LSP filter coefficient
 values used by each frame.

 \subsubsection{header decode}

 Configuration information for instances of floor zero decodes from the
 codec setup header (third packet).  configuration decode proceeds as
 follows:

 \begin{Verbatim}[commandchars=\\\{\}]
   1) [floor0_order] = read an unsigned integer of 8 bits
   2) [floor0_rate] = read an unsigned integer of 16 bits
   3) [floor0_bark_map_size] = read an unsigned integer of 16 bits
   4) [floor0_amplitude_bits] = read an unsigned integer of six bits
   5) [floor0_amplitude_offset] = read an unsigned integer of eight bits
   6) [floor0_number_of_books] = read an unsigned integer of four bits and add 1
   7) array [floor0_book_list] = read a list of [floor0_number_of_books] unsigned integers of eight bits each;
 \end{Verbatim}

 An end-of-packet condition during any of these bitstream reads renders
 this stream undecodable.  In addition, any element of the array
 \varname{[floor0_book_list]} that is greater than the maximum codebook
 number for this bitstream is an error condition that also renders the
 stream undecodable.


 \subsubsection{packet decode} \label{vorbis:spec:floor0-decode}

 Extracting a floor0 curve from an audio packet consists of first
 decoding the curve amplitude and \varname{[floor0_order]} LSP
 coefficient values from the bitstream, and then computing the floor
 curve, which is defined as the frequency response of the decoded LSP
 filter.

 Packet decode proceeds as follows:
 \begin{Verbatim}[commandchars=\\\{\}]
   1) [amplitude] = read an unsigned integer of [floor0_amplitude_bits] bits
   2) if ( [amplitude] is greater than zero ) \{
        3) [coefficients] is an empty, zero length vector
        4) [booknumber] = read an unsigned integer of \link{vorbis:spec:ilog}{ilog}( [floor0_number_of_books] ) bits
        5) if ( [booknumber] is greater than the highest number decode codebook ) then packet is undecodable
        6) [last] = zero;
        7) vector [temp_vector] = read vector from bitstream using codebook number [floor0_book_list] element [booknumber] in VQ context.
        8) add the scalar value [last] to each scalar in vector [temp_vector]
        9) [last] = the value of the last scalar in vector [temp_vector]
       10) concatenate [temp_vector] onto the end of the [coefficients] vector
       11) if (length of vector [coefficients] is less than [floor0_order], continue at step 6

      \}

  12) done.

 \end{Verbatim}

 Take note of the following properties of decode:
 \begin{itemize}
  \item An \varname{[amplitude]} value of zero must result in a return code that indicates this channel is unused in this frame (the output of the channel will be all-zeroes in synthesis).  Several later stages of decode don't occur for an unused channel.
  \item An end-of-packet condition during decode should be considered a
 nominal occruence; if end-of-packet is reached during any read
 operation above, floor decode is to return 'unused' status as if the
 \varname{[amplitude]} value had read zero at the beginning of decode.

  \item The book number used for decode
 can, in fact, be stored in the bitstream in \link{vorbis:spec:ilog}{ilog}( \varname{[floor0_number_of_books]} -
 1 ) bits.  Nevertheless, the above specification is correct and values
 greater than the maximum possible book value are reserved.

  \item The number of scalars read into the vector \varname{[coefficients]}
 may be greater than \varname{[floor0_order]}, the number actually
 required for curve computation.  For example, if the VQ codebook used
 for the floor currently being decoded has a
 \varname{[codebook_dimensions]} value of three and
 \varname{[floor0_order]} is ten, the only way to fill all the needed
 scalars in \varname{[coefficients]} is to to read a total of twelve
 scalars as four vectors of three scalars each.  This is not an error
 condition, and care must be taken not to allow a buffer overflow in
 decode. The extra values are not used and may be ignored or discarded.
 \end{itemize}


 \subsubsection{curve computation} \label{vorbis:spec:floor0-synth}

 Given an \varname{[amplitude]} integer and \varname{[coefficients]}
 vector from packet decode as well as the [floor0_order],
 [floor0_rate], [floor0_bark_map_size], [floor0_amplitude_bits] and
 [floor0_amplitude_offset] values from floor setup, and an output
 vector size \varname{[n]} specified by the decode process, we compute a
 floor output vector.

 If the value \varname{[amplitude]} is zero, the return value is a
 length \varname{[n]} vector with all-zero scalars.  Otherwise, begin by
 assuming the following definitions for the given vector to be
 synthesized:

    \begin{displaymath}
      \mathrm{map}_i = \left\{
        \begin{array}{ll}
           \min (
             \mathtt{floor0\_bark\_map\_size} - 1,
             foobar
           ) & \textrm{for } i \in [0,n-1] \\
           -1 & \textrm{for } i = n
         \end{array}
       \right.
     \end{displaymath}

     where

     \begin{displaymath}
     foobar =
       \left\lfloor
         \mathrm{bark}\left(\frac{\mathtt{floor0\_rate} \cdot i}{2n}\right) \cdot \frac{\mathtt{floor0\_bark\_map\_size}} {\mathrm{bark}(.5 \cdot \mathtt{floor0\_rate})}
       \right\rfloor
     \end{displaymath}

     and

     \begin{displaymath}
       \mathrm{bark}(x) = 13.1 \arctan (.00074x) + 2.24 \arctan (.0000000185x^2 + .0001x)
     \end{displaymath}

 The above is used to synthesize the LSP curve on a Bark-scale frequency
 axis, then map the result to a linear-scale frequency axis.
 Similarly, the below calculation synthesizes the output LSP curve \varname{[output]} on a log
 (dB) amplitude scale, mapping it to linear amplitude in the last step:

 \begin{enumerate}
  \item  \varname{[i]} = 0
  \item  \varname{[$\omega$]} = $\pi$ * map element \varname{[i]} / \varname{[floor0_bark_map_size]}
  \item if ( \varname{[floor0_order]} is odd ) {
   \begin{enumerate}
    \item calculate \varname{[p]} and \varname{[q]} according to:
            \begin{eqnarray*}
              p & = & (1 - \cos^2\omega)\prod_{j=0}^{\frac{\mathtt{floor0\_order}-3}{2}} 4 (\cos([\mathtt{coefficients}]_{2j+1}) - \cos \omega)^2 \\
              q & = & \frac{1}{4} \prod_{j=0}^{\frac{\mathtt{floor0\_order}-1}{2}} 4 (\cos([\mathtt{coefficients}]_{2j}) - \cos \omega)^2
            \end{eqnarray*}

   \end{enumerate}
   } else \varname{[floor0_order]} is even {
   \begin{enumerate}
    \item calculate \varname{[p]} and \varname{[q]} according to:
            \begin{eqnarray*}
              p & = & \frac{(1 - \cos^2\omega)}{2} \prod_{j=0}^{\frac{\mathtt{floor0\_order}-2}{2}} 4 (\cos([\mathtt{coefficients}]_{2j+1}) - \cos \omega)^2 \\
              q & = & \frac{(1 + \cos^2\omega)}{2} \prod_{j=0}^{\frac{\mathtt{floor0\_order}-2}{2}} 4 (\cos([\mathtt{coefficients}]_{2j}) - \cos \omega)^2
            \end{eqnarray*}

   \end{enumerate}
   }

  \item calculate \varname{[linear_floor_value]} according to:
          \begin{displaymath}
            \exp \left( .11512925 \left(\frac{\mathtt{amplitude} \cdot \mathtt{floor0\_amplitute\_offset}}{(2^{\mathtt{floor0\_amplitude\_bits}}-1)\sqrt{p+q}}
                   - \mathtt{floor0\_amplitude\_offset} \right) \right)
          \end{displaymath}

  \item \varname{[iteration_condition]} = map element \varname{[i]}
  \item \varname{[output]} element \varname{[i]} = \varname{[linear_floor_value]}
  \item increment \varname{[i]}
  \item if ( map element \varname{[i]} is equal to \varname{[iteration_condition]} ) continue at step 5
  \item if ( \varname{[i]} is less than \varname{[n]} ) continue at step 2
  \item done
 \end{enumerate}
	% -- mode: latex; TeX-master: "Vorbis_I_spec"; --
	%!TEX root = Vorbis_I_spec.tex
	% $Id$
	\section{Floor type 0 setup and decode} \label{vorbis:spec:floor0}

	\subsection{Overview}

	Vorbis floor type zero uses Line Spectral Pair (LSP, also alternately
	known as Line Spectral Frequency or LSF) representation to encode a
	smooth spectral envelope curve as the frequency response of the LSP
	filter. This representation is equivalent to a traditional all-pole
	infinite impulse response filter as would be used in linear predictive
	coding; LSP representation may be converted to LPC representation and
	vice-versa.



	\subsection{Floor 0 format}

	Floor zero configuration consists of six integer fields and a list of
	VQ codebooks for use in coding/decoding the LSP filter coefficient
	values used by each frame.

	\subsubsection{header decode}

	Configuration information for instances of floor zero decodes from the
	codec setup header (third packet). configuration decode proceeds as
	follows:

	\begin{Verbatim}[commandchars=\\\{\}]
	1) [floor0_order] = read an unsigned integer of 8 bits
	2) [floor0_rate] = read an unsigned integer of 16 bits
	3) [floor0_bark_map_size] = read an unsigned integer of 16 bits
	4) [floor0_amplitude_bits] = read an unsigned integer of six bits
	5) [floor0_amplitude_offset] = read an unsigned integer of eight bits
	6) [floor0_number_of_books] = read an unsigned integer of four bits and add 1
	7) array [floor0_book_list] = read a list of [floor0_number_of_books] unsigned integers of eight bits each;
	\end{Verbatim}

	An end-of-packet condition during any of these bitstream reads renders
	this stream undecodable. In addition, any element of the array
	\varname{[floor0_book_list]} that is greater than the maximum codebook
	number for this bitstream is an error condition that also renders the
	stream undecodable.



	\subsubsection{packet decode} \label{vorbis:spec:floor0-decode}

	Extracting a floor0 curve from an audio packet consists of first
	decoding the curve amplitude and \varname{[floor0_order]} LSP
	coefficient values from the bitstream, and then computing the floor
	curve, which is defined as the frequency response of the decoded LSP
	filter.

	Packet decode proceeds as follows:
	\begin{Verbatim}[commandchars=\\\{\}]
	1) [amplitude] = read an unsigned integer of [floor0_amplitude_bits] bits
	2) if ( [amplitude] is greater than zero ) \{
	3) [coefficients] is an empty, zero length vector
	4) [booknumber] = read an unsigned integer of \link{vorbis:spec:ilog}{ilog}( [floor0_number_of_books] ) bits
	5) if ( [booknumber] is greater than the highest number decode codebook ) then packet is undecodable
	6) [last] = zero;
	7) vector [temp_vector] = read vector from bitstream using codebook number [floor0_book_list] element [booknumber] in VQ context.
	8) add the scalar value [last] to each scalar in vector [temp_vector]
	9) [last] = the value of the last scalar in vector [temp_vector]
	10) concatenate [temp_vector] onto the end of the [coefficients] vector
	11) if (length of vector [coefficients] is less than [floor0_order], continue at step 6

	\}

	12) done.

	\end{Verbatim}

	Take note of the following properties of decode:
	\begin{itemize}
	\item An \varname{[amplitude]} value of zero must result in a return code that indicates this channel is unused in this frame (the output of the channel will be all-zeroes in synthesis). Several later stages of decode don't occur for an unused channel.
	\item An end-of-packet condition during decode should be considered a
	nominal occruence; if end-of-packet is reached during any read
	operation above, floor decode is to return 'unused' status as if the
	\varname{[amplitude]} value had read zero at the beginning of decode.

	\item The book number used for decode
	can, in fact, be stored in the bitstream in \link{vorbis:spec:ilog}{ilog}( \varname{[floor0_number_of_books]} -
	1 ) bits. Nevertheless, the above specification is correct and values
	greater than the maximum possible book value are reserved.

	\item The number of scalars read into the vector \varname{[coefficients]}
	may be greater than \varname{[floor0_order]}, the number actually
	required for curve computation. For example, if the VQ codebook used
	for the floor currently being decoded has a
	\varname{[codebook_dimensions]} value of three and
	\varname{[floor0_order]} is ten, the only way to fill all the needed
	scalars in \varname{[coefficients]} is to to read a total of twelve
	scalars as four vectors of three scalars each. This is not an error
	condition, and care must be taken not to allow a buffer overflow in
	decode. The extra values are not used and may be ignored or discarded.
	\end{itemize}




	\subsubsection{curve computation} \label{vorbis:spec:floor0-synth}

	Given an \varname{[amplitude]} integer and \varname{[coefficients]}
	vector from packet decode as well as the [floor0_order],
	[floor0_rate], [floor0_bark_map_size], [floor0_amplitude_bits] and
	[floor0_amplitude_offset] values from floor setup, and an output
	vector size \varname{[n]} specified by the decode process, we compute a
	floor output vector.

	If the value \varname{[amplitude]} is zero, the return value is a
	length \varname{[n]} vector with all-zero scalars. Otherwise, begin by
	assuming the following definitions for the given vector to be
	synthesized:

	\begin{displaymath}
	\mathrm{map}_i = \left\{
	\begin{array}{ll}
	\min (
	\mathtt{floor0\_bark\_map\_size} - 1,
	foobar
	) & \textrm{for } i \in [0,n-1] \\
	-1 & \textrm{for } i = n
	\end{array}
	\right.
	\end{displaymath}

	where

	\begin{displaymath}
	foobar =
	\left\lfloor
	\mathrm{bark}\left(\frac{\mathtt{floor0\_rate} \cdot i}{2n}\right) \cdot \frac{\mathtt{floor0\_bark\_map\_size}} {\mathrm{bark}(.5 \cdot \mathtt{floor0\_rate})}
	\right\rfloor
	\end{displaymath}

	and

	\begin{displaymath}
	\mathrm{bark}(x) = 13.1 \arctan (.00074x) + 2.24 \arctan (.0000000185x^2 + .0001x)
	\end{displaymath}

	The above is used to synthesize the LSP curve on a Bark-scale frequency
	axis, then map the result to a linear-scale frequency axis.
	Similarly, the below calculation synthesizes the output LSP curve \varname{[output]} on a log
	(dB) amplitude scale, mapping it to linear amplitude in the last step:

	\begin{enumerate}
	\item \varname{[i]} = 0
	\item \varname{[$\omega$]} = $\pi$ * map element \varname{[i]} / \varname{[floor0_bark_map_size]}
	\item if ( \varname{[floor0_order]} is odd ) {
	\begin{enumerate}
	\item calculate \varname{[p]} and \varname{[q]} according to:
	\begin{eqnarray*}
	p & = & (1 - \cos^2\omega)\prod_{j=0}^{\frac{\mathtt{floor0\_order}-3}{2}} 4 (\cos([\mathtt{coefficients}]_{2j+1}) - \cos \omega)^2 \\
	q & = & \frac{1}{4} \prod_{j=0}^{\frac{\mathtt{floor0\_order}-1}{2}} 4 (\cos([\mathtt{coefficients}]_{2j}) - \cos \omega)^2
	\end{eqnarray*}

	\end{enumerate}
	} else \varname{[floor0_order]} is even {
	\begin{enumerate}
	\item calculate \varname{[p]} and \varname{[q]} according to:
	\begin{eqnarray*}
	p & = & \frac{(1 - \cos^2\omega)}{2} \prod_{j=0}^{\frac{\mathtt{floor0\_order}-2}{2}} 4 (\cos([\mathtt{coefficients}]_{2j+1}) - \cos \omega)^2 \\
	q & = & \frac{(1 + \cos^2\omega)}{2} \prod_{j=0}^{\frac{\mathtt{floor0\_order}-2}{2}} 4 (\cos([\mathtt{coefficients}]_{2j}) - \cos \omega)^2
	\end{eqnarray*}

	\end{enumerate}
	}

	\item calculate \varname{[linear_floor_value]} according to:
	\begin{displaymath}
	\exp \left( .11512925 \left(\frac{\mathtt{amplitude} \cdot \mathtt{floor0\_amplitute\_offset}}{(2^{\mathtt{floor0\_amplitude\_bits}}-1)\sqrt{p+q}}
	- \mathtt{floor0\_amplitude\_offset} \right) \right)
	\end{displaymath}

	\item \varname{[iteration_condition]} = map element \varname{[i]}
	\item \varname{[output]} element \varname{[i]} = \varname{[linear_floor_value]}
	\item increment \varname{[i]}
	\item if ( map element \varname{[i]} is equal to \varname{[iteration_condition]} ) continue at step 5
	\item if ( \varname{[i]} is less than \varname{[n]} ) continue at step 2
	\item done
	\end{enumerate}