cip2012: draft.tex annotate

annotate draft.tex @ 56:fa819cf73ea7

Improved introduction, removed 1st para after section indent.

author	samer
date	Fri, 16 Mar 2012 18:05:17 +0000
parents	2f783c4c3562
children	ceec4e8b6585

rev	line source
samer@41	1 \documentclass[conference]{IEEEtran}
samer@4	2 \usepackage{cite}
samer@4	3 \usepackage[cmex10]{amsmath}
samer@4	4 \usepackage{graphicx}
samer@4	5 \usepackage{amssymb}
samer@4	6 \usepackage{epstopdf}
samer@4	7 \usepackage{url}
samer@4	8 \usepackage{listings}
samer@18	9 %\usepackage[expectangle]{tools}
samer@9	10 \usepackage{tools}
samer@18	11 \usepackage{tikz}
samer@18	12 \usetikzlibrary{calc}
samer@18	13 \usetikzlibrary{matrix}
samer@18	14 \usetikzlibrary{patterns}
samer@18	15 \usetikzlibrary{arrows}
samer@9	16
samer@9	17 \let\citep=\cite
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samer@18	26 \newcommand\sps{\,.\,}
samer@18	27 \newcommand\Ipred{\mathcal{I}_{\mathrm{pred}}}
samer@18	28 \newcommand\Ix{\mathcal{I}}
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samer@18	30 \newcommand\x{\vec{x}}
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samer@18	33 \def\bet(#1,#2){#1..#2}
samer@18	34
samer@18	35
samer@18	36 \def\ev(#1=#2){#1\!\!=\!#2}
samer@18	37 \newcommand\rv[1]{\Omega \to #1}
samer@18	38 \newcommand\ceq{\!\!=\!}
samer@18	39 \newcommand\cmin{\!-\!}
samer@18	40 \newcommand\modulo[2]{#1\!\!\!\!\!\mod#2}
samer@18	41
samer@18	42 \newcommand\sumitoN{\sum_{i=1}^N}
samer@18	43 \newcommand\sumktoK{\sum_{k=1}^K}
samer@18	44 \newcommand\sumjtoK{\sum_{j=1}^K}
samer@18	45 \newcommand\sumalpha{\sum_{\alpha\in\A}}
samer@18	46 \newcommand\prodktoK{\prod_{k=1}^K}
samer@18	47 \newcommand\prodjtoK{\prod_{j=1}^K}
samer@18	48
samer@18	49 \newcommand\past[1]{\overset{\rule{0pt}{0.2em}\smash{\leftarrow}}{#1}}
samer@18	50 \newcommand\fut[1]{\overset{\rule{0pt}{0.1em}\smash{\rightarrow}}{#1}}
samer@18	51 \newcommand\parity[2]{P^{#1}_{2,#2}}
samer@4	52
samer@4	53 %\usepackage[parfill]{parskip}
samer@4	54
samer@4	55 \begin{document}
samer@41	56 \title{Cognitive Music Modelling: an\\Information Dynamics Approach}
samer@4	57
samer@4	58 \author{
hekeus@16	59 \IEEEauthorblockN{Samer A. Abdallah, Henrik Ekeus, Peter Foster}
hekeus@16	60 \IEEEauthorblockN{Andrew Robertson and Mark D. Plumbley}
samer@4	61 \IEEEauthorblockA{Centre for Digital Music\\
samer@4	62 Queen Mary University of London\\
samer@41	63 Mile End Road, London E1 4NS}}
samer@4	64
samer@4	65 \maketitle
samer@18	66 \begin{abstract}
samer@18	67 People take in information when perceiving music. With it they continually
samer@18	68 build predictive models of what is going to happen. There is a relationship
samer@18	69 between information measures and how we perceive music. An information
samer@18	70 theoretic approach to music cognition is thus a fruitful avenue of research.
samer@18	71 In this paper, we review the theoretical foundations of information dynamics
samer@18	72 and discuss a few emerging areas of application.
hekeus@16	73 \end{abstract}
samer@4	74
samer@4	75
samer@25	76 \section{Introduction}
samer@9	77 \label{s:Intro}
samer@56	78 The relationship between
samer@56	79 Shannon's \cite{Shannon48} information theory and music and art in general has been the
samer@56	80 subject of some interest since the 1950s
samer@56	81 \cite{Youngblood58,CoonsKraehenbuehl1958,HillerBean66,Moles66,Meyer67,Cohen1962}.
samer@56	82 The general thesis is that perceptible qualities and subjective states
samer@56	83 like uncertainty, surprise, complexity, tension, and interestingness
samer@56	84 are closely related to information-theoretic quantities like
samer@56	85 entropy, relative entropy, and mutual information.
samer@56	86
samer@56	87 Music is also an inherently dynamic process,
samer@56	88 where listeners build up expectations on what is to happen next,
samer@56	89 which are either satisfied or modified as the music unfolds.
samer@56	90 In this paper, we explore this ``Information Dynamics'' view of music,
samer@56	91 discussing the theory behind it and some emerging appliations
samer@9	92
samer@25	93 \subsection{Expectation and surprise in music}
samer@18	94 One of the effects of listening to music is to create
samer@18	95 expectations of what is to come next, which may be fulfilled
samer@9	96 immediately, after some delay, or not at all as the case may be.
samer@9	97 This is the thesis put forward by, amongst others, music theorists
samer@18	98 L. B. Meyer \cite{Meyer67} and Narmour \citep{Narmour77}, but was
samer@18	99 recognised much earlier; for example,
samer@9	100 it was elegantly put by Hanslick \cite{Hanslick1854} in the
samer@9	101 nineteenth century:
samer@9	102 \begin{quote}
samer@9	103 `The most important factor in the mental process which accompanies the
samer@9	104 act of listening to music, and which converts it to a source of pleasure,
samer@18	105 is \ldots the intellectual satisfaction
samer@9	106 which the listener derives from continually following and anticipating
samer@9	107 the composer's intentions---now, to see his expectations fulfilled, and
samer@18	108 now, to find himself agreeably mistaken.
samer@18	109 %It is a matter of course that
samer@18	110 %this intellectual flux and reflux, this perpetual giving and receiving
samer@18	111 %takes place unconsciously, and with the rapidity of lightning-flashes.'
samer@9	112 \end{quote}
samer@9	113 An essential aspect of this is that music is experienced as a phenomenon
samer@9	114 that `unfolds' in time, rather than being apprehended as a static object
samer@9	115 presented in its entirety. Meyer argued that musical experience depends
samer@9	116 on how we change and revise our conceptions \emph{as events happen}, on
samer@9	117 how expectation and prediction interact with occurrence, and that, to a
samer@9	118 large degree, the way to understand the effect of music is to focus on
samer@9	119 this `kinetics' of expectation and surprise.
samer@9	120
samer@25	121 Prediction and expectation are essentially probabilistic concepts
samer@25	122 and can be treated mathematically using probability theory.
samer@25	123 We suppose that when we listen to music, expectations are created on the basis
samer@25	124 of our familiarity with various styles of music and our ability to
samer@25	125 detect and learn statistical regularities in the music as they emerge,
samer@25	126 There is experimental evidence that human listeners are able to internalise
samer@25	127 statistical knowledge about musical structure, \eg
samer@25	128 \citep{SaffranJohnsonAslin1999,EerolaToiviainenKrumhansl2002}, and also
samer@25	129 that statistical models can form an effective basis for computational
samer@25	130 analysis of music, \eg
samer@25	131 \cite{ConklinWitten95,PonsfordWigginsMellish1999,Pearce2005}.
samer@25	132
samer@25	133
samer@25	134 \comment{
samer@9	135 The business of making predictions and assessing surprise is essentially
samer@9	136 one of reasoning under conditions of uncertainty and manipulating
samer@9	137 degrees of belief about the various proposition which may or may not
samer@9	138 hold, and, as has been argued elsewhere \cite{Cox1946,Jaynes27}, best
samer@9	139 quantified in terms of Bayesian probability theory.
samer@9	140 Thus, we suppose that
samer@9	141 when we listen to music, expectations are created on the basis of our
samer@24	142 familiarity with various stylistic norms that apply to music in general,
samer@24	143 the particular style (or styles) of music that seem best to fit the piece
samer@24	144 we are listening to, and
samer@9	145 the emerging structures peculiar to the current piece. There is
samer@9	146 experimental evidence that human listeners are able to internalise
samer@9	147 statistical knowledge about musical structure, \eg
samer@9	148 \citep{SaffranJohnsonAslin1999,EerolaToiviainenKrumhansl2002}, and also
samer@9	149 that statistical models can form an effective basis for computational
samer@9	150 analysis of music, \eg
samer@9	151 \cite{ConklinWitten95,PonsfordWigginsMellish1999,Pearce2005}.
samer@25	152 }
samer@9	153
samer@56	154 % \subsection{Music and information theory}
samer@24	155 With a probabilistic framework for music modelling and prediction in hand,
samer@56	156 we are in a position to compute various
samer@25	157 \comment{
samer@25	158 which provides us with a number of measures, such as entropy
samer@25	159 and mutual information, which are suitable for quantifying states of
samer@25	160 uncertainty and surprise, and thus could potentially enable us to build
samer@25	161 quantitative models of the listening process described above. They are
samer@25	162 what Berlyne \cite{Berlyne71} called `collative variables' since they are
samer@25	163 to do with patterns of occurrence rather than medium-specific details.
samer@25	164 Berlyne sought to show that the collative variables are closely related to
samer@25	165 perceptual qualities like complexity, tension, interestingness,
samer@25	166 and even aesthetic value, not just in music, but in other temporal
samer@25	167 or visual media.
samer@25	168 The relevance of information theory to music and art has
samer@25	169 also been addressed by researchers from the 1950s onwards
samer@25	170 \cite{Youngblood58,CoonsKraehenbuehl1958,Cohen1962,HillerBean66,Moles66,Meyer67}.
samer@25	171 }
samer@9	172 information-theoretic quantities like entropy, relative entropy,
samer@9	173 and mutual information.
samer@9	174 % and are major determinants of the overall experience.
samer@9	175 Berlyne \cite{Berlyne71} called such quantities `collative variables', since
samer@9	176 they are to do with patterns of occurrence rather than medium-specific details,
samer@9	177 and developed the ideas of `information aesthetics' in an experimental setting.
samer@9	178 % Berlyne's `new experimental aesthetics', the `information-aestheticians'.
samer@9	179
samer@9	180 % Listeners then experience greater or lesser levels of surprise
samer@9	181 % in response to departures from these norms.
samer@9	182 % By careful manipulation
samer@9	183 % of the material, the composer can thus define, and induce within the
samer@9	184 % listener, a temporal programme of varying
samer@9	185 % levels of uncertainty, ambiguity and surprise.
samer@9	186
samer@9	187
samer@9	188 \subsection{Information dynamic approach}
samer@24	189 Bringing the various strands together, our working hypothesis is that as a
samer@24	190 listener (to which will refer as `it') listens to a piece of music, it maintains
samer@25	191 a dynamically evolving probabilistic model that enables it to make predictions
samer@24	192 about how the piece will continue, relying on both its previous experience
samer@24	193 of music and the immediate context of the piece. As events unfold, it revises
samer@25	194 its probabilistic belief state, which includes predictive
samer@25	195 distributions over possible future events. These
samer@25	196 % distributions and changes in distributions
samer@25	197 can be characterised in terms of a handful of information
samer@25	198 theoretic-measures such as entropy and relative entropy. By tracing the
samer@24	199 evolution of a these measures, we obtain a representation which captures much
samer@25	200 of the significant structure of the music.
samer@25	201
samer@25	202 One of the consequences of this approach is that regardless of the details of
samer@25	203 the sensory input or even which sensory modality is being processed, the resulting
samer@25	204 analysis is in terms of the same units: quantities of information (bits) and
samer@25	205 rates of information flow (bits per second). The probabilistic and information
samer@25	206 theoretic concepts in terms of which the analysis is framed are universal to all sorts
samer@25	207 of data.
samer@25	208 In addition, when adaptive probabilistic models are used, expectations are
samer@25	209 created mainly in response to to \emph{patterns} of occurence,
samer@25	210 rather the details of which specific things occur.
samer@25	211 Together, these suggest that an information dynamic analysis captures a
samer@25	212 high level of \emph{abstraction}, and could be used to
samer@25	213 make structural comparisons between different temporal media,
samer@25	214 such as music, film, animation, and dance.
samer@25	215 % analyse and compare information
samer@25	216 % flow in different temporal media regardless of whether they are auditory,
samer@25	217 % visual or otherwise.
samer@9	218
samer@25	219 Another consequence is that the information dynamic approach gives us a principled way
samer@24	220 to address the notion of \emph{subjectivity}, since the analysis is dependent on the
samer@24	221 probability model the observer starts off with, which may depend on prior experience
samer@24	222 or other factors, and which may change over time. Thus, inter-subject variablity and
samer@24	223 variation in subjects' responses over time are
samer@24	224 fundamental to the theory.
samer@9	225
samer@18	226 %modelling the creative process, which often alternates between generative
samer@18	227 %and selective or evaluative phases \cite{Boden1990}, and would have
samer@18	228 %applications in tools for computer aided composition.
samer@18	229
samer@18	230
samer@18	231 \section{Theoretical review}
samer@18	232
samer@34	233 \subsection{Entropy and information}
samer@41	234 \label{s:entro-info}
samer@41	235
samer@34	236 Let $X$ denote some variable whose value is initially unknown to our
samer@34	237 hypothetical observer. We will treat $X$ mathematically as a random variable,
samer@36	238 with a value to be drawn from some set $\X$ and a
samer@34	239 probability distribution representing the observer's beliefs about the
samer@34	240 true value of $X$.
samer@34	241 In this case, the observer's uncertainty about $X$ can be quantified
samer@34	242 as the entropy of the random variable $H(X)$. For a discrete variable
samer@36	243 with probability mass function $p:\X \to [0,1]$, this is
samer@34	244 \begin{equation}
samer@41	245 H(X) = \sum_{x\in\X} -p(x) \log p(x), % = \expect{-\log p(X)},
samer@34	246 \end{equation}
samer@41	247 % where $\expect{}$ is the expectation operator.
samer@41	248 The negative-log-probability
samer@34	249 $\ell(x) = -\log p(x)$ of a particular value $x$ can usefully be thought of as
samer@34	250 the \emph{surprisingness} of the value $x$ should it be observed, and
samer@41	251 hence the entropy is the expectation of the surprisingness $\expect \ell(X)$.
samer@34	252
samer@34	253 Now suppose that the observer receives some new data $\Data$ that
samer@34	254 causes a revision of its beliefs about $X$. The \emph{information}
samer@34	255 in this new data \emph{about} $X$ can be quantified as the
samer@34	256 Kullback-Leibler (KL) divergence between the prior and posterior
samer@34	257 distributions $p(x)$ and $p(x\|\Data)$ respectively:
samer@34	258 \begin{equation}
samer@34	259 \mathcal{I}_{\Data\to X} = D(p_{X\|\Data} \|\| p_{X})
samer@36	260 = \sum_{x\in\X} p(x\|\Data) \log \frac{p(x\|\Data)}{p(x)}.
samer@41	261 \label{eq:info}
samer@34	262 \end{equation}
samer@34	263 When there are multiple variables $X_1, X_2$
samer@34	264 \etc which the observer believes to be dependent, then the observation of
samer@34	265 one may change its beliefs and hence yield information about the
samer@34	266 others. The joint and conditional entropies as described in any
samer@34	267 textbook on information theory (\eg \cite{CoverThomas}) then quantify
samer@34	268 the observer's expected uncertainty about groups of variables given the
samer@34	269 values of others. In particular, the \emph{mutual information}
samer@34	270 $I(X_1;X_2)$ is both the expected information
samer@34	271 in an observation of $X_2$ about $X_1$ and the expected reduction
samer@34	272 in uncertainty about $X_1$ after observing $X_2$:
samer@34	273 \begin{equation}
samer@34	274 I(X_1;X_2) = H(X_1) - H(X_1\|X_2),
samer@34	275 \end{equation}
samer@34	276 where $H(X_1\|X_2) = H(X_1,X_2) - H(X_2)$ is the conditional entropy
samer@34	277 of $X_2$ given $X_1$. A little algebra shows that $I(X_1;X_2)=I(X_2;X_1)$
samer@34	278 and so the mutual information is symmetric in its arguments. A conditional
samer@34	279 form of the mutual information can be formulated analogously:
samer@34	280 \begin{equation}
samer@34	281 I(X_1;X_2\|X_3) = H(X_1\|X_3) - H(X_1\|X_2,X_3).
samer@34	282 \end{equation}
samer@34	283 These relationships between the various entropies and mutual
samer@34	284 informations are conveniently visualised in Venn diagram-like \emph{information diagrams}
samer@34	285 or I-diagrams \cite{Yeung1991} such as the one in \figrf{venn-example}.
samer@34	286
samer@18	287 \begin{fig}{venn-example}
samer@18	288 \newcommand\rad{2.2em}%
samer@18	289 \newcommand\circo{circle (3.4em)}%
samer@18	290 \newcommand\labrad{4.3em}
samer@18	291 \newcommand\bound{(-6em,-5em) rectangle (6em,6em)}
samer@18	292 \newcommand\colsep{\ }
samer@18	293 \newcommand\clipin[1]{\clip (#1) \circo;}%
samer@18	294 \newcommand\clipout[1]{\clip \bound (#1) \circo;}%
samer@18	295 \newcommand\cliptwo[3]{%
samer@18	296 \begin{scope}
samer@18	297 \clipin{#1};
samer@18	298 \clipin{#2};
samer@18	299 \clipout{#3};
samer@18	300 \fill[black!30] \bound;
samer@18	301 \end{scope}
samer@18	302 }%
samer@18	303 \newcommand\clipone[3]{%
samer@18	304 \begin{scope}
samer@18	305 \clipin{#1};
samer@18	306 \clipout{#2};
samer@18	307 \clipout{#3};
samer@18	308 \fill[black!15] \bound;
samer@18	309 \end{scope}
samer@18	310 }%
samer@18	311 \begin{tabular}{c@{\colsep}c}
samer@18	312 \begin{tikzpicture}[baseline=0pt]
samer@18	313 \coordinate (p1) at (90:\rad);
samer@18	314 \coordinate (p2) at (210:\rad);
samer@18	315 \coordinate (p3) at (-30:\rad);
samer@18	316 \clipone{p1}{p2}{p3};
samer@18	317 \clipone{p2}{p3}{p1};
samer@18	318 \clipone{p3}{p1}{p2};
samer@18	319 \cliptwo{p1}{p2}{p3};
samer@18	320 \cliptwo{p2}{p3}{p1};
samer@18	321 \cliptwo{p3}{p1}{p2};
samer@18	322 \begin{scope}
samer@18	323 \clip (p1) \circo;
samer@18	324 \clip (p2) \circo;
samer@18	325 \clip (p3) \circo;
samer@18	326 \fill[black!45] \bound;
samer@18	327 \end{scope}
samer@18	328 \draw (p1) \circo;
samer@18	329 \draw (p2) \circo;
samer@18	330 \draw (p3) \circo;
samer@18	331 \path
samer@18	332 (barycentric cs:p3=1,p1=-0.2,p2=-0.1) +(0ex,0) node {$I_{3\|12}$}
samer@18	333 (barycentric cs:p1=1,p2=-0.2,p3=-0.1) +(0ex,0) node {$I_{1\|23}$}
samer@18	334 (barycentric cs:p2=1,p3=-0.2,p1=-0.1) +(0ex,0) node {$I_{2\|13}$}
samer@18	335 (barycentric cs:p3=1,p2=1,p1=-0.55) +(0ex,0) node {$I_{23\|1}$}
samer@18	336 (barycentric cs:p1=1,p3=1,p2=-0.55) +(0ex,0) node {$I_{13\|2}$}
samer@18	337 (barycentric cs:p2=1,p1=1,p3=-0.55) +(0ex,0) node {$I_{12\|3}$}
samer@18	338 (barycentric cs:p3=1,p2=1,p1=1) node {$I_{123}$}
samer@18	339 ;
samer@18	340 \path
samer@18	341 (p1) +(140:\labrad) node {$X_1$}
samer@18	342 (p2) +(-140:\labrad) node {$X_2$}
samer@18	343 (p3) +(-40:\labrad) node {$X_3$};
samer@18	344 \end{tikzpicture}
samer@18	345 &
samer@18	346 \parbox{0.5\linewidth}{
samer@18	347 \small
samer@18	348 \begin{align*}
samer@18	349 I_{1\|23} &= H(X_1\|X_2,X_3) \\
samer@18	350 I_{13\|2} &= I(X_1;X_3\|X_2) \\
samer@18	351 I_{1\|23} + I_{13\|2} &= H(X_1\|X_2) \\
samer@18	352 I_{12\|3} + I_{123} &= I(X_1;X_2)
samer@18	353 \end{align*}
samer@18	354 }
samer@18	355 \end{tabular}
samer@18	356 \caption{
samer@30	357 I-diagram visualisation of entropies and mutual informations
samer@18	358 for three random variables $X_1$, $X_2$ and $X_3$. The areas of
samer@18	359 the three circles represent $H(X_1)$, $H(X_2)$ and $H(X_3)$ respectively.
samer@18	360 The total shaded area is the joint entropy $H(X_1,X_2,X_3)$.
samer@18	361 The central area $I_{123}$ is the co-information \cite{McGill1954}.
samer@18	362 Some other information measures are indicated in the legend.
samer@18	363 }
samer@18	364 \end{fig}
samer@30	365
samer@30	366
samer@36	367 \subsection{Surprise and information in sequences}
samer@36	368 \label{s:surprise-info-seq}
samer@30	369
samer@36	370 Suppose that $(\ldots,X_{-1},X_0,X_1,\ldots)$ is a sequence of
samer@30	371 random variables, infinite in both directions,
samer@36	372 and that $\mu$ is the associated probability measure over all
samer@36	373 realisations of the sequence---in the following, $\mu$ will simply serve
samer@30	374 as a label for the process. We can indentify a number of information-theoretic
samer@30	375 measures meaningful in the context of a sequential observation of the sequence, during
samer@36	376 which, at any time $t$, the sequence of variables can be divided into a `present' $X_t$, a `past'
samer@30	377 $\past{X}_t \equiv (\ldots, X_{t-2}, X_{t-1})$, and a `future'
samer@30	378 $\fut{X}_t \equiv (X_{t+1},X_{t+2},\ldots)$.
samer@41	379 We will write the actually observed value of $X_t$ as $x_t$, and
samer@36	380 the sequence of observations up to but not including $x_t$ as
samer@36	381 $\past{x}_t$.
samer@36	382 % Since the sequence is assumed stationary, we can without loss of generality,
samer@36	383 % assume that $t=0$ in the following definitions.
samer@36	384
samer@41	385 The in-context surprisingness of the observation $X_t=x_t$ depends on
samer@41	386 both $x_t$ and the context $\past{x}_t$:
samer@36	387 \begin{equation}
samer@41	388 \ell_t = - \log p(x_t\|\past{x}_t).
samer@36	389 \end{equation}
samer@36	390 However, before $X_t$ is observed to be $x_t$, the observer can compute
samer@46	391 the \emph{expected} surprisingness as a measure of its uncertainty about
samer@36	392 the very next event; this may be written as an entropy
samer@36	393 $H(X_t\|\ev(\past{X}_t = \past{x}_t))$, but note that this is
samer@36	394 conditional on the \emph{event} $\ev(\past{X}_t=\past{x}_t)$, not
samer@36	395 \emph{variables} $\past{X}_t$ as in the conventional conditional entropy.
samer@36	396
samer@41	397 The surprisingness $\ell_t$ and expected surprisingness
samer@36	398 $H(X_t\|\ev(\past{X}_t=\past{x}_t))$
samer@41	399 can be understood as \emph{subjective} information dynamic measures, since they are
samer@41	400 based on the observer's probability model in the context of the actually observed sequence
samer@36	401 $\past{x}_t$---they characterise what it is like to `be in the observer's shoes'.
samer@36	402 If we view the observer as a purely passive or reactive agent, this would
samer@36	403 probably be sufficient, but for active agents such as humans or animals, it is
samer@36	404 often necessary to \emph{aniticipate} future events in order, for example, to plan the
samer@36	405 most effective course of action. It makes sense for such observers to be
samer@36	406 concerned about the predictive probability distribution over future events,
samer@36	407 $p(\fut{x}_t\|\past{x}_t)$. When an observation $\ev(X_t=x_t)$ is made in this context,
samer@41	408 the \emph{instantaneous predictive information} (IPI) $\mathcal{I}_t$ at time $t$
samer@41	409 is the information in the event $\ev(X_t=x_t)$ about the entire future of the sequence $\fut{X}_t$,
samer@41	410 \emph{given} the observed past $\past{X}_t=\past{x}_t$.
samer@41	411 Referring to the definition of information \eqrf{info}, this is the KL divergence
samer@41	412 between prior and posterior distributions over possible futures, which written out in full, is
samer@41	413 \begin{equation}
samer@41	414 \mathcal{I}_t = \sum_{\fut{x}_t \in \X^*}
samer@41	415 p(\fut{x}_t\|x_t,\past{x}_t) \log \frac{ p(\fut{x}_t\|x_t,\past{x}_t) }{ p(\fut{x}_t\|\past{x}_t) },
samer@41	416 \end{equation}
samer@41	417 where the sum is to be taken over the set of infinite sequences $\X^*$.
samer@46	418 Note that it is quite possible for an event to be surprising but not informative
samer@46	419 in predictive sense.
samer@41	420 As with the surprisingness, the observer can compute its \emph{expected} IPI
samer@41	421 at time $t$, which reduces to a mutual information $I(X_t;\fut{X}_t\|\ev(\past{X}_t=\past{x}_t))$
samer@41	422 conditioned on the observed past. This could be used, for example, as an estimate
samer@41	423 of attentional resources which should be directed at this stream of data, which may
samer@41	424 be in competition with other sensory streams.
samer@36	425
samer@36	426 \subsection{Information measures for stationary random processes}
samer@43	427 \label{s:process-info}
samer@30	428
samer@18	429
samer@18	430 \begin{fig}{predinfo-bg}
samer@18	431 \newcommand\subfig[2]{\shortstack{#2\\[0.75em]#1}}
samer@18	432 \newcommand\rad{1.8em}%
samer@18	433 \newcommand\ovoid[1]{%
samer@18	434 ++(-#1,\rad)
samer@18	435 -- ++(2 * #1,0em) arc (90:-90:\rad)
samer@18	436 -- ++(-2 * #1,0em) arc (270:90:\rad)
samer@18	437 }%
samer@18	438 \newcommand\axis{2.75em}%
samer@18	439 \newcommand\olap{0.85em}%
samer@18	440 \newcommand\offs{3.6em}
samer@18	441 \newcommand\colsep{\hspace{5em}}
samer@18	442 \newcommand\longblob{\ovoid{\axis}}
samer@18	443 \newcommand\shortblob{\ovoid{1.75em}}
samer@56	444 \begin{tabular}{c}
samer@43	445 \subfig{(a) multi-information and entropy rates}{%
samer@43	446 \begin{tikzpicture}%[baseline=-1em]
samer@43	447 \newcommand\rc{1.75em}
samer@43	448 \newcommand\throw{2.5em}
samer@43	449 \coordinate (p1) at (180:1.5em);
samer@43	450 \coordinate (p2) at (0:0.3em);
samer@43	451 \newcommand\bound{(-7em,-2.6em) rectangle (7em,3.0em)}
samer@43	452 \newcommand\present{(p2) circle (\rc)}
samer@43	453 \newcommand\thepast{(p1) ++(-\throw,0) \ovoid{\throw}}
samer@43	454 \newcommand\fillclipped[2]{%
samer@43	455 \begin{scope}[even odd rule]
samer@43	456 \foreach \thing in {#2} {\clip \thing;}
samer@43	457 \fill[black!#1] \bound;
samer@43	458 \end{scope}%
samer@43	459 }%
samer@43	460 \fillclipped{30}{\present,\bound \thepast}
samer@43	461 \fillclipped{15}{\present,\bound \thepast}
samer@43	462 \fillclipped{45}{\present,\thepast}
samer@43	463 \draw \thepast;
samer@43	464 \draw \present;
samer@43	465 \node at (barycentric cs:p2=1,p1=-0.3) {$h_\mu$};
samer@43	466 \node at (barycentric cs:p2=1,p1=1) [shape=rectangle,fill=black!45,inner sep=1pt]{$\rho_\mu$};
samer@43	467 \path (p2) +(90:3em) node {$X_0$};
samer@43	468 \path (p1) +(-3em,0em) node {\shortstack{infinite\\past}};
samer@43	469 \path (p1) +(-4em,\rad) node [anchor=south] {$\ldots,X_{-1}$};
samer@43	470 \end{tikzpicture}}%
samer@43	471 \\[1.25em]
samer@43	472 \subfig{(b) excess entropy}{%
samer@18	473 \newcommand\blob{\longblob}
samer@18	474 \begin{tikzpicture}
samer@18	475 \coordinate (p1) at (-\offs,0em);
samer@18	476 \coordinate (p2) at (\offs,0em);
samer@18	477 \begin{scope}
samer@18	478 \clip (p1) \blob;
samer@18	479 \clip (p2) \blob;
samer@18	480 \fill[lightgray] (-1,-1) rectangle (1,1);
samer@18	481 \end{scope}
samer@18	482 \draw (p1) +(-0.5em,0em) node{\shortstack{infinite\\past}} \blob;
samer@18	483 \draw (p2) +(0.5em,0em) node{\shortstack{infinite\\future}} \blob;
samer@18	484 \path (0,0) node (future) {$E$};
samer@18	485 \path (p1) +(-2em,\rad) node [anchor=south] {$\ldots,X_{-1}$};
samer@18	486 \path (p2) +(2em,\rad) node [anchor=south] {$X_0,\ldots$};
samer@18	487 \end{tikzpicture}%
samer@18	488 }%
samer@18	489 \\[1.25em]
samer@43	490 \subfig{(c) predictive information rate $b_\mu$}{%
samer@18	491 \begin{tikzpicture}%[baseline=-1em]
samer@18	492 \newcommand\rc{2.1em}
samer@18	493 \newcommand\throw{2.5em}
samer@18	494 \coordinate (p1) at (210:1.5em);
samer@18	495 \coordinate (p2) at (90:0.7em);
samer@18	496 \coordinate (p3) at (-30:1.5em);
samer@18	497 \newcommand\bound{(-7em,-2.6em) rectangle (7em,3.0em)}
samer@18	498 \newcommand\present{(p2) circle (\rc)}
samer@18	499 \newcommand\thepast{(p1) ++(-\throw,0) \ovoid{\throw}}
samer@18	500 \newcommand\future{(p3) ++(\throw,0) \ovoid{\throw}}
samer@18	501 \newcommand\fillclipped[2]{%
samer@18	502 \begin{scope}[even odd rule]
samer@18	503 \foreach \thing in {#2} {\clip \thing;}
samer@18	504 \fill[black!#1] \bound;
samer@18	505 \end{scope}%
samer@18	506 }%
samer@43	507 \fillclipped{80}{\future,\thepast}
samer@18	508 \fillclipped{30}{\present,\future,\bound \thepast}
samer@18	509 \fillclipped{15}{\present,\bound \future,\bound \thepast}
samer@18	510 \draw \future;
samer@18	511 \fillclipped{45}{\present,\thepast}
samer@18	512 \draw \thepast;
samer@18	513 \draw \present;
samer@18	514 \node at (barycentric cs:p2=1,p1=-0.17,p3=-0.17) {$r_\mu$};
samer@18	515 \node at (barycentric cs:p1=-0.4,p2=1.0,p3=1) {$b_\mu$};
samer@18	516 \node at (barycentric cs:p3=0,p2=1,p1=1.2) [shape=rectangle,fill=black!45,inner sep=1pt]{$\rho_\mu$};
samer@18	517 \path (p2) +(140:3em) node {$X_0$};
samer@18	518 % \node at (barycentric cs:p3=0,p2=1,p1=1) {$\rho_\mu$};
samer@18	519 \path (p3) +(3em,0em) node {\shortstack{infinite\\future}};
samer@18	520 \path (p1) +(-3em,0em) node {\shortstack{infinite\\past}};
samer@18	521 \path (p1) +(-4em,\rad) node [anchor=south] {$\ldots,X_{-1}$};
samer@18	522 \path (p3) +(4em,\rad) node [anchor=south] {$X_1,\ldots$};
samer@18	523 \end{tikzpicture}}%
samer@18	524 \\[0.5em]
samer@18	525 \end{tabular}
samer@18	526 \caption{
samer@30	527 I-diagrams for several information measures in
samer@18	528 stationary random processes. Each circle or oval represents a random
samer@18	529 variable or sequence of random variables relative to time $t=0$. Overlapped areas
samer@18	530 correspond to various mutual information as in \Figrf{venn-example}.
samer@33	531 In (b), the circle represents the `present'. Its total area is
samer@33	532 $H(X_0)=\rho_\mu+r_\mu+b_\mu$, where $\rho_\mu$ is the multi-information
samer@18	533 rate, $r_\mu$ is the residual entropy rate, and $b_\mu$ is the predictive
samer@43	534 information rate. The entropy rate is $h_\mu = r_\mu+b_\mu$. The small dark
samer@43	535 region below $X_0$ in (c) is $\sigma_\mu = E-\rho_\mu$.
samer@18	536 }
samer@18	537 \end{fig}
samer@18	538
samer@41	539 If we step back, out of the observer's shoes as it were, and consider the
samer@41	540 random process $(\ldots,X_{-1},X_0,X_1,\dots)$ as a statistical ensemble of
samer@41	541 possible realisations, and furthermore assume that it is stationary,
samer@41	542 then it becomes possible to define a number of information-theoretic measures,
samer@41	543 closely related to those described above, but which characterise the
samer@41	544 process as a whole, rather than on a moment-by-moment basis. Some of these,
samer@41	545 such as the entropy rate, are well-known, but others are only recently being
samer@41	546 investigated. (In the following, the assumption of stationarity means that
samer@41	547 the measures defined below are independent of $t$.)
samer@41	548
samer@41	549 The \emph{entropy rate} of the process is the entropy of the next variable
samer@41	550 $X_t$ given all the previous ones.
samer@41	551 \begin{equation}
samer@41	552 \label{eq:entro-rate}
samer@41	553 h_\mu = H(X_t\|\past{X}_t).
samer@41	554 \end{equation}
samer@51	555 The entropy rate is a measure of the overall surprisingness
samer@51	556 or unpredictability of the process, and gives an indication of the average
samer@51	557 level of surprise and uncertainty that would be experienced by an observer
samer@51	558 processing a sequence sampled from the process using the methods of
samer@51	559 \secrf{surprise-info-seq}.
samer@41	560
samer@41	561 The \emph{multi-information rate} $\rho_\mu$ (following Dubnov's \cite{Dubnov2006}
samer@41	562 notation for what he called the `information rate') is the mutual
samer@41	563 information between the `past' and the `present':
samer@41	564 \begin{equation}
samer@41	565 \label{eq:multi-info}
samer@41	566 \rho_\mu = I(\past{X}_t;X_t) = H(X_t) - h_\mu.
samer@41	567 \end{equation}
samer@41	568 It is a measure of how much the context of an observation (that is,
samer@41	569 the observation of previous elements of the sequence) helps in predicting
samer@41	570 or reducing the suprisingness of the current observation.
samer@41	571
samer@41	572 The \emph{excess entropy} \cite{CrutchfieldPackard1983}
samer@41	573 is the mutual information between
samer@41	574 the entire `past' and the entire `future':
samer@41	575 \begin{equation}
samer@41	576 E = I(\past{X}_t; X_t,\fut{X}_t).
samer@41	577 \end{equation}
samer@43	578 Both the excess entropy and the multi-information rate can be thought
samer@43	579 of as measures of \emph{redundancy}, quantifying the extent to which
samer@43	580 the same information is to be found in all parts of the sequence.
samer@41	581
samer@41	582
samer@30	583 The \emph{predictive information rate} (or PIR) \cite{AbdallahPlumbley2009}
samer@46	584 is the mutual information between the present and the infinite future given the infinite
samer@46	585 past:
samer@18	586 \begin{equation}
samer@18	587 \label{eq:PIR}
samer@41	588 b_\mu = I(X_t;\fut{X}_t\|\past{X}_t) = H(\fut{X}_t\|\past{X}_t) - H(\fut{X}_t\|X_t,\past{X}_t).
samer@18	589 \end{equation}
samer@18	590 Equation \eqrf{PIR} can be read as the average reduction
samer@18	591 in uncertainty about the future on learning $X_t$, given the past.
samer@18	592 Due to the symmetry of the mutual information, it can also be written
samer@18	593 as
samer@18	594 \begin{equation}
samer@18	595 % \IXZ_t
samer@43	596 b_\mu = H(X_t\|\past{X}_t) - H(X_t\|\past{X}_t,\fut{X}_t) = h_\mu - r_\mu,
samer@18	597 % \label{<++>}
samer@18	598 \end{equation}
samer@18	599 % If $X$ is stationary, then
samer@41	600 where $r_\mu = H(X_t\|\fut{X}_t,\past{X}_t)$,
samer@34	601 is the \emph{residual} \cite{AbdallahPlumbley2010},
samer@34	602 or \emph{erasure} \cite{VerduWeissman2006} entropy rate.
samer@18	603 These relationships are illustrated in \Figrf{predinfo-bg}, along with
samer@18	604 several of the information measures we have discussed so far.
samer@51	605 The PIR gives an indication of the average IPI that would be experienced
samer@51	606 by an observer processing a sequence sampled from this process.
samer@18	607
samer@18	608
samer@46	609 James et al \cite{JamesEllisonCrutchfield2011} review several of these
samer@46	610 information measures and introduce some new related ones.
samer@46	611 In particular they identify the $\sigma_\mu = I(\past{X}_t;\fut{X}_t\|X_t)$,
samer@46	612 the mutual information between the past and the future given the present,
samer@46	613 as an interesting quantity that measures the predictive benefit of
samer@25	614 model-building (that is, maintaining an internal state summarising past
samer@46	615 observations in order to make better predictions). It is shown as the
samer@46	616 small dark region below the circle in \figrf{predinfo-bg}(c).
samer@46	617 By comparing with \figrf{predinfo-bg}(b), we can see that
samer@46	618 $\sigma_\mu = E - \rho_\mu$.
samer@43	619 % They also identify
samer@43	620 % $w_\mu = \rho_\mu + b_{\mu}$, which they call the \emph{local exogenous
samer@43	621 % information} rate.
samer@34	622
samer@4	623
samer@36	624 \subsection{First and higher order Markov chains}
samer@53	625 \label{s:markov}
samer@36	626 First order Markov chains are the simplest non-trivial models to which information
samer@36	627 dynamics methods can be applied. In \cite{AbdallahPlumbley2009} we derived
samer@41	628 expressions for all the information measures described in \secrf{surprise-info-seq} for
samer@36	629 irreducible stationary Markov chains (\ie that have a unique stationary
samer@36	630 distribution). The derivation is greatly simplified by the dependency structure
samer@36	631 of the Markov chain: for the purpose of the analysis, the `past' and `future'
samer@41	632 segments $\past{X}_t$ and $\fut{X}_t$ can be collapsed to just the previous
samer@46	633 and next variables $X_{t-1}$ and $X_{t+1}$ respectively. We also showed that
samer@36	634 the predictive information rate can be expressed simply in terms of entropy rates:
samer@36	635 if we let $a$ denote the $K\times K$ transition matrix of a Markov chain over
samer@36	636 an alphabet of $\{1,\ldots,K\}$, such that
samer@36	637 $a_{ij} = \Pr(\ev(X_t=i\|X_{t-1}=j))$, and let $h:\reals^{K\times K}\to \reals$ be
samer@36	638 the entropy rate function such that $h(a)$ is the entropy rate of a Markov chain
samer@36	639 with transition matrix $a$, then the predictive information rate $b(a)$ is
samer@36	640 \begin{equation}
samer@36	641 b(a) = h(a^2) - h(a),
samer@36	642 \end{equation}
samer@36	643 where $a^2$, the transition matrix squared, is the transition matrix
samer@36	644 of the `skip one' Markov chain obtained by jumping two steps at a time
samer@36	645 along the original chain.
samer@36	646
samer@36	647 Second and higher order Markov chains can be treated in a similar way by transforming
samer@36	648 to a first order representation of the high order Markov chain. If we are dealing
samer@36	649 with an $N$th order model, this is done forming a new alphabet of size $K^N$
samer@41	650 consisting of all possible $N$-tuples of symbols from the base alphabet.
samer@41	651 An observation $\hat{x}_t$ in this new model encodes a block of $N$ observations
samer@36	652 $(x_{t+1},\ldots,x_{t+N})$ from the base model. The next
samer@41	653 observation $\hat{x}_{t+1}$ encodes the block of $N$ obtained by shifting the previous
samer@36	654 block along by one step. The new Markov of chain is parameterised by a sparse $K^N\times K^N$
samer@41	655 transition matrix $\hat{a}$. Adopting the label $\mu$ for the order $N$ system,
samer@41	656 we obtain:
samer@36	657 \begin{equation}
samer@41	658 h_\mu = h(\hat{a}), \qquad b_\mu = h({\hat{a}^{N+1}}) - N h({\hat{a}}),
samer@36	659 \end{equation}
samer@36	660 where $\hat{a}^{N+1}$ is the $(N+1)$th power of the first order transition matrix.
samer@41	661 Other information measures can also be computed for the high-order Markov chain, including
samer@41	662 the multi-information rate $\rho_\mu$ and the excess entropy $E$. These are identical
samer@41	663 for first order Markov chains, but for order $N$ chains, $E$ can be up to $N$ times larger
samer@41	664 than $\rho_\mu$.
samer@43	665
samer@43	666 [Something about what kinds of Markov chain maximise $h_\mu$ (uncorrelated `white'
samer@43	667 sequences, no temporal structure), $\rho_\mu$ and $E$ (periodic) and $b_\mu$. We return
samer@43	668 this in \secrf{composition}.]
samer@36	669
samer@36	670
hekeus@16	671 \section{Information Dynamics in Analysis}
samer@4	672
samer@24	673 \begin{fig}{twopages}
samer@33	674 \colfig[0.96]{matbase/fig9471} % update from mbc paper
samer@33	675 % \colfig[0.97]{matbase/fig72663}\\ % later update from mbc paper (Keith's new picks)
samer@24	676 \vspace*{1em}
samer@24	677 \colfig[0.97]{matbase/fig13377} % rule based analysis
samer@24	678 \caption{Analysis of \emph{Two Pages}.
samer@24	679 The thick vertical lines are the part boundaries as indicated in
samer@24	680 the score by the composer.
samer@24	681 The thin grey lines
samer@24	682 indicate changes in the melodic `figures' of which the piece is
samer@24	683 constructed. In the `model information rate' panel, the black asterisks
samer@24	684 mark the
samer@24	685 six most surprising moments selected by Keith Potter.
samer@24	686 The bottom panel shows a rule-based boundary strength analysis computed
samer@24	687 using Cambouropoulos' LBDM.
samer@24	688 All information measures are in nats and time is in notes.
samer@24	689 }
samer@24	690 \end{fig}
samer@24	691
samer@36	692 \subsection{Musicological Analysis}
samer@36	693 In \cite{AbdallahPlumbley2009}, methods based on the theory described above
samer@36	694 were used to analysis two pieces of music in the minimalist style
samer@36	695 by Philip Glass: \emph{Two Pages} (1969) and \emph{Gradus} (1968).
samer@36	696 The analysis was done using a first-order Markov chain model, with the
samer@36	697 enhancement that the transition matrix of the model was allowed to
samer@36	698 evolve dynamically as the notes were processed, and was tracked (in
samer@36	699 a Bayesian way) as a \emph{distribution} over possible transition matrices,
samer@36	700 rather than a point estimate. The results are summarised in \figrf{twopages}:
samer@36	701 the upper four plots show the dynamically evolving subjective information
samer@36	702 measures as described in \secrf{surprise-info-seq} computed using a point
samer@36	703 estimate of the current transition matrix, but the fifth plot (the `model information rate')
samer@36	704 measures the information in each observation about the transition matrix.
samer@36	705 In \cite{AbdallahPlumbley2010b}, we showed that this `model information rate'
samer@36	706 is actually a component of the true IPI in
samer@36	707 a time-varying Markov chain, which was neglected when we computed the IPI from
samer@36	708 point estimates of the transition matrix as if the transition probabilities
samer@36	709 were constant.
samer@36	710
samer@36	711 The peaks of the surprisingness and both components of the predictive information
samer@36	712 show good correspondence with structure of the piece both as marked in the score
samer@36	713 and as analysed by musicologist Keith Potter, who was asked to mark the six
samer@36	714 `most surprising moments' of the piece (shown as asterisks in the fifth plot)%
samer@36	715 \footnote{%
samer@36	716 Note that the boundary marked in the score at around note 5,400 is known to be
samer@36	717 anomalous; on the basis of a listening analysis, some musicologists [ref] have
samer@36	718 placed the boundary a few bars later, in agreement with our analysis.}.
samer@36	719
samer@36	720 In contrast, the analyses shown in the lower two plots of \figrf{twopages},
samer@36	721 obtained using two rule-based music segmentation algorithms, while clearly
samer@37	722 \emph{reflecting} the structure of the piece, do not \emph{segment} the piece,
samer@37	723 with no tendency to peaking of the boundary strength function at
samer@36	724 the boundaries in the piece.
samer@36	725
samer@46	726 The complete analysis of \emph{Gradus} can be found in \cite{AbdallahPlumbley2009},
samer@46	727 but \figrf{metre} illustrates the result of a metrical analysis: the piece was divided
samer@46	728 into bars of 32, 64 and 128 notes. In each case, the average surprisingness and
samer@46	729 IPI for the first, second, third \etc notes in each bar were computed. The plots
samer@46	730 show that the first note of each bar is, on average, significantly more surprising
samer@46	731 and informative than the others, up to the 64-note level, where as at the 128-note,
samer@46	732 level, the dominant periodicity appears to remain at 64 notes.
samer@36	733
samer@24	734 \begin{fig}{metre}
samer@33	735 % \scalebox{1}[1]{%
samer@24	736 \begin{tabular}{cc}
samer@33	737 \colfig[0.45]{matbase/fig36859} & \colfig[0.48]{matbase/fig88658} \\
samer@33	738 \colfig[0.45]{matbase/fig48061} & \colfig[0.48]{matbase/fig46367} \\
samer@33	739 \colfig[0.45]{matbase/fig99042} & \colfig[0.47]{matbase/fig87490}
samer@24	740 % \colfig[0.46]{matbase/fig56807} & \colfig[0.48]{matbase/fig27144} \\
samer@24	741 % \colfig[0.46]{matbase/fig87574} & \colfig[0.48]{matbase/fig13651} \\
samer@24	742 % \colfig[0.44]{matbase/fig19913} & \colfig[0.46]{matbase/fig66144} \\
samer@24	743 % \colfig[0.48]{matbase/fig73098} & \colfig[0.48]{matbase/fig57141} \\
samer@24	744 % \colfig[0.48]{matbase/fig25703} & \colfig[0.48]{matbase/fig72080} \\
samer@24	745 % \colfig[0.48]{matbase/fig9142} & \colfig[0.48]{matbase/fig27751}
samer@24	746
samer@24	747 \end{tabular}%
samer@33	748 % }
samer@24	749 \caption{Metrical analysis by computing average surprisingness and
samer@24	750 informative of notes at different periodicities (\ie hypothetical
samer@24	751 bar lengths) and phases (\ie positions within a bar).
samer@24	752 }
samer@24	753 \end{fig}
samer@24	754
samer@46	755 \subsection{Content analysis/Sound Categorisation}
samer@42	756 Using analogous definitions of differential entropy, the methods outlined
samer@42	757 in the previous section are equally applicable to continuous random variables.
samer@42	758 In the case of music, where expressive properties such as dynamics, tempo,
samer@42	759 timing and timbre are readily quantified on a continuous scale, the information
samer@42	760 dynamic framework thus may also be considered.
peterf@39	761
samer@42	762 In \cite{Dubnov2006}, Dubnov considers the class of stationary Gaussian
samer@42	763 processes. For such processes, the entropy rate may be obtained analytically
samer@42	764 from the power spectral density of the signal, allowing the multi-information
samer@42	765 rate to be subsequently obtained. Local stationarity is assumed, which may
samer@42	766 be achieved by windowing or change point detection \cite{Dubnov2008}. %TODO
samer@42	767 mention non-gaussian processes extension Similarly, the predictive information
samer@42	768 rate may be computed using a Gaussian linear formulation CITE. In this view,
samer@42	769 the PIR is a function of the correlation between random innovations supplied
samer@42	770 to the stochastic process. %Dubnov, MacAdams, Reynolds (2006) %Bailes and
samer@42	771 Dean (2009)
peterf@39	772
samer@51	773 [ Continuous domain information ]
samer@51	774 [Audio based music expectation modelling]
samer@51	775 [ Gaussian processes]
peterf@26	776
samer@4	777
samer@4	778 \subsection{Beat Tracking}
samer@4	779
samer@43	780 A probabilistic method for drum tracking was presented by Robertson
samer@43	781 \cite{Robertson11c}. The algorithm is used to synchronise a music
samer@43	782 sequencer to a live drummer. The expected beat time of the sequencer is
samer@43	783 represented by a click track, and the algorithm takes as input event
samer@43	784 times for discrete kick and snare drum events relative to this click
samer@43	785 track. These are obtained using dedicated microphones for each drum and
samer@43	786 using a percussive onset detector (Puckette 1998). The drum tracker
samer@43	787 continually updates distributions for tempo and phase on receiving a new
samer@43	788 event time. We can thus quantify the information contributed of an event
samer@43	789 by measuring the difference between the system's prior distribution and
samer@43	790 the posterior distribution using the Kullback-Leiber divergence.
samer@43	791
samer@43	792 Here, we have calculated the KL divergence and entropy for kick and
samer@43	793 snare events in sixteen files. The analysis of information rates can be
samer@43	794 considered \emph{subjective}, in that it measures how the drum tracker's
samer@43	795 probability distributions change, and these are contingent upon the
samer@43	796 model used as well as external properties in the signal. We expect,
samer@43	797 however, that following periods of increased uncertainty, such as fills
samer@43	798 or expressive timing, the information contained in an individual event
samer@43	799 increases. We also examine whether the information is dependent upon
samer@43	800 metrical position.
samer@43	801
samer@4	802
samer@24	803 \section{Information dynamics as compositional aid}
samer@43	804 \label{s:composition}
samer@43	805
samer@53	806 The use of stochastic processes in music composition has been widespread for
samer@53	807 decades---for instance Iannis Xenakis applied probabilistic mathematical models
samer@53	808 to the creation of musical materials\cite{Xenakis:1992ul}. While such processes
samer@53	809 can drive the \emph{generative} phase of the creative process, information dynamics
samer@53	810 can serve as a novel framework for a \emph{selective} phase, by
samer@53	811 providing a set of criteria to be used in judging which of the
samer@53	812 generated materials
samer@53	813 are of value. This alternation of generative and selective phases as been
samer@53	814 noted by art theorist Margaret Boden \cite{Boden1990}.
samer@53	815
samer@53	816 Information-dynamic criteria can also be used as \emph{constraints} on the
samer@53	817 generative processes, for example, by specifying a certain temporal profile
samer@53	818 of suprisingness and uncertainty the composer wishes to induce in the listener
samer@53	819 as the piece unfolds.
samer@53	820 %stochastic and algorithmic processes: ; outputs can be filtered to match a set of
samer@53	821 %criteria defined in terms of information-dynamical characteristics, such as
samer@53	822 %predictability vs unpredictability
samer@53	823 %s model, this criteria thus becoming a means of interfacing with the generative processes.
samer@53	824
samer@53	825 The tools of information dynamics provide a way to constrain and select musical
samer@53	826 materials at the level of patterns of expectation, implication, uncertainty, and predictability.
samer@53	827 In particular, the behaviour of the predictive information rate (PIR) defined in
samer@53	828 \secrf{process-info} make it interesting from a compositional point of view. The definition
samer@53	829 of the PIR is such that it is low both for extremely regular processes, such as constant
samer@53	830 or periodic sequences, \emph{and} low for extremely random processes, where each symbol
samer@53	831 is chosen independently of the others, in a kind of `white noise'. In the former case,
samer@53	832 the pattern, once established, is completely predictable and therefore there is no
samer@53	833 \emph{new} information in subsequent observations. In the latter case, the randomness
samer@53	834 and independence of all elements of the sequence means that, though potentially surprising,
samer@53	835 each observation carries no information about the ones to come.
samer@53	836
samer@53	837 Processes with high PIR maintain a certain kind of balance between
samer@53	838 predictability and unpredictability in such a way that the observer must continually
samer@53	839 pay attention to each new observation as it occurs in order to make the best
samer@53	840 possible predictions about the evolution of the seqeunce. This balance between predictability
samer@53	841 and unpredictability is reminiscent of the inverted `U' shape of the Wundt curve (see \figrf{wundt}),
samer@53	842 which summarises the observations of Wundt that the greatest aesthetic value in art
samer@53	843 is to be found at intermediate levels of disorder, where there is a balance between
samer@53	844 `order' and `chaos'.
samer@53	845
samer@53	846 Using the methods of \secrf{markov}, we found \cite{AbdallahPlumbley2009}
samer@53	847 a similar shape when plotting entropy rate againt PIR---this is visible in the
samer@53	848 upper envelope of the scatter plot in \figrf{mtriscat}, which is a 3-D scatter plot of
samer@53	849 three of the information measures discussed in \secrf{process-info} for several thousand
samer@53	850 first-order Markov chain transition matrices generated by a random sampling method.
samer@53	851 The coordinates of the `information space' are entropy rate ($h_\mu$), redundancy ($\rho_\mu$), and
samer@53	852 predictive information rate ($b_\mu$). The points along the 'redundancy' axis correspond
samer@53	853 to periodic Markov chains. Those along the `entropy' produce uncorrelated sequences
samer@53	854 with no temporal structure. Processes with high PIR are to be found at intermediate
samer@53	855 levels of entropy and redundancy.
samer@53	856 These observations led us to construct the `Melody Triangle' as a graphical interface
samer@53	857 for exploring the melodic patterns generated by each of the Markov chains represented
samer@53	858 as points in \figrf{mtriscat}.
samer@53	859
samer@43	860 \begin{fig}{wundt}
samer@43	861 \raisebox{-4em}{\colfig[0.43]{wundt}}
samer@43	862 % {\ \shortstack{{\Large$\longrightarrow$}\\ {\scriptsize\emph{exposure}}}\ }
samer@43	863 {\ {\large$\longrightarrow$}\ }
samer@43	864 \raisebox{-4em}{\colfig[0.43]{wundt2}}
samer@43	865 \caption{
samer@43	866 The Wundt curve relating randomness/complexity with
samer@43	867 perceived value. Repeated exposure sometimes results
samer@43	868 in a move to the left along the curve \cite{Berlyne71}.
samer@43	869 }
samer@43	870 \end{fig}
hekeus@45	871
hekeus@13	872
hekeus@45	873 %It is possible to apply information dynamics to the generation of content, such as to the composition of musical materials.
hekeus@45	874
hekeus@45	875 %For instance a stochastic music generating process could be controlled by modifying
hekeus@45	876 %constraints on its output in terms of predictive information rate or entropy
hekeus@45	877 %rate.
hekeus@45	878
hekeus@45	879
hekeus@13	880
samer@23	881 \subsection{The Melody Triangle}
samer@23	882
samer@53	883 The Melody Triangle is an exploratory interface for the discovery of melodic
samer@53	884 content, where the input---positions within a triangle---directly map to information
samer@53	885 theoretic measures of the output. The measures---entropy rate, redundancy and
samer@53	886 predictive information rate---form a criteria with which to filter the output
samer@53	887 of the stochastic processes used to generate sequences of notes. These measures
samer@53	888 address notions of expectation and surprise in music, and as such the Melody
samer@53	889 Triangle is a means of interfacing with a generative process in terms of the
samer@53	890 predictability of its output.
samer@53	891
samer@53	892 The triangle is `populated' with first order Markov chain transition
samer@53	893 matrices as illustrated in \figrf{mtriscat}.
samer@53	894
samer@51	895 \begin{fig}{mtriscat}
samer@51	896 \colfig{mtriscat}
samer@34	897 \caption{The population of transition matrices distributed along three axes of
samer@34	898 redundancy, entropy rate and predictive information rate (all measured in bits).
samer@34	899 The concentrations of points along the redundancy axis correspond
samer@34	900 to Markov chains which are roughly periodic with periods of 2 (redundancy 1 bit),
samer@34	901 3, 4, \etc all the way to period 8 (redundancy 3 bits). The colour of each point
samer@34	902 represents its PIR---note that the highest values are found at intermediate entropy
samer@34	903 and redundancy, and that the distribution as a whole makes a curved triangle. Although
samer@51	904 not visible in this plot, it is largely hollow in the middle.}
samer@51	905 \end{fig}
samer@23	906
samer@43	907 The distribution of transition matrices plotted in this space forms an arch shape
samer@42	908 that is fairly thin. It thus becomes a reasonable approximation to pretend that
samer@42	909 it is just a sheet in two dimensions; and so we stretch out this curved arc into
samer@42	910 a flat triangle. It is this triangular sheet that is our `Melody Triangle' and
samer@42	911 forms the interface by which the system is controlled. Using this interface
samer@46	912 thus involves a mapping to information space; a user selects a position within
samer@51	913 the triangle, and a corresponding transition matrix is returned.
samer@51	914 \Figrf{TheTriangle} shows how the triangle maps to different measures of redundancy,
samer@42	915 entropy rate and predictive information rate.
samer@41	916
samer@41	917
samer@42	918 Each corner corresponds to three different extremes of predictability and
samer@42	919 unpredictability, which could be loosely characterised as `periodicity', `noise'
samer@42	920 and `repetition'. Melodies from the `noise' corner have no discernible pattern;
samer@42	921 they have high entropy rate, low predictive information rate and low redundancy.
samer@42	922 These melodies are essentially totally random. A melody along the `periodicity'
samer@42	923 to `repetition' edge are all deterministic loops that get shorter as we approach
samer@42	924 the `repetition' corner, until it becomes just one repeating note. It is the
samer@42	925 areas in between the extremes that provide the more `interesting' melodies.
samer@42	926 These melodies have some level of unpredictability, but are not completely random.
samer@42	927 Or, conversely, are predictable, but not entirely so.
samer@41	928
samer@51	929 \begin{fig}{TheTriangle}
samer@51	930 \colfig[0.9]{TheTriangle.pdf}
samer@51	931 \caption{The Melody Triangle}
samer@51	932 \end{fig}
samer@41	933
hekeus@45	934 %PERHAPS WE SHOULD FOREGO TALKING ABOUT THE
hekeus@45	935 %INSTALLATION VERSION OF THE TRIANGLE?
hekeus@45	936 %feels a bit like a tangent, and could do with the space..
samer@42	937 The Melody Triangle exists in two incarnations; a standard screen based interface
samer@42	938 where a user moves tokens in and around a triangle on screen, and a multi-user
samer@42	939 interactive installation where a Kinect camera tracks individuals in a space and
hekeus@45	940 maps their positions in physical space to the triangle. In the latter each visitor
hekeus@45	941 that enters the installation generates a melody and can collaborate with their
samer@42	942 co-visitors to generate musical textures---a playful yet informative way to
hekeus@45	943 explore expectation and surprise in music. Additionally visitors can change the
hekeus@45	944 tempo, register, instrumentation and periodicity of their melody with body gestures.
samer@41	945
hekeus@45	946 As a screen based interface the Melody Triangle can serve as a composition tool.
samer@42	947 A triangle is drawn on the screen, screen space thus mapped to the statistical
hekeus@45	948 space of the Melody Triangle. A number of tokens, each representing a
hekeus@45	949 melody, can be dragged in and around the triangle. For each token, a sequence of symbols with
hekeus@45	950 statistical properties that correspond to the token's position is generated. These
samer@51	951 symbols are then mapped to notes of a scale%
samer@51	952 \footnote{However they could just as well be mapped to any other property, such
samer@51	953 as intervals, chords, dynamics and timbres. It is even possible to map the
samer@51	954 symbols to non-sonic outputs, such as colours. The possibilities afforded by
samer@51	955 the Melody Triangle in these other domains remains to be investigated.}.
hekeus@45	956 Additionally keyboard commands give control over other musical parameters.
samer@23	957
samer@51	958 The Melody Triangle can generate intricate musical textures when multiple tokens
samer@51	959 are in the triangle. Unlike other computer aided composition tools or programming
samer@51	960 environments, here the composer engages with music on a high and abstract level;
samer@51	961 the interface relating to subjective expectation and predictability.
hekeus@45	962
hekeus@35	963
hekeus@35	964
hekeus@38	965
hekeus@38	966 \subsection{Information Dynamics as Evaluative Feedback Mechanism}
hekeus@38	967 %NOT SURE THIS SHOULD BE HERE AT ALL..?
hekeus@38	968
samer@46	969 \begin{fig}{mtri-results}
samer@46	970 \def\scat#1{\colfig[0.42]{mtri/#1}}
samer@46	971 \def\subj#1{\scat{scat_dwells_subj_#1} & \scat{scat_marks_subj_#1}}
samer@46	972 \begin{tabular}{cc}
samer@46	973 \subj{a} \\
samer@46	974 \subj{b} \\
samer@46	975 \subj{c} \\
samer@46	976 \subj{d}
samer@46	977 \end{tabular}
samer@46	978 \caption{Dwell times and mark positions from user trials with the
samer@46	979 on-screen Melody Triangle interface. The left-hand column shows
samer@46	980 the positions in a 2D information space (entropy rate vs multi-information rate
samer@46	981 in bits) where spent their time; the area of each circle is proportional
samer@46	982 to the time spent there. The right-hand column shows point which subjects
samer@46	983 `liked'.}
samer@46	984 \end{fig}
hekeus@38	985
samer@42	986 Information measures on a stream of symbols can form a feedback mechanism; a
hekeus@45	987 rudimentary `critic' of sorts. For instance symbol by symbol measure of predictive
samer@42	988 information rate, entropy rate and redundancy could tell us if a stream of symbols
samer@42	989 is currently `boring', either because it is too repetitive, or because it is too
hekeus@45	990 chaotic. Such feedback would be oblivious to long term and large scale
hekeus@45	991 structures and any cultural norms (such as style conventions), but
hekeus@45	992 nonetheless could provide a composer with valuable insight on
samer@42	993 the short term properties of a work. This could not only be used for the
samer@42	994 evaluation of pre-composed streams of symbols, but could also provide real-time
samer@42	995 feedback in an improvisatory setup.
hekeus@38	996
hekeus@13	997 \section{Musical Preference and Information Dynamics}
samer@42	998 We are carrying out a study to investigate the relationship between musical
samer@42	999 preference and the information dynamics models, the experimental interface a
samer@42	1000 simplified version of the screen-based Melody Triangle. Participants are asked
samer@42	1001 to use this music pattern generator under various experimental conditions in a
samer@42	1002 composition task. The data collected includes usage statistics of the system:
samer@42	1003 where in the triangle they place the tokens, how long they leave them there and
samer@42	1004 the state of the system when users, by pressing a key, indicate that they like
samer@42	1005 what they are hearing. As such the experiments will help us identify any
samer@42	1006 correlation between the information theoretic properties of a stream and its
samer@42	1007 perceived aesthetic worth.
hekeus@16	1008
samer@46	1009 Some initial results for four subjects are shown in \figrf{mtri-results}. Though
samer@46	1010 subjects seem to exhibit distinct kinds of exploratory behaviour, we have
samer@46	1011 not been able to show any systematic across-subjects preference for any particular
samer@46	1012 region of the triangle.
samer@46	1013
samer@46	1014 Subjects' comments: several noticed the main organisation of the triangle:
samer@46	1015 repetative notes at the top, cyclic patters along the right edge, and unpredictable
samer@46	1016 notes towards the bottom left (a,c,f). Some did systematic exploration.
samer@46	1017 Felt that the right side was more `controllable' than the left (a,f)---a direct consequence
samer@46	1018 of their ability to return to a particular periodic pattern and recognise at
samer@46	1019 as one heard previously. Some (a,e) felt the trial was too long and became
samer@46	1020 bored towards the end.
samer@46	1021 One subject (f) felt there wasn't enough time to get to hear out the patterns properly.
samer@46	1022 One subject (b) didn't enjoy the lower region whereas another (d) said the lower
samer@46	1023 regions were more `melodic' and `interesting'.
samer@4	1024
hekeus@38	1025 %\emph{comparable system} Gordon Pask's Musicolor (1953) applied a similar notion
hekeus@38	1026 %of boredom in its design. The Musicolour would react to audio input through a
hekeus@38	1027 %microphone by flashing coloured lights. Rather than a direct mapping of sound
hekeus@38	1028 %to light, Pask designed the device to be a partner to a performing musician. It
hekeus@38	1029 %would adapt its lighting pattern based on the rhythms and frequencies it would
hekeus@38	1030 %hear, quickly `learning' to flash in time with the music. However Pask endowed
hekeus@38	1031 %the device with the ability to `be bored'; if the rhythmic and frequency content
hekeus@38	1032 %of the input remained the same for too long it would listen for other rhythms
hekeus@38	1033 %and frequencies, only lighting when it heard these. As the Musicolour would
hekeus@38	1034 %`get bored', the musician would have to change and vary their playing, eliciting
hekeus@38	1035 %new and unexpected outputs in trying to keep the Musicolour interested.
samer@4	1036
hekeus@13	1037
samer@4	1038 \section{Conclusion}
samer@51	1039 We outlined our information dynamics approach to the modelling of the perception
samer@51	1040 of music. This approach models the subjective assessments of an observer that
samer@51	1041 updates its probabilistic model of a process dynamically as events unfold. We
samer@51	1042 outlined `time-varying' information measures, including a novel `predictive
samer@51	1043 information rate' that characterises the surprisingness and predictability of
samer@51	1044 musical patterns.
samer@4	1045
hekeus@45	1046
samer@51	1047 We have outlined how information dynamics can serve in three different forms of
samer@51	1048 analysis; musicological analysis, sound categorisation and beat tracking.
hekeus@50	1049
samer@51	1050 We have described the `Melody Triangle', a novel system that enables a user/composer
samer@51	1051 to discover musical content in terms of the information theoretic properties of
samer@51	1052 the output, and considered how information dynamics could be used to provide
samer@51	1053 evaluative feedback on a composition or improvisation. Finally we outline a
samer@51	1054 pilot study that used the Melody Triangle as an experimental interface to help
samer@51	1055 determine if there are any correlations between aesthetic preference and information
samer@51	1056 dynamics measures.
hekeus@50	1057
hekeus@45	1058
hekeus@44	1059 \section{acknowledgments}
samer@51	1060 This work is supported by EPSRC Doctoral Training Centre EP/G03723X/1 (HE),
samer@51	1061 GR/S82213/01 and EP/E045235/1(SA), an EPSRC Leadership Fellowship, EP/G007144/1
samer@51	1062 (MDP) and EPSRC IDyOM2 EP/H013059/1.
hekeus@44	1063
samer@56	1064 \bibliographystyle{abbrv}
samer@43	1065 {\bibliography{all,c4dm,nime,andrew}}
samer@4	1066 \end{document}

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