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Learning fast and accurate absolute pitch judgment in adulthood

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  * Published: 12 February 2025

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Learning fast and accurate absolute pitch judgment in adulthood
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  * Yetta Kwailing Wong  ORCID: orcid.org/0000-0002-8243-2047^1,2,
  * Leo Y. T. Cheung^3,
  * Vince S. H. Ngan^4 &
  * ...
  * Alan C.-N. Wong  ORCID: orcid.org/0000-0002-2129-3485^1,2,5 

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Abstract

Absolute pitch (AP) refers to the ability to identify the pitch of a
tone without external references. It is commonly believed that only
individuals with special genetic makeup and early musical training
within the critical period can develop AP. Recent studies have begun
to challenge the critical period notion by showing the possibility of
AP acquisition in adults. However, the learning effects could be
attributed to learning of pitch height instead of chroma, extended
working memory, relative pitch strategies, chance under repeated
attempts, pre-existing AP abilities and/or specific cognitive
profiles. An 8-week online computerized training program was designed
to address these concerns and clarify learnability of AP in
adulthood. Twelve musicians on average spent 21.4 h completing 15,327
training trials. By the end of the training, they learned to name an
average of 7.08 pitches (ranging from 3 to 12) at an accuracy of 90%
or above and within a response-time (RT) window of 1,305-2,028 ms.
After training, pitch-naming accuracy was significantly improved by
128.1% (from .139 to .317) and size of error reduced by 42.7% (from
2.62 to 1.50 semitones) for the trained timbre, which generalized
partially to an untrained timbre. Overall, results provide more
convincing evidence for the learnability of AP judgment in adulthood
beyond the critical period, similar to most perceptual and cognitive
abilities.

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Introduction

Absolute pitch (AP) refers to the ability to identify the pitch name
of a tone that is presented in isolation. In Western music, AP
involves identifying a correct pitch name out of 12 possible answers.
As straightforward as it appears, AP is rather rare, with a suggested
occurrence ranging from 1 in 10,000 in the population (Takeuchi &
Hulse, 1993) to 7-50% among well-trained musicians in music
conservatories (Deutsch et al., 2006; Miyazaki et al., 2012). Why is
AP so rarely found given the relatively small number of possible
alternatives and musicians' huge amount of exposure to these tones
and pitch names?

It is widely endorsed that the development of AP requires a special
genetic predisposition and an early onset of musical training during
the critical period (Bachem, 1940; Baharloo et al., 1998; Chin, 2003;
Deutsch, 2019; Drayna, 2007; Levitin & Rogers, 2005; Ross et al.,
2005; Trainor, 2005; Zatorre, 2003). Support of the genetic
contribution comes from the observation that AP runs in families
(Baharloo et al., 1998, 2000; Drayna, 2007; Gregersen et al., 1999,
2001). Evidence for the critical period comes from the observation
that AP possessors tend to start their musical training early in life
at or before 5 years of age (Gregersen et al., 1999). Importantly,
while learning AP in childhood is possible with months or years of
practice (Crozier, 1997; Miyazaki & Ogawa, 2006; Sakakibara, 2014),
it is considered impossible in adulthood with no "convincing success
observed" in repeated attempts in the past decades (p.434, Bachem,
1940; p.29, Levitin & Rogers, 2005; p.358, Takeuchi & Hulse, 1993).

Recent findings begin to challenge whether the critical period indeed
constrains the development of AP. Extensive perceptual training
lasting for 12-40 h has been shown to improve pitch-naming
performance for most adult participants, who learned to name on
average 7.2-9.4 pitches out of 12 across experiments (Wong et al.,
2020a, 2020b; Wong et al., 2020a, 2020b; see also Van Hedger et al.,
2019). The highest achievers can name 12 pitches at 90% accuracy or
above, an average error less than half a semitone, and an average
correct RT of around 2 s. This level of performance was comparable to
those of real-world AP possessors reported in the literature (see
discussion in Wong et al., 2020a, 2020b; Wong et al., 2020a, 2020b).
The results suggest that AP is not constrained by the critical period
and continues to develop in adulthood.

Despite the previous findings, the learnability of AP judgment in
adulthood remains inconclusive because of several methodological
issues. First, previous AP training was often limited to one octave
(Experiment 2, Wong et al., 2020a, 2020b; Wong et al., 2020a, 2020b)
or two octaves (Experiment 1 & 3, Wong et al., 2020a, 2020b). It
remains unclear whether the participants really learned the chroma of
the tones, which is shared by notes that are one or more octave(s)
apart with the same pitch name and considered the essence of AP
(Bachem, 1955; Zatorre, 2003), or they merely learned to name a
highly specific set of tones based on pitch height.

Second, many tones were presented with their correct pitch names in
the course of training, for example during training trials with
feedback, practice trials or sample listening (Wong et al., 2020a,
2020b; Wong et al., 2020a, 2020b). Previous studies used 18-20 s
continuous glissando stimuli to provide auditory interference before
subsequent testing (Wengenroth et al., 2013; Wong et al., 2020a,
2020b; Wong et al., 2020a, 2020b), which should minimize the use of
these tones as external reference for most participants (Peterson &
Peterson, 1959; Takeuchi & Hulse, 1993). However, it is possible that
the auditory interference was not effective enough for some
individuals with extended tonal working memory because of their
musical expertise (Talamini et al., 2022).

Third, due to a limited range of pitches used in previous studies,
the pitch difference between the tones in adjacent testing trials was
relatively small (Wong et al., 2020a, 2020b; Wong et al., 2020a,
2020b). This made it easier to use relative pitch strategies during
AP tests (Deutsch, 1972; Deutsch & Boulanger, 1984). Specifically,
participants could have learned to name a couple of the pitches in an
absolute manner, and used them as internally generated references to
name other pitches. Although no external references were involved, it
was inconsistent with the expectation that participants developed AP
with most or all pitches (Zatorre, 2003).

Fourth, acquisition of AP ability was often demonstrated by
successfully passing the last training level that included all 12
pitches (Wong et al., 2020a, 2020b; Wong et al., 2020a, 2020b).
Although the performance requirement for the last training level was
high, participants could have passed the final level by chance given
unlimited attempts. For example, a person with a true ability
corresponding to an accuracy level of 70% could have reached 90%
accuracy in a block after many attempts due to statistical fluke.

Fifth, the two highest achievers in a previous AP training already
attained a very high accuracy (proportion correct = 60-70%) in an AP
test before training (Table 2 in Van Hedger et al., 2019). This
performance level approached the average performance of real-world AP
possessors in several previous studies (Table 1 in Takeuchi & Hulse,
1993). Also, the two participants reached a performance plateau after
the first week of training, and the near-perfect accuracies stayed
similar in the following 7 weeks (Fig. 3A; Van Hedger et al., 2019).
It is therefore possible that the AP abilities observed at post-test
were existing to a large degree before training.

Lastly, one of the training studies selected participants with high
auditory working memory (Van Hedger et al., 2019), which makes it
unclear whether the observed AP learning could be generalized to the
general population. Overall, these issues lead to the question about
the quality and consistency of the acquired AP.

The goal of the current study was to examine the learnability of AP
judgment in adulthood after addressing the issues described above.
Adult musicians participated in an online AP training spanning
8 weeks. During training, they were presented a tone each time and
clicked on its pitch name within a specific time window (Fig. 1a). As
training progressed, more pitches were included and the time window
allowed was gradually reduced until participants attained fast and
accurate pitch-naming performance with all the 12 pitches (see
Methods). During pre-post tests, both the trained timbre and an
untrained timbre were introduced to examine the extent of
generalization of the AP learning.

Fig. 1
figure 1

(A) An example training trial of the absolute pitch (AP) training,
for a level with three pitch names being learned. (B) Individual
progress of the AP training. Number of pitches learned was defined by
the number of pitches that the participants could name with an
accuracy of at least 90%, without trial-by-trial feedback or external
reference provided, and within specific time windows (see Online
Supplementary Material Table 1). Each line represents the learning
progress of a participant. (C) The number of pitches learned at the
end of training for each participant. Each gray dot represents the
achievement of one participant, and the cross indicates the group
mean. The labels of each participant (e.g., S1, S2, etc.) match with
the ones used in the tables and other figures

Full size image

The methodological issues discussed above were addressed by the
following design. First, tones in three octaves were included in the
training to facilitate the learning of chroma instead of simply pitch
height. Second, no feedback was provided during the post-test,
including practice trials, such that no external reference could have
existed to enhance AP performance through working memory. Third,
during the pre-post tests, successive testing tones were always more
than an octave apart. This, together with the relatively short RT
windows of 5 s, reduced the effectiveness of any relative pitch
strategy applied internally in one's mind. Fourth, to complete the
training, participants were required to pass the final training level
four times in a row, with a waiting time of at least 12 h between the
third and the fourth attempts. The stable and consistent performance
required here would minimize the probability of one accidentally
fulfilling the accuracy criterion for the completion of the training
upon repeated attempts. Lastly, the participants were not screened
with any cognitive abilities and their AP performance was relatively
low before training (proportion of correct trials ranged from 0 to
0.36, mean = 0.139), and therefore their AP learning would be
representative and cannot be explained by pre-existing AP abilities
comparable to that of real-world AP possessors.

If the development of AP ability is not constrained by the critical
period and remains learnable in adulthood, there should be no "glass
ceiling" for AP learning up to the performance level comparable to
that of real-world AP possessors. In this case, the majority of
participants should improve in pitch naming after training, and it
should be possible for some participants to develop AP ability
approaching or comparable to that of real-world AP possessors.
Alternatively, if critical period limits AP development, AP
improvement should be limited, and none of the participants should
result in an AP ability that approached that of real-world AP
possessors.

Methods

Pre-registration

This study was pre-registered for tonal language speakers and
non-tonal language speakers (see the Open Science Statement for the
links). They were pre-registered separately because we had planned to
study both groups and had no intention to compare the degree of
learning of the two groups. Because of dropout and slower training
progress than expected (see details below), we decided to deviate
from the pre-registration in terms of dropping one of the planned
research questions, combining the data from the tonal and non-tonal
language speakers during analyses, the amount of training required to
participate in the post-test, and the RT window used (see Online
Supplementary Material (OSM) for details). Otherwise, the study was
conducted as described in the pre-registration documents.

Participants

Participants were recruited online through personal network, social
media, and university mass emails. They included both tonal and
non-tonal language speakers. Tonal language speakers were Cantonese
speakers recruited from Hong Kong. Non-tonal language speakers were
those who have not learned any tonal languages or lived in any
community internationally in which most people spoke a tonal language
during the critical period, i.e., before the age of 12 years.
Participants might have exposure to tonal languages afterwards, for
example, one participant started to learn a tonal language at the age
of 25 years. They should be able to understand English instructions,
be aged 18-59 years, and were required to have considerable
achievement or experience in music, i.e., by passing Grade 6 or above
in recognized public exams (e.g., ABRSM, Trinity, etc.) or by
extensive experience in music playing or performance. They filled out
a questionnaire to report their music training background, their
motivation, and their expected time commitment for learning AP. Those
who indicated substantial interest in acquiring AP and the
willingness to commit the time required for the training were invited
to the study. Participation was voluntary without any monetary
compensation for their time. All the training and testing sessions
were conducted online during the pandemic period. All participants
provided informed consent, with all methods (including experimental
protocols) approved and performed according to the guideline of the
Survey and Behavioral Research Ethics Committee of the Chinese
University of Hong Kong in accordance with the Declaration of
Helsinki.

The sample size of this study was affected by dropout and slow
training progress (Table 1). Specifically, ten withdrew from
participation, who had completed 5.06 h of training on average (SD =
 3.92; range = 0.83-12.2). Also, despite their strong interests in
learning AP, 25 participants could not keep up with the expected time
commitment of the training, and completed 3.80 h of training on
average (SD = 2.48; range = 0.37-8.10). This was likely caused by the
voluntary nature of the study during the pandemic because it did not
occur in our previous paid online training study (Wong et al., 2020a,
2020b).

Table 1 Number of participants included and excluded in the post-test
and the subsequent data analyses. Among the withdrawn participants,
their reasons for withdrawal included other commitments (N = 6) and
health reasons (N = 1); three participants did not provide any
explanations
Full size table

Thirteen participants who completed 10 h of training or more within
8 weeks were invited for post-test. One participant was excluded from
data analyses because, during the post-test, she listened to two
reference tones on her iPad during the break between two blocks of
testing trials even though this was strictly prohibited as explicitly
explained in the instruction (see below for details about monitoring
measures of participants' behavior during online testing).

As a result, 12 participants were included in the analyses. They
included seven tonal and five non-tonal language speakers (four
males, seven females, and one with non-binary gender), and were
27.8 years old on average (range 19-44, SD = 8.58 years; Table 2).
They had on average 12.8 years of musical training (SD = 5.42) and
spent 5.08 h on musical practice every week (SD = 3.73). This sample
size provided > 0.95 power, at p = 0.05, to reveal the effect of
improved AP ability before and after training based on the training
effect size in a previous training study (Cohen's d = 1.30 and 2.09
for improvement in the proportion of correct trials and in size of
pitch-naming error, respectively (Wong et al., 2020a, 2020b).
Separate analyses that included only those who had completed the 25 h
of training, as originally planned in the pre-registration, led to
similar results in the ANOVA analyses (see OSM).

Table 2 Language and music training background of the participants.
The data of the onset of music training of tonal language speakers
were missing due to procedural error
Full size table

It is possible that the excluded participants were those who learned
AP less effectively, and therefore the results reported in this study
would have over-estimated the AP learning in the population. To test
this possibility, the learning progress was compared between the
included and excluded participants during the first 6,000 trials of
learning (Fig. 2). Mann-Whitney U tests were used to test whether the
number of pitches learned between the included and excluded
participants during each of the first five bins of training (1,200
trials per bin, corresponding to roughly an hour of learning) were
similar. Mann-Whitney U tests were used because Shapiro-Wilk tests
showed a violation of the normality assumption for all of the bins (p
s <= 0.003). Those who completed less than 1,200 trials over 8 weeks
were not considered in this analysis (N = 8; mean = 735.5 trials; SD 
= 316.1; Table 1). The participant who failed to adhere to the
instruction of not using an external pitch reference during testing
was not considered in this analysis because this exclusion was not
relevant to the potential differences in learning progress of the
dropouts.

Fig. 2
figure 2

Boxplot of the progress of the absolute pitch (AP) training for
participants who were included or excluded from the analyses (Table 1
). Number of pitches learned was defined by the number of pitches
that the participants could name with an accuracy of at least 90%,
without trial-by-trial feedback or external reference provided, and
within the specific time windows (Online Supplementary Material
Table 1)

Full size image

Results showed that there were no observable differences in all of
the bins between the two groups (all ps > 0.21). Bayes statistics
showed weak evidence supporting no difference in the number of
pitches learned in all bins (Bayes Factor[10] ranged between 0.337
and 0.624). Similar analyses were not performed from the sixth bin
onwards as there were only four or less participants left in the
excluded group. These showed that the risk of over-estimating the AP
learning by investigating the included participants only was minimal.

Materials

Piano tones from three octaves (C4 to B6) were generated using two
different digital pianos (Roland FP60 and Yamaha Arius), and guitar
tones spanning the same range were generated by an online
synthesizer. The tones were presented in clips of 800 ms in length,
with a 100-ms ramp at the beginning and at the end using Audacity.
The tones were then normalized to the sound pressure of 0.99 Pascal
in volume using Praat. The training used piano tones, while the
pre-post test included piano tones to examine the training effect and
guitar tones to examine learning generalization to an untrained
timbre. The piano tones used during training and pre-post tests were
generated from different sources (Roland FP60 for training and Yamaha
Arius for testing) so as to ensure that the observed learning effects
were general to the timbre of piano instead of a specific acoustic
spectrum. Participants were recommended to use a headphone during
training and were required to use a headphone during pre-post tests
(see below).

Training

For AP training, participants were instructed to finish 25 h of
training online over 8 weeks, and complete at least 2 h of training
per week. The training included 288 training levels, with 24 levels
for each additional pitch, with the goal of training participants to
acquire fast and accurate AP judgment while recognizing small
improvements in the process.

Training started with one pitch (the pitch "F") with 24 training
levels that require a progressively higher level of accuracy to pass
(from 20 to 90%), with feedback provided at first and followed by
no-feedback levels, and with progressively shorter RT windows (from
1,183 ms for learning one pitch to 2,028 ms for learning 12 pitches).
When one passed the 24th level, a new pitch adjacent to the original
set of pitch(es) would be added to the training followed by another
24 levels of training. The new pitch would be alternatively taken
from the upper or the lower side of the starting pitch. For example,
"E" was added when one passed all levels with "F," and then "F#" was
the pitch added next. This cycle repeated until all 12 pitches were
introduced.

To ensure that participants were learning the pitch names instead of
working on a relative judgment of highest versus lowest tones within
the training set, four additional pitches were included in the
training around the learning pitches, i.e., + 2, + 1 semitones
relative to the highest pitch being trained, and -1, -2 semitones
relative to the lowest pitch being trained. Participants should
indicate that these four pitches were "out of bound," i.e., tones
that did not match any of the to-be-learned pitch names. In other
words, when participants were learning "one pitch," they were in fact
hearing tones of five pitches. They were required to name one of the
pitches and identify the other four as "out of bound." The
out-of-bound tones faded out when the training set became larger,
i.e., when there were no pitches left untrained immediately above or
below the training set. They were no longer included when the
training set included all 12 pitches.

During training, participants clicked on a button in the middle of
the screen to start a trial. Then, a tone would be presented for
800 ms, and a response image with all the possible response options
(the training pitch names and an option of "out-of-bound"; Fig. 1a).
Participants were required to click on one of the options within the
RT window. Responses after the designated RT window would be regarded
as errors. Also, semitone errors, i.e., answers that were one
semitone off the correct answers, were regarded as errors.

Participants could opt for hearing sample tones before the start of
each training level. They could click on one of the trained pitches,
and then they would hear all of the tones associated with that pitch
(across three octaves) presented in a random order. They could
repeatedly listen to the sample tones without time limit until they
decided to proceed. If the subsequent level was one without feedback,
a Shepard tone, i.e., a continuously descending tone that does not
have clear transition between isolated pitches, would be presented
for 20 s to disrupt the working memory associated with the heard tone
samples.

To make the best use of participants' training time, we also
introduced a level-jumping mechanism. This allowed participants to
jump to a higher level that matched with his or her demonstrated
performance and skip the training levels in between. For example,
although level 1 requires only an accuracy of 20% to pass, if
participants attained 90% accuracy at this level, they could skip the
following levels that require 30-90% accuracies, and proceed to the
level after that requires 90% accuracy.

When the number of trained pitches was five or above, two special
exercises were additionally provided after every 15 attempted
training levels so as to pinpoint individual learning needs. The
special exercises focused on a target pitch with the lowest accuracy
over the last 15 attempted training levels. In the special exercises,
participants were prompted to select whether the presented tone was
the target pitch or other out-of-bound pitches. The first special
exercise included 12 trials with feedback, and the second special
exercise included 22 trials without feedback. Also, when participants
attempted the same level for ten times or more without passing it,
they were contacted by the experimenter and provided an option to
return to a lower level, e.g., those with feedback or with a longer
RT, to gradually learn again. This was up to participants to decide
and the exact level to go to was discussed on an individual basis.
This option was adopted at 1.26% of the total attempted levels.

Other motivational measures were added to gamify the training
experience. For example, participants could earn tokens by achieving
various accuracies even if they did not pass a training level. With
ten tokens, they had a chance of doubling the points earned at a
trial such that it would be easier to pass a level. Sometimes these
chances of doubling the points could appear randomly (1 in 80 trials
on average) as an unexpected reward. These added strategic elements
to the training for motivational purposes. Importantly, at the final
24th level of learning each additional pitch, none of these strategic
elements were allowed, such that participants needed to achieve the
expected performance without extra assistance before moving on.
Finally, participants were informed about the number of consecutive
days they had been participating in the training. This number would
drop to zero if they did not do any training for more than two
calendar days. This served as a reward for encouraging consistent
training behavior.

Since the training was conducted online, participants could perform a
training session anywhere as long as they had access to the Internet.
To encourage participants to find a suitable place and time with
stable Internet connection to do the training, participants were
informed that only training sessions lasted for more than 15 min
would be counted towards their 25 h of training time.

To finish the training, participants should either complete 25 h of
training or fulfil the following criteria: (1) passing the 288th
training level for three consecutive times; and then (2) achieving a
"one-take-pass" performance of the 288th (final) level after at least
12 h of no-training waiting time. This ensures that participants
completed the training with a consistent performance instead of
simply achieving the 90% accuracy criterion once by chance with
repeated attempts.

Pre-post tests

An AP-naming test was used as the pre-post test. Training effects
were assessed with a one-group repeated-measures design with two
within-subject factors of Pre-post (pre-test/post-test) and Timbre
(trained/untrained). No control training group was required here
because AP is known to be notoriously difficult to acquire even with
decades of musical training and exposure (Takeuchi & Hulse, 1993;
Ward, 1999), and therefore placebo effects were not a concern. A
previous study also reported that repeated attempts of the same AP
test in the same session, using a pitch name verification task and
each with 144 trials, resulted in similar performances (d' = 0.27,
0.42, and 0.30 for the three attempts, respectively; Wong et al.,
2020a, 2020b). This demonstrates that AP performance showed limited
changes just by repeated testing.

Each pre-post test included 144 trials, involving tones in 12 pitches
in two timbres (trained/untrained) and three octaves (octaves 4-6),
and each appearing twice. Participants finished a block of trials
with the trained timbre, followed by one with the untrained timbre.
All the tones of different octaves within each block were randomized
with the restriction that tones in adjacent trials were more than 12
semitones apart to discourage the contribution of relative pitch in
AP performance (Carroll, 1975; Deutsch, 1972; Miyazaki, 1988, 1989,
1990). Participants were required to respond as fast and as
accurately as possible, with a maximum RT window of 5 s. Semitone
errors were regarded as errors, and so were responses beyond the 5-s
time window.

Since the pre-post tests were conducted online, several measures were
taken to prevent the possibility of (or at least identify) cheating
behavior, for example, to inappropriately enhance performance by
relying on external devices during testing. First, participants were
required to use personal headphones, with an additional checking of
the audio setup of the computer before testing to ensure that the
only audio output was the headphone. This made sure that no other
external devices could possibly receive the audio output of the tones
during testing to provide any extra hints. Second, before testing,
participants were required to show the testing environment (including
the surface of their table) to experimenters with a webcam to reduce
the likelihood that there would be devices that could be of extra
assistance. Third, the test sessions were recorded using Zoom, during
which participants were required to share the whole desktop screen
with the experimenter. This was to monitor any additional software or
web browsers available on the computer. Lastly, participants were
required to show their faces during the Zoom recording such that the
experimenter could monitor their face and eye movement for any
suspicious search of extra hints during testing. These measures
discouraged cheating and minimized the possibility that participants
received any extra help during the pre-post tests. As mentioned
above, one participant was excluded because the Zoom recording showed
that she listened to two tones on her iPad during the break between
two blocks of trials.

Analyses

Analyses were performed with Jamovi (v. 2.3.21). As planned,
repeated-measures ANOVA with Pre-post (pre-test/post-test) x Timbre
(trained/untrained) were conducted on the proportion correct, size of
error (i.e., absolute deviation of the response from the correct
answers in the unit of semitones), and the correct RT during pre-post
tests.

Results

Training progress

On average, participants completed 21.4 training hours (SD = 4.18;
range 12.6-26.5 h) and 15,327 training trials (SD = 5,293; range
7,500-24,524 trials). At the end of the training, participants were
exposed to 11.08 pitches on average (including the "out-of-bound"
tones), and were able to name 7.08 pitches (SD = 3.65; range 3-12)
with an accuracy of 90% or above, without any feedback or any extra
assistance, and within a RT window of 1,305-2,028 ms that varied
depending on the number of pitches being trained (Figs. 1B-C; OSM
Table 1).

Pre-post tests

Overall, participants improved in note naming after training as
indicated by an increased proportion of correct responses, reduced
error, and reduced correct RT, with some generalization to the
untrained timbre (Fig. 3). One participant was not included in the RT
analyses because no trial was performed correctly during pre-test
(Fig. 3).

Fig. 3
figure 3

The pre-test and post-test performance for absolute pitch (AP)
naming. The top panel shows performance for proportion correct, size
of error (absolute deviations in semitone), and correct response time
(RT; ms) for the trained timbre for (A-C), and the bottom panel shows
that for the untrained timbre (D-F). The thick black bars show the
group mean of each condition. The dotted lines show the chance levels
of performance in terms of proportion correct and size of error. The
labels of each participant (e.g., S1, S2, etc.) match with the ones
used in the tables and other figures

Full size image

After training, there was a 128.1% increase^Footnote 1 in proportion
correct for the trained timbre (mean[pre] = 0.139; mean[post] =
 0.317), with 10 out of 12 participants showing a numerical
improvement. There was also a 42.7% drop in size of error for the
trained timbre (mean[pre] = 2.62 semitones; mean[post] = 1.50
semitones), with 11 out of 12 participants showing a numerical
improvement. A 2 x 2 analysis of variance (ANOVA) with Prepost
(pre-test/post-test) and Timbre (trained/untrained) as within-subject
factors showed a main effect of Prepost for proportion correct, F
(1,11) = 8.15, p = 0.016, e[p]^2 = 0.426, and for size of error, F
(1,11) = 19.7, p < 0.001, e[p]^2 = 0.642, both indicating a higher
accuracy after training. The main effect of Prepost was close to
significant for correct RT, F(1,10) = 4.32, p = 0.064, e[p]^2 =
 0.302, with a trend of faster responses after training (mean[pre] =
 3,034 ms; mean[post] = 2,624 ms). The main effect of Timbre was
significant for size of error, F(1,11) = 4.97, p = 0.048, e[p]^2 =
 0.311, with a smaller error for the trained (mean = 2.28 semitones)
than untrained (mean = 2.42 semitones) timbre. The interaction
between Prepost and Timbre was significant for proportion correct, F
(1,11) = 7.94, p = 0.017, e[p]^2 = 0.419, and for size of error, F
(1,11) = 11.8, p = 0.006, e[p]^2 = 0.517. Post hoc Tukey tests (p 
< 0.05) revealed that proportion correct was higher during post-test
than pre-test only for the trained timbre but not for the untrained
timbre, while size of error dropped for both timbres but more so for
the trained one.

As shown in Fig. 3, two participants (S1 and S2, non-tonal and tonal
speakers, respectively) performed considerably better than the other
participants during the post-tests for tones in the trained timbre in
terms of proportion correct (0.89 and 0.78, respectively), size of
error (0.42 and 0.31, semitone respectively), and correct RT
(1,586 ms and 1,502 ms, respectively). Results of the above Prepost x
Timbre ANOVAs remained similar after excluding these two participants
(see OSM), indicating that the group training effects were not driven
only by these two participants.

The third participant who completed all training levels showed a low
accuracy and a large error during the post-test (S3 with brown
square; Fig. 3). In the optional written feedback provided to us, he
shared that he tried to listen to the sample tones for reference and
then apply the relative pitch strategy to "legally game the training
system." While relative pitch strategies allowed him to get through
the AP training in a less controlled environment, the complete
absence of reference during the post-test disabled his use of
relative pitch strategies (see Methods) and therefore revealed that
his AP was indeed limited.

Discussion

An 8-week online computerized training program was designed to
address potential methodological issues in previous studies and
clarify the learnability of AP in adulthood. By the end of the
training, participants were able to name 7.08 pitches (range = 3-12
pitches) at an accuracy of 90% or above within a response-time window
of 1,305-2,028 ms. Pre-post tests showed significantly improved
pitch-naming performance, with a 128.1% increase in accuracy (mean
proportion correct from 0.139 to 0.317) and a 42.7% decrease in size
of error (from 2.62 to 1.50 semitones) after training for the trained
timbre, which generalized partially to tones of an untrained timbre.
Two participants passed all training levels and showed highly
accurate and fast AP judgment with all 12 pitches in the post-test
(Figs. 1 and 3), demonstrating that there was no "glass ceiling" for
AP development in adulthood.

Importantly, the performance attained in the current study cannot be
attributed simply to pitch height learning, external references in
one's working memory, luck, or specific cognitive profiles. First,
participants learned to attach the same pitch name to all tones
sharing the same chroma in three octaves, demonstrating that they
learned the chroma of the tones rather than the specific pitch height
of individual tones. Without feedback at any point during the
post-test, no external reference was available in one's working
memory. For participants who passed all the training levels, accurate
and fast AP performance was consistently demonstrated four times in a
row and again during the post-test, indicating stable and replicable
performance that cannot be explained by luck. The lack of cognitive
screening during participant recruitment suggest that the observed AP
learning cannot be explained by specific cognitive profiles.

While there is no known strategy to ensure a complete elimination of
relative pitch strategies (Wong et al., 2020a, 2020b), the current
study adopted stringent measures to minimize their use. This included
large pitch distances between adjacent trials, known to make relative
pitch strategies more difficult to apply (Baharloo et al., 1998;
Carroll, 1975; Deutsch, 1972; Deutsch & Boulanger, 1984; Deutsch et
al., 2006; Miyazaki, 1988, 1989, 1990; Van Hedger et al., 2019), and
achieving speeded correct responses of 1.5-2 s by the two
participants who learned all 12 pitches (OSM Table 1, Fig. 3C). The
RT was achieved using arbitrary mouse-click selections among 12
alternatives and was comparable to that of real-world AP possessors
(Wong et al., 2020a, 2020b; Wong et al., 2020a, 2020b). Combining
these measures minimized the room for internal pitch calculations,
making relative pitch strategies even more implausible than previous
studies that adopted longer response windows (typically 3 s or more)
or more automatized writing responses (e.g., Baharloo et al., 1998;
Deutsch et al., 2006; Van Hedger et al., 2019).

The attained AP performance after training is unlikely to be
explained by pre-existing abilities. The two participants who
acquired accurate and fast AP performance did show higher AP
accuracies than others during pretest (proportion correct = 0.36 and
0.36, size of error = 1.75 and 2.06 semitones for S1 and S2
respectively; Fig. 3). However, individuals with such performance
were rarely considered "AP possessors" because their accuracy was
lower than half of that frequently demonstrated by real-world "AP
possessors" (e.g., Takeuchi & Hulse, 1993). Importantly, it took them
18 and 21 h to complete the training with slow and gradual
improvement (Fig. 1B). Therefore, it is likely that their AP ability
gradually developed during the training.

While the most successful learners in AP training started with
relatively better pretest performance in some studies (e.g., the
current study; Van Hedger et al., 2019), it was not consistently
observed in other training studies (Wong et al., 2020a, 2020b; Wong
et al., 2020a, 2020b). For example, one participant who acquired AP
had a lower pretest accuracy (0%) than the group mean (13.9%; Wong et
al., 2020a, 2020b). Hence there was no evidence suggesting that
pretest performance is an important factor in explaining AP training
success.

The ability to learn fast and accurate AP judgment in adulthood in
all participants, ranging from a few to all 12 pitches, challenges
the widely endorsed notion that the critical period constrains the
development of AP (Baharloo et al., 1998; Deutsch, 2019; Drayna, 2007
; Levitin & Rogers, 2005; Takeuchi & Hulse, 1993; Trainor, 2005;
Zatorre, 2003). The non-tonal speaker who attained fast and accurate
AP performance after training started music training at 24 years of
age (Table 2), indicating that early onset of musical training was
not essential for AP development during adulthood.

The current findings are inconsistent with the core assumption of the
two-component model of AP (Levitin & Rogers, 2005). This cognitive
model explicitly states that most people can perceive tones presented
in isolation and form AP memory well (Schellenberg & Trehub, 2003),
but only a selected few can overcome the difficulty in pitch
labelling, i.e., the ability to associate a verbal label with a
pitch. However, all participants in the current study learned to
quickly and accurately name at least a subset of the pitches, from
7.08 pitches on average to all 12 pitches in two individuals (Fig. 1
C). The continuous distribution found in the current and previous
training studies (Miyazaki & Ogawa, 2006; Wong et al., 2020a, 2020b;
Wong et al., 2020a, 2020b) shows that, apart from perceiving isolated
tones and establishing AP memory, most people can associate verbal
labels with tones in an absolute manner (see also Van Hedger et al.,
2020).

Our findings provided additional evidence that exposure to tonal
languages during early childhood is not an essential condition for
learning AP judgment in adulthood. Non-tonal language speakers, who
have not been exposed to tonal languages before 12 years of age, can
acquire AP judgment with tones in a single octave (Wong et al., 2020a
, 2020b) and with tones in multiple octaves (participant S1 in the
current study). Future studies may directly compare the development
of AP among tonal and non-tonal language speakers to test if previous
exposure to tonal languages, while unnecessary, leads to any
advantages in AP acquisition during training as suggested in previous
work (Deutsch et al., 2004, 2006, 2009).

Since the training was performed with piano tones, it was possible
that pianists might have enjoyed the advantage of timbre familiarity
and therefore had a larger degree of AP improvement. However, the
data did not support this possibility. First, the average improvement
of the non-pianists was numerically larger than that of pianists for
the trained timbre (OSM Table 2). Also, some pianists improved
relatively slowly (e.g., S10), while one of the pianists achieved
fast and accurate AP (S1). The other participant who achieved fast
and accurate AP was a violinist. Overall, there was no evidence
supporting that pianists enjoyed an advantage of learning AP due to
timbre familiarity.

Some researchers may have concerns about the above interpretations of
findings. First, some may question whether the performance of the two
highest-achieving participants after training should be regarded as
"true" AP. In the literature, "true" AP refers to AP that is highly
accurate, fast, effortless, and automatic (Ross et al., 2005;
Takeuchi & Hulse, 1993). This is often considered categorically
different from other forms of AP, for example, "quasi," "partial,"
"implicit," and "pseudo" AP, which generally refer to AP with a lower
accuracy, limited to a subset of pitches, or expressed in terms of
perceptual discriminability rather than explicit labelling (Bachem,
1940; Deutsch, 2002; Takeuchi & Hulse, 1993; Van Hedger et al., 2015;
Ward, 1999; but see Bermudez & Zatorre, 2009; Van Hedger et al., 2020
). Apart from performance level, it was also reported that some
"true" AP possessors can accurately produce, i.e., sing, a tone of a
certain pitch absolutely (Takeuchi & Hulse, 1993), and others can
better differentiate between tuned and mistuned tones (Ross et al.,
2005). Hence, the key question underlying this concern is how "true"
AP is defined.

Importantly, the literature does not have any consensus about what
performance level "true" AP represents, and many studies simply
relied on self-report to categorize participants as "true" AP (see
discussion in Bermudez & Zatorre, 2009; Wong et al., 2020a, 2020b).
Notably, the two highest-achieving participants in the current study,
based on the accuracy and speed of their AP judgment, would be
categorized as "true" AP in more than 80% of the published papers
that adopted an objective performance-based definition of AP (Wong et
al., 2020a, 2020b). Given that it is representative in the literature
to consider these two participants "true" AP, researchers who
question the appropriateness of this interpretation should explicitly
define the alternative level of performance for defining "true" AP,
justify why this definition is more appropriate, and explain why the
performance observed here should still be considered categorically
different from such defined "true" AP.

Other researchers might agree that the two highest-achieving
participants had a comparable performance with that of "true" AP, but
regard them as outliers and therefore their achievements were not
representative of the feasible development of AP in the population.
This concern might stem from two different reasons. First, from the
perspective that AP is dichotomous (Athos et al., 2007), these two
participants had above-chance performance during the pretest
(proportion correct = 0.36 and 0.36, size of error = 1.75 and 2.06
semitones for S1 and S2, respectively), which did not fit into either
the "all" or "none" categories of AP (Fig. 3). Hence, they might
simply be outliers and not representative of the population. However,
the dichotomous view has been challenged by empirical findings that
showed a considerable number of musicians with an above-chance
performance similar to that of these two participants but far from
that of "true" AP (Bermudez & Zatorre, 2009; Van Hedger et al., 2020;
Vanzella & Schellenberg, 2010). Therefore, cases like these should
not be disregarded simply because they do not fall into either the
"all" or "none" category of AP ability.

Another reason to consider these two participants as outliers comes
from the perspective that the critical period represents "a central
tendency, an average age at which individuals pass through a
particular developmental stage" (p.106, Levitin & Zatorre, 2003).
Accordingly, the rare individuals (i.e., outliers) who could learn AP
beyond the critical period are well expected purely on statistical
ground. Notably though, on average 14.7% of participants (range =
 10.0-18.1%), i.e., about one in seven, were able to learn to name
all 12 pitches after training (the current study; Wong et al., 2020a,
2020b; Wong et al., 2020a, 2020b). Also, some participants may have
been able to name all pitches accurately had the AP training lasted
for longer (e.g., those who acquired naming for 10 or 11 pitches).
These participants are too many to be considered outliers. Also, the
above description of the critical period (Levitin & Zatorre, 2003)
deviates from its typical definition that considers early experience
essential for normal development (Knudsen, 2004). Music experience in
early life does relate to a higher tendency of AP development
(Gregersen et al., 1999), but this is more consistent with the
concept of a "sensitive period," which states that experience has a
particularly strong effect during early life but the psychological
function concerned remains plastic throughout the lifespan (Hooks &
Chen, 2007; Sengpiel, 2007). Under this definition, acquiring "true"
AP in adulthood should well be possible, albeit more difficult. Adult
AP training studies like the current one (Wong et al., 2020a, 2020b;
Wong et al., 2020a, 2020b) often involved a much shorter training
period than those with young children. For example, children took
6 weeks to learn AP for one pitch (Crozier, 1997), and they took
1.5-3 years to learn all pitches (Miyazaki & Ogawa, 2006; Sakakibara,
2014). Whether a sensitive period of AP development exists should be
clarified by matched methods and measurements of AP learning between
young children and adults.

Data availability

The datasets analyzed in the current study are available on the Open
Science Framework repository at: https://osf.io/jfz35/?view_only=
4d3861ed0aef461082d88cce5347c1d3

Code availability

The codes used in this study were not available to the public.

Notes

 1. The change in percentage was calculated by the equation [mean
    [post]--mean[pre] / mean[pre]].

References

  * Athos, E. A., Levinson, B., Kistler, A., Zemansky, J., Bostrom,
    A., Freimer, N., & Gitschier, J. (2007). Dichotomy and perceptual
    distortions in absolute pitch ability. Proceedings of the
    National Academy of Sciences of the United States of America, 104
    (37), 14795-14800. https://doi.org/10.1073/pnas.0703868104

    Article  PubMed  PubMed Central  Google Scholar 

  * Bachem, A. (1940). The Genesis of Absolute Pitch. The Journal of
    the Acoustical Society of America, 11, 434-434. https://doi.org/
    10.1121/1.1916056

    Article  Google Scholar 

  * Bachem, A. (1955). Absolute Pitch. The Journal of the Acoustical
    Society of America, 27(6), 1180-1185. https://doi.org/10.1121/
    1.1908155

    Article  Google Scholar 

  * Baharloo, S., Johnston, P. a., Service, S. K., Gitschier, J., &
    Freimer, N. B. (1998). Absolute pitch: An approach for
    identification of genetic and nongenetic components. American
    Journal of Human Genetics, 62(2), 224-231. https://doi.org/
    10.1086/301704

    Article  PubMed  Google Scholar 

  * Baharloo, S., Service, S. K., Risch, N., Gitschier, J., &
    Freimer, N. B. (2000). Familial Aggregation of Absolute Pitch.
    The American Journal of Human Genetics, 67(3), 755-758. https://
    doi.org/10.1086/303057

    Article  PubMed  Google Scholar 

  * Bermudez, P., & Zatorre, R. J. (2009). A Distribution of Absolute
    Pitch Ability as Revealed by Computerized Testing. Music
    Perception, 27(2), 89-101. https://doi.org/10.1525/
    mp.2009.27.2.89

    Article  Google Scholar 

  * Carroll, J. B. (1975). SPEED AND ACCURACY OF ABSOLUTE PITCH
    JUDGMENTS: SOME LATTER-DAY RESULTS. ETS Research Bulletin Series,
    1975(2), i-71. https://doi.org/10.1002/j.2333-8504.1975.tb01075.x

    Article  Google Scholar 

  * Chin, C. S. (2003). The Development of Absolute Pitch: A Theory
    Concerning the Roles of Music Training at an Early Developmental
    Age and Individual Cognitive Style. Psychology of Music, 31(2),
    155-171. https://doi.org/10.1177/0305735603031002292

    Article  Google Scholar 

  * Crozier, J. B. (1997). Absolute Pitch: Practice Makes Perfect,
    the Earlier the Better. In Psychology of Music (Vol. 25, pp.
    110-119).

  * Deutsch, D. (1972). Octave generalization and tune recognition.
    Perception & Psychophysics, 11(6), 411-412. https://doi.org/
    10.3758/BF03206280

    Article  Google Scholar 

  * Deutsch, D. (2002). The puzzle of absolute pitch. Current
    Directions in Psychological Science, 11(6), 200-204.

    Article  Google Scholar 

  * Deutsch, D. (2019). The Mystery of Absolute Pitch. In Musical
    Illusions and Phantom Words (pp. 82-102). Oxford University
    Press. https://doi.org/10.1093/oso/9780190206833.003.0007

  * Deutsch, D., & Boulanger, R. C. (1984). Octave Equivalence and
    the Immediate Recall of Pitch Sequences. Music Perception, 2(1),
    40-51. https://doi.org/10.2307/40285281

    Article  Google Scholar 

  * Deutsch, D., Dooley, K., Henthorn, T., & Head, B. (2009).
    Absolute pitch among students in an American music conservatory:
    Association with tone language fluency. The Journal of the
    Acoustical Society of America, 125(4), 2398-2403. https://doi.org
    /10.1121/1.3081389

    Article  PubMed  Google Scholar 

  * Deutsch, D., Henthorn, T., & Dolson, M. (2004). Absolute Pitch,
    Speech, and Tone Language: Some Experiments and a Proposed
    Framework. Music Perception, 21(3), 339-356. https://doi.org/
    10.1525/mp.2004.21.3.339

    Article  Google Scholar 

  * Deutsch, D., Henthorn, T., Marvin, E., & Xu, H. (2006). Absolute
    pitch among American and Chinese conservatory students:
    Prevalence differences, and evidence for a speech-related
    critical period. The Journal of the Acoustical Society of
    America, 119(2), 719-719. https://doi.org/10.1121/1.2151799

    Article  PubMed  Google Scholar 

  * Drayna, D. (2007). Absolute pitch: A special group of ears.
    Proceedings of the National Academy of Sciences of the United
    States of America, 104(37), 14549-14550. https://doi.org/10.1073/
    pnas.0707287104

    Article  PubMed  PubMed Central  Google Scholar 

  * Gregersen, P. K., Kowalsky, E., Kohn, N., & Marvin, E. W. (1999).
    Absolute Pitch: Prevalence, Ethnic Variation, and Estimation of
    the Genetic Component. The American Journal of Human Genetics, 65
    (3), 911-913. https://doi.org/10.1086/302541

    Article  PubMed  Google Scholar 

  * Gregersen, P. K., Kowalsky, E., Kohn, N., & Marvin, E. W. (2001).
    Early childhood music education and predisposition to absolute
    pitch: Teasing apart genes and environment. American Journal of
    Medical Genetics, 98(3), 280-282. https://doi.org/10.1002/
    1096-8628(20010122)98:3%3c280::AID-AJMG1083%3e3.0.CO;2-6

    Article  PubMed  Google Scholar 

  * Hooks, B. M., & Chen, C. (2007). Critical Periods in the Visual
    System: Changing Views for a Model of Experience-Dependent
    Plasticity. Neuron, 56(2), 312-326. https://doi.org/10.1016/
    j.neuron.2007.10.003

    Article  PubMed  Google Scholar 

  * Knudsen, E. I. (2004). Sensitive Periods in the Development of
    the Brain and Behavior. Journal of Cognitive Neuroscience, 16(8),
    1412-1425. https://doi.org/10.1162/0898929042304796

    Article  PubMed  Google Scholar 

  * Levitin, D. J., & Rogers, S. E. (2005). Absolute pitch:
    Perception, coding, and controversies. Trends in Cognitive
    Sciences, 9(1), 26-33. https://doi.org/10.1016/j.tics.2004.11.007

    Article  PubMed  Google Scholar 

  * Levitin, D. J., & Zatorre, R. J. (2003). On the nature of early
    music training and absolute pitch: A reply to Brown, Sachs,
    Cammuso, and Folstein. Music Perception, 21(1), 105-110.

    Article  Google Scholar 

  * Miyazaki, K. (1988). Musical pitch identification by absolute
    pitch possessors. Perception & Psychophysics, 44(6), 501-512.
    http://www.ncbi.nlm.nih.gov/pubmed/3200669

  * Miyazaki, K. (1989). Absolute pitch identification: Effects of
    timbre and pitch region. Music Perception, 7, 1-14.

    Article  Google Scholar 

  * Miyazaki, K. (1990). The Speed of Musical Pitch Identification
    Possessors by Absolute-Pitch Possessors. Music Perception, 8(2),
    177-188. https://doi.org/10.2307/40285495

    Article  Google Scholar 

  * Miyazaki, K., Makomaska, S., & Rakowski, A. (2012). Prevalence of
    absolute pitch: A comparison between Japanese and Polish music
    students. The Journal of the Acoustical Society of America, 132
    (5), 3484-3493.

    Article  PubMed  Google Scholar 

  * Miyazaki, K., & Ogawa, Y. (2006). Learning Absolute Pitch by
    Children. In Music Perception (Vol. 24, pp. 63-78).

  * Peterson, L. R., & Peterson, M. J. (1959). Short-term retention
    of individual items. Journal of Experimental Psychology, 61,
    12-21.

    Google Scholar 

  * Ross, D., & a., Gore, J. C., & Marks, L. E. (2005). Absolute
    pitch: Music and beyond. Epilepsy & Behavior : E&b, 7(4),
    578-601. https://doi.org/10.1016/j.yebeh.2005.05.019

    Article  Google Scholar 

  * Sakakibara, A. (2014). A longitudinal study of the process of
    acquiring absolute pitch: A practical report of training with the
    "chord identification method." Psychology of Music, 42(1),
    86-111. https://doi.org/10.1177/0305735612463948

    Article  Google Scholar 

  * Schellenberg, E. G., & Trehub, S. E. (2003). Good pitch memory is
    widespread. Psychological Science, 14(3), 262-266. http://
    www.ncbi.nlm.nih.gov/pubmed/12741751

  * Sengpiel, F. (2007). The critical period. Current Biology, 17
    (17), R742-R743. https://doi.org/10.1016/j.cub.2007.06.017

    Article  PubMed  Google Scholar 

  * Takeuchi, a. H., & Hulse, S. H. (1993). Absolute pitch.
    Psychological Bulletin, 113(2), 345-361. http://
    www.ncbi.nlm.nih.gov/pubmed/8451339

  * Talamini, F., Blain, S., Ginzburg, J., Houix, O., Bouchet, P.,
    Grassi, M., Tillmann, B., & Caclin, A. (2022). Auditory and
    visual short-term memory: Influence of material type, contour,
    and musical expertise. Psychological Research Psychologische
    Forschung, 86(2), 421-442. https://doi.org/10.1007/
    s00426-021-01519-0

    Article  PubMed  Google Scholar 

  * Trainor, L. J. (2005). Are there critical periods for musical
    development? Developmental Psychobiology, 46(3), 262-278. https:/
    /doi.org/10.1002/dev.20059

    Article  PubMed  Google Scholar 

  * Van Hedger, S. C., Heald, S. L. M., Koch, R., & Nusbaum, H. C.
    (2015). Auditory working memory predicts individual differences
    in absolute pitch learning. Cognition, 140, 95-110. https://
    doi.org/10.1016/j.cognition.2015.03.012

    Article  PubMed  Google Scholar 

  * Van Hedger, S. C., Heald, S. L. M., & Nusbaum, H. C. (2019).
    Absolute pitch can be learned by some adults. PLoS ONE, 14(9),
    e0223047-e0223047. https://doi.org/10.1371/journal.pone.0223047

    Article  PubMed  PubMed Central  Google Scholar 

  * Van Hedger, S. C., Veillette, J., Heald, S. L. M., & Nusbaum, H.
    C. (2020). Revisiting discrete versus continuous models of human
    behavior: The case of absolute pitch. PLoS ONE, 15(12), e0244308.
    https://doi.org/10.1371/journal.pone.0244308

    Article  PubMed  PubMed Central  Google Scholar 

  * Vanzella, P., & Schellenberg, E. G. (2010). Absolute pitch:
    Effects of timbre on note-naming ability. PLoS ONE, 5(11),
    e15449-e15449. https://doi.org/10.1371/journal.pone.0015449

    Article  PubMed  PubMed Central  Google Scholar 

  * Ward, W. D. (1999). Absolute Pitch. In D. Deutsch (Ed.), The
    Psychology of Music (pp. 265-298). Academic Press.

    Chapter  Google Scholar 

  * Wengenroth, M., Blatow, M., Heinecke, A., Reinhardt, J.,
    Stippich, C., Hofmann, E., & Schneider, P. (2013). Increased
    Volume and Function of Right Auditory Cortex as a Marker for
    Absolute Pitch. Cerebral Cortex, 24(May), 1127-1137. https://
    doi.org/10.1093/cercor/bhs391

    Article  PubMed  Google Scholar 

  * Wong, Y. K., Lui, K. F. H., Yip, K. H. M., & Wong, A. C. N.
    (2020a). Is it impossible to acquire absolute pitch in adulthood?
    Attention, Perception, & Psychophysics, 82(3), 1407-1430. https:/
    /doi.org/10.3758/s13414-019-01869-3

    Article  Google Scholar 

  * Wong, Y. K., Ngan, V. S. H., Cheung, L. Y. T., & Wong, A. C. N.
    (2020b). Absolute pitch learning in adults speaking non-tonal
    languages. Quarterly Journal of Experimental Psychology, 73(11),
    1908-1920. https://doi.org/10.1177/1747021820935776

    Article  Google Scholar 

  * Zatorre, R. J. (2003). Absolute pitch: A model for understanding
    the influence of genes and development on neural and cognitive
    function. Nature Neuroscience, 6(7), 692-695. https://doi.org/
    10.1038/nn1085

    Article  PubMed  Google Scholar 

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Acknowledgements

We would like to thank Sophie Mok and Anson Wong for their help with
data collection.

Funding

The research received no specific grants from any funding agency in
the public, commercial, or non-for-profit sectors.

Author information

Authors and Affiliations

 1. School of Psychology, University of Surrey, 43AC05, Lewis Carroll
    Building, Guildford, Surrey, GU2 7XH, UK

    Yetta Kwailing Wong & Alan C.-N. Wong

 2. Institute for Sustainability, University of Surrey, Guildford, UK

    Yetta Kwailing Wong & Alan C.-N. Wong

 3. Department of Educational Psychology, The Chinese University of
    Hong Kong, Ma Liu Shui, Hong Kong

    Leo Y. T. Cheung

 4. Department of Psychology, The Chinese University of Hong Kong, Ma
    Liu Shui, Hong Kong

    Vince S. H. Ngan

 5. Surrey Institute for People-Centered AI, University of Surrey,
    Guildford, UK

    Alan C.-N. Wong

Authors

 1. Yetta Kwailing Wong
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 4. Alan C.-N. Wong
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Contributions

YW and AW: conceptualization, design, and manuscript writeup.

YW: data collection and analysis. LC: programming and manuscript
editing. VN: data collection and manuscript editing.

Corresponding authors

Correspondence to Yetta Kwailing Wong or Alan C.-N. Wong.

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The authors declare no potential conflicts or competing interest in
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Ethics approval and consent to participate

All participants provided informed consent, with all methods
(including experimental protocols) approved and performed according
to the guideline of the Survey and Behavioral Research Ethics
Committee of the Chinese University of Hong Kong in accordance with
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Wong, Y.K., Cheung, L.Y.T., Ngan, V.S.H. et al. Learning fast and
accurate absolute pitch judgment in adulthood. Psychon Bull Rev
(2025). https://doi.org/10.3758/s13423-024-02620-2

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  * Accepted: 03 November 2024

  * Published: 12 February 2025

  * DOI: https://doi.org/10.3758/s13423-024-02620-2

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Keywords

  * Music cognition
  * Sound recognition
  * Perceptual learning
  * Perceptual expertise
  * Critical period

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