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The Path to Audiating Harmony Clearly... Experience 8 Breakthroughs
👉 Get the Free Supplement: https://www.uremusic.com/audiation-inner-ear-training-for-musicians
Most musicians can hear harmony, but actually holding it in your mind? That’s where almost everyone struggles.
Experience 8 science-backed breakthroughs that will transform the way you audiate harmony.
What You’ll Learn:
👉 Why harmony collapses in your mind (and how to fix it)
👉 Breakthrough exercises to strengthen your auditory working memory
👉 The science behind audiation and predictive coding
👉 How to train your brain to hold chords, intervals, and moving lines—internally
👉 Real-time tests and interactive chat prompts
👉 If you’ve ever felt lost when harmony gets complex, this is your path forward.
👇 Type YES in the chat if harmony turns to mush when you try to hear it internally!
Timestamps:
00:00 Why Harmony Collapses
00:31 The Silent Note Test (Breakthrough 1)
01:42 The Vanishing Tone Breakthrough 2)
03:26 Audiation is Not Just Memory
04:02 The First Internal Chord (Breakthrough 3)
05:30 Audiation is Not Recall
06:26 Contrary Motion Stability (Breakthrough 4)
07:45 Auditing Harmony Isn't Possible
08:24 Hearing an Internal Chord (Breakthrough 5)
11:43 Tonotopic Path
13:17 Solfège Systems
15:49 Contrary Motion Stability (Breakthrough 6)
17:35 The Internal Bassline (Breakthrough 7)
19:53 Internal Modulation (Breakthrough 8)
21:20 Instant Ear Training Fixes
22:24 The Internal Cadence (Bonus Breakthrough 1)
23:41 Melody over Harmony (Bonus Breakthrough 2)
24:34 An Audiation Path That Works
🔬 Science References & Clarifications
This training is grounded in established auditory neuroscience and cognitive science research. The terminology used in the video is pedagogical—designed to make complex internal listening skills trainable—rather than a direct copy of academic labels. The cited research supports the underlying neural mechanisms involved in audiation: sustained auditory representations, predictive processing, and multi-stream auditory tracking.
Below are the scientific foundations referenced in the video, with brief clarifications on how each applies:
🧠Auditory Working Memory
Kumar et al. (2016). A Brain System for Auditory Working Memory. Journal of Neuroscience.
Auditory working memory relies on sustained cortical activity that persists after a sound ends. The “hold the tone” exercises engage these mechanisms, showing natural decay limits when internal sound isn’t yet stabilized.
⚡ Stable Neural Firing
Ulanovsky et al. (2003). Processing of low-probability sounds by cortical neurons. Nature Neuroscience.
Auditory representations persist only when neural firing patterns remain stable. Destabilized firing causes internal sound traces to collapse. This stability-versus-decay property is a core audiation challenge.
🎶 Auditory Cortex
Zatorre, Belin, & Penhune (2002). Structure and function of auditory cortex. Trends in Cognitive Sciences.
The auditory cortex is central to pitch, timbre, harmony, and musical imagery. When external sound disappears, unsupported tones are often dropped unless actively maintained.
🔄 Predictive Coding
Friston (2005). A theory of cortical responses. Philosophical Transactions of the Royal Society B.
The brain predicts sensory input and updates internal models when predictions fail. In music, this explains why “missing” notes collapse without a strong predictive framework—and why trained audiation feels stable.
🎼 Two-Tone Predictive Model
McLachlan & Wilson (2010). The central role of the auditory cortex in musical memory and perception. Frontiers in Psychology.
While the term is pedagogical, the mechanism is established: the auditory cortex encodes relational pitch information. Stabilizing intervals is foundational for harmonic audiation.
🛤️ Dorsal Auditory Stream
Rauschecker & Scott (2009). Maps and streams in the auditory cortex. Nature Neuroscience.
The dorsal auditory stream supports sequential and motion-based sound processing. Struggling to hold a moving line internally reflects load on these tracking mechanisms.
🗺️ Tonotopic Map
Formisano et al. (2003). Mirror-symmetric tonotopic maps in human auditory cortex. Neuron.
Different frequencies activate distinct regions of the auditory cortex. Holding multiple tones increases representational load, which is why internal chords often flicker without training.
đź’ˇ Neural Efficiency
Neubauer & Fink (2009). Intelligence and neural efficiency. Neuroscience & Biobehavioral Reviews.
Stable representations require fewer resources and persist longer. Unstable internal sounds fade more quickly.
🔀 Dual-Stream Tracking
Alain & Arnott (2000). Selectively attending to auditory objects. Frontiers in Bioscience.
The brain can track multiple auditory objects at once. Contrary motion and multi-voice harmony demand this system, which strengthens with training.
🔊 Subcortical Pitch Pathway
Bidelman & Krishnan (2011). Subcortical encoding of behaviorally relevant pitch cues. Journal of Neuroscience.
View all episodes
By Kevin Ure👉 Get the Free Supplement: https://www.uremusic.com/audiation-inner-ear-training-for-musicians
Most musicians can hear harmony, but actually holding it in your mind? That’s where almost everyone struggles.
Experience 8 science-backed breakthroughs that will transform the way you audiate harmony.
What You’ll Learn:
👉 Why harmony collapses in your mind (and how to fix it)
👉 Breakthrough exercises to strengthen your auditory working memory
👉 The science behind audiation and predictive coding
👉 How to train your brain to hold chords, intervals, and moving lines—internally
👉 Real-time tests and interactive chat prompts
👉 If you’ve ever felt lost when harmony gets complex, this is your path forward.
👇 Type YES in the chat if harmony turns to mush when you try to hear it internally!
Timestamps:
00:00 Why Harmony Collapses
00:31 The Silent Note Test (Breakthrough 1)
01:42 The Vanishing Tone Breakthrough 2)
03:26 Audiation is Not Just Memory
04:02 The First Internal Chord (Breakthrough 3)
05:30 Audiation is Not Recall
06:26 Contrary Motion Stability (Breakthrough 4)
07:45 Auditing Harmony Isn't Possible
08:24 Hearing an Internal Chord (Breakthrough 5)
11:43 Tonotopic Path
13:17 Solfège Systems
15:49 Contrary Motion Stability (Breakthrough 6)
17:35 The Internal Bassline (Breakthrough 7)
19:53 Internal Modulation (Breakthrough 8)
21:20 Instant Ear Training Fixes
22:24 The Internal Cadence (Bonus Breakthrough 1)
23:41 Melody over Harmony (Bonus Breakthrough 2)
24:34 An Audiation Path That Works
🔬 Science References & Clarifications
This training is grounded in established auditory neuroscience and cognitive science research. The terminology used in the video is pedagogical—designed to make complex internal listening skills trainable—rather than a direct copy of academic labels. The cited research supports the underlying neural mechanisms involved in audiation: sustained auditory representations, predictive processing, and multi-stream auditory tracking.
Below are the scientific foundations referenced in the video, with brief clarifications on how each applies:
🧠Auditory Working Memory
Kumar et al. (2016). A Brain System for Auditory Working Memory. Journal of Neuroscience.
Auditory working memory relies on sustained cortical activity that persists after a sound ends. The “hold the tone” exercises engage these mechanisms, showing natural decay limits when internal sound isn’t yet stabilized.
⚡ Stable Neural Firing
Ulanovsky et al. (2003). Processing of low-probability sounds by cortical neurons. Nature Neuroscience.
Auditory representations persist only when neural firing patterns remain stable. Destabilized firing causes internal sound traces to collapse. This stability-versus-decay property is a core audiation challenge.
🎶 Auditory Cortex
Zatorre, Belin, & Penhune (2002). Structure and function of auditory cortex. Trends in Cognitive Sciences.
The auditory cortex is central to pitch, timbre, harmony, and musical imagery. When external sound disappears, unsupported tones are often dropped unless actively maintained.
🔄 Predictive Coding
Friston (2005). A theory of cortical responses. Philosophical Transactions of the Royal Society B.
The brain predicts sensory input and updates internal models when predictions fail. In music, this explains why “missing” notes collapse without a strong predictive framework—and why trained audiation feels stable.
🎼 Two-Tone Predictive Model
McLachlan & Wilson (2010). The central role of the auditory cortex in musical memory and perception. Frontiers in Psychology.
While the term is pedagogical, the mechanism is established: the auditory cortex encodes relational pitch information. Stabilizing intervals is foundational for harmonic audiation.
🛤️ Dorsal Auditory Stream
Rauschecker & Scott (2009). Maps and streams in the auditory cortex. Nature Neuroscience.
The dorsal auditory stream supports sequential and motion-based sound processing. Struggling to hold a moving line internally reflects load on these tracking mechanisms.
🗺️ Tonotopic Map
Formisano et al. (2003). Mirror-symmetric tonotopic maps in human auditory cortex. Neuron.
Different frequencies activate distinct regions of the auditory cortex. Holding multiple tones increases representational load, which is why internal chords often flicker without training.
đź’ˇ Neural Efficiency
Neubauer & Fink (2009). Intelligence and neural efficiency. Neuroscience & Biobehavioral Reviews.
Stable representations require fewer resources and persist longer. Unstable internal sounds fade more quickly.
🔀 Dual-Stream Tracking
Alain & Arnott (2000). Selectively attending to auditory objects. Frontiers in Bioscience.
The brain can track multiple auditory objects at once. Contrary motion and multi-voice harmony demand this system, which strengthens with training.
🔊 Subcortical Pitch Pathway
Bidelman & Krishnan (2011). Subcortical encoding of behaviorally relevant pitch cues. Journal of Neuroscience.