Aspects of the present invention provide an approach for dynamically optimizing a beat. In an embodiment, a current movement rate and biometric data for each user in a group performing a physical activity are collected. An upcoming movement rate for each user is predicted based on the collected current movement rates and biometric data. Music having an optimized beat is then generated based on a lowest upcoming movement rate among the predicted upcoming movement rates.

A restorative musical system having a musical composition, which has a plurality of audio elements, a start and an end, and a slow tempo. The plurality of audio elements having a phrase, a plurality of arrangements, a pulsating sound, and a field recording element. The phrase and the pulsating sound adapted to repeat within the musical composition, while the plurality of arrangements is adapted to be introduced in succession. Additionally, the plurality of audio elements is audio mixed to play at a solfeggio frequency and are adapted to cause stereo imaging.

The present invention relates to a method and system for analysing audio (eg. music) tracks. A predictive model of the neuro-physiological functioning and response to sounds by one or more of the human lower cortical, limbic and subcortical regions in the brain is described. Sounds are analysed so that appropriate sounds can be selected and played to a listener in order to stimulate and/or manipulate neuro-physiological arousal in that listener. The method and system are particularly applicable to applications harnessing a biofeedback resource.

The present invention discloses a method and system of providing a real time audification of neonatal EEG signals. The method comprises the steps of: receiving preprocessed neonatal EEG signals; changing a characteristic of the preprocessed signals in a phase vocoder; resampling the output signals from the vocoder to a predetermined audio frequency range; converting the resampled signals into stereo signals; and selecting a plurality of channels from the stereo signals as the output audio signals.

An immersive device may include a floor reflective mirrored surface, a first wall reflective mirrored surface, a second wall reflective mirrored surface, a third wall reflective mirrored surface, a fourth wall reflective mirrored surface, and a ceiling reflective mirrored surface. The reflective mirrored surfaces may form a perimeter of and bound the reflective chamber. One or more light emitting elements may be configured to emit light into the reflective chamber. A processing unit may be in electrical communication with the light emitting elements. A sound device may be in communication with the processing unit, and the sound device may be configured to output sound to a user within the reflective chamber. An array of sensors, such as: digital camera, microphone, and electrophysiological monitoring devices that may be in communication with the processing unit, and are configured to change the experience of the user within the chamber depending upon the signals from the sensors on the user.

A method for layering and mixing monaural beats to help sleep is proposed. In the method for layering and mixing the monaural beats, a plurality of monaural beats is mixed and output in a waveform to help sleep, so as to generate a plurality of monaural beats by loading a plurality of pieces of frequency data according to a selected brain wave waveform, adjust decibels of the plurality of monaural beats, and generate one analog wave file by mixing the plurality of adjusted monaural beats, whereby brainwave entrainment may be further improved and performed in a short time.

The present invention relates to a method and system for analysing audio (eg. music) tracks. A predictive model of the neuro-physiological functioning and response to sounds by one or more of the human lower cortical, limbic and subcortical regions in the brain is described. Sounds are analysed so that appropriate sounds can be selected and played to a listener in order to stimulate and/or manipulate neuro-physiological arousal in that listener. The method and system are particularly applicable to applications harnessing a biofeedback resource.

The invention relates to a system for automatically creating a soundtrack, comprising a camera device (1, 1) for recording a user-generated video, at least one wearable sensor (3, 3), and a control unit (2, 2) in communication with the camera device (1, 1) and the at least one wearable sensor (3, 3). The control unit (2, 2) is adapted to generate the soundtrack based on data gathered from the at least one wearable sensor (3, 3) during the recording of the user-generated video. The invention further relates to a method for automatically creating a soundtrack, computer program product, a computer readable memory storage unit computing arrangement or mobile device (1, 11) for executing the method.

An immersive device may include a floor reflective mirrored surface, a first wall reflective mirrored surface, a second wall reflective mirrored surface, a third wall reflective mirrored surface, a fourth wall reflective mirrored surface, and a ceiling reflective mirrored surface. The reflective mirrored surfaces may form a perimeter of and bound the reflective chamber. One or more light emitting elements may be configured to emit light into the reflective chamber. A processing unit may be in electrical communication with the light emitting elements. A sound device may be in communication with the processing unit, and the sound device may be configured to output sound to a user within the reflective chamber. An electrophysiological monitoring device may be in communication with the processing unit, and the electrophysiological monitoring device may be configured to record electrical activity of a body of the user.

An immersive device may include a floor reflective mirrored surface, a first wall reflective mirrored surface, a second wall reflective mirrored surface, a third wall reflective mirrored surface, a fourth wall reflective mirrored surface, and a ceiling reflective mirrored surface. The reflective mirrored surfaces may form a perimeter of and bound the reflective chamber. One or more light emitting elements may be configured to emit light into the reflective chamber. A processing unit may be in electrical communication with the light emitting elements. A sound device may be in communication with the processing unit, and the sound device may be configured to output sound to a user within the reflective chamber. An array of sensors, such as: digital camera, microphone, and electrophysiological monitoring devices that may be in communication with the processing unit, and are configured to change the experience of the user within the chamber depending upon the signals from the sensors on the user.