A system that assists acupuncture based on the physiological signals of the human body. Physiological signals comprise respiratory signals, electrocardiographic signals, electrical skin signals, electroencephalograph signal, blood flow signals, pulse wave signals and/or signals derived from above signals. The acupuncture treatment process comprises the following: controlling the actuator of the automatic acupuncture device through physiological signals to start, to stop acupuncture treatment or to perform acupuncture techniques such as twisting or lifting-thrusting. It also provides an automatic acupuncture system to assist acupuncture based on Chinese Medicine Body Clock information.

Environmental characteristics of habitable environments (e.g., hotel or motel rooms, spas, resorts, cruise boat cabins, offices, hospitals and/or homes, apartments or residences) are controlled to eliminate, reduce or ameliorate adverse or harmful aspects and introduce, increase or enhance beneficial aspects in order to improve a “wellness” or sense of “wellbeing” provided via the environments. Control of intensity and wavelength distribution of passive and active Illumination addresses various issues, symptoms or syndromes, for instance to maintain a circadian rhythm or cycle, adjust for “jet lag” or season affective disorder, etc. Air quality and attributes are controlled. Scent(s) may be dispersed. Hypoallergenic items (e.g., bedding, linens) may be used. Water quality is controlled. Noise is reduced and sounds (e.g., masking, music, natural) may be provided. Passive and active pathogen controls are employed. Controls are provided for the occupant and/or facility personnel, as is instruction, and surveys, including assessing wellness.

Typically, high NREM stage N3 sleep detection accuracy is achieved using a frontal electrode referenced to an electrode at a distant location on the head (e.g., the mastoid, or the earlobe). For comfort and design considerations it is more convenient to have active and reference electrodes closely positioned on the frontal region of the head. This configuration, however, significantly attenuates the signal, which degrades sleep stage detection (e.g., N3) performance. The present disclosure describes a deep neural network (DNN) based solution developed to detect sleep using frontal electrodes only. N3 detection is enhanced through post-processing of the soft DNN outputs. Detection of slow-waves and sleep micro-arousals is accomplished using frequency domain thresholds. Volume modulation uses a high-frequency/low-frequency spectral ratio extracted from the frontal signal.

Methods, systems and devices that provide a therapeutic solution to alleviate the pain and discomfort of phantom limb syndrome are disclosed. The methods and systems of the present invention generally comprise capturing data from recording devices operably coupled to a processor and/or computing device, the recording devices configured to capture data associated with intact portions of a missing limb, one or more intact limbs and/or portions of the environment surrounding the missing limb, identifying the data captured, generating a three-dimensional virtual image of the missing limb and the surrounding environment from the data captured, and displaying the three-dimensional virtual image and the portions of the surrounding environment to the amputee such that the missing limb appears intact. The present invention advantageously provides a therapeutic and more immediate solution to alleviate the pain and discomfort from phantom limb syndrome.

A plush toy is provided. The plush toy includes a head attached to a body having two leg-like appendages. The toy has an opening leading to a first pocket located inside the body. The first pocket is interconnected to a second pocket located inside the head. The opening to the second pocket at the intersection of the head and body can be closed with a hook-and-look type fastener. The second pocket is sized and configured to contain a sensory stimulus module capable of playing music, vibrating, and emitting white noise at different volumes to sooth a child. When inserted inside the second pocket, buttons on the module are aligned with indicia on the posterior side of the head which permit a user to press through the fabric to activate and control the module. A teether in the shape of hugging arms is attached to the toy and provides teething relief and enjoyment for the child.

A sleep improvement system includes a lifestyle pattern generator configured to generate a lifestyle pattern from at least one of sleep information about sleep of a user, lifestyle information about the user, and living condition information about the user.

Environmental characteristics or scenes of habitable environments (e.g., hotel or motel rooms, spas, resorts, cruise boat cabins, offices, hospitals and/or homes, apartments or residences, or other spaces or sub-spaces) are controlled to facilitate certain activities of a user in the environment by increasing focus, preparing for sleep, directing movement, masking ambient noise, and improving air quality, among others. Controllable characteristics include, for example, lighting, CO.sub.2/O.sub.2 levels, humidity levels, sound, aroma, and air temperature. Controls are provided for the occupant and/or facility personnel to select activities or scenes, or sensors detect the activity and implement an appropriate scene.

A sensor is configured for measuring skin conductance. An amplifier is used to convert the skin conductance into an analog output voltage which is then converted into the digital domain by an analog-to-digital converter, so that an increase in the tonic skin conductance and the phasic skin conductance response are obtained in the digital domain. The amplifier has a non-linear logarithmic gain, with a decreasing gain for increasing skin conductance values. The sensor enables detection of increases in both tonic and phasic signals over a wide range of skin conductance. This allows the use of a lower resolution, and therefore lower cost, analog-to-digital converter.

Methods, systems and devices that provide a therapeutic solution to alleviate the pain and discomfort of phantom limb syndrome are disclosed. The methods and systems of the present invention generally comprise capturing data from recording devices operably coupled to a processor and/or computing device, the recording devices configured to capture data associated with intact portions of a missing limb, one or more intact limbs and/or portions of the environment surrounding the missing limb, identifying the data captured, generating a three-dimensional virtual image of the missing limb and the surrounding environment from the data captured, and displaying the three-dimensional virtual image and the portions of the surrounding environment to the amputee such that the missing limb appears intact. The present invention advantageously provides a therapeutic and more immediate solution to alleviate the pain and discomfort from phantom limb syndrome.

Environmental characteristics or scenes of habitable environments (e.g., hotel or motel rooms, spas, resorts, cruise boat cabins, offices, hospitals and/or homes, apartments or residences, or other spaces or sub-spaces) are controlled to facilitate certain activities of a user in the environment by increasing focus, preparing for sleep, directing movement, masking ambient noise, and improving air quality, among others. Controllable characteristics include, for example, lighting, CO.sub.2/O.sub.2 levels, humidity levels, sound, aroma, and air temperature. Controls are provided for the occupant and/or facility personnel to select activities or scenes, or sensors detect the activity and implement an appropriate scene.