TWI536940B - Pillow - Google Patents

Description

pillow

The present invention is a pillow, and more particularly to a pillow having brain wave harmonic resonance.

Sleep is an indispensable element of human health. Pillow design has a great impact on improving sleep quality. Therefore, there are memory pillows, latex pillows, etc., which are developed with high-tech materials to improve the sleep quality of users.

However, with the development of science and technology, human beings are disturbed by brain pressure due to work pressure or excessive use of electronic equipment. The brain is disordered, the spirit is not good, the memory is not concentrated, and the serious impact on life and sleep quality is really necessary. problem. Although as mentioned above, there are many pillows with good materials and ergonomic design, but these designs are not helpful for people with brain waves, complicated minds and sleep disorders.

In order to solve the technical problem that the pillow can not solve the brain wave disorder and the sleep disorder caused by the complicated thinking, the present invention proposes a vibration wave generating device integrated in the pillow which can help to reconcile the brain wave, and let the user sleep. The process can reconcile the brain waves to achieve the effect of assisting sleep and calming the mind.

The present invention provides a pillow comprising a pillow body, a brain wave generating module and one or more ear bone resonators, the pillow body comprising a head contact surface, wherein the one or more ear bone resonators are correspondingly disposed on the head Contact surface In the adjacent position, the brain wave generating module comprises a brain wave waveform database, wherein the brain wave database stores an brain wave, the brain wave generating module is electrically connected to the ear bone resonator and controls the brain wave based on the brain wave The ear bone resonator generates a vibration wave or sound wave output corresponding to the brain wave.

Further, the pillow comprises two ear bone resonators respectively disposed on the head contact surface.

The brain wave generating module includes a central processing module and a second signal processing module electrically connected to the central processing module, a battery, an input unit, a display unit and a voice circuit. The waveform database internally stores α waves, β waves, δ waves, θ waves, brain waves with improved memory, and a brain wave that helps sleep, and the battery provides power required for the internal components of the brain wave generating module to work. The input unit and the display unit are divided into a user input and output interface of the brain wave generating module, and the voice circuit is controlled by the central processing module to perform sound output; the two signal processing modules respectively and the two ear bones The resonator is electrically connected, and each brain signal waveform outputted by the central processing module is digitally analog converted and amplified and output to the correspondingly connected ear bone resonator.

Wherein, the ear bone resonator is embedded in the head contact surface.

Wherein, the pillow body is a latex pillow, a memory pillow, a separate tubular pillow or a cotton pillow.

The brain wave generating module accepts setting for a preset time, and continuously controls the ear bone resonator to play brain waves at the preset time, and plays a warning voice when the preset time expires.

Thereby, the present invention has the following features:

1. It can continuously output brain wave resonance wave or sound wave during sleep, which can be used by the user to receive brain waves that help to sleep through the ear bones during sleep. The technical effect of the lack of technology.

2. After the set time, a warning voice output can be generated to alert the user.

Please refer to the first, second and third figures, which are preferred embodiments of the pillow, comprising a pillow body 10, a brain wave generating module 20 and two ear bone resonators 30, the pillow body 10 The form is not limited, and may be a latex pillow, a memory pillow, a separate tubular pillow, a cotton pillow, etc., and includes a head contact surface.

The brain wave generating module 20 is an electronic module that can generate a brain wave. According to the definition of the Journal of Science (2011): " Many nerve cells in the human brain are constantly moving day after day; cell activities emit electromagnetic waves. If scientific instruments are used to detect the potential activity of the brain, it looks like on the screen. Like the waves, so we call it "brain wave." Simply put, brain waves and brain consciousness have a certain degree of correspondence, just like the rhythm of brain cell activity. ... In 1929, Berger recorded the same radio wave activity on the human skull for the first time. He recorded and measured the tiny discharge process in the human brain. This is the first time in human history to publish a brainwave record, named "Brain." Electroencephalogram (EEG, EEG). ...the brainwave diagram is a graph of the potential difference of a certain point on time on the head casing, usually in microvolts (millionths of a volt). The generation of the potential difference is related to the cell membrane potential. There is a potential difference on both sides of the cell membrane. This is because the extra negative ions in the cell are attracted to the extracellular positive ions, forming potentials in the inner and outer layers of the cell membrane, such as the membrane of nerve cells. The potential is generally between -40 and -90 mV (potential in the cell relative to the potential outside the cell). The potential difference recorded by the brain wave is caused by the tens of thousands of nerve cells in the cerebral cortex near the surface. When people are in eyes, eyes closed, awake or coma, the vibration frequency of brain waves will change significantly, between 1 and 40 Hz. The International Organization of Societies for Electrophysiological Technology is based on different frequencies. The brain wave is divided into α, β, δ, and θ waves. When people focus on thinking, reasoning, or stress, nervousness, uncomfortableness, anxiety, etc., it is easy to measure the beta wave (12~38Hz), and the beta wave has the highest frequency, which is the brainwave of the "consciousness" level. After the concentration is reduced, relaxed, swayed, emptied, absent-minded, and closed, the alpha wave (8~12Hz) is measured. The alpha wave can be said to be the bridge between consciousness and subconsciousness. Once in sleep, the brainwaves become low-frequency waves θ waves (4~8Hz) and δ waves (0.5~4Hz). θ waves are “subconscious” waves, such as memory, perception, emotion, attitude, belief, dream or meditation. Etc.; delta waves are the "unconscious" level that is needed to restore physical exertion. The combination of α, β, δ, and θ waves can reflect human behavior and learning performance. "In other words, brain wave brain activity on behalf of the state, pressure, tension, deep thinking, sleep, and so all states produce different outputs, and can produce similar or vibrations or sound waves through play and brain wave response frequency, can also be This will change and affect brain waves and change the activity of the human brain. In order to obtain the waveform basis of the brain wave, please refer to the seventh figure, which can be completed by the following steps:

Brain wave measurement: The electrode is attached to the brain to continuously read the waveforms recorded in various states of the brain.

Signal amplification: Amplify the captured waveform.

Analog digital conversion: digitally converts the amplified waveform.

Signal analysis and extraction: Analyze the brain waves of different frequencies with waveforms after digitization, and extract brain waves of different frequencies and types one by one.

Brainwave waveforms are captured: brain waves are extracted and separated into several different types of brain waves. The classification is stored in a brainwave database.

Save to database: Save different types of brain waves to the database.

The brain wave generating module 20 includes a central processing module 24 and a respective a second signal processing module 22 electrically connected to the central processing module 24, a battery 25, an input unit 26, a display unit 27, and a voice circuit 28, the central processing module 24 internally containing a brain wave waveform data The brainwave waveform database stores various brain waves, such as alpha waves, beta waves, delta waves, theta waves, brain waves with improved memory, brain waves that help sleep, and the like. The battery 25 provides the power required for the internal components of the brain wave generating module 20 to operate. The input unit 26 and the display unit 27 are divided into user input and output interfaces of the brain wave generating module 20, thereby respectively accepting a use. Input and settings and generate an electronic status or message display. The voice circuit 28 is controlled by the central processing module 24 to perform sound output.

The signal processing module 22 is connected to the signal converter 222 and a signal amplifying circuit 224 by the brain wave input waveform of the brain wave outputted by the central processing module 24. The signal converter 222 digitally converts the brain wave to an analog signal, and the brain wave forming the analog form is further amplified by the signal amplification circuit 224. Each of the signal processing modules 22 is coupled to one of the ear bone resonators 30, and outputs the amplified brain wave waveform to the connected ear bone resonator 30. The ear bone resonator 30 is a generator capable of generating a vibration frequency or generating an air vibration, which can be generated by a current change of the coil and the iron core through a coil, an iron core and a cushion body, such as a general horn. The reciprocating motion causes the cushion body to vibrate to generate air vibration.

When in use, please refer to the fourth, fifth and sixth figures. Two of the ear bone resonators 30 are embedded on the head contact surface when the head of a user 50 rests on the head contact surface. At the time, the back bone 53 of the user 50 corresponds to the position of the two ear bone resonators 30, so that the brain wave vibration generated by the ear bone resonator 30 is outputted through the ear bone 53 so that the user can hear the ear. The brain wave generated by the bone resonator 30, so that the user 50 can sleep According to the type of brain waves that the user chooses to play, the program achieves the technical effect of promoting sleep. The step of the brain wave generating module 20 controlling the ear bone resonator 30 to generate brainwave output may be as shown in the sixth figure, and the steps thereof may include:

The sleep timer is set: the central processing module 24 sets a preset sleep time, for example, 8 hours, when the user selects to start playing brain waves.

Waveform calculation processing: The central processing module 24 performs arithmetic processing according to brain waves stored in the brain wave waveform library, and the so-called arithmetic processing refers to amplitude enhancement of the brain wave data obtained from the brain wave waveform database. Digital analog conversion processing and other work.

Signal amplification processing: The brain wave is amplified.

Output to the ear bone resonator: The central processing unit 24 outputs the brain wave to the connected ear bone resonator 30 via the signal processing module 22, and outputs a vibration wave.

Time>T: The central processing unit 24 determines the time (T) that the ear bone resonator 30 continuously plays the resonance wave corresponding to the brain wave, and when the judgment result is that the playing time exceeds the preset playing time, the next step is performed, otherwise, Then, the step of the wave operation processing is executed.

The voice prompt is activated: the central processor 24 controls the voice circuit 28 to play a voice output to alert the user 50.

It can be seen that the brain wave outputted by the present invention can be used by the user to receive brain waves that help to sleep through the back of the ear during sleep, and solve the technical effect of the deficiencies of the prior art.

10‧‧‧Pillow body

20‧‧‧ brain wave generating module

24‧‧‧Central Processing Module

22‧‧‧Signal Processing Module

222‧‧‧Signal Converter

224‧‧‧Signal amplification circuit

25‧‧‧Battery

26‧‧‧ Input unit

27‧‧‧Display unit

28‧‧‧Voice circuit

30‧‧‧ ear bone resonator

50‧‧‧Users

53‧‧‧ Ear bones

The first figure is a perspective view of a preferred embodiment of the invention.

The second figure is a side view of a preferred embodiment of the invention.

The third figure is a block diagram of a system according to a preferred embodiment of the present invention.

The fourth figure is a schematic view of the use of the preferred embodiment of the present invention.

Figure 5 is a schematic illustration of the use of a preferred embodiment of the invention.

Figure 6 is a flow chart of a preferred embodiment of the present invention.

Figure 7 is a flow chart of brain wave measurement according to a preferred embodiment of the present invention.

10‧‧‧Pillow body

27‧‧‧Display unit

28‧‧‧Voice circuit

30‧‧‧ ear bone resonator

Claims (7)

A pillow comprising a pillow body, a brain wave generating module and one or more ear bone resonators, the pillow body comprising a head contact surface, wherein the one or more ear bone resonators are correspondingly disposed on the head contact surface In the adjacent position, the brain wave generating module comprises a brain wave waveform database, wherein the brain wave database stores various brain waves, and the brain wave generating module is electrically connected to the ear bone resonator and controls the ear bone resonance. The device generates a vibration wave or sound wave output corresponding to various brain waves. The pillow of claim 1, comprising two ear bone resonators respectively disposed on the head contact surface. The brain wave generating module includes a central processing module and a second signal processing module electrically connected to the central processing module, a battery, an input unit, and a pillow. a display unit and a voice circuit, wherein the brain wave waveform database stores α wave, β wave, δ wave, θ wave, brain wave with improved memory and brain wave for assisting sleep, and the battery provides the brain wave generating module The input unit and the display unit are divided into user input and output interfaces of the brain wave generating module, and the voice circuit is controlled by the central processing module to perform sound output; The signal processing module is electrically connected to the two ear bone resonators, and each brain signal waveform outputted by the central processing module is digitally analog converted and amplified and output to the corresponding connected ear. Bone resonator. The pillow according to claim 3, wherein the ear bone resonator is embedded in the head contact surface. The pillow body as claimed in claim 1 or 2 or 3 or 4, wherein the pillow body is a latex pillow, a memory pillow, a separate pillow or a cotton pillow. The brain wave generating module is configured to be set for a preset time, and the ear bone resonator is continuously controlled to play brain waves during the preset time, and is configured to apply the brain wave according to claim 1 or 2 or 3 or 4 A warning tone is played when the preset time expires. According to the pillow of claim 5, the brain wave generating module is configured to be set for a preset time, and continuously controls the ear bone resonator to play brain waves at the preset time, and plays when the preset time expires. A warning voice.