KR20240018143A - Smart lighting for inducing sleep based on ECG data - Google Patents

Abstract

The present invention relates to a smart light for inducing sleep based on electrocardiogram measurement data during sleep. By attaching it to the finger using an electrocardiogram sensor, the electrocardiogram can be measured even when the user moves, thereby solving the problem of difficulty in continuously filming a user with a moving lens. By doing so, it solves the existing problem of making it difficult to continuously photograph a moving user with a lens.
In other words, the present invention is a lighting control device and method that includes an electrocardiogram sensor manufactured in a band format so that it can be attached to a finger and measure the electrocardiogram even when the user moves, transmitting the measured electrocardiogram signal to a signal processing unit, and lighting the processed signal. A communication unit made up of Raspberry Pi so that it can be transmitted to It is composed of lighting using Arduino to induce sleep.
Therefore, the present invention solves the problem that it is difficult to continuously film a moving user with a lens by attaching it to the finger by using an electrocardiogram sensor to measure the electrocardiogram even when the user moves. This solves the existing problem of difficulty in continuously filming a moving user with a lens. It has the effect of resolving the problem.

Description

Smart lighting for inducing sleep based on ECG data}

The present invention relates to smart lighting for inducing sleep based on electrocardiogram measurement data during sleep,

More specifically, in the lighting control device and method,

An ECG sensor manufactured in a band format so that it can be attached to the finger and measure the ECG even when the user moves, a communication unit made up of Raspberry Pi to transmit the measured ECG signal to the signal processing unit and transmit the processed signal to the lighting, A signal processing unit using MATLAB to detect the R-peak value of the ECG signal by analyzing the waveform of the ECG signal, and lighting using Arduino to induce sleep by adjusting the brightness according to the user's condition based on the processed signal. By composing,

The purpose is to solve the problem of having a lens that is difficult to continuously photograph a moving user by attaching it to the finger and measuring the electrocardiogram even when the user moves.

In general, lighting control devices and methods control the state of lighting by measuring the user's electrocardiogram.

As described above, the lighting control device and method consists of lighting, a lens, and a communication unit.

The lighting control device and method described above is a method of controlling lighting through Bluetooth communication by measuring an electrocardiogram by photographing a part of the body using a lens.

However, the conventional lighting control device and method as described above had a problem in that it was difficult to continuously photograph a moving user with a lens.

Republic of Korea Patent Application No. 1020180115604

Accordingly, the present invention is intended to solve the problem that it is difficult for conventional lighting control devices and methods to continuously photograph a moving user with a lens.

In other words, the present invention is an electrocardiogram sensor manufactured in a band format so that it can be attached to a finger and measure the electrocardiogram even when the user moves, transmits the measured electrocardiogram signal to the signal processor, and transmits the processed signal to the lighting using a Raspberry Pi. It consists of a communication unit, a signal processing unit using MATLAB to detect the R-peak value of the ECG by analyzing the waveform of the measured ECG signal, and an Arduino to induce sleep by adjusting the brightness according to the user's condition based on the processed signal. It is composed of lighting using Ino.

Therefore, the present invention consists of an ECG sensor manufactured in a band format so that it can be attached to the finger and measure the ECG even when the user moves, and a Raspberry Pi to transmit the measured ECG signal to the signal processing unit and transmit the processed signal to the lighting. Communication unit, a signal processing unit using MATLAB to detect the R-peak value of the ECG by analyzing the waveform of the measured ECG signal, and an Arduino to induce sleep by adjusting the brightness according to the user's condition based on the processed signal. By configuring it with lighting using an electrocardiogram sensor, which is attached to the finger and can measure the electrocardiogram even when the user moves, it has the effect of solving the problem of difficulty in continuously filming a moving user with a lens.

Figure 1: Illustration of the overall configuration of the present invention

Figure 2: Embodiment of the present invention

Figure 3: Interior of the present invention

In other words, the present invention is a (1) ECG sensor manufactured in a band format so that it can be attached to a finger and measure the ECG even when the user moves, transmits the measured ECG signal to the signal processing unit, and transmits the processed signal to the lighting. (2) Communication unit composed of Raspberry Pi, (3) Signal processing unit using MATLAB to detect the R-peak value of the ECG by analyzing the waveform of the measured ECG signal, and adjust the brightness according to the user's condition based on the processed signal. It consists of (4) lights using Arduino that can be adjusted to induce sleep.

Here, (1) the electrocardiogram sensor is manufactured in the form of a band so that it can be attached to the finger and measure the electrocardiogram even when the user moves.

Hereinafter, the process of using the present invention will be described as follows.

As described above, the present invention relates to a lighting control device and method, including (1) an electrocardiogram sensor manufactured in a band format so that it can be attached to a finger and measure the electrocardiogram even when the user moves, transmitting the measured electrocardiogram signal to a signal processor, and (2) Communication unit composed of Raspberry Pi to transmit the processed signal to the lighting, (3) Signal processing unit using MATLAB to detect the R-peak value of the ECG by analyzing the waveform of the measured ECG signal, processed signal Based on this, if the present invention is implemented by applying the present invention, which consists of (4) lights using Arduino to induce sleep by adjusting the brightness according to the user's condition, it will solve the problem of difficulty in continuously filming a moving user with a lens. will be.

In addition, in the implementation of the present invention, if the present invention consisting of (1) an electrocardiogram sensor manufactured in a band type is applied and implemented, it will be possible to measure the electrocardiogram even when the user moves by attaching it to the finger.

1: ECG sensor, 2: Communication unit, 3: Signal processing unit, 4: Lighting

Claims (2)

In a lighting control device and method,
(1) An electrocardiogram sensor manufactured in a band format so that it can be attached to a finger and measure the electrocardiogram even when the user moves, and a Raspberry Pi is used to transmit the measured electrocardiogram signal to the signal processing unit and transmit the processed signal to the lighting ( 2) Communication unit, which analyzes the waveform of the measured ECG signal and uses MATLAB to detect the R-peak value of the ECG signal. (3) Signal processing unit, adjusts brightness according to the user's condition based on the processed signal to induce sleep. Smart lighting for sleep induction based on electrocardiogram measurement data during sleep, which consists of (4) lights using Arduino. According to clause 1,
(1) A smart light for inducing sleep based on electrocardiogram measurement data during sleep, which is manufactured in a band format so that it can be attached to the finger through an electrocardiogram sensor and measure the electrocardiogram even when the user moves.