KR102166726B1 - Module For Measuring Circadian Action Factor And Bio Illuminance Measuring Device Including The Same - Google Patents

Abstract

The present invention provides a circadian wavelength filter that passes external light according to a circadian rhythm sensitivity curve, a visual wavelength filter that passes external light according to a visual sensitivity curve, and detects external light that has passed through the circadian wavelength filter. A photo-sensing unit that converts into a first analog signal, detects external light that has passed through the visual wavelength filter, and converts it into a second analog signal, and calculates the ratio of the first and second analog signals, based on this It provides a circadian correction coefficient measuring module and a bio illuminance measuring apparatus including a circadian correction coefficient calculating unit that calculates the correction coefficient.

Description

A circadian correction factor measurement module and a bio-illuminance measuring device including the same. {Module For Measuring Circadian Action Factor And Bio Illuminance Measuring Device Including The Same}

The present invention relates to a circadian correction coefficient measuring module and a bio illuminance measuring apparatus including the same.

Humans live with a circadian cycle, which is called a circadian rhythm, and this circadian rhythm is most affected by light.

Looking at the sun, the sun begins to rise and brighten in the morning, gradually darkens in the evening as the sun goes down, and various creatures have also changed and adapted for a long time according to the daily change of the sun, and humans also influence the solar circumference. When the sun rises in the morning, I wake up and start the day. When the sun goes down, I take a break, sleep, and live with the cycle of the day.

On the other hand, when light is received in the evening, the secretion of melatonin, one of the hormones that has a great influence on our body's sleep, is suppressed, thereby disrupting sleep and disturbing the circadian rhythm, resulting in a probability of exposure to various diseases. Becomes higher.

Diseases caused by such disturbances in the circadian rhythm include seasonal emotional disorders, sleep disorders, depression, jet lag and health disorders related to shift work. For the treatment of these diseases, melatonin secretion is suppressed in the morning and evening hours. It is necessary to help the secretion of melatonin occur easily so that the circadian rhythm is well balanced.

Meanwhile, a general illuminance measuring apparatus measures the illuminance (Lux) of external light using a light sensitivity characteristic curve for the human eye, that is, a visual wavelength filter (V(λ) Filter) that follows the visual sensitivity curve. Here, the illuminance (Lux) means the intensity of light that can be perceived by the human eye, and will be referred to hereinafter as the visual illuminance (Lux) to distinguish it from the bio-illuminance (Biolux) to be described later.

According to such a visual sensitivity curve, the maximum sensitivity is obtained in light having a wavelength range of 450 nm to 700 nm.

However, when a general illuminance measuring device following the visual sensitivity curve measures the visual illuminance value without correction for different types of external light, the bio illuminance value that affects the human circadian rhythm may be different depending on the type of external light source. I can.

This is because the light emission spectrum varies according to the type of external light source, and the light sensitivity characteristics of the hormone that controls the circadian rhythm change as the emission spectrum changes.

For this reason, it is important to find out the color temperature or Circadian Action Factor (CAF) information of an external light source in order to measure the bio illuminance.

However, in order to obtain the above information, an expensive spectral illuminometer must be used, and there is a limitation in miniaturization due to the characteristics of the detector and the detector.

Korean Patent Publication No. 10-2001-0090519

In the present invention, by applying a circadian wavelength filter and a visual wavelength filter, a circadian correction coefficient and a bio illuminance can be measured in a relatively simple manner, and additional parts for calculating the bio illuminance can be omitted. It is an object of the present invention to provide a circadian correction factor measuring module and a bio illuminance measuring device that can be reduced in size and can be applied to various products at low cost.

In addition, the present invention can diagnose a user's circadian rhythm by measuring bio illuminance, and a circadian correction coefficient measurement module capable of reinforcing the user's circadian rhythm according to the diagnosed user's circadian rhythm, and a bio illuminance measurement It aims to provide a device.

The technical problems to be achieved in the present invention are not limited to the technical problems mentioned above, and other technical problems that are not mentioned can be clearly understood by those of ordinary skill in the technical field to which the present invention belongs from the following description. There will be.

To achieve the above object, a circadian wavelength filter for passing external light according to a circadian rhythm sensitivity curve, a visual wavelength filter for passing external light according to a visual sensitivity curve, and external light passing through the circadian wavelength filter And converts it to a first analog signal, detects external light that has passed through the visual wavelength filter, and converts it to a second analog signal, and calculates the ratio of the first and second analog signals, It provides a circadian correction coefficient measuring module including a circadian correction coefficient calculating unit that calculates the circadian correction coefficient based on.

In addition, the circadian rhythm sensitivity curve is a characteristic curve of the light sensitivity for the hormone in charge of the circadian rhythm and is a curve that becomes the maximum sensitivity in the circadian wavelength band.

In addition, the hormone responsible for the circadian rhythm is melatonin or cortisol.

In addition, the circadian wavelength band is 400 nm to 600 nm.

In addition, the visual sensitivity curve is a characteristic curve for light sensitivity to the human eye and is a curve that becomes the maximum sensitivity in the visual wavelength band.

In addition, the visual wavelength band is 450 nm to 700 nm.

In addition, the circadian correction coefficient calculation unit includes a storage unit for storing a function defining a relationship between the circadian correction coefficient and a ratio of the first analog signal to the second analog signal.

Also, the circadian correction factor is proportional to the ratio of the first analog signal to the second analog signal.

A circadian wavelength filter that passes external light according to a circadian rhythm sensitivity curve, a visual wavelength filter that passes external light according to a visual sensitivity curve, and a first analog signal by detecting external light that has passed through the circadian wavelength filter. And a photodetector that detects external light that has passed through the visual wavelength filter and converts it into a second analog signal, and calculates the ratio of the first and second analog signals, and calculates a circadian correction factor based on this It provides a bio-illuminance measuring device including a circadian correction coefficient calculating unit and a bio illuminance calculating unit that calculates a bio illuminance value of external light based on the circadian correction coefficient.

Further, it further includes a visual illuminance calculator configured to convert the second analog signal into a digital signal to calculate a visual illuminance value of external light.

In addition, the bio illuminance value is calculated by multiplying the circadian correction coefficient and the visual illuminance value.

In addition, the circadian rhythm sensitivity curve is a characteristic curve of the light sensitivity for the hormone in charge of the circadian rhythm and is a curve that becomes the maximum sensitivity in the circadian wavelength band.

In addition, the hormone responsible for the circadian rhythm is melatonin or cortisol.

In addition, the circadian wavelength band is 400 nm to 600 nm.

In addition, the visual sensitivity curve is a characteristic curve for light sensitivity to the human eye and is a curve that becomes the maximum sensitivity in the visual wavelength band.

In addition, the visual wavelength band is 450 nm to 700 nm.

In addition, the circadian correction coefficient calculation unit includes a storage unit for storing a function defining a relationship between the circadian correction coefficient and the ratio of the first analog signal to the second analog signal.

Also, the circadian correction factor is proportional to the ratio of the first analog signal to the second analog signal.

According to the present invention, by applying a circadian wavelength filter and a visual wavelength filter, it is possible to measure the circadian correction coefficient and the bio illuminance in a relatively simple manner, and additional parts for calculating the bio illuminance may be omitted, thereby measuring the bio illuminance. There is an effect that the device can be miniaturized and can be applied to various products at low cost.

In addition, by measuring the bio-illuminance of the present invention, the user's circadian rhythm can be diagnosed, and the user's circadian rhythm can be strengthened according to the diagnosed user's circadian rhythm.

The effects of the present invention are not limited to those mentioned above, and other effects that are not mentioned will be clearly understood by those of ordinary skill in the art from the following description.

1 is a schematic block diagram of a bio illuminance measuring apparatus according to an embodiment of the present invention.
2 is a graph showing the secretion amount of melatonin and cortisol according to the human circadian cycle.
3 is a graph showing a circadian rhythm sensitivity curve and a visual sensitivity curve.
4 is a graph showing a circadian correction factor according to a ratio of a first analog signal to a second analog signal measured through an experiment.

A preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings, but the same or similar elements are assigned the same reference numerals regardless of the reference numerals, and redundant descriptions thereof will be omitted.

In addition, in describing the present invention, when it is determined that a detailed description of a related known technology may obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, it should be noted that the accompanying drawings are only for easily understanding the spirit of the present invention and should not be construed as limiting the spirit of the present invention by the accompanying drawings.

1 is a schematic block diagram of a bio illuminance measuring apparatus according to an embodiment of the present invention. And, Figure 2 is a graph showing the secretion amount of melatonin and cortisol according to the human cycle. And, Figure 3 is a graph showing a circadian rhythm sensitivity curve and a visual sensitivity curve.

As shown in FIG. 1, the bio-illuminance measuring apparatus according to the embodiment of the present invention includes a Circadian Lambda Filter (C(λ) Filter) 110 and a Visual Lambda Filter: V( λ) Including a filter) 120, a light sensing unit 130, a circadian action factor (CAF) calculating unit 140, a visual illuminance calculating unit 210, and a bio illuminance calculating unit 220. Can be configured.

The circadian wavelength filter 110, the visual wavelength filter 120, the photodetector 130, and the circadian correction coefficient calculation unit 140 may be manufactured as separate modules, the circadian correction coefficient measurement module 100, and In this case, the circadian correction coefficient measurement module 100 may be mounted on a general visual illuminance measuring device and used to measure a bio illuminance value (Biolux) in addition to the visual illuminance value (Lux).

Here, the visual illuminance value (Lux) refers to the intensity of light that can be perceived by the human eye, and the visual illuminance measurement device is an element that detects the illuminance of light emitted from an external light source, and various formats known in the art A light meter of can be used.

On the other hand, as shown in Figure 2, melatonin (Melatonin) is almost no secretion from 6 am to 6 pm, then the secretion amount increases rapidly starting at 6 pm and reaches a maximum around midnight until 6 am. It can be seen that it decreases rapidly.

Cortisol, contrary to melatonin, has little secretion from 6 pm to 6 am, then increases rapidly from 6 am to peak at around noon and then decreases rapidly until 6 pm. Can be seen.

As described above, the bio-illuminance measuring apparatus according to an embodiment of the present invention measures the bio-illuminance value (Biolux) by using that hormones such as melatonin or cortisol, which control human circadian rhythm, are related to light. do.

The circadian wavelength filter 110 passes external light according to the circadian rhythm sensitivity curve.

As shown in FIG. 3, the circadian rhythm sensitivity curve is a characteristic curve of light sensitivity for hormones that control human circadian rhythm, and is a curve that becomes the maximum sensitivity in the circadian wavelength band. Here, the cycle wavelength band may be 400nm to 600nm.

According to such a circadian rhythm sensitivity curve, the maximum sensitivity is obtained in light having a wavelength range of about 400 nm to 600 nm.

Accordingly, the circadian wavelength filter 110 following the circadian rhythm sensitivity curve is a band pass filter that passes external light having a wavelength of 400 nm to 600 nm, which is a circadian wavelength band, and blocks external light having a wavelength band other than that. It works.

The one-period wavelength filter 110 may be configured as a band pass filter as a blue pass filter.

Here, the blue pass filter transmits light having a wavelength range of 400 nm to 600 nm, and has a maximum transmittance in a wavelength range of about 450 nm.

Accordingly, the circadian wavelength filter 110, as a band pass filter, may pass light having a wavelength range of 400 nm to 600 nm and block light having a wavelength band other than that.

The visual wavelength filter 120 passes external light according to the visual sensitivity curve.

As shown in Fig. 3, the visual sensitivity curve is a light sensitivity characteristic curve for the human eye and is a curve that becomes the maximum sensitivity in the visual wavelength band. Here, the visual wavelength band may be 450 nm to 700 nm.

According to such a visual sensitivity curve, the maximum sensitivity is obtained in light having a wavelength range of 450 nm to 700 nm.

Accordingly, the visual wavelength filter 120 following the visual sensitivity curve operates as a band-pass filter that passes external light having a wavelength of 450 nm to 700 nm, which is a visual wavelength band, and blocks external light having a wavelength other than that.

The photodetector 130 detects external light that has passed through the circadian wavelength filter 110, converts it to a first analog signal C (eg, a voltage value), and passes through the visual wavelength filter 120. It detects external light and converts it into a second analog signal V (eg, a voltage value).

Here, the photo-sensing unit 130 may constitute a closed circuit composed of a photo diode and a variable resistor, and the amount of light that has passed through the circadian wavelength filter 110 and the visual wavelength filter 120 is measured by wavelength. Each voltage value corresponding to the integrated value can be output.

Specifically, the photodiode generates a current corresponding to light passing through the circadian wavelength filter 110 and the visual wavelength filter 120, respectively, and the current flows through the variable resistor to apply a constant voltage across the variable resistor.

The photo-sensing unit 130 may measure the first analog signal C and the second analog signal V by measuring the voltage applied across the variable resistor.

The light sensing unit 130 may be composed of one or two, and when composed of one, one light sensing unit 130 sequentially passes the light passing through the circadian wavelength filter 110 and the visual wavelength filter 120, respectively. The first analog signal (C) and the second analog signal (V) are sequentially measured by receiving an input, and when the two are configured, the two photodetectors 130 are provided with a circadian wavelength filter 110 and a visual wavelength filter 120 The first analog signal (C) and the second analog signal (V) are respectively measured by receiving each of the light passing through each.

On the other hand, the first analog signal (C) and the second analog signal (V) output from the light detection unit 130 are out of ranges that can be processed by the circadian correction coefficient calculation unit 140 and the visual illuminance calculation unit 210 When the saturation state is reached, the first analog signal C and the second analog signal V can be output by reducing the output gain, that is, reducing the resistance value of the variable resistor.

The circadian correction factor calculation unit 140 calculates a ratio (C/V Voltage Ratio) of the first analog signal C and the second analog signal V, and based on this, the Circadian Action Factor: CAF) is calculated.

Here, the circadian correction factor (CAF) may be defined as a ratio of the Circadian Efficacy of Radiation (CER) to the Luminous Efficacy of Radiation (LER), and the second analog signal (V ) To the ratio of the first analog signal C (C/V Voltage Ratio) and linearly proportional relationship.

The relationship between the ratio of the first analog signal C to the second analog signal V and the circadian correction factor CAF was confirmed through an experiment.

Specifically, external light is passed through each of the circadian wavelength filter 110 and the visual wavelength filter 120 to output the first analog signal C and the second analog signal V, respectively, and the second analog signal V ) To the ratio of the first analog signal (C) (C/V Voltage Ratio) was calculated. At the same time, the circadian correction factor (CAF) was measured using a separate spectral illuminometer (not shown). In addition, a circadian correction factor (CAF) according to the ratio of the first analog signal (C) to the second analog signal (V) (C/V Voltage Ratio) is displayed on the graph.

4 is a graph showing a circadian correction factor CAF according to a ratio of a first analog signal C to a second analog signal V measured through an experiment.

As shown in Figure 4, it is confirmed that the circadian correction factor (CAF) is a relationship linearly proportional to the ratio of the first analog signal (C) to the second analog signal (V) (C/V Voltage Ratio). I can. And, if this relationship is expressed as an equation, it is as follows.

[Equation]

CAF=A×(C/V Voltage Ratio)+B

Here, A and B are constant constants, and were measured as 3.67331 and -0.94773, respectively, in this experimental example, and may vary depending on the magnitude of the voltage and resistance applied to the photodiode.

In this way, the circadian correction coefficient calculation unit 140 implements a logic corresponding to the above equation to determine the ratio of the first analog signal C to the second analog signal V (C/V Voltage Ratio). By substituting) into the above equation, a circadian correction factor (CAF) can be calculated.

To this end, the circadian correction coefficient calculating unit 140 is a storage unit in which a function defining the relationship between the circadian correction factor CAF and the ratio of the first analog signal C to the second analog signal V is stored ( (Not shown) may be included.

The visual illuminance calculating unit 210 receives the second analog signal V from the light sensing unit 130 and converts the second analog signal V into a digital signal to calculate a visual illuminance value Lux of external light.

The bio-illuminance calculating unit 220 receives the circadian correction coefficient CAF from the circadian correction coefficient calculating unit 140 and calculates a bio-illuminance value (Biolux) of external light based on the circadian correction coefficient CAF.

Specifically, the bio illuminance calculation unit 220 receives a visual illuminance value Lux from the visual illuminance calculator 210 and multiplies the visual illuminance value Lux by a circadian correction factor CAF to obtain a bio illuminance value (Biolux). ) Is calculated.

Meanwhile, when a general visual illuminance measuring apparatus measures the visual illuminance value Lux for different types of external light without correction, the bio illuminance value Biolux may be different according to the type of external light source and color temperature. This is because the emission spectrum varies according to the type and color temperature of the external light source, and when the emission spectrum is different, the light sensitivity characteristics of the hormone responsible for the circadian rhythm also change.

For example, light in which the blue and cyan wavelength bands are mixed has a visual illuminance of 350 lx, a bio illuminance of 812 blx, and a circadian correction factor (CAF) of 2.32, and light in the cyan wavelength band has a visual illuminance of 350 lx and a bio illuminance of 413 blx. , Has a circadian correction factor of 1.18. In addition, light in the white wavelength band with a color temperature of 10000K has a visual illuminance of 350 lx, a bio illuminance of 406 blx, and a circadian correction factor (CAF) of 1.16, and a fluorescent lamp with a color temperature of 4300K has a visual illuminance of 350 lx, a bio illuminance of 210 blx, and 0.60. Has a circadian correction factor (CAF) of

As described above, it can be seen that even in the case of a light source having the same visual illuminance value Lux, the bio illuminance value (Biolux) and the circadian correction factor value (CAF) vary according to the type and color temperature.

For this reason, the conventional bio-illuminance measuring device provides information necessary to calculate the non-visual bio-illuminance value (Biolux) from the illuminance value (Lux) measured by the visual illuminance measuring device, for example, circadian correction according to the type of external light. Coefficient (CAF) or circadian efficacy of radiation (CER) and luminous efficacy of radiation (LER) are stored in advance, and the visual illuminance value (Lux) measured by the visual illuminance measuring device A complex method was employed to calculate the bio-illuminance value (Biolux) using the circadian correction factor (CAF) or circadian radiation efficiency value (CER) and radiative luminescence efficiency value (LER) according to the type of external light stored in the past. .

However, the bio-illuminance measuring apparatus according to an embodiment of the present invention directly calculates a circadian correction factor (CAF) using the circadian wavelength filter 110 and the visual wavelength filter 120, and based on this, a bio illuminance value (Biolux ), it is possible to measure the bio-illuminance value (Biolux) in a relatively simple manner compared to the prior art. In addition, since additional parts for calculating the bio-illuminance value (Biolux) can be omitted, the bio-illuminance measuring device can be downsized and applied to various products at low cost.

In this way, the bio-illuminance measuring apparatus according to an embodiment of the present invention can diagnose the user's circadian rhythm by measuring the bio-illuminance value (Biolux), and the user diagnosed through a separate circadian strengthening unit (not shown) The user's circadian rhythm can be reinforced according to the circadian rhythm of.

In other words, by controlling the hormones that govern the circadian rhythm, the user's circadian rhythm can be corrected, and diseases that are caused by disturbance of the circadian rhythm, such as seasonal emotional disorder, sleep disorder, depression, and jet lag. And health diseases related to shift work.

For example, by irradiating the user's eyes with light in the circadian wavelength band in the morning through the circadian intensifier (not shown), it suppresses the user's melatonin secretion, helping to facilitate the release of melatonin in the evening. The user's circadian rhythm can be well balanced.

Although not shown in the drawings, the apparatus for measuring bio illuminance according to an exemplary embodiment of the present invention may further include a display unit (not shown) that displays the calculated bio illuminance value (Biolux).

Through this, the user can visually check the current circadian rhythm state of the user, and the circadian rhythm can be corrected according to the circadian rhythm state.

In addition, the bio-illuminance measuring apparatus according to an embodiment of the present invention further includes a storage unit (not shown) that stores a circadian rhythm according to the passage of time and stores a required reference bio-illuminance value according to the circadian rhythm. I can.

Here, if the measured bio-illuminance value (Biolux) is smaller than the reference bio-illuminance value by comparing the reference bio-illuminance value stored in the storage unit (not shown) with the measured bio-illuminance value (Biolux), the display unit (not shown) causes the You can have a warning to reinforce your circadian rhythm.

The embodiments described in the present specification and the accompanying drawings are merely illustrative of some of the technical ideas included in the present invention. Accordingly, it is obvious that the embodiments disclosed in the present specification are not intended to limit the technical idea of the present disclosure, but to explain the technical idea, and thus the scope of the technical idea of the present disclosure is not limited by these embodiments. Modified examples and specific embodiments that can be easily inferred by those of ordinary skill in the art within the scope of the technical idea included in the specification and drawings of the present invention are included in the scope of the present invention. It will have to be interpreted.

100: circadian correction factor measurement module
110: circadian wavelength filter
120: visual wavelength filter
130: light detection unit
140: circadian correction coefficient calculation unit
210: visual illuminance calculation unit
220: bio illuminance calculation unit

Claims (18)

A circadian wavelength filter for passing external light according to a circadian rhythm sensitivity curve;
A visual wavelength filter for passing the external light according to a visual sensitivity curve;
A photodetector configured to detect the external light passing through the circadian wavelength filter and convert it into a first analog signal, and detect the external light passing through the visual wavelength filter and convert it into a second analog signal; And
Comprising the ratio of the first and second analog signals, and including a circadian correction coefficient calculating unit for calculating a circadian correction coefficient based on the ratio,
The circadian rhythm sensitivity curve is
As a characteristic curve for light sensitivity to hormones in charge of the circadian rhythm, it is a curve that becomes the maximum sensitivity in the circadian wavelength band.
The visual sensitivity curve is
As a characteristic curve for light sensitivity to the human eye, the curve that becomes the maximum sensitivity in the visual wavelength band
Circadian correction factor measurement module.
delete The method of claim 1,
The hormone responsible for the circadian rhythm is melatonin or cortisol.
Circadian correction factor measurement module.
The method of claim 1,
The circadian wavelength band is 400nm to 600nm
Circadian correction factor measurement module.
delete The method of claim 1,
The visual wavelength band is 450nm to 700nm
Circadian correction factor measurement module.
The method of claim 1,
The circadian correction coefficient calculation unit
And a storage unit storing a function defining a relationship between the circadian correction coefficient and the ratio of the first analog signal to the second analog signal.
Circadian correction factor measurement module.
The method of claim 1,
The circadian correction factor is
Proportional to the ratio of the first analog signal to the second analog signal
Circadian correction factor measurement module.
A circadian wavelength filter for passing external light according to a circadian rhythm sensitivity curve;
A visual wavelength filter for passing the external light according to a visual sensitivity curve;
A photodetector configured to detect the external light passing through the circadian wavelength filter and convert it into a first analog signal, and detect the external light passing through the visual wavelength filter and convert it into a second analog signal;
A circadian correction coefficient calculating unit calculating a ratio of the first and second analog signals and calculating a circadian correction coefficient based on the ratio of the first and second analog signals; And
And a bio illuminance calculator configured to calculate a bio illuminance value of the external light based on the circadian correction coefficient,
The circadian rhythm sensitivity curve is
As a characteristic curve for light sensitivity to hormones in charge of the circadian rhythm, it is a curve that becomes the maximum sensitivity in the circadian wavelength band.
The visual sensitivity curve is
As a characteristic curve for light sensitivity to the human eye, the curve that becomes the maximum sensitivity in the visual wavelength band
Bio illuminance measuring device.
The method of claim 9,
A visual illuminance calculator that converts the second analog signal into a digital signal and calculates a visual illuminance value of the external light
Bio illuminance measurement device further comprising a.
The method of claim 10,
The bio illuminance value is
Calculated by the product of the circadian correction coefficient and the visual illuminance value
Bio illuminance measuring device.
delete The method of claim 9,
The hormone responsible for the circadian rhythm is melatonin or cortisol.
Bio illuminance measuring device.
The method of claim 9,
The circadian wavelength band is 400nm to 600nm
Bio illuminance measuring device.
delete The method of claim 9,
The visual wavelength band is 450nm to 700nm
Bio illuminance measuring device.
The method of claim 9,
The circadian correction coefficient calculation unit
And a storage unit storing a function defining a relationship between the circadian correction coefficient and the ratio of the first analog signal to the second analog signal.
Bio illuminance measuring device.
The method of claim 9,
The circadian correction factor is
Proportional to the ratio of the first analog signal to the second analog signal
Bio illuminance measuring device.

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