JP2023094221A - Conversion device and conversion method - Google Patents

Abstract

To provide a conversion device and a conversion method allowing measurement of the intensity of light without using a sensor that measures the intensity of light.SOLUTION: A conversion device comprises: an acquisition unit that acquires the value of power generated by a solar battery cell; and a control unit that converts the value of the generated power into the intensity of light in a desired wavelength range based on a predetermined conversion factor.SELECTED DRAWING: Figure 2

Description

The present invention relates to a conversion device and conversion method.

Conventionally, it is known that the biorhythm is corrected by sunlight, and it is known that the biorhythm affects sleep. For example, a technique has been proposed for evaluating the depth of sleep by measuring the intensity of sunlight (eg, Patent Document 1).

As described above, the intensity of sunlight (for example, illuminance) is assumed to be used in various scenes in addition to the evaluation of the depth of sleep. For example, usage scenes include drying in the sun, sunburn, raising animals, raising plants, and mental health.

JP 2016-28662 A

By the way, since the use scene described above assumes sunlight, the use of a sensor that measures the intensity of sunlight can be assumed. Similarly, since the usage scene described above assumes sunlight, the usage of a solar cell device can also be assumed.

In view of this background, the inventors have made intensive studies and found that the sensor for measuring the intensity of light can be omitted by using a solar cell device. In other words, the inventors have found that by omitting the sensor, the number of parts can be reduced and the space can be saved.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-described problems, and provides a conversion device and a conversion method that make it possible to measure the intensity of light without using a sensor for measuring the intensity of light. intended to provide

One aspect of the disclosure includes an acquisition unit that acquires a value of generated power of a photovoltaic cell, and a control unit that converts the value of generated power into the intensity of light in a desired wavelength band based on a predetermined conversion coefficient. It is a conversion device.

One aspect of the disclosure includes step A of obtaining a value of generated power of a solar cell, and step B of converting the value of generated power into intensity of light in a desired wavelength band based on a predetermined conversion factor. It is a conversion method.

ADVANTAGE OF THE INVENTION According to this invention, the conversion apparatus and conversion method which can measure the intensity|strength of light can be provided, without using the sensor which measures the intensity|strength of light.

FIG. 1 is a diagram for explaining a wearable terminal 100 according to an embodiment. FIG. 2 is a diagram showing a conversion device 300 according to an embodiment. FIG. 3 is a diagram for explaining wavelengths according to the embodiment. FIG. 4 is a diagram for explaining predetermined transform coefficients according to the embodiment. FIG. 5 is a diagram for explaining predetermined transform coefficients according to the embodiment. FIG. 6 is a diagram for explaining predetermined transform coefficients according to the embodiment. FIG. 7 is a diagram for explaining experimental results according to the embodiment. FIG. 8 is a diagram for explaining experimental results according to the embodiment.

Embodiments will be described below with reference to the drawings. In addition, in the following description of the drawings, the same or similar reference numerals are given to the same or similar parts. However, the drawings are schematic.

[Embodiment]
(wearable terminal)
A wearable terminal according to an embodiment will be described below. It should be noted that the wearable terminal is only one example of a system in which a conversion device, which will be described later, is installed.

As shown in FIG. 1 , the wearable terminal 100 has a display section 110 , a photovoltaic (PV) cell (hereinafter referred to as a PV (Photovoltaic) cell) 120 , a body section 130 and a clip 140 . The wearable terminal 100 may be configured to communicate with a terminal 200 such as a smart phone. Although not particularly limited, the communication method may be Bluetooth (registered trademark).

The display unit 110 is configured by a display such as a liquid crystal display or an organic EL (Electro-Luminescence) display. The display unit 110 may be a touch panel type display.

The PV cell 120 is a cell that generates power according to light such as sunlight. PV cell 120 may be a bendable cell. PV cell 120 may be a transparent cell. If the PV cells 120 are transparent, the PV cells 120 may be placed on the surface of the display section 110 .

The main unit 130 incorporates a conversion device 300, which will be described later. The main unit 130 may have a secondary battery that stores power generated by the PV cells. The PV cell 120 and the display section 110 may be arranged on the surface of the main body section 130 . A clip 140 may be arranged on the back surface of the body portion 130 .

Clip 140 is a member for attaching wearable terminal 100 to a user. The clip 140 may be attached to, but not limited to, the user's clothing, belt, bag, or the like.

(conversion device)
A conversion device according to an embodiment will be described below. The conversion device 300 may be built in the wearable terminal 100 described above.

As shown in FIG. 2, the conversion device 300 has a communication section 310, a measurement section 320, and a control section 330. FIG.

The communication unit 310 is configured by a communication module. The communication module can be a wireless communication module that complies with standards such as Bluetooth, IEEE802.11a/b/g/n/ac/ax, LTE, 5G, 6G, and standards such as EEE802.3 may be a wired communication module conforming to Although not particularly limited, the communication unit 310 may communicate with the terminal 200 .

Measurement unit 320 is configured by a power sensor. In the embodiment, the measurement unit 320 constitutes an acquisition unit that acquires the value of the power generated by the PV cell 120. FIG. Although not particularly limited, the measuring unit 320 may be configured by a current sensor and measure the generated current [mA] of the PV cell 120 . A case in which the measurement unit 320 acquires the current value [mA] will be exemplified below.

Controller 330 may include at least one processor. The at least one processor may be formed by a single integrated circuit (IC), or by a plurality of communicatively coupled circuits (such as integrated circuits and/or discrete circuit(s)). good too.

In the embodiment, the control unit 330 constitutes a control unit that converts the value of generated electric power (current value [mA] in the embodiment) into the intensity of light in a desired wavelength band based on a predetermined conversion factor. The predetermined conversion coefficient is a coefficient for converting the value of generated power into the intensity of light in the desired wavelength band, and can be specified based on the correlation between the value of generated power and the intensity of light in the desired wavelength band. Details of the predetermined transform coefficients will be described later.

Although not particularly limited, the intensity of light may be represented by energy passing through a unit area perpendicular to the propagation direction of light per unit time. The intensity of light may be expressed in [mW] or may be expressed in [dBm]. The intensity of light may be a value with energy added, and may be read as light energy, may be read as photon flux density [μmol], or may be read as spectral sensitivity.

In the embodiment, invisible light such as ultraviolet light is used as the desired wavelength band. It may be [lx], luminous intensity [cd], brightness [cd/m ² ], or the like.

(wavelength)
The wavelength according to the embodiment will be described below. Here, a case is exemplified where the wavelength band of light that contributes to power generation of the PV cell 120 is 350 nm to 1,100 nm.

As shown in FIG. 3, in the wavelength band of 350 nm to 1,100 nm, the solar radiation intensity differs for each wavelength band. The unit of solar radiation intensity may be represented by [kW/m ² ] or may be represented by [MJ/m ² ]. The distribution of solar radiation intensity shown in FIG. 3 is merely an example, and the distribution of solar radiation intensity may differ depending on factors such as the height of the sun.

Here, the power generated by the PV cell 120 is a value obtained for the entire wavelength band from 350 nm to 1,100 nm. It is preferable to use different predetermined transform coefficients for each band. For example, the predetermined conversion factor used when the desired wavelength band is 350-500 nm is preferably different from the predetermined conversion factor used when the desired wavelength band is 400-600 nm.

Based on such knowledge, for example, the predetermined conversion coefficient may be set as follows.

(predetermined conversion factor)
The predetermined transform coefficients according to the embodiment will be described below. Specifically, the relationship between the current value of the power generated by the PV cell 120 and the intensity of light in the desired wavelength band, that is, the predetermined conversion coefficient for converting the current value to the intensity of light will be described.

In a first option, the predetermined conversion factor may be different for each desired wavelength band, as shown in FIG. For example, the predetermined conversion coefficient used when the desired wavelength band is the wavelength band A may be different from the predetermined conversion coefficient used when the desired wavelength band is the wavelength band B. In such a case, the predetermined conversion coefficients that are different for each desired wavelength band may be stored in advance in the controller 330 .

In a second option, as shown in FIG. 5, the predetermined conversion factor may be different for each time to convert current values to light intensity. Although not particularly limited, the time may be represented by months or by seasons. For example, the predetermined conversion coefficient used in the case where the current value is converted into light intensity at time A is different from the predetermined conversion coefficient used in the case where the current value is converted into light intensity at time B. good too. In such a case, the predetermined conversion coefficients that differ for each period may be pre-stored in the controller 330 .

In the second option, the wearable terminal 100 has a function of receiving signals from the satellite positioning system, receives time information from the satellite positioning system, and may specify the time based on the received time information. . A satellite positioning system may be referred to as a GNSS (Global Navigation Satellite System). The satellite positioning system may include GPS (Global Positioning System), may include GLONASS, and may include Michibiki. Wearable terminal 100 may receive information specifying the timing from terminal 200 .

In a third option, as shown in FIG. 6, the predetermined conversion factor may be different for different regions converting current values to light intensity. Without limitation, regions may be represented by regions divided by latitude, geographic divisions (e.g., Asia, Oceania, North America, Central and South America, Europe, Russia, Middle East and North Africa, Africa, etc.). may be represented by For example, the predetermined conversion coefficient used in the case where the region where the current value is converted to the light intensity is the region A is different from the predetermined conversion coefficient used in the case where the region where the current value is converted into the light intensity is the region B. good too. In such a case, the predetermined transform coefficients that differ from region to region may be stored in the controller 330 in advance.

In the third option, the wearable terminal 100 has a function of receiving signals from a satellite positioning system, receives location information from the satellite positioning system, and may identify an area based on the received location information. . A satellite positioning system may be referred to as GNSS. The satellite positioning system may include GPS, may include GLONASS, and may include Michibiki. Wearable terminal 100 may receive information specifying an area from terminal 200 .

The fourth option may be a combination of two or more options selected from the first to third options.

(Action and effect)
In the embodiment, the controller 330 converts the value of the power generated by the PV cell 120 into the intensity of light in the desired wavelength band based on a predetermined conversion factor. According to such a configuration, it is possible to appropriately measure the intensity of light by using the value of the power generated by the PV cell 120 without using a sensor for measuring the intensity of light. As a result, it is possible to reduce the number of parts and save space.

In embodiments, the predetermined conversion factor may be different for each desired wavelength band. According to such a configuration, a sensor for measuring the light intensity for each desired wavelength band is not required, and by using the value of the power generated by the PV cell 120, the light intensity for each desired wavelength band can be appropriately adjusted. can be measured.

In embodiments, the predetermined conversion factor may be different for each time to convert current values to light intensity. According to such a configuration, when assuming a case where the relationship between the value of the power generated by the PV cell 120 and the intensity of light in the desired wavelength band may change due to the height of the sun varying from season to season. Even so, it is possible to appropriately measure the intensity of light for each desired wavelength band.

In embodiments, the predetermined conversion factor may be different for each region that converts current values to light intensity. According to such a configuration, assuming a case where the relationship between the value of the power generated by the PV cell 120 and the intensity of light in the desired wavelength band may change due to the difference in the height of the sun in each region. Even so, it is possible to appropriately measure the intensity of light for each desired wavelength band.

[Modification 1]
Modification 1 of the embodiment will be described below. Modification 1 mainly describes differences from the above-described embodiment.

Specifically, in the embodiment, the case where the conversion device 300 is incorporated in the wearable terminal 100 is exemplified. On the other hand, in Modification 1, a variation of the system to which conversion device 300 is applied will be described.

In Modification 1, conversion device 300 may be applied to a wearable terminal having PV cells, or may be applied to a system including a solar cell device having PV cells. Here, the solar cell device may be assumed to be a stationary solar cell device installed outdoors. For example, the system to which conversion device 300 is applied may include the system shown below.

First, the system may be a sun-dried food production system. The desired wavelength band may be a band that affects sun drying. In such cases, a study of the effect of light intensity on food taste may be conducted by recording the light intensity converted from the value of the generated power of the PV cell. An alert may be output to the food producer when the light intensity converted from the value of the generated power of the PV cell falls outside the proper range.

Second, the system may be a system for tanning. The desired wavelength band may be the UV (Ultra-Violet) band. In such cases, the system may output various alerts when the light intensity converted from the PV cell generated power value exceeds a threshold. The alert may include an alert that warns of overexposure to ultraviolet rays and an alert that notifies the timing when the effect of sunscreen has decreased. The system may recommend appropriate sunbathing time for users who want to tan, and may recommend appropriate sun protection measures for users who do not want to tan.

Third, the system may be a system for vitamin D. The desired wavelength band may be the entire wavelength band that contributes to power generation of the PV cell. In such cases, the system may recommend sunbathing hours that produce adequate amounts of vitamin D.

Fourth, the system may be a system for raising animals (eg, reptiles). The desired wavelength band may be the entire wavelength band that contributes to power generation of the PV cell. In such cases, the system may monitor the animal for adequate UV light exposure. The body temperature of the animal may be maintained at an appropriate temperature using power generated by the PV cell.

Fifth, the system may be a system for growing plants. The desired wavelength band may be the entire wavelength band that contributes to power generation of the PV cell. In such cases, the system may monitor whether the plants are getting adequate sunlight. Suitable plants may be recommended based on the light intensity converted from the PV cell generated power value.

Sixth, the system may be a mental health system. The desired wavelength band may be the entire wavelength band that contributes to power generation of the PV cell. In such cases, the system may recommend appropriate sunbathing time according to sleep, fatigue, anxiety, and so on.

Seventh, the system may be a maintenance system. The desired wavelength band may be the UV band. In such cases, the system may monitor the amount of UV radiation on structures such as bridges and buildings, and output an alert to prompt the building to be repainted.

Eighth, the system may be a system related to heat stroke prevention. The desired wavelength band may be the entire wavelength band that contributes to power generation of the PV cell. In such a case, the system may output an alert urging the user who is working or doing outdoor activities to prevent heatstroke.

[experiment]
Experiments are described below. In the experiment, the correlation between the wavelength band (350-1,100 nm) contributing to the power generation of the PV cell 120 and a part of the wavelength band was confirmed.

First, we prepared an optical sensor that can measure the intensity of light in the entire wavelength band (350-1,100 nm) and can measure the intensity of light in a part of the entire wavelength band. Second, the optical sensor measures the intensity of light in the entire wavelength band (350-1,100 nm), and the optical sensor measures the intensity of light in the first wavelength band (350-500 nm), which is part of the entire wavelength band. Then, the intensity of light in the second wavelength band (400-600 nm), which is part of the entire wavelength band, was measured by an optical sensor. Third, calculate the correlation between the light intensity of the entire wavelength band and the light intensity of the first wavelength band, and calculate the correlation between the light intensity of the entire wavelength band and the light intensity of the second wavelength band. bottom.

FIG. 7 shows the correlation between the intensity of light in all wavelength bands and the intensity of light in the first wavelength band. As shown in FIG. 7, it was found that the coefficient of determination (R2) representing the correlation was extremely high. Similarly, the correlation between the intensity of light in all wavelength bands and the intensity of light in the second wavelength band is as shown in FIG. As shown in FIG. 8, it was found that the coefficient of determination (R2) representing the correlation was extremely high.

Here, in FIG. 7, the “slope” is a coefficient representing the correlation of the intensity of light in the first wavelength band with respect to the intensity of light in all wavelength bands. Similarly, in FIG. 8, "slope" is a coefficient representing the correlation of the intensity of light in the second wavelength band with respect to the intensity of light in all wavelength bands. Although affected by the conversion loss of the PV cell 120, the intensity of light in all wavelength bands can be used as an indicator of the power generated by the PV cell 120. In other words, the "inclination" shown in FIGS. 7 and 8 may be considered to be equivalent to the predetermined transform coefficient described above. Under these premises, the following findings were obtained.

First, the slope representing the correlation of the light intensity of the first wavelength band with respect to the light intensity of the entire wavelength band is the slope representing the correlation of the light intensity of the second wavelength band with respect to the light intensity of the entire wavelength band. revealed to be different. That is, it has been found that the predetermined conversion coefficient is preferably different for each desired wavelength band.

Second, the slope in summer (eg, June-August) is relatively larger than that in winter (eg, December-January). In other words, the height of the sun is expected to affect the given conversion factor. In other words, it has become clear that the predetermined conversion coefficient is preferably different for each period.

Third, the height of the sun is expected to affect the given conversion factor since the slope varies from season to season. Therefore, it can be said that it is preferable that the predetermined conversion coefficient is different for each region.

[Other embodiments]
Although the present invention has been described by the above-described embodiments, the statements and drawings forming part of this disclosure should not be construed as limiting the present invention. Various alternative embodiments, implementations and operational techniques will become apparent to those skilled in the art from this disclosure.

Although not specifically mentioned in the above disclosure, the desired wavelength band may be the entire wavelength band that contributes to the power generation of the PV cell 120, or a part of the wavelength band that contributes to the power generation of the PV cell 120. good.

In the above disclosure, the case in which the PV cells 120 generate electricity using sunlight has been mainly described. However, the above disclosure is not so limited. The PV cell 120 may generate power using light emitted from the lighting device.

Although not specifically mentioned in the above disclosure, the predetermined conversion factor may be specified by learning the correlation between the measurement result of the light intensity in the desired wavelength band and the measurement result of the generated power of the PV cell. In such learning, it is not necessary to use the wearable terminal 100 described above. It may be measured by a current sensor. Learning may be performed for each desired wavelength band, may be performed for each period, or may be performed for each region. Learning may be deep learning represented by AI (Artificial Intelligence).

Although not specifically mentioned in the disclosure above, a program that causes a computer to execute each process performed by the conversion device 300 may be provided. Also, the program may be recorded on a computer-readable medium. A computer readable medium allows the installation of the program on the computer. Here, the computer-readable medium on which the program is recorded may be a non-transitory recording medium. The non-transitory recording medium is not particularly limited, but may be, for example, a recording medium such as CD-ROM or DVD-ROM.

Alternatively, a chip configured by a memory storing a program for executing each process performed by the conversion device 300 and a processor executing the program stored in the memory may be provided.

DESCRIPTION OF SYMBOLS 100... Wearable terminal, 110... Display part, 120... PV cell, 130... Main-body part, 140... Clip, 200... Terminal, 300... Conversion apparatus, 310... Communication part, 320... Measurement part, 330... Control part

Claims (5)

an acquisition unit that acquires the value of the power generated by the solar cell;
and a controller that converts the value of the generated power into the intensity of light in a desired wavelength band based on a predetermined conversion factor. 2. The conversion device according to claim 1, wherein said predetermined conversion coefficient differs for each of said desired wavelength bands. 3. The conversion device according to claim 1, wherein said predetermined conversion coefficient differs for each time of converting the value of said generated power into the intensity of light in said desired wavelength band. 4. The conversion device according to any one of claims 1 to 3, wherein said predetermined conversion coefficient differs for each region where the value of said generated power is converted into the intensity of light in said desired wavelength band. a step A of obtaining the value of the power generated by the solar cell;
A conversion method comprising a step B of converting the value of the generated power into the intensity of light in a desired wavelength band based on a predetermined conversion factor.

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