KR100840766B1 - Illuminance meter having measurement function in light and shade - Google Patents

Abstract

An illuminometer having a measurement function in light and shade is provided to measure exact illumination in light and shade by using a first photodiode in light and a second photodiode in shade. An illuminometer having a measurement function in light and shade includes a sensing unit(100) and a processing unit(200). The sensing unit has a sensor to sense light and a switch to switch the sensor in light and shade. The processing unit processes data measured by the sensing unit to display illumination data. The sensing unit has a first photodiode(110), a second photodiode(111), a luminosity correction filter(113), and a measurement conversion switch(112). One end of the first photodiode is connected to the measurement conversion switch, and the other end is connected to an amplifying circuit(210) so that the first photodiode senses light of a 555nm wavelength in light. One end of the second photodiode is connected to the measurement conversion switch, and the other end is connected to the amplifying circuit so that the second photodiode senses light of a 507nm wavelength in shade. The luminosity correction filter filters the incident light and makes the light clear. The measurement conversion switch switches between the amplifying circuit and the first photodiode and between the amplifying circuit and the second photodiode.

Description

Illumination Meter Having Measurement Function In Light and Shade}

1 is a graph showing wavelength band visibility of human eye cells;

2 is a wavelength band visibility graph showing the problem of the conventional illuminometer,

3 is a block diagram of a spot meter and cow hour meter combined illuminometer according to a preferred embodiment of the present invention,

Figure 4 is a circuit diagram of a spot sight and dark hour combined illumination meter according to a preferred embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: detector 110: first photodiode

111: second photodiode 112: measurement switching switch

113: luminous correction filter

200: processor 210: amplification circuit

211: microcomputer 212: display

213: power

The present invention relates to an illuminometer. More specifically, the luminous correction filter and the silicon photodiode, that is, the first photodiode for the illuminance measurement sensor, are corrected by the luminous correction filter to have a peak value at 555 nm for spot illumination illumination detection and a peak value at 507 nm. It has two sensors that can distinguish and measure the luminous correction filter and the silicon photodiode, that is, the second photodiode, for detecting dark illumination. It relates to an illuminometer with a measurement switching switch capable of detecting and measuring a non-visible curve of 507 nm.

In general, an illuminance meter is a guide type and a digital type that measure the illuminance (planar illuminance) when natural light, such as sunlight, and light of a general light source (incandescent lamp, fluorescent lamp, etc.) are incident on a photocell. Says the instrument.

Also, the luminosity curve is a curve indicating the degree of brightness perceived by the human eye with respect to the light energy. The human eye senses the brightness by light stimulation of the same energy. This is not the same. The visibility of the bright spot is the brightest sense of yellow-green with a wavelength of 555 nm, and the increase or decrease of the wavelength weakens the sense of brightness. This is called visibility and can be expressed as a curve by taking a wavelength on the horizontal axis, which is called a visibility curve or an invisibility curve (比 視 感 度 曲線). Since there are individual differences in visibility, the standard visibility is set as an international commitment.

1 is a graph showing wavelength band visibility of human eye cells.

Referring to FIG. 1, there are two types of retinal cells, vertebral cells and rod cells, which are mainly bright cells and dark cells in the dark. Because of this, the visibility curve is divided into two types: visibility in the bright place and visibility in the dark place. In general, the visibility is referred to as 'brightness of light'. At this time, if the energy carried by the light of wavelength 555nm is 1W, 683 lm is transmitted as the brightness of light, and this constitutes the unit of brightness. In the dark field of view, the sensitivity of rod cells reaches a maximum wavelength of 507 nm and high sensitivity to blue light. For this reason, as it becomes dark, the maximum sensitivity shifts from yellowish green to blue, where red is dark and blue is perceived as bright.

2 is a graph showing wavelength vs. visibility of a conventional illuminometer.

Referring to FIG. 2, the luminous filter used in the conventional illumination sensor detects light in a non-sensitivity characteristic curve having a maximum visibility of 555 nm at all times, whether daytime or night, and displays illumination at night, and the maximum visibility is 507 nm at night. Since the illuminance is not measured in the non-sensitivity characteristic curve of the shifted wavelength band, a lamp having a large luminescence spectrum of 507 nm is much brighter when the spectrum of a specific lamp is concentrated at 555 nm in the night light, but the visibility is much brighter. Because of this, there is a problem that the human illuminance due to the mechanical illuminance measured by the illuminometer and the visibility of the eye is inconsistent.

In order to solve this problem, the present invention uses a luminous correction filter and a silicon photodiode, that is, a first photodiode, which has a peak value at 555 nm by using a luminous correction filter for illuminance measurement, and used for spot illumination illumination detection. It is equipped with a luminous correction filter with peak value and two sensors that can distinguish and classify a silicon photodiode, that is, a second photodiode, for detecting illumination in the dark, and detects a non-visual curve with a maximum viewing wavelength of 555 nm at the sight. It is an object of the present invention to provide an illuminometer with a measurement switching switch capable of detecting and measuring a non-visible curve having a maximum viewing wavelength of 507 nm.

In order to achieve the above object, the present invention, in the illumination meter for measuring the brightness of the light at the time of sight / dark, monitoring unit 100 having a switch for switching the light sensor and the sensor to detect the sight and cow sight 100 ); And a processing unit 200 receiving the data measured by the monitoring unit 100 and processing the data in the processing device to display the illumination data.

The monitoring unit 100 is connected to the measurement switching switch 112 on one side and the other side is connected to the amplifier circuit 210, the first photodiode 110 for detecting the light of the wavelength of 555nm at the sight; A second photodiode 111 connected to the measurement switch 112 and the other connected to the amplification circuit 210 and sensing light having a wavelength of 507 nm in the dark; A luminous correction filter (113) installed on the first photodiode (110) and the second photodiode (111) and filtering the incident light so that it can be clearly seen visually; And a measurement switching switch 112 for switching the amplifying circuit 210 and the first photodiode 110 and for switching the amplifying circuit 210 and the second grape diode 111.

 The processing unit 200 is connected to the measurement switching switch 112 and the amplification circuit 210 for amplifying the data transmitted from the first photodiode or the second photodiode; A microcomputer 211 receiving the amplified data from the amplifying circuit 210 and converting optical data into electrical data and calculating the electrical data; A display 212 configured to output data converted and calculated by the microcomputer 211; And a power source 213 for supplying power to the microcomputer 211.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

Figure 3 is a block diagram of the illumination meter for spot sight and cow sight in accordance with a preferred embodiment of the present invention.

Referring to Figure 3, the present invention includes a monitoring unit having a sensor for detecting the light and a switch for switching between the sight and cow hour sensor; And a processing unit 200 receiving the data measured by the monitoring unit 100 and processing the data in the processing device to display the illuminance data.

The monitoring unit 100 is equipped with a grape sensor that operates at the time of sight and cow, respectively. The switching device to operate differently at the time of sight and at the time of measurement is a switch for measurement. The sensor is measured differently at different times.

When the measurer measures the illuminance, the photoelectric sensor operating at the sight is selected by adjusting the measurement change switch at the time of spot, and the grape sensor operating at the time of cow is selected by operating the measurement change switch at the time of spot.

In this way, more precise roughness measurement is possible.

4 is a circuit diagram of a spot sight and dark hour combined illuminometer according to a preferred embodiment of the present invention.

Referring to Figure 4, the detection unit 100 of the present invention is connected to the measurement switching switch 112, one side is connected to the amplifier circuit 210, the other side detects the light of the wavelength of 555nm at the sight A first photodiode 110; A second photodiode 111 connected to the measurement switch 112 and the other connected to the amplification circuit 210 and sensing light having a wavelength of 507 nm in the dark; A luminous correction filter 113 installed on the first photodiode 110 and the second photodiode 111 and filtering the incident light so that it can be clearly seen visually; And a measurement switching switch 112 for switching the amplifying circuit 210 and the first photodiode 110 and for switching the amplifying circuit 210 and the second grape diode 111.

 In addition, the processor 200 of the present invention includes an amplifier circuit 210 connected to the measurement switching switch 112 and amplifying data transmitted from the first photodiode or the second photodiode; A microcomputer 211 receiving the amplified data from the amplifying circuit 210 and converting optical data into electrical data and calculating the electrical data; A display 212 configured to output data converted and calculated by the microcomputer 211; And a power source 213 for supplying power to the microcomputer 211.

The first photodiode 110 embedded in the sensing unit 100 detects light having a wavelength of 555 nm at the time of attraction.

In addition, the first photodiode 110 has one side connected to the measurement switching switch 112 and the other side is connected to the amplification circuit 210 included in the processing unit 200. By switching 112, the first photodiode 110 is operated.

The second photodiode 111 embedded in the detector 100 detects light having a wavelength of 507 nm in the dark.

In addition, the second photodiode 111 has one side connected to the measurement switching switch 112 and the other side connected to the amplifying circuit 210 included in the processing unit 200. By switching 112, the second photodiode 110 is operated.

The luminous correction filter 113 is installed on the upper surfaces of the first photodiode 110 and the second photodiode 111 to filter the incident light so that it can be clearly seen visually.

The amplifying circuit 210 amplifies the optical data detected by the first photodiode 110 or the second photodiode 111 and transmits the amplified data to the microcomputer 211 at the rear stage.

The microcomputer 211 converts the optical data amplified by the amplification circuit 210 into electrical data and calculates the converted data as numerical data.

The calculated data is transmitted to the display 212 by the microcomputer 211.

The display 212 displays the data transmitted from the microcomputer 211 in a symbol that the measurer can recognize.

The power source 213 serves to supply electricity so that the microcomputer 211 operates normally and stably.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

As described above, according to the present invention, a luminous sensor for illuminance measurement sensor and a silicon photodiode, that is, a first photodiode are corrected with a luminous correction filter, and have a peak value at 555 nm for spot illumination illumination detection. It has two sensors that can distinguish and measure the visibility correction filter having peak value in the photodiode and the silicon photodiode, that is, the second photodiode for detecting the illumination at the time of cow's eye. It is possible to measure the illuminance at the time of sight and darkness by attaching a measurement switch that detects and distinguishes the non-visual curve of the maximum viewing wavelength of 507 nm.

Claims (3)

In the illuminometer for measuring the brightness of the light at the time of sight and dark, A monitoring unit (100) having a sensor for detecting light and a switch for switching between spot and dark sensors; A processing unit 200 receiving the data measured by the monitoring unit 100 and processing the data in the processing apparatus to display illuminance data; Illuminance meter for sight sight and cow sight, characterized in that it comprises a. The method of claim 1, wherein the monitoring unit 100 A first photodiode 110 connected to the measurement switching switch 112 and the other side connected to the amplifying circuit 210 and sensing light having a wavelength of 555 nm at a spot; A second photodiode 111 connected at one side to the measurement switching switch 112 and at the other end to the amplification circuit 210 and detecting light having a wavelength of 507 nm in the dark; A luminous correction filter (113) installed on the first photodiode (110) and the second photodiode (111) and filtering the incident light so that it can be clearly seen visually; A measurement switching switch 112 for switching the amplifying circuit 210 and the first photodiode 110 and switching the amplifying circuit 210 and the second grape diode 111; Illuminance meter for sight sight and cow sight, characterized in that it comprises a. The method of claim 1, wherein the processing unit 200 An amplification circuit 210 connected to the measurement switching switch 112 and amplifying data transmitted from a first photodiode or a second photodiode; A microcomputer 211 which receives the data amplified by the amplifying circuit 210 and converts optical data into electrical data and calculates the electrical data; A display 212 for outputting data converted and calculated by the microcomputer 211; A power source 213 for supplying power to the microcomputer 211; Combined illuminometer at the time of sight and cow time characterized in that it comprises a.

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