JP5938697B2 - Light control device, lighting control device, and light control method - Google Patents

Description

  The present invention relates to a dimming device, a lighting control device, and the like that control the amount of power supplied to the light emitting means by PWM control in order to adjust the brightness of various light emitting means that emit light by electric power, such as lighting fixtures and light emitting devices. It relates to a light control method.

  2. Description of the Related Art Conventionally, in various light emitting means such as various lighting fixtures and light emitting devices such as LEDs, light bulbs, and cold cathode tubes, brightness (for example, luminance of the lighting fixture) is adjusted by controlling the amount of power supplied. A method using PWM (Pulse Width Modulation, pulse width modulation) is known for controlling the electric energy (see, for example, Patent Document 1). In this method, the amount of electric power and the magnitude of the signal are changed by changing the duty ratio of the PWM signal formed by periodically output pulses (the ratio of the ON signal to the ON / OFF period of the PWM signal). Etc. On the other hand, conventionally, the luminance range is divided into three regions, a low luminance region, an intermediate region, and a high region, and the luminance is changed so that the luminance change amount per unit of the duty ratio increases as the luminance region increases. Is known (see, for example, Patent Document 2).

JP 2010-245942 A (FIG. 3, FIG. 4 etc.) JP 2006-111265 A

  However, it is known that human vision determines a change in brightness based on a ratio. For this reason, when the brightness of the light emitting means is controlled by PWM control, the pulse width (duration of each pulse) is set in 64 steps, such as a change in a low brightness level (for example, a minimum value 0 to a maximum value 63). When the brightness is changed linearly by changing the value, for example, a change in a portion where the degree of brightness is high compared to, for example, a change from 1 to 2 in the pulse width (in the above case, the pulse width is changed from 62 to 63, for example). The change in brightness is felt less. In the invention described in Patent Document 1, since the brightness of the light emitting means changes linearly with the change of the duty ratio, the light of the light emitting means is changed even if the brightness is changed by the same pulse width. There is a problem that a person who views directly or indirectly (hereinafter referred to as “viewer”) gives a feeling that the change in brightness decreases as the brightness increases.

  In Patent Document 2, since the luminance change amount per unit of the duty ratio increases as the luminance increases, the above problem is reduced. However, Patent Document 2 has a problem that the luminance changes greatly at a boundary portion between regions (a portion where a corner is formed when represented in a graph), which gives the viewer a sense of discomfort.

  On the other hand, in the configurations of Patent Document 1 and Patent Document 2, when the brightness of the light emitting unit is adjusted by digital processing, the brightness is processed by setting the number of steps from the minimum value to the maximum value. In some cases, the value of can't be processed with only an integer value. Therefore, since the value after the decimal point is processed, the number of digits required for the processing increases, the circuit scale increases, and there is a problem that the manufacturing effort and the manufacturing cost increase.

  The present invention has been made in view of the above problems, and suppresses an increase in manufacturing cost, and changes in apparent brightness at the time of dimming various light emitting means regardless of the degree of brightness. It is an object to provide a light control device, a lighting control device, and a light control method that can be made uniform.

In order to achieve the above object, according to the first aspect of the present invention, power is supplied to the light emitting means capable of controlling the amount of light emission by controlling the amount of power supplied by PWM control, and the PWM control is performed. A light control device for controlling the amount of electric power supplied to the light emitting means by adjusting a duty ratio of the light emitting means, and substantially uniforming a change in apparent brightness during light control of the light emitting means. On the logarithmic graph where one axis is the duty ratio or an element that determines the duty ratio, and the other axis is a brightness value, the duty ratio or the element that determines the duty ratio and the correlation between the brightness and the curve showing the linear variation as a first characteristic line, the value of the one axial side coordinate, emit light at the maximum brightness value of the light emitting means when for light emitting the light emitting unit by the light control device The value of the coordinate on the other axis side is larger than the value of the coordinate on the other axis side of the first characteristic line, and when light is emitted by the light control device A value corresponding to a specific point on the logarithmic graph , which is a point indicating the maximum value of the brightness of the light emitting means, is set as a specific value, and is drawn from the specific value toward the contact point on the first characteristic line. and, a straight line as the tangent of the specific value and the first characteristic line when a second characteristic line, the minimum value of the values of said one shaft to the value of the contact, the particular size The PWM control is performed on the first pulse, the dimming is performed depending on the first characteristic line, and the value from the contact value to the coordinate value of the maximum value of the one axis is specified. The PWM control is performed on the pulse whose magnitude is changed, and depending on the second characteristic line Characterized by comprising a duty ratio setting means for setting the duty ratio to perform the serial dimming.

According to a second aspect of the present invention, in addition to the configuration of the first aspect, the duty ratio setting means includes a duty ratio table for determining the duty ratio, and depends on the first characteristic line. When performing the dimming, the duty ratio is determined by calculation, and when performing the dimming depending on the second characteristic line, the duty ratio is determined based on data recorded in the duty ratio table. It is characterized by determining.

According to a third aspect of the present invention, in addition to the configuration of the first or second aspect , the light emitting means is an LED.

According to a fourth aspect of the present invention, there is provided a lighting control device, wherein the light control device according to any one of the first to third aspects and power supply to the light emitting means based on the control of the light control device. And a lighting means for lighting the light emitting means.

According to a fifth aspect of the present invention, power is supplied to the light emitting means capable of controlling the amount of light emission by controlling the amount of power supplied by PWM control, and the duty ratio of the PWM control is adjusted. controls power of the electric power supplied to said light emitting means, substantially a dimming method for equalizing the duty ratio one axis the change in the visible brightness during dimming of said light emitting means or elements for determining the duty ratio, on a logarithmic graph with the value of the brightness of the other axis, the a curve of a linear change in the correlation between the brightness and factors that determine the duty ratio or the duty ratio One characteristic line, and the value of the coordinate on the one axis side is a value of a point at which the light emitting means emits light at the maximum brightness when the light emitting means emits light by a light control device, and the other axis The value of the coordinate of is larger than the value of the coordinate on the other axis side of the first characteristic line, and indicates the maximum value of the brightness of the light emitting means when the light control device emits light in it, the the specific value a value corresponding to a specific point on the logarithmic graph, and drawn towards the specific value to the contacts of the first characteristic line, said first characteristic line and the specific value a straight line as the tangent is taken as the second characteristic line and, from the minimum value of the values of the one shaft to the value of the contact, performs the PWM control in the duty ratio of a specific range of size The dimming is performed depending on the first characteristic line, and the range of the specific size is changed from the value of the contact point to the value of the coordinate of the maximum value of the one axis. The PWM control is performed at the duty ratio, and depending on the second characteristic line, Characterized by comprising the duty ratio setting procedure for setting the duty ratio to perform the light.

  According to the first and sixth aspects of the invention, the characteristic line as a tangent drawn from the specific value on the logarithmic graph toward the contact on the first characteristic line depends on the second characteristic line. By adjusting the brightness, the brightness increase / decrease amount accompanying the change in the duty ratio and the pulse width can be increased as the brightness increases, and the light control that linearly changes the brightness can be realized. In addition, by adjusting the brightness of the characteristic line indicating the linear change on the logarithmic graph depending on the first characteristic line, the value used for dimming results in a value after the decimal point and the number of digits in the numerical value increases. Can be deterred. Therefore, it is easy to set the first characteristic line and the second characteristic line within a range that does not exceed the resolution limit of the digital circuit. Since the increase in the number can be suppressed, good dimming can be performed without increasing the circuit scale. Furthermore, by making the second characteristic line a tangent drawn toward the first characteristic line on the logarithmic graph, the change in the slope of the junction between the first characteristic line and the second characteristic line is reduced, From the contact point, dimming that depends on the first characteristic line is dimmed depending on the second characteristic line, or dimming that depends on the second characteristic line is dimmed depending on the first characteristic line. By shifting to light, it is possible to realize dimming in which a change in brightness does not rapidly increase or decrease in the transition portion. This makes it possible to substantially uniform the change in apparent brightness during dimming of the various light emitting means, regardless of the degree of brightness, while suppressing an increase in manufacturing cost.

According to the first aspect of the present invention, since the specific value is the maximum value of brightness, good light control can be performed up to the maximum value or minimum value of brightness.

According to the second aspect of the present invention, when dimming is performed depending on the first characteristic line, the duty ratio is determined by calculation, which complicates the calculation. When performing light, dimming is performed based on the data recorded in the duty ratio table, so that accurate values can be calculated by simple calculations in areas where the duty ratio can be easily calculated, making the calculation of the duty ratio complicated. Since the value can be calculated easily and quickly using the duty ratio table in the area to be performed, good dimming can be performed by PWM control while suppressing the complexity of the circuit and the increase in manufacturing cost.

According to the third aspect of the present invention, in the PWM control suitable for the light emission control of the LED, the appearance at the time of dimming the various light emitting means regardless of the degree of brightness while suppressing the increase of the manufacturing cost. The change in brightness can be made substantially uniform.

According to the fourth aspect of the present invention, it is possible to substantially uniform change in apparent brightness during dimming of various light emitting means regardless of the degree of brightness while suppressing an increase in manufacturing cost.

It is a functional block diagram which shows the whole structure of the lighting control apparatus and light control apparatus which concern on embodiment of this invention. It is a graph which shows the correlation with the setting value of a pulse width, and the brightness | luminance of LED in a lighting control apparatus and a light control apparatus same as the above.

[Basic configuration]
1 and 2 show an embodiment of the present invention.

  FIG. 1 is a functional block diagram showing the overall configuration of the lighting device and the light control device according to this embodiment.

  The lighting control device 1 </ b> A and the light control device 1 shown in FIG. 1 are used to supply power to various “light emitting means” that emit light by power. In this embodiment, the “light emitting means” are, for example, LEDs 3 as one or a plurality of “lighting devices” provided in a gaming machine 2 such as a pachinko machine shown in FIG.

  The lighting control device 1A and the light control device 1 of this embodiment perform lighting control of the LED 3 (for example, on / off control of the LED 3) and light control (for example, luminance control for adjusting luminance as “brightness”). Specifically, the lighting control device 1 </ b> A and the dimming device 1 perform the lighting control and dimming of the LED 3 by adjusting the duty ratio of the PWM control to control the amount of power supplied to the LED 3. . The lighting control and dimming of the LED 3 are performed based on an arbitrary program, wired logic, or the like periodically or whenever an event such as “big hit” occurs.

  The lighting control device 1A and the light control device 1 are disposed in a main body of a pachinko machine (not shown). However, the lighting control device 1A and the dimming device 1 may be provided separately from the main body of the pachinko machine (not shown), and one dimming device 1 is provided in a plurality of pachinko machines (not shown). You may perform lighting control of LED3 provided with two or more, respectively.

  A lighting control device 1 </ b> A according to this embodiment shown in FIG. 1 is a so-called LED driver, and includes a light control device 1, a lighting processing unit 4 as a “lighting unit”, and a light control operation unit 5.

  The light control device 1 includes at least one CPU 11, and the operation of the light control device 1 is controlled by processing of instructions and data in the CPU 11. The light control device 1 further includes a RAM 12 that functions as a work area in the processing of the CPU 11, a ROM 13 that stores various data, an EEPROM (not shown), a magnetic disk (not shown), and the like. The light control device 1 may be provided with various configurations for sequence control instead of the CPU 11, and the operation may be controlled by the operation of the configuration.

  Further, the light control device 1 includes a duty ratio setting unit 14 and a duty ratio table 15 as “duty ratio setting means”. The duty ratio setting unit 14 and the duty ratio table 15 may be provided using functional means based on the result of program processing in the CPU 11 or may be provided by hardware.

  The duty ratio setting unit 14 selects a duty ratio determination method (described later) based on the transmission of the clock signal, the count of the transmitted clock signal, the input value (described later) supplied from the dimming operation unit 5, The duty ratio and pulse width are calculated, and the duty ratio is determined (described later) based on the duty ratio data read from the duty ratio table 15, and the determined duty ratio and pulse width are output to the lighting processing unit 4. In this embodiment, “duty ratio setting” and “duty ratio determination” are used for setting and determining the duty ratio in addition to setting and determining the duty ratio itself. Configurations and procedures related to the setting and determination of the duty ratio, such as setting and determining the pulse width within the specific period (that is, the duration of each pulse) are also included (the same applies in this specification). .

  The duty ratio table 15 stores data related to the duty ratio when dimming to a specific range of brightness. The duty ratio setting unit 14 reads this data to determine the duty ratio when dimming to a specific range of brightness.

  The lighting processing unit 4 includes a power source such as an AC power source and a DC power source, a transformer for converting a voltage, a rectifier that rectifies a current supplied from the power source into a DC current of a constant voltage, and a rectified current from two values of ON and OFF A pulse current generator for outputting as a pulse current. The pulse generator generates a pulse current in which the pulse width is set based on the duty ratio determined by the duty ratio setting unit 14, and supplies the pulse current to the LED 3 to light the LED 3.

  The dimming operation unit 5 is input from another configuration provided in the gaming machine 2 or the like (for example, the processing result of a specific program in the CPU 11), or manual input by a viewer or an operator who performs adjustment work (for example, In response to the input of signals output based on the results of brightness detection of various types of light sensors (not shown) and the operation of a slide-type or dial-type light control device), the brightness for turning on the LED 3 is determined. The determined luminance information is output to the light control device 1.

[Principle of light control and lighting control]
FIG. 2 is a graph showing the correlation between the setting value of the pulse width and the luminance of the LED 3 in the lighting control device 1A and the light control device 1 of this embodiment. Hereinafter, the principle of the light control by the light control device 1 and the lighting control of the LED 3 by the lighting control device 1A will be described with reference to FIG.

A graph 100 as a “logarithmic graph” shown in FIG. 2 is a set value of a pulse width of a pulse current for which PWM control is performed as a “element for determining a duty ratio”, the vertical axis being supplied to the LED 3, and the vertical axis Is a semilogarithmic graph showing the luminance of the LED 3. In the figure, the setting value of the pulse width shown on the horizontal axis is a predetermined time zone (for example, in the duty ratio setting unit 14, there is a counter that circulates in the order of 0 → 1 →... 62 → 0, One period of this counter from 0 to 62 (a total of 63 counts) is set to 63 sections from a set value 0 to a set value 62 (that is, 2 ⁰ -1 to 2 ⁶ -1), and a 6-bit digital signal (2 ^{0-1 to} 2 ⁶ -1) (PWM control can be performed with 6-bit resolution. For example, if the set value is 0, all pulses in one cycle (63 sections from 0 to 62) are OFF. If the set value is 62, the control is performed so that all the pulses in one cycle are ON.) The mode is shown on the linear axis.

In the graph 100, “luminance” shown on the vertical axis represents the luminance of the LED 3 on the logarithmic axis. In this graph 100, the minimum value of the luminance of the LED 3 (for example, 0 cd / m ^{2 to} 1.0 cd / m ² ) is divided into 1024 equal parts from ⁰ to 1023 (that is, 2 ⁰ −1 to 2 ¹⁰ −1). A mode in which processing can be performed with a 10-bit digital signal is shown on the logarithmic axis.

  Since this graph 100 is a semi-logarithmic graph, what is displayed as a curve on a graph whose linear and vertical axes are both linear is displayed, and what is displayed as a straight line is displayed as a curve. The Accordingly, in the following, with reference to the display on the graph in which both the vertical and horizontal axes are on the linear axis, the line displayed as a straight line on the graph 100 is “curved” and the line indicating the linear characteristic displayed as a curve is expressed as “straight line”. ".

  Here, (Principle 1) to (Principle 5), which are considered as the principles of dimming, are shown and discussed below.

(Principle 1)
As described above, human vision recognizes brightness by a ratio. In view of this human visual characteristic, on the graph 100, from the luminance 1 (minimum (integer) value excluding “0”), which is the minimum value 101, to the maximum value 102 as the “specific value”. If dimming is performed along the ideal curve 103 that connects up to a certain luminance 1023 with a straight line, the dimming appears to be a linear increase / decrease in luminance that is not uncomfortable to human vision. Therefore, also in this embodiment, it is desirable to perform light control in a manner closer to the ideal curve 103.

(Principle 2)
On the other hand, along the uniform PWM line 104 set so that the brightness increases and decreases substantially in proportion to the change of the linear characteristic of the duty ratio of the characteristic, for example, the duty ratio of “(set value + 1) / 63”. Consider the case of dimming.

  This uniform PWM line 104 is greatly different in characteristics from the ideal curve 103, and the slope becomes gentler as it approaches the maximum value 102. Therefore, in this (Principle 2), the problem of the prior art (the problem in the above-mentioned [Patent Document 1]) that the change in brightness is felt less as the brightness increases is solved. Not.

(Principle 3)
On the other hand, as shown in (Principle 1), when dimming the LED 3 by PWM control approximated to the ideal curve 103 in digital processing, the values on the ideal curve 103 are taken in descending order. In the region below the vertical axis value 32 (the horizontal axis value is also 32 at this time), a value below the decimal point is generated. Therefore, as (Principle 3), dimming is performed with a value along the ideal curve 103 in a region below the limit point 105 that can take an integer value as a “contact point” shown in FIG. As a result, the number of digits required for dimming increases and the circuit scale increases.

(Principle 4)
Here, in this embodiment, a set of limit values that can take an integer value is represented by “first = X” as shown in FIG. 2 when the horizontal axis value is X and the vertical axis value is Y. The limit straight line 106 as the “characteristic line”. Then, in view of the problem of (Principle 3), as (Principle 4), an area 107 where the value of the vertical axis is from the maximum value 102 to the limit point 105 is set along the ideal curve 103 from the limit point 105 to the minimum value 101. If the dimming is performed along the limit line 106 along the limit line 106 (that is, along the pseudo logarithmic curve 106a shown in FIG. 2), the dimming close to the ideal curve 103 can be achieved without increasing the circuit scale. It can be carried out.

  However, in this case (Principle 4), the control state changes from the ideal curve 103 to the limit straight line 106 or from the limit straight line 106 to the ideal curve 103 in the vicinity of the limit point 105, that is, in the region 108 and its vicinity shown in FIG. To do. In this part, that is, the part of the area 109 shown in FIG. 2, the dimming state also changes abruptly. Therefore, when dimming in the area 108, the viewer feels that the brightness change has changed abruptly. Will be given. That is, the problem of the conventional technique (the problem described in [Patent Document 2] described above) cannot be solved.

(Principle 5)
In order to solve the problems shown in the above (Principle 2) to (Principle 4), as (Principle 5), as shown in FIG. 2, on the graph 100, from the maximum value 102 toward the contact 110 on the limit straight line 106. Then, a tangent line 111 as a “second characteristic line” is drawn. Then, it is considered that dimming is performed depending on the tangent line 111 from the maximum value 102 to the contact point 110, and dimming is performed depending on the limit straight line 106 from the contact point 110 to the minimum value 101.

  In this case, the tangent line 111 and the limit straight line 106 contact at an approximate inclination angle at the contact point 110. That is, as shown in FIG. 2, the region 112 where the tangent line 111 and the limit straight line 106 contact with each other at the contact point 110 is continuous without a sharp change in inclination.

  Therefore, in this (Principle 5), when the luminance is gradually increased, the dimming that depends on the limit straight line 106 is shifted to the dimming that depends on the tangent 111 at the contact 110, and the luminance is gradually increased. In the case of lowering, the light control depending on the tangent 111 is shifted to light control depending on the limit straight line 106. By controlling in this way, it is possible to realize dimming in which the change in brightness does not increase or decrease rapidly at the transition portion.

  Moreover, in (Principle 5), control is not performed with a value lower than the limit straight line 106, so that a value after the decimal point is generated in the numerical value required for dimming, and the necessary number of digits is increased (and the decimal point is increased). In order not to generate the following values, it is possible to suppress the increase in the number of digits of the integer value), and it is possible to suppress an increase in circuit scale when controlled by a digital circuit.

  Further, in (Principle 5), the inclination of the tangent line 111 from the maximum value 102 to the contact point 110 and the inclination of the limit straight line 106 from the contact point 110 to the minimum value 101 are close to the inclination of the ideal curve 103. If dimming is performed along the tangent line 111 or the limit straight line 106, it is possible to realize dimming that is close to the dimming along the ideal curve 103 and that appears to be a linear increase / decrease in luminance that is not strange to human vision.

  In view of the above, in this embodiment, the light control device 1 performs light control based on the above (Principle 5), thereby suppressing an increase in manufacturing cost and regardless of the degree of brightness. The change in the apparent brightness of the light emitting means is made substantially uniform.

[Dimming and lighting control procedure]
In this embodiment, the light control device 1 and the lighting control device 1A perform light control and lighting control of the LED 3 in the following procedure.

<Brightness determination>
First, the dimming operation unit 5 of the lighting control device 1 </ b> A determines the luminance with which the LED 3 is lit for the dimming device 1, and outputs information on the determined luminance to the dimming device 1. As described above, the dimming operation unit 5 can be input from other components provided in the gaming machine 2 or the like, manual input by a viewer or an operator who performs adjustment work, and various optical sensors (see FIG. In response to an input of a signal output based on the result of luminance detection (not shown), the luminance is determined.

<Selection of duty ratio determination method and determination of duty ratio>
The dimming device 1 receives the luminance information determined and output by the dimming operation unit 5, and the numerical value of the luminance for turning on the LED 3 (the numerical value indicated as the parameter on the horizontal axis in FIG. 2) is the value of the contact 110. Whether it is above or below the value of the contact 110 is confirmed.

  When the numerical value of brightness is lower than the value of the contact 110, the light control device 1 calculates the duty ratio by calculation. That is, in this embodiment, as described above, the value on the horizontal axis (pulse width per one cycle of the pulse current shown in 63 levels from 0 to 62) is X, and the value on the vertical axis (the luminance of the LED 3). ) Is Y, the pulse width is calculated such that Y = X. Then, the duty ratio is determined based on the calculated pulse width.

If the number of the brightness is above the value of the contact 110, the light control apparatus 1 determines the pulse width based on data of the duty ratio table 15. The duty ratio is determined based on the pulse width.

<Duty ratio output and lighting control>
The dimmer 1 outputs the determined duty ratio to the lighting processing unit 4. The lighting processing unit 4 generates a pulse current having this duty ratio, supplies the pulse current to the LED 3, and performs lighting control of the LED 3. That is, the lighting control device 1 </ b> A turns on the LED 3 with the luminance determined by the dimming operation unit 5. Alternatively, the lighting control device 1 </ b> A adjusts the luminance of the LED 3 that is already lit so as to be the luminance determined by the dimming operation unit 5.

  As described above, in this embodiment, the brightness is adjusted depending on the tangent 111 drawn from the maximum value 102 on the logarithmic graph 100 toward the value of the contact 110 on the limit straight line 106. Thus, as the luminance of the LED 3 increases, the amount of increase / decrease in luminance accompanying a change in duty ratio or pulse width can be increased, and dimming that linearly changes the luminance can be realized. Also, by adjusting the luminance depending on the limit straight line 106 that is a characteristic line indicating a linear change on the logarithmic graph 100, a value after the decimal point is generated in the value used for dimming, and the number of digits of the numerical value Can be prevented from growing. Therefore, it becomes easy to set the limit straight line 106 and the tangent line 111 within a range that does not exceed the resolution limit of the digital circuit, and the number of digits of the numerical value to be processed becomes large when processing by the digital circuit. Therefore, good dimming can be performed without increasing the circuit scale. Furthermore, by making the second characteristic line a tangent line 111 drawn toward the limit straight line 106 of the logarithmic graph 100, the change in the inclination of the joint portion between the limit straight line 106 and the tangent line 111 is reduced, and the contact 110 is At the boundary, the dimming that depends on the limit line 106 is changed to dimming that depends on the tangent line 111, or the dimming that depends on the tangent line 111 is shifted to dimming that depends on the limit line 106. It is possible to realize dimming that does not change rapidly. Thereby, the appearance change of the brightness of the LED 3 can be made substantially uniform regardless of the degree of brightness while suppressing an increase in manufacturing cost.

  In this embodiment, since the specific value is the maximum value 102 of the luminance of the LED 3, it is possible to perform good dimming up to the maximum value 102 or the minimum value 101 of the luminance.

  In this embodiment, when the LED 3 is dimmed depending on the limit straight line 106, the duty ratio is determined by calculation, and the calculation becomes complicated. When the dimming is performed depending on the tangent 111, the duty ratio is determined. By adjusting the brightness based on the data recorded in the table 15, an accurate value is calculated by a simple calculation in a region along the limit straight line 106 where the duty ratio can be easily calculated. Since the value can be calculated easily and quickly using the duty ratio table 15 in the region along the tangent line 111 that is becoming more complex, it is possible to achieve good adjustment by PWM control while suppressing the complexity of the circuit and the increase in manufacturing cost. Can do light.

  In this embodiment, in the PWM control suitable for the light emission control of the LED 3, the change in the apparent brightness during the dimming of the LED 3 is substantially uniform regardless of the degree of luminance while suppressing an increase in manufacturing cost. Can be

  In this embodiment, the dimming device 1 determines the pulse width, but may determine the duty ratio instead of the pulse width.

  In this embodiment, the graph 100 is a semilogarithmic graph having a logarithmic axis on the vertical axis, but may be a semilogarithmic graph having a logarithmic axis on the horizontal axis. Both may be a log-log graph with a logarithmic axis.

  In this embodiment, it is assumed that the LED 3 as the “lighting device” is disposed in the gaming machine 2 and the gaming machine 2 is a pachinko machine, but a gaming machine other than the pachinko machine, for example, a pachislot machine It may be a machine. In this embodiment, the “lighting device” is LED 3, but lighting devices other than LED 3, for example, various lighting fixtures such as incandescent light bulbs, neon tubes, etc. may be used. It may be a “lighting device”, for example, an indoor lamp of a house or a building, a street lamp, illumination, a headlamp of a transportation system, or the like. Further, the lighting control device 1 </ b> A and the light control device 1 may be used in combination with control other than the “lighting fixture”, for example, drive control of a motor or the like.

  In this embodiment, the lighting control device 1A and the dimming device 1 are used for dimming the LED 3 as the “lighting fixture”. However, the lighting control device 1A and the dimming device 1 are not limited to this. The light device 1 may be used for dimming “light emitting means” other than the “lighting fixture” that emits light by electric power and can be dimmed. For example, the lighting control device 1A and the light control device 1 are “light-emitting devices” that are home appliances and the like, and can adjust the brightness, specifically, various computers such as personal computers, mobile phones, smartphones, liquid crystal televisions, Backlights of liquid crystal displays used for video recorders, etc., and electrical appliances using displays other than liquid crystals (for example, cathode ray tube displays, plasma displays, organic EL displays, etc.) (for example, televisions, video devices, computer devices, mobile phones, smartphones, etc.) ), Etc. may be used for dimming.

  In this embodiment, the “brightness” of the lighting device is the luminance of the LED 3. However, the present invention is not limited to this, and is a unit system for measuring various brightnesses such as illuminance, luminous intensity, and visibility. May be. Further, dimming or lighting control may be performed for brightness such as luminance of a specific color in a color lighting device such as a color LED.

  In this embodiment, the “specific value” is the maximum luminance value 102 of the LED 3 and the ideal curve 103 connecting the maximum value 102 and the minimum luminance value 101 of the LED 3 is formed. ”Is the minimum value 101, and an ideal curve 103 connecting the minimum value and the maximum value 102 may be formed. The “specific value” is a specific value other than the maximum value 102 and the minimum value 101 of the luminance of the LED 3, and the tangent 111 is a line drawn from the “specific value” toward the limit straight line 106. There may be. Furthermore, a line drawn from the “specific value” toward the limit line 106 is an approximation of the ideal curve 103, and forms a slope close to the limit line 106 at the point of contact with the limit line 106. As long as it is used instead for the light control of LED3, what kind of thing may be sufficient.

Further, in this embodiment, the horizontal axis values (pulse width) and (suitable value to 2 ⁶ i.e. the 6-bit digital circuit) 63 phase values of 0 to 62, the vertical axis value (luminance) 1024 Although the phase value (2 ¹⁰ i.e. a value suitable for the 10-bit digital circuitry), the present invention is not limited thereto, if the value suitable for digital circuits, the vertical axis, the value of the abscissa what (e.g. vertical Both the axis and the horizontal axis may be 128 (2 ⁸ ) step values or 127 (2 ⁸ -1) steps, that is, values suitable for an 8-bit digital circuit.

  The above embodiment is an exemplification of the present invention, and it is needless to say that the present invention is not limited to the above embodiment.

DESCRIPTION OF SYMBOLS 1A ... Lighting control apparatus 1 ... Light control apparatus 3 ... LED (light emission means, lighting fixture)
4 ... lighting processing part 11 ... signal output part (signal output means)
12 ... Counter section (counter means)
13: Data acquisition unit (data acquisition means)
14: Duty ratio setting unit (duty ratio setting means)
15 ... Duty ratio table 100 ... Graph (logarithmic graph)
101 ... Minimum value 102 ... Maximum value (specific value)
106 ... Limit straight line (first characteristic line)
110 ... contact 111 ... tangent (second characteristic line)

Claims (5)

Power is supplied to the light emitting means capable of controlling the amount of light emission by controlling the amount of power supplied by PWM control, and the power supplied to the light emitting means is adjusted by adjusting the duty ratio of the PWM control. A dimming device for controlling the amount of electric power and substantially uniforming the change in apparent brightness during dimming of the light emitting means,
On the logarithmic graph where one axis is the duty ratio or an element that determines the duty ratio and the other axis is a brightness value, the duty ratio or the element that determines the duty ratio and the linearity of the correlation between the brightness the curve showing the change as a first characteristic line,
The value of the coordinate on the one axis side is the value of the point at which the light emitting means emits light at the maximum brightness when the light emitting means is caused to emit light by the light control device,
The value of the coordinates of the other axis is greater than the value of the coordinates of the other axis of the first characteristic line, and the brightness of the light emitting means when emitted by the dimmer a point showing the maximum value, the specific value a value corresponding to a specific point on the logarithmic graph,
And drawn toward the specific value to the contacts of the first characteristic line, the straight line as the tangent of the specific value and the first characteristic line when a second characteristic line,
From the minimum value of the value of the one axis to the value of the contact point, performing the PWM control in a pulse of a specific magnitude, performing the dimming depending on the first characteristic line,
The PWM control is performed in a pulse in which the specific magnitude is changed from the value of the contact point to the coordinate value of the maximum value of the one axis, and depending on the second characteristic line, A light control device comprising a duty ratio setting means for setting the duty ratio so as to perform light control. The duty ratio setting means includes a duty ratio table for determining the duty ratio. When the light control is performed depending on the first characteristic line, the duty ratio is determined by calculation, and the second 2. The light control device according to claim 1, wherein when performing the light control depending on a second characteristic line, the duty ratio is determined based on data recorded in the duty ratio table . It said light emitting means is a light control device according to claim 1 or 2, characterized in that an LED. A light control device according to any one of claims 1 to 3,
  A lighting control device comprising: lighting means for supplying power to the light emitting means based on the control of the light control device and lighting the light emitting means. Power is supplied to the light emitting means capable of controlling the amount of light emission by controlling the amount of power supplied by PWM control, and the power supplied to the light emitting means is adjusted by adjusting the duty ratio of the PWM control. A dimming method for controlling the amount of power and substantially uniforming the change in apparent brightness during dimming of the light emitting means,
  On the logarithmic graph where one axis is the duty ratio or an element that determines the duty ratio and the other axis is a brightness value, the duty ratio or the element that determines the duty ratio and the linearity of the correlation between the brightness The curve showing the change is the first characteristic line,
  The value of the coordinate on the one axis side is the value of the point at which the light emitting means emits light at the maximum brightness when the light emitting means is caused to emit light by the light control device,
  The value of the coordinates of the other axis is greater than the value of the coordinates of the other axis of the first characteristic line, and the brightness of the light emitting means when emitted by the dimmer A value corresponding to a specific point on the logarithmic graph, which is a point indicating the maximum value, is a specific value,
  And when the straight line as the tangent line between the specific value and the first characteristic line drawn from the specific value toward the contact point on the first characteristic line is a second characteristic line,
  From the minimum value of the value of the one axis to the value of the contact point, the PWM control is performed at a duty ratio in a specific size range, and the dimming is performed depending on the first characteristic line,
  From the contact value to the maximum coordinate value of the one axis, the PWM control is performed with the duty ratio changing the specific size range, and the second characteristic line A light control method comprising a duty ratio setting procedure for setting the duty ratio so as to perform the light control depending on the duty ratio.

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