JPH07263152A - Dimming lighting system - Google Patents

Abstract

PURPOSE:To provide a dimming lighting system where the indicated value on an operating apparatus and the brightness as visual perception can be made to correspond to each other without sense of incongruity. CONSTITUTION:In an operating apparatus 1, a manipulated variable and the indicated value are set in proportional relation. In a function operating circuit 2, the relation between the brightness as the visual perception in the increasing direction and decreasing direction of optical output and the optical output as the physical quantity is defined as a function. The indicated value of the operating apparatus 1 is inputted into the function operating circuit 2, and the value of optical output is outputted from there. A dimming signal generating circuit 3 produces a dimming signal, based on the output value of the function operating circuit 2, and controls the optical output of an emitter 5 through a dimmer 4.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a dimming illumination device which changes the light output of a light emitting portion according to an instruction value of an operating device.

[0002]

2. Description of the Related Art Hitherto, there has been proposed a dimming lighting device in which the light output of a lighting device is adjusted by operating an operating device such as a fader. In this type of dimming lighting device, the current value is set in a proportional relationship between the value indicated by the operating device and the light output of the lighting fixture. For example, a variable resistor or the like is used as the operation device, and the operation amount of the variable resistor and the light output of the lighting fixture are made to have a proportional relationship.

Further, there has been proposed a dimming illumination device in which a switch is provided as an operating device and the light output is gradually increased or decreased within a fixed time after the switch is operated. This type of dimming lighting device performs so-called fade-in control or fade-out control, and the light output is currently proportional to time.

[0004]

By the way, according to the knowledge newly obtained by the present inventors, as will be described later, when the light output changes in a relatively short time, the light output as a physical quantity The change and the change in brightness as visual perception do not match. For example, when it is perceived that the light output is relatively large and high in brightness, there is little change in brightness even if the light output is increased, and when it is perceived that the light output is relatively small and low in brightness, the light output It is perceived that the brightness changes significantly with a slight increase in. Moreover, the present inventors have also found that there is a history phenomenon in the relationship between the light output and the brightness, and there is a different relationship between the process in which the light output changes from light to dark and the process in which it changes from dark to light. There is.

Therefore, in the conventional configuration in which the instruction value on the operation device and the light output are in a proportional relationship as described above, or the elapsed time at the time of fade-in control or fade-out control is in a proportional relationship, Since the light output changes linearly with respect to the indicated value or the elapsed time, and the brightness is not proportional to the indicated value or the elapsed time, there is a problem that the change in brightness is perceived as unnatural and causes a feeling of strangeness. .

[0006] Such a problem is avoided by an expert operating an operating device such as a fader in stage lighting or the like, but when performing an effect by dimming at a party venue or a general home, the expert does not. Since it does not exist, it is the current situation that the conventional configuration cannot eliminate the above-mentioned discomfort. The present invention is intended to solve the above problems, and provides a dimming lighting device capable of associating an instruction value with an operating device and a brightness as visual perception without a sense of discomfort without requiring skill. Is what you are trying to do.

[0007]

According to a first aspect of the present invention, there is provided a dimming illuminating device which changes a light output of a light emitting portion in accordance with an instruction value of an operating device, and a visual perception in an increasing direction and a decreasing direction of the light output. And a light output as a physical quantity, based on a relationship between the brightness as a physical quantity and a light output as a physical quantity, a conversion means for converting the brightness set by the instruction value of the operating device into a light output corresponding to the above relationship is provided. .

According to a second aspect of the present invention, the conversion means is a scale indicating the indication value of the operating device, and the scale indicating the indication value different in the increasing direction and the decreasing direction of the light output is described. To do. The invention according to claim 3 is characterized in that the operating device is provided with an operating portion capable of performing a rotating operation or a straight-moving operation, and an operating amount of the operating portion and an instruction value are set in a proportional relationship.

According to a fourth aspect of the present invention, the operating device is provided with an operating section for numerically inputting an indicated value. Claim 5
In the invention of claim 1, the operating device provides an operating section for instructing directions of increase and decrease of the light output, and an instruction value in the direction specified by the operating section in proportion to the elapsed time during the period of operating the operating section. And a change instruction value generating section.

According to the sixth aspect of the present invention, the operating unit has an operating unit in which the instruction value can be set stepwise, and the instruction value is gradually increased or decreased with the passage of time when the step of the instruction value is changed. And a fade control unit for reaching the changed instruction value, and the instruction value output from the fade control unit has a constant change amount of brightness per unit time.

According to a seventh aspect of the present invention, the operating device is provided with an operating section capable of setting an instruction value stepwise in a plurality of steps, and the instruction values at each step are set at equal intervals. According to the invention of claim 8, in the conversion means, the relationship between the brightness and the light output is set as a different relationship between the increasing direction and the decreasing direction of the light output, and the present value of the instruction value is changed each time the instruction value of the operation unit is changed. A characteristic is that the relationship is set so as to connect the maximum value or the minimum value of the indicated value and the fixed value, or two types of relationship adopted depending on the direction in which the indicated value of the operation unit is changed are set. And

According to the ninth aspect of the invention, the conversion means has a relationship between the brightness and the light output, which is obtained from two kinds of relationships defined separately for the increasing direction and the decreasing direction of the light output. It is characterized in that either the relationship with the average value or one of the above two kinds of relationships is adopted. According to the invention of claim 10, as a conversion means, a conversion table storing correspondence relationships for all combinations of brightness and light output that can be set as an instruction value of the operation device,
It is characterized in that any one of a function operation circuit in which an optical output with respect to an instruction value of the operation device is set as a function formula is adopted.

[0013]

The present inventors conducted the following evaluation experiments in order to clarify what kind of characteristics human brightness has as visual perception. In the experiment, 6 subjects (4 males and 2 females) were seated in a real space of about 6 tatami mats, the eye level was set to about 0.8 m from the floor, and the horizontal plane in the center of the floor was set. The illuminance was changed. Here, the illuminance was changed in 6 stages in the range of 20 to 1000 lux in consideration of the illuminance in a general indoor illumination space. In the initial setting, it is assumed that the brightness as a visual perception is proportional to the logarithm of the illuminance as a physical quantity, and it is 20 lux, 45 lux, 100 lux, 20 lux.
It was set in 6 levels of 0 lux, 450 lux, and 1000 lux. The time to maintain the illuminance at each stage is 0.7 seconds,
The illuminance was gradually changed from the lowest illuminance, and when the highest illuminance was reached, the illuminance was lowered 1.8 seconds later. When the minimum illuminance was reached, the illuminance was increased again 1.8 seconds later, and the increase and decrease of the illuminance were repeated multiple times. That is, as shown in FIG. 9, the illuminance was changed with the passage of time, and the time t ₁ was set to 0.7 seconds and the time t ₂ was set to 1.8 seconds.

In the process of changing the illuminance as described above, when the subject perceives that the change in brightness of two adjacent steps is different from the change in brightness of the other adjacent two steps, that step The subject was asked to report the change and the magnitude of the change. For example, 3 levels (100 lux) and 4 levels (20 lux)
The change in brightness with 0 lux) was declared to be greater than the change in brightness of the other two adjacent steps. Based on such a report from the subject, the illuminance of each stage is adjusted so that the subject can perceive that the change in brightness of two adjacent stages is almost equal, and then the illuminance newly set for each stage. The above experiment was carried out. However, the minimum illuminance (20 lux) and the maximum illuminance (1000 lux) were fixedly set. Such an experiment was repeated until the change in brightness for all two adjacent steps became perceived as almost equal by most subjects.
Here, it is assumed that there is a history phenomenon in visual perception of brightness, and the illuminance at each stage is set separately when changing from low illuminance to high illuminance and when changing from high illuminance to low illuminance. .

As a result of the above-described experiment, as shown in FIG. 10, the brightness perceived by the change from low illuminance to high illuminance (the lower curve of FIG. 10. The change direction is indicated by an arrow). Is almost exponentially related to the illuminance, and the brightness is almost logarithmically related to the illuminance in the change from the high illuminance to the low illuminance (the upper straight line in FIG. 10, the direction of change is indicated by an arrow). I got the knowledge. That is, it was verified that the brightness as a visual perception has a history phenomenon with respect to the changing direction of the illuminance as a physical quantity. From the results of the above experiment, the degree of perception of brightness at the maximum illuminance is 100, and 0 at the minimum illuminance.
Thus, the relational expression expressing the brightness x as human visual perception is obtained using the illuminance (light output) y as follows. Bright → dark: x = 100 {A log (y / y _max ) + X _max } (1) Dark → bright: x = B (y-y _min ) ^C + X _min (2) where A = K (X _min −X _max ) / log (y _min / y
_{max), B = K (X} max -X min) / (y max -
y _min ) ^C , C = 0.4 to 0.5. Also,
X _max and X _min are the maximum value and the minimum value of the brightness x, respectively, and are defined so that the maximum value of the light output is 100. y _max and y _min are the maximum value and the minimum value of the light output of the light emitting unit, respectively, and are represented by illuminance in units of lux. K is set so that A has a value of 45 to 60, if the variable range of the optical output is 20 to 1000 lux.

However, an object of the present invention is to provide a lighting device capable of dimming control so that the relationship between the value indicated by an operating device for dimming operation and the brightness as visual perception can be associated with each other without discomfort. The light output of the light emitting unit of the lighting device is set based on the value indicated by the operating device. That is, the indicated value of the operating device corresponds to the brightness x and the light output is y.
Therefore, the inverse function of equations (1) and (2) is used so that x in equations (1) and (2) becomes an input, and x = 100 {A log (y / y _max ) + X _max } = F
⁻¹ (y) x = B (y−y _min ) ^C + X _min = g ⁻¹ (y), light → dark: y = f (x) (3) dark → bright: y = g ( x) (4) The indicated value x and the optical output y should be associated with each other. The invention of each claim is made based on this knowledge.

That is, the structure of claim 1 is a basic structure, and the relationship between the brightness as a visual perception and the light output as a physical quantity is set, and the above-mentioned relationship is applied with the value indicated by the operating device as the brightness. By doing so, the light output corresponding to the brightness is determined. By adopting this configuration,
It is possible to associate the indication value of the operating device with the brightness as the visual perception without any discomfort.

According to the second aspect of the present invention, the scale indicating the indication value of the operating device is described so as to show different indication values in the increasing direction and the decreasing direction of the light output, and the above-mentioned formula (3) is used. With a simple configuration, the scale of the light → dark change process and the dark → light change process are represented by associating the x value of the equation (4) with the light output so that the x value becomes the indicated value of the scale. It is possible to achieve the purpose.

According to the third aspect of the present invention, since the operating unit is provided with the operating unit capable of the rotating operation or the rectilinear operation, and the operating amount of the operating unit and the instruction value are set in a proportional relationship, the operation feeling and the brightness can be improved. It will be possible to match the perception of Sa almost. In the configuration of claim 4, since the operation unit is provided with the operation unit for inputting the numerical value of the instruction value, the instruction value input as a numerical value can be associated with the brightness.
By using such an operation unit, when selecting a desired brightness, the process of selecting another brightness is unnecessary.

According to the fifth aspect of the present invention, the operating section for instructing the direction of increase and decrease of the light output, and the direction specified by the operating section in proportion to the elapsed time during the period of operating the operating section. Since the operation unit is provided with the instruction value generation unit for changing the value, by operating the operation unit to indicate the direction of increase or decrease of the light output and continuing the operation until the desired brightness is reached, Brightness changes over time. Here, since the brightness changes in proportion to the elapsed time when the operation of the operation unit is continued, the change in the brightness is almost proportional to the elapsed time, and the change in brightness as visual perception is uncomfortable. Does not occur.

According to the sixth aspect of the present invention, the instruction value can be set stepwise by the operation portion of the operation device, and when the step of the instruction value is changed, the instruction value is gradually increased with the passage of time. By providing a fade control unit that increases and decreases to reach the changed instruction value, and keeps the change amount of the instruction value output from the fade control unit per unit time constant, when changing the instruction value The change in brightness up to the indicated value after the change is almost proportional to the elapsed time.

According to the structure of claim 7, when the instruction values can be set stepwise by the operation portion of the operating device, the instruction values at each step are set at equal intervals, and the steps are switched. The change in brightness is perceived at almost equal intervals at any stage. According to the configuration of claim 8, the relationship between the brightness and the light output is set as a different relationship depending on the direction of increase or decrease of the light output, and the current value of the instruction value is set every time the instruction value of the operation unit is changed. The relationship is set so as to connect the maximum value or the minimum value of the instruction values, or two types of relationships that are adopted depending on the direction in which the instruction value of the operation unit is changed are fixedly set. Whichever relationship is used, it is possible to change the light output so as to correspond to the brightness as the visual perception in the increasing direction and the decreasing direction of the light output.

According to a ninth aspect of the present invention, the relationship between the light output and the average value of the brightness obtained from the two kinds of relationships defined separately for the direction of increase and decrease of the light output, and one of the two kinds of relationships. The relationship between the brightness and the light output is 1 regardless of the direction of increase or decrease of the light output.
It is set to one. In this configuration, the accuracy of the correspondence between the brightness as the visual perception and the light output of the light emitting unit is reduced as compared with the case where the relationship is set individually for the direction of increase and decrease of the light output, but compared with the conventional configuration. Correspondence becomes possible with good accuracy.

According to a tenth aspect of the present invention, there is provided a concrete configuration as a converting means, wherein data corresponding to a relatively small number of data corresponding to the indicated value of the operating device and the light output, as in the case of setting the light output stepwise. In this case, a conversion table that stores the correspondence relationships for all combinations of brightness and light output that can be set as the indication value of the operation device may be used, and the correspondence relationship between the indication values of the operation device and the light output may be small. When the data does not become data, a function operation circuit in which the light output corresponding to the indicated value of the operating device is set as a function formula may be used. Since the conversion table does not require calculation, the configuration is simple, and by using the function calculation circuit, it is possible to flexibly deal with changes in specifications of the light emitting unit.

[0025]

【Example】

(Embodiment 1) In the present embodiment, as shown in FIG. 1, a function operation circuit 2 for performing the operations of the expressions (3) to (4) with respect to the output value of the operation device 1, and a function operation circuit. 2. A dimming signal generation circuit 3 that outputs a dimming signal corresponding to the calculation result in 2, and a dimmer that controls the light output of the light emitting unit 5 based on the dimming signal output from the dimming signal generation circuit 3. 4 and. The light emitting unit 5 includes a large number of lighting loads 5a that illuminate one lighting space.

As shown in FIG. 2, the manipulator 1 includes a rotary shaft 1
A variable resistor 13 whose resistance value changes with the rotation of 3a is provided, and a knob exposed to the outside of the body 10 of the operating device 1 is attached to the tip of the rotary shaft 13a as the operating portion 11. Further, as shown in FIG. 3, a scale 12 corresponding to the operation unit 11 is written on the body 10. In this case, the variable resistor 13 has a linear relationship between the rotation angle (that is, the operation amount) and the resistance value, and the resistance value which is the output value of the operation device 1 is proportional to the rotation amount of the rotating shaft 13a. Change. Further, the scales 12 are shown at equal intervals so as to have a linear relationship with the rotation angle.

By the way, the variable resistor 1 in the operating unit 1
A cylindrical rotating body 14 is coupled inside the body 10 to the rotating shaft 13 a of No. 3. The lower surface of the sliding body 15 is in sliding contact with a part of the peripheral surface of the rotating body 14 so that a frictional force acts between the peripheral surface of the rotating body 14 and the lower surface of the sliding body 15. Therefore, the sliding body 15 moves to the left and right in FIG. 2B according to the rotating direction of the rotating shaft 13a. The upper part of the sliding body 15 is inserted into a movement restriction recess 16 provided on the inner surface of the body 10, and the lateral movement range of the sliding body 15 is restricted by the movement restriction recess 16. Also,
Arm pieces 15a are projectingly provided on the left and right side surfaces of the sliding body 15, and the movable contact 1 is provided at the tip of each arm piece 15a.
7 are connected. Each movable contact 17 is a fixed contact 1.
8 is arranged, and when the sliding body 15 moves to the left or right in FIG. 2B according to the rotation direction of the rotating shaft 13a, the movable contactor 17 on which the sliding body 15 has moved is the fixed contactor. 18 will be contacted. Further, when the rotational force applied to the operation unit 11 is released, both the movable contactors 17 are separated from the fixed contactors 18 by the spring force of the movable contactors 17. In this way, the operation direction (rotation direction) of the operation unit 11 can be detected by the movable contact 17 and the fixed contact 18.

The output value of the operating device 1 is input to the function calculating circuit 2 together with the information on the rotating direction of the operating portion 11. The above-described equations (3) and (4) are set in the function operation circuit 2, and when the output value of the operation device 1 is input to the function operation circuit 2, it corresponds to the light output of the light emitting unit 5. Output value is generated. Here, which of the equations (3) and (4) is selected in the function operation circuit 2 is determined by the open / closed state of the movable contact 17 and the fixed contact 18 provided in the operation device 1. For example, if the light output increases when the operation unit 11 is rotated to the right in FIG. 3, the formula (3) is selected for left rotation and the formula (4) is selected for right rotation. In the operation device 1, the operation amount (rotation angle) of the operation unit 11 is in a proportional relationship with the output value, and in the function calculation circuit 2, the brightness x as a human visual perception is the light output y as the physical amount of the light emitting unit 5.
After all, the operation amount of the operation device 1 corresponds to the brightness. Further, the scale 12 of the operating device 1 has a proportional relationship with the brightness. The calculation result of the function calculation circuit 2 is input to the dimming signal generation circuit 3, and the dimming signal generation circuit 3
Then, the dimming signal according to the format of the dimmer 4 is generated so that the light output of the light emitting unit 5 corresponds to the output value of the function calculation circuit 2.

The dimmer 4 is well known in the art, and for example, the light emitting section 5 is obtained by controlling the phase of a triac.
That changes the power supplied to the light emitting unit 5 or changes the output frequency of the inverter circuit by supplying high frequency power to the light emitting unit 5 through the resonance circuit while using an inverter circuit. Use something that makes you

In this embodiment, the manipulator 1 is used to rotate the manipulating part 11, but the variable resistor 13 may be a slidable manipulator that allows the manipulating part 11 to be operated in a straight line. When the light output of the light emitting unit 5 is continuously changed as in the above embodiment, the scale 12 of the operating unit 1 is used.
As described above, the brightness may be expressed at equal intervals to express the brightness as a percentage of 0 to 100%. When the operation unit 1 that changes the light output of the light emitting unit 5 in a stepwise manner is used, the operation amounts between the steps are set at equal intervals, and the operation unit 1
Numerical values or characters are written on the scale 12 of. In the case of numerical values, the intervals between the numerical values are set to be equal intervals, and for example, if five levels of display are performed, “0”, “2”
It may be described as 5 ”,“ 50 ”,“ 75 ”,“ 100 ”, or the like. When written in letters,
It may be expressed as “medium”, “dark”, or the like. In this case, it is desirable to equally divide the brightness according to the number of brightness switching steps so that changes in brightness between the steps are perceived at equal intervals.

Further, instead of the scale 12, a display such as a liquid crystal display may be provided in the operating device 1 so that the value indicated by the operating device 1 is displayed. As a display method using a display device, analog display using a bar graph or a pie chart, or digital display using numerical values or characters can be adopted. (Embodiment 2) In Embodiment 2, one kind of scale 12 of the controller 1 is used.
In the present embodiment, two types of scales 12a and 12b are shown, and the positions of the scales 12a and 12b and the output value of the operation unit 1 are described. An example is shown in which the scales 12a and 12b are set so that the relationship corresponds to the relationship between x and y in the expressions (3) and (4) described above. That is, when the operating device 1 having the same configuration as that of the first embodiment except for the scales 12a and 12b is used, the brightness indication value by the scales 12a and 12b is not the operation amount (moving distance). Scales 12a, 12b not proportional
Become unequal intervals. Moreover, the scale 12a used for the operation of increasing the brightness and the scale 12b used for the operation of decreasing the brightness are shown separately on the left and right sides of the operation unit 11. Since the output value of the manipulator 1 is proportional to the manipulated variable, the moving dimension of the manipulating part 11 is set to the value of y obtained when the brightness is substituted for x in the above equations (3) and (4). The indicated values on the scales 12a and 12b are set to be proportional to each other.

Also in this embodiment, as in the first embodiment, the operating device 1
In the case of continuous dimming, the numerical values written on the scales 12a, 12b can be expressed as a percentage of 0 to 100%, and in the case of stepwise dimming as the operating device 1, numerical values or characters can be used. it can. Further, as in the case of the first embodiment, the value indicated by the operation device 1 may be displayed on the display device.

According to the above-mentioned configuration, the output value of the operating device 1 is the value indicated by the scales 12a and 12b converted by the equations (3) to (4). Is unnecessary. That is, the dimming signal can be generated by directly inputting the output of the controller 1 to the dimming signal generating circuit 3. Other configurations are similar to those of the first embodiment.

(Embodiment 3) In each of the above embodiments, the manipulator 1
The rotary type or the linear type operating unit 11 is used as the output unit, and the output value changes according to the operation amount of the operating unit 11. However, in the present embodiment, an operating device capable of inputting an instruction value by a numerical value. 1 is used. That is, the operation unit 1 is provided with a ten-key pad or a digital thumbwheel switch as the operation unit 11 so that a desired brightness can be numerically input.
For brightness, a numerical value of 0 to 100 is usually used in association with a percentage, but a numerical value indicating the number of steps of brightness may be used if stepwise dimming is performed.

The operating device 1 having this configuration has a built-in instruction value generating unit for generating an output value corresponding to the instruction value input from the operating unit 11, and the output value proportional to the instruction value is generated in the instruction value generating unit. Is generated, it becomes possible to replace the operating device 1 of the first embodiment. Here, the indicated value generation unit detects the direction of change in the optical output by discriminating the magnitude relationship between the present indicated value and the inputted indicated value, and the function arithmetic circuit 2 also receives information regarding the changing direction together with the output value. Try to give. Further, the instruction value generator may perform the operation in the function operation circuit 2, and in this case, the function operation circuit 2 becomes unnecessary as in the second embodiment. Other configurations are similar to those of the first embodiment.

(Embodiment 4) This embodiment shows an example in which the brightness is changed over time according to a preset program. That is, the operating device 1 is provided with a timer for counting the passage of time and a program memory so that the instruction value of brightness and the time for keeping the instruction value can be stored in the program memory. Operation unit 1 of operation device 1
As 1, there is used a device capable of inputting numerical values as in the case of the third embodiment, and a mode selection switch capable of selecting a setting mode for registering a program in a program memory and an operation mode for generating an output value according to the program, and an input. An input switch for instructing to sequentially register each numerical value in the program memory is added. The other configuration of the controller 1 is the same as that of the third embodiment.

Therefore, it is necessary to select the setting mode, input the brightness indication value and operate the input switch, and then input the time for maintaining the brightness and operate the input switch as many times as necessary. When the operation mode is selected after repeatedly storing the desired program in the program memory, the light output of the light emitting unit 5 can be changed according to the registered program. Here, lighting of the light emitting unit 5
It is desirable to separately provide a switch for turning off the light so that the operation according to the program is started when the lighting is instructed in the operation mode. Alternatively, a plurality of programs may be registered, and a desired program may be selected before the light emitting unit 5 is turned on. In this way, by changing the output value of the controller 1 according to the program,
Since the brightness is changed with the lapse of time, the same structure as that of the first embodiment can be used for the configuration excluding the operating device 1.

In this embodiment, the time for maintaining the desired brightness is set as the time information, but it is also possible to set the time as the time information and change the brightness at the desired time. Good. (Embodiment 5) This embodiment shows an example in which the brightness is continuously changed with the lapse of time while the operation unit 11 of the operation device 1 is being operated. That is, as the operation unit 11 of the operation device 1, as shown in FIG. 5, one having an up switch 11a for increasing the brightness during operation and a down switch 11b for decreasing the brightness during operation is used. As the up switch 11a and the down switch 11b, separate push button switches are used, or switches that are push-pull and that increase brightness on one side of the push operation and pull operation and decrease brightness on the other side are used. Alternatively, it is possible to use a slide switch or the like which has an operation portion that is slidable with respect to the neutral position and increases brightness when operated to one side from the neutral position and decreases brightness when operated to the other side. As the up switch 11a and the down switch 11b, either one with one operation unit or two with an operation unit can be used, and the form of the operation unit can be mechanically operated, as well as changes in capacitance, etc. You may use the non-mechanical thing using.

The operation unit 1 is also provided with an instruction value generator 19 for measuring the time during which the up switch 11a and the down switch 11b are operated. The instruction value generator 19 is configured to generate an instruction value proportional to the elapsed time when the up switch 11a and the down switch 11b are operated, and use this instruction value as the output value of the controller 1. For example, if the time required to change the brightness from the minimum value to the maximum value is 10 seconds, the up switch 11
If a or the down switch 11b is operated for 5 seconds, the change width of the brightness becomes 50% of the width between the minimum value and the maximum value. However, the up switch 11a or the down switch 11
When the maximum or minimum value of brightness is reached during the operation of b, the maximum or minimum light output is maintained. This output value is input to the function calculation circuit 2 and the formula (3) or the formula (4) is applied to continuously change the light output of the light emitting unit 5 while operating the up switch 11a or the down switch 11b. To do. Further, since the instruction value generation unit 19 determines the instruction value (that is, the output value) so that the temporal change of the brightness becomes constant, the temporal change of the light output of the light emitting unit 5 does not feel uncomfortable.

With the above-mentioned configuration, the operating portion 1 of the operating device 1
While operating 1, the brightness changes continuously, and the manner of the change depends on the increase / decrease of brightness in (3) to (4).
Since it follows the formula, it is perceived that the brightness changes at a constant rate over time. Other configurations are similar to those of the first embodiment. (Embodiment 6) This embodiment is configured so that the brightness can be set stepwise, and when the brightness level is changed, the brightness gradually changes with the passage of time, and An example is shown in which the brightness of a stage is reached. That is, as shown in FIG. 6, the operating device 1 includes an operation unit 11 such as a changeover switch for setting the instruction value in a stepwise manner, and an instruction value before the change when the instruction value is changed by the operation unit 11. And a fade control unit 20 for changing the instruction value up to the instruction value in a constant time. The fade control unit 20 is configured so that the change in the instruction value (output value) per unit time within the fixed time becomes constant. That is, when the brightness level is changed, the brightness before the change is changed to the brightness after the change in a constant time, and the change in the brightness is proportional to the elapsed time. Therefore, the fade-in control and the fade-out control are performed. There is no sense of incongruity in the change in brightness. Here, as the stage where the brightness can be set, there may be two stages of turning on and off, or three stages or more.

(Embodiment 7) In each of the above embodiments, the output value of the manipulator 1 is used as an input in the function operation circuit 2, and the manipulator 1
An example in which the operations of the expressions (3) to (4) are performed each time the operation of is performed is shown. However, in the present embodiment, as shown in FIG. 7, the output value (that is, the indicated value) of the operation device 1, The conversion means is realized by using the conversion table 2'corresponding with the calculation results of the expressions (3) to (4) for each instruction value. That is, when the brightness is designated stepwise, the number of data defining the correspondence between the brightness x and the light output y is small, and in such a case, the function calculation circuit 2 is used. The configuration becomes simpler by collating the indicated value output from the operation unit 1 with the conversion table 2'instead of performing the calculation and obtaining the corresponding light output.

Here, as the output value (instruction value) of the operation unit 1, if the operation unit 11 is capable of inputting a numerical value such as a numeric keypad, the numerical value may be used. When a variable resistor whose value changes and a plurality of fixed resistors are used, the resistance value may be used. Since the resistance value cannot be directly input to the conversion table 2 ', the resistance value is converted into a voltage value and the voltage value is converted from analog to digital so that a digital value equivalent to the numerical value input is generated. do it.
In the conversion table 2 ′, if an address value is associated with an instruction value and the value of the optical output is stored for each address, the address is selected according to the instruction value which is a digital value output from the controller 1, and the address is selected. It becomes possible to retrieve the value of the optical output stored in. Here, information regarding the direction of change in brightness caused by the operation of the operation device 1 is also input to the conversion table 2 ', and the range of addresses to be used is switched according to the direction of change. For example, the lower bits of the address data of the memory forming the conversion table 2'may be designated by the output value of the analog-digital converter, and the upper bit of the address data may be used to select the region corresponding to the direction of change in brightness. Example 1 is applied to other configurations.
Is the same as.

In each of the above-mentioned embodiments, the light output of the light emitting section 5 is changed by changing the power supplied to the light emitting section 5 by the dimmer 4, but the light emitting section 5 is changed by the multiple lamp lighting load 5a. The dimmer 4 may be configured to change the illuminance of the illumination space by controlling the number of lights of the illumination load 5a to change. In this case, the number of lights of the lighting load 5a corresponds to the dimming level.

By the way, in each of the above-described embodiments, when the direction of change in brightness is switched as dark → bright → dark or bright → dark → bright, the brightness at which the changing direction is reversed is the maximum value of the variable range or If it is not the minimum value, as is apparent from FIG. 10, two brightness values correspond to one light output value. Therefore, as a method of changing the brightness other than the maximum value or the minimum value to another brightness, one of the following two methods is adopted.

The first method is a method of fixedly setting the relationships of the expressions (3) and (4) and selecting one of the relationships according to the direction of change in brightness. The second method is a method in which the expression (3) or the expression (4) is newly redefined between the current brightness value and the maximum value or the minimum value, and the relationship according to the new definition is used. Which of the maximum value and the minimum value is used in the second method is determined by the direction of change from the current value, and the maximum value is used in the direction of increasing brightness.

These methods will be described with reference to FIG. FIG. 8A shows an example of performing an operation of dark → bright → dark, and shows a case where the changing direction of the brightness is switched from the position a to reach the position c (minimum brightness).
At this time, in the first method in which the relationship between the brightness and the light output is fixedly set, the relationship in the dark → bright direction is the lower curve and the position of a is on the lower curve, and the bright → Since the relationship in the dark direction is the straight line on the upper side of FIG. 8 (a), it shifts from the position a to the straight line at the same light output, passes through the position b, and finally
The light output is controlled so that it goes through the path of a → ro → ha. If the second method is adopted, equation (3) is redefined so that the position of b is 100 and the position of c, which is the minimum light amount, is 0, and the redefined relation is Is used to change the light output so that it goes through the path of A → C without passing through the position of B.

The same applies to the process of light → dark → bright. As shown in FIG. 8 (b), if the position of a in light → dark is the current value, in the first method, a → b. → The light output is controlled so as to pass through the path of Ha, and the second method uses the redefined relation without passing through the position of B, so as to pass through the path of → Ha. Here, in the second method, the current value of brightness and the maximum value or the minimum value are used, but instead of continuously dimming, the dimming is performed stepwise as in the sixth embodiment and the time elapses. When changing the brightness accordingly, the value after the change becomes known, so instead of redefining the relationship between the maximum and minimum brightness values and the current value, the values before and after the change The relationship may be redefined by the brightness value of.

Further, in each of the above embodiments, the way of changing the light output is changed according to the direction of the increase / decrease of the brightness, but it is not necessary to strictly control the brightness depending on the application. There is also. In such a case, if the relationship between the instruction value and the optical output of the operating device 1 is set so that the average value of the expressions (3) and (4) is used or only one of them is used. Good. In either case, comparing with the conventional case where the brightness as the visual perception and the instruction value of the operation unit 1 are set independently of each other, the difference between the operation of the operation unit 1 and the change of the brightness is compared. The feeling of nature is reduced.

[0049]

According to the first aspect of the present invention, the relationship between the brightness as the visual perception and the light output as the physical quantity is set, and the value indicated by the operating device is used as the brightness to apply the above relationship to the brightness. Since the corresponding light output is determined, there is an advantage that the indication value of the operating device and the brightness as visual perception can be associated with each other without discomfort.

According to the invention of claim 2, the scale indicating the indication value of the operating device is described so as to show different indication values in the increasing direction and the decreasing direction of the light output. It has an advantage that it is possible to achieve the purpose although it has a simple structure in which each scale is marked. According to the third aspect of the present invention, the operation unit capable of rotating operation or straight movement operation is provided in the operation device, and the operation amount of the operation unit and the instruction value are set in a proportional relationship. There is an effect that and can be almost matched.

According to the fourth aspect of the present invention, since the operating unit is provided with the operation unit for inputting the numerical value of the indicating value, the indicating value inputted as the numerical value can be associated with the brightness, and this operating unit is used. This has the advantage that the process of selecting another brightness when selecting the desired brightness is unnecessary. According to the invention of claim 5, the operating section for instructing the direction of increase and decrease of the light output, and the instruction value is changed in the direction specified by the operating section in proportion to the elapsed time during the period of operating the operating section. Since the operation value is provided with an instruction value generation unit to be operated, the operation unit is operated so as to indicate the direction of increase and decrease of the light output, and the operation is continued until the desired brightness is obtained. Since the brightness changes in proportion to the elapsed time when the operation of the operation unit is continued, the change in brightness is almost proportional to the elapsed time, and the brightness as a visual perception is changed. There is an advantage that the change of does not cause discomfort.

According to a sixth aspect of the present invention, the instruction value can be set stepwise by the operation unit of the operating device, and when the step of the instruction value is changed, the instruction value is gradually increased with the passage of time. A fade control unit that increases and decreases to reach the changed instruction value is provided, and the change amount of the instruction value output from the fade control unit per unit time is constant, so change when changing the instruction value The change in brightness up to the subsequent instruction value is almost proportional to the elapsed time, and as a result, the change in brightness in the fade-in control and the fade-out control does not feel uncomfortable. According to the invention of claim 7, when the instruction values can be set stepwise by the operation unit of the operating device, the instruction values of each step are set at equal intervals, and therefore, the brightness of the step change It has the advantage that the changes are perceived at approximately equal intervals at every stage.

According to the eighth aspect of the present invention, the relationship between the brightness and the light output is set as a different relationship according to the direction of increase or decrease of the light output, and the current value of the instruction value is changed each time the instruction value of the operation unit is changed. Since the relationship is set so as to connect the maximum value or the minimum value of the instruction value, or the two types of relationship adopted depending on the direction in which the instruction value of the operation unit is changed are fixedly set, Regardless of which relationship is used, it is possible to change the light output so as to correspond to the brightness as the visual perception in the increasing direction and the decreasing direction of the light output, and an advantage that the change in the light output does not cause a feeling of strangeness. Have.

According to a ninth aspect of the present invention, the relationship between the light output and the average value of the brightness obtained from the two kinds of relationships defined separately for the direction of increase and decrease of the light output, and one of the two kinds of relationships. Since the relationship between brightness and light output is set to one regardless of the direction of increase or decrease in light output, when setting a relationship for each direction of increase or decrease in light output. The accuracy of the correspondence between the brightness as the visual perception and the light output of the light emitting unit is lower than that of the above-mentioned method, but there is an advantage that the correspondence can be achieved with the accuracy of comparison with the conventional configuration. Moreover, since there is only one relationship, there is an advantage that the configuration is simple.

The invention of claim 10 is a concrete structure as a conversion means, and the structure is simple because a calculation is not necessary if a conversion table is used, and the specification of the light emitting part can be changed by using a function calculation circuit. There is an advantage that it can respond flexibly.

[Brief description of drawings]

FIG. 1 is a block diagram of a first embodiment.

2A and 2B show an operating device used in Example 1, where FIG. 2A is a vertical sectional view and FIG. 2B is a horizontal sectional view.

FIG. 3 is a front view of the main part of the operating device used in the first embodiment.

FIG. 4 is a front view of a main part of an operating device used in a second embodiment.

FIG. 5 is a block diagram of a fifth embodiment.

FIG. 6 is a block diagram of a sixth embodiment.

FIG. 7 is a block diagram of a seventh embodiment.

FIG. 8 is a diagram illustrating the operation of the embodiment.

FIG. 9 is an explanatory diagram showing an experimental process for explaining the operation of the present invention.

FIG. 10 is a diagram illustrating the principle of the present invention.

[Explanation of symbols]

 1 Manipulator 2 Function arithmetic circuit 3 Dimming signal generating circuit 4 Dimmer 5 Light emitting part 11 Operating part 11a Up switch 11b Down switch 12 Scale 12a Scale 12b Scale 19 Indication value generating part 20 Fade control part

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Takashi Saito 1048, Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Works Ltd. (72) Nobuo Iwata, 1048, Kadoma, Kadoma City, Osaka Matsushita Electric Works Ltd. (72) 72) Inventor Masaaki Ichikawa 1048 Kadoma, Kadoma City, Osaka Prefecture Matsushita Electric Works Co., Ltd. (72) Inventor Hiroaki Yasumi 1048 Kadoma, Kadoma City, Osaka Matsushita Electric Works Co., Ltd.

Claims (10)

[Claims] 1. In a dimming lighting device that changes the light output of a light emitting unit according to an instruction value of an operating device, a brightness as a visual perception and a light output as a physical quantity in an increasing direction and a decreasing direction of the light output. A dimming illumination device comprising conversion means for converting the brightness set by the instruction value of the operating device into a light output corresponding to the above relationship based on the relationship. 2. The conversion means is a scale indicating an indication value of the operating device, and a scale indicating an indication value different in an increasing direction and a decreasing direction of the light output is written. Dimming lighting device. 3. The dimming device according to claim 1, wherein the operating device is provided with an operating portion capable of performing a rotating operation or a straight-moving operation, and an operating amount of the operating portion and an instruction value are set in a proportional relationship. Lighting equipment. 4. The dimming lighting device according to claim 1, wherein the operation device includes an operation unit for numerically inputting an instruction value. 5. The operating device comprises an operating section for instructing directions of increase and decrease of light output, and an instruction value in a direction specified by the operating section in proportion to elapsed time during a period of operating the operating section. The dimming lighting device according to claim 1, further comprising: 6. The operating device comprises an operating section in which an instruction value can be set stepwise, and an operation portion after the change is made by gradually increasing or decreasing the instruction value with the passage of time when the step of the instruction value is changed. A dimming lighting device, comprising: a fade control unit for reaching an instruction value, wherein the instruction value output from the fade control unit has a constant amount of change in brightness per unit time. 7. The dimming control according to claim 1, wherein the operating device includes an operating section capable of setting an instruction value stepwise in a plurality of steps, and the instruction values at each step are set at equal intervals. Lighting equipment. 8. The conversion means sets the relationship between the brightness and the light output as a different relationship between the increasing direction and the decreasing direction of the light output, and sets the current value of the indicated value each time the instruction value of the operation unit is changed. It is characterized in that the relationship is set so as to connect the maximum value or the minimum value of the instruction values, or two kinds of relationships adopted depending on the direction in which the instruction value of the operation unit is changed are fixedly set. The dimming lighting device according to claim 1. 9. The relationship between the light output and the average value of the brightness obtained from the two kinds of relationships defined separately for the increasing direction and the decreasing direction of the light output as the relationship between the brightness and the light output in the converting means. , Or one of the two types of relationships described above is adopted, and the dimming lighting device according to any one of claims 1 to 7. 10. A conversion table that stores correspondence relationships for all combinations of brightness and light output that can be set as an instruction value of the operating device, and the optical output for the instruction value of the operating device is set as a functional expression as the converting means. 10. The dimming lighting device according to any one of claims 1 to 9, wherein any one of the function calculation circuits is adopted.