DE60309026T2 - LIGHTING CONTROL - Google Patents

Abstract

A lighting control apparatus 10 has at least one luminous flux control 21, 22, 23 for setting a predetermined luminous flux of at least one coloured light channel. A modulator 30 cyclically modulates the predetermined luminous flux using a least one of a predetermined cyclic period, a predetermined waveform and a predetermined modulation amplitude. Colour saturation and illumination level control may also be provided. Preferably the apparatus controls both DMX-enabled lights and non-DMX-enabled lights.

Description

The The present invention relates to a lighting control device.

In known lighting control devices for generating varying Color mixtures, such as in architectural lighting, The lighting is switched on by entering and saving controlled or controlled by different color settings or scenes, this being a fixed luminous flux of red, green and light sources blue and neutral tones, possibly yellow, as well as the cyclical traversal of the individual scenes. This involves entering and storing a large number from scenes ahead, which is a laborious and time-consuming process represents. Furthermore, overall a constant color saturation or to get lighting these factors for each generated scene should be set.

The U.S. U.S. Patent No. 5,530,322 discloses a lighting control system for controlling a plurality of lighting zones via a plurality of lighting control circuits. However, this does not disclose maintaining a whole predetermined luminous flux or a color saturation when the luminous flux is changed by light in different colors.

Of the present invention is based on the object, the above mentioned disadvantages according to the state to solve the technology at least partially.

Intended is according to one first aspect of the present invention, a lighting control device, a color light flow adjusting means for adjusting the corresponding one comprises a predetermined luminous flux of at least one color light channel, and with a modulation means for cyclically modulating the predetermined luminous flux using at least one predetermined cyclic period, a predetermined waveform and a predetermined one Modulation amplitude; characterized by a control device for controlling a neutral colored light channel for controlling a resulting color saturation total or a resulting total luminous flux of the neutral colored light channel and the at least one colored light channel, when the luminous flux of the at least one colored light channel cyclically is modulated.

Preferably the at least one colored light channel comprises at least one red light channel, a green one Light channel or a blue light channel.

Preferably If the neutral colored light channel is a yellow one Light channel.

In Suitably, the modulation device has a phase adjustment device for phasing a cyclic period of a first colored Light channel with respect to a cyclic period of at least one second colored light channel.

In Advantageously, the lighting control system comprises a Phase adjusting device that serves, at least the phase the first colored light channel to reverse or freeze in the relationship to the at least one second colored light channel.

In Suitably, the modulation means comprises a period adjustment means for Setting the predetermined cyclic period.

Preferably the modulation means comprises a waveform selection means for selecting the predetermined waveform.

In Advantageously, the waveform selector can be a waveform select a plurality of waveforms, preferably a linear rising waveform, a sine waveform, and a peak waveform having.

Preferably The modulation device comprises a modulation amplitude adjustment device for setting the predetermined modulation amplitude.

In Suitably, the lighting control device further comprises a lighting control corrector for converting a linear control signal to a linear luminous flux control a light source with a nonlinear relationship between the linear To provide control signal and the luminous flux.

In Advantageously, the lighting control device comprises Further, a fluorescent luminous flux control device for controlling the minimum luminous flux of device-controlled Fluorescent light sources.

Advantageously, the lighting control apparatus further comprises a chroma control means for controlling a signal representative of the luminous flux of the neutral colored light channel in response to a signal representative of the luminous flux of the at least one colored light channel controlled by the apparatus; wherein the chroma control device processing means for determining a value of a vector sum of signals representing the luminous flux of the at least one colored light channel and for determining a value of a scalar signal representing the neutral colored light channel around the sum of the value and the value of the scalar a predetermined constant value representing a predetermined desired color saturation of a combination of light sources controlled by the device.

alternative The lighting control device further comprises a control device for a constant illumination value for maintaining a predetermined Total light output, by adjusting a signal that has a luminous flux of the neutral colored light channel is dependent on signals, which represents the luminous flux of at least one colored light channel, wherein the constant illumination value device is a processing device for determining a value of the signal comprising the luminous flux represents the neutral colored light channel, leaving a scalar Sum of the luminous flux of the at least one colored light channel representing signals and the scalar signal representing the luminous flux represents the neutral colored light, remains constant, as the Signals can vary, which the luminous flux of the at least one colored light channel represent.

In Suitably, the lighting control device further comprises a Digital Multiplex (DMX) interface for controlling DMX-capable light sources and a Manchester coded digital interface for controlling non-DMX enabled Light sources.

The The present invention will now be described by way of example with reference to FIG the attached Drawings described. In the drawings show:

1 a simplified schematic diagram of a lighting control device according to the present invention;

2 a block diagram of the lighting control device 1 ;

3 a schematic representation of the polyphase oscillator of 1 and 2 ; and

4 a color space diagram useful for understanding the present invention.

In the pictures are the same components with the same ones Reference numerals designates.

Regarding the pictures of the 1 and 2 has a lighting control device 10 for example the sliders 21 . 22 . 23 for setting the basic values for the luminous flux for the corresponding red, green and blue light source channels. The corresponding outputs of the sliders are each equipped with a polyphase oscillator 30 so that the polyphase oscillator can modulate the fundamental values set by the sliders. This is in the picture 1 showing the output of the sliders 21 . 22 . 23 through the summing modules 41 . 42 . 43 with corresponding red, green and blue issues 31 . 32 . 33 of the polyphase oscillator 30 be summed so that the corresponding modulated outputs on the lines 411 . 421 . 431 result. A modulation amplitude input 34 goes to the polyphase oscillator 30 provided for selecting the depth or amplitude of the multiphase oscillator 30 generated modulation. A period setting input 35 is provided to determine the length of the period over which the polyphase oscillator passes 30 goes through cyclically. Like this in the picture 2 is shown in more detail, further inputs or inputs are provided: a waveform selector 36 for selecting the shape of a waveform of the modulation; a color mixture selector 37 possibly associated with associated signal lights, for selecting a type of a plurality of types of color mixing as described below generated by the polyphase oscillator; and a cycle direction selector 38 for selecting the freezing of the color mixing cycles or a direction in which the color mixture passes through the colors which may have associated indicator lights to indicate the selected status.

The modulated three-phase output on the wires 411 . 421 . 431 from the polyphase oscillator 30 , where one phase corresponds to one of the respective red, green and blue light channels, becomes a pastel control module 50 entered. The pastel control module 50 also has as input a pastel or chroma value selector 51 on.

An output of the pastel or chroma control module 50 is represented as a neutral light channel along with the outputs red, green and blue from the polyphase oscillator 30 entered into a blackout module, which makes it possible to darken one or more light channels through a blackout selector input 61 which may have an associated signal light, such as a light emitting diode (LED), to indicate when the dimming is operational. The output of the blackout module 60 is preferably linearly controlled using a four-wire bus Light sources are supplied and parallel to the inputs of a linear power conversion module 71 to a lighting control curve, such as for incandescent or halogen lamps, on a cold cathode conversion module 72 to apply a lighting control curve for cold cathode neon lamps, and to a fluorescence conversion module 73 to apply a lighting control curve for fluorescent lamps. The output of the fluorescent lamps may be through a digital interface using Manchester coding, and the output to other lamps may use a known Digital Multiplexer (DMX) protocol for lamp lighting control.

The is called, the device may have two separate digital outputs, a first one Output using a known RJ12 connection system for controlling digital phosphor display units, and a second Output to simultaneously provide the DMX output to DMX controlled Lighting systems, such as incandescent lamps, luminescent diodes or cold cathode or Glimmkathodenbeleuchtung. Thus, DMX-controlled lighting control units be used to glow consumers controlled with RGBY dichroic or other filters, and similar Lighting controllers can be used to suitable neon transformers for the scheme of RGBY neon / argon lighting to control. Alternatively or in addition can use an analog voltage protocol in combination with a digital-to-analog converter become. Suitable fluorescent light sources may include fluorescent tubes which in red, green, blue and maybe yellow filters are switched to a RGB mix with variable Heat under To provide use of the yellow source. The data connection to the fluorescence unit can be detected by a known concatenated RJ12 plug and socket system.

The fluorescence conversion module 73 is further provided with a minimum fluorescence value selector 731 their use is described below in the text.

In use, the basic values for the red, green and blue light channels are selected using the appropriate color selectors 21 . 22 . 23 to produce a required basic color to be modulated. The pastel control selector 51 is adjusted so that a required color saturation is generated to produce a desired heat of the color. The depth or amplitude control 34 is set to a required percentage or depth of the modulation to be applied to the basic values of red, green and blue by the polyphase oscillator 30 is determined. The depth of the change can be set in the range of 0% to 100 to realize either subtle hue changes or strong hue changes. The waveform selector is set to determine a shape of the modulation wave, such as a sine waveform, a linearly rising waveform, or a peak waveform generated by the polyphase oscillator 30 applied to the basic values of the selected red, green and blue values. The waveform selector can be designed to act individually on each of the light channels to select the same waveforms for all channels, which is normally sufficient. The period of the selected waveform, for example between 10 seconds and 24 hours per full cycle, is determined using the period setting selector 35 selected. A desired color mixture type, that is, the relative phase of RGB or using an additional yellow light channel, RGBY waveforms, for example, an RGB burst, to which a three phase waveform is applied to the three color outputs, or an RGBY color tracking cycle, using a four-phase waveform sequence is determined using the color mixture type selector 37 and the arrangement of using the cycle direction selecting direction 38 selected cycle selected.

in the Principle can the depth or amplitude of the modulation and the period of the cycle the waveform for each light channel selected differently which, in practice, has proven to be sufficient, the same depth and period for to select each light channel. The same adjustment of the period for each light channel leads to a repeatable color cycle, and this is usually desirable applies. In practice, it is likely that the absolute Depth of modulation for each Color channel is different because the modulated signal is a product of percentage depth modulation and that specified for that color Basic value is.

The operation of the multiphase oscillator 30 is going out in terms of the picture 3 best understood. The multiphase oscillator 30 has a clock generator 301 for generating a clock signal whose period through the period setting selection means 35 can be changed. The clock signal output of the clock generator 301 gets into a counter 302 entered by the input from the cycle direction selector 38 is controlled, depending on whether the counter is running forward or backward or whether the cyclic course is frozen. Multiple outputs from the counter are in waveform lookup tables 303 are input to generate waveforms through which the light channels are cyclic, the period through the period selector 35 is determined. The type of the waveform selected from the waveform lookup tables is set by setting the waveform selector 36 which has a three-line bus input to the waveform look-up tables corresponding to the three light channels, indicating the type of the selected waveform and the relative phases of the three light channels.

The three phases of the three-phase output of the waveform lookup tables 303 are output on separate lines corresponding to the three separate light channels, to corresponding modulation depth multipliers or amplitude modulators 341 . 342 . 343 , which are parallel by the depth or amplitude control 34 to adjust the amplitude of the selected waveform to be used so as to modulate the fundamental values of the light channels defined by the corresponding color selectors 21 . 22 . 23 as already described in the text.

For modulating the basic value signals from the corresponding color selection devices 21 . 22 . 23 become corresponding outputs or outputs of the depth multipliers or amplitude modulators 341 . 342 . 343 into corresponding basic color multipliers or amplitude modulators 211 . 221 . 231 which also inputs from the basic color selectors 21 . 22 . 23 receive. The corresponding outputs of the color multipliers or amplitude modulators 211 . 221 . 231 are then from the appropriate summing modules 41 . 42 . 43 with the primary color signals from the primary color selectors 21 . 22 . 23 so that corresponding modulated, phase color channels on respective output lines 411 . 421 . 431 be formed as described above in the text.

To better understand the operation of the lighting control device to automatically control the color saturation or the overall lighting can be seen on the figure 4 which shows a representation of the color space, wherein the directions of the vectors represent the color or hue, and wherein the length of the vectors represents the color saturation, ie the ratio of color to white light. The length of the vectors is weighted according to the relative strengths of the RGB sources and by a factor to account for the varying sensitivity of the human eye to different colors. The figure shows the vector addition of a red light component R, a green component G and a blue component B, resulting in a bright green.

The modulated signals on the wires 411 . 421 . 431 for the red, green and blue output from the polyphase oscillator 30 become the pastel or chroma control module 50 and a value for the neutral color channel is selected so that a sum of the value of a vector sum of the red, green and blue values and the scalar neutral value remains constant, as determined by the value represented by the pastel or chroma value. select direction 51 is selected. It will be appreciated that a pastel control can be automatically used with any known RGB color mixing system to vary the intensity of a fourth neutral color light source (preferably white or yellow), thus providing a range of accurately controlled pastel tones, ie, color saturation.

Like this in the picture 2 shown by dashed lines, may alternatively be a lighting control module 80 passing through a lighting setting input 81 are provided to obtain an overall constant illumination value from the light sources controlled by the device as the color mixture cycles through. In this case, a value of the neutral color channel is changed so that a scalar sum of the red, green, blue, and neutral values remains constant on that through the illumination adjustment input 81 selected value. Again, it will be appreciated that such a constant illumination value controller can be used in conjunction with many known RGB color mixing systems to automatically change the intensity of a neutral color light source (preferably white or yellow) to provide a range of accurately controlled illumination value , A master lighting value control may be provided (not shown) to all outputs ranging from 0-100% of the value entering a four-wire bus to the blackout module 60 to scale.

Thus, the polyphase oscillator is used to disturb the RGB baselines to provide a controlled trajectory through the color space as shown in FIG 4 to create. The software in the pastel control module or lighting control module then uses a fourth neutral light source accordingly to provide automated color saturation control of the lighting so that one of these properties is controlled during the color cycle.

In the picture in the picture 2 illustrated embodiment, the result The instantaneous value of the neutral light channel with the red, green and blue modulated outputs from the polyphase oscillator to the blackout module 60 where it can be used to clear all light outputs by reducing control outputs to zero, if desired.

The output of the blackout module 60 is fed directly to DMX-capable lamps to change the luminous flux from the blue, green, red and neutral colored lamps. The output also becomes parallel to the inputs of a linear power conversion module 71 to apply a lighting control curve for cold cathode lamps and to a fluorescence conversion module 73 to apply a lighting control curve for fluorescent lamps. The output to fluorescent lamps may be through a digital interface using Manchester coding, and the output to other lamps may use a known Digital Multiplexer (DMX) protocol for lamp lighting control. In this way, DMX-capable lamps and non-DMX-capable lamps can be simultaneously controlled by the same control unit.

Control units for fluorescent light devices usually have a "cut-off" light level below which the fluorescent tube is extinguished to extend the tube life.This feature may be included in the present invention, but may be prevented by the illumination control device turn off controlled fluorescent lamps at low light intensity, a minimum luminous flux for the fluorescent lamps through the selector 731 be set for a minimum fluorescence value, wherein the selection means with the fluorescence conversion module 73 connected is. Although the result of this adaptation is a slightly reduced hue and saturation range, the operation at low light level is softer because the tubes are not turned off and on during normal operation during one cycle of color mixing.

Intended is in accordance with the present Invention thus provides a digital color mixing illumination system for the synchronized Color mixing of fluorescence, cold cathode neon and other light sources with lighting control. The synchronized control is through the direct digital control of fluorescent light sources and the Using a DMX protocol to control other DMX-enabled lighting sources with lighting control.

Claims (14)

Lighting control device ( 10 ) having a color light flow adjustment device ( 21 . 22 . 23 ) for adjusting the corresponding predetermined luminous flux of at least one color light channel, and with a modulation device ( 30 ) for cyclically modulating the predetermined luminous flux using at least one predetermined cyclic period, a predetermined waveform and a predetermined modulation amplitude; characterized by a control device ( 50 . 80 ) for controlling a neutral colored light channel to control a total resulting color saturation or a resultant total illumination value of the neutral colored light channel and the at least one colored light channel when the luminous flux of the at least one colored light channel is cyclically modulated. A lighting control system according to claim 1, wherein the at least one colored light channel has at least one red light channel, a green light channel or a blue light channel. A lighting control system according to claim 2, wherein it is the neutral colored light channel around a yellow light channel is. Lighting control system according to one of claims 1 to 3, wherein the modulation means comprises a phasing means for phasing a cyclic period of a first colored Light channel with respect to a cyclic period of at least one having second colored light channel. A lighting control system according to claim 4, wherein said lighting control means ( 38 ) which serves to reverse or freeze at least the phase of the first colored light channel in relation to the at least one second colored light channel. A lighting control device according to any one of the preceding claims, wherein the modulation means comprises period adjustment means (14). 35 ) for setting the predetermined cyclic period. A lighting control apparatus according to any one of the preceding claims, wherein said modulating means comprises waveform selection means (14). 36 ) for selecting the predetermined waveform. A lighting control apparatus according to claim 7, wherein the waveform selecting means may select a waveform of a plurality of waveforms, preferably linearly has a lower waveform, a sine waveform, and a peak waveform. Illumination control device according to one of the preceding claims, wherein the modulation device ( 30 ) comprises modulation amplitude adjustment means for adjusting the predetermined modulation amplitude. A lighting control device according to any one of the preceding claims, wherein said lighting control means ( 71 . 72 . 73 ) for converting a linear control signal to provide linear luminous flux control of a light source having a nonlinear relationship between the linear control signal and the luminous flux. A lighting control apparatus according to any one of the preceding claims, further comprising a fluorescent luminous flux control means (10). 731 ) for controlling the minimum luminous flux of device-controlled fluorescent light sources. Illumination control device according to one of the preceding claims, wherein the control device ( 50 ) controls a signal representing the luminous flux of the neutral colored light channel, in response to a signal representing the luminous flux of the at least one colored light channel controlled by the device; wherein the chroma-controlling means comprises processing means for determining a value of a vector sum of signals representing the luminous flux of the at least one colored light channel, and for determining a value of a scalar signal representing the neutral colored light channel by the sum of the value Value of the scalar to a predetermined constant value representing a predetermined desired color saturation of a combination of light sources controlled by the device. A lighting control device according to any one of claims 1 to 11, wherein said control means ( 80 ) maintains a predetermined light output as a whole by adjusting a signal representing a luminous flux of the neutral colored light channel in response to signals representative of the luminous flux of at least one colored light channel, the constant illumination value means comprising processing means for determining a value of the signal representing the luminous flux represents the neutral colored light channel, so that a scalar sum of the signals representing the luminous flux of the at least one colored light channel and the scalar signal, which represents the luminous flux of the neutral colored light remains constant, since the signals can vary which the luminous flux of the at least one represent colored light channel. Lighting control device according to one of previous claims, and further comprising a digital multiplexing (DMX) interface for controlling from DMX-enabled Light sources and a Manchester-coded digital interface to control non-DMX enabled Includes light sources.