SE533554C2 - Device and method for contact-free control of light source - Google Patents

Description

533 554 2 Although the above-mentioned solution certainly provides the opportunity for desirable non-contact control of the light of a light source, there is more to be desired in terms of the user-friendliness of the control; thus, there is a need for an improved device for non-contact control of a light source.

Summary of the invention The purpose of the present invention is to at least partially try to remedy the above problems.

According to a first aspect, this and other objects are achieved with a device for non-contact control of a light source in accordance with that specified in claim 1.

The present invention thus introduces a device for non-contact control of a light source, which device via adjustment of the indicator intensity of said indicator based on detected light, enables a user to get an intuitive response on how he / she controls the light source. For example, the closer the user places his hand over the sensor, the more light is reflected from the transmitter, and consequently, the more light the transmitter reflects, the more light of the first wavelength is detected by the detector. It should be noted that the purpose of "optical transmitter arranged to emit light of a first wavelength" is not to limit the light to a unique wavelength, but that the term is considered to include a peak power wavelength with adjacent wavelengths. The "first wavelength" can thus rather than consist of a single wavelength, consist of several wavelengths.

Furthermore, the amount of detected light is represented by the first wavelength of a signal which in turn affects the intensity of the light source. If the user places his hand further away from the sensor, the intensity of the light source will consequently be lower.

It may be desirable to have an inertia in the connection between the hand movements over the sensor and the resulting change in the intensity of the light source, ie. that the latter does not change too quickly and / or too jerkily.

By immediately adjusting the indicator intensity when detecting reflected light, the indicator can point out to the user - without delay - that his hand is within the sensor's sensing range and thus affects the control of the light source. the indicator thus simplifies for the user in that he by studying the change of indicator intensity in connection with the hand being transferred over the sensor can gain an acceptance of whether the hand is within the sensing range or not, and thus perform a slow and controlled control. of the intensity of the light source without overcompensating for hand movements.

If the hand is outside the sensor's sensing range, for example, the indicator intensity can be controlled to be zero or weak, and if the hand is within the sensing range, intensity can be controlled to a stronger intensity.

The invention thus provides a solution which gives the user a user-friendly response to ongoing control of the light source, and enables, for example, controlled control of a light source which may be located separately from the device, such as out of sight of the user. comprises three LEDs emitting red, green and blue light, respectively, the light source parameters are controlled based on the respective amount of reflected light by said first, second and third wavelengths detected by the respective three detectors. For example, a combination of a certain amount of detected reflection of the first, second and third wavelengths may lead to the light source being controlled by a certain light composition, while other combinations of detected reactions may lead to other light compositions. Thus, the amount of detected reflected light of the respective wavelength can be used to affect the intensity of the light source in combination with which or which of the said first, second and third detectors detect reflection to affect the color balance of the light source. Accordingly, the said embodiment enables for non-contact control of the light composition of a light bowl in the three-dimensional color space. The user does not have to perform fl your actions, such as changing the mode of the device, to control the color balance and the intensity of the light source; both parameters can be determined and controlled at the same time, under one and the same influence by the user. Suitably the effect consists in the user placing the hand at the desired distance from the device above, or obliquely above, the first, second and / or third sensor.

The respective first, second and third indicators may be adapted to indicate with individual indicator intensity the amount of corresponding detector reflected light. Should the user not feel satisfied when interpreting the composition of the indicator intensities, he / she can adjust the position of the hand and immediately via the indicator intensities get a response on how the movement affects the control of the light source. Furthermore, the user holds his hand over, for example, the second and third sensors but not over the first, only light of the second and third wavelengths will be detected, the light composition of the light source being controlled accordingly and the first indicator intensity in order to give the user intuitive feedback suitably. to be set to be extremely weak or even zero.

Furthermore, the control unit may be adapted to adjust said indicator intensity in relation to said signal. According to such an embodiment, the indicator intensity can be adjusted steplessly in relation to the signal, in other words indirectly in relation to the light source intensity, with immediate indicator intensity change in indirect relation to the distance between the user's hand and the sensor when the hand is moved within the sensing range. In other words, by simply following changes in the indicator intensity while moving the hand up and down above the sensor, the user can get an idea of the degree to which the intensity of the light source changes. The intensities of the light source and the indicator do not necessarily have to follow each other linearly, but the indicator intensity can be further adjusted with, for example, the use of weighting factors. Thus, the intensity of the indicator can be adjusted e.g. based on the ambient volume or brightness, which enables improved possibilities to give the user an intuitive response. In order to avoid additional light when the hand is at the limit of a sensitivity range for the sensor, the control unit may further be adapted to start controlling said indicator intensity only when said first signal exceeds an adaptive threshold value. Utilization of threshold values in the form of adaptively variable limits may thus mean that a required minimum level of reflected light needs to be detected for the control device to start operating. Preferably, in the event of a mains switch-on, all reflected light that depends on the environment can be measured, and the limit for impact is then set by a relatively large margin to ambient reactors. When the sensor eventually comes into contact with a user's hand, the threshold value can be lowered, and new threshold values are continuously calculated accordingly.

Said indicator can suitably e.g. for reasons of space are included in the sensor, and further consist of a sound indicator which, for example, emits volume or sound frequency in relation to the signal. However, in order to further illustrate to the user the control of the intensity, the indicator may comprise a light indicator arranged to emit visible light. This enables the user to respond with a visual feedback, which represents an intuitive response. Furthermore, in the case that the indicator intensity can be adjusted in relation to the signal, the visual feedback can become even clearer in that the light indicator in the event of changes in the intensity of the light source has its amount of light adjusted in relation thereto. 533 554 The transmitter may be arranged to emit light within the infrared light range, but may also alternatively comprise said light indicator. In the latter case, the light emitting from the light indicator suitably constitutes the light which is stated to be of a first wavelength, which after reaction is intended to be detected by the detector. This reduces the need for a separate transmitter and light indicator, respectively, as the transmitter is thus not only adapted to emit light of a first wavelength, but also to represent the light indicator and the property of adapting light intensity of the emitted light based on the signal. In order to enable a sensing area in the form of a controlled albeit sufficient space within which a user can influence the reaction of the transmitter, said sensor may comprise a lens arranged to focus light emitted from said transmitter led in space extended plane. Focusing the emitted light on so that the sensor's sensing area forms a plane extending in space rather than, for example, a point allows the user to influence the reaction within the entire plane's range, thus not having to place the hand directly over the sensor without a placement. obliquely above can give the same result.

The device may further comprise a bandpass filter adapted to substantially transmit said reflected light. The bandpass filter enables the filtering of light other than that reflected from the transmitter, whereby light such as daylight or light bulb lighting can be disregarded as input parameters when controlling the intensity. For example, the transmitter emits pulsating high-frequency light, whereby the detector via the bandpass filter is adapted to be only sensitive to this pulsating light.

It should be noted that the wording regarding the bandpass filter "mainly" adapted to let through said reflected light is intended to be interpreted as meaning that the reflected light is the light that is largely let through, while smaller parts of unwanted light to some extent may not be completely can be filtered out.

In order to further improve the user-friendliness and give the user a visual response to the control in the three-dimensional color space, said first, second and third indicators can be arranged to emit lights with different wavelengths. In this way, the user is greeted with different colors from the first, second and third indicators, respectively, whereby the user is given the opportunity to more easily distinguish which of the first, second and third detectors detects reflected light from his corresponding transmitter. 533 554 6 Suitably the colors of the indicators represent the colors of which the light source consists. Consequently, when the light source consists of a corresponding red, green and blue, e.g. LED in order to be able to cover the entire three-dimensional color space, said first, second and third indicators can be arranged to emit light of wavelengths corresponding to red, green and blue respectively. This gives the user a particularly intuitive response to the control of the light source in that he / she, by studying the respective color indicator and its intensity, gets a direct idea of how the LED of the corresponding color in the light source is affected by the position of the hand over the sensors. In order to give the user the opportunity to in a simple manner be able to influence one, two or all sensors at one and the same time, said first, second and third sensors can be arranged in such a way that light emitted from said respective transmitter forms a corresponding equilateral triangle. in relation to each other. Thus, the user can choose to place, for example, one of the sensors, for example one ovan slightly above, or obliquely above, the corresponding sensor, to influence two of the sensors, for example place one or several fingers suitably above the corner where the two sensors concerned meet, and to affect all three sensors, for example, place the whole hand above the sensors in such a way that all sensors are affected and thus light of the first, second and third wavelengths is reflected.

In cases where you choose to use the light indicators as a transmitter, the phenomenon can arise that e.g. the user's skin reflects different wavelengths differently; for example, the skin reflects red light better than blue. Accordingly, the device may comprise an amplifier arranged to amplify said first signal by a first factor and said second signal by a second factor which differs from said first factor. Thus, signals related to the first, second and third wavelengths, respectively, can be amplified in an appropriate manner and thereby compensate for e.g. the properties of the skin to reflect the respective wavelengths differently.

Furthermore, the present invention comprises a lighting device comprising a device for non-contact control of a light source according to the above, and at least one light source connected thereto. With such a lighting device, advantages as presented above can be achieved. Note that fl your light sources can be controlled at a time or alternately, this would be desirable.

According to a second aspect, a method for non-contact control of a light source is provided in accordance with that set out in claim 15. 533 554 7 The corresponding advantages presented above in connection with the first aspect of the invention are also applicable to the second.

Brief Description of the Drawings Particularly preferred embodiments of the present invention will now be described in more detail, by way of example, with reference to the accompanying drawings.

Figure 1a shows a block diagram of an exemplary lighting device comprising a device for non-contact control of a light source in accordance with a first embodiment of the present invention.

Figure 1b illustrates the lighting device in figure ia with an alternative wireless control of the light source, in accordance with a second embodiment.

Figure 2 shows in side view a part of the control device 2 illustrated in Figure 1a.

Figure 3 is a flow chart of exemplary method steps that may be performed in connection with the device illustrated in Figure 1a.

Description of Preferred Embodiments The present invention will be described in more detail below with reference to the accompanying drawings, which show current preferred embodiments of the invention. The invention may, however, encompass many different embodiments and should not be construed as limited to the embodiments shown herein; rather, these embodiments are provided for the purpose of clarifying, completing, and fully expressing the scope of the invention to those skilled in the art.

Figure 1a shows a block diagram of an exemplary lighting device 1 comprising a device 2 for non-contact control of a light source 3 in accordance with a first embodiment of the present invention. An external influence 8 can be represented by, for example, a finger, a number of fingers or an entire hand as well as any object that can be placed and transferred over the touch device 2, whereby a user can be given the opportunity to influence the control of the light source 3. Although the lighting device 1 in the stated example only comprises a single light source 3, however, the invention is not limited thereto; any number of light sources 3 may be included for common or alternating control via the control device 2. The light source 3 may be arranged to emit light of any type, and may thus comprise, for example, one or more traditional light bulbs, LEDs and / or other types of light emitting units. Figure 1a comprises the light source a red 31, a green 32 and a blue 33 LED, respectively, and can thus, through various combinations of these primary colors, support an almost infinite number of colors of varying intensity. It should be clarified again, however, that said diodes 31, 32, 33 do not necessarily have to be arranged to emit light of respective red, green and blue color, respectively, but that the wavelengths of the light as indicated above can be arbitrary.

To control the light source 3, the non-contact control device 2 comprises a control unit 4, which in turn may comprise a plurality of modules required for the control. In the exemplary first embodiment, the control unit 4 comprises a memory 41, a microprocessor 42, an amplifier 43 and a bandpass filter 44. Note that the control unit 4 is in no way limited to comprising only one of the respective modules 41, 42, 43, 43 or even all of them, but rather may include a preferred number of respective modules 41, 42, 43, 44 preferred for the particular implementation.

The control unit 4 is further connected to a sensor part 5, comprising one or a number of sensors. Figure 1a comprises the sensor part 5 three sensors: a red 51, a green 52 and a blue 53 respectively. Note, however, that the invention is not limited to danill but rather may comprise a single sensor arranged to emit light of arbitrary wavelengths, or an arbitrary number of sensors arranged to emit light of similar or different colors. Note thus that the emitted light may be within the visible light range, but may still be infrared light. In order to enable the sensors 51, 52, 53 to emit light, these may respectively comprise an optical transmitter. In the example given, the transmitters are LEDs of corresponding colors, ie. of a respective red 531, green and blue LED. These LEDs are arranged to emit light of a first 6, second 10 and third 11 wavelength, respectively, corresponding to red 6, green 10 and blue 11 light respectively. Note that the transmitter 511 is not necessarily an LED and is not necessarily adapted to emit light limited to a single wavelength, but rather can emit a peak power wavelength with surrounding wavelengths which together can form said red light 6.

Due to the principal similarities between the respective sensors 51, 52, 53, essentially only the red sensor 51 is described, implicitly that also the green 52 and the blue sensor 53 comprise corresponding or similar components, and exhibit corresponding behavior. The red sensor 51 further comprises a lens 512, such as for example a cylinder lens, which enables red light 6 which can be emitted from said transmitter 511 to be able to be focused in a plane 7 extending in space. The cylindrical lens 512 may for instance be adapted to focus the plane 7 in such a way that it extends straight up perpendicularly, or slightly obliquely, in relation to how the cylinder lens 512 is arranged over the red transmitter 511. The plane 7 can thus constitute a pulpit area, a space, within which a user's example | 8 has the ability to affect red light 6 emitted from the red transmitter 511.

The red sensor 51 may further comprise a detector 513, such as a phototransistor or photodiode. The detector 513 may be arranged to receive reflected light of said first wavelength 6, the reaction of which may occur if the red light 6 were to bounce against, for example, the hand 8.

In order to clarify to a user which of the respective sensing areas 7 affects him when the hand 8 is moved or placed above the sensor part 5, the control device 2 may further comprise a respective indicator associated with the respective sensors 51, 52, 53. the indicator may for example be of a sound indicator that can be adapted to emit volume or sound frequency based on the amount of detected reflected light detected by the associated sensor. Alternatively, and as is the case in the embodiments of Figure 1a, the indicator may be a light indicator arranged to emit light, such as, for example, any visible light, based on the amount of detected reflected light detected by the associated sensor. It should be clarified that the visible light, although it may be considered appropriate, need in no way be of a color corresponding to the 6 which the sensor 51 to which the indicator is associated is adapted to emit. Furthermore, the indicator may preferably, although not necessarily, be included in the sensor 51 with which it is associated. In addition, the indicator as illustrated in Figure 1a may also be included in the corresponding transmitter 511, whereby the indicator and transmitter can thus be based on and consist of one and the same LED 511.

The sensors 51, 52, 53 can, as illustrated in the example, be arranged in such a way that light emitted from the respective sensors in space form a corresponding equilateral triangle in relation to each other, and the possibility is thus given for the user to be able to influence a , two or all three sensors at once. This can be achieved, for example, in that the sensors 51, 52, 53 are positioned corresponding to an equilateral triangle relative to each other so that a plane 7 created by 533 554 emitted light 6 from one of the sensors 51 forms an equilateral triangle relative to the corresponding plane which created by the other two sensors 52, 53. Alternatively, the same effect can be achieved by corresponding focusing adjustment of the respective cylinder lens 512. Note that the sensors 51, 52, 53 may be positioned in other ways, such as for example in a row and slightly offset relative to each other, or in an arbitrary manner in accordance with what can be considered appropriate for the current implementation.

According to the embodiments illustrated in Figure 1a, the control device 2 is wired connected to the light source 3. However, the invention is not limited thereto, but as illustrated in Figure 1b, one or more light sources 3 'may alternatively be controlled wirelessly according to a second embodiment. In general, the parts in Figure 1b are almost identical or similar to those illustrated and described in Figure 1a, so that only distinct differences will be elucidated in the following. According to the second embodiment, the lighting device 1 'may comprise a control unit 4', which in addition to the previously mentioned modules 41, 42, 43, 44 may also comprise a module 45 for wireless communication with the light source 3 '. The module 45 for wireless communication may comprise required components for support of arbitrary wireless communication protocol, for example IR communication or radio communication such as e.g. Zigbee.

In order to be able to be controlled wirelessly, the light source 3 'can also comprise necessary components, such as for instance an antenna 9.

With reference to Fig 2 which illustrates in side view a part of the control device 2 shown in Fig 1a, further exemplary components applicable to the first embodiment will now be described. Figure 2 illustrates how the red transmitter 511, also the indicator, can be arranged in relation to the cylinder lens 512 and the detector 513.

Preferably, these are arranged so that red light 6, arranged to be emitted from the transmitter 511 via the cylinder lens 512, can be focused in space in such a way that the light 6 when a user places or for his hand 8 over the sensor 51 can bounce back towards the detector 513. Note that the detector 513 relative to the transmitter 511 can be placed in a lower position, whereby light 6 emitted directly from the transmitter 511, i.e. light which has not been re-reflected can to a greater extent avoid being detected by the detector 513. In order to to some extent re-reflect the inserts of the detector 513 from light other than that of the corresponding transmitter 511, the detector 513 may further be surrounded by a screen 20, such as for example a circumferential tube. Thus, the detector 513 can be made less sensitive to ambient light such as daylight, to other ambient lighting, as well as to reflected light from other sensors 52. 53 than the sensor 51 in which said detector 513 is included.

Furthermore, Figure 2 shows how the red sensor 51 can be integrated on a circuit board 21, and how other electronics 22 comprising the above-mentioned control unit 4 and, for example, drive steps towards both transmitter 511 and light source 3 can be arranged in relation to danill. Sensor 51, circuit board 21 and electronics 22 may further comprise, for example, an enclosing housing 23 such as an acrylic disc, an upper part such as a stainless steel cover plate 24 and a lower part such as a metal base board 25. In order to provide a tennis coupling between the upper and lower part 24, 25, the control device 2 may further comprise an element arranged between the parts 24, 25 with corresponding properties, such as for instance a brass profile 26. Note that the above-mentioned surrounding parts 23, 24, 25 and the choice of material thereof are only of an exemplary nature, and that the scope of the invention thus should not be considered limited to these. In operation of the lighting device 1, the non-contact control of the light source 3 can be a continuous process, which enables dynamic changes of the light composition of the light source 3 over time. With reference to Figure 3 in combination with Figure 1a, a fate diagram will now be described, which illustrates exemplary method steps that can be performed in connection with the device illustrated in Figure 1a. It should be noted that the following steps do not necessarily have to be performed in the order given below, but can to some extent be reversed and / or partially performed simultaneously.

In a first step 302, either or all of the red 51, green 52 and blue sensor 53, respectively, may emit light of wavelengths first 6, second 10 and third 11, respectively. For the red sensor 51, the light of the first wavelength 6, i.e. the red light, is thus transmitted via the included red transmitter 511, which according to the first embodiment preferably but not necessarily also acts as a corresponding red indicator. The transmitter 511 may, for example, although not necessarily operate with a pulsating light 6.

As long as no external influence 8 is performed, the light composition of the light source 3 can be seen as unaffected by the control device 2. However, as soon as a user places or moves his hand 8 over the sensor part 5, in a next step 304 light emitted from any or all of the sensors 51, 52, 53 are caused to bounce back against the respective sensor.

As a result of the transmitted light being caused to be reflected in step 306, the respective sensors 51, 52, 53 can thus receive reflected light of the 533 554 12 and first 6, second 10 and third 11 wavelengths, respectively, which for the red sensor 51 can take place by means of the included red detector 513. Whether only one or all of the first 6, second 10 and / or third 11 wavelengths are reflected can be determined by where the user places his hand 8 over the sensor part 5. An 8 8 placed only over the red sensor area 7 can lead to the fact that only light of the first wavelength 6 is re-reflected to the red sensor 51, while a sensor 8 placed as illustrated in Figure 1a over the corresponding green and blue sensing range can lead to only light of the second 10 and third 11 wavelengths being re-reflected to the respective green and blue sensor 52, 53. Placing the entire hand 8 over all sensors 51, 52, 53 can thus lead to all three wavelengths 6, 10, 11 being reflected. In order to effectively ensure that the red sensor 51 for the most part only receives reflections of the light 6 which the sensor 51 itself produces, the red detector 513 can be made to filter out the corresponding light 6 by means of the bandpass filter 44. Consequently, the red the detector 513 by means of the bandpass filter 44 filters out, for example, pulsating emitted reflected red light 6, and largely filters out daylight as well as incandescent lighting and reflected green 10 and blue light 11, respectively. Note that the bandpass filter 44 is not considered necessary according to certain embodiments; for example, the need for bandpass filters 44 is less for sensors 51, 52, 53 arranged to emit infrared light than for sensors 51, 52, 53 arranged to emit visible light. In step 308, signals can be obtained by means of the control unit 4, which signals represent corresponding amounts of re-detected detected light. A first signal may represent the amount of reflected light of the first wavelength 6 detected by the red sensor 51, a second signal may represent the amount of reflected light of the second wavelength 10, i.e. green light, which is detected by the green sensor 52, and a third signal may represent the amount of reflected light of the third wavelength 11, i.e. blue light, which is detected by the blue sensor 53.

Due to the fact that human skin tends to react different wavelengths to different amounts, the first, second and third signals, respectively, in step 310 can be amplified differently to remedy this phenomenon. Thus, amplifier 43 may amplify the first signal by a first factor, the second signal by a second factor, and / or the third signal by a third factor. For example, by amplifying the third - blue - signal more than the first - red - signal is amplified, the signals after the amplifications 533 554 13 can thus be weighted appropriately to be virtually independent of the skin's ability to re-reflect red light 6 better than blue 11.

Based on the signals obtained, the respective indicator intensity of the indicators can then be controlled in step 312. By feeding the values of the first, second and third signals, respectively, which correspond to the amount of reflected light of the first 6, second and third 11, respectively, to the wavelength of the microprocessor 42, the indicator intensities can be controlled relative thereto.

According to the first embodiment illustrated in Figure 1, the red transmitter 511, as previously pointed out, also constitutes the light indicator, whereby the indicator intensity which is adjusted based on the first signal in this case may thus consist in adjusting the light intensity of the transmitter 511 itself.

The adjustment of indicator intensity preferably takes place, although not necessarily relatively immediately, whereby the user can receive direct feedback on how the position of the hand 8 affects the control of the light device 3. the intensity of the red transmitter 51 can assume two positions; a rather weak light intensity in the case that no reaction of the first wavelength 6 is detected by the red detector 513. and a stronger light intensity in the case that said reaction is detected. Alternatively, an indicator intensity can be adapted to be adjusted in relation to the signal from which it is controlled, and can thus be adapted, for example, steplessly based on the changes in the value of the signal. Due to the fact that the amount of reflected light emitted detected can be in direct proportion to the distance to the external influence 8, indicator intensity in this case can consequently indicate just this; the closer to the hand 8 the red detector 513 is located, the stronger light intensity is emitted from the transmitter as well as the light indicator 511. In step 314, control of the light composition of the light source 3 can be achieved by means of said control unit 4 and the obtained signals.

By feeding the values of the first, second and third signals corresponding to the amount and respectively of reflected light of the first 6, second and third wavelengths 11, respectively, to the microprocessor 42, the light composition of the light source 3 can be controlled in relation to these values. In other words, by allowing the signal values to form the basis for calculations of the light composition of the light source 3, the light source 3 can thus be controlled based on how the user chooses to place his hand 8 over the sensor part 5, and thus in relation to how much light is detected by each wavelength. In the illustrated example in Figure 1, as previously stated, the light source 3 comprises a red 31, green 32 and blue LED 33, respectively, and the light composition of the light source 3533 can thus move in a three-dimensional color space.

Through different combinations of the three LEDs 31, 32, 33 both the intensity of the light source 3 and the color balance can be adjusted, and this adjustment is thus controlled by the user's movements 8 over the sensor part 5 and that the control unit 4 based on the resulting signals then controls the light source 3 relative thereto. For example, the setting of the red LED 31 of the light source 3 may be based on the first signal, the setting of the green LED 32 may be based on the second signal and the setting of the blue LED 33 may be based on the third signal.

Preferably, although not necessarily, the adaptation of the light composition of the light source 3 to the values of the signals takes place with a certain delay. This delay can be arbitrary, for example from a few tenths of a second up to a few seconds. Furthermore, advanced ramp levels of reflected light can be the basis for when the microprocessor 42 allows an external influence 8 to have an impact in the light composition of the light source 3, which b | .a. aims to avoid light adder of the light device 3 as a result of, for example, a trembling fi 8 ger 8.

According to the exemplary first embodiment illustrated in Figure 1 and referred to in Figure 3, as previously stated, the light source 3 consists of said red 31, green 32 and blue LED 33, respectively, while the sensor part 5 consists of said red 51, green 52 and blue sensor 53, respectively. Furthermore, the respective indicator is included in the respective transmitter, and in Figure 1, the red transmitter 511 thus also constitutes the corresponding red indicator.

These conditions have the effect that the red indicator 511 of the sensor part 5 can represent the red LED 31 of the light source 3, where the same also applies to the respective green and blue indicators in relation to the green 32 and the blue LED 33. Thus, in that the red indicator 511 as well as the red LED 31 of the light source 3 can be controlled by the first signal, the user can by studying the red indicator 511 get an idea of how he affects the light settings for the red LED 31 of the light source 3. It should be clarified, however, that the red the light settings of the sensor 31 and the light intensity of the red indicator 511 in the case that the latter is controlled in relation to the first signal, do not in any way have to follow each other linearly. For example, the microprocessor 42 can implement previously reported delays and ramp levels, and furthermore the indicator intensity as well as the light composition of the light source 3 could be adapted by means of the microprocessor 42 with weighting factors and hence ambient light conditions are taken into account.

When the user eventually removes his hand 8 in step 316, the settings which for the moment constitute the light composition of the light source 3 can preferably be maintained. Thus, in subsequent steps 318, the current light composition settings can be stored in the memory 41, and the light composition of the light source 3 is thus maintained until a new external influence 8 causes changed signal values with subsequent new light composition.

A determination of whether the light composition settings should be stored can be based, for example, on the speed at which the hand 8 is removed from above the sensor part 5; preferably a rapid removal can trigger the storage while slow for fl expansions 8 can be interpreted as continued action intended to set the light composition of the light source 3.

It should be clarified that all three illustrated sensors 51, 52, 53 do not necessarily have to be active, ie. be used; it is also quite possible and within the scope of the invention to perform control of the light source 3 by means of a single sensor. The consequence of this may be that instead of being given the opportunity to control light emitted from the light source 3 in a three-dimensional color space in the form of color balance and intensity, the control may be limited to affecting only the intensity of the light source 3, not color balance. Furthermore, it can again be clarified that the light source 3 does not necessarily consist of three LEDs 31, 32, 33 adapted to emit red, 6, green 10 and blue light 11, respectively, but according to some embodiments may comprise fewer or more LEDs adapted to emit colors other than the above, or even include one or fl of your non-LED light generators. The consequence of this can also in this case be that only the intensity of the light source 3 can be affected rather than a light composition in a three-dimensional color space, regardless of the number of sensors 51, 52, 53 in the sensor part 5.

The present invention has thus been described with the aid of exemplary embodiments. However, those skilled in the art will appreciate that the scope of the invention is in no way limited to the above-mentioned embodiments, but also, for example, covers control devices which comprise only one sensor, or where two sensors are considered applicable. Furthermore, it should again be clarified that although in the above-mentioned embodiments the indicators consist of the transmitters themselves, these may in alternative embodiments be separate components and the control device thus adapted to support these separately. 533 554 16 In addition, the person skilled in the art realizes that the control device can also use threshold values in the form of adaptively variable limits, whereby a minimum level of reflected light may be required for the control device to start acting. Preferably, in the event of a mains switch-on, all reflected light that depends on the environment can be measured, and the limit for impact is then set by a relatively large margin to ambient reactors. When the sensor eventually came into contact with a user's hand, the threshold value could be lowered, and new threshold values could be continuously calculated accordingly. Thus, the sensor can have an adaptively calculated threshold value with a certain hysteresis, whereby the addition of the light source's emitted light when the hand settles at the limit of the sensor's sensitivity range can be avoided.

Furthermore, it is understood that in addition to being controlled via the user's influence, the light composition of the light source can be supplemented with control via pre-programming of the microprocessor. Such pre-programming could, for example, control the light source according to a preselected behavior selected by the user and be represented by random light compositions that vary over time.

Finally, it should be further understood that units, elements and the like illustrated in the drawings are not necessarily to scale.

Claims (15)

10 15 20 25 30 35 533 554 i? PATENT REQUIREMENTS A device (2) for non-contact control of a light source (3), which device (2) comprises: at least a first sensor (51) comprising a first optical transmitter (511) arranged to emit light of a first wavelength (6) and a first optical detector (513) arranged to receive reflected light from said optical transmitter (511) arising by an external influence (8) of a user, a first indicator (511), and a control unit (4) adapted to receive a first signal representing the amount of light of said first wavelength (6) detected by said first detector (513), said control unit (4) further adapted to control intensity of light emitted from said light source (3) relative to said first signal and indicator intensity of the indicator (511) based on said first signal, and wherein the device (2) further comprises: a second sensor (52) comprising a second optical transmitter arranged to emit light of a second wavelength (10) and a second optical detector arranged to receive reflected light from said second optical transmitter arising from an external influence (8) of a user, characterized in that the device further comprises: a second indicator, a third sensor (53) comprising a third optical transmitter arranged to emitted light of a third wavelength (11) and a third optical detector arranged to receive reflected light from said third optical transmitter arising from an external influence (8) by a user, and a third indicator, whereby said control unit (4) is further adapted based on the first signal, a second signal representing the amount of light of said second wavelength (10) detected by said second detector and a third signal representing the amount of light of said third wavelength (11) detected by said third detector control light emitted from the light source (3) in a three-dimensional color space. 10 15 20 25 30 35 533 554 IS Device (2) according to claim 1, wherein said control unit (4) is adapted to adjust said indicator intensity in relation to said first signal. Device (2) according to claim 1 or 2, wherein said control unit (4) is adapted to start controlling said indicator intensity only when said first signal exceeds an adaptive threshold value. A device (2) according to any one of the preceding claims, wherein said sensor (51) comprises said indicator (511). Device (2) according to any one of the preceding claims, wherein said indicator (511) comprises a light indicator. The device (2) according to claim 5, wherein said transmitter (511) comprises said light indicator. Device (2) according to any one of claims 1-5, wherein said transmitter (511) is arranged to emit light within the infrared light range. Device (2) according to any one of the preceding claims, wherein said sensor (51) comprises a lens (512) arranged to focus light (6) emitted from said transmitter (511) in a space-extending plane (7). ). A device (2) according to any one of the preceding claims, wherein the device (2) further comprises a bandpass filter (44) adapted to substantially transmit said reflected light. A device (2) according to any one of the preceding claims, wherein said first (511), second and third indicators are arranged to emit light of different wavelengths. A device (2) according to any one of the preceding claims, wherein said first (511), second and third indicators are arranged to emit light of wavelengths corresponding to red (6), green (10) and blue (11) respectively. 10 15 20 25 30 35 533 554 | ° l Device (2) according to any one of the preceding claims, wherein said first (51), second (52) and third (53) sensors are arranged in such a way that light (6), (10), (11) which transmitted from said respective transmitters (51, 52, 53) correspondingly form an equilateral triangle in relation to each other. A device (2) according to any one of the preceding claims, wherein the device (2) further comprises an amplifier (43) arranged to amplify said first signal by a first factor and said second signal by a second factor which differs from said first factor. . Lighting device (1) comprising: a device (2) for non-contact control of a light source (3) according to any one of claims 1-13, and at least one light source (3) connected thereto. A method of non-contact control of a light source, the method comprising: emitting (302) light of at least a first wavelength by means of a first optical transmitter (511) which is included in a first sensor (51); emitting (302) light of a second (10) and third (11) wavelength, respectively; receiving (306) reflected light from said transmitter (511) arising (304) by an external influence of a user, by means of a first optical detector (513) which is included in said sensor (51); receiving (306) reflected light of said second (10) and said third (11) wavelengths, respectively; obtaining (308) a first signal representing the amount of light of said first wavelength (6) detected by said detector (513) by means of a control unit (4); characterized in that the method further comprises: obtaining (308) a second signal representing the amount of reflected light of said second wavelength (10) and obtaining (308) a third signal representing the amount of reflected light of said third wavelength (1). 1); in controlling (312) indicator intensity of a first light indicator (511) based on said first signal; controlling (312) the respective indicator intensity of (312) indicators based on said received signals; 533 554 controlling (314) intensity of light emitted from said light source (3) by said control unit (4) relative to said first signal; and controlling (314) the light composition of said light source (3) by means of said control unit (4) and said obtained signals.