FR2796173A1 - Light level detector with supplementary filtering for lighting control that is less sensitive to stray light sources or weather conditions - Google Patents

Abstract

The lighting control detector (5,2,3) has two photo-diodes (2,3) operating in the visible spectrum beneath a filter (5) which delivers two light beams at two different wavelengths. A signal processor (4) sums the signals from the two photo-diodes and delivers this signal to a decision module, which decides whether or not to activate the local lighting circuit.

Description

<U> Filter brightness detector, </ U> in particular <U> for lighting control </ U> </ U> The invention relates to the field of the detection of ambient light intensity, for the control of a user circuit, in particular a public lighting circuit, a motor vehicle or a room, for example a garage door.

To carry out this detection, for example in an urban environment, it is known to use a device comprising a sensor that measures the intensity of the local light and processing means that decide to open or close the circuit. lighting according to a comparison between a light intensity signal from the sensor and a threshold.

Such devices use sensors operating either in the visible spectral band or in the infrared spectral band.

The invention more particularly relates to detection in the visible range, that is to say in the spectral band between about 350 nm and about 750 nm.

Lighting control devices, for example public, are intended to mitigate the absence of sunlight. This lighting, however, is not enough for men to evolve in good conditions. The man has therefore developed many complementary lighting devices, such as vehicle headlights, or domestic lighting.

Such complementary lighting may momentarily or durably disturb the control devices causing unexpected trips or interruptions. Other factors may also disturb the detection. For example, transient meteorological variations due to haze, fog, clouds, and the like.

These factors mean that the known devices, and mainly those working in the visible, do not bring complete satisfaction.

The present invention therefore aims to significantly improve the situation.

It proposes for this purpose a control device. in particular of illumination of the type described in the introduction, in which - the sensor comprises at least two photodiodes operating in the visible spectral band and a filter for applying to the photodiodes two light flows extracted from the local light and centered on two lengths of light. selected wave, and the processing means comprise, firstly, a computing module capable of forming the signal <B> dl </ B> luminous intensity by summation of first and second signals delivered by the two photodiodes, a second part, a selective analysis module of the first and second signals and, thirdly, a module capable of making the decision to trigger or interrupt the user circuit, in particular local lighting, in according to a predetermined condition relating to the comparison of the light intensity signal at the threshold and the result of the analysis. The Applicant has indeed found that comparing (selective analysis in the broad sense of the term) the light intensities of portions of ambient light belonging to different spectral bands, the intensities that take these portions in the absence of disturbances, it was possible to detect a disturbance and consequently to modulate the decision to open or close the lighting circuit.

Several types of selective analysis can be envisaged. for example, it is possible to calculate the value of the ratio between the values of the first and second signals, and then to compare the value of this ratio with a threshold ratio representative of the ratio of the intensities of the ambient light to the surroundings of the first and second wavelengths chosen, and finally deliver to the decision module a disturbance message in case of crossing the threshold report. As a variant, the value of the first signal may be compared with the value of the second signal, and then the decision module may receive a disturbance message when the result of the comparison does not satisfy a chosen criterion representative of the intensities of the ambient light around first and second wavelengths chosen. In another variant, the values of the first and second signals may be compared to pairs of values representative of first and second signals associated with the intensities of light. ambient to the first and second wavelengths chosen, so as to deduce a disturbance level, then deliver to the decision module a disturbance message when the level deduced exceeds a chosen threshold level. In a preferred embodiment, the filter is an optic provided with at least two zones capable of absorbing the wavelengths of the ambient light which differ substantially from the two wavelengths chosen by predetermined upper and lower quantities. In other words, the optics transmits only two portions of light belonging to different spectral bands.

More preferably still, the zones are obtained by depositing, on an optical medium, filtering layers, such as inks of different colors, in particular blue and violet.

Many variants of the device can be envisaged. They are distinguished by the following characteristics, which can be taken separately and in combination: the processing means may advantageously comprise a digital filter, powered by the detection photodiodes, for delivering the first and second signals in a sampled form; a programmable timing module can be provided capable of storing at least one delay time, the processing means then being arranged to open or close the local lighting circuit after the expiration of the delay time. In this case, it is advantageous for the processing means to be arranged to open or close the local lighting circuit if the decision has been confirmed at least once during the timeout period; the processing means may comprise a management module for storing information representative of the operation of the local lighting circuit, in particular its operating times; it is also possible to provide a programming module for the processing means, the latter preferably operating by remote control thanks to a third photodiode for receiving programming data in the form of electromagnetic waves (downloading). In this case, it is advantageous for the optics to be provided with a third zone enabling transmission of the programming data to the third photodiode, this zone preferably being a layer of colored ink, in particular red. Similarly, it is particularly advantageous for the programming module to include a fourth photodiode for transmitting data in the form of electromagnetic waves, in particular data representative of the stored operating information; the processing means will preferably comprise a microcontroller comprising the analysis, decision and calculation modules, at least part of the timing module, part of the programming module, the digital filter and a storage memory.

The device according to the invention can be advantageously used for the control of a public lighting circuit, or a lighting system of a motor vehicle, or a lighting circuit premises, including. Furthermore, the invention also relates to a lighting control method comprising the following steps: a) measuring the intensity of the local light by means of a sensor, b) comparing a signal of luminous intensity drawn from the sensor at a threshold, and c) decide on the opening or closing of a local lighting circuit according to the result of the comparison. This process is characterized in that on the one hand, in step a), before measuring the intensity of the ambient light, this light is filtered to form two light fluxes centered on two lengths of light. chosen to obtain first and second light intensity signals, and then summing said first and second signals to form said light intensity signal, and secondly, that in step c) selectively analyzing the first and second signals to determine a possible light disturbance, and then making the decision based on a predetermined condition of comparing the light intensity signal to the threshold and the result of the analysis.

Other characteristics and advantages of the invention will become apparent upon examination of the following detailed description, and the accompanying drawings, in which - FIGS. 1A and 1B illustrate two parts of a control device according to the invention. 1, respectively in a cross-sectional view and in a perspective view, FIG. 2 illustrates in a view from above a mode of positioning of the detection and telecontrol photodiodes of FIG. 3 illustrates an embodiment of a FIG. filter according to the invention, and - Figure 4 is an electrical diagram of the device of Figures 1A and 1B. The attached drawings are, for the most part, of a certain character. Accordingly, they are an integral part of the description and may contribute to the definition of the invention, if any.

In the detailed description which follows, the invention will be described in an application to public lighting. Of course, the invention is not limited to this area alone. It may in particular relate to the control of a lighting system of a motor vehicle, or premises, or the like. In a very general manner, the invention applies to any lighting circuit control likely to be disturbed by unusual light sources; or by meteorological variations, tending to temporarily increase or decrease the usual ambient light intensity.

FIG. 1A is a schematic illustration of a first so-called detection portion of a control device for a lighting circuit according to the invention. This first part comprises first a printed circuit 1 preferably made of CMS technology.

In the illustrated example, the printed circuit 1 has on its upper face at least two detection photodiodes 2, 3 which operate in the visible spectral band, that is to say between about 350 nanometers and about 750 nanometers. These photodiodes 2 and 3 are connected to processing means which preferably comprise a microcontroller 4 for analyzing the light intensities detected by the photodiodes.

Upstream of the photodiodes 2 and 3, that is to say above their detection face, there is provided a filter 5 capable of performing a spectral and spatial filtering of the ambient light. By definition, the set consists of the detection photodiodes and the filter.

The processing means, in particular the controller 4, and the photodiodes 2 and 3 are connected to a second part of the device, called manual control, made in the form of a housing 6, by means of a multi-strand cable 7 This housing 6 is supplied with current through an input / output 8 connected to the mains. Of course, the housing could be autonomous, and thus powered by a rechargeable battery, or batteries.

In the illustrated example, the housing 6 and the first light detection portion are intended to be implanted in different places, although not far away. In this example, the housing 6 has an input / output 9 for the manual control of the local lighting circuit. Similarly, the microcontroller 4 has an input / output 26 integrated in the cable 7 for the automated control of the local lighting circuit.

The filter 5 and the printed circuit 1, which supports the photo diodes 2 and 3 and the microcontrol 4, are, in the illustrated example, secured to a support 10, made, for example, in an aluminum-based material. More specifically, the electrical and / or electronic components 2, 3 and 4 are therefore housed inside the cavity 11 defined by the support 10, while the filter 5 is dimensioned so as to close the cavity 11. The filter can thus isolating weather and pollution from electrical and / or electronic components.

As best illustrated in FIG. 3, the filter 5 is preferably an optic provided with at least two zones 12 and 13 for absorbing spectral bands of ambient light that differ from one another. In fact, the filter 5 is intended to apply to the detection photodiodes 2 and 3 two light flows drawn from the local light and centered on two different selected wavelengths, A1 and R2.

The two zones 12 and 13 are therefore intended to absorb the wavelengths of the ambient light which lie outside the spectral ranges which are substantially centered on the wavelengths A1 and A2. Preferably, the range of wavelengths surrounding A, 1 is from 420 to about 500 nanometers, and that surrounding A, 2 is from about 590 to about 700 nanometers. In other words, they correspond for A1 to a blue cast and for A2 to a red cast.

The detection photodiodes 2 and 3 preferably have substantially identical extended detection spectral ranges, and incorporating the wavelengths A1 and A2 respectively provided by the two zones 12 and 13 of the filter. Thus, it will be possible to use two photodiodes operating in a wavelength range between about 330 nm and about 720 nm. For example, it is possible to use planar silicon photodiodes. from the company VTB, centered on an opde length of approximately 580 nm, and referenced VTB8440B.

But this is not necessary. We can indeed use. two detection photodiodes 2 and 3 having different detection spectral ranges, substantially centered on the two wavelengths A, 1 and X2, respectively.

To obtain the chosen wavelengths, the zones 12 and 13 of the filter 5 are preferably colored in blue and violet, respectively. These colors are obtained, preferably, by deposition of filtering layers on a transparent optical medium 14, and more preferably still by deposition of ink layers.

Preferably, the optical support is made of a polycarbonate type material, such as LEXAN grained manufactured by the General Electric Company. This support, about 250 microns thick, withstands the weather very well. I1 is therefore particularly suitable for the protection of electrical and / or electronic components housed in the cavity 11. Moreover, to color the filtering areas 12 and 13, the inks of the SERICOL mark can be used. The French company MARTIN GRAVURES produces such optical filters.

As illustrated in FIG. 3, it is particularly advantageous that the filter 5, here optical, comprises at least a third zone 15 providing the transmission of remote control signals at the level of remote control photodiodes 16 and 17 (see FIG. ), also located on the printed circuit 1, coupled to the microcontroller 4 and which will be discussed later.

Preferably, the third zone 15 is a colored zone obtained by the deposition of an ink layer of the type of those described previously, but of different color *, for example red.

The mode of operation of the device according to the invention will now be described in more detail with reference to FIG.

The Applicant has found that at the times of triggering (dusk) and stop (sunrise) of the public lighting circuits, the ambient light had particular characteristics, and especially dominant in the lengths of waves centered on blue (A1) and red (A2). Depending on whether one is before dark, or after, or before sunrise or after, the spectrum of visible light will be dominant (intensity) in blue or red . Therefore, in case of disturbance of the ambient light, there will be a change of at least one of the usual light intensities of wavelengths predominantly blue and red. According to the invention, these modifications can be quantified by the processing means, then analyzed so as to determine whether they correspond to a real disturbance, that is to say a transient disturbance, or to a lasting modification of the light ambient solar, which requires the opening or closing of the local lighting circuit. The ambient light arrives at the two detection photodiodes 2 and 3 in the form of two spatially separated streams (spatial filtering), and centered respectively on the wavelengths .k1 and X2 (spectral filtering). These flows give rise to first S1 and second S2 "raw" analog signals which are transmitted to the microcontroller 4 via the printed circuit 1.

Preferably, the microcontroller 4 comprises a digital filter for sampling the raw analog signals S1 and S2 before they are used to perform, on the one hand, a measurement of luminous intensity, and on the other hand, a light disturbance detection.

The microcontroller 4 comprises a calculation module, powered by the digital filter, and intended to summon the first sampled signals S1 and S2, to form a light intensity signal S1, which is then compared with a memorized light intensity threshold Thin. and preferably modifiable.

To determine whether a light disturbance affects ambient light, the processing means includes a selective analysis module for analyzing the first S1 and second S2 sampled signals provided by the digital filter. This analysis module is preferably integrated in the microcontroller 4.

Several modes of operation can be envisaged for the analysis module. In a first exemplary embodiment, the analysis module calculates the value of the ratio between the respective values of the first S1 and second S2 sampled signals. This amounts to making the ratio between the detected light intensity, centered on X1, and the detected light intensity, centered on A2, or the inverse ratio. The value of this ratio is then compared with a memorized threshold ratio, for example in the analysis module itself or in a memory provided for this purpose in the microcontroller 4. This threshold ratio is a representational value of the ratio. ambient light intensities around the selected wavelengths A1 and A, 2, in the absence of light disturbance. Of course, this threshold ratio must be adjusted according to the location where the control device according to the invention is located, and in particular its first detection part.

When the value of the calculated ratio is substantially greater than the stored threshold ratio (higher value crossing), this indicates that the detected ambient light is subject to a disturbance. The same applies when the value of the calculated ratio is substantially lower than the stored threshold ratio (crossing by lower value). In one case as in the other, a disturbance message is delivered by the analysis module to a decision module which is also located in the microcontroller 4; preferably: In a second exemplary embodiment, the analysis module compares the value of the sampled first signal -Si with the value of the sampled second signal S2. It could be a simple comparison of values, or a subtraction operation. The result of this comparison of Si to S2 is confronted with a chosen criterion which is a function of the intensities of the ambient light around the selected wavelengths A1 and X2.

Such a criterion can be a stored condition of the type "before sunrise. If is always greater than S2, and after sunrise and before dark S2 is always greater than Si". In this way, if at the instant of the detection Si is greater than S2, while at this time of the day S2 must be greater than S1, the ambient light is subject to a light disturbance. In this case, the analysis module delivers a disturbance message to the decision module.

In a third exemplary embodiment, there is provided a memory for storing a correspondence table between pairs of values, which are representative of values of first and second signals associated with the intensities of the ambient light around the selected wavelengths A1 and A2 in the absence of disturbance, and representative information, for example, levels of disturbance. In this case, the analysis module is arranged to compare the values of the first S1 and second S2 sampled signals with the pairs which are stored in the correspondence table, so as to determine in this table the pair which has values identical to those S1 and S2 sampled signals, or substantially identical, then deduce the associated perturbation level.

If the disturbance level thus obtained exceeds a chosen threshold level, for example stored in the memory of the analysis module, said analysis module delivers a disturbance message to the decision module.

The memory in which the table is stored can be either the memory of the microcontroller 4, and more particularly a register thereof, or a memory specific to the analysis module.

In what has just been said, the expression "disturbance message" must be understood in a broad sense. It may be either a computer message according to a particular format, or a simple analog signal delivered on an output, this signal may be of a predetermined value, or a variable value when must convey information representative of the intensity of the disturbance.

Other modes of operation may be envisaged for the analysis module.

As indicated above, the control device according to the invention makes a measurement of the received light intensity and a "measurement" of the possible disturbance which parasitizes this light intensity, which has just been described.

The luminous intensity SI which is calculated (by the calculation module) is compared with a threshold intensity Slim, which can vary according to the location of the detecting part of the control device. It is specified here that it is particularly advantageous for the detection zones of the photodiodes to be oriented substantially towards the zenith. The threshold intensity Slim is stored in a memory of the processing means, and preferably in the decision module. The comparison between the intensity signal SI and the threshold intensity is also preferably carried out in the decision module.

If the intensity signal SI is below the threshold Slim at a time of day when it is normal, the control device can then remain in its current state. For example, the detection takes place before sunrise and the light intensity must be below the threshold. In this case, whether a disturbance message has been issued or not, the decision module leaves the control device in its current state.

On the other hand, if the intensity signal SI is greater than the threshold, when it should be lower than this, it clearly indicates that the ambient light has been substantially modified since the last detection.

Two cases may arise. In a first case, no disturbance message was delivered by the analysis module, and consequently the ambient light is naturally passed above the threshold. The state of the control device must therefore be modified (transition from the open state to the closed state, or from the closed state to the open state). In the second case, a disturbance message was issued by the analysis module, indicating that a light disturbance is disturbing the ambient light. The decision module then considers that the state of the control device does not need to be changed.

It may be interesting, in order to modulate a decision to modify the operating state of the lighting circuit, that the processing means comprise a programmable delay module. Such a delay module can indeed make it possible to count down a stored duration as soon as a decision is taken, so that the state of the local lighting circuit is only modified (open or closed) if the decision has been confirmed. before the end of the dwell time.

As a variant, the final (and definitive) decision to modify the operating state of the local lighting circuit can be taken following an analysis of the slope of the light intensity signal SI as a function of time. Indeed, if during the delay time the slope has become greater than a threshold slope corresponding, for example, to the usual sunrise slope, then this indicates that a strong light disturbance has come to parasitize the ambient light. In this case the decision to change the state of the circuit is canceled. A fictitious threshold, greater than the stored intensity threshold, which is used for comparison with the light intensity signal, can be used for this purpose, to avoid hysteresis effects of the detectors. This can be advantageous, especially in case of disturbance by car headlights.

As has been indicated previously, it is particularly advantageous, particularly when the first detection part of the control device is located in a place difficult to access, that the control device comprises remote control means allowing at least to modify its operating parameters through signals transmitted by electromagnetic waves. To do this, a module is provided for programming the processing means. This module comprises a reception photodiode 16 which is preferably placed below the third zone 15 covered with a layer of red ink, and advantageously on the printed circuit 1.

This photodiode 16 has a spectral range of operation substantially centered on the wavelength of electromagnetic signals transmitted by a remote operator. These signals comprise programming data, and preferably the data representative of the different thresholds used by the processing means (light intensity threshold, threshold ratio, threshold level), as well as the criterion or criteria chosen for the analysis module. and the delay time of the timer module.

It is possible, for example, to use a silicon PIN photodiode of the OP905 type operating in the infrared domain, and more particularly centered on a wavelength of approximately 900 nanometers.

Furthermore, it may be particularly advantageous that the control device according to the invention also comprises means for remotely downloading certain information it contains. For this purpose, a fourth transmission photodiode 17 is preferably provided which is also intended to be placed below the third zone 15 covered with a layer of red ink, and advantageously on the printed circuit 1. such fourth photodiode 17 is, by definition, part of the programming module. It is therefore intended to transmit on request data in the form of electromagnetic waves, and more particularly data representative of at least some of the operating information of the control device.

Such operating information can be managed and stored by a management module that preferably comprises the microcontroller 4. It may be, for example, the cumulative duration of operation of the local lighting circuit controlled by the device control (in programmed automatic mode and / or in manual mode). But, of course; many other information can be managed by the management module, such as the opening and closing hours of the lighting circuit over several days or even weeks, and the like. The part of the programming module other than the two transmission and reception photodiodes 17 and 16 is preferably integrated with the microcontroller 4. The microcontroller may for example be PIC 16F type.

Preferably, the fourth transmitting photodiode 17 is of the infrared type. It may be, for example; a diode photo of SIEMENS SFH.487 type substantially centered on a wavelength of about 880 nanometers. As best illustrated in Figure 4; the detection and remote control photodiodes operate, preferably, in current mode and not in voltage mode. It is therefore necessary that they be calibrated before the installation of the control device at the place of detection. This calibration, intended to obtain substantially identical gains on the photodiodes of detection, can be obtained using the potentiometers 18 and 19. Nevertheless, the calibration can be obtained algorithmically, using the microcontroller 4.

As illustrated in FIG. 4, the microcontroller 4 manages the automatic opening (shutdown), closing (on) and delaying of the public lighting circuit. This management is of the programmed type, as described above, insofar as the various management, analysis and processing parameters can be modified remotely using the remote control means.

However, it is particularly advantageous to provide in parallel manual management means in the housing 6 of the control device, which is usually placed in a place easily accessible to an operator.

In the illustrated example, the housing 6 comprises for this purpose three actuating members 20, 21 and 22 respectively for causing a forced march of the lighting circuit, or a forced stop of the same circuit, or again operation for a predetermined time delay.

In addition, and preferably still, the housing 6 comprises on its front display means for the operator to view the operating mode of the local lighting circuit. In the example illustrated, three diodes are thus provided, a first diode, preferably green, indicating the power supply mode of the housing or a disturbance, a second diode, preferably red, indicating a functioning in operation. forced operation, and a third diode, preferably orange, indicating operation in the delay mode. The forced operation of the lighting circuit can be interrupted only if the stop button 21 is actuated. operating mode the red diode 23 remains continuously lit, the manual relay 9 for controlling the lighting circuit is switched on, and when the option allows, the operating time in manual mode is counted, for example in view of a download.

The timer function allows the lighting circuit to operate for a time that can be parameterized through, preferably, the previously described programming module. By default, this time can be approximately 20 minutes. Preferably, during this manual delay time, the processing means verify that disturbances, or other events, do not occur.

This manual time-out mode can be interrupted by pressing the forcing key 20, or the stop key 21, or when automatically switching from standby (before dark) to the operating state (after dark).

During the entire duration of the manual delay, the orange diode 25 remains on, the manual relay 9 is switched on and the duration of the operating time in manual mode is counted.

In the foregoing, a number of modules have been described. Some of them may be partially or completely in the form of programs or software installed in the microcontroller, the complementary part then being made from electronic components or circuits.

The invention also relates to a local lighting control method which can be implemented by the control device which has just been described.

This process comprises three major steps. In a first step (a), the local ambient light is filtered to form two light fluxes centered on two selected wavelengths A1 and A2, in order to obtain first S1 and second S2 light intensity signals. These first and second signals are then summed to form a signal of luminous intensity SI.

In a second step (b), the signal of luminous intensity SI is compared with a threshold Slim, after a possible sampling.

In a third step (c), which may be partially performed simultaneously with step (b), the first and second signals are selectively analyzed to determine a possible light disturbance. Then, it is decided to open or close a local lighting circuit according to a predetermined condition relating to the result of the comparison of the light intensity signal with said threshold and the result of the analysis.

Examples of selective signal analysis and decision making have been described previously. Moreover, all the functions that have been described with reference to the control device can be transposed into additional or optional steps or sub-steps of the method.

The invention is not limited to the device embodiment and the method described above, but it extends to the variants that the skilled person can implement in the context of the claims below.

Thus, there has been described a control device provided with two spectral and spatial filtering zones, cooperating with two photodiodes of detection: But it is clear that one could use more than two filtering zones and two photodiodes of detection, for example three filter areas and. three detection photodiodes so as to refine the decisions made by the processing means.

Furthermore, in the embodiment described, reference has been made to remote control means for downloading and remote downloading of data and other information. But it is clear that in a simplified mode the control device may not include such remote control means.

On the other hand, it has been described a control device in which the filter was an optical element type optical polycarbonate support having several filtering areas. However, the filter could be of another type, such as for example an electromagnetic filter, or an optical lens providing wavelength separation, or an element provided with a three-dimensional pattern adapted to the separation of length. wave. In addition, an embodiment has been described in which the detection part is housed in a support. However, the elements contributing to the detection could be embedded in a resin block so as to be secured to each other.

Finally, the detection part could be directly integrated in a housing equipped with manual controls and a window for the filter, to form an integrated control device.

Claims (25)

<U> Claims </ U> A control device, in particular lighting, comprising a sensor (5,2,3) for measuring part of the intensity of the local light, and processing means (4) for deciding the opening or closing a user circuit according to a comparison between a light intensity signal taken from the sensor and a threshold, characterized in that said sensor comprises at least two photodiodes (2,3), operating in the visible spectral band and capable of delivering first (S1) and second (S2) signals, and a filter (5) for applying to the photodiodes two light fluxes drawn from the local light and centered on two selected wavelengths (λ1, λ2), and in that said processing means (4) comprise a calculation module arranged to form said light intensity signal by summation of the first (S1) and second (S2) signals, a selective analysis module, first and second signals and a decision module able to take said decision according to a predetermined condition relating to the comparison of the light intensity signal with said threshold and the result of the analysis. 2. Device according to claim 1, characterized in that said filter (5) is an optic provided with at least a first (12) and second (13) areas adapted to absorb the wavelengths of ambient light which differ substantially from said two selected wavelengths (λ1, λ2) by predetermined upper and lower amounts. 3. Device according to claim 2, characterized in that said first (12) and second (13) areas are obtained respectively by depositing first and second filter layers on an optical medium (14). 4. Device according to claim 2, characterized in that said first and second filter layers are inks of different colors, in particular blue and violet. 5. Device according to one of claims 3 and 4, characterized in that said optical medium (14) is a blade made of a synthetic material, in particular polycarbonate. 6. Device according to one of claims 1 to 5, characterized in that said processing means (4) comprise a digital filter fed by said detection photodiodes (2,3) and adapted to deliver said first (S1) and second (S2) signals in a sampled form. 7. Device according to one of claims 1 to 6, characterized in that said analysis module is arranged to calculate the value of the ratio between the values of the first (S1) and second (S2) signals; then. comparing said value of the ratio with a threshold ratio representative of the ratio of the intensities of the ambient light. around. first and second wavelengths chosen, and finally deliver to the decision module a disturbance message in case of: crossing of said threshold ratio. 8. Device according to one of claims 1 to 6, characterized in that said analysis module is arranged to compare the value of the first signal with the value of the second signal, and to deliver to the decision module a disturbance message. when the result of said comparison does not verify a chosen criterion representative of the intensities of ambient light around the first and second wavelengths chosen (X1, Â2). 9. Device according to one of claims 1 to 6, characterized in that said processing means comprise a memory for storing a correspondence table between pairs of values, representative of first and second signals associated with the intensities of the ambient light around the first and second selected wavelengths (λ 1,, λ 2), and perturbation level representative information, and in that said analysis module is arranged to compare the values of said first (S1) and second ( S2) signals to couples stored in said table, to derive a disturbance level and issue the decision module a disturbance message when said level deduced exceeds a chosen threshold level. 10. Device according to one of claims 1 to 9, characterized in that it comprises a programmable time delay module capable of storing at least one delay time, said processing means being arranged to open or close the circuit d local lighting after said delay time has elapsed. 11. Device according to claim 10, characterized in that the processing means (4) are arranged to open or close the local lighting circuit if the decision has been confirmed at least once during said timeout period. 12. Device according to one of claims 1 to 11, characterized in that said processing means (4) comprise a clean management module. storing information representative of the operation of the local lighting circuit, in particular its operating times. 13. Device according to one of claims 1 to 12, characterized in that it comprises a programming module of the processing means (4). 14. Device according to claim 13, characterized in that said programming module comprises a third photodiode adapted to receive programming data in the form of electromagnetic waves, in particular data representative of the thresholds, threshold ratio, threshold level, chosen criterion. , and said delay time. 15. Device according to one of claims 13 and 14 in combination with one of claims 2 to 5, characterized in that said optics is provided with a third zone (15) adapted to transmit to said third photodiode (16) the programming data. 16. Device according to claim 15, characterized in that said third zone (15) is obtained by depositing a layer of color ink, in particular red. 17. Device according to one of claims 13 to 16 in combination with claim 12, characterized in that said programming module comprises a fourth photo diode (17) able to emit data in the form of electromagnetic waves, in particular representative data of the stored operating information. 18. Device according to one of: claims 1 to 17, characterized in that said processing means (4) comprises a microcontroller (4) comprising said analysis, decision and calculation modules, a part at least of said timing module, a portion of the programming module, said digital filter and a memory in which said threshold is stored. 19. Device according to claim 18, characterized in that it comprises a printed circuit (1) on which are located the photodiodes (2,3,16,17) and said microcontroller (4). 20. Device according to one of claims 1 to 19, characterized in that said sensor (5,2,3) and said processing means (4) are joined together by a resin, in particular sealed. 21. Device according to one of claims 1 to 20, characterized in that said sensor (5,2,3) and said processing means (4) are secured to a support (10), in particular made of a material to aluminum base. 22. Use of the device according to one of the preceding claims for controlling a public lighting circuit. 23. Use of the device according to one of claims 1 to 21 for the control of a lighting system of a motor vehicle. 24. Use of the device according to one of claims 1 to 21 for controlling a lighting circuit premises. 25. A lighting control method, comprising the steps of: a) measuring. the intensity of the local light by means of a sensor, b) compare a signal of luminous intensity drawn from the sensor to a threshold, and c) decide on the opening or the closing of a circuit of local lighting, according to the result of said comparison, characterized in that, in step a), before measuring the intensity of the ambient light is filtered this light. to form two light fluxes centered on two selected wavelengths for obtaining first and second light intensity signals, and then summing these first and second. second signals for forming said luminous intensity signal, in that, in step c), the first and second signals are selectively analyzed to determine a possible light disturbance, and then said decision is made according to a condition predetermined for comparing the light intensity signal to said threshold and the result of the analysis.