FR2983568A1 - HELIOSTAT WITHOUT DEVICE FOR MEMORIZATION OR CALCULATION OF SOLAR POSITIONS - Google Patents

Abstract

Heliostats generally use a solar position calculator and / or an electronic memory of these solar positions in order to correctly orient their mirrors. The present invention describes a heliostat which has no computer or electronic memory of solar positions, which simplifies the sun tracking device and makes it more reliable. This heliostat comprises on the one hand a first axis of rotation (3) which is parallel to the axis of rotation of the Earth (4) and which rotates one revolution in 23h56mn; a second axis of rotation and a mirror set to reflect solar radiation (7) along the first axis of rotation (3); and on the other hand an optical sensor coupled to a correction logic based on the variation of the speed of rotation of the first axis (3) and the inclination of the second axis of rotation.

Description

The present invention relates to heliostats and more particularly to devices for positioning the mirror of a heliostat accurately with respect to the path of the sun and with respect to a target towards which the heliostat reflects solar radiation. STATE OF THE ART A heliostat must permanently position its mirror with respect to the sun and with respect to the target to which it must reflect solar radiation. In general the mirror is rotated about two perpendicular axes, which allows it to take any position necessary to reflect the direct rays of the sun to a fixed target. Given the apparent displacement of the sun, the exact position of the mirror must be corrected permanently. More precisely, the frequency of the repositioning of the mirror depends on the positioning accuracy desired at each instant. The higher the instantaneous precision required, the higher the repositioning frequency of the mirror. For example, for an angular accuracy of 0.5 degrees the repositioning frequency is about 2 minutes. On the other hand, to correctly position the mirror, it is necessary to know precisely the relative position of the sun and the target. For this there are in the state of the art, astronomical calculators that provide the exact position of the sun for a given date and time. This position is given for example in height relative to the horizon and in degrees of angle with respect to the South. Two motors rotate the mirror of the heliostat along its two axes of rotation to position correctly when receiving the coordinates of the sun provided by the computer. Other more sophisticated known systems have, in addition to astronomical calculators, an optical or electronic device for detecting the exact position of the sun. This exact position then makes it possible to correct and refine the position of the sun given by the computer. Indeed the position given by the calculator does not take into account the inaccuracies due to the mechanics of the heliostat, such as the bending of certain mechanical parts due to the offset of the center of gravity or the wear of some parts in friction or the inaccuracy of the engines. To simplify the logic of tracking the sun, some other known devices record the movements of the heliostat during a day, then reproduce this movement the next day with some corrections made by the optical detection of the exact position of the sun. Thus from day to day the displacement of the heliostat is corrected only by taking as a reference the course of the heliostat during the previous day. In all the aforementioned cases, the heliostats known according to the state of the art require an electronic memory either to store the program of the astronomical calculator, or to memorize the multiple positions of the mirror during a day. Some known systems are based on the fact of using only the optical detection of the solar position to orient the heliostat, but this principle has often been abandoned because of the random situation corresponding to a succession of several days without sunlight. that is to say with the sun permanently hidden by clouds for several days in a row. In addition, these known systems until now required complex electronics to search for the exact position of the sun on the celestial vault, that is to say on a window of more than 180 ° wide and 48 ° high.

OBJECT OF THE INVENTION A main object of the invention is to propose a device and an operating logic capable of overcoming the aforementioned drawbacks related to known devices for positioning heliostats.

A particular object of the invention is to provide a device and a method for accurately orienting a heliostat without the need for a computer or an electronic memory to store successive solar positions, which will also reduce the complexity and the cost of the device, and to increase its reliability of its operation. SUMMARY OF THE INVENTION In principle, the invention consists in providing the heliostat with an optical sensor capable of simply detecting the actual position of the sun, without calculation and without projections, from solar positions previously stored, but simply by transmitting the signal from the selected optical sensor to a control logic connected to the motors of the heliostat, and this control logic will minimize, during adjustment phases, the positioning error of the mirror. This will be tantamount to slaving the mirror's movements around its axes of rotation to the positioning error, then minimizing the positioning error until it is canceled. To minimize the positioning error of the mirror, the invention provides for optimizing the amount of light received by an optical sensor integral with the mirror, and reflected towards the target. Following an automated adjustment phase, the heliostat rotates around its main axis of rotation at a constant speed until the next phase of position adjustment. More specifically, the invention therefore relates to a heliostat comprising a movable mirror oriented towards the sun so as to reflect solar radiation to a target, the mirror being driven by a motor on the one hand around a first axis rotation parallel to the axis of rotation of the Earth and secondly around a second axis of rotation perpendicular to said first axis of rotation, the heliostat being characterized in that it comprises a bidirectional optical sensor able to measure d on the one hand the quantity of light, or brightness, received from the sun and on the other hand the quantity of light reflected towards the target, and in that it further comprises a control logic able to act on the positioning of the mirror around each axis of rotation to optimize on the one hand the amount of light received from the sun by the bidirectional sensor and on the other hand the amount of light reflected by the mirror in the direction of the corn. Thanks to this simple principle, the heliostat does not need complex memories and calculators to calculate the position of the sun, but requires an optical sensor associated with a logic circuit, for example combinatorial, to find by successive tests of optimization, the optimal position of the sensor and consequently the corresponding optimum position of the mirror. Advantageously, the bidirectional optical sensor comprises: a first planar photovoltaic cell, active on its two faces, and positioned on the heliostat so that the plane which includes said first cell also includes the first axis of rotation; a second planar photovoltaic cell, also active on its two faces, and positioned on the heliostat so that the plane which includes said second cell is both parallel to the first axis of rotation and perpendicular to the plane of said first cell. With such a bidirectional optical sensor structure, it is advantageous to provide for the two photovoltaic cells to be arranged on the bidirectional optical sensor so that the first photovoltaic cell can receive only the light reflected by the mirror and not the direct light of the sun. , and so that the second photovoltaic cell can receive only the direct sunlight and not the light reflected by the mirror, which will make the brightness measurements on both cells reliable. In addition, said first and second photovoltaic cells of the bidirectional optical sensor are integral with the first axis of rotation, the position of the first cell is adjusted so that the brightness on each of its two faces is identical when the mirror is positioned so that its axis perpendicular to the plane of the mirror is aligned with the sun, and the position of the second cell is adjusted so that the brightness on each of its two faces is identical when the mirror is positioned around its second axis of rotation so that the reflected rays mirror are parallel to the first axis of rotation and directed towards the target. Thanks to the optical sensor thus configured, it is possible to detect the orientation of the mirror which optimizes both the light energy received from the sun, and the light energy reflected by the mirror towards the target, and this optimization is reached when the two opposite faces of each photovoltaic sensor receive the same amount of light.

According to the invention, the adjustment of the position of the first and second photovoltaic cells is performed by said control logic, which slaves the movement of the motors operating the mirror and its optical sensor around the first and second axes of rotation of the mirror. , as a function of the signal representative of the brightness picked up and reflected by the optical sensor. For this purpose, the optical sensor delivers its signal to a comparator electronic circuit to which it is electrically connected, and which compares the brightness on each of the two faces of the two cells. This comparator transmits the result of the comparison to the control logic connected to the motors driving the mirror, and this logic controls the speed and direction of rotation of the motors according to the comparison. This process is iterative and is continued during a mirror positioning adjustment phase, until the comparator indicates that the opposite faces of the cells of the optical sensor are receiving the same amount of light.

In the case of a conventional heliostat, the mirror is driven around its first axis of rotation from East to West, and this training is done at a substantially constant speed of one revolution per day in normal operation, and at a speed slightly above or below this speed for a set period of time, under the control of said control logic.

In order to optimize the positioning of the mirror as a function of the radiation received from the sun and of the radiation reflected towards the target, the control logic is thus configured to accelerate or slow down the rotation of the mirror around each axis of rotation during the adjustment period of time, until the positioning of the bidirectional optical sensor integral with the mirror is optimized.

In an advantageous embodiment of said control logic, the latter is configured to execute a program comprising the following steps: substantially adjusting the position of the mirror along its two axes of rotation so that the solar radiation received by the mirror is reflected in the extension of the first axis of rotation and towards the target; using the bidirectional optical sensor, measure the brightness of the sun and repeat this measurement until the measured brightness is greater than a predetermined threshold of minimum brightness; when the measured brightness is greater than the threshold of minimum brightness, test the orientation of the mirror according to the signal delivered by the bidirectional optical sensor; if the signal delivered by the bidirectional optical sensor indicates a mirror positioning error along the first axis of rotation or the second axis of rotation, temporarily modify the speed of rotation of the mirror about said axis of rotation, then repeat the test of mirror orientation until the mirror orientation test indicates the absence of a mirror positioning error around each axis of rotation. According to a preferred variant, said program is executed only after a stability test of the solar irradiance, indicating that the brightness received by the mirror is greater than the threshold of minimum brightness for a period of time greater than a predetermined time delay. This makes it possible to avoid that a positioning adjustment of the mirror is undertaken while the sun is not sufficiently apparent to fine tune the path of the mirror. DETAILED DESCRIPTION OF THE INVENTION FIGS. 1, 2 and 3 illustrate the invention. - Figure 1 is a block diagram in elevation and in section of a heliostat according to the invention. FIG. 2 is a perspective diagram of the bidirectional optical sensor associated with the mirror. - Figure 3 is a flowchart that illustrates the basic logic of the automation or program that allows fine adjustment of the position of the mirror for optimized monitoring of the sun. Referring to Figure 1. The heliostat of Figure 1 comprises a mirror (1) which is pivotable about two perpendicular axes of rotation: a first axis of rotation (3) whose longitudinal axis (4) is parallel to the axis of rotation of the Earth, that is to say directed towards the pole star (5), and a second axis of rotation (2) which is perpendicular to the first axis of rotation (3) and integral with him.

The mirror (1) is positioned so that the direct rays (7) of the sun (6) are reflected (8) continuously parallel to the same axis of direction (4) as that of the first axis of rotation (3). The target (10) which is fixed is thus positioned also in the extension of this axis (4). This feature requires that the tracking of the sun (6) is done on the one hand by a rotational movement from East to West of the first axis of rotation (3) with a constant speed of 23h56mn per day to follow the sun in its movement diurnal, and secondly by a rotation of the second axis of rotation (2) of plus or minus 12 degrees per year on either side of its mean position which corresponds to the position of the mirror (1) at the time of the equinoxes to follow the sun in its seasonal movement. This last adjustment therefore requires a rotation of an angle of about 1 ° per week. These two features, namely a first axis whose rotational speed is constant and equal to 360 ° per day, and a second axis whose rotation is extremely slow (on average 0.14 ° per day), will allow accurate monitoring sun without calculator or electronic memory. For this, the heliostat is equipped with a bidirectional optical sensor (9) which is fixed to the first axis of rotation (3) and in the path of the reflected rays (8). FIG. 2 gives a schematic representation of this bidirectional optical sensor (9) which is constituted on the one hand by a first plane photovoltaic cell C1, active on its two faces, and positioned so that the plane which includes the cell C1 also includes the first axis of rotation (3). The optical sensor (9) consists of a second photovoltaic cell C2, active on both its faces, and positioned so that the plane which includes the cell C2 is both parallel to the first axis of rotation (3) and perpendicular to the plan of the cell Cl.

According to the invention, the two photovoltaic cells (C1, C2) are arranged on the bidirectional optical sensor (9) so that the first photovoltaic cell (C1) can receive only the light reflected by the mirror and not the direct light of the sun, and so that the second photovoltaic cell (C2) can receive only the direct sunlight and not the light reflected by the mirror. This can be done in particular by covers placed around the cells, except in the direction from which the brightness to be measured must come. The cells C1 and C2 being photovoltaic, they deliver an electric current that represents the amount of light, or brightness that is received on each of their two faces. The cells C1 and C2 being integral with the first axis (3), they rotate with the latter by following the sun (6) in its clockwise movement from East to West. The cell C1 is set so that the brightness on each of its two faces is identical when the mirror (1) is correctly positioned around its first axis of rotation (3) and is facing the sun (6). The cell C2 is set so that the brightness on each of its two faces is identical when the mirror (1) is positioned correctly around its second axis of rotation (2) and the reflected rays (8) of the sun are well parallel to the first axis of rotation (3). The bidirectional optical sensor (9) is electrically connected to an electronic circuit (not shown) which continuously compares the brightness on each of the faces of the two cells (C1, C2). A variation of brightness of a face with respect to its opposite face then informs about the nature of the offset that has occurred with respect to the ideal position of the mirror (1), this information is then transmitted to a logic circuit that will correct this shift by a control on the speed of rotation of the first axis (3) and / or by controlling the inclination of the mirror (1) relative to its second axis of rotation (2). But a variation of brightness detection and the corresponding correction command of the position of the mirror (1) can be reliable only if the sun is present and without rapid variations in its luminous intensity due for example to passages of mists or clouds . This disadvantage is solved by the inventive and new features of the device and its operational logic. Indeed once the device in operation the main instruction is that of rotating the first axis of rotation (3) with a constant speed of one revolution in 23h53mn. The only drifts to be corrected are those due to: - the inaccuracy of the speed of rotation of the first axis (3), but this inaccuracy is very small with regard to the existing electronic clocks; the inaccuracy of mechanical transmissions, but this inaccuracy is the same as that of known heliostats; - the seasonal movement of the sun, 0.14 degrees per day, which will require only one correction per day if the requested accuracy is less than this value. Thus the device can operate for a whole day, or even for several days, without any correction of drift positioning of the mirror is necessary, and without the need for a computer or an electronic memory of solar positions. This reliability is therefore statistically compatible with the operating frequency of the bidirectional optical sensor (9) which will be triggered as soon as the sunlight is sufficient and remains stable for a period of time necessary for a series of measurements. The operating program implemented by the control logic is illustrated by the flowchart of FIG. 3. After the mirror (1) has been adjusted along its two axes of rotation (3,2) so that the solar radiation ( 7) is reflected (8) towards the target (10) positioned in the extension (4) of the first axis of rotation (3), is imposed on the first axis (3) a rotation of East to West of a turn in 23H56mn to follow the sun in its hourly movement. Then the brightness L of the sun is measured using the optical sensor (9). If this brightness is below a certain predetermined minimum threshold (LS), then the measurement is repeated until the brightness of the sun exceeds this minimum value LS. This LS value is measured for example by a photovoltaic cell or by a pyranometer. It can be expressed in Lux, or milliamps produced by a photovoltaic cell. As soon as the brightness L of the sun is greater than or equal to the minimum value LS, a clock is triggered while continuing the measurements of brightness L. If a period of time T for example of 2 minutes flows with a brightness L remaining higher at LS, this means that the brightness of the sun is sufficiently stable to allow comparative measurements on each of the faces of the two cells C1 and C2. If the brightness measured by the sensor is different between the faces CiA and C1B of the first photovoltaic cell C1, it means that there has been a drift in the tracking of the sun in its hourly movement, so a set point is given by 30 control logic, either to increase the rotation speed of the first axis of rotation (3) if the brightness picked up by CiA is greater than that of C1B, or to reduce the rotation speed of the first axis of rotation (3) if the brightness captured by CiA is lower than that of C1B. A reiteration of the brightness measurement is started until the one picked up by C1A and the one picked up by C1B are equal. Then, a measurement of the brightness captured by the faces C2A and C2B of the second photovoltaic cell C2 is similarly initiated. If the brightness is different between C2A and C2B it means that there has been a drift in the tracking of the sun in its seasonal movement, so a set point is given by the control logic is to increase the inclination of the mirror (1) along its second axis of rotation (2) if the brightness of C2A is greater than that of C2B, or to reduce the inclination of the mirror (1) along its second axis of rotation (2) if the brightness captured by C2A is less than that captured by C2B. As soon as the luminosities of C2A and C2B are equal the clock is reset and a new loop of measurements is started on the luminosity L. So in summary: - a heliostat comprises a mirror (1), a first axis of rotation ( 3) parallel to the axis of rotation of the Earth rotating from East to West at the constant speed of one revolution per day, a second axis of rotation (2) perpendicular and integral with the first axis of rotation (3) and a bidirectional optical sensor (9). This heliostat on the one hand has no storage device and calculation of solar positions and on the other hand performs positioning corrections of the mirror (1) according to the following logic: - the mirror (1) is set along its two axes rotation (3,2) so that the solar radiation (7) is reflected (8) in the extension (4) of the first axis of rotation (3), - then the bidirectional optical sensor (9) measures the brightness L of the sun if this brightness L is less than a minimum LS then the measurement of L is repeated until it exceeds the value of LS. as soon as the brightness L of the sun is greater than or equal to LS, then a clock counts a period of time T while continuing the measurements of L - Si during this period of time T we have L> LS then an orientation test of the mirror (1) is made so that if there is a positioning error along the first axis of rotation (3), then a set point is given to increase or decrease the speed of rotation of said axis (3), then a reiteration the orientation test of the mirror (1) is made until the orientation test no longer displays an error concerning the first axis of rotation (3). - Then if the mirror orientation test (1) detects a positioning error along the second axis of rotation (2), then a set point is given to increase or decrease the inclination of the mirror (1) along its second axis of rotation (2), and a reiteration of the mirror orientation test (1) is made until the orientation test no longer displays an error concerning the second axis of rotation (2). - Then the clock is reset and a new loop of measurements of period of time T is started while continuing the measurements of brightness L. This basic flow chart can be completed by additional tests to further secure this correction protocol. for example, a test on the number of corrections per minute. If this number is too large it would mean that there is an abnormal instability of the system and then an alarm can be generated. EXEMPLARY EMBODIMENT A heliostat is composed of a mirror (1) glass plane 4 millimeters thick and 1m x 1.50m dimension mounted on a metal frame allowing the rotation of the mirror (1) along a first axis of rotation (3) inclined along the axis of rotation of the Earth (4), and a second axis of rotation (2) perpendicular and integral with the first axis (3). The mirror (1) is initially set to reflect the sun rays (7) to a target (10) which is a square photovoltaic panel of 1m side. The target (10) is placed in the extension of the first axis of rotation (3). In order to follow the movement of the sun (6), the rotation of the mirror (1) along its two axes is carried out using a motor and mechanical transmissions known to those skilled in the art. In particular the rotation around the first axis of rotation (3) is at a constant speed of 1 revolution in 23h56mn and the rotation along the second axis (2) is punctually made to catch the shift of the sun during its seasonal movement. The control of the movements of the mirror (1) is controlled by a control circuit which contains no stored record of solar positions but continuously receives the information of a bidirectional optical sensor (9) placed in the path of the reflected solar radiation (8). ) and secured to the first axis of rotation (3). The bidirectional optical sensor (9) provides a signal representative of the inclination of the light beam that it receives, in particular the inclination with respect to the first axis of rotation (3) and with respect to the second axis of rotation (2). These two pieces of information make it possible to control the correction of the position of the mirror (1) until the inclinations become zero, that is to say until the reflected beam is well parallel to the first axis of rotation ( 3) and reaches the target (10). The process of correcting the orientation of the mirror (1) is carried out according to the following logic: - a photovoltaic cell coupled to the first axis of rotation (3) and directed towards the sun measures the brightness L of the sun. if this luminosity L is less than a minimum LS of 600 W / m2, then the measurement of L is repeated until it exceeds the value LS. as soon as the luminosity L of the sun is greater than or equal to LS, then a clock measures a period of time T equal to 2 mn while continuing the measurements of L. - If during this whole period of time T we have L> LS then a mirror orientation test (1) is requested of the bidirectional optical sensor (9) so that if there is a positioning error along the first axis of rotation (3), a set point is given to increase or decrease the speed of rotation of said axis (3), then a reiteration of the mirror orientation test (1) is made until the orientation test no longer displays an error concerning the first axis of rotation (3) . - Then if the orientation test of the mirror (1) detects a positioning error along the second axis of rotation (2), a set point is given to increase or decrease the inclination of the mirror (1) along its second axis of rotation (2), then a reiteration of the mirror orientation test (1) is made until the orientation test no longer displays an error concerning the second axis of rotation (2). - Then the clock is reset and a new loop of measurements of time period T is started while continuing the measurements of L. Thus the mirror (1) remains permanently positioned so as to reflect the solar radiation to the target (10). When the sun is veiled or hidden by clouds or during the night, the mirror (1) continues to rotate with the same speed as the sun (1 turn in 23h56mn) until the sun reappears with sufficient brightness (L> LS) to allow a positioning measurement and possibly a correction.

BENEFITS OF THE INVENTION Finally, the invention makes it possible for a heliostat to simplify its sun tracking protocol and to become independent of any solar position memorization and / or independent of any astronomical calculation system, thereby providing a definite gain in cost and reliability.

Claims (10)

REVENDICATIONS1. Heliostat comprising a mirror (1) movable towards the sun so as to reflect solar radiation to a target (10), this mirror being driven by a motor on the one hand around a first axis of rotation (3) parallel to the axis of rotation of the Earth and secondly around a second axis of rotation (2) perpendicular to said first axis of rotation (3), characterized in that it comprises a bidirectional optical sensor (9) adapted to measuring on the one hand the amount of light received from the sun and on the other hand the amount of light reflected towards the target (10), and control logic able to act on the positioning of the mirror (1) around each axis of rotation (2,3) in order to optimize, on the one hand, the quantity of light received from the sun by the bidirectional optical sensor (9) and, on the other hand, the quantity of light reflected by the mirror (1) in the direction of the target (10). 2. Heliostat according to claim 1, characterized in that the bidirectional optical sensor (9) comprises: a first planar photovoltaic cell (C1), active on its two faces, and positioned on the heliostat so that the plane which includes said first cell (C1) also includes the first axis of rotation (3); a second plane photovoltaic cell (C2), active on its two faces, and positioned on the heliostat so that the plane which includes said second cell (C2) is both parallel to the first axis of rotation (3) and perpendicular in the plane of said first cell (C1). 3. Heliostat according to claim 2, characterized in that the two photovoltaic cells (C1, C2) are arranged on the bidirectional optical sensor (9) so that the first photovoltaic cell (C1) can receive only the light reflected by the mirror and not the direct sunlight, and so that the second photovoltaic cell (C2) can receive only the direct sunlight and not the light reflected by the mirror. 4. Heliostat according to claim 3, characterized in that said first and second photovoltaic cells (C1, C2) of the bidirectional optical sensor are integral with the first axis of rotation (3), the position of the first cell (C1) being adjusted to that the brightness on each of its two faces is identical when the mirror (1) is positioned so that its axis perpendicular to the plane of the mirror is aligned with the sun (6), and the position of the second cell (C2) being adjusted to that the brightness on each of its two faces is identical when the mirror (1) is positioned around its second axis of rotation (2) so that the rays reflected (8) by the mirror are parallel to the first axis of rotation (3). ) and directed towards the target (10). 5. Heliostat according to claim 4, characterized in that the adjustment of the position of the first cell and the second photovoltaic cell (C1, C2) is effected by said control logic slaving the movement of the motors operating the mirror around its first and second axes of rotation (3,2). 6. Heliostat according to claim 4, characterized in that the bidirectional optical sensor (9) is electrically connected to a comparator electronic circuit 20 which compares the brightness received on each of the two faces of the two cells (C1, C2) and which transmits the result of the comparison to the control logic connected to the motors operating the mirror. 7. Heliostat according to any one of the preceding claims, characterized in that the mirror (1) is driven around its first axis of rotation (3) from East to West, this training being performed at a substantially constant speed of one revolution per day in normal operation, and at a speed slightly greater or slightly less than this speed for a set period of time, under the control of said control logic. 30 8. Heliostat according to any one of the preceding claims, characterized in that for optimizing the positioning of the mirror as a function of the radiation received from the sun and the radiation reflected to the target, the control logic is configured to accelerate or slow down the rotation of the mirror around each axis of rotation for a set period of time, until the positioning of the bidirectional optical sensor (9) integral with the mirror is optimized. 9. Heliostat according to claim 8, characterized in that said control logic is configured to execute a program comprising steps of: - substantially adjust the position of the mirror (1) along its two axes of rotation (3,2) for the solar radiation (7) received by the mirror is reflected (8) in the extension (4) of the first axis of rotation (3) and towards the target (10); - Using the bidirectional optical sensor (9), measure the brightness (L) of the sun and repeat this measurement until the measured brightness is greater than a predetermined threshold of minimum brightness (LS); when the measured brightness (L) is greater than the minimum brightness threshold (LS), testing the orientation of the mirror (1) according to the signal delivered by the bidirectional optical sensor (9); - if the signal delivered by the bidirectional optical sensor (9) indicates a mirror positioning error along the first axis of rotation (3) or the second axis of rotation (2), temporarily change the speed of rotation of the mirror about said axis rotation (3.2), then repeat the mirror orientation test (1) until the mirror orientation test indicates the absence of a mirror positioning error around each axis of rotation ; 10. Heliostat according to claim 9, characterized in that said program is executed only after a stability test of the solar irradiance, indicating that the brightness (L) received by the mirror (1) is greater than the threshold ( LS) of minimum brightness for a period of time greater than a predetermined time delay (Ts).