DE102006034145B4 - A method of communication between a home automation sensor and a home automation device for controlling visual comfort or thermal comfort - Google Patents

Abstract

A method of communication between a domotic sensor (RSU) which measures the magnitude of a physical phenomenon and is provided with a transmission means (TX1) for transmitting a physical phenomenon signal and a domotic device (20) dedicated thereto to control visual comfort or thermal comfort in a building, wherein the transmission of a signal is triggered by a measurement of a change in the magnitude of the physical phenomenon when the change exceeds a predetermined threshold, and wherein the transmitted signal is at least one of the measured Intensity (INFO (MS)), characterized in that the threshold at which the measurement is triggered is a transmission threshold (TXT +, TXT-) varying as a function of the magnitude of the physical phenomenon.

Description

description

The invention relates to a communication method. It also relates to a domotic sensor, so a sensor for home and home electronics to perform such a method, as well as an installation with such a domotic sensor.

In the field of dynamic sunshade devices, information provided by a sensor is used to control the lowering or raising of movable elements. The sensors used are, in particular, those which measure solar radiation, luminance, illuminance or wind.

These devices have presented problems in terms of thresholds at which the automated actuations of the movable sunshade securing elements are triggered.

According to the patent US 5,225,748 A a device for controlling a Rouleau-, blind or awning motor is known, which is connected with a wire connection to a wind sensor, to a sensor measuring the solar radiation and to a device measuring the position of the motor. If at the same time there is sunshine and wind, then the rouleau or the blind or the awning is lowered to a certain, depending on the measured wind speed altitude. The threshold values used for comparison with the voltage representative of the wind speed are e.g. B. determined by increasing reference voltages.

In many other known devices, the connection between the sensor and the control device is wireless through radio frequency.

In view of the sometimes difficult accessibility to the meteorological sensor, it is very advantageous that the reaction thresholds, that is to say the threshold values which allow the actuations of the movable element to be triggered, can be adjusted without requiring access to the sensor.

Thus, with the exception of the case where means are needed for bidirectional communication, which is expensive, it is necessary that the reaction threshold be stored at the level of the control unit for the motor operating the sunshade elements. The storage and / or change of the threshold or thresholds can then be performed directly or by means of a mobile device remote control.

Now, however, the information measured by the sensor must be transmitted with sufficient frequency so that it can be evaluated in time intervals appropriate for safety and comfort, which is necessary for the proper functioning of the installation.

In the case of a sensor-transmitter unit whose transmitter operates at radio frequency, there are two reasons for a quasi-continuous transmission of a signal containing information about the magnitude of the measured physical quantity:

The first reason is the overcrowding of the approved radio frequency spectrum. Depending on the level of transmitter strength, current regulations also require limiting the duration of the transmission or its repetition rate.

The second reason concerns the special case of autonomous sensor transmitter units. These are powered by a battery or by means for converting a physical phenomenon into electrical energy. In this case, it is clear that the transmissions must be limited as much as possible in order to increase the autonomy of the sensor. For example, one knows from the document FR 2 740 825 A1 a sun shading installation where a sensor gives a signal when a threshold is exceeded.

Solutions have been considered to solve this problem.

From the patent DE 198 35 252 C2 For example, a domotic communication system is known which operates with sensor transmitter units and a receiver connected to an actuator. In this system, the transmission of the signals by the sensor-transmitter units is time-independent, but depends on the variations in the measurements provided by the sensor-transmitter units. In one embodiment, the signal strength is a function of the changes in the measurements.

The document DE 10 2004 032 618 A1 describes a domotic apparatus for controlling a heating system having a sensor-transmitter unit that transmits signals to a receiver and measures the temperature in a room. In this case, the sensor-transmitter unit transmits a signal only when the temperature changes significantly in comparison to a setpoint temperature. The sending of measured temperature values takes place in intervals of variable duration, wherein in each case a transmission process only is triggered when a plurality of temperature differences in the same direction and the sum exceeds a threshold, with positive sign and negative sign fluctuations compensate each other. The power supply of the device is effected by a solar cell. Since sufficient light falls on the solar cell during the day, a temperature reading can be sent more frequently even with smaller temperature fluctuations. During dark periods, especially at night, there is less transmission, which is achieved by using a larger threshold. By measuring the illuminance, the dark phase is detected and the larger threshold value is used.

Furthermore, from the EP 1 122 378 A1 a sunshade known, which in response to the weather parameters transmitted by one or more sensors, in particular for wind and sun, and retracted. The transmission of the sensor signals as well as the retraction and extension of the awning is done only when predetermined measured values.

In certain applications, particularly in the motorization of rouleaux, blinds and awnings, the solutions described in the above-mentioned documents are not optimal. Namely, if these solutions are applied to a device for operating a rouleau, a blind or an awning, and if a threshold value for the change of the wind speed at which the wind sensor emits a signal, to ensure a safe operation of the device, then a certain Number of useless signals transmitted.

The invention has for its object to provide a method of communication between a Domotik sensor and a Domotik device which avoids the disadvantages explained above and improves the known communication method. In particular, the method of the invention allows to reduce the number of transmissions from the sensor transmitter unit and still transmit sufficient information. Thanks to this method, the overfilling and / or energy consumption of the sensor is smaller than in the case of known devices, without the dynamic performance of the installation consisting of the domotic sensor and the domotic device being reduced.

The communication method according to the invention is characterized by the features stated in the characterizing part of claim 1.

Various embodiments of the communication method according to the invention are given in the dependent claims 2 to 6.

The domotic sensor according to the invention is defined by claim 7.

The installation according to the invention is defined by claim 8.

Various embodiments of the inventive installation are given in the dependent claims 9 and 10.

• 1 ist das Schema einer Ausführungsform einer Installation nach der Erfindung.
• 2 ist ein Ablaufdiagramm einer Ausführungsform des Kommunikationsverfahrens nach der Erfindung.
• 3 und 4 sind graphische Darstellungen zur Erläuterung der Werte, welche die Übertragungsschwellen annehmen können.

The drawings show, by way of example, an embodiment of the installation according to the invention and illustrate an embodiment of the communication method according to the invention.

• 1 is the diagram of an embodiment of an installation according to the invention.
• 2 Figure 3 is a flow chart of one embodiment of the communication method of the invention.
• 3 and 4 Fig. 4 are graphs for explaining the values which the transmission thresholds can take.

In the 1 illustrated installation 10 basically has a sunshade device 20 , a sensor-transmitter unit RSU and a mobile user interface RCU.

The sunshade device has a sunshade element SPE in at least two opposite directions YOU 1 and YOU 2 can be operated by a motor MOT, which is controlled by a control unit SMU; This control unit SMU also processes the sun signals, and the radio frequency receiver RX This control unit allows the interface RCU sent signals and those from the sensor-transmitter unit RSU to receive transmitted signals. These signals are electromagnetic signals whose transmission blocks are in 1 are shown.

The transmission of the control commands is carried out by the user by pressing a keyboard of the interface, which a first control button UPC and a second control button DNC having. Pressing the first button causes the transmission of one from a transmitter TX2 sent control command, which from the receiver RX is received and after evaluation by a not shown processor of the control unit SMU the operation of the motor and the displacement of the sun protection element SPE in a first direction DIR1 , z. B. raising, triggers. Conversely, a pressure on the second key causes the transmission of a control command, which the displacement of the Sunshade element SPE in the other direction DIR2 , z. B. a release triggers. The coding and decoding of such instructions is well known to those skilled in the art.

The control signals issued by the user interface contain in their transmission block a typical identification information for the interface ID2 , As an alternative, the recognition information ID2 be a common detection signal for all installation elements.

The sensor-transmitter unit RSU has a logical processing unit CPU , Memory MEM, MSA *, TXT and at least one first sensor SA for a weather phenomenon, namely a wind speed sensor, a temperature sensor or a solar radiation sensor.

It can also be a second sensor SB be installed in the sensor-transmitter unit, which provides information about the measurement of several weather phenomena to the control unit SMU transfers.

This information is provided by a sender TX1 in a signal FR1 whose transmission block is a typical for the sensor-transmitter unit detection information ID1 and the measurement information INFO (MS) contains. This information is not transmitted constantly. For this purpose, the memory arrangement of the sensor-transmitter unit RSU at least a first memory TXT in which a transmission threshold is stored, and a second memory MSA * in which a measured value is stored. You can also use a third memory MEM in which the last value measured before the transmission of a signal is stored. The sensor-transmitter unit also has a polling timer TM on, which determines the time interval separating the successive measurements.

An embodiment of the invention will be described with reference to FIGS 2 described.

During an initialization step E10 becomes the value MSA the strength of a physical phenomenon from the first sensor SA measured.

In a first step E11 becomes the value MSA In the storage room MSA ^* saved.

In a second step E12 As soon as the timer generates a signal, the value of the magnitude of the physical phenomenon is measured.

One then arrives at a test step T11 in which the current value MSA the strength of the physical phenomenon with that in memory MSA ^* stored value is compared. These are the differences MSA - MSA * and MSA * - MSA calculated and with the appropriate thresholds TXT + and TXT - compared, and when exceeding the same, a signal is transmitted. These thresholds are called transmission thresholds. According to variants of the method, the threshold values TXT + and TXT - be the same or different.

If the magnitude of the change in the magnitude of the physical phenomenon does not exceed any of the transmission thresholds, the first step E11 switched back, in which the current measured value MSA the strength of the physical phenomenon in the memory MSA ^* is saved during the following test step T11 to be used.

Now, if the magnitude of the change is one of the transmission thresholds TXT + or TXT - exceeds, one arrives at a step E13 in which a signal FR1 to the control unit SMU is sent. As mentioned, the transmission block of this signal contains at least information about the measured value MSA , A first variant of the embodiment is directly related to the last measured value MSA. A second variant of the embodiment is the difference to the last stored value MSA *; this distance thus represents the percentage of change in the magnitude of the measured physical phenomenon. A third variant of the embodiment is the difference to the value measured in the previous transmission. A fourth variant of the embodiment is a combination of several previous information. In a fifth variant of the embodiment, that of a second sensor SB performed measurement MSB added. For simplicity, the measurement information is called INFO (MS).

In one step E14 becomes the measured value MSA in the third memory MEM stored so that the value that triggered the transmission of a signal is stored.

After that, the program returns to the first step E11 back.

Thanks to the above-described embodiment of the method, the transmission of an information signal concerning the value of the physical phenomenon only takes place when the derivative of this value reaches a certain threshold. Therefore, if the value of the magnitude does not vary, no information signal is transmitted.

An additional test T12 can between the test step T11 and the step E13 be provided. This test verifies that the transmission of the signals is allowed. So the test z. For example, ensure that an allowed number of transmissions per unit of time is not exceeded. It can be provided that this test does not take place when the size of the first test step T11 calculated change the thresholds TXT + or TXT - greatly exceeds. In principle, this is an additional test T12 only in case of a strongly fluctuating weather situation of use. In this case, it is unnecessary to repeatedly transmit these fluctuating measurements. This test T12 can advantageously be replaced by a period of time in which the transmissions are blocked, whereby a special signal can be transmitted before blocking in order to notify the control unit of this blockage.

In a second embodiment of the process of the method, in step T12 to the step E12 be decreased if none of the transmission thresholds is exceeded. In this way, the value becomes SMA In the storage room MSA ^* stored only when a signal has been transmitted. In this embodiment, it is the change in magnitude since the last transmission that is determinative of the initiation of a new transmission.

In a simple application, there is only a single, predetermined transmission threshold. However, it is more effective to use multiple thresholds. 3 shows an example for determining a plurality of transmission thresholds according to a logarithmic law.

In this example, it is assumed that the measured quantity MSA increases uniformly from zero. In the beginning area (left) becomes the value MSA considered too weak to be considered. In a first range of values becomes a threshold value TXT1 considered for comparison. The following value range becomes a threshold value TXT2 considered for comparison. In other words, the larger the measured quantity, the more the transmission threshold decreases. This example is applicable to certain situations where the measured magnitude of the physical phenomenon is the wind speed. At low wind speeds, one can tolerate a significant change in speed, so it is normal for the threshold to be TXT1 is chosen large. The modern rouleaux and awnings withstand considerable wind speeds, provided they are uniform. These wind conditions often occur on the coast, and a steady wind should not damage the sunshade installation; however, the stronger the wind blows, the more wind fluctuations demand the structure of the sun protection installation. It is therefore important to set the threshold for strong winds ( TXT3 . txt4 . TXT5 ) to reduce.

On the other hand shows 4 an example of the determination of several transmission thresholds according to an exponential law. In addition, in this example, a hysteresis in the selected thresholds was assumed.

This time, the measurement MSA z. B. a measurement of the illuminance. It can be seen that the transmission threshold is low when the measured illuminance is weak, so you tolerate much stronger illuminance without signal transmission, if the measured illuminance is large: For example, if their value in the fourth range, starting from zero moves, the Reinforcement over TXT14 lie to effect a signal transmission. The threshold is even higher in this area ( TXT21 ), if it is a reduction. Such a choice is explained on the one hand by the logarithmic sensitivity of the eye and on the other hand by the habituation effect of the retina.

The storage of the predetermined transmission thresholds with respect to the change in the measured quantity therefore makes it possible to transmit the signals as little as possible, as often as possible, in order to limit the high occupancy of the spectrum and the energy consumption of the transmitter. The threshold values are stored in memory in the form of a table (in 1 through the entirety of the memory shown in perspective TXT symbolized) or are calculated using a simple algorithm. It may also be provided that the thresholds are determined or modified by a learning process based on the evolution of the previously measured values. In the event that the sensor-transmitter unit has means for bidirectional communication, the determination or the modification of the threshold values can also be carried out by the user via the user interface.

It is also possible to store several tables of transmission thresholds in the memory of the sensor-transmitter unit. When installing the sensor transmitter unit then allows a switch TMC to manually select the desired table to suit the type of Domotic installation.

The choice of a particular threshold or a table of values for the transmission thresholds when installing the sensor-transmitter unit must not be equated with the setting of an actuation threshold. In fact, according to the invention, the actuation thresholds are stored at the level of the control unit SMU and can be modified there.

Upon receipt of a transmission block containing the information about the magnitude of the physical phenomenon, the control unit determines a quantity representative of that magnitude. In the simplest case, this value of the magnitude is directly the measured value MSA when it has been transmitted as information. It may also be the derivation of the strength or a mean or filtered value of the strength or even a combination of these possibilities. This representative value then becomes an adjustable threshold MVT compared.

The actuation threshold MVT is by means of manual adjustment TMS adjustable, which is located on the control unit and z. B. consists of a switch with multiple positions.

The actuation threshold MVT is preferably from the control interface RCU off set. In fact, the control unit SMU be mechanically installed in the motor-containing actuator, which is itself installed in the rouleau with the sun protection element. For this reason, a switch arranged on the control unit would be difficult to access.

A special operation of the keyboard of the user interface, z. B. a prolonged pressure on the two control buttons UPC and DNC , allows it to operate in a special mode in which the transmitted signals of the type in 1 With FR22 are designated signals. These contain the recognition information ID2 of the user interface and an indication of the setting of the actuation threshold ST (MVT) , For example, this statement translates a number of pulses to the key UPC or on the button DNC which allows to specify a shift of the threshold or a certain choice of a threshold number in a predetermined list. A dot-dashed arrow symbolizes the setting of the actuation threshold due to the receiver RX received information.

A similar operation allows adjustment of the transmission thresholds of the sensor-transmitter unit, if this with a medium TX1 equipped for bidirectional communication. A not in 1 shown transmission block, similar FR22 , then from the transmitter TX2 to the receiving part of the communication means TX1 transfer.

If the quantity representative of the magnitude of the physical phenomenon is the actuation threshold MVT exceeds, an operation command from the control unit to the engine MOT transfer. Depending on the circumstances, this command is a command to raise or lower.

Preferably, several actuation thresholds are set at the level of the control unit. The setting with the manual setting TMS or by the user interface then affects the entirety of the actuation thresholds. The actuation thresholds may also follow the logarithmic or exponential laws used in the 3 and 4 are shown. They may also have a hysteresis according to the direction of the change in the magnitude of the physical phenomenon. In contrast, the control thresholds set in the control unit are generally different from the transmission thresholds of the sensor-transmitter unit. They refer to possibly different sizes, and the first are adjustable in the once commissioned installation, while the second are not.

The interface of the control unit may also serve to convey information about which actuation should be undertaken at a particular actuation threshold. In the case of wind measurement, it can, as is known, be a partial, depending on the wind force more or less far up pulling. In the event that the sensor unit includes a rain sensor, the triggered when exceeding a precipitation threshold operation is a pulling up or on the contrary a lowering, depending on whether the awning or people are to be protected, for. B. in front of a shop window of a business.

Claims (10)

A method of communication between a domotic sensor (RSU) which measures the magnitude of a physical phenomenon and is provided with a transmission means (TX1) for transmitting a physical phenomenon signal and a domotic device (20) dedicated thereto to control visual comfort or thermal comfort in a building, wherein the transmission of a signal is triggered by a measurement of a change in the magnitude of the physical phenomenon when the change exceeds a predetermined threshold, and wherein the transmitted signal is at least one of the measured Intensity (INFO (MS)), characterized in that the threshold at which the measurement is triggered is a transmission threshold (TXT +, TXT-) varying as a function of the magnitude of the physical phenomenon. Method according to Claim 1 Characterized in that the information includes the amount of change in strength since the last transmission. Method according to Claim 1 or 2 , characterized in that the information contains the last measured strength. Method according to one of Claims 1 to 3 , characterized in that the transmission threshold varies logarithmically with the magnitude of the physical phenomenon. Method according to one of Claims 1 to 3 , characterized in that the transmission threshold varies exponentially with the magnitude of the physical phenomenon. Method according to one of the preceding claims, characterized in that the transmission threshold varies according to a hysteresis with the magnitude of the physical phenomenon. Domotic sensor (RSU) for measuring the strength of a physical phenomenon, comprising transmission means (TX1) for transmitting at least one physical phenomenon signal, characterized in that it comprises hardware means (CPU, TM, MEM, MSA *, TXT) and software for performing the method according to any one of the preceding claims. Installation (10) with a domotic sensor (RSU) according to the preceding claim and with a control unit (SMU) for controlling a motor (MOT), which drives a movable sunshade element (SPE), wherein the control unit is adapted to one for the Strength of the physical phenomenon representative quantity derived from the received information transmitted by the Domotic sensor on the strength of the physical phenomenon and to determine at least one command to automatically pull up and at least one command for automatically lowering the movable sunshade element, if for the strength of the physical Phenomenon representative size exceeds at least one actuation threshold. Installation (10) after Claim 8 , characterized in that it comprises a user interface (RCU) provided with a transmission means (TX2), that the control threshold (s) of the control unit can be adjusted by means of said user interface and that said user interface in at least one mode of operation in which it allows the transmission of control commands for controlling the movement of the motor, and in another mode in which it allows the transmission of signals containing information for modifying the operating threshold or thresholds. Installation (10) after Claim 8 or 9 , characterized in that it comprises a user interface (RCU) and a domotic sensor (RSU) provided with means for bidirectional communication, that the transmission threshold can be adjusted by means of the user interface and that the user interface at least in an operation allowing the transmission of control commands to control the movement of the motor, and operating in another mode allowing the transmission of signals to the sensor containing information for modifying the transmission threshold or transmission thresholds.

Images