EP3117569A1 - Circuit assembly for operating lighting means via a master-slave system - Google Patents

Abstract

The invention relates to a circuit assembly for operating at least one lighting means, comprising at least one master device (M1); at least one slave device (SL1-1); and a bus system having at least one bus (BM1), by means of which bus system the at least one master device and the at least one slave device are coupled; wherein the bus is designed as a two-wire cable, wherein the at least one master device has at least one feeding connection (SPM1), which is coupled to the bus and is designed to place a control signal (USM1) on the bus, wherein the at least one master device is coupled to a first voltage supply (UVM1); wherein the at least one slave device (SL1-1) comprises a non-feeding connection, which is coupled to the bus, wherein the slave device (SL1-1) comprises a connection for at least one lighting means, a second voltage supply (UVM1S1), and a read-out device for reading out the control signal on the bus, wherein the read-out device comprises a potential-isolating device (D14, Q8) and wherein the connection for the at least one lighting means and the second voltage supply are provided on the side of the read-out device isolated from the bus with regard to potential.

Description

 Besehreibung

CIRCUIT ARRANGEMENT FOR OPERATING LUMINAIRES OVER

A MASTER SLAVE SYSTEM

Technical area

The present invention relates to a circuit arrangement for operating at least one luminous means comprising at least egg ^¬ ner master device, at least one slave device and a bus system with at least one bus to which said at least one master device and a slave device coupled to at least.

Called state of the art lamps or lamps, hereinafter referred to as LE (= light engines), elements for automation ^¬ mation of lighting systems may contain. This may be at ^¬ play as light sensors that prevent switching on the LE at sufficiently high ambient light levels of relationships as they LE automatically turn on when the Umgebungshel ^¬ ligkeit falls below a predetermined value. Furthermore, a motion sensor can also be integrated on an LE which switches on the LE or changes its brightness if a movement, for example a moving person, is detected in a target field.

In some applications, however, it may be useful to provide a relatively high number of lights for lighting reasons, but not to provide sensors in each of these lights. It is advantageous to use sensors only in to install part of the luminaires and to remotely control the other luminaires from the luminaire with sensor.

The present invention is concerned with the problem of describing a simple way of how control signals from a luminaire with a sensor, ^hereinafter referred to as a master, can be transmitted to a luminaire without a sensor, hereinafter referred to as a slave.

From the prior art, numerous bus Bezie ^¬ hung as master-slave systems are known, for example, under the designation I ² C or DALI.

In this regard, the AT discloses 11444 Ul an interface for a bus device of a Beleuchtungsanla ^¬ ge, wherein the interface comprises a rectifier for ^¬ judge the voltage of the bus line, and means for electrical isolation of the bus line, wherein the rectifier and the means for potential separation contained in an integrated interface.

The GB 2115240 A discloses a control device for Steue ^¬ tion is applied from an AC power supply to a load the current through the phase control of an electrically triggerable switch which is connected between load and power supply, wherein the control device comprises a Phasendetek- gate device for Generation of a sequence of clock signals ^¬ at respective times, to which the AC power supply is at a predetermined point in its waveform.

Furthermore, DE discloses 20 2005 021 023 Ul a Gebäudein ^¬ stallationssystem consisting of two different Bussys- temen, which each have at least one bus device that communicate with each other for the purpose of communication, the demand-function ^¬ fulfillment and commissioning a Busübertragungsmodul, wherein incoming information of the first bus system in transmitted commands the second bus system and / or incoming information from the second bus ^¬ systems in transferable commands of the first bus system vice ^¬ sets are, all bus devices have such a structure that the bus devices of the first bus system are only using a custom physical layer as adapted bus devices for use in the second bus system ^¬ bar ,

From DE 10 2009 009 535 AI a circuit for driving a control gear for a light application is known, with a galvanically isolated transformer to which a Steuersig ^¬ signal can be applied, and with a power unit, which depends on the galvanically isolated transformer the control signal is activated.

However, these systems require not inconsiderable circuit, installation and cost. For simple applications, such high complexity and functionali ^¬ ty is not desirable for cost reasons.

Presentation of the invention

The object of the present invention is therefore to develop a generic circuit arrangement such that a cost-effective transmission of control signals from a master to at least one slave is made possible. This object is achieved by a circuit arrangement having the features of patent claim 1.

The present invention is based on the finding that ei ^¬ ne cost-effective solution of the above object is made possible when the bus is designed as a simple two-wire line to which the master device applies a control signal. The invention further based on the fact that the Mastervorrich ^¬ tung, in particular different master devices, and the at least one slave device, in particular different slave devices can usually be coupled in non vorhersag ^¬ Barer manner with the different phases of alternating ^¬ grid. Would without further Vorkeh ^¬ stanchions slave devices thus to read out the force applied by the master device control signal of electrically conducting tend coupled to the bus, so it could cause a short circuit kom ^¬ men in unfortunate choice of the power supply of the master and the Spannungsver ^¬ supply of the at least one slave which not only prevents readout of the control signal by the slave, but could destroy both components of the master and the slave. This problem is vermie ^¬ when the readout electrically isolated, that is, electrically isolated, is carried out. In this way, the master and slave can be coupled in any way with the power supply, without causing short circuits or destruction of the corresponding circuits would be feared. The master and the slaves can be connected to the AC ^mains without further precautions.

, The bus is according to the invention therefore, as mentioned, carried out as a two-wire line ^¬. The master device has at least a feeding terminal coupled to the bus and configured to apply a control signal to the bus, wherein the master ^{device is} coupled to a first power supply. The at least one slave device includes a non-feeding port that is coupled to the bus, where ^¬ summarizes a connection for at least one light source, a second power supply and an off ^¬ reading device for reading the control signal on the bus to ^¬ at the slave device. The read-out device in turn comprises a potential-altrennvorrichtung, wherein the terminal for the at least one lighting means and the second voltage supply to the electrically isolated from the bus side of the readout device is vorgese ^¬ hen.

In a preferred embodiment, the Mastervor ^¬ direction also comprises a non-feeding terminal which can be coupled to another bus, wherein the master device comprises a connection for at least one lamp and a read-out device for reading the control signal on the wei ^¬ teren bus, wherein the read-out device a potential separation ^¬ device comprises and the connection for the at least one light source is provided on the isolated from the further bus side of the read-out device. By this measure ^¬ takeover possibility is basically created so that the master device can read a control signal from another bus ^¬. This becomes particularly relevant when, as will be explained in more detail below, a second master device is coupled to the bus, with which the first master device is coupled to its feeding terminal. In this context, it is particularly preferred when the non-feeding port of the master device further comprises a short-circuit device ^¬ is Pelbar with the other bus LAD, wherein the short-circuit device gear, a control inputs for applying a short-circuit signal comprises and out ^¬ sets, the two lines of the other bus upon application of a short-circuit signal at its control input kurzzuschlie ^¬ SEN, wherein the short-circuit device comprises a Potentialtrennvor ^¬ direction for separating the potential of the control input from polyvinyl tential of the other bus. In this way, a master device, which is coupled only with its non-feeding terminal to a bus, the control signal of the master device, which is coupled with its feeding terminal to the bus, override, that is to say cancel. In this way, the basis is created that several Mastervor ^¬ directions, which are preferably each coupled to at least one slave device via its feeding terminal, can cooperate, each with a bus of Busys ^¬ tems only a master device with its dining on - coupled circuit, however, several master devices can be coupled with their non-feeding terminals. Since ^¬ by their non-feeding terminals gekop ^¬-coupled master devices can the potential, and thus the control signal, determine on the bus and thus control the Mastervor- direction, which is connected with its feeding connection with the ^¬ sem bus, as well as to Slave devices coupled to this bus.

In one embodiment, therefore, the circuit ^arrangement comprises at least a first and a second bus, at least a first and a second master device, each with a feeding terminal and a non-feeding terminal, wherein at least the feeding terminal of the first master device is coupled to the first bus, the feeding terminal of the second master device being coupled to the second bus, the non-feeding terminal of the second master device being connected to the second bus first bus is coupled. In this constellation, the second master device, via its non-feeding terminal, can affect the potential, and thus the control signal, on the first bus, which is actually fed by the first master device. In a concrete application example, one can imagine a long corridor, at one end of which the first master device is positioned and at the opposite end of which the second master device is positioned. A plurality of slave devices, which are the first master device zugeord ^¬ net are distributed between the first and the second Mastervor ^¬ direction and are electrically isolated coupled to the first bus. Both master devices are equipped with a motion sensor. Now, if the first master device detected no movement and thus the coupled with her bulbs and coupled to the associated slave ^¬ devices bulbs by appropriate control by applying a corresponding control signal in a resting state, for example, off or dimmed leaves, can second master device, if it detects a BEWE ^¬ tion, override this switch-off and thus activate themselves, ie their own light source, the light source of the first master device and the light source of the coupled to the first bus slave devices. In this way, several master-slave devices according to the invention can thus be used. Systems are interconnected, for example, to control the Be ^¬ lighting in a long corridor sections.

The respective potential separation ^device preferably comprises an opto-coupler. If a transformer were used instead, the control signal would have to be present as an AC signal. In Ver ^¬ use of an optocoupler, however, in an inexpensive and simple way a DC signal can be transmitted. EMC problems can be reliably prevented. The optocoupler preferably comprises a transmitting diode and a phototransistor, wherein a current limiting device, in particular an ohmic resistor, is coupled in series with the transmitting diode. This current limiting device is particularly advantageous when the forward voltages of several connected to the bus ^¬ ner readout devices are different in size. The current limitation can ensure that approximately the same current flows in all the transmitting diodes connected to the bus. This ensures a reliable function of the Op ^¬ tokoppler or connected to the bus Auslesevorrich ^¬ tions regardless of their number. The feeding terminal of a master ^device preferably comprises a first current limiting device, which is arranged between the positive terminal of its voltage supply and the bus or between the minus terminal of its voltage supply and the bus. With this current limiting device, it can be ensured that the non-feeding terminal of another master device connected to the bus can short-circuit the bus voltage in order to override, ie to deactivate, the control signal of the master device, which is coupled with its supply terminal to the bus. The current limiting device also contributes to the fact that the bulbs take no damage even in the case of a wrong connection.

For protection of the bus against maladjustment, game as to allow examples accidental coupling of the supply tension ^¬ voltage on the bus or by joining two dining connec ^¬ se two master, may be provided, that the feeding port of a master device, a first Di ^¬ ode and a second diode, wherein the first diode between a first connection of its power supply and a first line of the bus is coupled and the second diode between a second terminal of its voltage supply ^¬ supply and a second line of the bus, wherein the first and the second diode are arranged in antiparallel.

To further improve the circuit arrangement of the feeding port of a master device may comprise a second current ^¬ limiting device, wherein one of Strombegren ^¬ wetting devices between the minus terminal of its clamping ^¬ voltage supply and the bus and the other current limiting ^¬ device between the plus terminal of its Spannungsver ^¬ supply and the bus is arranged. This measure ensures that take in case of accidental connection of mains voltage to the bus terminals connected Mas ^¬ ter and slave devices no harm. According to a preferred development of the non-SpeI ^¬ transmitting terminal includes a rectifier which is disposed on the bus coupled to the side of the potential separation device to the DC ^¬ direction of the control signal on the bus. In this way, whatever the polarity of the tax nals on the bus a transmission with one and the same opto ^¬ coupler take place.

Preferably, the non-feeding terminal ei ^¬ ne evaluation, which is designed to evaluate the control signal on the bus to which the non-feeding terminal is coupled, whose input to the phototransistor of Op ^¬ tokopkopers the respective potential separation device and the output with the respective lighting means is coupled, wherein the control signal represents a PWM signal. In this way, the evaluation device is provided isolated from the bus, the possibility is created by einzu¬ by varying the PWM signal different operating states of coupled to the non-feeding terminals illuminant ^¬ . In this context, it is particularly advantageous if the evaluation device is designed to implement the PWM signal as follows: A bus-controlled operation of the respective luminous ^¬ means with nominal power or a nominal luminous flux is activated by a PWM signal with 0% pulse width and / or a busgesteuerter off state of the respective light-emitting ^¬ means is activated by a PWM signal having a kleins ^¬ th permissible pulse width and / or bus-operating with dimming levels between the off state and the nominal Leis ^¬ tung or the nominal luminous flux are activated by a PWM signal with pulse widths which are larger than the smallest permissible pulse width, in particular also by a PWM signal with 100% pulse width. By this arrangement results in several advantages: Because a nominal operation is ak ^¬ tivated by a PWM signal of 0% pulse width, i.e., between the bus lines is no voltage, allowing the slave devices operate in the case where they are not connected to a bus with a nominal Leis ^¬ tung or nominal light current. Due to the fact that a PWM signal with a smallest permissible pulse width is agreed for a bus-controlled off state of the respective luminous means, standby losses are minimized optimally. The agreement that with a PWM signal with pulse widths that are greater than the smallest allowable pulse width, bus-controlled operating modes can be activated with different dimming levels, results in a particularly high efficiency, since the light sources supplied to the light ^¬ tion, for example, the ambient brightness depending ge ^¬ can be made. Especially just can also beispiels-, by a PWM signal with 100% duty cycle, which corresponds to a DC signal, a fixed relationship be ^¬, in the master stored in the slave devices dimming be activated here.

Preferably, the at least one master device includes a sensor, in particular a brightness sensor and / or a motion sensor that is adapted to provide a Sen ^¬ sorsignal at its output, wherein the at least one master ^¬ device is adapted to generate the control signal in dependence on the sensor signal. In other words, only the respective master devices need to be provided with a sensor, then the connected slave devices or even other master devices (via their non-supplying input) according to the sensor signal control Kings ^¬ nen. Further preferred embodiments will be apparent from the sub ^¬ claims.

Short description of the drawing (s)

In the following, embodiments of the now ahead ^¬ invention with reference to the accompanying drawings will be described in more detail. These show:

Fig. 1 is a schematic view of an embodiment of the present invention;

Fig. 2 is a more detailed illustration of the embodiment of Fig. 1;

Fig. 3 shows an embodiment of a supply circuit with two

 Current limiting devices;

Fig. 4 shows an embodiment of an analog Auswertevorrich ^¬ tung; and

Fig. 5 examples of control signals for setting different ^¬ Licher light fluxes in an inventive scarf ^¬ processing arrangement.

Preferred embodiment of the invention

The same reference numerals are used for identical and equivalent construction elements ^¬ hereinafter. These are introduced only once for the sake of clarity. Fig. 1 shows a schematic representation of a Ausführungsbei ^¬ game of a circuit ^arrangement according to the invention. This includes a first master Ml and a second master M2. The master M1 comprises a feeding terminal SPM1, which is designed to apply a control signal to a bus BMI. The master M1 further comprises a non-feeding terminal NSPM1, which is coupled to a bus BMO. Between the bus BMO and an input of the master Ml EMI a Po ^¬ tentialtrennvorrichtung PTM11 is provided. Between the bus BMO and an output AMI of the master Ml a potential separation device PTM12 is provided. The master Ml is connected to a supply voltage Ver ^¬ UVM1 that can exchange clamping ^¬ voltage source, such as a mains voltage present. Over the bus BMI are the master Ml several slaves SL1-1 and SL1-N assigned, where N represents a natural number. These also have a non feeding An ^¬ circuit which is coupled via a respective potential separation device PTS1- 1 and PTSL N bus BMI.

Each slave SL1-1, SL1-N is coupled via a corresponding input ES11 or ES1N to the respective potential separation device PTS11 or PTS1N. The slave SL1-1 is coupled to a voltage source UVM1S1, the slave SL1-N to a voltage source ^¬ UVM1S2. The master M2 is powered by a voltage source UVM2. Its non-feeding terminal NSPM2 comprises an input EM2 on the one hand and an output AM2 on the other hand and is coupled to the bus BMI. The corresponding potential separation devices are designated PTM21 and PTM22. The master M2 controls the bus BM2 with its feeding terminal SPM2. A slave SL21 is coupled with its input E21 via a potential ^¬ separating device PTS21 to the bus BM2. This slave SL2-1 is supplied by a power supply UVM2S1. A slave SL2-N is coupled with its input E2N via a potential ^¬ separating device PTS2N to the bus BM2. This slave SL2-N is powered by a power supply UVM2SN.

The power supplies mentioned can be coupled in any Wei ^¬ se, ie with arbitrary phases, with an AC voltage network.

The devices connected to the respective buses BMI and BM2 slaves can only read the voltage or voltage waveform at each ^¬ weiligen bus and its operation set the respective ^¬. In this overview, neither sensors of the master Ml, M2 nor their bulbs, nor the Leuchtmit ^¬ tel of the slaves are located. How these within the jeweili ^¬ gen device (slave or master) must be supplied from a supply Spannungsversor ^¬, the skilled person is well known, but by way of example explained in more detail in connection with FIG. 2.

In order to operate as a so-called multi-master system he ^¬ possible, each master Ml, M2 has a non spei ^¬ send port that is connected to the corresponding bus BMI and BM2. About this master Ml, M2 in the same Way as slaves query the voltage signal of the bus to ^¬ additionally but change the signal.

With the structure shown in FIG. 1 it can be achieved that a number of light sources consisting of two masters and N slaves can be controlled by the master M1 via its feeding terminal and also the master M2 impresses the operation of the arrangement via its non-feeding terminal NSPM2 ^{¬ can} flow.

Each master M1, M2 can thus query the voltage signal of another bus, via its non-feeding connection NSPM1 or NSPM2, in the same way as the slaves, to which it is connected via its non-feeding connection. Thus, in this case, the non-feeding terminal NSPM1 of the master Ml is coupled to a bus BMO, the non-feeding terminal NSPM2 of the master M2 to the bus BMI. Then only the state of the "neighbor bus" is queried via the Dio ^{¬ the} distance in the optocoupler of the non-feeding Masteranschlus ^¬ ses. The Abfra ^¬ gen of "own bus", which is integrally ^¬ closed at the dining connector can be done in two ways: first, as described below in conjunction with Figure 2a illustrated by the example of the master Ml without optocoupler directly in the dining At ^¬. conclusion by an interrogation device AFM1, which includes a voltage sensor voltage ^¬ over which the master Ml can recognize that the master M2 short-circuits the bus BMI. Second, via a structure, not shown, as in the non-feeding An ^¬ circuit, but the device is internally connected to the bus BMI.

FIG. 2 a shows a circuit realization of the exemplary embodiment of a circuit arrangement according to the invention shown schematically in FIG. 1. As you can see, the circuit-technical idea consists in the fact that the supply ^¬ de connection of a first master Ml is not carried out electrically isolated, but all other connections, that is the slaves SL1-1, SL1-2, SL1-N and the non-feeding port NSPM2 a second master M2 are only connected via potential-separating devices, such as optocouplers, to the bus BMI.

In the following explanations, the structure or mode of operation of certain elements of the circuit device according to the invention is explained by way of example on specific modules. Apparent to those skilled in the art entspre ^¬ sponding modules from other elements of the same category (slave, master, etc.) are constructed accordingly.

A circuit example for a non-feeding connection:

At the input of the non-feeding terminals NSPM1 the master Ml, ES11 whereby ent ^¬ speaking buses BMI or BMO are polarized in the slave SL1-1, NSPM2 the master M2, anlie ^¬ constricting control signals are rectified. The diodes D15 to D18 are used for rectification in the master M1, the diodes D9 to D12 in the slave SL1-1 and the diodes D21 to D24 in the master M2. To read each serves an optocoupler to ^¬ summarizes a transmitting diode and a phototransistor. In the master Ml the transmitting diode is denoted by D51, the phototransistor not shown for clarity. In slave SL1-1, the transmitting diode is denoted by D14, the phototransistor by Q8. When master M2, the transmitting diode is denoted by D52, the phototransistor again not shown. The respective transmission diode is in series with a Strombegren ^¬ pollution, for example, by a resistor (R15 at the master Ml, R7 SL1-1 for the slave, the master R16 M2) can be formed, with correct polarity applied to the output of the corresponding DC rectifier , The LE, in this case using the example of the slaves SL1-1 represented by two LEDs, can thereby poten ^¬ tialfrei via the phototransistor Q8 of the optocoupler evaluate the lying on the bus BMI control signal USM1. For this purpose, the supply voltage UVM1S1 of the slave SL1-1 is rectified by means of the diodes D52 to D55 and applied to the series connection of an ohmic resistor R17 and the phototransistor Q8 ^¬ . The potential at the collector of transistor Q8 is supplied ei ^¬ nem pCl microprocessor which controls a series to the LEs between the outputs of the rectifier D52 to D55 gekoppel- th transistor Q7.

A circuit extension for a non-feeding master connection, for example, the connection NSPM1 the master Ml, allows the master Ml the bus voltage of a "neighbor ^¬ busses" can also short out. For this purpose a Kurzschlussvorrich ^¬ tung is further coupled to the output of the rectifier D15 to D17, which includes the series connection of an optional rule ^¬ ohm resistor R5 and a transistor Q2. The transistor Q2 is designed as a phototransistor and cooperates with a transmitter diode D65. With a suitable control of the transmitting diode D65 this includes the phototransistor Q2 short and thereby specifies a short-circuit signal to the "Nachbarbus" ^¬ before lying the bus BMO.

In order to recognize that the master M2 applies a short-circuit signal to the bus BMI, an interrogator is provided in the master M1 AFM1 provided, which includes a voltage sensor, via which the master Ml can detect whether the master M2 shorts the bus BMI

The feeding terminal SPM1 of the master Ml includes a current limiting SBM11 and two diodes D26 and D20. The current limitation SBM11 ensures that the non-feeding terminal NSPM2 of another master M2 connected to the bus BMI can short-circuit the bus voltage without destroying the components of the master M1. In addition, tra ^¬ gen current limiting SBM11 and the two diodes D20, D26 to the fact that LEs are not damaged in the event of incorrect installation. A faulty connection would be at ^¬ before game as if accidentally each feeding arrival circuits, SPM1 of the master Ml and M2 of the master SPM2, would be connected to the same bus line BMI.

The power supply of the master Ml is realized by applying a rectifier comprising the diodes D5 to D8 to an AC voltage source UVM1, for example a mains voltage. At the output of the rectifier D5 to D8 is a rectified AC voltage ready, which is smoothed by means of a parallel circuit comprising a capacitor C2 and an ohmic resistor RIO. This rectified AC voltage serves on the one hand to operate the components of the master Ml, in particular also its LE, not shown. As can be seen from Fig. 2b, is calculated from the voltage and the control signal UVM1 USM1 Won ^¬ NEN, the present is a PWM signal having a level between 0 V and 10 V. For this purpose, the rectified change is Selvoltage UVM1 the series circuit of an ohmic ^¬ resistance R18 and a Zener diode ZI supplied, wherein the Zener diode is an electronic switch, in this case the Bipo ^¬ lartransistor Q9, connected in parallel. Its base is coupled to the output of a microprocessor pC2, which is just ^¬ if supplied by the rectifier D5 to D8. The micropro cessor ^¬ pC2 BS has an input via which it a Steuersig ^¬ nal, for example, a brightness sensor or a BEWE ^¬ supply sensor, is supplied. The microprocessor pC2 is formed off, steer the transistor Q9 in response to the signal BS at ^¬. This will be described in more detail below with reference to FIG.

The serially connected to the control signal USM1 Spannungsbegren ^¬ tion SBM11 includes the transistors Ql and Q4 and the ohmic resistors Rl and R8. In this case, the ohmic resistor Rl connected between the collector and the base of transistor Ql is coupled ge ^¬, the ohmic resistor R8 between the base and the emitter of the transistor Q4. The base of transistor Q4 is coupled to the emitter of transistor Ql and the collector of transistor Q4 is coupled to the base of transistor Ql.

Another current limiting device SBM12 is coupled between the negative terminal of the voltage source USM1 and the bus BMI. This measure ensures that even in the case of accidental connection of the mains voltage UVM1 to the bus connections, the devices connected to the bus are not damaged.

Fig. 3 shows a more detailed view and a Abwand ^¬ development of a section of Fig. 2a, namely, the current limiting Tonging devices of the master Ml. The Strombegrenzungsvor ^¬ SBM11 direction corresponds to that shown in Fig. 2a, wherein le ^¬ diglich the transistor Ql is designed as a Darlington stage. The current limiting device SBM12 comprises the series connection of a transistor Q15 and an ohmic resistor R18, which are coupled between a bus line and the reference potential. Between the base of transistor Q15 and the diode D61 Bezugspo ^¬ tential a coupled. Parallel with the diode D61, the collector-emitter path of a transistor Q14 overall is on, its base through the series connection of an ohmic resistor R19 and a diode D60 to a bus line is gekop ^¬ pelt. The base of transistor Q15 is coupled via a resistor R23 ohm ^¬ rule to the plus terminal of the voltage source USM1.

While in Fig. 2 represents the evaluation circuit is provided in digital form with ^¬ means of the microprocessor pCl the example of the slave SL1-1 ^¬, Fig. 4 shows a similar evaluation on the example of the slave SL1-1, the different PWM signals converted so that certain conditions in the LEs activated ^¬ to. Such an evaluation circuit 10 can be used in all slaves or for the non-feeding connections of the master Ml, M2.

On the input side, this evaluation circuit 10 is coupled to the bus BMI via an opto ^¬ coupler, which comprises the transmitting diode D14 and the phototransistor Q8. To supply this from ^¬ evaluation circuit 10 of the slave SL1-1, which usually represents the mains voltage, a DC voltage from the supply voltage is UVMS1 UVM1S1 'derived, which in the Ausführungsbei ^¬ game 10V. Between the connections of the voltage source le UVMS1 'is the series circuit of an ohmic resistor R43 and a transistor Q21 coupled. The base-emitter path of the transistor Q21 is connected in parallel with the parallel connection of an ohmic resistor R74 and a capacitor C13. The base terminal of the transistor Q21 is coupled via a resistor R71 to the collector of Fototran ^¬ sistor Q8. Between the collector of Q8 Fototransis ^¬ gate and the voltage source UVMS1 'is an ohmic reflection ^¬ was coupled R70. Between the terminals of the voltage source UVMS1 ', the series circuit of a transistor Q20 and an ohmic resistor R75 is coupled. The base of the transistor Q21 is on the one hand coupled via the parallel circuit ei ^¬ nes capacitor C12 and an ohmic resistance R72 to the plus terminal of the voltage source UVMS1 '. Ande ^¬ hand, this base via a transistor Q22 to the low- pressure connection of the voltage source is coupled UVMS1 '. The base of transistor Q22 is coupled to the collector of the phototransistor Q8, and via the series circuit of a Kondensa ^¬ tors CIO, an ohmic resistor R77 and an ohmic resistor R76, the connection point between the Kon ^¬ capacitor CIO and resistor R77 via a diode D80 is coupled to the negative terminal of the voltage source UVMS1 'and the connection point between the ohmic Widerstän ^¬ the R77 and R76 via the parallel circuit of a capacitor Cll and a resistor R78.

How it works: As can be seen, an off-output is formed by the emitter of the transistor Q20 and a dimming output by the collector of the transistor Q21. The following important conditions result: 1. An OV signal, ie a PWM signal with a duty cycle of 0% or a non-connected input, causes the base of the transistor Q21 receives a sufficiently high voltage through the ohmic resistors R70 and R71 and the Kollek - Gate-emitter voltage U _C E of the transistor Q21 goes to 0V, where ^¬ by the signal "Dimming" goes to 0V (low).

The base of the transistor Q22, however, remains at 0V because of the con ^¬ densators CIO. Any voltage peaks during switching are strongly attenuated by the capacitor Cll and the ohmic resistors R78 and R77. Characterized the base of the Tran ^¬ sistors Q20 remains over the ohmic resistor R72 to the potential of UVMS1, whereby the "Off" on the ohm resistor R75 ^¬'s signal remains at 0V (low).

2. A PWM signal with the smallest permissible size at the ^{input of} the opto-coupler leads at the collector of the transistor Q8 to an inverted PWM signal with a very high duty cycle. This leads via the high-pass from the ohmic resistances R77 and R78 and the capacitor CIO to a sufficiently high Sig ^¬ nalpegel at the transistor Q22. Through the resistor R76, the current will continue to be limited in ^¬ the base of transistor Q22. The capacitor CII provides for buffering the Sig ^¬ Nalles and cooperates with the resistor R77 together as a low pass. About the ohmic resistance R78 of the capacitor ^¬ Cll is discharged in other operating conditions in a defined time. The diode D80 ensures that during the short on-time at the input of the optocoupler (0V at the collector of Tran ^¬ sistor Q8) of the capacitor Cll is not significantly discharged, but then current in the circuit D80, CIO and Q8 can flow. The capacitor Cll and the ohmic resistor R78 act as additional low-pass for changing signal states at the base of the transistor Q20, which is pulled in this state via the transistor Q22 to OV. As a result, the signal "OFF" almost takes on the potential of UVMS1 (high). The ohmic resistor R80 limits the current through the base of the Transis ^¬ sector Q20.

3. A PWM signal with almost 100% duty cycle or a DC voltage at the input of the optocoupler causes the Kol ^¬ lector-emitter voltage U _C E of the transistor Q8 is almost 0V and thus the base of the transistor Q21 is pulled to 0V. Thus, the "dimming" signal via the ohmic resistance is ^¬ was raised to R73 UVMS1 (high). The network of the ohm resistors ^¬ rule R71, R74 and capacitor C13 also acts as a low pass for any spikes. The base of the transistor Q22 in this state via the resistor R78 at 0V, thus leaving the base of the transistor Q20 via the resistor R72 on the Po ^¬ tential of UVMS1. As a result, the signal "Off" remains at 0V (low) via the ohmic resistor R75. The following table shows, in conjunction with FIG. 5, the behavior of the evaluation circuit 10 of FIG. 4:

PWM pulse signal at the signal at the operating state spread to node "Off" node of the LE

 Bus line "Dimm"

0% low low nom. Power smallest not out to ^¬ high state

casual size defined

100% low high dimming condition

Accordingly, a PWM pulse width on the bus line BMI of 0%, that is, a short circuit between the two Busleitun ^¬ gen, leads to a low signal at the node Off and a low signal at the node dimming. Characterized the respective LE is operated with nominal Leis ^¬ processing. If a PWM signal with the smallest permissible pulse width is given to the bus line, a signal high at the node Off, an undefined signal at the node Dimm, which results in the OFF state of the LE. At node off, however, is on the bus line a DC voltage signal, that is, a PWM signal having a pulse width of 100% defined, produces a low signal, which is operated ^¬ by the LE in a predetermined dimming state at node dimming a high signal, ,

In addition to these three operating states, Fig. 5 shows an example of a further operation state in which a PWM signal with egg ^¬ ner pulse width is set by 95% on the bus line, which leads to a further dimmed state, which can be arranged according to darker or brighter than the dimming status which results at a PWM pulse width of 100%. . From the architecture according to Figure 5, the following advantageous ^¬ exemplary operation of the master-slave system is obtained as shown in FIG. 2:

- It is determined that the bus-controlled operation of the slaves and the master, which are connected via their non-feeding terminal to the same bus line, with nominal power or nominal luminous flux is activated by a PWM signal with 0% bus width is on the bus line, ie no voltage between the bus lines. This will allow the slaves to operate at nominal power (or nominal luminous flux) in the event they are not connected to a bus.

- To minimize standby losses, it is further determined that the bus-controlled OFF state of the slaves and the master, which are connected via their non-feeding terminal to the same bus ^¬ line, thereby activating a PWM signal with the smallest allowable pulse width is located on the bus ^¬ line.

- Other bus-controlled operating modes of the slaves and the master, which are connected via their non-feeding connection to the same bus ^¬ line, are activated by PWM signals with larger pulse widths than the smallest allowable pulse width acti ^¬ fourth. Particularly simple example, by a PWM signal with 100% duty cycle (corresponding to a DC clamping voltage signal ^¬) a fixed into the masters and slaves dimming will be activated. This definition of the operating states enables the following operation:

In the case of a detected movement, each master, which is connected with its feeding or non-feeding terminal with egg ^¬ ner bus line, put all the connected LEs in the nominal operating state.

The master, which is integrally joined ^¬ with its feeding port on the bus, sets to at detected movement no clamping ^¬ lation (PWM signal of 0% duty cycle) to the bus. The master, which is connected to the bus with its non-feeding connection, closes the bus lines briefly when movement is detected, whereby no voltage (PWM signal with 0% duty cycle) is present on the bus. This is possible because, as described above, the supply circuit of the feeding master is current limited.

In idle state, that is no detection of a movement by the master, which is connected to its feeding connection with a bus line ^¬, a PWM signal with a duty ratio> 0 on the bus. This quiescent state, there are several Mög ^¬ possibilities:

- The master creates a PWM signal of the smallest allowable pulse width ^¬ on the bus, resulting in that all LEs, which are connected to this bus, generate no light (off state). By the power of masters and slaves is minimized in this standby mode because the Ener gy ^¬ is minimal for the operation of the receiving devices on the slaves and the masters and the signal generation in the dining Master required.

- The master applies a PWM signal with a pulse width greater than the smallest permissible pulse width to the bus. This condition causes all LEs connected to this bus to produce light of a predefinable fixed value or to generate an amount of light proportional to the PWM signal pulse width (dimming condition).

The motion detector may be provided with a time control, so that the corresponding control signal is applied over a bare vorgeb ^¬ time on the respective bus.

Claims

claims

1. Circuit arrangement for operating at least one light ^¬ means with

 - At least one master device (Ml);

 - at least one slave device (SL1-1); and

 a bus system having at least one bus (BMI) to which the at least one master device and the at least one slave device are coupled;

 characterized,

in that the bus (BMI) is designed as a two-wire line, wherein the at least one master device (M1) has at least one feeding terminal (SPM1) which is coupled to the bus (BMI) and designed to apply a control signal (USM1) to the bus (BMI ), wherein the at least one master ^¬ device (Ml) is coupled to a first power supply (UVM1);

wherein the at least one slave device (SL1-1) comprises a non-feeding port (ES11) connected to the bus (BMI) is coupled, wherein the slave device (SL1-1) (ei ^¬ NEN connection for at least one luminous means, a second voltage supply UVM1S1) and a readout device for reading out the control signal (USM1) on the bus (BMI) summarizes order ^¬, wherein the readout device comprises a Potentialtren ^¬ nvorrichtung (D14, Q8) and the terminal for the at ^¬ least one luminous means and the second Spannungsversor ^¬ Supply (UVM1S1) on the isolated from the bus (BMI) Be ^¬ te the read-out device is provided.

2. Circuit arrangement according to claim 1, characterized,

in that the master device (M1) comprises a non-feeding connection (NSPM1) which can be coupled to a further bus (BMO), the master device (M1) comprising a connection for at least one luminous means and a read-out device for reading the control signal (USM1) on the further bus (BMO), wherein the readout device comprises a potential separation device and the connection for the at least one light source on the isolated from the further bus (BMO) side of the readout ^{device is} seen before ^¬ .

3. Circuit arrangement according to claim 2,

 characterized,

that the non-feeding port of the master device (Ml) further holds a short-circuit means (D65, R5, Q2) for ^¬ that (BMO) is connected to the other bus coupled, wherein the short circuit means (D65, R5, Q2) having a control input for applying a short-circuit signal comprises and is adapted to the two lines of the further bus (BMO) at at ^¬ are of a short-circuit signal at its control input briefly shut ^¬, wherein the short circuit means (D65, R5, Q2), a potential separation device (D65, Q2) for separating the Po ^¬ tentials of the control input from the potential of the further Bus ^¬ ses (BMO) includes.

4. Circuit arrangement according to claim 3,

 characterized,

 the circuit arrangement comprises:

at least a first (BMI) and a second bus (BM2); - At least a first (Ml) and a second Mastervorrich ^¬ device (M2) each having a feeding terminal (SPM1, SPM2) and a non-feeding terminal (NSPM1, NSPM2), wherein at least the feeding terminal (SPM1) of the first

Master device (Ml) is coupled to the first bus (BMI),

wherein the feeding terminal (SPM2) of the second Mastervor ^¬ direction (M2) is coupled to the second bus (BM2), wherein the non-feeding terminal (NSPM2) of the second Mastervor ^¬ direction (M2) is coupled to the first bus (BMI) ,

5. Circuit arrangement according to one of the preceding Ansprü ^¬ che,

 characterized,

 in that the respective potential separation device (D51, Q2, D65, D14, Q8) comprises an optocoupler.

6. Circuit arrangement according to claim 5,

 characterized,

that the photo coupler comprises a transmitter diode (D51; D14; D65);, wherein serially to Sen ^¬ dediode (D51; D14, D65) and ei ^¬ NEN photo transistor (Q2 Q8) having a current limiting means (R15; R7), especially an ohmic resistor, is coupled.

7. Circuit arrangement according to one of the preceding Ansprü ^¬ che,

 characterized,

in that the feeding terminal (SPM1) of a master device (M1) has a first current limiting device (SBM11; SBM12) includes, between the plus terminal of its voltage supply ^¬ (UVM1) and the bus (BMI) or between the minus connection of its power supply (UVM1) and the bus (BMI) is arranged. Circuit arrangement according to Claim 7,

characterized,

that the feeding port (SPM1) summarizes a master device (Ml) a first diode (D26) and a second diode (D20) to ^¬, wherein the first diode (D26) between a first on ^¬ circuit of its power supply (UVM1) and a first Line of the bus is coupled and the second diode (D20) between a second terminal of its power supply (UVM1) and a second line of the bus, wherein the first (D26) and the second diode (D20) are arranged in anti-parallel. Circuit arrangement according to one of Claims 7 or 8, characterized

that the feeding port (SPM1) a master device (Ml), a second current limiting device (SBM12; SBM11), wherein a current limiting device (SBM11; SBM12) between the minus terminal of its Spannungsversor ^¬ supply (UVM1) and the bus (BMI) and a Current limiting device ^¬ (SBM12, SBM11) between the positive terminal of its power supply (UVM1) and the bus (BMI) is arranged. Circuit arrangement according to one of the preceding Ansprü ^¬ che,

characterized, that the non-feeding port (NSPM1; ES11) comprises (D52 to D55 D15 to D18), the coupled on the bus (BMI) side of the potential separating ^¬ device for rectifying the control signal (USM1) on the bus (BMI a rectifier ) is arranged.

1. Circuit arrangement according to one of the preceding Ansprü ^¬ che,

 characterized,

that the non-feeding port (NSPM1; ES11) comprises an off ^¬ value device (10) which is designed, the STEU ^¬ ersignal (USM1) on the bus (BMI) to which the non-SpeI ^¬ transmitting terminal (NSPM1; ES11) is coupled, evaluate, whose input is coupled to the phototransistor of the optocoupler of the respective potential separation device and whose output is coupled to the respective light source, wherein the control ^¬ signal (USM1) represents a PWM signal.

2. Circuit arrangement according to claim 11,

 characterized,

 in that the evaluation device (10) is designed to convert the PWM signal as follows:

 a bus-controlled operation of the respective nominal power or nominal luminous flux is activated by a 0% pulse width PWM signal; and or

- A bus-controlled off state of the respective lighting means is activated by a PWM signal with a smallest allowable pulse width; and or - bus-operating with dimming levels between the off state and the nominal power or the nominal luminous flux are activated by a PWM signal having pulse ^¬ widths that are greater than the minimum allowable pulse width, in particular by a PWM signal with 100%

Pulse width.

Circuit arrangement according to one of the preceding claims, characterized

that the at least one master device (Ml; M2), comprising a sensor, in particular a brightness sensor and / or a motion sensor that is adapted to provide a sensor signal at its from ^¬ gear, wherein the at least one master device (Ml; M2) is adapted to generate the control ^¬ signal in response to the sensor signal.