EP0549005B1 - System for equipment control, comprising a common channel - Google Patents

System for equipment control, comprising a common channel Download PDF

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Publication number
EP0549005B1
EP0549005B1 EP19920203386 EP92203386A EP0549005B1 EP 0549005 B1 EP0549005 B1 EP 0549005B1 EP 19920203386 EP19920203386 EP 19920203386 EP 92203386 A EP92203386 A EP 92203386A EP 0549005 B1 EP0549005 B1 EP 0549005B1
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EP
European Patent Office
Prior art keywords
unit
equipment
actuator
units
communication channel
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EP19920203386
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German (de)
French (fr)
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EP0549005A1 (en
Inventor
Erik Jan Van Dort
Handoko Kohar
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Koninklijke Philips NV
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Koninklijke Philips Electronics NV
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    • GPHYSICS
    • G08SIGNALLING
    • G08CTRANSMISSION SYSTEMS FOR MEASURED VALUES, CONTROL OR SIMILAR SIGNALS
    • G08C15/00Arrangements characterised by the use of multiplexing for the transmission of a plurality of signals over a common path

Definitions

  • the invention relates to a system for equipment control, comprising a plurality of equipment and actuator units, and a common communication channel, equipment and actuator units being provided with means for comprising a unit address.
  • an equipment unit is any device present in a home, shop or other place that can be controlled according to messages on a communication channel. Examples of such equipment are lights, equipment for heating and airconditioning, video and audio apparatus, intruder alarm, application controller, and domestic appliances such as a washing machine or a coffee-maker.
  • An actuator unit is any device that may send messages into the communication channel to switch or adjust an equipment unit in response to external changes. Actuator units comprise wall switches, sensors, timers and remote control units. In its simplest form, activation of an actuator unit will switch on or off an equipment unit.
  • a system according to the introductory paragraph is the BatiBUS system commercialised by the company Merlin Gerin, Meylan, F-38240 France. A description of this system is given in the Article "BatiBUS: intelligentie via 'twisted pair'", in the magazine RB Elektronica, October 1991, p 38-40, published by 'De Muiderkring BV', Weesp, The Netherlands.
  • equipment and actuator units are linked to each other by assigning to them the same address. Such address has to be given by an operator by means of hardware switches on each individual equipment unit. The operator need to take considerable care not to confuse addresses. A reconfiguration of the system needs a careful preparation in order to assign a unique address to each group of cooperating equipment and actuator units.
  • a unit can have only one address, and the logical connection between actuators and equipment is established via said address it is not possible to link partially overlapping groups of equipment to different actuators. For example, it is not possible to switch two lights with a first actuator and to link a second actuator with only one of the two lights together with other pieces of equipment.
  • a further disadvantage of this known system is that there must be prior knowledge in the system of the type of equipment and actuator units possible and the way they cooperate when linked together. The need for prior knowledge inhibits an easy extension of the system with pieces of equipment of a new type.
  • an object of the invention to provide a system for the control of equipment in a working or living environment which is more flexible and requires less preparation when a reconfiguration of the system is desired, which allows partially overlapping groups of equipment units to be linked to different actuators and which can be easily extended with new types of equipment or actuators.
  • a system for equipment control in accordance with the invention is characterized
  • European patent application 0 296 022 describes a system with modules interconnected via a bus.
  • a module has an input and/or an output.
  • the input of a module is connected to an information source.
  • the output of a module is connected to a device, such as an indicator, which uses the output signal.
  • a functional relationship between an input of a first module and the output of a second module can be established by selecting an input on the first module and an output on the second module, displaying the selected input and output to a user, and in a programming mode storing the address of the first module, the number of the input, the address of the second module and the number of the output in both modules.
  • the modules are not functionally involved .
  • An alternative embodiment for easily establishing logical links is characterized in that the actuator unit is operative to change state in response to an event;
  • a list of actuator addresses is established. Into each of the programmable memories of the selected actuators the address or addresses of the equipment units associated with the link-signal are subsequently stored.
  • At least one equipment unit has associated with it a programmable memory for storing at least one programmable message and means for storing into the associated programmable memory said at least one message and means for emitting at least one of the stored messages via the common communication channel in response to a change of state in the unit.
  • an equipment unit may act as an actuator.
  • Equipment units and actuator units are not mutually exclusive. For example, an actuator may switch on a piece of equipment which then will operate till a predetermined condition occurs. When said condition occurs the equipment will behave as an actuator and control or switch another piece of equipment.
  • An equipment unit that may behave as an actuator is, of course, provided with means to generate a link-signal.
  • This embodiment may further comprise means for storing messages in the programmable memory of said at least one equipment unit, the messages comprising the addresses of the actuator units associated with the link signal.
  • the actuator units which are logically coupled with the equipment unit receives a message when the equipment unit changes state.
  • the message may cause a change of state in the actuator unit as well, for example, it may switch on or off an indicator in the actuator unit.
  • this return link between equipment unit and actuator is established simultaneously with the forward link between actuator and equipment units, without operator action required.
  • the system in accordance with the invention may have the equipment and actuator units comprising a further programmable memory for storing the unit address and means for storing into said programmable memory a unit address.
  • a equipment or actuator unit When a equipment or actuator unit is inserted in the system it receives a unit address via the communication channel.
  • a list of address assigned can be maintained and, consequently, the unit address may be unique.
  • This system further comprises a central unit being arranged for assigning unit addresses to actuator and equipment units.
  • a central unit being arranged for assigning unit addresses to actuator and equipment units.
  • the use of a central unit for assigning unit addresses to equipment and actuator units is advantageous as such a central unit can assemble a list of all addresses used, thereby avoiding the need for each equipment and actuator unit be provided with means to assemble such a list when inserted into the system. Duplication of such means in all units and heavy communication on the common communication channel just after switching on a new unit is thereby avoided.
  • a preferred embodiment of the system according to the invention further comprises a configuration unit comprising means for retrieving information about the interaction between equipment and actuator units from a background memory, the configuration unit further comprising means for submitting messages containing information retrieved from said background memory to the programmable memories associated with equipment and actuator units which are marked and to the equipment and actuator units associated with a link-signal, when a link-signal occurs.
  • the messages emitted by an actuator may comprise instructions for the equipment unit for which the message is intended. As the actuator has no prior knowledge of the equipment unit, the instruction part of the message needs to be obtained from a source having knowledge the set of possible instructions for that equipment unit, and stored in the programmable memory of the actuator unit.
  • the background memory in the configuration unit contains sets of instructions for the interaction or cooperation of the various types of actuator and equipment units in the system.
  • the background memory can be updated in order to store therein additional sets of instructions when new types of actuators or equipment units become available. Updating is possible, for example when the background memory is an exchangeable memory such as an optical or magnetic disk.
  • each actuator or equipment unit may have a set of instructions describing with which available equipment and actuator units it may interact and how the interaction takes place. This set of instructions is added in the course of the installation of the new actuator or equipment unit added to the contents of the background memory.
  • the instructions may be available on a card with a magnetic strip or a chip card.
  • the mark- and link-signals and the signals for storing messages in the associated memories can be transmitted via the common communication channel to and from the configuration unit.
  • a separate communication channel can be used which channel is switched off when no such reconfiguration takes place.
  • An embodiment of the system in accordance with the invention may have the programmable memory associated with each actuator and equipment unit, respectively, being physically integrated with the unit.
  • the common communication channel is not used for obtaining the messages that are to be send from an actuator to an equipment unit or vice versa. Consequently, the load on the common communication channel is significantly reduced and the communication channel may be slower and cheaper. This is advantageous especially in applications with a large number of actuators and equipment units, such as office buildings.
  • An embodiment of the system according to the invention has the mark-means in at least one equipment or actuator unit comprising a switch for marking the unit, the switch being associated with the unit.
  • Analogous the system may be further have at least one equipment or actuator unit comprising a switch for generating a link-signal associated with said equipment or actuator unit.
  • the switches may be buttons which are physically present on the housing of the actuator or equipment units.
  • the switches may be connected to a detector for remote control signals, for example infra-red, allowing the user activating the switches remotely.
  • the system may comprise a remote control unit for remotely activating, by means of wireless transmission of a signal beam, said switches for marking a unit and for generating a link-signal, the remote control unit being arranged for emitting a signal beam in a selected direction only.
  • the signal beam of the remote control is aimed at the equipment or actuator unit to be selected. For the purpose of marking and linking equipment and actuator units in the system a simple remote control unit with only two different signals is necessary.
  • the common communication channel can be an optical or electrical bus, an example of the latter is the D2B-bus, commercialised by the company D2B-systems in Redhill, England, which is described in US-A 4 429 384.
  • Preferably at least part of the communication between equipment and actuator units is by wireless transmission of signals by way of radio frequency (RF) or infra-red (IR) transmission.
  • RF radio frequency
  • IR infra-red
  • FIG. 1 an example of a system for the control of equipment according to the invention is shown.
  • the system contains a common communication channel 10, for example a D2B-bus, which is coupled to a number of equipment and actuator units. Shown are two lights 11 and 12, two switches 13 and 14, a timer 15 which acts as a time-controlled switch, a movement detector 16, for example a IR- or sound detector, which behaves like a switch when any movement or noise is detected in its vicinity, video and audio equipment 17 and 18, a remote control unit 19 with a detector 20 and an application controller 21.
  • the application controller 21 functions as an actuator reacting on a combination of different inputs, indicated are a timer 22, a IR-detector 23 and a sound detector 24.
  • the inputs to the application controller may be directly connected as shown or communicate with the application controller via the common communication channel 10.
  • the communication channel 10 is further linked to a central unit 30 and to a memory unit 31.
  • the function of the central unit 30 is to assign unit addresses to each of the actuator and equipment units in the system.
  • the memory unit 31 comprises a programmable memory containing for each actuator unit an associated memory for storing therein the unit addresses of the equipment units to which the actuator unit is linked.
  • the system functions basically as follows. If an actuator changes state, the associated memory is accessed and messages are transmitted to the units of which an address is present in the associated memory.
  • a message may contain merely the address of a destination equipment unit, may contain a general instruction or the message may be related to the specific change of state of the actuator unit.
  • the equipment units to which a message is transferred will change their state in a way contained in or implied by the message.
  • Equipment units and actuator units are not mutually exclusive. For example, an actuator may switch on a piece of equipment which will operate till a predetermined condition occurs. When said condition occurs the equipment will behave as actuator and switch another piece of equipment such as an alarm or an indicator on the original actuator unit. Consequently, in the system the actuator and equipment units are treated as equivalent.
  • actuator unit is used to indicate units that transmit messages to other units when they change state.
  • Equipment unit is used for units receiving messages.
  • Each of the equipment and actuator units comprise a programmable address memory and means to communicate with the central unit.
  • each of the equipment and actuator units will transmit initialising messages to the central unit and in response they will receive their unit address.
  • the unit address is subsequently stored in a programmable address memory.
  • Preferably unit addresses are unique, but also the same address can be assigned to different units that operate completely in parallel.
  • the memories are preferable of a non-volatile type, for example EEPROM. Inserting a new equipment or actuator unit has as initially as effect that the new unit will be given a unit address only. In a stable configuration the central unit 30 may be switched off or disconnected.
  • each actuator unit is provided with its own associated memory containing the table of equipment unit addresses.
  • the advantage of this embodiment is that the common communication channel 10 is not used for messages from the actuator units towards the memory units 31.
  • FIG 2 a functional diagram of an actuator unit 40 is shown in more detail.
  • the actuator unit 40 can be in one of several states 41, 42, 43 or 44.
  • an 'event' occurs, i.e . the state of the actuator changes, shown in the Figure by an arrow indicating a change from state 41 to state 42
  • an internal signal corresponding to this change is generated.
  • the influence causing the change of state is, for example, a person turning a knob, a temperature reaching a predetermined value or the lapse of a time interval.
  • the internal signal is compared with the contents of a column 'events' 47 in an 'event table' 45.
  • messages in the event table 45 that are linked with said entry 46 are transmitted via the common communication channel 10. These messages comprise the destination addresses, i.e . the unit addresses of the equipment units, as stored in column 48 and possible further instructions for the addressed equipment as stored in column 49 in the event table 45.
  • a functional diagram of an equipment unit 50 is shown in Figure 3.
  • the unit 50 is connected to the common communication channel 10 via an internal interface 51.
  • the unit can be in one of several states, shown are a first state 53 and a second state 54, for example "on” and "off".
  • a message is received via the common communication channel 10, it is analyzed in the interface circuit 51.
  • the destination address comprised in the message is compared with the unit address as stored in the programmable address memory 52. Only if the two match, the message will affect the state the equipment unit is in.
  • the change of state may be implicit or explicit. With an implicit change is meant that the mere receipt of the message will cause the present state to be changed to the other state.
  • the message comprises an instruction, following that instruction the equipment unit changes to a particular state contained in the instruction. No change of state occurs if the equipment unit was already in the particular state.
  • the Figure suggests a change to the second state 54, indicated by arrow 55.
  • the equipment unit 50 may comprise further the circuitry of an actuator unit.
  • it may comprise a programmable memory with an event table 45 and means to select addresses and messages from the event table and transmit them via the common communication channel 10 if the equipment unit changes state. The change of state can be reported back to the actuator unit from which the message originated and to other parts of the system.
  • each unit is provided with a first switch 61, mark-switch. Activating this switch causes a mark-register 62 to be set.
  • the register 62 may be located in the unit and be, for example a flip-flop.
  • a link-signal generator 64 sends a link-signal via the common communication channel 10, causing all units in the system to be scanned and the addresses of those units of which the mark-register 62 is set to be loaded into the event table 45 associated with the unit of which the link switch 63 is activated.
  • this table may comprise message fields 49.
  • the message fields 49 contain, for example, an identification of the state of the unit of which the mark-register is set at the moment the mark switch is activated or at the moment the link-signal is generated.
  • the actuator unit changes state, the state stored in the message field 49 will be transmitted to the equipment unit with the stored address and this equipment unit will thereby be instructed to change its state to the state it had when the logic connection between actuator unit and equipment unit was established.
  • the main advantage of the system according to the invention is that by this procedure the actuator units need to have no prior knowledge about the equipment units. Instructions for the equipment units are retrieved from the equipment units or from elsewhere and stored in the programmable memory or event table of the actuator unit in a format that has no meaning for the actuator, but has a meaning for the equipment unit.
  • An actuator unit 70 is a three-state switch with states "A", "B”, and "C"
  • the equipment unit is a thermostat 71
  • a further equipment unit is light 72.
  • the thermostat 71 is set at a nominal temperature of 14°C
  • light 72 is switched off by means of a local switch 72c and the three-state switch 70 is set at state "A”.
  • a logical connection is made by activation of the mark-switches 71a and 72a of the thermostat 71 and of the light 72 and subsequently of the link-switch 70b of the three-state switch 70.
  • the same procedure is repeated for a nominal temperature of 22°C at the thermostat, light 72 switched on and the three-state switch in state "C".
  • the nominal temperature of the thermostat is 19°C, and only the thermostat is connected, using mark-switch 71a and link-switch 70b, not the light 72.
  • turning the three-state switch to state “A” will cause light 72 to be switched off and the thermostat to regulate the temperature to 14°C.
  • Moving the three-state switch 70 to state “B” causes the thermostat to regulate the temperature to 19°C but will not change the state of the light 72.
  • State “C” of the three-state-switch 70 will switch on light 72 and regulate the temperature to 22°C.
  • a system such as described in relation to Figure 4 allows to connect logically equipment and actuator units that cannot cooperate usefully with each other, for example a pair of lights or a pair of motion detectors.
  • FIG 5 an embodiment of a system in accordance with the invention is shown, which embodiment comprises a separate configuration unit 80.
  • the configuration unit 80 serves to assign unit addresses to the equipment and actuator units 81, 82, 83, respectively and 84 and makes it possible to limit connections between units to connections that are useful.
  • the actuator and equipment units are provided with mark-switches 81a, 82a, 83a and 84a and link-switches 81b, 82b, 83b and 84b, respectively.
  • Initialising the system or adding a new equipment or actuator unit to the system proceeds as follows.
  • the new unit When a new unit 85 is added to the system, the new unit will transmit a message to the configuration unit 80 via the common communication channel 10.
  • the configuration unit 80 has a predetermined address which is known to the new unit. With this message the new unit 85 will make itself known to the configuration unit 80 and also indicate of which type it is, for example, switch, thermostat, light or television-set.
  • a message is returned by the configuration unit 80 communicating the unit address of the new unit 85 to it. This unit address is stored internally in the new unit.
  • each unit is associated with a further programmable memory containing the event table, preferably comprised inside the unit.
  • Cooperation between units is established by filling the event table with addresses and, if relevant, with instructions.
  • cooperation between an actuator unit 81 and a plurality of equipment units 83, 84 and 85 is established by the following procedure.
  • the mark-switches 83a, 84a and 85a of the equipment units are activated.
  • Activation of mark-switch 83a causes the unit 83 to transmit a mark-message to the configuration unit 80, which message comprises the type of the unit, the unit address and the present state of the unit 83.
  • the unit 83 is now marked by storing its address, state and type in a memory in the configuration unit 80.
  • the other unit 84 and 85 are marked analogous by activating the mark-switches 84a and 85a, respectively, thereby building a table of marked units in the configuration unit.
  • the actuator unit 81 to be coupled with the equipment units 83, 84 and 85, is selected by means of activating its link-switch 81b. This causes a link-message to be transmitted to the configuration unit 80.
  • the link message comprising the type of unit 81, its address and the state it is in.
  • an event table will be generated by configuration unit 80 with as input the table of marked units 83, 84 and 85 and the contents of the link-message from unit 81.
  • an interface description between any pair of marked and linked unit types can be used.
  • the interface description contains the behaviour between a pair of unit types when cooperating. Without an interface description for a particular pair of unit types, no entry will be generated in the event table.
  • the interface description, together with the states of the two units is assembled to form the instruction to be entered in the event table.
  • the entries are transmitted via the common communication channel 10 to the actuator unit 81 associated with the link signal, to replace, update or supplement the existing event table.
  • An analogous procedure can be performed when the mark-signals originate from actuator units and the link-signal is generated in an equipment.
  • the event tables in the marked units may be updated with address and instruction for the linking unit. This allows a cross-link and return communication between the units.
  • the interface descriptions are available from a background memory 90 connected to the configuration unit 80.
  • the contents of the background memory should be replaceable, for example when new types of equipment and actuator units become available.
  • the background memory is an exchangeable magnetic or optical storage medium, such as a floppy disc, a CD-ROM, a card with a magnetic strip or a build-in semiconductor chip memory.
  • the configuration unit contains an erasable memory, for example a build-in magnetic disc or semi-conductor memory, that can be updated from an exchangeable medium.
  • the mark and link signals may be generated by means of a remote control unit 89.
  • the remote control unit 89 cooperates with detectors in the actuator and equipment units.
  • units 83 and 84 are provided with detectors 83c and 84c, respectively.
  • the remote control unit 89 is of the "point and shoot" type having a narrow beam. Aiming the remote control unit 89 towards the detector, 83c or 84c, and activating the mark button 89a or the link-button 89b, activates the mark or link signal generating circuit connected to detectors 83c and 84b in the units 83 and 84, respectively.
  • a "point and shoot" type of remote control unit makes it unnecessary to provide buttons on the remote control unit to identify the equipment or actuator by means of an address and, more importantly, it relieves the user of the need to memorise those addresses or look for them beforehand.
  • the common communication channel 10 may comprise a variety of transmission possibilities.
  • the connection of unit 82 is partially via two-way infra-red communication, indicated by a IR-transmitter/receiver 86 connected to the common communication channel 10 and a transmitter/receiver 87 connected to the unit 82.
  • the means to mark en link the units in creating a system configuration use the same common communication channel 10 as the messages between the actuator and equipment units when the system is operating normally.
  • the common communication channel 10 may be a wired bus
  • the configuration unit is a portable device communicating with each of the units by means of two-way IR.
  • a "point and shoot" remote control unit can be integrated with this portable device. Marking and linking units will cause not a mark-link signal on the common communication channel but transmitting the mark- and link-signals to the portable configuration unit wirelessly and the assembled event table is transmitted along the same route.
  • a graphic interface is illustrated to facilitate interaction of a user with the equipment control system.
  • the graphical user interface 100 is a combination of an actuator unit and an equipment unit, not unlike other units.
  • the graphical interface contains a keypad 101 and/or a pointing device 105 and a screen 102, for example an LCD-screen.
  • the screen and input devices may be integrated, for example in a touch-sensitive screen.
  • the graphical interface comprises further a programmable memory, for storing an event table.
  • the graphical user interface 100 is logically connected to all equipment and actuator units in the system or to all units in a functional portion of the system, for example all units in a particular room or in a section of a building.
  • the user interface comprises means for remotely marking all units in the system and generating a link signal for itself.
  • the programmable memory in the graphical user interface 100 comprises an extended event table.
  • the programmable memory may further comprise a table of unit addresses and names or labels or icons for all equipment and actuator units in the functional portion of the system coupled to the graphical user interface. Initially the names are assigned by the system, and divided, for example, of a combination of type and a number. The labels or icons can be changed via the keypad 101. Instructions in the extended event table do not only cause an equipment unit to change state, but may cause other changes in the equipment or actuator units. In combination with "mark" and "link” keys 103 and 104 on the keypad 101, and with the label attached to each equipment and actuator unit the units can be remotely caused to generate mark- and link-signals.
  • equipment and actuator units themselves are also provided with a programmable memory containing such name
  • a change in the name of a unit entered by a user via a graphical user interface will cause the name in the equipment or actuator unit to be changed.
  • This change of name is handled in the unit as a change in state and causes further messages to be send to inform all other relevant units about the change of name. Consequently, entering a new name via one graphical user interface will change the name on all displays in the whole system.
  • a change in operational state of an equipment or actuator unit is communicated to the graphical user interface 100 and made visible by a symbol on the screen 102. The screen will show all units, or a selected portion, in their present states.
  • the only information that an equipment and actuator unit contains about other equipment and actuator units is comprised in the event table.
  • the event table is filled with instructions for other units, these instructions are loaded or changed when the system is initialised or reconfigured.
  • the instructions have no meaning to the unit in the programmable memory of which they are stored.
  • the central or configuration unit is only needed during initialisation or reconfiguration. No messages are send to or received from the central unit during normal operation.

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Description

The invention relates to a system for equipment control, comprising a plurality of equipment and actuator units, and a common communication channel, equipment and actuator units being provided with means for comprising a unit address.
Such a system can be used in a living or working environment to establish a flexible configuration for interactions between different pieces of equipment being and actuators for controlling the equipment. In the framework of the present invention an equipment unit is any device present in a home, shop or other place that can be controlled according to messages on a communication channel. Examples of such equipment are lights, equipment for heating and airconditioning, video and audio apparatus, intruder alarm, application controller, and domestic appliances such as a washing machine or a coffee-maker. An actuator unit is any device that may send messages into the communication channel to switch or adjust an equipment unit in response to external changes. Actuator units comprise wall switches, sensors, timers and remote control units. In its simplest form, activation of an actuator unit will switch on or off an equipment unit.
A system according to the introductory paragraph is the BatiBUS system commercialised by the company Merlin Gerin, Meylan, F-38240 France. A description of this system is given in the Article "BatiBUS: intelligentie via 'twisted pair'", in the magazine RB Elektronica, October 1991, p 38-40, published by 'De Muiderkring BV', Weesp, The Netherlands. In the BatiBUS system equipment and actuator units are linked to each other by assigning to them the same address. Such address has to be given by an operator by means of hardware switches on each individual equipment unit. The operator need to take considerable care not to confuse addresses. A reconfiguration of the system needs a careful preparation in order to assign a unique address to each group of cooperating equipment and actuator units. As a unit can have only one address, and the logical connection between actuators and equipment is established via said address it is not possible to link partially overlapping groups of equipment to different actuators. For example, it is not possible to switch two lights with a first actuator and to link a second actuator with only one of the two lights together with other pieces of equipment. A further disadvantage of this known system is that there must be prior knowledge in the system of the type of equipment and actuator units possible and the way they cooperate when linked together. The need for prior knowledge inhibits an easy extension of the system with pieces of equipment of a new type.
It is, inter alia, an object of the invention to provide a system for the control of equipment in a working or living environment which is more flexible and requires less preparation when a reconfiguration of the system is desired, which allows partially overlapping groups of equipment units to be linked to different actuators and which can be easily extended with new types of equipment or actuators.
A system for equipment control in accordance with the invention is characterized
  • in that the actuator unit is operative to change state in response to an event;
  • in that the equipment unit is operative to change state in response to a message received from an actuator unit via the communication channel, and
  • in that the system comprises:
  • for each actuator unit an associated programmable memory for storing at least one programmable message associated with a state change of the actuator unit;
  • for each equipment unit an associated mark-means for marking the unit;
  • means for generating a link-signal associated with at least one actuator unit;
  • coupling means for logically coupling any equipment unit, which has been marked by the associated mark-means, with said at least one actuator unit; said coupling means being arranged for storing for each of the marked equipment units a message comprising the address of the marked equipment unit in the programmable memories of said at least one actuator unit; and
  • means for emitting, in response to a state change of an actuator unit, any message associated with said state change and stored in the programmable memory associated with said actuator unit via the common communication channel. In the programmable memories of the actuator units unit addresses of the equipment units which are linked with the actuator will be stored, thereby establishing a logical connection between actuator and equipment units. As each actuator has its own associated memory and its own list of addresses of logically connected equipment units, partially overlapping groups of equipment units can be realized. As unit addresses and possibly further contents of the messages are to be stored in the programmable memory of an actuator, a new type of equipment can be inserted without problem as only the content of the programmable memory has to be changed or extended. When reconfiguring the system, the only action of the operator required is to indicate the logical link between actuator and equipment to the system. Unit addresses are preferably unique, however within the frame of the invention a number of units may have identical addresses These units will be handled as a single unit and receive the same instructions. In practice, three units are switched in parallel. Alternatively, a group of equipment units may have unique but related addresses and a message can be directed to all units in such a group by using as a destination address a portion common to all units within the group. By marking the units a list of addresses of equipment units is assembled When a link-signal is generated this list of addresses is subsequently stored in the programmable memories of the actuator units associated with said link-signal. Preferably, also information or an instruction relating to the state the equipment is in at the time of marking or linking is equally stored in the programmable memory. Marking can also be established in other ways, for example, by setting mark-registers associated with the unit.
  • European patent application 0 296 022 describes a system with modules interconnected via a bus. A module has an input and/or an output. The input of a module is connected to an information source. The output of a module is connected to a device, such as an indicator, which uses the output signal. A functional relationship between an input of a first module and the output of a second module can be established by selecting an input on the first module and an output on the second module, displaying the selected input and output to a user, and in a programming mode storing the address of the first module, the number of the input, the address of the second module and the number of the output in both modules. As a result information presented to the input of the first module is passed to the output of the second module. The modules are not functionally involved .
    An alternative embodiment for easily establishing logical links is characterized in that the actuator unit is operative to change state in response to an event;
  • in that the equipment unit is operative to change state in response to a message received from an actuator unit via the communication channel; and
  • in that the system comprises:
  • for each actuator unit an associated programmable memory for storing at least one programmable message associated with a state change of the actuator unit;
  • for each actuator unit an associated mark-means for marking the unit;
  • means for generating a link-signal associated with at least one equipment unit;
  • coupling means for logically coupling any actuator unit, which has been marked by the associated mark-means, with said at least one equipment unit; said coupling means being arranged for storing in the programmable memories of the marked actuator units messages comprising the addresses of said at least one equipment unit; and
  • means for emitting, in response to a state change of an actuator unit, any message associated with said state change and stored in the programmable memory associated with said actuator unit via the common communication channel.
  • In this embodiment a list of actuator addresses is established. Into each of the programmable memories of the selected actuators the address or addresses of the equipment units associated with the link-signal are subsequently stored.
    In a preferred embodiment of the system according to the invention at least one equipment unit has associated with it a programmable memory for storing at least one programmable message and means for storing into the associated programmable memory said at least one message and means for emitting at least one of the stored messages via the common communication channel in response to a change of state in the unit. In this embodiment an equipment unit may act as an actuator. Equipment units and actuator units are not mutually exclusive. For example, an actuator may switch on a piece of equipment which then will operate till a predetermined condition occurs. When said condition occurs the equipment will behave as an actuator and control or switch another piece of equipment. An equipment unit that may behave as an actuator is, of course, provided with means to generate a link-signal.
    This embodiment may further comprise means for storing messages in the programmable memory of said at least one equipment unit, the messages comprising the addresses of the actuator units associated with the link signal. In circumstances, it may be advantageous that the actuator units which are logically coupled with the equipment unit receives a message when the equipment unit changes state. The message may cause a change of state in the actuator unit as well, for example, it may switch on or off an indicator in the actuator unit. In this embodiment this return link between equipment unit and actuator is established simultaneously with the forward link between actuator and equipment units, without operator action required.
    The system in accordance with the invention may have the equipment and actuator units comprising a further programmable memory for storing the unit address and means for storing into said programmable memory a unit address. When a equipment or actuator unit is inserted in the system it receives a unit address via the communication channel. In the system a list of address assigned can be maintained and, consequently, the unit address may be unique.
    This system further comprises a central unit being arranged for assigning unit addresses to actuator and equipment units. The use of a central unit for assigning unit addresses to equipment and actuator units is advantageous as such a central unit can assemble a list of all addresses used, thereby avoiding the need for each equipment and actuator unit be provided with means to assemble such a list when inserted into the system. Duplication of such means in all units and heavy communication on the common communication channel just after switching on a new unit is thereby avoided.
    A preferred embodiment of the system according to the invention further comprises a configuration unit comprising means for retrieving information about the interaction between equipment and actuator units from a background memory, the configuration unit further comprising means for submitting messages containing information retrieved from said background memory to the programmable memories associated with equipment and actuator units which are marked and to the equipment and actuator units associated with a link-signal, when a link-signal occurs. In this embodiment the messages emitted by an actuator may comprise instructions for the equipment unit for which the message is intended. As the actuator has no prior knowledge of the equipment unit, the instruction part of the message needs to be obtained from a source having knowledge the set of possible instructions for that equipment unit, and stored in the programmable memory of the actuator unit. For this purpose the background memory in the configuration unit contains sets of instructions for the interaction or cooperation of the various types of actuator and equipment units in the system. Preferably the background memory can be updated in order to store therein additional sets of instructions when new types of actuators or equipment units become available. Updating is possible, for example when the background memory is an exchangeable memory such as an optical or magnetic disk. Alternatively each actuator or equipment unit may have a set of instructions describing with which available equipment and actuator units it may interact and how the interaction takes place. This set of instructions is added in the course of the installation of the new actuator or equipment unit added to the contents of the background memory. For example, the instructions may be available on a card with a magnetic strip or a chip card.
    The mark- and link-signals and the signals for storing messages in the associated memories can be transmitted via the common communication channel to and from the configuration unit. Alternatively, as the configuration unit is necessary only for initialisation and during reconfiguration of the system, a separate communication channel can be used which channel is switched off when no such reconfiguration takes place.
    An embodiment of the system in accordance with the invention may have the programmable memory associated with each actuator and equipment unit, respectively, being physically integrated with the unit. By placing the programmable memory of each unit in the unit itself, the common communication channel is not used for obtaining the messages that are to be send from an actuator to an equipment unit or vice versa. Consequently, the load on the common communication channel is significantly reduced and the communication channel may be slower and cheaper. This is advantageous especially in applications with a large number of actuators and equipment units, such as office buildings.
    An embodiment of the system according to the invention has the mark-means in at least one equipment or actuator unit comprising a switch for marking the unit, the switch being associated with the unit. Analogous the system may be further have at least one equipment or actuator unit comprising a switch for generating a link-signal associated with said equipment or actuator unit. In these embodiments there a close physical relation exists between the equipment or actuator unit and a switch for marking or generating a link-signal. For example, the switches may be buttons which are physically present on the housing of the actuator or equipment units. Alternatively, or in addition, the switches may be connected to a detector for remote control signals, for example infra-red, allowing the user activating the switches remotely.
    Then the system may comprise a remote control unit for remotely activating, by means of wireless transmission of a signal beam, said switches for marking a unit and for generating a link-signal, the remote control unit being arranged for emitting a signal beam in a selected direction only. The signal beam of the remote control is aimed at the equipment or actuator unit to be selected. For the purpose of marking and linking equipment and actuator units in the system a simple remote control unit with only two different signals is necessary.
    The common communication channel can be an optical or electrical bus, an example of the latter is the D2B-bus, commercialised by the company D2B-systems in Redhill, England, which is described in US-A 4 429 384. Preferably at least part of the communication between equipment and actuator units is by wireless transmission of signals by way of radio frequency (RF) or infra-red (IR) transmission.
    These, and other more detailed aspects of the invention will now be elucidated by way of example with reference to the accompanying drawings.
    The drawings show in
  • Figure 1 diagrammatically a system in according to the invention, comprising a number of possible equipment units and actuator units;
  • Figure 2 a functional representation of an actuator unit;
  • Figure 3 a functional representation of an equipment unit;
  • Figure 4 a system with a thermostat, two lights and a three-state switch;
  • Figure 5 a further embodiment of a system in accordance with the invention; and
  • Figure 6 a graphical user interface for use in a system according to the invention.
  • In Figure 1 an example of a system for the control of equipment according to the invention is shown. The system contains a common communication channel 10, for example a D2B-bus, which is coupled to a number of equipment and actuator units. Shown are two lights 11 and 12, two switches 13 and 14, a timer 15 which acts as a time-controlled switch, a movement detector 16, for example a IR- or sound detector, which behaves like a switch when any movement or noise is detected in its vicinity, video and audio equipment 17 and 18, a remote control unit 19 with a detector 20 and an application controller 21. The application controller 21 functions as an actuator reacting on a combination of different inputs, indicated are a timer 22, a IR-detector 23 and a sound detector 24. The inputs to the application controller may be directly connected as shown or communicate with the application controller via the common communication channel 10. The communication channel 10 is further linked to a central unit 30 and to a memory unit 31. The function of the central unit 30 is to assign unit addresses to each of the actuator and equipment units in the system. The memory unit 31 comprises a programmable memory containing for each actuator unit an associated memory for storing therein the unit addresses of the equipment units to which the actuator unit is linked.
    The system functions basically as follows. If an actuator changes state, the associated memory is accessed and messages are transmitted to the units of which an address is present in the associated memory. A message may contain merely the address of a destination equipment unit, may contain a general instruction or the message may be related to the specific change of state of the actuator unit. The equipment units to which a message is transferred will change their state in a way contained in or implied by the message.
    Equipment units and actuator units are not mutually exclusive. For example, an actuator may switch on a piece of equipment which will operate till a predetermined condition occurs. When said condition occurs the equipment will behave as actuator and switch another piece of equipment such as an alarm or an indicator on the original actuator unit. Consequently, in the system the actuator and equipment units are treated as equivalent. In this description distinction is made between actuator units and equipment units for the purpose of clarity only. The term actuator unit is used to indicate units that transmit messages to other units when they change state. Equipment unit is used for units receiving messages.
    The central unit 30, in its most simple form, is charged with the assignment of unit addresses only. Each of the equipment and actuator units comprise a programmable address memory and means to communicate with the central unit. When the system is initialised, each of the equipment and actuator units will transmit initialising messages to the central unit and in response they will receive their unit address. The unit address is subsequently stored in a programmable address memory. Preferably unit addresses are unique, but also the same address can be assigned to different units that operate completely in parallel. As the system should be resistant against power failure, the memories are preferable of a non-volatile type, for example EEPROM. Inserting a new equipment or actuator unit has as initially as effect that the new unit will be given a unit address only. In a stable configuration the central unit 30 may be switched off or disconnected.
    Rather than a common memory unit 31, connected in the system in a preferred embodiment each actuator unit is provided with its own associated memory containing the table of equipment unit addresses. The advantage of this embodiment is that the common communication channel 10 is not used for messages from the actuator units towards the memory units 31.
    In Figure 2 a functional diagram of an actuator unit 40 is shown in more detail. The actuator unit 40 can be in one of several states 41, 42, 43 or 44. When, by some influence an 'event' occurs, i.e. the state of the actuator changes, shown in the Figure by an arrow indicating a change from state 41 to state 42, an internal signal corresponding to this change is generated. The influence causing the change of state is, for example, a person turning a knob, a temperature reaching a predetermined value or the lapse of a time interval. The internal signal is compared with the contents of a column 'events' 47 in an 'event table' 45. When a match is found in the event table between the type of event that occurred and an entry 46 in the 'events' column 47, messages in the event table 45 that are linked with said entry 46 are transmitted via the common communication channel 10. These messages comprise the destination addresses, i.e. the unit addresses of the equipment units, as stored in column 48 and possible further instructions for the addressed equipment as stored in column 49 in the event table 45.
    A functional diagram of an equipment unit 50 is shown in Figure 3. The unit 50 is connected to the common communication channel 10 via an internal interface 51. The unit can be in one of several states, shown are a first state 53 and a second state 54, for example "on" and "off". When a message is received via the common communication channel 10, it is analyzed in the interface circuit 51. Firstly the destination address comprised in the message is compared with the unit address as stored in the programmable address memory 52. Only if the two match, the message will affect the state the equipment unit is in. The change of state may be implicit or explicit. With an implicit change is meant that the mere receipt of the message will cause the present state to be changed to the other state. For an explicit change of state the message comprises an instruction, following that instruction the equipment unit changes to a particular state contained in the instruction. No change of state occurs if the equipment unit was already in the particular state. The Figure suggests a change to the second state 54, indicated by arrow 55.
    The equipment unit 50 may comprise further the circuitry of an actuator unit. In particular it may comprise a programmable memory with an event table 45 and means to select addresses and messages from the event table and transmit them via the common communication channel 10 if the equipment unit changes state. The change of state can be reported back to the actuator unit from which the message originated and to other parts of the system.
    In order to fill the event table 45 in the programmable memories of the actuator and equipment units, each unit is provided with a first switch 61, mark-switch. Activating this switch causes a mark-register 62 to be set. As indicated in Figures 2 and 3 the register 62 may be located in the unit and be, for example a flip-flop. When a second switch 63, the link-switch, on one of the units is activated, a link-signal generator 64 sends a link-signal via the common communication channel 10, causing all units in the system to be scanned and the addresses of those units of which the mark-register 62 is set to be loaded into the event table 45 associated with the unit of which the link switch 63 is activated. By this flexible and simple procedure a logical connection is established between actuator and equipment units. As an alternative, the unit address of the unit of which the link switch 63 is activated can be added to the event tables of the units of which the mark-register 62 is set.
    In addition to storing the unit addresses in destination fields 48 of the event table 45, this table may comprise message fields 49. The message fields 49 contain, for example, an identification of the state of the unit of which the mark-register is set at the moment the mark switch is activated or at the moment the link-signal is generated. When the actuator unit changes state, the state stored in the message field 49 will be transmitted to the equipment unit with the stored address and this equipment unit will thereby be instructed to change its state to the state it had when the logic connection between actuator unit and equipment unit was established. The main advantage of the system according to the invention is that by this procedure the actuator units need to have no prior knowledge about the equipment units. Instructions for the equipment units are retrieved from the equipment units or from elsewhere and stored in the programmable memory or event table of the actuator unit in a format that has no meaning for the actuator, but has a meaning for the equipment unit.
    By way of example, this is illustrated in Figure 4. An actuator unit 70 is a three-state switch with states "A", "B", and "C", the equipment unit is a thermostat 71, a further equipment unit is light 72. The thermostat 71 is set at a nominal temperature of 14°C, light 72 is switched off by means of a local switch 72c and the three-state switch 70 is set at state "A". Now a logical connection is made by activation of the mark-switches 71a and 72a of the thermostat 71 and of the light 72 and subsequently of the link-switch 70b of the three-state switch 70. The same procedure is repeated for a nominal temperature of 22°C at the thermostat, light 72 switched on and the three-state switch in state "C". In the third state "B" of the three-state switch 70 the nominal temperature of the thermostat is 19°C, and only the thermostat is connected, using mark-switch 71a and link-switch 70b, not the light 72. After this initialisation procedure turning the three-state switch to state "A" will cause light 72 to be switched off and the thermostat to regulate the temperature to 14°C. Moving the three-state switch 70 to state "B" causes the thermostat to regulate the temperature to 19°C but will not change the state of the light 72. State "C" of the three-state-switch 70 will switch on light 72 and regulate the temperature to 22°C.
    A system such as described in relation to Figure 4 allows to connect logically equipment and actuator units that cannot cooperate usefully with each other, for example a pair of lights or a pair of motion detectors. In Figure 5 an embodiment of a system in accordance with the invention is shown, which embodiment comprises a separate configuration unit 80. The configuration unit 80 serves to assign unit addresses to the equipment and actuator units 81, 82, 83, respectively and 84 and makes it possible to limit connections between units to connections that are useful. The actuator and equipment units are provided with mark- switches 81a, 82a, 83a and 84a and link- switches 81b, 82b, 83b and 84b, respectively.
    Initialising the system or adding a new equipment or actuator unit to the system proceeds as follows. When a new unit 85 is added to the system, the new unit will transmit a message to the configuration unit 80 via the common communication channel 10. The configuration unit 80 has a predetermined address which is known to the new unit. With this message the new unit 85 will make itself known to the configuration unit 80 and also indicate of which type it is, for example, switch, thermostat, light or television-set. In response to this message, a message is returned by the configuration unit 80 communicating the unit address of the new unit 85 to it. This unit address is stored internally in the new unit.
    As mentioned before, each unit is associated with a further programmable memory containing the event table, preferably comprised inside the unit. Cooperation between units is established by filling the event table with addresses and, if relevant, with instructions. Analogous to the embodiment described before, cooperation between an actuator unit 81 and a plurality of equipment units 83, 84 and 85 is established by the following procedure. The mark- switches 83a, 84a and 85a of the equipment units are activated. Activation of mark-switch 83a causes the unit 83 to transmit a mark-message to the configuration unit 80, which message comprises the type of the unit, the unit address and the present state of the unit 83. When the configuration unit 80 has knowledge about the type of unit associated with the address, the type information needs not to be transmitted. The unit 83 is now marked by storing its address, state and type in a memory in the configuration unit 80. The other unit 84 and 85 are marked analogous by activating the mark-switches 84a and 85a, respectively, thereby building a table of marked units in the configuration unit.
    The actuator unit 81, to be coupled with the equipment units 83, 84 and 85, is selected by means of activating its link-switch 81b. This causes a link-message to be transmitted to the configuration unit 80. The link message comprising the type of unit 81, its address and the state it is in. Subsequently, an event table will be generated by configuration unit 80 with as input the table of marked units 83, 84 and 85 and the contents of the link-message from unit 81. As further input an interface description between any pair of marked and linked unit types can be used. The interface description contains the behaviour between a pair of unit types when cooperating. Without an interface description for a particular pair of unit types, no entry will be generated in the event table. The interface description, together with the states of the two units is assembled to form the instruction to be entered in the event table. After the entries for the event table are assembled, the entries are transmitted via the common communication channel 10 to the actuator unit 81 associated with the link signal, to replace, update or supplement the existing event table. An analogous procedure can be performed when the mark-signals originate from actuator units and the link-signal is generated in an equipment. In addition to amending the event table of the unit generating the link-signal, also the event tables in the marked units may be updated with address and instruction for the linking unit. This allows a cross-link and return communication between the units.
    The interface descriptions are available from a background memory 90 connected to the configuration unit 80. The contents of the background memory should be replaceable, for example when new types of equipment and actuator units become available. Preferably, the background memory is an exchangeable magnetic or optical storage medium, such as a floppy disc, a CD-ROM, a card with a magnetic strip or a build-in semiconductor chip memory. Alternatively, the configuration unit contains an erasable memory, for example a build-in magnetic disc or semi-conductor memory, that can be updated from an exchangeable medium.
    Alternatively to activating mark- and link-switches that are physically connected with the actuator and equipment units, the mark and link signals may be generated by means of a remote control unit 89. The remote control unit 89 cooperates with detectors in the actuator and equipment units. In Figure 5, units 83 and 84 are provided with detectors 83c and 84c, respectively. Preferably, the remote control unit 89 is of the "point and shoot" type having a narrow beam. Aiming the remote control unit 89 towards the detector, 83c or 84c, and activating the mark button 89a or the link-button 89b, activates the mark or link signal generating circuit connected to detectors 83c and 84b in the units 83 and 84, respectively. A "point and shoot" type of remote control unit makes it unnecessary to provide buttons on the remote control unit to identify the equipment or actuator by means of an address and, more importantly, it relieves the user of the need to memorise those addresses or look for them beforehand. The common communication channel 10 may comprise a variety of transmission possibilities. In Figure 5 the connection of unit 82 is partially via two-way infra-red communication, indicated by a IR-transmitter/receiver 86 connected to the common communication channel 10 and a transmitter/receiver 87 connected to the unit 82.
    In the described embodiments the means to mark en link the units in creating a system configuration use the same common communication channel 10 as the messages between the actuator and equipment units when the system is operating normally. As the configuration unit is only needed during initialization or when the configuration needs to be changed a different communication channel may be used for this purpose. For example, the common communication channel 10 may be a wired bus, and the configuration unit is a portable device communicating with each of the units by means of two-way IR. A "point and shoot" remote control unit can be integrated with this portable device. Marking and linking units will cause not a mark-link signal on the common communication channel but transmitting the mark- and link-signals to the portable configuration unit wirelessly and the assembled event table is transmitted along the same route.
    In Figure 6 a graphic interface is illustrated to facilitate interaction of a user with the equipment control system. Considered from the system the graphical user interface 100 is a combination of an actuator unit and an equipment unit, not unlike other units. The graphical interface contains a keypad 101 and/or a pointing device 105 and a screen 102, for example an LCD-screen. The screen and input devices may be integrated, for example in a touch-sensitive screen. The graphical interface comprises further a programmable memory, for storing an event table. During initialisation the graphical user interface 100 is logically connected to all equipment and actuator units in the system or to all units in a functional portion of the system, for example all units in a particular room or in a section of a building. For this end, the user interface comprises means for remotely marking all units in the system and generating a link signal for itself. The programmable memory in the graphical user interface 100 comprises an extended event table. The programmable memory may further comprise a table of unit addresses and names or labels or icons for all equipment and actuator units in the functional portion of the system coupled to the graphical user interface. Initially the names are assigned by the system, and divided, for example, of a combination of type and a number. The labels or icons can be changed via the keypad 101. Instructions in the extended event table do not only cause an equipment unit to change state, but may cause other changes in the equipment or actuator units. In combination with "mark" and "link" keys 103 and 104 on the keypad 101, and with the label attached to each equipment and actuator unit the units can be remotely caused to generate mark- and link-signals.
    If the equipment and actuator units themselves are also provided with a programmable memory containing such name, in addition to the unit address, a change in the name of a unit entered by a user via a graphical user interface, will cause the name in the equipment or actuator unit to be changed. This change of name is handled in the unit as a change in state and causes further messages to be send to inform all other relevant units about the change of name. Consequently, entering a new name via one graphical user interface will change the name on all displays in the whole system. In the same way a change in operational state of an equipment or actuator unit is communicated to the graphical user interface 100 and made visible by a symbol on the screen 102. The screen will show all units, or a selected portion, in their present states.
    In the system according to the invention the only information that an equipment and actuator unit contains about other equipment and actuator units is comprised in the event table. The event table is filled with instructions for other units, these instructions are loaded or changed when the system is initialised or reconfigured. The instructions have no meaning to the unit in the programmable memory of which they are stored. As no prior knowledge of the other units is present, the system is very flexible in adding new units, even of a hitherto unknown type. In a preferred embodiment the central or configuration unit is only needed during initialisation or reconfiguration. No messages are send to or received from the central unit during normal operation.

    Claims (16)

    1. System for equipment control, comprising a plurality of equipment (50) and actuator (40) units, and a common communication channel (10), the equipment and actuator units being provided with means (52) for comprising a unit address, characterized:
      in that the actuator unit (40) is operative to change state in response to an event;
      in that the equipment unit (50) is operative to change state in response to a message received from an actuator unit via the communication channel; and
      in that the system comprises :
      for each actuator unit (40) an associated programmable memory (45) for storing at least one programmable message associated with a state change of the actuator unit;
      for each equipment unit (50) an associated mark-means (61) for marking the unit;
      means (64) for generating a link-signal associated with at least one actuator unit;
      coupling means (64) for logically coupling any equipment unit, which has been marked by the associated mark-means, with said at least one actuator unit; said coupling means being arranged for storing for each of the marked equipment units a message comprising the address of the marked equipment unit in the programmable memories of said at least one actuator unit; and
      means for emitting, in response to a state change of an actuator unit, any message associated with said state change and stored in the programmable memory associated with said actuator unit via the common communication channel.
    2. System for equipment control, comprising a plurality of equipment (50) and actuator (40) units, and a common communication channel (10); the equipment (50) and actuator (4) units being provided with means (52) for comprising a unit address; characterized:
      in that the actuator unit (40) is operative to change state in response to an event;
      in that the equipment unit (50) is operative to change state in response to a message received from an actuator unit via the communication channel; and
      in that the system comprises:
      for each actuator unit an associated programmable memory (45) for storing at least one programmable message associated with a state change of the actuator unit;
      for each actuator unit an associated mark-means (61) for marking the unit;
      means (64) for generating a link-signal associated with at least one equipment unit;
      coupling means (64) for logically coupling any actuator unit, which has been marked by the associated mark-means, with said at least one equipment unit; said coupling means being arranged for storing in the programmable memories of the marked actuator units messages comprising the addresses of said at least one equipment unit; and
      means for emitting, in response to a state change of an actuator unit, any message associated with said state change and stored in the programmable memory associated with said actuator unit via the common communication channel.
    3. System as claimed in Claim 1, or 2, characterized in that with at least one equipment unit a programmable memory is associated for storing at least one programmable message and means for storing into the associated programmable memory said at least one message and means for emitting at least one of the stored messages via the common communication channel in response to a change of state in the unit.
    4. System as claimed in Claim 3, characterized in that it comprises means for storing messages in the programmable memory of said at least one equipment unit, the messages comprising the addresses of the actuator units associated with the link signal.
    5. System according to Claim 1, 2, 3, or 4, characterized in that the equipment and actuator units comprise a further programmable memory for storing the unit address and means for storing into said programmable memory a unit address.
    6. System as claimed in Claim 5, characterized in that the system comprises a central unit (30) being arranged for assigning unit addresses to actuator and equipment units.
    7. System as claimed in Claim 1, 2, 3, 4, 5, or 6, characterized in that it comprises a configuration unit (80) comprising means for retrieving information about the interaction between equipment and actuator units from a background memory (90), the configuration unit further comprising means for submitting messages containing information retrieved from said background memory to the programmable memories associated with equipment and actuator units which are marked and to the equipment and actuator units associated with a link-signal, when a link-signal occurs.
    8. System as claimed in any of the preceding Claims, characterized in that the programmable memory associated with each actuator and equipment unit, respectively, is physically integrated with the unit.
    9. System as claimed in Claim 1 or 2, characterized in that the mark-means in at least one equipment or actuator unit comprises a switch for marking the unit, the switch being associated with the unit.
    10. System as claimed in Claim 2, 3 or 9, characterized in that at least one equipment or actuator unit comprises a switch for generating a link-signal associated with said equipment or actuator unit.
    11. System as claimed in Claim 9 or 10, characterized in that the system comprises a remote control unit (89) for remotely activating, by means of wireless transmission of a signal beam, said switches for marking a unit and for generating a link-signal, the remote control unit being arranged for emitting a signal beam in a selected direction only.
    12. System according to any of the preceding Claims, characterized in that the common communication channel comprises means for wireless transmission of signals for at least part of the trajectory of the signals.
    13. Actuator unit (40) suitable for use in a system for equipment control, comprising a plurality of equipment (50) and actuator (40) units; a common communication channel (10); for each equipment unit an associated mark-means (61) for marking the equipment unit; and the units being provided with means (52) for comprising a unit address; wherein
         the actuator unit (40) is operative to change state in response to an event; the actuator unit comprises: a programmable memory (45) for storing at least one programmable message associated with a state change of the actuator unit; means (64) for sending a link-signal via the common communication channel causing all units in the system to be scanned and for storing for each marked unit a message comprising the address of the marked unit in the programmable memory; and means for emitting, in response to a state change of the actuator unit, any message associated with said state change and stored in the programmable memory via the common communication channel.
    14. Actuator unit (40) suitable for use in a system for equipment control, comprising a plurality of equipment (50) and actuator (40) units; a common communication channel (10); and the units being provided with means (52) for comprising a unit address; wherein
         the actuator unit (40) is operative to change state in response to an event; the actuator unit comprises: a programmable memory (45) for storing at least one programmable message associated with a state change of the actuator unit; mark-means for marking the unit; means for in response to a link-signal received from an equipment unit via the common communication channel storing a message comprising the address of the equipment unit in the programmable memory; and means for emitting, in response to a state change of the actuator unit, any message associated with said state change and stored in the programmable memory via the common communication channel.
    15. Equipment unit (50) suitable for use in a system for equipment control, comprising a plurality of equipment (50) and actuator (40) units; a common communication channel (10); for each actuator unit (40) an associated mark-means (61) for marking the actuator unit and means for emitting, in response to a state change of the actuator unit, any message associated with said state change and stored in a programmable memory (45) associated with the actuator unit via the common communication channel; and the units being provided with means for comprising a unit address; wherein:
         the equipment unit comprises means (64) for sending a link-signal via the common communication channel causing a message comprising the address of the equipment unit to be stored in the programmable memory of marked actuator units; and the equipment unit is operative to change state in response to a message received from an actuator unit via the communication channel.
    16. Graphical user interface (100) for use in a system for equipment control, comprising a plurality of equipment (50) and actuator (40) units and a common communication channel (10); wherein the graphical user interface comprises a display screen (102), a data entry device (101), means for remotely generating a mark signal for marking equipment units and actuator units, means for generating a link signal for logically connecting the marked units to the graphical user interface by causing the marked units to store a message comprising an address of the graphical user interface in a programmable memory associated with the marked units; and means for visualizing on the display screen the actual status of the equipment and actuator units logically connected to the graphical user interface.
    EP19920203386 1991-11-11 1992-11-04 System for equipment control, comprising a common channel Expired - Lifetime EP0549005B1 (en)

    Priority Applications (1)

    Application Number Priority Date Filing Date Title
    EP19920203386 EP0549005B1 (en) 1991-11-11 1992-11-04 System for equipment control, comprising a common channel

    Applications Claiming Priority (3)

    Application Number Priority Date Filing Date Title
    EP91202937 1991-11-11
    EP91202937 1991-11-11
    EP19920203386 EP0549005B1 (en) 1991-11-11 1992-11-04 System for equipment control, comprising a common channel

    Publications (2)

    Publication Number Publication Date
    EP0549005A1 EP0549005A1 (en) 1993-06-30
    EP0549005B1 true EP0549005B1 (en) 1999-03-17

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    DE19523097A1 (en) * 1995-06-26 1997-01-02 Abb Research Ltd Distributor of information
    DE19544027C2 (en) * 1995-11-25 1999-01-07 Bernward Dr Zimmermann Bus system, especially for electrical installation
    DE19651308C2 (en) * 1996-12-10 1998-10-22 Becker Gmbh Audio sound system for a motor vehicle
    DE19652617C1 (en) * 1996-12-18 1997-09-11 Bosch Gmbh Robert Alarm time generation method for automobile control devices
    DE19715028B4 (en) * 1997-04-11 2008-07-03 Insta Elektro Gmbh Bus-capable dimmers, electronic transformers and ballasts for brightness control of luminaires
    FR2770014B1 (en) * 1997-10-20 2000-03-10 Schneider Electric Sa CONTROL METHOD FOR AN ELECTRICAL INSTALLATION COMPRISING COMMUNICABLE MODULES, DEVICE AND INSTALLATION IMPLEMENTING SUCH A METHOD
    DE19814611A1 (en) 1998-04-01 1999-10-07 Bosch Gmbh Robert Bus system, especially for a home automation device
    FR2795544B1 (en) * 1999-06-28 2001-08-10 Schneider Electric Ind Sa COMMUNICATION DEVICE COMPRISING A CONFIGURATION DEVICE FOR HOME AUTOMATION INSTALLATION, INSTALLATION CONFIGURED BY SUCH A DEVICE AND CONFIGURATION METHOD
    US6759966B1 (en) * 2000-09-01 2004-07-06 Linsong Weng Wireless remote control bulb device
    HUP0104960A2 (en) * 2001-11-15 2003-07-28 Attila Murlasits Apparatus and method for regulating of electric loads
    SE535962C2 (en) 2011-06-23 2013-03-05 Zoliex Ab A control procedure in a network

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    FR2616935B1 (en) * 1987-06-17 1991-06-21 Duranton Rene BUS ADDRESSING DEVICE
    US4918690A (en) * 1987-11-10 1990-04-17 Echelon Systems Corp. Network and intelligent cell for providing sensing, bidirectional communications and control
    EP0453399A1 (en) * 1990-04-17 1991-10-23 Somfy Installation with a plurality of receivers and transmitters

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    Publication number Publication date
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