DE10017182C2 - alarm device - Google Patents

Description

The present invention relates to an alarm device according to the preamble of claim 1.

Such devices, such as in the form of smoke detectors which a wirelessly to a central base station tied detector unit (satellite) to monitor in one the space (this is within the scope of the present invention an outdoor area is also meant) and in the event of an alarm, for example if there is one critical concentration of smoke in a measuring chamber of the Satellite, then an alarm signal is generated and transmitted over the radio range is transmitted to the base station. Then there a suitable evaluation of the alarm and, if necessary, the process further measures to react to the alarm take place. Especially with a view to flexible attachment without has the need to lay special signal lines the wireless connection between detector unit and base proven its unity; however, this does in practice the increase in radio signals from various transmitters in the relevant frequency bands (in particular for derar applications approved ISM tapes) to considerable Problems: This is how the security of the deployed comes Radio link against interference in view of the present "Alarm technology" area of special importance, and conventional Lö using a known radio link solutions often show considerable deficits in the area of Immunity to interference or third-party signals.

In addition, there are considerable practical problems if intended, known systems (consisting of egg ner base unit and one or more wirelessly bound detector units), e.g. in the With regard to a larger number of detec to be connected gate units of different detector types: So it is about au extremely problematic from the perspective of a base station  Simultaneously connect a plurality of signals wirelessly to monitor and evaluate their detector units without that signal collisions or other interference occur; A possible way out here is to provide a synchro clocked system, which is due to radio technology the required bidirectional technology for additional Effort. The complexity of these problems continues enlarged by the fact that different sensor types, i.e. et wa fire, gas, motion sensors, each very own Generate alarm or status signals, so in practice So far, usually in such an application wired systems (i.e. each detector unit is over connect a special signal line to the base station be selected.

DE 196 37 768 A1 describes an alarm device according to The preamble of the main claim is known. Furthermore, the DE 39 28 142 A1 a remote control system with transmitters for the Ausge ben an alarm signal via radio waves, each sensor contains an 8-bit identification code.

Furthermore, the post-published is the prior art Called DE 199 39 535 A1; this after that for age rank published the relevant application of the present application Scripture discloses an alarm device according to the Oberbe attacked the main claim, which additionally a sensor unit for generating and transmitting a sensor unit identifying address signal and a voltage supply status and an alarm status of the sensor unit indicating status signal is formed. The in the Signals described in the publication are output periodically sends, the transmission rate increases in the event of an alarm. Such a signal also contains information on the sensor type; the transmission is switched on by synchronization signals passes.

The radio sensor of US Pat. No. 5,430,433 A periodically sends out data packets which contain an address signal and a status signal. In addition, the combination of data packets into groups is also known from GB 2 313 980 A. There, 16 data packets, each with 72 bits, are sent out within a group. GB 2 313 980 A deals with the reliable detection of collisions and interference between radio signals from several unidirectional radio sensors.

Starting from US 5,430,433 A, it is therefore Object of the present invention, a gat appropriate alarm device with regard to flexibility the possible uses and the immunity to interference Interference on the radio link, particularly due to third parties gnale or other radio services to improve.

The task is accomplished by the device with the features of claim 1; advantageous developments of Invention are described in the subclaims.

This is advantageous in accordance with the invention de Invention a transmission protocol for the radio link before which a plurality of data packets and parent Neten data packet groups, both address signals le, as well as status signals, are provided in each of the data packets  are such that in each data packet group ei ne redundancy in the form of successive multiple times address and status signals.

The inventive concept of the radio link as System for packet-controlled data transmission and the he structure of the data packets and data packet group according to the invention This ensures that even with heavily fre acknowledged radio transmission channels Transmission requirements corresponding to the requirements of alarm systems security is possible. The data packets also enable the use of digital circuit technology according to the invention gie on both sides of the radio links, especially be preferred (and with the effect of a technologically fold and therefore inexpensive construction) unit and the base station for one-way use only Communication (i.e. from the detector unit to the base state on) is formed, so that advantageously the base sta tion does not have its own transmitter unit (and accordingly the detec door unit does not have to have its own receiver unit).

The term is within the scope of the present invention "Radio link" to be interpreted widely. Such are especially so Connections based on electromagnetic waves as to be considered by the invention which includes above the Fre, traditionally regarded as a "high frequency range" frequency spectrum, including connections the base of infrared rays.

As a result, the present invention enables high in a surprisingly simple circuit communicating with one another in a reliable manner can, according to the status and / or Address signal also offers the possibility of a spe sensor type currently used (i.e. smoke, gas, movement, Glass breakage, moisture sensor, etc.) to identify and to be taken into account accordingly as a signal at the receiving end gene.  

Especially when, as in a preferred embodiment Form provided, the detector unit according to the protocol provided data packets and data packet groups periodically transmits (in the case of a non-alarm state, in the further also called standby mode, for example at intervals of between about 30 and about 60 seconds) uses the signal sent over the radio link to determine whether there is a particular detec gate unit (hereinafter also referred to as "sensor unit") is in a trouble-free operating state (or there is still a radio connection via the radio link act). It is also particularly preferred to use one Transmission rate of data packet groups (i.e. the number of transmitted within a predetermined time interval Data packet groups) in one from standby mode was to increase the deviating alarm status so that it can be evaluated such an alarm state largely without delay can be determined.

In contrast, the (often battery-assisted) power consumption a wirelessly connected detector unit the transmission protocol is designed in such a way that Long dead times (break times) between each other following groups of data packets, an active (and thus transmission state that consumes only a significant amount of electricity a detector unit less than 5%, typically even less than 1% of the operating time, with the result nis that there is considerable downtime in battery operation let it be realized.

To make the present invention particularly easy to use According to a preferred further development, the Invention provided within a learning mode of the Basi unit an initialization of a detector unit for closing Interact with the base unit: This ge prefers to do so in response to about manu elle actuation of a corresponding switching element the Ba sisstation the ones emitted by the respective detector unit  Data packets with the special, identifying (and specific to the detector unit) address signal receives this address signal, more preferably together identify the sensor type of the detector unit with one the signal, in a suitable storage unit of the Basi unit stores and so for future regular operation the detector unit considers this to be correct with the base station interactively identi can fection.

It is also particularly preferred in the context of the present Invention, the connection of a detector unit (in vorlie text also synonymously referred to as "sensor unit") the base station using an asynchronous transmission protocol the radio link. Not only does this allow in a unidirectional approach is particularly advantageous tion, this also simplifies signal processing and processing, namely a transmission of the data packets over the radio link only by a suitable Se sequence of synchronization signals must be initiated.

It is at data packet groups transmitted in groups between individual groups Packet groups provided a first pause time, the length of which, above all is reasonable and random. This will in a particularly suitable way of trouble-free coexistence a plurality of (asynchronously) connected detector units Supported to a base station: namely, should due two De connected to a common base station detector units happen to have a data pair at the same time Send out ket group (or for an overlap sor gen), this would lead to a one clear signal indicating proper operation is recognizable and evaluable. Accordingly, further Da ten package groups of the detector units are awaited. However, these no longer take place at the same time point because of the distance to a subsequent data packet group is variable and therefore different; corresponding  it is now possible to receive data packet groups at the receiving end to receive both detector units without interference.

According to a further preferred embodiment, this is Conceptually designed transmission protocol so that within a data packet group (where according to the invention both the address and the status signal by the Multiple data packets are sent multiple redundant) predetermined second break times are provided, the one have a clear, constant length. By reception side evaluating this constant and known length of the second pause time between two data packets (the so far characteristic of a data packet group within the framework of the present alarm system) it is therefore possible to clearly determine whether a received data packet group comes from an associated detector unit, or et wa from another system or transmitter unit that is in the frame men of the present system brings no useful signal, son which is rather to be understood as a disturbance. So far serves preferably the second predetermined break time for delimitation of other systems that may also be in the concerned room to be monitored or its neighbor shaft can be provided.

Further advantages, features and details of the invention emerge from the description below more preferred Exemplary embodiments and with reference to the drawings; this show in

Figure 1 is a schematic block diagram of the alarm device according to a first preferred embodiment of the inven tion.

Fig. 2 in the signal-time diagram a representation of a transmission cycle or the packet structure of the data protocol for use in the device according to Fig. 1 and

Fig. 3 is a flow diagram with substantially Ver method steps for describing signal generation in the sensor unit of FIG. 1.

As shown in FIG. 1, a schematically shown, unidirectional radio link 10 connects a base unit 12 and one (or more) sensor unit (s) 14 . These have, as shown in FIG. 1, a sensor element 16 , which can be configured in an otherwise known manner as a fire, smoke, movement, brightness, temperature or presence sensor and in response to a corresponding environmental condition , e.g. B. smoke in a (not shown ge) measuring chamber of the sensor unit 14 , can output an output signal. This output signal is, as shown in FIG. 1, fed to a signal detection and processing unit 18 , which converts the sensor signal for subsequent conversion into a digital radio signal, and the signals to be transmitted in the described exemplary embodiment in addition to a sensor alarm signal - a message Si signal about low battery voltage, a status signal about the correct operating state (in the event of no alarm), a fault signal in the event of a malfunction in the sensor unit, and an identification signal relating to the respective sensor type. For this purpose, the signal detection unit 18 is typically provided with a suitably programmed microcontroller unit which, in the exemplary embodiment shown, has three parallel output signal channels A, B, C; In addition, the signal acquisition unit 18 is connected to a parameter storage unit 20 , in which (in the manner of a permanent memory) an address individually assigned to the sensor unit 14 (in the exemplary embodiment shown 3 bytes of 8 bits) is stored, and in addition a suitable data identifier for Identification of the type of sensor element 14 . Furthermore, as shown schematically in FIG. 1, the signal detection unit 18 is connected to a voltage supply unit 22 , which is typically implemented as a battery, the signal detection unit having suitable functionality in order to achieve a low voltage supply state (not sufficient for correct operation) the power supply unit.

The signal detection unit 18 is immediately downstream of a protocol or packet generation unit 23 which evaluates the three output signal channels A, B and C of the signal detection unit 18 and, in a manner to be described below, generates a digital, binary packet signal which corresponds to a predetermined packet structure and is passed from a downstream transmission unit 25 with otherwise known high-frequency modules via the radio link 10 to the base unit 12 .

On the reception side, the base unit 12 has a reception unit 24 assigned to the radio path 10 , which is followed by a control and evaluation unit 28 which interacts with a storage unit 26 . This again provides received signals processed and evaluated by the control / evaluation unit 28 via a suitable interface unit 30 for the transmission, evaluation and / or control of corresponding alarm units for output.

The device shown schematically in FIG. 1 now makes it possible to monitor both an alarm-free and trouble-free operation of the sensor unit 14 in the manner to be described in more detail below, and also to react immediately to an alarm and / or fault signal from the unit 14 , or to determine (by the absence of a protocol-based transmission signal) that the radio link 10 is not functioning properly.

Signal acquisition and processing in the sensor unit 14 will be described below with reference to the schematic representation of a transmission cycle in FIG. 2, which is shown as a signal / time diagram and has the packet structure shown in FIG. 2.

More specifically takes place in the shown transmission cycle according to Dar position (A) of Fig. 2 is a transmission of four packet groups PG1, PG2, PG3, PG4 place, wherein a pause time T1 is provided between each packet group which is variable between aufein other following groups PGi, is typically moves between 0.2 and 2.7 seconds and is set or determined by a random generator implemented in the signal detection unit 18 .

Fig. 2 shows (b) in an enlarged form the structure of a packet group PGi. As shown in the structure, each packet group PGi in the illustrated embodiment begins with a sequence of twenty synchronization pulses (shown as a block SYN), with each pulse having a bit length of 208 microseconds at a transmission speed of 4,800 baud, for example, the synchronization block SYN one Has a length of 8.32 ms. The synchronization packet SYN is followed by a synchronization gap (pause time) T2 of a fixed length of 4.16 ms (corresponding to a bit length of 20), and, as shown in FIG. 2 (b), each follows from a start bit S1 or stop bit S2 limited packets P1, P2. , , Pj (where j is typically between 11 and 20, ie within a packet group between 11 and 20 data packets Pj are transmitted), and with individual packets with preceding or following start / stop bits S1, S2 between them the fixed, constant Have pause time T2 of 4.16 ms.

For example, 11 data packets P1 to P11 are inside a packet group PGi transmitted, so the entire packet Group with the 11 break times T2 and the Synchronisati onsblock SYN a total length of approx. 352 ms.

Fig. 2 additionally shows how a signal packet P (j = 1 ... 11) is constructed, namely it consists of a total of four data bytes (each with eight bits), the first three bytes as address bytes ADR1, ADR2, ADR3 are realized (thus an individualizing address of a sensor unit can be coded a total of 24 bits), and in addition a fourth byte in the exemplary embodiment shown encodes the sensor type in the first 4 bits and the current operating status in the second 4 bits.

The data transmission protocol described above and shown schematically in FIG. 2 enables not only status data of a respective sensor unit to be transmitted in an operationally reliable and efficient manner (whereby, in order to increase operational reliability, the alarm device on the receiving side is designed by the control and evaluation unit 28 in such a way that That at least three times the same address and status information, i.e. a packet P, must be read in correctly before information is considered valid), the predetermined, constant pause times T2 within a packet group are a good indicator that a received signal is actually from an associated sensor unit was sent from. As already described at the beginning, the variable pause time T1 between successive packet groups PG ensures that, in the (theoretical) case of a collision between two packet groups PG, sensor units operated simultaneously can no longer collide at least one consecutively sent packet group.

In further to Figure 3, the signal generation and processing for the erläu shouldered in Fig. 2 protocol is based on the flow chart. Described the method shown in Fig. 3 in particular relates to the operation of the signal detection and processing unit 18 and the protocol unit 23.

Thus, in a step S1 the signal of the sensor element 16 (which is permanently supplied with current by the voltage supply unit 22 ) is detected and processed (unit 18 ), and in step S2 it is then determined whether an alarm signal (channel C of unit 18 ) is set or not. In the event of an alarm (decision in S2: YES), the method branches to step S21, activates the voltage supply to the transmitter unit 25 there , and the four packet groups (ie a transmission cycle according to FIG. 2) PG1 to PG4 are sent (S22) in step S23 the check as to whether the alarm signal (channel C) is still active, and if this is the case (decision YES), after a delay time of 5 seconds (S24), the process branches back to step S22, i.e. the reissuing of a transmission cycle with four Packet groups in which the individual packets transmit the alarm signal in their status byte. This described loop also increases the transmission rate of the packet groups compared to a non-alarm state, because in the described alarm case, as mentioned, the transmission cycle (the interval between successive groups of 4 groups of packets) is reduced to 5 seconds, while in the non-alarm state From this was typically about 40 seconds.

If, on the other hand, it is determined in step S23 that there is no longer an alarm signal at output C of the unit 18 , the transmitter is switched off in a step S25.

The determination in step S2 that there is no alarm signal (channel C) then leads to the initiation of a routine which, at periodic intervals, here about 40 seconds, sends out a so-called sign of life, that is again the packet group shown in FIG. 2, only in the longer 40 second intervals compared to an alarm state (step S3).

More specifically, within the specified 40 second period, channel B of unit 18 outputs a corresponding sign of life signal pulse (typically 10 ms in length), and a check is carried out in step S31 to determine whether this pulse is present on channel B. If this is not the case, the routine branches to step S25, ie the transmitter is de-energized. If, on the other hand, it is found that an activation pulse of this type is present at output B, the transmitting unit 25 is activated in step S32, that is to say applied to this voltage, and the operating voltage of the voltage supply unit 22 is checked in step S33 by the signal detection unit 18 . Specifically, an identifier for low battery voltage is generated by the three output channels A, B, C in that a signal on A follows immediately after a signal B; this is tested in step S34, and if such a low battery voltage is detected, the corresponding status byte is set in packets P (j = 1... 11) in step S39 (see FIG. 2). Accordingly, the following step S4 then triggers the generation and execution of a transmission cycle (ie four packet groups PGi, i = 1... 4, according to FIG. 2).

If, on the other hand, it is determined in step S34 that the operating / battery voltage is sufficient (S35), a check is carried out in step S36 for the presence of a fault in the sensor-side signal generation; Specifically, unit 18 tests here whether a signal exists on channel A within the period given by the clock on channel B, which is then identified as a fault (S37) and the transmission cycle is then carried out in S4 with a correspondingly set status byte. Alternatively, the routine branches from S36 to step S38, where the status byte in FIG. 2 is set to "status ok", and here too the transmission cycle according to FIG. 2 is initiated with S4.

Dung According to a further preferred development of the OF INVENTION the base unit 12 is a regi (not shown) associated with striereinheit which for each of the Ba siseinheit 12 associated sensor units 14 has a specifi c counter unit. The registration unit is designed such that, in response to a data packet received by a respective sensor unit (by solving the specific address data), it identifies the respective sensor unit and increments or decrements the associated counter unit (depending on the configuration).

In predetermined periods, e.g. B. in sections of about 8 minutes, it is now checked whether the meter reading has changed, whether from a Sen a signal (sign of life) has been received, with further preference for each counter or for the sen unit can be set individually, if at all such monitoring for operational readiness and proper function is necessary.

This further development according to the invention allows is therefore independent of a specific interference to be received determine the status or status signal via the radio link, whether the radio link or the connected Sen unit is working properly, and that already Failure to receive proper data packets in the predetermined or presettable periods can then for outputting corresponding error or alarm messages to lead.  

In the concrete implementation can be (for example by means of ge suitable programmed functionality of the base station or the registration unit) this inventive idea in particular re also realize that every review cycle (e.g. in the 8-minute intervals) to an increment error or decrement an error, and then a Data packet received correctly within this period a reset of this counter means. Then in particular the review period was chosen so that in the interim a large number of data packets would have been received can, in particular, only short, temporary Interference can be intercepted using radio systems without a malfunction needs to be displayed.

As a result, the present invention thus produces in pro A radio prototype that is easy to implement in terms of grammar koll, what low hardware expenditure with highest possible transmission and combination security, especially with regard to a variety of with one Base station of sensor units to be used, combined. The signal ver according to the invention contains particular importance work and preparation also in that problem-free not just a unique address assignment from the sensor unit and base station is possible (i.e. the base station in particular special can also ignore any received signals that do not come from a clearly identified address), but also together every status or alarm signal who evaluated and evaluated with a corresponding sensor type that can.

Claims (11)

1. Alarm device for room monitoring with a smoke, gas, motion or sound sensor ( 16 ), via a radio link ( 10 ) with a base station ( 12 ) connected detector unit ( 14 ), which in response to a predetermined, the Sensor-activating ambient state in a room to be monitored is designed to transmit an alarm signal over the radio link,
wherein the detector unit ( 14 ) is designed to generate and transmit an address signal (ADR1-ADR3) identifying the detector unit and a status signal (STATUS) indicating a voltage supply state, a standby operating state, an alarm state and / or a malfunctioning state of the detector unit,
characterized in that
the radio link is implemented by means of a transmission protocol having a plurality of data packet groups (PGi),
the data packet groups each comprise a plurality of data packets (Pj) from the address signal and status signal, and
a pause time (T2) of predetermined, constant length is provided between successive data packets (Pj). 2. Device according to claim 1, characterized in that the detector unit for periodic emission of data packet groups (PGi) is formed, wherein a transmission rate of data packets in the alarm state of the detector unit is higher than in the Be willingness operating condition. 3. Device according to claim 1 or 2, characterized records that the base station means for communication tion fault detection that is used for monitoring of data packets and received over the radio link  Data packet groups are trained, as well as Ausge ben a communication interference signal when inside a predetermined periodic period no egg signals corresponding to the set profile will catch. 4. Device according to one of claims 1 to 3, characterized characterized that the status signal is an identifica tion signal, which is characteristic of a Sensor type is assigned to the detector unit, the base station to cooperate with a A plurality of detector units, preferably with ver different sensor types. 5. Device according to one of claims 1 to 4, characterized characterized in that the base unit means for In itialization of the base unit with a detec Gate unit connecting radio link, wherein the initialization means for preferably wireless Detect the one that identifies the detector unit Address signal in response to one at the base learning mode that can be activated and for saving of the address signal are formed. 6. Device according to one of claims 1 to 5, characterized characterized that the transmission protocol asyn is realized chronologically and a transfer of a da package group by broadcasting Synchronisa tion signals (SYN) initiated over the radio link becomes. 7. Device according to one of claims 1 to 6, characterized characterized that the transmission protocol between data packets that are consecutive in time provides a first pause time (T1), the length of which va riabel and preferably randomly generated.   8. Device according to one of claims 1 to 7, characterized characterized that the second break time (T2) predetermined, constant length from the base station to clearly differentiate one from one Data unit group transmitted from detector unit Radio signals from not the alarm device associated third-party devices can be evaluated.   9. Device according to one of claims 1 to 8, characterized in that the detector unit has a signal processing unit ( 18 , 23 ) assigned to the sensor ( 16 ) and a transmission unit ( 25 ) connected downstream of the signal processing unit, the transmission protocol being formed such that in the standby operating state of the detector unit, the transmitter unit is de-energized in at least 99%, preferably 99.5% of the time. 10. Device according to one of claims 1 to 9, characterized characterized that the radio link in an ISM Frequency band, preferably in the range 433, 868 or 919 MHz, is operable. 11. The device according to one of claims 1 to 10, characterized in that the base station ( 12 ) has a registration unit which, in response to a data packet group detected by a detector unit, increments or decrements a counting unit specifically assigned to the detector unit, and within predetermined Time intervals determine whether a counter reading of the registration unit has changed.