DE102008053339B3 - Method for transmitting data to e.g. sensor, of wireless network, involves exchanging data packets of network member of one activity class whose primary channel is defective in one of time slots, which is assigned to another member of class - Google Patents

Abstract

The invention relates to a method for transmitting data to subscribers of a wireless network provided with at least two transmission channels (K1, K2). Measures are proposed whereby only in the case of a disturbance of a transmission channel (K1) to another transmission channel (K2) is avoided. This means that not all subscribers have to be permanently synchronized due to a permanent channel or frequency change, which allows the subscribers to be switched passive over a longer period of time in order to minimize their energy requirements.

Description

The The invention relates to a method for transmitting data to subscribers one provided with at least two transmission channels Wireless network. About that In addition, the invention relates to a wireless network for performing the Method and also a coordinator, which is used in Such a wireless network is suitable.

Out The IEEE 802.15.4 standard is a wireless transmission protocol Sensor networks known, this standard communication between Ensures participants of different manufacturers. The transmission protocol between the participants, a coordinator, each one participant at least one slot (a time slice) within a frame (within one cycle time) for data transmission on a transmission channel this Wireless network provides. This is the beginning of such Frames through a marker - through a so-called beacon - the participants displayed, with which the participants with the coordinator time synchronized become.

It Now it may happen that, especially in an industrial environment this transmission channel temporarily "breaks in" (Channel Fading) and for a communication can not be used. This has a disturbing effect a technical process to be controlled or a technical control Plant off.

Around such disorders can largely avoid the communication by means of another transmission channel maintained in the event of a channel disturbance. Known systems - for example Bluetooth systems - use a so-called frequency hopping method (Frequency Hopping), as part of the transmission of the channel multiple times changed per second and the transmission power to the same extent on the dedicated frequency band is distributed. The disadvantage is that such Systems are not coordinated and it leads to unpredictable collisions can come if several such systems are active and influence each other. About that have to go out all participants will be permanently synchronized because a permanent Channel or frequency change takes place within the frequency band. This means that the participants are not passive over a longer period of time can be switched to minimize their energy needs.

Around namely to ensure, that the participants who are trained as a sensor or actor can, preferably consume little energy, it is desirable, the receiver or to switch the sender of the respective subscriber passively, which means that in this idle state (sleep mode) no communication between the respective participant and a coordinator. Only the part of the participant which is responsible for recording measurement data or is intended to output setpoints, can be constantly active be switched. To communicate between the coordinator and to enable a participant who is in hibernation will be first For example, this participant is activated on an event or time-controlled basis. Subsequently the participant must synchronize with the coordinator to as part of the communication, a data packet from the participant to the coordinator or transferred from the coordinator to the participant. The Time synchronization is done - like mentioned - by of the beacon, each participant after receiving the beacon reset the time, which means that all activated participants with the coordinator are time synchronous.

US 2004/0235489 A1 discloses a method and a device for wireless communication, wherein measures are provided which enable a switchover from a channel of low transmission quality to a channel with good transmission quality.

A method according to the preamble of claim 1 is known from DE 10 2006 036 603 A1 known. In the event that a current transmission path is disturbed, is switched to a new transmission path, with a particular selection of a time slot for data transmission on the new transmission path is not provided.

Of the The present invention is therefore based on the object, a method specify the type mentioned above, which influences the influence of channel interference reduced communication. Furthermore, a wireless network is too create, which to carry out of the procedure, and, moreover, a coordinator for use in such a wireless network.

These Task is in terms of the method with the in the characterizing Part of claim 1, relating to the wireless network with the in the characterizing part of claim 3 and in view of the Coordinator with the measures specified in the characterizing part of claim 5 solved.

It is advantageous that only in the case of a channel disturbance to another transmission channel is avoided, so that all participants do not have to be permanently synchronized due to a permanent channel or frequency change. This allows the participants to be passive switched over a longer period, to minimize their energy needs. Turns z. B. a participant in the form of a sensor only in a time interval of 10 s, it requires in a cycle of 10 ms only every thousandth time slot for transmission on its primary channel. Such a sensor is suitable for "sharing" its time slice with another sensor of the same activity class if the primary channel of the further sensor is disturbed and the transmission therefore takes place on the secondary channel of the further sensor, which is the primary channel of such a sensor.

Further advantageous embodiments of the invention will become apparent from the further subclaims.

The Invention, its embodiments and their advantages will be below based on an embodiment explained in more detail with reference to the single figure of the drawing. The Figure of the drawing shows the structure of a deterministic transmission protocol.

With 1 is a cycle time of a deterministic TDMA (Time Division Multiple Access) method referred to, which is provided in a wireless network as a communication protocol between coordinators not shown here and participants also not shown here in the form of sensors. A first coordinator communicates with a first sensor via a first channel K1 of the wireless network, a second coordinator uses a second channel K2 of the wireless network time-synchronized with the first channel via the coordinators for data exchange with a second and a third sensor. The beginning of a cycle time 1 the respective coordinator shows the sensors by means of a marking 2 - By a so-called beacon -, wherein the respective coordinator assigns each sensor at least one time slot for the transmission of a data packet. In the illustrated embodiment, it is assumed that the cycle time 1 nine time slots Z1, Z2, ... Z9, of which the third time slot Z3 within the first channel K1 for the transmission of a data packet D1 to or from the first sensor, the third and eighth time slot Z3, Z8 within the second channel K2 for the Transmission of a data packet D2, D3 are reserved to or from the second and third sensor. It is further assumed that the first coordinator assigns the first channel K1 as the primary channel and the second channel K2 as the secondary channel to the first sensor, the knowledge of which sensors are assigned to which channels as the primary channel and as the secondary channel, both in the first and in the second channel Coordinator is deposited. Of course, the wireless network can be designed such that only one coordinator coordinates the data transmission on both channels K1, K2.

According to the specifications of a user, which takes place within the framework of a project planning, parameterization and / or configuration of the wireless network, the coordinators assign the sensors a first or a second activity class, of which the first activity class comprises sensors which communicate more frequently than sensors of the first second activity class. In other words, frequently-communicating sensors are assigned to one activity class, low-communicating sensors of another activity class, and the knowledge of which sensors are assigned to which activity class is also stored in the coordinators. In the present example, the second sensor transmits Z2 within each cycle time in the second time slot 1 or within each cycle, a data packet D2 over the second channel, which means that this sensor is frequently active. For example, in the event that the cycle time 1 is ten milliseconds, 100 timeslots are needed within one second. In contrast, the first or the third sensor does not transmit K1, K2 within each cycle time via the first or the second channel 1 an event, which indicates a low activity. Such sensors usually transmit readings only one or more minutes apart. Due to the fact that the second sensor frequently transmits data, it is assigned to a first activity class, while the first sensor and the third sensor are assigned to a second activity class.

Next the assignment of the sensors to the first or second activity class wise - like explained - the coordinators provide the sensors with a primary and for at least some of these sensors to a secondary channel too. A data transfer or a communication between the coordinators and sensors over the respective primary channel in the case of a trouble-free Communication. In contrast, the data is transmitted via the respective secondary channel, if due to a channel fault a Data transmission over the respective primary channel not possible is. In the present example is for the second, often active and for the third, low-active sensor, the second channel K2 provided as a primary channel, for the first, low-active sensor is the primary channel K1 and the first channel as a secondary channel the second channel K2 provided.

It can now happen that z. B. the first sensor during a time interval Za (time slots Z3 ... Z5) "wakes up" and due to the following marker 2 (the following beacon) time-synchronized, but the sensor during the third time slot Z3 can not transmit its data packet D1 to the first coordinator, because the first channel K1 is temporarily disturbed. Due to this disturbance of the primary channel of the first sensor - the channel K1 - cause the first and the second coordinator that the data packet D1 of the first sensor via the Se Secondary channel of the first sensor - the second channel K2 - takes place, wherein the data packet D1 of the first, low-active sensor in the time slot Z8 is transmitted, which is provided for the third, also slightly active sensor.

To this data packet transmission the first sensor switches back to passive (sleep mode), causing the energy requirement of the sensor is reduced.

Around to further reduce the energy requirement of a sensor or actuator, is provided, the synchronization time of "dormant" sensors or actuators to reduce.

The Time synchronization is done - like mentioned - by of the beacon, each participant (sensor or actuator) after the Reception of the beacon resets the time, which means that all activated participants are time-synchronized with the coordinator. Due to the fact that the respective participant after his activation, d. H. after his "recovery phase", wait first until he receives the beacon, is the time required to create a data packet exchanging between participant and coordinator prolongs what means that the so-called latency deteriorates. in the unfavorable Case, the latency involves almost two time cycles, and then, if a participant in the first time slot of the time cycle after a Beacon wakes up, but the data packet only in the last time slot, assigned to this subscriber can be transmitted. First with the beacon of the following time cycle synchronizes the Subscriber and must wait until the last time slot of this time cycle a data exchange with the coordinator can take place. The energy consumption the subscriber increases with the duration of the switched-on transmitter and receiver the participant strongly, whereby in particular, if a high Number of participants must communicate with the coordinator, the energy needs is high; because an increasing number of participants increases the cycle time due The increase in the required time slots increases the synchronization times and thus the latency of a communication, which is a high Energy requirement for the participants due to the switched on transmitter and receiver of the Entrants.

In order to reduce the synchronization time of "stationary" sensors or actuators, it is therefore provided that the respective coordinator in the timeslot Z2, ..., Z9 of the respective channel of the sensor or actuator, a further marker (an "additional Beacon" ) enters, which does not transmit a data packet during the time slot Z2, ..., Z9, this further marking is also provided for time synchronization. In the event that z. B. the coordinator in the time slot Z6 after the time interval Za enters a further mark, the sensor is already synchronized due to this marker and not only due to the following marker 2 , whereby a channel change occurs due to a possible following disturbance at an earlier time. Other designs in connection with this improved time synchronization are from the German patent application 10 2008 038 584 whose content is considered part of the present application.

Claims (5)

Method for transmitting data to subscribers of a wireless network provided with at least two transmission channels, wherein - one of the transmission channels (K1, K2) is assigned to one of the transmission channels as primary channel and the other transmission channel as secondary channel and the channels (K1, K2) are time-synchronized, - the exchange of a data packet (D1, D2, D3) between at least one coordinator and in each case one of the participants during at least one time slot (Z2, ... Z9) of a time cycle ( 1 ) takes place via the respective primary channel, - in the event that the primary channel of one of the subscribers is disturbed, the exchange of the data packet (D1, D2, D3) of this subscriber during at least one time slot (Z2, ... Z9) of a time cycle ( 1 ) takes place via the secondary channel, characterized in that - the subscribers are assigned at least one first or second activity class, of which one of these activity classes comprises subscribers who communicate more frequently than subscribers of the other activity class, and - the exchange of the data packet (D1, D2 , D3) of one of the participants of the other activity class whose primary channel is disturbed takes place in the time slot (Z8) which is assigned to a further participant in this other activity class. Method according to claim 1, characterized in that that for every transmission channel (K1, K2) a coordinator is provided. Wireless network with at least one coordinator and at least two transmission channels for the transmission of data to subscribers, wherein - the participants one of the transmission channels (K1, K2) is assigned as a primary channel and the other transmission channel as a secondary channel and the channels (K1, K2) time-synchronized the exchange of a data packet (D1, D2, D3) between the coordinator and in each case one of the subscribers during at least one time slot (Z2,... Z9) of a time cycle ( 1 ) takes place via the respective primary channel, - in the event that the primary channel of one of the part the exchange of the data packet (D1, D2, D3) of this subscriber during at least one time slot (Z2, ... Z9) of a time cycle ( 1 ) takes place via the secondary channel, characterized in that - the subscribers are assigned at least one first or second activity class, of which one of these activity classes comprises subscribers who communicate more frequently than subscribers of the other activity class, and - the exchange of the data packet (D1, D2 , D3) of one of the participants of the other activity class whose primary channel is disturbed takes place in the time slot (Z8) which is assigned to a further participant in this other activity class. Wireless network according to claim 3, characterized in that that the wireless network for every transmission channel (K1, K2) has a coordinator. Coordinator for use in a wireless network according to claim 3 or 4, wherein - the coordinator is assigned to the subscribers of one of the transmission channels (K1, K2) as a primary channel and the other transmission channel as a secondary channel and the channels (K1, K2) are time-synchronized, the coordinator causes the exchange of a data packet (D1, D2, D3) between the coordinator and in each case one of the participants during at least one time slot (Z2, ... Z9) of a time cycle ( 1 ) takes place via the respective primary channel, - the coordinator in the event that the primary channel of one of the subscribers is disturbed, causes the exchange of the data packet (D1, D2, D3) of this subscriber during at least one time slot (Z2, ... Z9 ) of a time cycle ( 1 ) is carried out via the secondary channel, characterized in that - at least one first or second activity class is stored in the coordinator for each of the participants, one of these activity classes comprising subscribers who communicate more frequently than subscribers of the other activity class, and - the coordinator causes the exchange of the data packet (D1, D2, D3) of one of the subscribers of the other activity class whose primary channel is disturbed takes place in the time slot (Z8) which is assigned to a further subscriber of this other activity class.