WO2001006824A1

WO2001006824A1 - Energy saving administration of a data transfer network

Info

Publication number: WO2001006824A1
Application number: PCT/DE2000/001984
Authority: WO
Inventors: Uwe Schwark; Edgar Bolinth; Ralf Kern
Original assignee: Siemens Aktiengesellschaft
Priority date: 1999-07-21
Filing date: 2000-06-16
Publication date: 2001-02-01
Also published as: AU5965500A; DE19934250A1

Abstract

The invention relates to a data transfer network having a plurality of nodes (0, 1, 2, 3), one (0) of which is provided with an autonomous power supply. Said nodes can assume a master or slave role, whereby energy consumption varies accordingly. The aim of the invention is to ensure that autonomous power is supplied over a long standby period, whereby the node (0) provided with said autonomous power supply transfers a master role to a second node if it initially assumes a master role with high energy consumption in the set-up of the network.

Description

description

Energy-saving management of a data transmission network

The present invention relates to a method for managing a data transmission network and a transmission network suitable for using the method. The network comprises a plurality of nodes, at least one of which has an autonomous energy supply, for example in the form of a rechargeable battery or a battery, and which are set up to take over roles which differ in their energy consumption, each of which Role to be assumed for the role in building the network.

Such bifunctional nodes are common in cordless communication systems with the ability to establish a network without prior configuration, so-called ad hoc LANs. One of the roles that a node can assume is that of a network master, which controls essential tasks such as the timing of the entire network. Each network has exactly one master, the remaining nodes each take on the role of slaves. The master role is usually assumed by the node that initiates the connection establishment between the nodes of the network, that is, the network establishment.

The organizational effort that the master has to do in order to coordinate the communication of the individual nodes within the network means that the energy consumption of a node differs depending on whether it is working as a master or as a slave, the energy expenditure of the Masters is higher. If the role of high energy consumption has to be performed by a node that has an autonomous energy supply, this accelerates the exhaustion of the energy supply and thus shortens the time in which the transmission network can work continuously. The object of the invention is to specify a method for managing a data transmission network of the type shown, in which an unnecessary load on the autonomous energy supply is avoided and the uninterrupted working time of the transmission network is thus increased.

This goal is achieved by dynamically assigning the different roles to the nodes of the network, in which the node with autonomous energy supply, if it initially assumed a role with high energy consumption when building the network, transfers this role to a second node.

In this way, even if the transmission network consists only of nodes with an autonomous energy supply, the role with high energy consumption does not have to be carried out continuously by the same node, so that its energy supply is protected and the energy supplies of the other nodes are at least temporarily be used for this role.

If there is a node with a network-connected energy supply, it is of course preferred if it is selected to take on the role with high energy consumption.

Since the energy consumption of this node does not affect the network's uninterrupted working time, this node can remain in the role of high energy consumption indefinitely.

Such a node with a network-connected power supply can be identified on the basis of its address within the network. For this purpose, two groups of addresses are expediently defined for nodes of the network, addresses of the first group each being assigned to nodes with autonomous energy supply and addresses of the second group to those with network-connected energy supply. the. This allows the node that tries to deliver the role with high energy consumption to recognize the suitability of a second node for taking over this role based on its network address. According to a simple embodiment, the second group contains only one address, even if the network comprises several nodes with a network-connected energy supply, so that the role with high energy consumption is always handed over to the node with this address.

Alternatively, it is possible for the second group to comprise a plurality of addresses, and for the node whose addresses belong to the second group to select the node which takes on the role with high energy consumption on the basis of additional criteria.

In particular, if the network is a network with wireless transmission, it is expedient to select from among several nodes with the addresses belonging to the second group the one to take over a master role with higher energy consumption, which guarantees the best transmission quality to the remaining nodes of the network.

Further features and advantages of the invention result from the following description of exemplary embodiments with reference to the figures.

Show it:

1 shows a Bluetooth piconet as an example of a transmission network according to the present invention; and

2 shows the sequence of a signaling protocol which is processed by the nodes of the network from FIG. 1 in order to determine a node to which the master role is to be transferred. Figure 1 shows schematically an inventive Bluetooth network. The network comprises four nodes, a mobile phone 0, for example according to the GSM standard, a laptop computer 1, a printer 2 and a cordless mouse 3. Further components, for example a second microcomputer, a cordless keyboard or the like, could also be a node of the network, but are not shown in the figure, since they are not essential for understanding the present invention.

If, for example, an e-mail arrives from a base station 4 via the cell phone 0, a Bluetooth component of the cell phone 0 must establish a connection to the corresponding components of the other devices 1 to 3 of the network in order to be able to transmit the e-mail. The mobile phone 0, as the node initiating the connection, thus initially has the role of the master in the data transmission network. This means that the mobile phone 0 has to ensure the time synchronization of the data traffic of all other devices, and also that all data transmissions between the other devices 1, 2, 3 of the network, which all work as slaves, run via the mobile phone 0.

As a result, the battery of the mobile phone is loaded and soon exhausted. In order to avoid this problem, a command is provided in the protocol of the data transmission network according to the invention which allows a node of the network working as a master to transfer its master role to another node.

Various scenarios are conceivable for the application of such a command. In a first such scenario, a temporary master such as the mobile telephone 0 can give any other node in the network, which is selected, for example, according to the random principle, a command to assume the master role. This scenario is useful when all nodes in the network have an autonomous power supply own battery or accumulator. In this case, the master role is continuously exchanged between the individual nodes as long as the network is working in order to distribute the increased energy consumption associated with the exercise of this role as evenly as possible to all nodes. The time that a node waits before it continues to transfer the master role it has taken on can be predefined, for example, depending on the specified capacity of its energy supply, or it can be determined dynamically depending on the current charge level of the energy supply, in order to ensure the longest possible service life for all To reach knots.

If the communication network has nodes with network-connected energy supply, such as printer 2 in the case of the network shown in FIG. 1, it is of course better for the service life of the battery or accumulator-operated nodes if the energy-consuming master role is constantly supplied by a device supplied with mains voltage is perceived. This situation arises automatically when all autonomously powered devices transfer the master role to a randomly selected other node in the network after a given period of time. If the transmission process is repeated only enough times, the random selection of the node taking over the master role must fall on a node with mains power supply, with which the role then remains.

A second scenario presupposes the presence of at least one node with network-connected energy supply in the network.

In order to shorten the search phase for such a node, a targeted transfer to nodes with mains power supply can take place instead of the randomly controlled transfer of the master role. Such targeted forwarding is based on the use of different groups of addresses for the nodes of a network, with addresses of the first Group of autonomously supplied nodes and those of the second group are network-supplied nodes. When the cellular phone 0 initiates the establishment of the network, the other nodes reveal themselves to it with their respective addresses. On the basis of these addresses, the mobile telephone 0 is able to immediately recognize those nodes which have a mains power supply and to transmit the master role directly to one of these terminals.

Devices such as the laptop 1 can work autonomously as well as mains-powered. Such a device therefore expediently has two addresses, each belonging to the two different groups, and identifies itself to the initiating device 0 optionally with one of the two addresses, depending on whether it is network-powered or autonomous at the relevant time.

In a communication system such as that shown in FIG. 1, the computer, in this case the laptop 1, is generally the device with the greatest need for data transmission. For this reason, it can be useful to specify this device as the one that is to take on the master role. This measure is equivalent to the fact that the second group of addresses to which the master role may be transferred contains only the address of the device 1 in question.

In the event that the laptop is predefined as a device that is to assume the master role, the two scenarios can advantageously be combined. If the laptop works autonomously and therefore reveals itself to the mobile phone with an address of the first group, a targeted transfer of the master role to it is not possible, and the transfer of this role from one node to another takes place according to the first scenario. If the laptop is switched to mains power supply, it has to identify itself to the other nodes in the network with its second address and then receives the master role. If the communication network has at least two network-supplied nodes, such as the printer 2 and the laptop 1 supplied via its charger 7, the second group of addresses can comprise the addresses of all devices supplied with mains power or at least a plurality of them, according to a further scenario, and an autonomously powered device such as mobile phone 0 selects from among the various nodes with mains power supply the one that has the best connections to all other nodes in the network. Such a scenario is particularly useful in the case of a cordless data transmission network such as the Bluetooth network considered here, in which the transmission connections between individual nodes can be of different quality.

The method for determining the node which is best suited as a master from the point of view of transmission technology is explained with reference to FIG. The figure comprises four lines, which are designated by 0 to 3 and each transmit and receive activity of the mobile phone 0, the laptop 1, the

Represent printer 2 or the mouse 3. It goes without saying that these four devices are each only examples of possible nodes of a network according to the invention and that the method could run in an identical form with other nodes involved.

At the beginning of the procedure shown in Figure 2, the mobile phone 0 is the master of the Bluetooth network and the other three devices work as slaves. Communication between the devices therefore takes place exclusively on the connections 5 between the mobile phone 0 on the one hand and one of the three other devices on the other hand. In a first phase of the method, shown as column 10 in FIG. 2, the mobile telephone 0 sends a request to the laptop 1 to temporarily take over the function of the master, in order in this way direct data transmission on the connections 6 between the laptop 1 and to enable the three other devices. This request is also received by the remaining nodes 2, 3.

In the subsequent phase 11, all nodes working as slaves confirm the temporary role reversal. The order in which the individual nodes 1 to 3 send the confirmations can be determined, for example, on the basis of their network address, which results in the order shown in FIG.

The temporary transfer of the master role to the laptop 1 means for all other nodes 0, 2, 3 of the network that they have to send out a predetermined test data packet. This happens in phase 12. The order in which the test data packet is sent out also depends on the addresses of the other nodes.

After the laptop 1 (on the radio connections 6) has received all the expected test data packets, in phase 13 it sends a request to the mobile phone 0 to take over the master role again. This request is also received by printer 2 and mouse 3.

In phase 14, the devices 0, 2 and 3 send confirmations to the laptop 1 giving the master role, just as in phase 11 to the mobile phone 0, and the mobile phone again assumes its role as master which was temporarily given in phases 12 and 13.

At the same time, the laptop 1 evaluates those from the other nodes

0, 2, 3 received test data packets and transmits its evaluation of the transmission quota to the mobile phone 0 in phase 15. The criteria used for the evaluation of the transmission quota can vary depending on the application environment and equipment of the air interfaces of the devices. For example, the laptop 1 can directly measure the signal level of the received test data packet and use it as a use the quality of the transmission of a single radio connection. It is also possible to use a test data packet with a predetermined content, the laptop 1 then being able to assess the transmission quality on the basis of a comparison of the received test data packet with the predetermined content. For the purpose of this assessment, many correction mechanisms that are used for normal data transmission on the radio links can be switched off, in order to enable a more sensitive assessment of the transmission quality. However, the transmission quality of the individual connections 6 is only a partial aspect when assessing the suitability of the laptop as a successor in the master role. A node in the network may have good connections to other nodes, but may still be unsuitable as a master if it is unable to reach one or more other nodes in the network, or the transmission quality to such nodes is so poor that one Numerous necessary repetitions affect the effective transmission rate of the network. For this reason, the variance of the transmission quality of its individual connections 6 expediently also flows into the assessment of the transmission quality of the laptop 1, the transmission quality of the laptop 1 being rated the worse, the greater the variance. If the laptop 1 cannot reach any of the remaining nodes or can only reach them with poor connection quality, this also affects the evaluation of its connection quality.

The method shown in FIG. 1 for the laptop 1 is repeated in an analogous manner for the printer 2, all connections between the printer and other nodes in the network being checked, some of which are not shown in the figure.

Since the mouse 3 has an autonomous energy supply, it is not qualified to assume the master role, and it is it is therefore not necessary to assess their connection quality.

After the procedure shown in FIG. 2 has been carried out for the laptop 1 and the printer 2, the mobile telephone 0 has the ratings of the transmission quality of these devices and issues a command to assume the master function to the device that has received the best rating , As soon as this device takes over the master role, the mobile phone 0 can take on the less energy-intensive slave role.

Claims

claims

1. A method for managing a data transmission network with a plurality of nodes (0, 1, 2, 3), of which at least one (0) has an autonomous energy supply, and which are set up to take on roles which are in each other differ in their energy consumption, the role to be assumed by each node (0, 1, 2, 3) in establishing the network being determined, characterized in that the node (0) has an autonomous energy supply, if it is initially involved in establishing the network has taken over a role with high energy consumption, transfers this role to a second node (1).

2. The method according to claim 1, characterized in that the node with autonomous energy supply (0) as a second node selects a node (1) with network-connected energy supply.

3. The method according to claim 2, characterized in that each node (0, 1, 2, 3) within the network is assigned an address, wherein a first group of addresses nodes with autonomous energy supply and a second group of addresses nodes with network energy - Supply is reserved, and that the node with autonomous energy supply (0) recognizes a node as suitable for taking over the role with high energy consumption if it has an address of the second group.

4. The method according to claim 3, characterized in that the second group comprises only one address.

5. The method according to any one of the preceding claims, characterized in that one of the rollers is a master roller and another is a slave roller.

6. The method according to claim 5, characterized in that the role with high energy consumption is the master role, that the nodes (0, 1, 2, 3) of the network are connected wirelessly and that an evaluation of the transmission quality of the connections (6) of the slaves is carried out among each other, and the node (0) working as a master with autonomous energy supply among several nodes (1, 2) working as a slave with network-connected energy supply determines who (1) to take over the master role who best transmits the quality other nodes (0, 2, 3) guaranteed.

7. The method according to claim 6, characterized in that selected for the evaluation of each node (1) with network-connected energy supply in turn and the transmission quality between the selected (1) and the other nodes (0, 2, 3) based the transmission of a test data packet is evaluated.

8. The method according to claim 7, characterized in that the node with autonomous energy supply (0) sends a request to send the test data packet (phase 11), and that the other nodes (0, 2, 3) the test data packet to the selected node ( 1) send.

9. The method according to claim 8, characterized in that each of the other nodes (0, 2, 3) is assigned a time offset, after which it begins with the transmission of the test data packet.

10. The method according to any one of claims 6 to 9, characterized in that the selected node (1) temporarily assumes the role of the master for evaluating the transmission quality.

11. The method according to any one of claims 6 to 10, characterized in that the evaluation on the selected kno- ten (1), and that the results are transmitted to the node (0) with autonomous energy supply.

12. The method according to any one of claims 6 to 11, characterized in that the evaluation of a connection between the selected node (1) and one of the other nodes (0, 2, 3) based on the signal strength with which a test data packet from the selected node ( 1) is received, and / or the error rate of the test data packet takes place.

13. The method according to any one of claims 6 to 12, characterized in that the evaluation of the transmission quality of the selected node (1) based on the variance of the transmission quality of the individual connections between the selected node (1) and the other nodes (0, 2, 3rd ) and / or based on the number of other nodes whose transmission quality to the selected node is inadequate.

14. Data transmission network, in particular for carrying out the method according to one of the preceding claims, with a plurality of nodes (0, 1, 2, 3), which are set up to take over roles that differ in their energy consumption, and from which at least one (0) has an autonomous energy supply, characterized in that the node (0) with an autonomous energy supply strives to transfer an assumed role with high energy consumption to a second node.

15. Data transmission network according to claim 14, characterized in that it is a Bluetooth network.