WO2006134060A1 - Method and device for transmitting data - Google Patents

Abstract

The invention relates to a method for transmitting data in a network, wherein all relevant devices which are used for the transfer, via alternative channels which communicate in a wireless manner with a standard channel, and which are secured by rear switching to the standard channel, such that all the participating devices remain in the system as part of the network.

Description

description

Method and device for data transmission

The invention relates to a method for data transmission according to the preamble of claim 1 and to a device for data transmission according to the preamble of claim 6.

From the ever-converging communication technology, there are known networks, such as a "Local Area Network" LAN, having a plurality of devices adapted for data transmission, the transmission of the data being wired, i. via the stations connecting lines, while at a local, so-called. Wireless network ("Wireless Local Area Network"), the transmission wirelessly, i. via a radio link, whereby in the case of a WLAN also a hybrid network of stations connected via line or radio link is permissible.

One form of at least partially wireless networks are infrastructure networks in which each data transfer is made via a particularly excellent device, the access point. Another form is ad-hoc networks, which do not necessarily require an excellent device such as the access point. The devices communicate directly with each other within such a network. If two devices are outside their respective radio range, they use other devices in the network as intermediate stations for data transmission in the 802.11s standard, which is referred to as multi-hopping.

For ad-hoc networks and mesh networks, the following problems occur which can significantly reduce the actual achievable data throughput in the network compared to the technical bandwidth. Problem 1) Hidden node problem. In a wireless network, it can happen that two devices are each out of range of the other device. If data is to be transferred from each of these two devices to a third device that is within range of the first two devices, a collision occurs. The first two devices can not detect that the other device is transmitting at the same time, and the third device can not receive two transmissions at the same time.

Problem 2) Exposed node problem. In a wireless network, the case may arise that data from two transmitting devices should be transmitted to two other receiving devices. The arrangement of the devices is such that the two receiving devices can only receive the respective correct transmitting device due to the respective radio range of the transmitting devices, so that a transmission at the same time is possible. If the arrangement of the devices continues to be such that the two transmitting devices are within their respective radio range, only one of the two devices will transmit in each case in order to avoid collisions. Since a collision is excluded due to the arrangement of the devices in this case, there is an unnecessary restriction of transmission here.

Problem 3) Basically, all data transfers that take place must share the technically available bandwidth. Many simultaneous transmissions therefore reduce the data throughput for each individual data transmission. This leads to the further problem that QoS requirements for certain data transmissions in a busy network can not be met. "Time-critical" data, such as voice data ("Voice over IP", VoIP) and video conferencing, the latter services are so time-critical, among other things because delays and / or data loss of a user immediately detected, ie heard or gese - may therefore not be transferred with the required quality.

The object underlying the invention is to specify a possibility which at least reduces the known problems.

This object is achieved by a method according to claim 1 and an apparatus according to claim 6.

In this case, in a wireless network with at least two devices designed for data transmission, which are connected in the default setting via a standard channel for signaling and data transmission, the following voting steps are carried out between at least two participating devices before the start of a data transmission:

- Decision not to use the default channel for data transmission - Decision for an alternative channel

Change of involved devices to the alternative channel

Thereafter, the planned data transmission via the alternative channel and after completion of the data transmission, a change takes place in the default setting.

The wireless network can be an infrastructure network in which the communication between devices always takes place via an access point. Alternatively, it is also possible that the network is an ad hoc network in which the devices can communicate directly with one another. Furthermore, it can also be a multihop network, in which data transfer between two devices, which can not reach each other directly due to their limited radio range, can be used for forwarding devices lying between them. The devices that make up this network are all devices that can be linked to a wireless network. These are, for example, telephones, laptops, PCs, PDAs, mobile phones. Network devices such as routers and gateways can also be involved in such a network. It is also possible that the communication device is an external device which is wired to a PC and allows it to be part of the wireless network. Through a gateway, the wireless network can be connected to a wired network, such as the Internet.

By default, all devices that are part of the wireless network communicate with each other via a radio channel called a standard channel. The setting of this default channel can be done by the user, be pre-set by the manufacturer or only result in the creation of the network.

The standard channel is used both for signaling between the devices, i. for votes that take place prior to actual data transmission, as well as for the actual data transmissions used. The method according to the invention makes it possible to deviate from the standard channel for data transmissions. However, returning to the default setting after transmitting data over a channel other than the standard channel ensures that the devices involved remain part of the wireless network.

If there is a data transmission between at least two devices, voting steps take place in advance. In the first

Step a decision is made not to use the default channel for data transfer. This decision may be based on factors such as the nature of the data to be transmitted. Another possibility is that the decision is based on which device is the sending device or which devices are the target of the data transfer. For example, the decision may be based on whether the destination of the data transfer is outside the wireless network. A the simple possibility is that there is always an attempt to use a different channel for data transmission.

If the decision is made not to use the default channel, a decision is made for a particular alternative channel used for data transmission. For this purpose, a search for an alternative channel is performed first. Its load can be used as a criterion for using a channel. A channel could only be considered if the load reaches a threshold value at most. It is also possible to choose the alternative channel without stress test. It is also possible to select the alternative channel based on a predefined assignment of channels to the type or content of the data transmission or QoS request. In the decision, the load of the standard channel can be used.

If an alternative channel is found, the use of this channel is tuned between the devices and the participating devices change to the alternative channel. This tuning may e.g. take place through a multicast message to all participating devices. This multicast message contains the request to change the channel. It can also provide further information, e.g. over the planned duration of the data transmission.

It is possible that all participating devices respond to the multicast message, for example with an "OK" or "NOT OK" response. Restrictions can also be returned in an "OK" response, for example, about the maximum duration of the channel change for a device involved If the data transmission is possible taking into account the answers, the request to change channels can be made in a further multicast message In this case, in turn, additional information can be passed on, such as a period of time for which the channel change should exist. It is also possible that the "NOT OK" answers will prevent data transmission, for example delaying the data transfer or sending it with a different QoS request.It is also possible to use the default channel after all.

In the case of data transmission without intermediate devices, only transmitting and receiving devices need to change. If multi-hopping is used, all devices in between must also change.

Then the actual data transmission takes place via the alternative channel. It is possible in this case that the use of the alternative channel no longer requires all the devices involved for the transmission. In this case, the data transmission can also take place via a different route. Because of the use of the alternate channel, this usually means that some of the devices involved actually perform the data transfer.

After completion of the data transfer, all devices that have changed to the alternative channel in the coordination steps, return to the default setting. This can be done automatically or through a multicast message, in which all participating devices are requested to change to the default setting. This means that all participating devices can send and receive again on the standard channel and thus are part of the network again.

The advantage of the method according to the invention is that the probability and frequency of packet collisions is reduced. This is because any two data transmissions are likely to be transmitted on different channels, which will not interfere with each other. This means that both the hiddle-node problem and the exposed-node problem are reduced. Another advantage is that the usable bandwidth for data transfers increases, but all devices still remain part of the same network. Thus, a higher throughput can be achieved. Furthermore, both jitter and delay are reduced.

A particular advantage of the method according to the invention is that without special hardware, i. with devices with only one transceiver, can be used. The existing hardware is thus better used.

Advantageous embodiments and further developments of the invention are specified in subclaims.

An advantageous embodiment and development of the invention consists in that the data transmission takes place via at least one intermediate device, i. Multihopping is used.

A particular advantage arises when several transmitting devices from at least partially via multi-hopping data transmission via a gateway to another or from another, eg. Wired network should take place, e.g. the Internet. Since the multihopping transmissions occupy the standard channel, the gateway is not fully utilized. However, the method according to the invention makes it possible to fully utilize the gateway. It is possible that the gateway polls other devices while changing the channel used.

A further advantageous embodiment and further development of the invention consists in that the decision not to use the standard channel for data transmission is based on the type or content of the data to be transmitted. For example, the decision may be based on whether there is video content or audio content. It can also be based on whether these contents are time-critical, such as during telephone calls or videoconferences. It results the advantage that better throughput coupled with lower delay is achievable for data transfers. Particularly advantageous here is that no corresponding identification of the data must be made.

A further advantageous embodiment and further development of the invention consists in that the decision not to use the standard channel for data transmission is based on a QoS request. This has the advantage that QoS requirements can be implemented much better.

A further advantageous embodiment and development of the invention consists in that a decision to change the channel for data transmission based on type or location of at least one of the devices involved. For example. the decision may be based on whether the target device is a device in another network, e.g. on the Internet. The decision can also be based on whether the target device or the transmitting device is, for example, a laptop or a telephone. This has the advantage that targeted data transfers can be preferred and also targeted data transfers can be penalized, both based on the target device. As a result, for example, it can be ensured that a gateway, which provides the connection to the Internet, is sufficiently utilized but also not significantly overloaded.

The invention will be explained in more detail with reference to embodiments shown in the drawing. Showing:

Figure 1 network topology with gateway

The exemplary network N according to FIG. 1 contains a first transmitting device GS1 from which data are transmitted to a gateway G via multihopping via a first intermediate device GZ1. Furthermore, the network N contains a second transmitting device GS2, of which by means of multi-hopping via second intermediate device GZ2 also data are sent to the gateway G. The gateway G is outside the radio range of the two transmitting devices GSL, GS2. The two sending devices GS1, GS2 and the two intermediate devices GZ1, GZ2 are all within the respective radio range of one of the devices GS1, GS2, GZ1, GZ2. The gateway G is connected to the Internet. Furthermore, the network N includes two telephones T1, T2 and a laptop L.

In this example, both sending devices GS1, GS2 want to transfer data to the Internet, that is to say via the gateway G. For the first sending device GS1, in this example, the gateway G decides to keep the default channel SK. So there is no channel change. For the second sending device GS2, the gateway G decides not to use the standard channel SK. In this case, the decision is based on the type of the destination device for data transmission and on the utilization of the gateway. Since the actual destination is outside the network N, in both cases the gateway G is the destination. The intention is to achieve the best possible utilization of the gateway G.

The gateway G therefore searches for an alternative channel AK. Once this is found, the gateway G sends a multicast message to the second devices GS2, GZ2 with the request for a channel change to the alternative channel AK. The two second devices GS2, GZ2 answer this, for example, with "OK", whereupon the gateway G sends a second multicast message with the request to change channels.

The second devices GS2, GZ2 then switch to the alternative channel AK. The first devices GSl, GZl remain on the standard channel SK. The transmission to the gateway G takes place via the respective selected channel, ie via the standard channel SK from the first intermediate device GZ1 and via the alternative channel AK from the second intermediate device GZ2. The gateway G hereby polls the the intermediate devices GZl, GZ2 and switches between the channels back and forth.

The data rate assumed in this example is 54 Mbps according to the 802.11g standard. Since the first and second devices send GS1, GS2, GZ1, GZ2 on different channels, theoretically they could reach the full data rate. In turn, the devices GZ1, GZ2 in between must both transmit and receive, whereby the data rate halves the practically achievable data rate for each of the two data streams.

That is, the achievable data rate on all four radio links is 27 Mbps in this example. These four radio links are between first transmitting and first intermediate device GS1, GZ1, between first intermediate device GZ1 and gateway G, and between second transmitting and second intermediate device GS2, GZ2 and second intermediate device GZ2 and gateway G.

The gateway G thus receives twice 27MBit / s, so a total of 54MBit / s, so is fully utilized. Without the alternative channel AK, all devices GS1, GS2, GZ1, GZ2 would have to share the data rate of 54 Mbit / s and the gateway G would receive only 27 Mbit / s.

After the data transmission from the second transmitting device GS2 via the second intermediate device GZ2 to the gateway G, the second devices GS2, GZ2 switch back to the standard channel SK and thus continue to form a single network N.

In an alternative embodiment, the decision as to whether the standard channel is used for data transmission is based on the type of data transmitted. For voice data, an alternative channel AK is used, while for other transmissions the standard channel SK is used. That the Decisive device here is the respective sending device.

Thus, if a call takes place by means of the two telephones T1, T2 of the network, that is to say a data transmission with voice data, then it is decided not to use the standard channel SK. An alternative channel AK is searched and the telephones involved Tl, T2 switch to this channel. After completion of the conversation, ie the data transmission, both telephones T1, T2 change back to the basic setting, i. on the standard channel SK.

In an alternative embodiment, the decision not to use the default channel SK is based not on the type of data but on a QoS request for the data transfer. In this case, the alternative channel AK is again used for voice data, since a good transmission quality is necessary for this. However, for other data transmissions, too, a channel change comes into question, depending on the required QoS. Video conferencing between the laptop L and the first transmitting device GS1 will also take place on the alternative channel AK.

Claims

claims

1. A method for data transmission in a network with at least two configured for data transmission devices (T1, T2, L, G, GS1, GS2, GZ1, GZ2), which connect in a basic setting via a standard channel (SK) for signaling and data transmission can, characterized in that before the start of a data transmission between at least two participating devices (T1, T2, L, G, GS1, GS2, GZ1, GZ2) the following voting steps are performed,

- Decision not to use the standard channel (SK) for data transmission

- Change the devices involved to an alternative channel (AK), after which the

Data transmission via the alternative channel (AK) and

- a change back to the default setting done.

2. A method for data transmission according to claim 1, characterized in that the data transmission by multi-hopping over at least one intermediate device

(T1, T2, L, G, GS1, GS2, GZ1, GZ2).

3. Method for data transmission according to one of the preceding claims, characterized in that the decision not to use the standard channel (SK) for data transmission is based on the type or content of the data to be transmitted.

A data transmission method according to any one of the preceding claims, characterized in that the decision not to use the standard channel (SK) for data transmission is based on a QoS request.

5. Data transmission method according to one of the preceding claims, characterized in that the decision not to use the standard channel (SK) for data transmission, based on the type or location of at least one of the participating devices (T1, T2, L, G, GS1, GS2, GZ1, GZ2).

6. Device for data transmission in a network with at least two devices configured for data transmission (T1, T2, L, G, GS1, GS2, GZ1, GZ2), which connect in a basic setting via a standard channel (SK) for signaling and data transmission can, according to one of the preceding claims, characterized in that before the start of a data transmission between at least two participating devices (T1, T2, L, G, GS1, GS2, GZ1, GZ2) the following voting steps are feasible,

- Decision not to use the standard channel (SK) for data transmission

- Change the devices involved to an alternative channel (AK), after which the

Data transmission via the alternative channel (AK) and - a change back to the default setting are feasible.