DE102018124691A1 - Master-slave system - Google Patents

Abstract

A master-slave system for communication via a radio link with at least one slave device and one master device is proposed, the slave device and the master device being set up to communicate via the radio link, the master device being set up to transmit the at least one slave device transmission resources allocate the radio link, the master device being set up to define at least one slot list, the slot list defining an allocation of time slots to the at least one slave device, the master device being set up to manage the available transmission resources by means of one or more allocation pages, wherein each allocation page contains a plurality of time slots of the transmission resources, and wherein the master device is set up to define a slot list for each of the one or more allocation pages.

Description

The invention relates to a master-slave system for communication via a radio link. Furthermore, the present invention relates to a motor vehicle, in particular a passenger car, which is a slave device or a master device for communication with a master device or a slave device in such a master-slave system.

In a communication system that uses a radio link to transmit messages or data between different participants, there are usually only limited transmission resources. The dimensions time and frequency are available as transmission resources in such a radio communication system. In order to avoid interference between different participants in the radio communication system, transmission resources are usually assigned exclusively to one participant. When managed by a central facility to which all subscribers have contact, the central facility can statically divide the resources between the radio subscribers.

However, the static allocation of transmission resources is inflexible when there is a change in the topology of the radio communication network. If, for example, individual subscribers join or leave the radio communication network, newly required or freed up transmission resources have to be redistributed. The effort required for this can have adverse effects on the latency and the data rate in the radio communication network.

Furthermore, such a static allocation of transmission resources can in principle also result in interference from radio users with changing, dynamic interference properties. This is the case, for example, in radio systems in which the channel is changed frequently. This includes, for example, a Bluetooth system in which the channel is changed after each channel access. The permanent change of channels can cause interference between the participants. Avoiding such interferences in a static system is difficult and usually results in a severe loss of channel capacity, since the static allocation of resources also takes into account the changing channel access and therefore channel capacities must be kept free for this.

The invention is therefore based on the object of enabling communication between a plurality of subscribers in a communication system, interference between the subscribers being reduced and at the same time increasing the capacity used for the transmission resources.

This object is achieved by a master-slave system for communication via a radio link according to claim 1.

The master-slave system has at least one slave device and one master device which are set up to communicate via the radio link, the master device being set up to allocate transmission resources of the radio link to the at least one slave device.

The proposed master-slave system is set up to change the topology, i. H. to take into account a change in the number of participants and to enable a corresponding dynamic allocation of the transmission resources to the at least one slave device. The master device is therefore set up to manage the existing transmission resources by means of one or more allocation pages. Each allocation page contains a plurality of time slots of the transmission resources.

The transmission resources are understood to mean the total channel capacity, i. H. both the frequency and time channels. The master device is also set up to define a slot list for each of the one or more allocation pages, the slot list defining an allocation of the time slots to the at least one slave device. Since one or more allocation pages can be used, each of the allocation pages can define a different division for one or more slave devices. If the topology of the system changes, for example when new slave devices are added or slave devices leave the system, it is sufficient to adjust only one of the allocation pages in its allocation. The remaining allocation pages can remain unchanged, so that such a change does not affect all participants.

Furthermore, it is possible to add new allocation pages so that the transmission resources are distributed to the slave devices in several steps and can thus be easily adapted to different topologies. In this way, the master-slave system enables a static allocation of the transmission resources to the slave devices by means of the slot lists of each allocation page and a dynamic allocation of the transmission resources to the slave devices by means of the allocation pages themselves.

According to a further embodiment, a plurality of slave devices are assigned to an allocation page and the slot list specifies an orthogonal distribution of the transmission resources among the plurality of slave devices.

Each allocation page can thus be used to distribute the transmission resources over a number of slave devices by assigning different time slots to different slave devices.

At the same time, the transmission resources can be orthogonally divided among the multiple slave devices. In this way, interference between the different slave devices can be reduced even further.

Due to the orthogonal distribution of the transmission resources, these are exclusively assigned to a slave device. As a result, the slave device can independently decide on the access methods to be used for the transmission resources, without this having to be communicated to the master device or other slave devices. This enables the network to be quickly adapted to changing channel properties, which the slave device can utilize by quickly changing the access methods.

According to a further embodiment, the slot list is a blacklist, which is set up to block time slots for the at least one slave device for transmission. The blocking list thus defines the time slots in which a slave device may transmit data or rather may not transmit data. Alternatively, the slot list can be a release list (so-called whitelist), which is set up to release time slots for the at least one slave device for transmission.

The master device can be set up to dynamically adapt the slot list. If the topology of the system changes, i. H. if new slave devices are added or are removed, the slot list, i. H. the allocated time slots are dynamically adapted to the change in the system.

According to a further embodiment, the master device is set up to divide the frequency range of the transmission resources over several allocation pages. Here, one allocation side follows the other over the frequency range, it being possible for the transmission resources to be allocated to a plurality of slave devices by using a plurality of allocation sides.

In one embodiment, the master device can detect a change in the number of slave devices in the master-slave system and, based on the change in the number of slave devices, adapt the distribution of the frequency range of the transmission resources to the allocation sides. Several allocation pages can differ in particular in their associated slot list. Different allocation pages can thus be used in succession, allocating transmission resources to the different slave devices and therefore also differing in their associated slot list. The different allocation pages can be repeated over the frequency range.

It can be taken into account, for example, what priority a slave device has in the master-slave system. Slave devices that transmit critical information, e.g. Security-critical or time-critical data such as telephone data can have a higher priority than slave devices that transmit uncritical information. An allocation side can thus divide the transmission resources among the slave devices in such a way that such requirements are taken into account. The transmission resources can be assigned primarily to slave devices that have a higher priority. Allocation pages that contain transmission resources for slave devices with higher priority can be scheduled more frequently over the frequency range than allocation pages that only supply slave devices with lower priority with transmission resources.

In order to take the priority of the slave devices into account, the master device can be set up to determine a priority of the slave devices and to assign the slave devices to one of the allocation pages based on their respective priority. For example, two different allocation pages can be used, the first allocation page containing slave devices with a higher priority and the second allocation page containing slave devices with a lower priority. Via the frequency range, for example, the allocation side with slave devices with higher priority could be allocated two thirds of the frequency range, whereas the allocation side with slave devices with lower priority could only be allocated one third of the frequency range.

According to a further aspect, a motor vehicle, in particular a passenger car, is proposed. The motor vehicle can represent either the slave device or the master device in a master-slave system as described above. The corresponding master or slave device for communication with the Motor vehicle can be a mobile device, such as a smartphone, tablet PC or the like.

Furthermore, a method for communication between at least one slave device and one master device via a radio link is proposed. The method comprises the following steps: allocating transmission resources of the radio link to the at least one slave device by managing the existing transmission resources by means of one or more allocation pages, each allocation page containing a plurality of time slots of the transmission resources, and a slot list for each of the one or more allocation pages is defined, the slot list defining an allocation of the time slots to the at least one slave device.

The embodiments and features described for the proposed device apply correspondingly to the proposed method.

Furthermore, a computer program product is proposed which has a program code which is designed to cause the method described above to be carried out on a computer.

A computer program product, such as a computer program means, for example as a storage medium, such as Memory card, USB stick, CD-ROM, DVD, or in the form of a downloadable file from a server in a network. This can be done, for example, in a wireless communication network by transmitting a corresponding file with the computer program product or the computer program means.

Further possible implementations of the invention also include combinations of features or embodiments described above or below with reference to the exemplary embodiments that are not explicitly mentioned. The person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the invention.

Further advantages and advantageous embodiments are specified in the description, the drawings and the claims. In particular, the combinations of the features specified in the description and in the drawings are purely exemplary, so that the features can also be present individually or in a different combination.

The invention is to be described in more detail below with reference to exemplary embodiments illustrated in the drawings. The exemplary embodiments and the combinations shown in the exemplary embodiments are purely exemplary and are not intended to define the scope of the invention. This is defined solely by the pending claims.

• 1: ein Master-Slave-System zur Kommunikation über eine Funkverbindung;
• 2: eine erste beispielhafte Allokationsseite zur Zuteilung von Übertragungsressourcen der Funkverbindung;
• 3: eine zweite beispielhafte Allokationsseite zur Zuteilung von Übertragungsressourcen der Funkverbindung;
• 4: eine erste beispielhafte Aufteilung des Frequenzbereichs der Übertragungsressourcen auf Allokationsseiten;
• 5: eine zweite beispielhafte Aufteilung des Frequenzbereichs der Übertragungsressourcen auf Allokationsseiten; und
• 6: eine dritte beispielhafte Aufteilung des Frequenzbereichs der Übertragungsressourcen auf Allokationsseiten.

Show it:

• 1 : a master-slave system for communication via a radio link;
• 2nd : a first exemplary allocation page for the allocation of transmission resources of the radio link;
• 3rd : a second exemplary allocation page for the allocation of transmission resources of the radio connection;
• 4th : a first exemplary division of the frequency range of the transmission resources on allocation pages;
• 5 : a second exemplary division of the frequency range of the transmission resources on allocation pages; and
• 6 : a third exemplary division of the frequency range of the transmission resources on allocation pages.

In the following, identical or functionally equivalent elements are identified with the same reference symbols.

1 shows a master-slave system 100 with a master institution 20th and two slave devices 22 , 24th that can communicate over a radio link. The radio connection can be, for example, a Bluetooth connection or an ultra-wideband connection. Other types of radio connections are also possible.

The transmission resources of the radio link can by the master device 20th to the slave devices 22 , 24th be divided. In particular, the time and frequency can be divided. This division is static in previous systems. A change in the topology of the system, ie when new slave devices 22 , 24th add or slave devices 22 , 24th In previous systems, this meant that a complete reallocation of the transmission resources was necessary. However, this can lead to adverse effects on latency and data rate.

To avoid this and to allow a dynamic adjustment of the allocation of transmission resources when the number of slave devices 22 , 24th changes, is the master institution 20th set up to allocate the Adapt transmission resources dynamically accordingly. For this, one or more allocation pages 26 used as in 2nd and 3rd are shown. Each of the allocation pages has a plurality of time slots 0-19 based on one or more slave devices 22 , 24th can be divided.

The allocation pages 26 enable a mix of static and dynamic resource distribution, as explained in more detail below. The content of each allocation page 26 itself microscopically describes the detailed allocation of transmission resources to one or more slave devices 22 , 24th . In particular, the microscopic division allows the selection or blocking of individual time slots 0-19 for individual slave devices 22 , 24th by means of a slot list, which is shown in the following figures as an example of a blocking list, in which time slots are blocked for transmission. Alternatively, the slot list can also be designed as a release list that releases time slots for transmission.

In 2nd are the time slots, for example 4th , 16 and 18th for a slave device 22 locked, which means that the slave device 22 may be broadcast in all other time slots. Are multiple slave devices 22 , 24th a single allocation page 26 assigned, the blacklist can be used to split the time slots and also use an orthogonal split of the channels.

This is in 3rd shown, the slave device 22 the time slots 0-9 are released for transmission, whereas the time slots 10-19 are blocked for transmission. The slave device 24th in return are the time slots 10-19 released for transmission, whereas the time slots 0-9 are locked. This division of the time slots 0-19 a block list can be viewed as a static distribution of the transmission resources.

Various allocation pages can be used to enable dynamic allocation of the transmission resources 26 , 28 , 30th can be used, as exemplified in 4th - 6 is shown. The different allocation pages 26 , 28 , 30th can differ by their respective blacklist. For example, the allocation page 26 two slave devices 22 , 24th allocated, whereas the allocation side 28 and the allocation side 30th additional slave devices (not shown) are allocated.

In 4th will only be an allocation page 26 used, which therefore occupies the entire frequency range. Become two different allocation pages 26 , 28 used as it is in 5 is shown, these can be based on a priority of the respectively assigned slave devices 22 , 24th be distributed over the frequency range. In 5 the two allocation sides are examples 26 , 28 evenly distributed over the frequency range.

In 6 are the allocation side 26 Slave devices 22 , 24th assigned with higher priority than the allocation pages 28 , 30th . To the transmission in the slave devices 22 , 24th Ensuring with higher priority and treating them with priority is the allocation side 26 half of the frequency range 26 allocated, whereas the allocation pages 28 , 30th need to share the other half of the frequency range.

The allocation of the frequency range to the different allocation pages can be adjusted as required. In particular, the distribution of the frequency range on the allocation sides 26 , 28 , 30th dynamically adaptable if one or more slave devices 22 , 24th join or drop out of the system. In this case, additional allocation pages 26 , 28 , 30th add or allocation pages 26 , 28 , 30th fall away.

Since only the frequency range is divided differently, an adjustment of the static division of the time slots, as in 2nd and 3rd shown is not required. In this way, the necessary adaptation of the transmission resources for the various slave devices 22 , 24th and thus interference during transmission can be minimized.

By using the master-slave system described above, central control of a radio communication system is made possible, in which a simple reallocation of transmission resources is possible when individual participants, in particular slave devices, enter, leave or change configuration. In particular, the content of each allocation page can be changed or, depending on requirements, new allocation pages can be added or allocation pages can be removed. If a change is made to an allocation page, i. H. a slot list, e.g. a blacklist, adjusted, only changes the configuration of individual participants, i. H. the slave devices assigned to the respective allocation page. However, this has no effect on slave devices that are assigned to other allocation pages. In this way, both a static (within an allocation page) and a dynamic (adaptation of the allocation pages) adaptation of a radio communication system to a change in the topology is possible.

Reference list

0-19

Time slots

20th

Master institution

22

Slave device

24th

Slave device

26

Allocation page

28

Allocation page

30th

Allocation page

100

Master-slave system

Claims (10)

Master-slave system (100) for communication via a radio link, with at least one slave device (22, 24) and one master device (20), the slave device (22, 24) and the master device (20) being set up via the Communicate radio connection, the master device (20) being set up to allocate transmission resources of the radio connection to the at least one slave device (22, 24), the master device (20) being set up to define at least one slot list, the slot list being an assignment of Defines time slots for the at least one slave device (22, 24), characterized in that the master device (20) is set up to manage the available transmission resources by means of one or more allocation pages (26, 28, 30), each allocation page (26, 28, 30) contains a plurality of time slots (0, ..., 19) of the transmission resources, and wherein the master device (20) d is set up to define a slot list for each of the one or more allocation pages (26, 28, 30). Master-slave system according to Claim 1 , characterized in that several slave devices (22, 24) are assigned to an allocation page (26, 28, 30) and that the slot list defines an orthogonal distribution of the transmission resources among the several slave devices (22, 24). Master-slave system according to Claim 1 or 2nd , characterized in that the slot list is a blocking list which is designed to block time slots (0, ..., 19) for the at least one slave device (22, 24) for transmission. Master-slave system according to one of the preceding claims, characterized in that the master device (20) is set up to dynamically adapt the slot list. Master-slave system according to one of the preceding claims, characterized in that the master device (20) is set up to divide the frequency range of the transmission resources over several allocation pages (26, 28, 30). Master-slave system according to Claim 5 , characterized in that the master device (20) is set up to recognize a change in the number of slave devices (22, 24) in the master-slave system (100) and based on the change in the number of slave devices (22, 24 ) to adapt the distribution of the frequency range to the allocation pages (26, 28, 30). Master-slave system according to Claim 5 or 6 , characterized in that the several allocation pages (26, 28, 30) differ in their associated slot list. Master-slave system according to one Claims 5 to 7 , characterized in that the multiple allocation pages (26, 28, 30) repeat over the frequency range. Master-slave system according to one of the Claims 5 to 8th , characterized in that the master device (20) is set up to determine a priority of the at least one slave device (22, 24) and the at least one slave device (22, 24) based on the priority of one of the allocation pages (26, 28, 30 ) assign. Motor vehicle, in particular a passenger car, which has a slave device (22, 24) or a master device (20) for communication with a master device (20) or a slave device (22, 24) in a master-slave system (100) according to one of the preceding claims is.

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