JP2020156084A - Dynamic qos mapping between mapped radio bearers according to urllc tactile feedback use examples - Google Patents

Abstract

To facilitate and provide an on-the-fly required adjustment between QoS flows of a tactile feedback end user platform in a serving RAN.SOLUTION: A method comprises: determining mapping of a first data flow to a second data flow of communication by a network device in a communication network; on the basis of the determination, setting a function for use at arrival time of a data packet of the first data flow in order to derive a temporary change of at least one of service quality parameters set for the second data flow of communication; and transmitting, to the network device in the communication network, an indication of the determined mapping and the set function to be used by the network device in communication.SELECTED DRAWING: Figure 6A

Description

The teachings according to exemplary embodiments of the invention generally relate to improving NR support for URLLC tactile feedback, and more specifically, facilitating on-the-fly coordination between QoS flows of the tactile feedback end-user platform in serving RANs. Regarding the offer.

background

This section is intended to provide the background and context of the invention described herein. The description here may include those that can be patented and have not necessarily been conceptualized or patented. Therefore, unless otherwise stated herein, the content of this section is not prior art to the specification and claims of the present application and is not recognized as prior art by inclusion in this section.

Specific abbreviations that may be used in this specification and drawings are defined below.
AF (Application Function) Application Function AMF (Access and Mobility Management Function) Access Mobility Management Function DL (Downlink) Downlink DRB (Data Radio Bearer) Data Radio Bearer eMBB (enhanced Mobile Broadband) High Speed Large Capacity Mobile Broadband gNB Next Generation Node B Or base station IAS (Industrial Automation System) Industrial Automation System NF (Network Function) Network Function NN (Network Node) Network Node NR (New Radio) New Radio or 5G
PCF (Policy Control Function) Policy Control Function RAN (Radio Access Network) Radio Access Network RB (Radio Bearer) Radio Bearer SMF (Session Management Function) Session Management Function UL (Uplink) Uplink UPF (User Plane Function) User Plane Function URLLC (Ultra Reliable and Low Latency Communication) Highly Reliable Low Latency Communication SDAP (Service Data Adaptation Protocol) Service Data Adaptation Protocol

In today's technological environment surrounding electronic devices, electronic device manufacturers are rushing to create functional interfaces for their users. One of the functional interfaces is realized by utilizing "haptics". Haptics refer to generating haptic feedback from a user when using a user interface (UI) associated with a haptic system that performs signaling that mimics mechanical selection based on the user touching the electronic device.

Description

An exemplary embodiment of the present invention aims to improve the operation of such a tactile system with respect to electronic devices.

According to one embodiment, a method is provided and the method is
Determining the association of the first data flow of communication by a network device in a communication network with the second data flow, and
Based on the determination, upon arrival of the data packet of the first data flow to derive a temporary change of the quality of service parameter set for the second data flow of the communication to at least one parameter. Setting the function to use and
To transmit the determined mapping and the indication of the set function used by the network device in the communication to the network device of the communication network.
including.

According to one embodiment, a method is provided and the method is
Determining the mapping of the first data flow of the communication of the communication network to the second data flow,
Derivation of a temporary change to at least one of the quality of service parameters set for the second data flow of the communication is associated with use upon arrival of the data packet of the first data flow. To make a decision based on the function
Based on the determination, the transient changes to the at least one parameter of at least one resource block mapped to the second data flow of the communication are made to reduce at least the latency of the communication. Applying features and
including.

According to one embodiment, a device is provided and the device is
A means for determining the association of a first data flow of communication by a network device in a communication network with a second data flow, and
Based on the determination, upon arrival of the data packet of the first data flow to derive a temporary change of the quality of service parameter set for the second data flow of the communication to at least one parameter. Means to set the function to use and
Means for transmitting the determined association and the indication of the set function used by the network device in the communication to the network device of the communication network.
To be equipped.

According to one embodiment, a device is provided and the device is
A means of determining the association of a first data flow of communication in a communication network with a second data flow,
Derivation of a temporary change to at least one of the quality of service parameters set for the second data flow of the communication is associated with use upon arrival of the data packet of the first data flow. Means to decide based on the function given,
Based on the determination, the transient changes to the at least one parameter of at least one resource block mapped to the second data flow of the communication are made to reduce at least the latency of the communication. The means to apply the function and
To be equipped.

According to certain embodiments, the first data flow may include a high priority quality of service parameter, the second data flow may have a lower priority quality of service than the service quality parameter of the first data flow. It may include parameters.

According to certain embodiments, the first data flow may include a high-reliability, low-latency communication service quality data flow, and according to one embodiment, the second data flow is a high-speed, high-capacity mobile broadband communication service quality data flow. Alternatively, it may include one of another high-reliability, low-latency communication service quality data flows with different service qualities.

According to certain embodiments, the high-reliability, low-latency communication service quality data flow may include a tactile feedback flow, and according to certain embodiments, the high-speed, high-capacity mobile broadband communication service quality data flow may include a video or audio transmission flow. Including at least one of.

According to certain embodiments, the association may be set according to at least one of a data flow or a packet of the data flow associated with the communication.

According to certain embodiments, the association of the first data flow with the second data flow may be quasi-static depending on the setting of the quality of service flow, or a tactile feedback service quality flow. It may be dynamic depending on the packet of.

According to one embodiment, the at least one parameter of the quality of service parameter set for the second data flow is the quality of service for at least one radio bearer mapped to the second data flow of the communication. It may include parameters.

According to certain embodiments, the function of deriving the temporary change to the quality of service parameter is within a predetermined time interval starting at the time of arrival of a data packet with said first data flow in the network device. It may be set to be used for.

According to certain embodiments, the temporary change may be valid for all data packets in the second data flow.

According to certain embodiments, the function may only be used within the time associated with the timer.

According to certain embodiments, the temporary change to the at least one parameter may include a latency requirement change to the at least one parameter.

According to certain embodiments, the first data flow and the second data flow may belong to different network slices of the communication network.

The aspects, features, and effects of the various embodiments of the present disclosure, such as those described above, will become clearer from the following detailed description with reference to the accompanying drawings. In the drawings, similar reference numerals are used to indicate similar or even elements. The drawings are illustrated to facilitate understanding of the embodiments of the present disclosure and are not necessarily shown to scale.

FIG. 1 shows a high level block diagram of various devices used to carry out various aspects of the present invention.

FIG. 2 shows a method according to an exemplary embodiment of the invention applicable to serving base stations.

FIG. 3 shows another method according to an exemplary embodiment of the present invention.

FIG. 4 shows a message flow for a quality of service flow for changing the wireless bearer flow mapping for a network device such as a base station according to an exemplary embodiment of the present invention.

FIG. 5 shows a message flow for a quality of service flow for changing the wireless bearer flow mapping for a network device such as a user device according to an exemplary embodiment of the present invention.

A method that can be carried out by the apparatus according to the exemplary embodiment of the present invention is shown. A method that can be carried out by the apparatus according to the exemplary embodiment of the present invention is shown.

Detailed explanation

An exemplary embodiment of the invention proposes methods and devices that enable the provision of on-the-fly coordination between QoS flows of a haptic feedback end-user platform in a serving RAN.

Section 5.3 of 3GPP TR 22.862-e10 describes ultra-low latency.

According to the description, various uses of "ultra-low latency" are characterized by ultra-low latency system requirements. It is essential to send messages between senders and receivers at extremely high speed. Data rates can vary depending on the application. For example, it can be low for measurements and control signaling, and can be medium to high for sending video, for example in a virtual environment. Reliability is also important depending on the application. If you need to send information quickly, it is often important to ensure that it arrives.

A typical area where this type of communication is required is the tactile internet. For example, a human operator controls a device to receive both visual and tactile feedback from the manipulated device and its environment. Therefore, the operator feels as if the device is an extension of his arm or eye, as if he were actually in the environment.

Regarding traffic, 3GPP has announced that "extreme realtime communication" will make communication network requirements extremely stringent. The touch internet is an example of ultra-real-time applications. For touch Internet applications, extremely low latency, extremely high reliability, and extremely high security are required.

The following is described as an example of ultra-real-time communication.
・ Completely immersive, proximity cloud virtual reality ・ Remote control of vehicles and robots, and real-time control of flying and driving objects ・ Remote health management, health monitoring, diagnosis, treatment, surgery / education (remote guidance, distance learning, remote control) group work)

It is also stated that the touch internet will make mobile communication networks an extension of the human senses and nervous system. As a human sensory system, latency is required to be milliseconds or less in order to be perceived as an immediate reaction. If the force feedback from the remote-controlled tool is too slow, the tool will be difficult to operate. If visual feedback from a virtual or augmented reality headset is too slow, human operators may experience VR sickness.

An even more important requirement for the Touch Internet is its extremely high reliability. When a human operator operates a device that interacts with its surroundings, it is extremely important that the device is always in full control. Safety is also important. It is necessary to eliminate the possibility of disconnection, modification, and hijacking of the connection by a third party, and to keep the connection state safe without disconnection.

In addition, the following requirements can be considered.
The system provides a one-way delay of 1 ms between mobile devices and devices in the peripheral Internet.
-The system achieves ultra-low latency in one direction at the wireless layer (1ms).
-The system is ultra-reliable.
• The system provides connections that are extremely difficult to block, modify, or hijack.
• The system minimizes the delay required before sending user data (eg, due to signaling, including for security purposes).

Some of these requirements are for drones where communication is established on an event basis, for example.

In order to reduce the delay according to such an application, for example, it is necessary to minimize the man-hours required before the user data can be transmitted.

In the use of related tactile feedback, such as robot-assisted surgery, image-guided robots or "cobots" (collaborative robots) are increasingly being used for a variety of procedures. Furthermore, in the near future, different devices will be required to share the information provided by the robot (actual position, pressure feedback, etc.) synchronized with the video generated from the image source. In order for the surgeon to operate as if he were not assisted by the robot, the movement, sight, and touch between the surgeon and the robot must be perfectly synchronized. This is not possible with the latency and synchronization capabilities of current communication systems.

Tactile feedback usage typically results in high communication traffic flow (including virtual reality audio, video transmission, visual, and tactile feedback) for human users. Such communication traffic flow needs to be delivered to the end-user device after being properly tuned for reliability, latency, and synchronism. However, the discrepancy between visual feedback and background virtual reality video transmission may not be clear. However, it can be expected that visual feedback will be faster and have higher resolution (higher frame rate, more reliable delivery) than background video transmission. That is, it is expected that the QoS requirements for visual feedback data regarding latency and reliability will be stricter than those for background image transmission. In addition, the haptic feedback end-user system is equipped with a number of different microphones and cameras, which can lead to many different QoS flows for audio and video transmission.

The implementation of wireless access of communication traffic flow in the use example of haptic feedback as described above will be considered in relation to 3GPP NR. Here, a human user is referred to as a UE connected to one or more end-user devices such as cameras, sensors, actuators and the like. In this case, each communication traffic flow to the UE may be mapped to the QoS flow of the serving NR network in the DL. Therefore, there can be one or more QoS flows for virtual reality audio and video transmission. This is shown as {q # 1, ..., Q # N}. Further, there may be one or more QoS flows for visual feedback and tactile feedback, which are shown as {b # 1, ..., B # M}. q # is typically characterized as an eMBB with periodic or continuous interaction real-time data. On the other hand, b # is characterized as a URLLC with final interaction ultra-real-time data. Note that the end-user device platform or system may consist of multiple UEs, in which case it may be necessary to coordinate the communication traffic flow to the end-user device platform among all UEs.

Focusing on the serving RAN or gNB, the NR allows the serving gNB to map one or more QoS flows to the RB established and implemented between the serving gNB and the UE. Here, {q # 1, ..., q # N} is mapped to {RB # q1, ..., RB # qK}, and {b # 1, ..., b # M} is {RB # b1, ..., RB. It shall be mapped to # bL}. RB # bi, 1 ≦ i ≦ L may be the same as or different from RB # qj, 1 ≦ j ≦ K. Thus, visual or tactile feedback packets may or may not be mapped to the same RB for virtual reality audio and video transmission.

Required between eMBB QoS flow and URLLC QoS flow, {q # 1, ..., q # N} and {b # 1, ..., b # M} as issues associated with human-related tactile feedback use cases. The relevance cannot be accurately identified. That is, such relationships are relatively variable, depending on the movements, emotions, experiences, or perceptions of the human users involved. As in the surgeon example above, the movement, sight, and touch between the surgeon and the robot must be perfectly synchronized in order for the surgeon to operate as if he were not assisted by the robot. is there. This is not possible with the latency and synchronization capabilities of current communication systems.

Similar requirements may apply to other use cases, such as machine tools that require operator-synchronized video flow and further tactile feedback on material surfaces. The simplest and most reliable way to achieve all the necessary adjustments between the associated QoS flows is to have all the relevant eMBB QoS flows at the same QoS level required by the relevant URLLC QoS flows. Is to correspond to. However, this is the worst situation when it comes to wireless resource consumption and can be unrealizable in serving networks.

According to an exemplary embodiment of the invention, a serving RAN facilitates the necessary adjustments between on-the-fly related QoS flows and at least provides an efficient way to achieve this adjustment.

Before explaining the exemplary embodiments of the present invention in detail, a simplified block diagram of various electronic devices suitable for use in carrying out the exemplary embodiments of the present invention will be described with reference to FIG.

FIG. 1 shows a block diagram of one possible non-limiting exemplary system in which exemplary embodiments of the invention can be implemented. In FIG. 1, the user device (UE) 10 wirelessly communicates with the wireless network 1. A UE is a wireless device, generally a mobile device that has access to a wireless network. The UE 10 comprises one or more processors DP10A, one or more memories MEM10B, and one or more transceivers TRANS10D interconnected via one or more buses. Each one or more transceivers TRANS10D has a receiver and a transmitter, respectively. The one or more buses are addresses, data, or control buses and may include any interconnect mechanism such as a series of lines on a motherboard or integrated circuit, optical fiber, or other optical communication equipment. One or more transceivers TRANS10D are connected to one or more antennas for communication 11 to gNB12 and communication 18 to NN13, respectively. One or more memories MEM10B include the computer program code PROG10C. The UE 10 communicates with the gNB 12 and / or the NN 13 via the wireless link 111.

The gNB 12 (which can be NR / 5G node B or evolved NB) may be a base station such as a master or secondary node base station communicating with a device such as NN13 or UE10 in FIG. 1 (eg, NR or LTE). (For long term evolution). The gNB 12 makes a wireless device such as the UE 10 accessible to the wireless network 1. The gNB 12 comprises one or more processors DP12A, one or more memory MEM12Cs, and one or more transceivers TRANS12D interconnected via one or more buses. According to exemplary embodiments, these TRANS12Ds can include X2 and / or Xn interfaces used to implement exemplary embodiments of the invention. One or more transceivers TRANS12D each have a receiver and a transmitter. One or more transceivers TRANS12D are connected to one or more antennas for communication with UE 10 via at least link 11. The one or more memory MEM12Bs and the computer program code PROG12C are configured by the one or more processors DP12A to perform one or more of the operations described herein on the gNB 12. The gNB 12 may communicate with another device such as gNB or eNB, or NN13. In addition, links 11 and / or other links may be wired, wireless, or both, and may implement X2 or Xn interfaces. Further, the link 11 may be via another network device such as (but not limited to) an NCE / MME / SGW device such as NCE14 in FIG.

The NN 13 can include mobility functional devices such as AMF or SMF, and the NN 13 may include an NR / 5G node B, or in some cases an evolved NB, and a device such as gNB 12 and / or UE 10 and / or a wireless network 1. It may include a base station such as a master or secondary node base station (eg, NR or LTE (Long Term Evolution)) that communicates. The NN 13 comprises one or more processors DP13A, one or more memory MEM13Bs, one or more network interfaces, and one or more transceivers TRANS12D interconnected via one or more buses. According to exemplary embodiments, these network interfaces of NN13 can include X2 and / or Xn interfaces used to implement exemplary embodiments of the invention. Each one or more transceivers TRANS13D has a receiver and a transmitter connected to one or more antennas. One or more memories MEM13B include the computer program code PROG13C. For example, the one or more memory MEM13Bs and the computer program code PROG13C are configured by the one or more processors DP13A to cause the NN13 to perform one or more of the operations described herein. The NN13 may communicate with another mobility function device and / or an eNB such as gNB12 or UE10, or any other device using, for example, link 11 or another link. The link may be wired, wireless, or both, and may implement, for example, an X2 or Xn interface. Further, as described above, the link 11 may be via other network devices such as (but not limited to) NCE / MME / SGW devices such as NCE14 in FIG.

One or more buses of the device of FIG. 1 are addresses, data, or control buses, and any interconnect mechanism such as a series of lines, optical fibers, or other optical communication equipment, wireless channels, etc. on a motherboard or integrated circuit. May include. For example, one or more transceivers TRANS12D, TRANS13D and / or TRANS10D may be implemented as remote radioheads (RRHs), and other elements of gNB may be located physically different from RRHs. In this case, a part of one or more buses 157 may be realized as an optical fiber cable connecting other elements of gNB 12 to RRH.

Note that FIG. 1 shows a network node or base station such as gNB12 shown in FIG. 1 and a mobility management device such as NN13 shown in FIG. 1. These devices are e-node B (for LTE, NR, etc.). eNB) may be incorporated or incorporated therein. Even in that case, it can be set to carry out the exemplary embodiment of the present invention.

Also, although the description herein indicates that a "cell" performs a function, it is clarified that the gNB and / or user equipment and / or mobility management function device that forms the cell performs the function. I want to be understood. In addition, the cells form a part of gNB, and there may be a plurality of cells for each gNB.

The wireless network 1 may include a network control element (NCE) 14, which may include an MME (mobility management entity) / SGW (serving gateway) function, thereby providing a telephone line and / or a data communication network (eg, the Internet). It realizes the connection with another network such as. The gNB 12 and NN 13 are connected to the NCE 14 via the link 13 and / or the link 14. Furthermore, it should be noted that the operation according to the exemplary embodiment of the invention performed by NN13 can be performed similarly by NCE14.

The NCE 14 comprises one or more processors DP14A, one or more memories MEM14B, and one or more network interfaces (N / WI / F), which are one or more connected to links 13 and / or 14. It is interconnected via the bus. According to exemplary embodiments, these network interfaces may include X2 and / or Xn interfaces used to carry out exemplary embodiments of the invention. One or more memories MEM14B includes computer program code PROG14C. The one or more memory MEM14B and the computer program code PROG14C cause the one or more processors DP14A to perform one or more operations necessary for the NCE14 to correspond to the operations according to the exemplary embodiments of the present invention. It is composed of.

The wireless network 1 may realize network virtualization. This is the process of integrating hardware and software network resources and network functionality into a virtual network that is a single software-based management entity. Network virtualization involves platform virtualization, which is often combined with resource virtualization. Network virtualization can be categorized as external (many networks or parts of a network integrated into a virtual unit) or internal (providing network-like functionality to a software container on a single system). Will be done. The virtualized entities obtained by network virtualization are, to some extent, implemented using hardware such as processors DP10, DP12A, DP13A, and / or DP14A and memory MEM10B, MEM12B, MEM13B, and / or MEM14B. Please note that. Such virtualized entities also produce technical effects.

Computer-readable memory MEM12B, MEM13B, and MEM14B are of any type suitable for the technical environment in the field and are removable with semiconductor-based memory devices, flash memory, magnetic memory devices and systems, optical memory devices and systems, fixed memory. It may be realized using any suitable data storage technology such as memory. The computer-readable memories MEM12B, MEM13B, and MEM14B may be means for realizing the storage function. The processors DP10, DP12A, DP13A, and DP14A are of any type suitable for the technical environment in the field and are one or more general purpose computers, dedicated computers, microprocessors, digital signal processors (DSPs), and multi-cores. It may include, but is not limited to, a processor based on the processor architecture. Processors DP10, DP12A, DP13A, and DP14A may be means for performing functions such as controlling UE10, gNB12, NN13, and other functions described herein.

In general, various embodiments of the user device 10 include a smartphone having a wireless communication function, a tablet, a mobile phone such as a personal digital assistant (PDA), a portable computer having a wireless communication function, a digital camera having a wireless communication function, and the like. Imaging devices, gaming devices with wireless communication functions, music storage and playback devices with wireless communication functions, Internet devices that enable wireless Internet access and browsing, tablets with wireless communication functions, and combinations of these functions Can include, but is not limited to, a portable unit or terminal incorporating the.

According to an exemplary embodiment of the invention, the serving RAN facilitates the necessary adjustments between the UE-related QoS flows of the tactile feedback end-user platform on the fly, and an improved way to achieve this adjustment is serving. It is based on the concept that the QoS profile of at least one associated RB and associated QoS settings are temporarily changed when the final haptic feedback packet is present or arrives in the RAN.

The at least one associated RB may be the same as or different from the RB to which the tactile feedback packet or the QoS flow to which it belongs is mapped. This mapping and mapping may vary dynamically on the fly in response to haptic feedback packets. Temporary changes to the QoS profile of at least one associated RB and associated QoS settings are in response to or based on the QoS profile of the QoS flow to which the tactile feedback packet belongs and the associated QoS settings. Temporary changes are in effect over a predetermined time interval, after which they revert to using a preset QoS profile. Depending on the traffic characteristics of the haptic feedback flow, QoS changes or updates may also be performed on a regular basis.

For at least these reasons, the operation of the exemplary embodiment of the invention includes:
-Set a serving RAN for associating a first QoS flow of URLLC (tactile feedback QoS flow) with at least one second QoS flow of eMBB (video / audio transmission flow). This association may be set according to the tactile feedback QoS flow, according to the tactile feedback packet, or both.
When a data packet of the first QoS flow arrives at the serving RAN, a temporary change is derived for at least one QoS parameter set in the RB (referred to as the associated RB) to which the second QoS flow is mapped. To do this, set a serving RAN for the rule or function associated with the association.
When the data packet of the first QoS flow arrives at the serving RAN, the serving RAN determines the association and the temporary change of the associated RB to at least one QoS parameter, and the associated RB Apply this temporary change on the fly for scheduling purposes.

The necessary synchronization between haptic feedback and associated visual feedback or virtual reality video / audio transmission is ensured and provided only as needed. This contributes to the prevention of waste of network resources.

The concept of introducing the operation according to the exemplary embodiment of the present invention has been described by taking URLLC and eMBB as examples. It is clear that this concept is applicable to all types of services with stringent flow synchronization requirements.

FIG. 2 shows one method according to an exemplary embodiment of the present invention applicable to a serving base station apparatus such as a gNB apparatus.

As shown for gNB 205 in FIG. 2, in step 210, from a network control entity (eg, AMF / SMF), gNB 205 has a first QoS flow (tactile feedback QoS flow) of URLLC and at least one second of eMBB. Receives a sign of association with a QoS flow (video / audio transmission flow). This association may be set quasi-statically according to the tactile feedback packet of the first QoS flow, or both, depending on the QoS flow. As shown in step 220 of FIG. 2, when a data packet of the first QoS flow arrives at the gNB, the network control entity (eg, AMF / SMF) maps the second QoS flow to the RB (associated). Receives a rule or function setting used to derive a temporary change to at least one QoS parameter set in (referred to as RB). In step 230 of FIG. 2, the data packet of the first QoS flow is received from the network entity (for example, UPF with / without MEC) regardless of whether or not the association is updated. In step 240 of FIG. 2, in handling the data packet of the second QoS flow mapped to the associated RB, a temporary change to this RB is derived and applied. Next, in step 250 of FIG. 2, the data of the first QoS flow and the second QoS flow is transmitted to the UE.

Some of the operations according to the exemplary embodiments of the present invention include at least:
The data packet of the first QoS flow may be mapped to the associated RB or a different RB.
-Temporary changes to at least one QoS parameter in the associated RB are set to the corresponding parameters set in the first QoS flow, from the time the data packet in the first QoS flow arrives at the serving RAN. Valid over the set time interval to start. This is specified in the configuration rule associated with the mapping.
A temporary change to at least one QoS parameter in the associated RB is set to the corresponding parameter set in the first QoS flow and arrives at the serving RAN before the data packet in the first QoS flow. , Valid for all data packets in the second QoS flow buffered in the serving RAN. This is specified in the configuration rule associated with the mapping.
• At least one QoS parameter relates to latency requirements. This is specified in the configuration rule associated with the mapping.

For exemplary embodiments of the invention, the same mechanism can be applied to the gNB and SDAP layers within the UE as defined in the current 3GPP TS 37.324 in this application.

Examples of the operation for the serving RAN and the like according to the embodiment of the present invention include the following.
-Set the correspondence between the first QoS flow (tactile feedback QoS flow) of URLLC and at least one second QoS flow (video / audio transmission flow) of eMBB in the serving RAN. This association may be set according to the tactile feedback QoS flow, according to the tactile feedback packet, or both.
When a data packet of the first QoS flow arrives at the serving RAN, the rules or functions associated with the mapping are added to the serving RAN (SDAP layer in the gNB) to derive a temporary QoS flow for the DRB mapping of the second QoS flow. ).
-When the data packet of the first QoS flow arrives at the gNB, the serving RAN (SDAP layer in the gNB) is made to determine the association and the temporary change QoS flow for the DRB mapping of the second QoS flow, and the DRB mapping is performed. Apply this temporary QoS flow to.

Further, the operation for the UE and the like according to the exemplary embodiment of the present invention includes at least the following.
-Set the correspondence between the first QoS flow (tactile feedback QoS flow) of URLLC and at least one second QoS flow (video / audio transmission flow) of eMBB in the serving RAN. This association may be set according to the tactile feedback QoS flow, according to the tactile feedback packet, or both.
-When a data packet of the first QoS flow arrives at the UE (SDAP layer), a rule or function associated with the mapping is set in the UE in order to derive a temporary QoS flow for the DRB mapping of the second QoS flow. ..
-When the data packet of the first QoS flow arrives at the gNB, the UE (SDAP layer) is made to determine the mapping and the temporary change QoS flow for the DRB mapping of the second QoS flow, and the DRB mapping is made to make this temporary change. Apply a QoS flow.

The exemplary embodiments of the invention described herein are applicable to network slices. For example:

The first and second QoS flows belong to different slices.

Traffic on one particular QoS flow triggers a change in QoS of the slice. When traffic arrives at the first QoS flow, it triggers a QoS change for slices with a second QoS flow.

Temporary changes to the QoS parameters of a QoS flow for DRB mapping may be time-limited by a timer. The timer starts when the change is applied (packet arrival in the first QoS flow). When the timer expires, the changes return to normal.

FIG. 3 shows a method according to an exemplary embodiment of the present invention. FIG. 3 shows some network signaling procedures according to some aspects of the present invention.

As shown in FIG. 3, signaling is performed between the tactile feedback UE platform 300, the serving gNB305, the AMF / SMF management function device 310, and the user plane function (UPF) 315. As shown in step 317 of FIG. 3, an operation is performed between the tactile feedback UE platform 300, the serving gNB 305, and the AMF / SMF 310, including a QoS flow and RB setting for serving the tactile feedback user. Here, QoS flow # 1 is tactile feedback as URLLC, and QoS flow # 2 is a video stream as eMBB. As shown in step 319 of FIG. 3, the marking of the association between the QoS flows # 1 and # 2 is communicated from the AMF / SMF 310 to the serving gNB 305. In step 320 of FIG. 3, the rule or function setting associated with the marked association in step 319 is communicated from the AMF / SMF 310 to the serving gNB 305. As shown in step 322 of FIG. 3, data about the associated QoS flow is transmitted between the tactile feedback UE platform 300, the serving gNB305, and the UPF315. In step 325 of FIG. 3, packet # 1 of the QoS flow # 2 is communicated from UPF315 to the serving gNB305. In step 330 of FIG. 3, packet # 2 of the QoS flow # 2 is communicated from UPF315 to the serving gNB305. In step 335 of FIG. 3, packet # 1 of the QoS flow # 2 is communicated from the serving gNB 305 to the tactile feedback UE platform 300. In step 340 of FIG. 3, packet # 2 of the QoS flow # 2 is communicated from the serving gNB 305 to the haptic feedback UE platform 300. In step 347 of FIG. 3, tactile commands are communicated from the tactile feedback UE platform 300 to the serving gNB 305. In step 350 of FIG. 3, packet #i (i is an integer) of QoS flow # 2 is communicated from UPF315 to serving gNB305. In step 353 of FIG. 3, the tactile command received by the serving gNB in step 347 is communicated from the serving gNB 305 to the UPF 315. In step 355, the QoS flow # 1 tactile feedback packet is communicated from the UPF315 to the serving gNB305. In step 360, packets # i + 1 of QoS flow # 2 are communicated from UPF315 to serving gNB305. As shown in step 365 of FIG. 3, this operation involves ensuring synchronization between associated QoS flows as needed. As shown in step 370 of FIG. 3, when the serving gNB305 receives the tactile feedback packet of the QoS flow # 1, it is temporary for the QoS process of the QoS flow # 2 to the packet #i of the QoS flow # 2 and the packet # i + 1. Derive and apply changes. In step 375 of FIG. 3, packet # i + 2 of QoS flow # 2 is communicated from UPF315 to serving gNB305. Derived temporary changes to QoS processing of QoS flow # 2 do not apply to packet # i + 2 of QoS flow # 2. Further, for communication between the serving gNB 305 and the tactile feedback UE platform 300, the QoS flow # 1 tactile feedback packet in step 380 of FIG. 3, the QoS flow # 2 packet # i in step 381, and step 383. The QoS flow # 2 packet # i + 1 and the QoS flow # 2 packet # i + 2 in step 385 are included.

The association between the haptic feedback QoS flow and one or more video / audio QoS flows may be quasi-static depending on the settings of the QoS flow, or dynamic depending on the packet of some haptic feedback QoS flow. It may be as described above. If there is only one QoS flow for video / audio transmission, or if the association between the tactile feedback QoS flow and a video / audio QoS flow is fixed, then only quasi-static mapping is required, which is shown in the figure. As shown in 3, it may be set in advance via the C plane and AMF / SMF. There are numerous QoS flows for video / audio transmission, and packets with different haptic feedback QoS flows can be associated with different video / audio QoS flows of a pre-identified subset of all video / audio QoS flows. In that case, it is necessary to dynamically mark the correspondence according to a given haptic feedback packet on the fly. Due to the URLLC nature of haptic feedback, on-the-fly packet-following dynamic mapping marking may be realized with the arrival of haptic feedback packets on the U-plane. For example, the UPF connected to the MEC determines the dynamic mapping of the received tactile feedback packet to the gNB in the serving RAN or control header of the tactile feedback packet, or to the existing protocol header of the tactile feedback packet. The association may be marked for gNB in any other suitable field of. This marking indicates at least the ID of the associated QoS flow (s). Note that the associated QoS flow of haptic feedback packets is one of a limited number of pre-identified subsets of video / audio QoS flows.

Therefore, a short preset index of each associated QoS flow can be used as a unique ID for each associated QoS flow to reduce protocol overhead. In this regard, some of the quasi-static settings of the preset subset and associated QoS flow index via the C plane may be applied prior to the dynamic on-the-fly operation.

Temporary changes in the QoS settings applied to the associated QoS flow or its RB are basically, for example, the associated QoS flow or its which can receive updated processing of the URLLC upon arrival of the tactile feedback packet. Identify the length, amount, or which QoS flow or data packet belonging to that RB can receive it. Individual practical examples of temporary changes are as described above. Further optionally, for example, to refer to, for example, the time when a given haptic feedback packet arrived at the gNB, or in connection with this, to a portion of a preset time offset (s) or to a serving gNB in the window. All packets of the associated QoS flow that arrive may be considered.

FIG. 3 shows an example of network operation in the case of DL data packet. Similarly, this concept is applicable to UL. It is assumed that a video camera and a sensor are provided in a mining tool such as a drill to support tactile feedback. During normal operation, the video stream can be transmitted at low QoS levels. If the operator wants tactile feedback, commands can be used to trigger the mapping process.

TS 23.501 currently defines the following QoS parameters that are specific to individual QoS flows.
・ 5QI, the components are as follows.
Resource type (GBR, deferred critical GBR or non-GBR)
-Priority level-Packet delay tolerance-Packet error rate-Average window (only for GBR and delay critical GBR resource types)
-Maximum data burst amount (only for delayed critical GBR resource types)
・ ARP
・ GFBR (GBR flow only)
・ MFBR (GBR flow only)
-Maximum packet loss rate-UL and DL (GBR flow only)

In addition to the flow-specific parameters described above, the following can also be mentioned.
-UE-AMBR, maximum bit rate specific to UE-Session AMBR, maximum bit rate specific to PDU session

For example, a temporary change to the eMBB flow in terms of packet delay tolerance, ie an update based on a temporary URLLC, is a temporary change in other QoS parameters such as average window, maximum data burst amount, MFBR, maximum packet loss rate, etc. It may need to be tied to a target update.

FIG. 4 shows a message flow for a quality of service flow for changing the wireless bearer flow mapping for a network device such as a base station according to an exemplary embodiment of the present invention. FIG. 4 shows a message flow for QoS flow for changing the DRB mapping of gNB. FIG. 4 further shows an example of implementing a timer used for transient QoS changes / QoS flows for DRB mapping (eg, step 475 of FIG. 4).

As shown in step 420 of FIG. 4, in the QoS flow and DRB settings to be provided to the tactile feedback user, # 1 is the tactile feedback as URLLC and # 2 is the video stream as eMBB (DRB1). DRB2 with improved processing volume and / or delayed latency is set. In step 425 of FIG. 4, the marking of the association between the QoS flows # 1 and # 2 is communicated from the AMF / SMF 410 to the serving gNB 405. In step 435 of FIG. 4, the rule or function setting associated with the association marked in step 425 is communicated from the AMF / SMF 410 to the serving gNB 405. In step 440 of FIG. 4, data about the associated QoS flow is transmitted. In step 445 of FIG. 4, packet # 1 of the QoS flow # 2 is communicated from UPF415 to the serving gNB405. In step 450, packet # 2 of the QoS flow # 2 is communicated from UPF415 to the serving gNB405. In step 455 of FIG. 4, packet # 1 of the QoS flow # 2 relating to DRB1 is communicated from the serving gNB405 to the haptic feedback UE platform 400. In step 460 of FIG. 4, the tactile command QoS flow # 1 is communicated from the tactile feedback UE platform 400 to the serving gNB405. In step 470 of FIG. 4, packet # 1 of the QoS flow # 2 is communicated from the serving gNB 405 to the haptic feedback UE platform 400. As shown in step 475 of FIG. 4, the QoS flow # 1 pause timer is started at the start of the QoS flow # 1 tactile feedback packet. As shown in step 480 of FIG. 4, the application of temporary QoS is stopped at the end point of the pause timer. In step 485 of FIG. 4, packet # 1 of the QoS flow # 2 relating to DRB1 is communicated from the serving gNB405 to the haptic feedback UE platform 400.

FIG. 5 shows a message flow for a quality of service flow for changing the wireless bearer flow mapping for a network device such as a user device according to an exemplary embodiment of the present invention. FIG. 5 shows a message flow for QoS flow for changing the DRB mapping of a network device such as a UE. FIG. 5 further shows an example of implementing a timer used for transient QoS changes / QoS flows for DRB mapping (eg, step 575 of FIG. 5).

As shown in step 520 of FIG. 5, in the QoS flow and DRB settings to be provided to the tactile feedback user, # 1 is the tactile feedback as URLLC and # 2 is the video stream as eMBB (DRB1). DRB2 with improved processing volume and / or delayed latency is set. As shown in step 525 of FIG. 5, the marking of the association between the QoS flows # 1 and # 2 is communicated from the AMF / SMF 510 to the serving gNB 505. In step 535 of FIG. 5, the rule or function setting associated with the association marked in step 525 is communicated from the AMF / SMF 510 to the serving gNB 505. In step 540 of FIG. 5, data about the associated QoS flow is transmitted. In step 545 of FIG. 5, packet # 1 of the QoS flow # 2 is communicated from the video source 500 to the UE 503. In step 550, packet # 1 of the QoS flow # 2 is communicated from UE 503 to the serving gNB 505. In step 555 of FIG. 5, the tactile command QoS flow # 1 is communicated from the serving gNB 505 to the UE 503. As shown in step 560 of FIG. 5, when the UE 503 receives the haptic feedback packet of QoS flow # 1, it derives and applies a temporary change to the QoS processing of QoS flow # 2 (QoS flow # 2 goes to DRB2). Mapped). In step 565 of FIG. 5, packet # 1 of the QoS flow # 2 is communicated from the video source 500 to the UE 503. In step 570 of FIG. 5, packet # 1 of the QoS flow # 2 relating to DRB2 is communicated from UE 503 of FIG. 5 to the serving gNB 505. Further, as shown in step 575 of FIG. 5, at the start of the haptic feedback packet of QoS flow # 1, the pause timer of QoS flow # 1 is started. In step 580 of FIG. 5, the application of temporary QoS is stopped at the end point of the pause timer. In step 585 of FIG. 5, packet # 1 of the QoS flow # 2 is communicated from the video source 500 of FIG. 5 to UE 503. Further, in step 590 of FIG. 5, packet # 1 of the QoS flow # 2 regarding DRB1 is communicated from the serving gNB 505 of FIG. 5 to the UE 503.

At least in FIG. 2, FIG. 3, FIG. 4, and FIG. 5 of the present specification, the step numbers are not limited. In each of FIGS. 2, 3, 4, and 5, the order of steps for performing the operation according to the exemplary embodiment of the present invention may be different from the order of the steps identified by the numbers. However, it is still operational as described herein.

FIG. 6A shows, as a non-limiting example, an operation that can be performed by a device such as a device associated with the UE 10, gNB 12, and / or NN 13 as shown in FIG. As shown in step 610, it is determined to associate the first data flow of communication by the network device (UE 10 and / or gNB 12 shown in FIG. 1) in the communication network (network 1 shown in FIG. 1) with the second data flow. To do. In step 620, based on the determination, the data in the first data flow is derived to derive a temporary change of the quality of service parameter set for the second data flow in the communication to at least one parameter. Set the function to be used when the packet arrives (TRANS13D, MEM13B, PROG13C, and DP13A shown in FIG. 1). Next, in step 630 of FIG. 6A, in the determined association and the communication with respect to the network device (UE10 and / or gNB12 shown in FIG. 1) of the communication network (network 1 shown in FIG. 1). The indication of the configured function used by the network device is transmitted (TRANS13D, MEM13B, PROG13C, and DP13A shown in FIG. 1).

According to an exemplary embodiment of the invention described in the above paragraph, the first data flow includes a high priority quality of service parameter, the second data flow is more than the service quality parameter of the first data flow. Includes low priority quality of service parameters.

According to an exemplary embodiment of the invention described in the above paragraph, the first data flow includes a highly reliable and low latency communication service quality data flow, and the second data flow is a high speed, large capacity mobile broadband communication service quality data flow. Or it includes one of another high-reliability, low-latency communication service quality data flows with different service qualities.

According to an exemplary embodiment of the invention described in the above paragraph, the reliable low latency communication service quality data flow includes a tactile feedback flow and the high speed mass mobile broadband communication service quality data flow is a video or audio transmission flow. Includes at least one of.

According to an exemplary embodiment of the invention described in the paragraph above, the association is set according to at least one of a data flow or a packet of a data flow associated with the communication.

According to an exemplary embodiment of the invention described in the paragraph above, the association of the first data flow with the second data flow may be quasi-static depending on the setting of the quality of service flow. Or it may be dynamic in response to a packet of some tactile feedback service quality flow.

According to an exemplary embodiment of the invention described in the paragraph above, the at least one of the quality of service parameters set for the second data flow is at least mapped to the second data flow of the communication. Includes quality of service parameters for one wireless bearer.

According to an exemplary embodiment of the invention described in the paragraph above, the function of deriving the temporary change to the quality of service parameter is the time of arrival of the data packet with the first data flow in the network device. It is set to be used within a predetermined time interval starting with.

According to the exemplary aspects of the invention described in the paragraph above, the temporary modification is valid for all data packets in the second data flow.

According to the exemplary aspects of the invention described in the paragraph above, the function is used only within the time associated with the timer.

According to the exemplary aspects of the invention described in the paragraph above, the temporary change to the at least one parameter includes a latency requirement change to the at least one parameter.

According to the exemplary aspects of the invention described in the paragraph above, the first data flow and the second data flow belong to different network slices of the communication network.

The non-transitory computer-readable medium (MEM13B shown in FIG. 1) stores a program code (PROG13C shown in FIG. 1), and when the program code is executed by at least one processor (DP13A shown in FIG. 1), the above Perform at least the actions described in the paragraph.

According to an exemplary embodiment of the invention described above, the apparatus is a second of a first data flow of communication by a network device (UE10 and / or gNB12 shown in FIG. 1) in a communication network (network 1 shown in FIG. 1). The means for determining the association of data with the data flow (TRANS13D, MEM13B, PROG13C, and DP13A shown in FIG. 1) are provided. Based on the determination, upon arrival of the data packet of the first data flow to derive a temporary change of the quality of service parameter set for the second data flow of the communication to at least one parameter. Means for setting functions for use (TRANS13D, MEM13B, PROG13C, and DP13A shown in FIG. 1) are provided. Further, the network device (shown in FIG. 1) is associated with the network device (UE10 and / or gNB12 shown in FIG. 1) of the communication network (network 1 shown in FIG. 1) in the determined association and communication. It comprises means (TRANS13D, MEM13B, PROG13C, and DP13A shown in FIG. 1) for transmitting the indication of the set function used by the UE 10 and / or gNB 12).

In an exemplary embodiment of the invention according to the paragraph above, at least the determining, setting, and transmitting means are encoded by a transceiver [TRANS13D], a computer program [PROG13C] executable by at least one processor [DP13A]. Includes a non-temporary computer-readable medium [MEM13B].

FIG. 6B shows, as a non-limiting example, an operation that can be performed by a device such as a device (eg, gNB 12 and / or UE 10 shown in FIG. 1). As shown in step 650 of FIG. 6B, the association of the first data flow of the communication of the communication network with the second data flow is determined. As shown in step 660 of FIG. 6B, deriving a temporary change to at least one of the quality of service parameters set for the second data flow of the communication is the data of the first data flow. Determined based on the associated function for use when the packet arrives. Next, in step 670 of FIG. 6B, the temporary change to the at least one parameter of at least one resource block mapped to the second data flow of the communication is performed to reduce the latency of at least the communication. To reduce, apply the function based on the decision.

According to an exemplary embodiment of the invention described in the above paragraph, the first data flow includes a high priority quality of service parameter, the second data flow is more than the service quality parameter of the first data flow. Includes low priority quality of service parameters.

According to an exemplary embodiment of the invention described in the above paragraph, the first data flow includes a highly reliable and low latency communication service quality data flow, and the second data flow is a high speed, large capacity mobile broadband communication service quality data flow. Or it includes one of another high-reliability, low-latency communication service quality data flows with different service qualities.

According to an exemplary embodiment of the invention described in the above paragraph, the reliable low latency communication service quality data flow includes a tactile feedback flow and the high speed mass mobile broadband communication service quality data flow is a video or audio transmission flow. Includes at least one of.

According to an exemplary embodiment of the invention described in the paragraph above, the association is set according to at least one of a data flow or a packet of a data flow associated with the communication.

According to an exemplary embodiment of the invention described in the paragraph above, the association of the first data flow with the second data flow may be quasi-static depending on the setting of the quality of service flow. Or it may be dynamic in response to a packet of some tactile feedback service quality flow.

According to an exemplary embodiment of the invention described in the paragraph above, the at least one of the quality of service parameters set for the second data flow is at least mapped to the second data flow of the communication. Includes quality of service parameters for one wireless bearer.

According to an exemplary embodiment of the invention described in the paragraph above, the function of deriving the temporary change to the quality of service parameter is the time of arrival of the data packet with the first data flow in the network device. It is set to be used within a predetermined time interval starting with.

According to the exemplary aspects of the invention described in the paragraph above, the temporary modification is valid for all data packets in the second data flow.

According to the exemplary aspects of the invention described in the paragraph above, the function is used only within the time associated with the timer.

According to the exemplary aspects of the invention described in the paragraph above, the temporary change to the at least one parameter includes a latency requirement change to the at least one parameter.

According to the exemplary aspects of the invention described in the paragraph above, the first data flow and the second data flow belong to different network slices of the communication network.

A non-transient computer-readable medium (MEM12B and / or MEM10B shown in FIG. 1) stores a program code (PROG12C and / or PROG10C shown in FIG. 1), which is the program code of at least one processor (DP12A shown in FIG. 1). And / or when performed by DP10A), it performs at least the actions described in the above paragraph.

According to the above-mentioned exemplary embodiment of the present invention, the device is a means for determining the association of the first data flow of the communication of the communication network (network 1 shown in FIG. 1) with the second data flow (FIG. 1). TRANS12D and / or TRANS10D, MEM12B and / or MEM10B, PROG12C and / or 10C, DP12A and / or 10A) shown in the above. To derive a temporary change to at least one of the quality of service parameters set for the second data flow of said communication (TRANS12D and / or TRANS10D, MEM12B and / or MEM10B, PROG12C and shown in FIG. 1). / Or 10C, DP12A and / or 10A), means for determining based on the associated function to be used upon arrival of the data packet of the first data flow (TRANS12D and / or TRANS10D, MEM12B and / Or MEM10B, PROG12C and / or 10C, DP12A and / or 10A). Further, based on the determination, the temporary change to the at least one parameter of at least one resource block mapped to the second data flow of the communication is performed to reduce at least the latency of the communication. The means for applying the above functions (TRANS12D and / or TRANS10D, MEM12B and / or MEM10B, PROG12C and / or 10C, DP12A and / or 10A shown in FIG. 1) are provided.

In an exemplary embodiment of the invention according to the paragraph above, at least the determining and transmitting means are a transceiver [TRANS12D and / or TRANS10D shown in FIG. 1] and at least one processor [DP12A and / or DP10A shown in FIG. 1]. Includes a non-transitory computer-readable medium [MEM12B and / or MEM10B shown in FIG. 1] encoded by a computer program [PROG12C and / or PROG10C shown in FIG. 1] that can be run by.

In general, various embodiments may be implemented in hardware or application-specific circuits, software, logic, or a combination thereof. For example, some aspects may be implemented in hardware and other aspects may be implemented in firmware or software that can be executed by computer devices such as controllers, microprocessors, etc., but the invention is not limited thereto. Various aspects of the invention may be illustrated and described using block diagrams, flowcharts, or other graphical representations. These blocks, devices, systems, technologies, or methods described herein are, by way of non-limiting example, hardware, software, firmware, application-specific circuits and logic, general purpose hardware and controllers, and other computers. It should be understood that it may be implemented in devices, or any combination of these.

Embodiments of the present invention may be implemented in various components such as integrated circuit modules. Much of the design of integrated circuits is a highly automated process. Complex and powerful software tools are available that transform logic-level designs into semiconductor circuit designs for etching and forming on semiconductor substrates.

As used herein, the term "exemplary" may mean "an example, an example, an example." None of the embodiments described herein as "exemplary" are necessarily found to be suitable or advantageous over the other embodiments. All embodiments described in the "Detailed Description" are exemplary embodiments provided for those skilled in the art to manufacture and use the invention, limiting the scope of the invention as defined in the claims. It's not a thing.

The above description, by way of exemplary and non-limiting examples, describes in sufficient detail the best methods and devices currently considered by the inventors to practice the invention. However, reading these statements in conjunction with the accompanying drawings and claims, it will be apparent to those skilled in the art that various modifications and adaptations are possible. Moreover, all and similar variations of these matters taught by the present invention are within the scope of the present invention.

It should be noted that "connected", "combined", or any variation thereof represents any direct or indirect connection or connection of two or more elements, and is "connected" or "connected". Note that it may include the case where there is one or more intermediate elements between the two elements. The connection or connection between these elements can be physical, logical, or a combination thereof. As adopted herein, the two elements use one or more wires, cables, and / or printed electrical connections, or wirelessly, as some non-limiting and non-exhaustive examples. It may be considered "connected" or "coupled" using electromagnetic energies such as those with wavelengths in the frequency domain, microwave domain, and optical (both visible and invisible) domains.

Also, some of the features of the preferred embodiments of the present invention could be advantageously used without the use of other features. Therefore, it should be considered that the above description merely explains the principle of the present invention and does not limit it.

Claims (17)

Determining the association of the first data flow of communication by a network device in a communication network with the second data flow, and
Based on the determination, upon arrival of the data packet of the first data flow to derive a temporary change of the quality of service parameter set for the second data flow of the communication to at least one parameter. Setting the function to use and
To transmit the determined mapping and the indication of the set function used by the network device in the communication to the network device of the communication network.
Including methods. Determining the mapping of the first data flow of the communication of the communication network to the second data flow,
Derivation of a temporary change to at least one of the quality of service parameters set for the second data flow of the communication is associated with use upon arrival of the data packet of the first data flow. To make a decision based on the function
Based on the determination, the transient changes to the at least one parameter of at least one resource block mapped to the second data flow of the communication are made to reduce at least the latency of the communication. Applying features and
Including methods. The first data flow comprises a high priority quality of service parameter, and the second data flow comprises a lower priority quality of service parameter than the service quality parameter of the first data flow. The method according to 2. The first data flow includes a high reliability low latency communication service quality data flow, and the second data flow is a high speed large capacity mobile broadband communication service quality data flow or another high reliability low latency communication service quality with different service qualities. The method of claim 1 or 2, comprising one of the data flows. The method of claim 4, wherein the high-reliability, low-latency communication service quality data flow includes a tactile feedback flow, and the high-speed, high-capacity mobile broadband communication service quality data flow includes at least one of a video or audio transmission flow. The method according to claim 1 or 2, wherein the association is set according to at least one of a data flow or a packet of the data flow associated with the communication. The association of the first data flow with the second data flow may be quasi-static depending on the quality of service setting, or may act in response to a packet of a tactile feedback service quality flow. The method of claim 1 or 2, which may be targeted. Claim that the at least one parameter of the quality of service parameter set for the second data flow includes a quality of service parameter for at least one radio bearer mapped to the second data flow of the communication. The method according to 1 or 2. The function of deriving the temporary change to the quality of service parameter is set to be used within a predetermined time interval starting at the time of arrival of a data packet with said first data flow in the network device. The method according to claim 1 or 2. The method of claim 9, wherein the temporary modification is valid for all data packets in the second data flow. The method of claim 9, wherein the function is used only within the time associated with the timer. The method of claim 1 or 2, wherein the temporary change to the at least one parameter comprises a latency requirement change to the at least one parameter. The method according to claim 1 or 2, wherein the first data flow and the second data flow belong to different network slices of the communication network. A device including a processing means and a memory means, wherein the memory means is configured to cause the device to perform the method according to any one of claims 1 to 13 when executed by the processing means. A device that stores the program instructions that have been made. A computer program comprising program instructions configured to cause the device to perform the method according to any one of claims 1 to 13, when executed by the processing means of the device. A means for determining the association of a first data flow of communication by a network device in a communication network with a second data flow, and
Based on the determination, upon arrival of the data packet of the first data flow to derive a temporary change of the quality of service parameter set for the second data flow of the communication to at least one parameter. Means to set the function to use and
Means for transmitting the determined association and the indication of the set function used by the network device in the communication to the network device of the communication network.
A device that comprises. A means of determining the association of a first data flow of communication in a communication network with a second data flow,
Derivation of a temporary change to at least one of the quality of service parameters set for the second data flow of the communication is associated with use upon arrival of the data packet of the first data flow. Means to decide based on the function given,
Based on the determination, the transient changes to the at least one parameter of at least one resource block mapped to the second data flow of the communication are made to reduce at least the latency of the communication. The means to apply the function and
A device that comprises.