DE112016007271T5 - RADIO ACCESS NETWORK AS A SERVICE FOR A WIRELESS NETWORK - Google Patents

Abstract

Certain embodiments described herein provide an electronic device that may be configured to identify a resource packet, wherein the resource packet includes standardized functions for use in communication in a radio access network. The identified resource bundle with one or more APIs to create a customized resource bundle, wherein the customized resource bundle includes customized functions for use in communication on a radio access network for a customized service, wherein the customized resource bundle is communicated on the network as a standardized packet. In one example, the custom resource pack includes a standard API and an override API, and the standard API follows standardized procedures to implement RAN services while the override API triggers non-standard handling to implement the RAN services.

Description

TECHNICAL PART

This disclosure relates generally to the field of calculation, and more particularly to a radio access network as a service for a wireless network.

GENERAL PRIOR ART

A radio access network (RAN) may be between a device such as a mobile phone, a computer, or an externally controlled machine and may provide a connection with other devices. RAN allows devices to wirelessly connect to a backbone or core network that transmits over the public switched telephone network (PSTN) or other infrastructure. The RAN receives a signal and data to and from a wireless endpoint, and data from the RAN can run on different traffic over different networks. Some types of RANs include a Universal Terrestrial Radio Access Network (UTRAN) and developed UTRAN (E-UTRAN) that often connect endpoints to the common platforms of the PSTN. Sometimes a custom use case for communication in the RAN is desired, and while some standards provide some customized use cases, not all use cases can address because the number and size of custom use cases can be large and standardization is limited.

list of figures

• 1 ein vereinfachtes Blockdiagramm eines Kommunikationssystems für ein Funkzugangsnetz als Dienst für ein Drahtlosnetz nach einer Ausführungsform der vorliegenden Offenbarung ist;
• 2 ein vereinfachtes Blockdiagramm, das Beispieldetails illustriert, die mit einem Kommunikationssystem für ein Funkzugangsnetz als Dienst für ein Drahtlosnetz nach einer Ausführungsform der vorliegenden Offenbarung assoziiert sind, ist;
• 3 ein vereinfachtes Blockdiagramm, das Beispieldetails illustriert, die mit einem Kommunikationssystem für ein Funkzugangsnetz als Dienst für ein Drahtlosnetz nach einer Ausführungsform der vorliegenden Offenbarung assoziiert sind, ist;
• 4 ein vereinfachtes Blockdiagramm, das Beispieldetails illustriert, die mit einem Kommunikationssystem für ein Funkzugangsnetz als Dienst für ein Drahtlosnetz nach einer Ausführungsform der vorliegenden Offenbarung assoziiert sind, ist;
• 5 ein vereinfachtes Blockdiagramm, das Beispieldetails illustriert, die mit einem Kommunikationssystem für ein Funkzugangsnetz als Dienst für ein Drahtlosnetz nach einer Ausführungsform der vorliegenden Offenbarung assoziiert sind, ist;
• 6 ein vereinfachtes Blockdiagramm, das Beispieldetails illustriert, die mit einem Kommunikationssystem für ein Funkzugangsnetz als Dienst für ein Drahtlosnetz nach einer Ausführungsform der vorliegenden Offenbarung assoziiert sind, ist;
• 7 ein vereinfachtes Blockdiagramm, das Beispieldetails illustriert, die mit einem Kommunikationssystem für ein Funkzugangsnetz als Dienst für ein Drahtlosnetz nach einer Ausführungsform der vorliegenden Offenbarung assoziiert sind, ist; und
• 8 ein vereinfachtes Blockdiagramm, das Beispieldetails illustriert, die mit einem Kommunikationssystem für ein Funkzugangsnetz als Dienst für ein Drahtlosnetz nach einer Ausführungsform der vorliegenden Offenbarung assoziiert sind, ist.

For a more complete understanding of the present disclosure and the features and advantages thereof, reference is had to the following description, taken in conjunction with the accompanying drawings, wherein like reference numerals represent like parts, wherein:

• 1 10 is a simplified block diagram of a communication system for a radio access network as a service for a wireless network according to an embodiment of the present disclosure;
• 2 a simplified block diagram illustrating example details associated with a communication system for a radio access network as a service for a wireless network according to an embodiment of the present disclosure is;
• 3 a simplified block diagram illustrating example details associated with a communication system for a radio access network as a service for a wireless network according to an embodiment of the present disclosure is;
• 4 a simplified block diagram illustrating example details associated with a communication system for a radio access network as a service for a wireless network according to an embodiment of the present disclosure is;
• 5 a simplified block diagram illustrating example details associated with a communication system for a radio access network as a service for a wireless network according to an embodiment of the present disclosure is;
• 6 a simplified block diagram illustrating example details associated with a communication system for a radio access network as a service for a wireless network according to an embodiment of the present disclosure is;
• 7 a simplified block diagram illustrating example details associated with a communication system for a radio access network as a service for a wireless network according to an embodiment of the present disclosure is; and
• 8th a simplified block diagram illustrating example details associated with a communication system for a radio access network as a service for a wireless network according to an embodiment of the present disclosure is.

The FIGURES of the drawings are not necessarily drawn to scale, the dimensions may be varied widely without departing from the scope of the present disclosure.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

EXEMPLARY EMBODIMENTS

The following detailed description sets forth exemplary embodiments of apparatus, methods, and systems related to a communication system to enable the radio access network as a service for a wireless network. Features such as structure (s), function (s), and / or property (s) are described, for example, for reasons of practicability with reference to an embodiment; Various embodiments may be practiced with any suitable one or more of the described features.

1 a simplified block diagram of a communication system 100 to use a radio access network as a service (RANaas) for a wireless network according to an embodiment of the present disclosure; The communication system 100 can a network 180 , one or more electronic devices 184 , and one or more secondary networks 184 contain. The network 180 can be a control node 102 and / or one or more developed nodes Bs (eNBs) 104 contain. The control node 102 and everybody eNB 104 can be a RANaaS engine 106 contain. The RANaaS engine 106 can be a selective API engine 108 , an allocating radio resource engine 110 and an associate processing resource engine 112 contain.

In one example, only the control node contains 102 a RANaaS engine 106 , In other examples, only one eNB contains 104 the RANaaS engine 106 , the control node 102 and one or more eNBs 104 contain the RANaaS engine 106 , or any other combination of them. The RANaaS engine 106 may ring in an existing network infrastructure node (eg, an eNB in a Long-Term Evolution (LTE) system) or in another network node that contains a control interface in a network infrastructure. Furthermore, other network elements that perform the function of the RANaaS engine 106 and the operations disclosed herein provide a RANaaS engine 106 are included and fall within the scope of this disclosure.

Elements off 1 may be coupled to others through one or more interfaces employing any suitable connections (wired or wireless) that provide useable ways for network communication. Furthermore, each can have one or more of these elements 1 combined or removed from the architecture based on specific configuration needs. The communication system 100 may include a configuration capable of implementing Transmission Control Protocol / Internet Protocol (TCP / IP) communication for transmission or reception of packets in a network. The communication system 100 may also function in conjunction with a user data protocol (IP) or other appropriate protocol, if appropriate and based on a particular need.

In one example, the communication system 100 configured to identify a resource packet (or a common resource packet), the resource packet providing standardized functions for use in a network, and modifying the resource packet with one or more predefined application program interfaces (APIs) on a radio access network functional element to provide a customized resource packet; wherein the customized resource packet is transmitted on the network as a standardized packet. In one example, the resource package may be identified from a standardized resource pool. The term "resource package" includes an industry standard package or standardized package of standardized functions for monitoring or managing activities and data in a network, such as a RAN network. The term "standardized resource pool" encompasses a pool or a group of resource packages. The term "standardized functions" includes general functions that have been approved or standardized by a group that governs a network or network protocol. The term "customized resource package" and "custom package" includes a package that has been modified by a resource package.

In one example, the network may be associated with a radio access network as a service. In yet another example, the adjusted resource packet may include one or more allocated radio resources and one or more allocated processing resources. Furthermore, the communication system 100 be configured to control the properties of the one or more allocated radio resources and the one or more allocated processing resources. In some implementations, the custom resource bundle includes executable APIs. In addition, the customized resource pack can be used with massive machine type communications or critical machine type communications or ultrarobuster Low-latency communication (URLLC). In one instance, the custom resource pack allocates a processing resource from a standardized resource pool containing a network function virtualization processor / spoke / interface pool. In another instance, the processing resource may include a radio resource from an air interface pool. Furthermore, the allocated resource bundle's allocated processing may be independent of the processing of other customized resource bundles.

For the purpose of illustrating certain example techniques of the communication system 100 It is important to understand the communication that can go through the network environment. The following basic information may be considered as a basis from which the present disclosure may be properly explained.

End users have more communication choices than ever before. A number of any of the technical trends are currently available (eg, more computing devices, more connected devices, etc.). A current trend is the opening up of network function programmability for the application user. For example, the opening up of network utility programability for application users is becoming an important trend in 5G wireless network system architecture development, requiring traditional telecom traders offering simple traffic tunnels to become modern telecommunications providers offering various composite services. In this way, the wireless network can not only provide traditional mobile broadband coverage to consumers and end users, but also provide customized RAN features for vertical industrial application users. The net function programmability only applies to stack layers that are higher than the network layer and the transport layer, such as the TCP / IP protocol layer. By using the API on these layers, a number of customized services can be provided in different areas, such as video, social networking, cloud computing, etc.

However, there are other types of custom RAN use cases of vertical industries that can not be supported by the programmability of these high-level APIs. These use cases require the possibility of adaptation in the RAN protocol stack locations that are lower than the network location and transport location (eg physical location, medium access control (MAC) location, RRC locations, etc.). These use cases may include the need for ultrashort latencies or ultrahigh robustness for data transmission to support a particular channel environment, such as ultra-low SINR, high speed to support ultra-long battery life, for private control of an information element with a latency of about 10us or 100us , for a private multi-access mechanism or send mechanism, for a private packet sorting function and retransmission mechanism, for a private ciphering algorithm, etc.

Some of the use cases are targeted by the 5G standard, but because the number and size of custom use cases can be high and standardization has a limited scope, others do not. Further, even if some customized use cases can be supported by new standards, the long standardization process can greatly slow down the time to market for new services, thereby affecting the application users of these services. Therefore, instead of creating a new standard for new use cases, it is necessary to open the RAN protocol stack tag programmability to the application users within the framework of current standards. As a result, users do not have to wait for the new standard to complete to meet their application needs. Furthermore, users do not even have to bring their private use cases into the standardization scope. In a 5G environment, telecom operators, who could provide such rapid non-standard RANaaS capability, could be a major competitive advantage in the vertical industry markets.

A communication system that RANaaS can provide for a wireless network, as in 1 described, can solve these problems (and others). In one example, the communication system 100 be configured to provide RANaaS for a wireless network. The term "RAN as a service" or "RANaaS" may include RAN function programmability to provide an application service or services. In one example, the RANaaS may be implemented to provide custom use cases to RAN application users, and configured to allocate a particular radio resource from an air interface pool that has or contains characteristics of distinctness and integration. Further, RANaaS may allow the allocation of a specific processing resource from the network function virtualization (NFV) processor / storage / interface pool in a manner that allocates the allocated processing resource for a custom use case either independently or with the use case adapted for others. Furthermore, RANaaS can select a number of predefined APIs on the Allow RAN function elements that may or may not follow the standardized procedures and behaviors to add the custom RAN functions to the RAN system by executing the selected preconfigured API on the allocated radio resource and allocated processing resource, as well as other customized ones use cases.

As explained above, the known solutions that can support customized vertical industry use cases to RAN functions must first create a new RAN standard and then develop RAN functions based on the standard. The problem with this solution is that, due to the limited scope of standardization, it can not cover all types of custom use cases and can not complete the standard process in a short enough time to meet some customer demands. In comparison, the communication system 100 be configured to provide a generic RANaaS solution that can employ programmability for application users within the current standard or networks currently in use, as well as in undeveloped networks. Using communication system 100 It may not be necessary to use standardization efforts and the requirement for adjusted use cases can be met in a timely manner. Furthermore, the communication system 100 be configured to provide a RANaaS architecture that operates on the currently deployed network without impacting the normal standardized operation. Furthermore, the communication system allows 100 a general feasibility of various RAN systems, including 2G / 3G / 4G and WiFi. In an exemplary implementation, the communication system 100 be configured to control the properties of the allocated radio resource and processing resource and provide a list of fully covered executable APIs as well as provide new solutions for massive machine type communication (MTC) or critical MTC scenarios. Compared with the concept of Mobile Edge Computing (MEC), which typically follows the standardized RAN air interface format, the communication system 100 allow a non-standard RAN air interface format in the allocated radio resources that allows a greater variety of customized functions.

In a specific exemplary implementation, a resource package can be allocated or identified. For example, the RANaaS engine 106 be configured to allocate or identify a resource packet. The term "resource package" includes an industry standard package or standardized package of standardized functions for monitoring or managing activities and data in a network, such as a RAN network. The term "standardized functions" includes general functions that have been approved or standardized by a group that governs a network or network protocol. In one example, the resource pack may be allocated or identified from a standardized resource pool. The term "standardized resource pool" encompasses a pool or a group of resource packages.

A resource packet may include a radio resource section and a processing resource section. The radio resource section obtained by allocating the radio resource engine 110 may be a number or percentage of the bandwidth, subcarriers, physical resource blocks (PRB), signaling or data radio bearers (SRB or DRB), etc., and these resources have the property of distinctness (e.g. adjusted resource use is separable from the resource used by other custom use cases). In other words, the operations on these resources should or will not affect operations on other resources.

The processing resource section created by allocating the processing resource engine 112 may be a calculation amount, signaling amount, amount of memory, etc. The resource packet may also include an integration property if the radio resource portion and the processing resource portion within a resource packet are combined and sufficient to provide a desired customized use case without the need to implement or process resource packets of other custom use cases. In an exemplary implementation, if necessary, a user of system 100 (eg, an administrator) first apply for a license of a regular or custom resource pack or API, and that license may be charged by telecommunications operators with the contents of the resource pack or API.

The opened resource package or API can be selected by selecting the API Engine 108 used to implement unique adjusted use cases based on the allocated resource package. The adjusted cases used can be categorized into two types. The first is a standard API that consistently follows current standards and uses the standardized method to implement RAN services. The term "current standards" and "standardized method" include the standards or Procedures for processing or performing standardized functions approved or standardized by a group regulating a network or network protocol. The second is an overriding API that allows non-standard handling, similar to using a private physical channel encoding or private RRC message to implement RAN services. User equipment that supports such RAN services may also have non-standard special handling. In some cases, the API operations may be restricted with some public rules (eg, with limited overall transmission power on eNB or the transmission power of each antenna should be identical). The API can have the properties of manageability so that the behavior of the API can be observed and its consequence anticipated or expected.

The APIs may program the functions in Physical (PHY), Medium Access Control (MAC), Radio Link Control (RLC), Packet Data Convergence Protocol (PDCP), Radio Resource Control (RRC), or other locations. Furthermore, different APIs could be used simultaneously to complete a custom use case. In one example, the custom use case may be configured to call APIs to program functions at PHY, MAC, or RRC levels and to reuse the functions in other logging locations.

In a specific example, a custom use case may be implemented by calling a selective set of APIs based on a resource packet. The APIs could be reused through various custom use cases, but a resource bundle can serve a unique, customized use case. For example, an adjusted use case 1 the APIs 1 . 2 and 3 call and resource pack 1 apply the custom use case 2 can the APIs 2 . 3 and 5 call and resource pack 2 apply the custom use case 3 can the APIs 1 . 4 and 5 call and the resource pack 3 apply etc.

In another example, a desired custom use case may be used to transmit data in LTE systems with a latency that may be as low as 100us. This is necessary through vertical industrial services such as vehicle-to-vehicle communication, remote operations, industrial control and so on. In a specific implementation, a resource package can be provided by the RANaaS engine 106 be allocated. During allocation of the resource packet, a radio resource may include a number of PRBs in a shared physical downlink channel (PDSCH) and a shared physical uplink channel (PUSCH), and a certain amount of processing resources may be involved in the processing of the resource packet. The assigned PRBs may be fixed or dynamic as indicated by PDCCH. If the associated PRBs are dynamic, the resource packet may be a certain percentage of resources of PRB. In this illustrative example, four groups of APIs can be called. It should be noted that the names of the APIs are for example purposes and other names or terms may be used without departing from the scope of this disclosure. SIGNALING_DL_RRC and SIGNALING_UL_RRC can be used to set up the configuration with user equipment for a customized service, such as by displaying the particular radio resource. SIGNALING DL MAC and SIGNALINGULMAC can be used to quickly indicate that a switch is on or off for a special transmit mode, or for a special status indicator used for uplink (UL) scheduling. DATA_TRANSFER_DL_PHY and DATA_TRANSFER_UL_PHY can be used to allow special transfer mode processing and resource allocation on a particular PDSCH and PUSCH. SCHEDULING DL MAC and SCHEDULINGULMAC can be used to schedule the radio resource and determine the transport format of the allocated PDSCH / PUSCH.

When the user acquires the license for this resource bundle, the system can call the APIs as needed to implement the desired custom use case of transferring data with a latency of only 100us within LTE systems. In an exemplary embodiment of this customized use case, the network configures user equipment for the configuration of the particular radio resource (e.g., PRB Location) and the parameters of the particular transmission mode (e.g., code rate, modulation mode, MI-MO mode, etc.) Call the APIs SIGNALING_DL_RRC and SIG-NALlNG_UL_RRC. The network causes the user equipment to switch the special transmission mode on the special radio resource by calling the APIs SIGNALING_DL_MAC and SIGNALING_UL_MAC on or off. When the transmission mode is switched off, the network could use a normal transmission mode to communicate with the user equipment. The network schedules by calling the APIs SCHEDULING DL MAC and SCHEDULINGULMAC and performs a data transmission with the special transmission mode by calling the APIs DATA_TRANSFER_DL_PHY and DATA_TRANSFER_UL_PHY in each OFDM symbol within PDSCH and PUSCH.

For massive MTC, another example can be used to implement a customized use case for massive MTCs. In this example, a desired adjusted use case may be for transmission of data over long distances, which is greater than the usual coverage of the LTE cells. This is required by vertical industrial services, such as live power / water sensing, environmental monitoring, and signal detection, etc. Since the UL transmit power at the user equipment is often limited, the critical issue with this adjusted usage is the expansion of the available distance of UL data transmission but not that of a downlink (DL) data transfer. It should be noted that the DL transmission power is not restricted on an eNB. In a specific implementation, a resource package is allocated (eg by the RANaaS engine 106 ). During the allocation of the resource packet, a radio resource containing a number of PRBs in PUSCH (e.g., as by the allocating radio resource engine 110 allocated) and a certain amount of processing resources (e.g., as by the allocating processing resource engine 112 allocated) to the resource package. In this illustrative example, four sets of APIs can be invoked for this custom use case. It should be noted that the names of the APIs are for example purposes and other names or terms may be used without departing from the scope of this disclosure. SIGNALING_DL_RRC and SIGNALING_UL_RRC can be used to set up the configuration with user equipment for a customized service, such as by displaying the particular radio resource. SIGNALING DL MAC and SIGNALINGULMAC can be used for quick indication of on or off of a special transmission mode or for a special status display used for uplink (UL) planning. DATA_TRANSFER_UL_PHY can be used for special transfer mode processing and resource allocation on the specific PUSCH. SCHEDULING UL MAC can be used to schedule the radio resource and determine the transport format of the allocated PUSCH.

If a resource bundle license has been purchased, the system can call the APIs as needed to implement the desired custom use case for massive MTCs. In an exemplary embodiment of the adjusted usage case, the network communicates data to the user equipment by the configuration of certain radio resources (eg, PRB Location) and the parameters of the particular transmission mode (eg, code rate, modulation mode, MIMO mode, etc.) Call the APIs SIGNALING_DL_RRC and SIGNALING_UL_RRC. The network causes the user equipment to switch the special transmission mode on the special radio resource by calling the APIs SIGNALING_DL_MAC and SIGNALING_UL_MAC on or off. When the transmission mode is switched off, the network could use a normal transmission mode to communicate with user equipment. The network performs the scheduling by calling API SCHEDULING_UL_MAC and performs a data transmission with the special transmission mode by calling the API DATA_TRANSFER_UL_PHY.

With a view to the infrastructure 1 is a communication system 100 illustrated according to an exemplary embodiment. Generally, the communication system 100 be implemented in any kind or topology of a network. network 180 represent a series of points or nodes of connected communication paths to receive and send information packets through the communication system 100 to get redirected. network 180 Provides a communicative interface between nodes and can be considered any Local Area Network (LAN), Virtual Local Area Network (VLAN), Wide Area Network (WAN), Wireless Local Area Network (WLAN), Metropolitan Area Network (MAN), Intranet, Extranet Virtual Private Network (VPN) and any other suitable architecture or system that enables communication in a network environment, or any other suitable combination thereof, including wired and / or wireless communication.

In communication system 100 For example, network traffic containing packets, frames, signals (analog, digital or any combination thereof), data, etc., may be sent and received in accordance with any suitable communication message protocol. Suitable communication message protocols may include a multi-layered scheme such as the Open Systems Interconnection (OSI) model, or derivatives or variants thereof (eg, Transmission Control Protocol / Internet Protocol (TCP / IP), User Datagram Protocol / IP (UDP / IP)). Furthermore, radio signal communication (eg, via a cellular network) may also be used in the communication system 100 be provided. Appropriate interfaces and infrastructure may be provided to facilitate communication with the cellular network.

The term "packet" as used herein refers to a unit of data that can be transferred between a source node and a destination node on a packet-switched network. A packet contains a source network address and a destination network address. These network addresses may be Internet Protocol (IP) addresses in a TCP / IP message protocol. As used herein, the term "data" refers to any type of binary, numeric, voice, video, text or script data, or any type of source or source Object code or other suitable information in any suitable format that can be communicated from one point to another in electronic devices and / or networks. Furthermore, messages, requests, responses and requests are forms of network traffic and may therefore include packets, frames, signals, data, etc.

In an exemplary implementation are the RANaaS engine 106 , the picking API engine 108 , the allocating radio resource engine 110 , and the allocating processing resource engine 112 Network elements are intended to include network devices, servers (virtual and physical), routers, switches, gateways, bridges, load balancers, processors, modules or other suitable virtual or physical devices, components, elements or objects that are operable to exchange information in a network environment , include. Network elements may include any suitable hardware, software, components, modules, or objects that enable the operations thereof, as well as appropriate interfaces for receiving, transmitting, and / or otherwise communicating data or information in a network environment. This may include appropriate algorithms and communication protocols that allow for effective data or information exchange.

Regarding the internal structure associated with the communication system 100 can be associated with the control node 102 and the eNB 104 each contain storage elements for storing information to be used in the operations described herein. The control node 102 and the eNB 104 may each contain information in a suitable memory element (eg random access memory (RAM), read only memory (ROM), erasable programmable ROM (EPROM), electrically erasable programmable ROM (EEPROM), application specific integrated circuits (ASIC), nonvolatile memory ( NVRAM), magnetic memory, magneto-optic memory, flash memory (SSD), etc.), software, hardware, firmware or other suitable components, devices, elements or objects, as appropriate and based on specific needs. Each of the memory elements mentioned herein should be understood as being included in the broad term 'memory element'. Further, the information contained in the communication system 100 used, tracked, dispatched, provided in any database, register, queue, table, cache, control list, or other memory structure, all of which may be referenced at any appropriate time frame. All such storage options may also be included in the broad term 'storage element' as used herein.

In certain example implementations, the functions described herein may be implemented by logic encoded in one or more tangible media (e.g., embedded logic provided in an ASIC, digital signal processor (DSP) instructions, software (potentially including Object code and source code) to be executed by a processor or similar machine, etc.), which may include nontranslational computer readable media. In some of these cases, memory elements may store data used for the operations described herein. This includes the storage elements being capable of storing software, logic, code or processor instructions that are executed to perform the activities described herein.

In an exemplary implementation, network elements of the communication system 100 , such as control nodes 102 and eNB 104 , Software modules (eg RANaaS engine 106 , Selecting API Engine 108 , allocating radio resource engine 110 and allocating processing resource engine 112 ) to accomplish or support operations as described herein. These modules may be appropriately combined in any suitable manner that may be based on particular configuration and / or deployment needs. In some embodiments, these operations may be performed by hardware that is implemented outside of this element, or included in another network device to achieve the desired function. Further, the modules may be implemented as software, hardware, firmware, or other suitable combination thereof. These elements may also include software (or interacting software) that can coordinate with other network elements to accomplish the operations as described herein.

Furthermore, each control node 102 and eNB 104 include a processor that can execute software or an algorithm to perform algorithms as described herein. A processor may execute any type of instructions associated with the data to accomplish the operations described herein. In one example, the processors could transform an item or article (eg, data) from one state or thing to another state or thing. In another example, the activities described herein may be implemented with fixed logic or programmable logic (eg, software / computer instructions executed by a processor) and those herein The elements identified could be some type of programmable processor, programmable digital logic (eg, a Field Programmable Gate Array (FPGA), an EPROM, an EEPROM) or an ASIC that includes digital logic, software, code, electronic instructions, or a suitable one Combination of it contains. Any of the potential processing elements, modules and machines described herein should be construed as being included in the broad term 'processor'.

control node 102 and eNB 104 may be network elements and include, for example, physical or virtual servers or other similar devices that may be used in a cloud service architecture. Cloud services may be broadly defined as the use of computing resources provided as a service over a network, such as the Internet. The services can be distributed and separated to provide support for network elements. Typically, computing, storage, and network resources are offered in a cloud infrastructure, which effectively shifts the workload from a local network to the cloud network. A server may be a network element, such as a server or a virtual server, and may be associated with clients, customers, endpoints, or end users who are communicating in the communication system 100 via a network. The term 'server' includes devices used to service requests from clients and / or a compute task for client systems 100 perform.

With a view to 2 is 2 a sample diagram 200 , the sample details that come with the communication system 100 are illustrated according to one embodiment illustrated. More precisely illustrated diagram 200 Examples Details related to resource package, API, and custom use case relationships. diagram 200 contains resource package 1 114a , Resource Pack 2 114b , Resource Pack 3 114c , API 1 116a , API 2 116b , API 3 116c , API 4 116d , API 5 116e , the adjusted use case 1 118a , the adjusted use case 2 118b , and the adjusted use case 3 118c ,

In an illustrative example, the RANaaS engine 106 be configured resource package 1 114a with API 1 116a , API 2 116b and API 3 116c combine to a customized use case 1 118a to create. Also, the RANaaS engine can 106 be configured resource package 2 114b with API 2 116b , API 3 116c , API 4 116d and API 5 116e combine to a customized use case 2 118a to create. Furthermore, the RANaaS engine 106 be configured resource package 3 114c with API 1 116a , API 3 116c , API 4 116d , and API 5 116e combine to a customized use case 2 118c to create. The selection of the API engine 108 can be configured to help in the selection of APIs. The Allocation of the Radio Resource Engine 110 may be configured to help select the radio resources and the allocating processing resource engine 112 may be configured to help select the allocated processing resources for the custom resource pack for each custom use case.

In an illustrative example, the following table contains a list of example APIs used in the communication system 100 can be used. It should be noted that the names of the APIs are for example purposes and other names or terms may be used without departing from the scope of this disclosure. It should also be noted that other APIs may be used or that any of the APIs may be customized. The following table is not a subsequent list and is provided for sample purposes only. API-I ndex API name Type resource pack use 1 DATA_TRANSFER_DL_PHY Overwrite A number of PDSCH RE, PDCCH amount, PUCCH amount, processability A user can create his own defined physical channel and any length of the TTI (as small as an OFDM symbol). So a shorter latency of PHY is possible. The user can use his own channel coding (such as LDPC, polar code), modulation (such as 4096QAM), MIMO methods and parameters to meet the specific power requirement or channel condition. 2 DATA_TRANSFER_UL_PHY Overwrite A number of PUSCH RE, PDCCH amount, PHICH amount, processability A user can create his own defined physical channel and any length of the TTI (as small as an OFDM symbol). So a shorter latency of PHY is possible. The user can use his own channel coding (such as LDPC, polar code), modulation (such as 4096QAM), MIMO methods and parameters to meet the specific power requirement or channel condition. 3 SCHEDULING DL MAC default processability Plan for a PDSCH involved in the resource bundle 4 SCHEDULING UL MAC default processability Plan for a PUSCH involved in the resource bundle 5 SIGNALING_DL_MAC Overwrite A number of the LCID value for MAC CE, processing capability A user can transmit private MAC signaling with the latency of multiple TTIs. (eg fast on / off indication or status of using API1 and API2). 6 SIGNALING_UL_MAC Overwrite A number of the LCID value for MAC CE, processing capability A user can transmit private MAC signaling with the latency of multiple TTIs. (eg fast on / off indication or status of using API1 and API2). 7 SIGNALING_DL_RRC Overwrite A number of signaling radio bearer, processing capability A user can transmit private RRC signaling with the latency of ten's TTIs. (eg slow display of power on / off or status of using API1 and API2). 8th SIGNALING_UL_RRC Overwrite A number of signaling radio bearer, processing capability A user can transmit private RRC signaling with the latency of ten's TTIs. (eg slow display of power on / off or status of using API1 and API2). 9 CIPHER_DL_PDCP Overwrite A number of the radio carrier, processing capability Cipher / decipher for a special security purpose, like police, security, state 10 CIPHER_UL_PDCP Overwrite A number of the radio carrier, processing capability Cipher / decipher for a special security purpose, like police, security, state 11 SON default Working capacity Automatic optimization of the parameters used in other APIs

With a view to 3 is 3 a block diagram, the sample details, with the communication system 100 are illustrated according to one embodiment illustrated. In one example, the network can 180 (not shown) may be implementation of a radio resource control (RRC) 120 , One or More Conversions of a Packet Data Convergence Protocol (PDCP) 122a to 122c , one or more implementations of a Radio Link Control (RLC) 124a to 124c , one or more media access level MAC scheduling implementations 126a and 126b , MAC multiplexing 132 , a PDSCH 134 , a physical downlink control channel (PDCCH) 136 , and a physical uplink control channel (PUCCH) 140 include. As in 3 illustrated, an adapted use case (eg adapted use case 1 118a as in 2 illustrated) implement the call of APIs to perform the functions in a physical location (e.g., PDSCH 134 , PDCCH 136 and PUCCH 140 ), a MAC location (eg MAC scheduling 126b) and an RRC layer (e.g., RRC 120 ). For example, PDSCH 134 , PDCCH 136 and PUCCH 140 Execute API1 116a, MAC scheduling 126b can API 2 116b run and RRC 120 can API 3 116c To run.

With a view to 4 is 4 a block diagram, the sample details, with the communication system 100 are illustrated according to one embodiment illustrated. In one example, network can 180 (not shown) one or more implementations of RRC 120a and 120b , one or more implementations of PDCP 122a to 122d , one or more reactions of RLC 124a to 124d , one or more implementations of MAC planning 126a and 126b , MAC multiplexing 132 , PDSCH 134 , PDCCH 136 and PUSH 138 To run. As in 4 illustrated, an adapted use case (eg adapted use case 2 118b as in 2 illustrated) contain a customized use case for critical MTC. For example, PDCCH 136 , PDSCH 134 and PUSH 138 API 2 116b included, MAC planning 126b can API 4 116d included, MAC multiplexing 132 can API 3 116c included and RRC 120 can API 5 116e contain.

In one example, the API 5 116e can be used to invoke SIG-NALING_DL_RRC and SIGNALING_UL_RRC to set up a configuration with custom service user equipment, such as to indicate a particular radio resource. Furthermore, API 3 116c can be used to invoke SIGNALING_DL_MAC and SIGNALING_UL_MAC to provide a quick indication of the activation or deactivation of a special transmission mode or status display for UL scheduling. Also, the API 4 116d can be used to call SCHEDULING_UL_MAC and SCHEDULING_DL_MAC to schedule a radio resource and determine a transport format of the allocated PUSCH. Furthermore, the API 2 116b can be used to DATA_TRANSFER_DL_PHY called to a special transfer mode processing and resource allocation on the PDSCH 134 DATA_TRANSFER_UL_PHY to create a special transfer mode processing and resource allocation on the PUSCH 138 to create or create. In one implementation is PUSCH 138 a mixed PUSCH, PDSCH 134 is a mixed PDSCH and PDCCH 136 is a mixed PDCCH, where the term "mixed" includes normal data transfer and data transfer for a customized use case. As a result, the normal and other customized services and data transfers that occur at other radio resources, although the adjusted use case does not conform to current standards (eg, an LTE standard), would not be affected by the customized use case. A special critical MTC transmission packet 158 for custom used cases for a critical MTC is in 7 illustrated.

With a view to 5 is 5 a block diagram, the sample details, with the communication system 100 are illustrated according to one embodiment illustrated. In one example, network can 180 (not shown) one or more implementations of RRC 120a and 120b , one or more implementations of PDCP 122a to 122d , one or more reactions of RLC 124a to 124d , one or more implementations of MAC planning 126a and 126b , MAC multiplexing 132 , PDSCH 134 , PDCCH 136 and PUSH 138 To run. As in 5 illustrated, an adapted use case (eg adapted use case 3 118c as in 2 illustrated) contain a customized use case for massive MTC. For example, PDSCH 136 and PUSH 138 API 1 116a included, MAC planning 126b can API 4 116d included, MAC multiplexing 132 can API 3 116c included and RRC 120 can API 5 116e contain.

In one example, the API 5 116e may be used to invoke SIGNALING_DL RRC and SIGNALING_UL_RRC to set up a custom service user equipment configuration, such as for displaying a particular radio resource. Furthermore, API 3 116c can be used to invoke SIGNALING_DL_MAC and SIGNALING_UL_MAC to provide a quick indication of the activation or deactivation of a special transmission mode or status display for UL scheduling. Also, the API 4 116d can be used to call SCHEDULINGULMAC to schedule a radio resource and determine the transport format of the allocated PUSCH. Furthermore, the API 1 116a can be used to call DATA_TRANSFER_UL_PHY for a special transfer mode processing on the PUSCH 138 to create or create.

In this particular example, data about the configuration of the particular radio resource (e.g., PRB Location) and the parameters of the particular transmission mode (eg, code rate, modulation mode, MIMO mode, etc.) are retrieved by calling APIs SIGNALING_DL_RRC and SIGNALING_UL_RRC communicates with the user equipment. The user equipment relating to the particular transmission mode at the particular radio resource can be turned on or off by calling the APIs SIGNALING_DL_MAC and SIGNALING_UL_MAC. If the transmission mode is turned off, the system could apply a normal transmission mode to communicate with the user equipment planning can be done by Call of API SCHEDULING_UL_MAC and execution of a data transfer with the special transfer mode can be achieved by calling the API DATA_TRANSFER_UL_PHY. As a result, the normal and other customized services and data transmissions that occur at other radio resources, although the adjusted use case does not conform to current standards (eg, LTE standards), would not be affected by the customized use case.

With a view to 6 is 6 a block diagram, the sample details, with the communication system 100 are illustrated according to one embodiment illustrated. In one example, a package may be 146 that in the n communication system 100 is used, a radio resource section 154 included by the allocating radio resource engine 110 is allocated, and a processing resource section 156 by the processing resource engine 112 is allocated. In a specific example, the package may 146 resource pack 1 114a and resource pack 2 114b and a resource for the public use section 152 contain.

The radio resource section 154 may include a number or percentage of bandwidth, subcarriers, physical resource blocks (PRB), signaling or data radio bearers (SRB or DRB), etc. These resources have the property of distinctness, whereby the resource used for a customized use case is separable from that used by other customized use cases, and the operations on those resources do not affect the operations on other resources. The processing of the resource section 156 may include a calculator amount, a signaling amount, an amount of energy, etc. These resources have the characteristics of integration if the radio resource and processing resource within a resource packet are sufficient to complete the desired custom use case and it is not necessary for the resource bundles to contain other custom use cases.

With a view to 7 is 7 a block diagram, the sample details, with the communication system 100 are illustrated according to one embodiment illustrated. More specifically illustrated 7 exemplary details pertaining to a special critical MTC transmission packet 158 for customized used cases for a critical MTC. For an exemplary block diagram illustrating example details, see 4 , The PDCCH location 160 indicates the Orthogonal Frequency Division Multiplexing (OFDM) symbol location Single-Carrier Frequency Division Multiple Access (SC-FDMA) of the data relevant to the service for the particular purpose of the PDCCH 136 used, the PDSCH place 162 indicates the location of the OFDM symbol of the data used for the special purpose service associated with the PDSCH 134 be used, the PUSCH place 164 indicates the OFDM or SC FDMA symbol location of the service for a specific purpose, which is PUSCH 138 are connected. In the special transmission mode of the special critical MTC transmission packet 158 User equipment data is in an OFDM symbol of the PDSCH 162 or an OFDM symbol of the PUSCH 164 instead of distributing the data across the entire PDSCH or PUSCH layer. In this way, the transmission latency for this user equipment is the duration of an OFDM symbol, which may be less than 100us in an LTE system. This particular transfer occurs only at the particular radio resource, such as a number of special PDSCH / PUSCH PRBs. OFDM is a method of encoding digital data at multiple carrier frequencies. SC-FDMA is a frequency-vision multiple-access scheme and may also be referred to as linear precoded OFDMA (LP-OFDMA). Like other multiple access schemes (TDMA, FDMA, CDMA, OFDMA), SC-FDMA can handle the assignment of multiple users to a shared communication resource. In addition, the SC-FDMA can be interpreted as a linear precoded OFDMA scheme by having another DFT processing step preceding conventional OFDMA processing.

With a view to 8th is 8th a block diagram, the sample details, with the communication system 100 are illustrated according to one embodiment illustrated. More specifically illustrated 8th exemplary details that focus on a special massive MTC transmission package 166 for customized used cases for a massive MTC refer. A PUSCH-adapted place of use 168 branches the PRB location of the customized data contained in the special massive MTC transmission packet 166 are included, and the PUSCH normal place of use 170 indicates the PRB location of normal or typical data contained in the special massive MTC transmission packet 166 are included. As in 8th As illustrated, the data of a user equipment is associated with an intermediate carrier as a unit, rather than as a specific PRB. In this way, the UL transmit power could be concentrated in the frequency domain as within an intermediate carrier. For example, the first domain illustrates 172a a first frequency domain, wherein a first user equipment may be allowed to concentrate, is power within an intermediate carrier, and the second domain 172b Figure 11 illustrates a second frequency domain in which a second user equipment may be allowed to concentrate is performance within another subcarrier. That way, the data becomes user equipment in one or a few sub-carriers in PUSCH 138 instead of being distributed across the entire spectrum of a PUSCH PRB. Because of this, the uplink transmission power for this user equipment in the frequency domain is concentrated to within an intermediate carrier. This may allow about three times the amount of increased coverage, such as distributing power within a PRB (considering a PRB = 12 subcarrier and path loss model PL = 22.0log10 (d) + 28.0 + 20log10 (fc)). This particular transfer occurs only at the particular radio resource, such as a number of special PUSCH PRBs. It should be noted that the examples provided herein may describe interaction with two, three or more network elements. However, this was for purposes of clarity and purely by way of example. In some cases, it will be easier to describe one or more of the functions of a particular set of operations by referring only to a limited number of network elements. It should be noted that the communication system 100 and its disclosures are easily scalable and can accommodate a large number of components as well as more sophisticated arrangements and configurations. Accordingly, the examples given should not limit the scope or broad disclosures of the communication system 100 which may be applicable to a variety of other architectures. For purposes of the present disclosure, the phrase "A and / or B" stands for (A), (B), or (A and B). For the purposes of the present disclosure, the term "A, B and / or C", (A), (B), (C), (A and B), (A and C), (B and C) or (A , B, and C).

While the present disclosure has been described in detail with reference to specific arrangements and configurations, these example configurations and arrangements may be materially changed without departing from the scope of the present disclosure. Furthermore, certain components may be combined, separated, eliminated or added based on specific needs and implementations. Furthermore, even if the communication system 100 With reference to certain elements and operations that facilitate the communication process, these elements and operations may be replaced by any suitable architecture, protocols, and / or procedures that support the intended function of the communication system 100 to reach.

Numerous other changes, substitutions, variations, alterations, and modifications will be apparent to one of ordinary skill in the art, and it is intended that the present disclosure encompass all such changes, substitutions, variations, alterations, and modifications as fall within the scope of the appended claims. In order to help the United States Patent and Trademark Office (USPTO) and also to all readers of a patent issued upon filing this application in interpreting the claims appended thereto, the Applicant wishes to note that the Applicant: (a) does not intend to do so To use one of the appended claims to paragraph six (6) of 35 USC section 112 to withdraw, as it exists at the date of this document, unless the words "means for" or "step for" are specifically used in the specific claims; and (b) does not intend, by specifying in the specification, to limit this disclosure in any manner that is not otherwise reflected in the appended claims.

OTHER NOTES AND EXAMPLES

Example 1 is at least one machine readable non-transitory storage medium having instructions stored thereon, the instructions, when executed by at least one processor, causing the at least one processor to identify a resource pack, the resource pack having standardized functions for use in the communication a radio access network, and modify the identified resource packet with one or more APIs to create a customized resource packet. The customized resource packet may include customized functions for use in communication on a radio access network for a customized service, and the customized resource packet is communicated on the network as a standardized packet.

In Example 2, the content of Example 1 may optionally include, the custom resource package including a standard API and an override API.

In Example 3, the content of any one of Examples 1 through 2 may optionally be included, the standard API serving standardized procedures to implement RAN services while the override API triggers non-standard handling to implement the RAN services.

In Example 4, the content of any one of Examples 1 through 3 may optionally include the customized resource pack containing one or more allocated radio resources and one or more allocated processing resources.

In Example 5, the content of any one of Examples 1 through 4 may optionally include, wherein the instructions, when executed by the at least one processor, further cause the at least one processor, the properties of the one or more allocated radio resources and the one or more to allocate allocated processing resources.

In example 6, the content of any one of examples 1 through 5 may optionally include a gate, the customized resource package containing executable APIs.

In Example 7, the content of any one of Examples 1 through 6 may optionally include the customized resource package related to massive machine type communications.

In Example 8, the content of any one of Examples 1 through 7 may optionally include the customized resource package related to critical machine type communications.

In Example 9, the content of any one of Examples 1 through 8 may optionally include, where the allocated resource packet allocation processing is independent of the processing of other customized resource packets.

In example 10, a system may include at least one processor to identify a resource packet, wherein the resource packet includes standardized functions for use in communication on a radio access network, and modify the identified resource packet with one or more APIs to provide a customized resource packet. The customized resource packet may include customized functions for use in communication on a radio access network for a customized service, and the customized resource packet is communicated on the network as a standardized packet.

In example 11, the content of example 10 may optionally include, with the custom resource pack containing a standard API and an override API.

In Example 12, the content of any one of Examples 10 through 12 may optionally include the standard API following standardized procedures to implement RAN services while the override API triggers non-standard handling to implement the RAN services.

In example 13, the content of one of examples 10-12 may optionally include, wherein the customized resource pack includes one or more allocated radio resources and one or more allocated processing resources.

In Example 14, the content of any of Examples 10 through 13 may optionally include, wherein the processor may further control the characteristics of the one or more radio resources and the one or more allocated processing resources.

In Example 15, the content of any one of Examples 10 through 14 may optionally include the customized resource pack associated with massive machine type communications or critical machine type communications.

Example 16 is a device for providing the radio access network as a service for a wireless network, the at least one memory element, at least one processor coupled to the at least one memory element, one or more radio access network as service engines, when executed by the at least a processor is configured to identify at least one resource packet, the resource packet containing standardized functions for use in communication on a radio access network, and modifying the identified resource packet with one or more APIs to create a customized resource packet. The customized resource packet may include customized functions for use in communication on a radio access network for a customized service on the network as a standardized packet.

Example 17 may optionally contain the content of example 16, wherein the customized resource package includes a standard API and an override API.

In Example 18, the content of any one of Examples 16 through 17 may optionally include the standard API following standardized procedures to implement RAN services while the override API triggers non-standard handling to implement the RAN services.

In example 19, the content of any one of examples 16 through 18 may optionally include, wherein the customized resource pack includes one or more allocated radio resources and one or more allocated processing resources.

In example 20, the content of any one of examples 16 to 19 may optionally include, wherein the one or more wireless access network as a service engines are configured to control the characteristics of the one or more associated radio resources and the one or more allocated processing resources ,

Example 21 is a method of identifying a resource packet, wherein the resource packet includes standardized functions for use in communication on a radio access network, and modifying the identified resource packet with one or more APIs to provide a customized resource packet. The customized resource packet may include customized functions for use in communication on a radio access network for a customized service on the network as a standardized packet

In example 22, the content of example 21 may optionally include, the custom resource package including a standard API and an override API.

In example 23, the content of one of examples 21 to 22 may optionally include, wherein the customized resource pack includes one or more allocated radio resources and one or more allocated processing resources.

In example 24, the content of any one of examples 21 to 23 may optionally include the customized resource pack associated with massive machine type communications or critical machine type communications.

In example 25, the content of one of examples 21 to 24 may optionally include rules of the properties of the one or more radio resources and the one or more allocated processing resources.

Claims (25)

A machine-readable non-transitory storage medium or machine-readable non-transitory storage medium having instructions stored thereon, the instructions, when executed by at least one processor, causing the at least one processor: identify a resource packet, the resource packet containing standardized functions for use in communication on a radio access network; and modify the identified resource bundle with one or more APIs to create a customized resource bundle, wherein the customized resource bundle includes customized functions for use in communication on a radio access network for a customized service, the customized resource bundle communicating on the network as a standardized packet becomes. Machine-readable storage medium or machine-readable storage media Claim 1 , where the custom resource bundle includes a standard API and an override API. Machine-readable storage medium or machine-readable storage media Claim 2 whereas the standard API follows standardized procedures to implement RAN services while the override API triggers non-standard handling to implement RAN services. Machine-readable storage medium or machine-readable storage media Claim 1 wherein the customized resource packet includes one or more allocated radio resources and one or more allocated processing resources. Machine-readable storage medium or machine-readable storage media according to one of Claims 1 and 3 to 4 wherein the instructions, when executed by the at least one processor, further cause the at least one processor to: control the characteristics of the one or more allocated radio resources and the one or more allocated processing resources. Machine-readable storage medium or machine-readable storage media according to one of Claims 1 and 3 to 4 , where the custom resource bundle contains executable APIs. Machine-readable storage medium or machine-readable storage media according to one of Claims 1 and 3 to 4 wherein the customized resource pack is associated with massive machine-type communications. Machine-readable storage medium or machine-readable storage media according to one of Claims 1 and 3 to 4 wherein the customized resource pack is associated with critical machine type communications. Machine-readable storage medium or machine-readable storage media according to one of Claims 1 and 3 to 4 where the allocated processing of the custom resource bundle is independent of the processing of other customized resource bundles. System comprising: at least one processor to: identify a resource packet, the resource packet containing standardized functions for use in communication on a radio access network for a general service; and modify the identified resource bundle with one or more APIs to create a customized resource bundle, wherein the customized resource bundle includes customized functions for use in communication on a radio access network for a customized service, the customized resource bundle communicating on the network as a standardized packet becomes. System after Claim 10 , where the custom resource bundle includes a standard API and an override API. System after Claim 11 whereas the standard API follows standardized procedures to implement RAN services while the override API triggers non-standard handling to implement RAN services. System after Claim 10 wherein the customized resource packet includes one or more allocated radio resources and one or more allocated processing resources. System after Claim 10 wherein the instructions, when executed by the at least one processor, further cause the at least one processor to: control the characteristics of the one or more allocated radio resources and the one or more allocated processing resources. System according to one of Claims 10 and 12 to 14 wherein the customized resource pack is associated with massive machine type communications or critical machine type communications. Apparatus for providing a radio access network as a service for a wireless network, comprising: at least one storage element; at least one processor coupled to the at least one memory element; one or more radio access network as a service engines that, when executed by the at least one processor, is configured to: identify a resource packet, the resource packet containing standardized functions for use in communication on a radio access network; and modify the identified resource bundle with one or more APIs to create a customized resource bundle, wherein the customized resource bundle includes customized functions for use in communication on a radio access network for a customized service, the customized resource bundle communicating on the network as a standardized packet becomes. Device after Claim 16 , where the custom resource bundle includes a standard API and an override API. Device after Claim 17 whereas the standard API follows standardized procedures to implement RAN services while the override API triggers non-standard handling to implement RAN services. Device after Claim 16 wherein the customized resource packet includes one or more allocated radio resources and one or more allocated processing resources. Device according to one of Claims 16 . 18 and 19 wherein the one or more radio access network as service engines are configured to: control the characteristics of the one or more allocated radio resources and the one or more allocated processing resources. Method, comprising: Identifying a resource packet, the resource packet including standardized functions for use in communication on a radio access network; and Modifying the identified resource packet with one or more APIs to create a customized resource packet, wherein the customized resource packet includes customized functions for use in communication on a radio access network for a customized service, wherein the customized resource packet is communicated on the network as a standardized packet , Method according to Claim 21 , where the custom resource bundle includes a standard API and an override API. Method according to Claim 21 wherein the customized resource packet includes one or more allocated radio resources and one or more allocated processing resources. Method according to one of Claims 21 to 23 wherein the customized resource pack is associated with massive machine type communications or critical machine type communications. Method according to one of Claims 21 to 23 , further comprising: controlling the characteristics of the one or more radio resources and the one or more allocated processing resources.

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