FI123550B - Method and device for network administration - Google Patents

Description

Method and device for network management

Area

The invention relates to a method and a device for network management. More particularly, the invention relates to the management of network infrastructure in networks comprising machine-to-machine systems.

Background

The following description of the prior art may include views, observations, conceptions, or representations or associations with representations not known in the state of the art relevant to the invention but provided by the invention. Some such inputs provided by the invention may be specifically highlighted below, while other inputs provided by the invention will be apparent from the context.

In modern messaging and computer networks, managing network infrastructure hardware such as PCs, servers, and printers is an important part of network operations. For a large network of tens and thousands of devices to be effectively or even managed, a systematic approach is required. Today, infrastructure management is done using standards such as the Simple Network Management Protocol (SNMP) or the Netconf installer. These protocols allow controlled and efficient monitoring of devices connected to the network. These methods work well in an Etherned-based office information technology (IT) environment, which includes devices that have processor power. Energy consumption, transport costs and implementation complexity do not cause concern in this environment.

c \ j 25 Companies are rapidly integrating Machine-to-Machine (M2M) systems with their IT support infrastructure, for example, for power control, remote machine control, building automation and asset management 00 S. M2M systems often include very simple, inexpensive, battery-powered devices connected through deep, low-bandwidth main deep networks. Also, the scope of M2M network devices is completely different and can include up to millions of devices in a single control loop.

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Traditional IT systems network management solutions and existing protocols such as SNMP are too inefficient and complex to manage end-to-end M2M systems. Existing solutions are not designed for deep networks or for a very large number of devices with low processing power and minimal energy consumption.

Thus, machine-to-machine systems nowadays often employ specialized inherited or individual solutions. Part of the reason for this is that many M2M systems are not IP-based, but the trend toward individual protocols has continued even when IP-based networking is available.

Quick description

It is an object of the invention to provide improved network infrastructure management in networks comprising machine-to-machine systems.

According to one aspect of the invention there is provided a device comprising 15 binary network service interfaces for communicating with resource nodes operably connected to the device using a binary network service; a resource directory for storing a register of the resource nodes; a data cache for storing information relating to the resource nodes; and an interface for managing resource nodes, which interface is configured to receive requests for resource nodes according to the Simple Network Management Protocol, communicate with the binary network service interface, and respond to the request based on communication with the binary network service interface; and a controller for coordinating the operation of the device.

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According to another aspect of the invention, there is provided a method of managing cp c1, 25 resource nodes, comprising communicating with resource nodes.

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x sa using the binary web service; resource register nodes

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resource directory; caching information related to resource nodes

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§ data cache; receiving requests for a simple network management protocol for data related to resource nodes; retrieving the requested data from the cache or nodes; and responding to the request by sending the requested data.

3

List of figures

Embodiments of the present invention will now be described, by way of example only, and with reference to the accompanying drawings, in which Figure 1 illustrates an example of a network management system sheet 5, to which embodiments of the invention may apply. FIG. 5 is a signaling diagram illustrating an embodiment of the invention. FIG. 7 illustrates an example of a messaging sequence and FIG. 8 illustrates a multiple embodiment of a network management system.

DESCRIPTION OF EMBODIMENTS 20 The following embodiments are exemplary. While the specification may refer to "" one "," "one", or "" some "embodiments in several paragraphs of the text, this does not necessarily mean that each refers to an embodiment (s) of word 5 or that a particular feature

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4 applies only to a single embodiment. The individual cp cn 25 features of the various embodiments may also be combined to provide other embodiments.

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x Communication between programs and computers is crucial

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element. Different programs, computers, and processors can switch between

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§ information without human involvement. Different networks and protocols m ΪΙ are used in different environments. On the Internet, the Transmission Control Protocol 00 30 col / Internet Protocol (TCP / IP) is the basic communication protocol used.

TCP / IP takes care of the compilation and decompression of packet data.

4 The IP addresses the packet addresses so that they are delivered to the correct destination. Above TCP / IP, Hypertext Transfer Protocol (HTTP) is used as a client / server protocol. The program can send an http request to a server that responds with another HTTP message.

5 The exchange of interoperable messages using APIs (Application Program Interfaces) provided by servers on the Internet is accomplished using web services. The web service can be implemented in many ways, typically using the Representative State Transfer (REST) model, which has built-in network connectivity protocols such as HTTP, and the payload encoding in Extensible Markup Language (XML), or implemented as a remote object called SOAP (Simple Object). Access Protocol).

Low-power wireless networks, such as IEEE 802.15.4-based embedded and sensor networks, have very limited resources for transmitting pa-15 chains. These are very energy efficient networks, and chip technology is cheap. For this reason, technology is advancing very rapidly towards embedded devices such as automation, measurement, tracking and control.

In low-power wireless networks, current web service 20 technologies are far too complex (titles, content parsing) and heavy (high costs of titles and content). Recently, binary network service protocols have been developed for low power networks. The binary web service solution includes a suitable web service protocol (such as a simplified £ 2 HTTP or binary web service protocol such as the Constrained Applicati-

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^ 25 is the use of Protocol (CoAP) application protocol and powerful content coding (such as Efficient XML Interchange EXI, Binary XML or Fast Infoset Fl).

σ> ^ An embodiment of the invention describes a network management system

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£ (NMS) for machine-to-machine applications where data and management information is collected from restricted devices, typically over restricted networks such as O! £ 30 GPRS or IEEE 802.15.4.4. Instead of managing such a network using User Datagram Protocol (UDP) based protocols or SNMP, an innovative binary network service is used. Three network management mechanisms are introduced: resource logging and detection, proxy SNMP, and domain management.

Figure 1 illustrates an example of a network management system architecture to which embodiments of the invention may be applied.

5 The architecture consists of the NMS server 102 of the network management system, which hosts the background components of the NMS system. Such an NMS server can be implemented anywhere, whether on a conventional personal computer (PC) or on a server cloud. The NMS server components may be located on the same device or may be distributed to the cluster 10. Embodiments of the invention have been designed in different sizes from small M2M systems (thousands of nodes) to very large M2M systems (hundreds of millions of nodes). The NMS server 102 provides an interface through which network service clients 104 can access NMS management information using standard HTTP network service protocols 120 such as REST. Further, due to the embodiments of the invention, the same management information can be accessed by conventional SNMP management tools 106 using the conventional SNMP 118 protocol.

The embedded M2M devices or resource nodes 110, which are managed by the NMS server 102, can be connected to the server directly via IP 116 or through the proxy server 108. The interfaces between the node, the proxy server and the server 114, 116 are implemented using a binary network service protocol over IP. According to one embodiment, proxy 108 may assist in the logging process, provide additional security, and interim storage of proxy services on behalf of the nodes. The M2M devices 110 are located on a limited network 112, which would render the £ 2 25 conventional management protocols too inefficient. The restricted or low-power wireless network 110 may be a multi-hop network comprising a plurality of 9 wireless low-power nodes. In this simplified example

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00 illustrates one node 110.

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According to one embodiment, wireless links in wireless network 110 can be implemented using IEEE 802.15.4 with Internet Protocol v6 (6lowpan), IEEE 802.15.4 with ZigBee, Bluetooth or Bluetooth ° Ultra Low Power ( ULP), a low power wireless local area network, a private low power radio, cellular system or any other system suitable for low power transmission. IEEE stands for Electrical and Electronics Engineers.

Embedded M2M devices or resource nodes 110 are configured to implement an NMS client and one or more Manage-5 ment Information Base (MIB). Management databases are used by SNMP to determine the management information structure for a resource.

Figure 2 illustrates an example of an NMS server 102. The server may consist of a plurality of components. The control function 204 is configured to coordinate the components and acts as a corporate communication bus. The server comprises 10 binary network service interfaces 210 which are operatively connected to a control function and configured to perform client and service functions of the network service interfaces and to provide offset and network domain functions. The binary network service interface may also be responsible for maintaining network resource information cache 214 and resource directory 212. The network resource information cache 214 is used to temporarily store management resources received from the NMS server. This caching significantly improves efficiency when subsequent requests for this resource are internally fetched instead of downloading a limited M2M network. Resource directory 212 is a register of all resources on the M2M network. The directory is used to collect re-20 resource registrations from M2M nodes at boot time, and requests resources for other NMS components. Resource directory 212 thus eliminates the need for management tools to directly examine the M2M network (which is very inefficient co).

The server further comprises an SNMP Proxy component 206 configured to act as an SNMP agent for any SNMP management tool that may communicate with the NMS server via SNMP interface 118.

| The SNMP agent is configured to find management resources (having the MIB-oo structure) in resource directory 212 and to produce a virtual management database 00. This virtual MIB represents all nodes on the M2M network and their Hales 30 bird databases. Thus, a direct connection to each node using SNMP is not required. The SNMP proxy 202 is configured to make an internal resource request from the binary network service interface 210 when it receives a request for an MIB-7 object. If the resource is already cached 214, the response can be returned immediately. The same management information is provided through the web service interface 202. This is usually achieved through the RESTful HTTP interface 120, where any web server or browser can find resources 5 in resource directory 212 and then request them using the URLs found. If the URL is found in the cache, the response can be returned directly. Otherwise, the resource is requested from the associated M2M node.

In one embodiment, the SNMP proxy and the network service interface communicate with the outside world using standard "non-binary" protocols. The binary network service interface may be configured to communicate with the nodes using binary protocols such as CoAP requests. NMS server units communicate internally using Application Program Interface (API) calls that are protocol-independent. Thus, the HTTP, SNMP and CoAP protocols end with their respective interface-15 components. The SNMP component is configured to query the resource it needs from the frontend using an internal API call. The frontend is configured to initiate a CoAP request if it does not have a cached version. Thus, according to one embodiment, the NMS server is configured to act as a resource relay rather than a protocol converter.

According to one embodiment, the NMS server may comprise a graphical user interface 208 for, for example, a system user to administer the system. This interface may be initially implemented or implemented via a pai-co expensive web page over HTTP.

In addition to being used to access management resources 10, the NMS server 102 may similarly be used to register and access application data and resources. The only difference is that non- | management resources are not available through the SNMP proxy interface.

oo Management resources include, for example, information on the number of incoming / outgoing IP-00 packets in the radio interface. Application resources include, for example, o 30 sensor temperature or servo-related information. SNMP is not used to access application resources because management databases are not a powerful tool for obtaining such information from resource nodes.

8

Next, the mechanism for logging and discovering resources for network management will be explored. In traditional SNMP-enabled network management, the SNMP network administrator continually scans the LAN for nodes to manage and find which management databases are available.

However, M2M applications are often made from deep Wide Area Networks over very limited links, where delays are often long. In such an environment, traditional SNMP management does not work effectively.

According to one embodiment, the M2M nodes 110, the NMS server 102, and any proxy servers 108 are configured to perform a resource recording and detection mechanism suitable for restricted networks 10. According to one embodiment, the managed data objects or resources in the node are represented as network resources. Node resources can be defined as a Uniform Resource Identifier network resource structure. The network resource is identified by the Uniform Resource Locator (URL). Uniform Resource 15 The Locator is a Uniform Resource Identifier (URI) that specifies where a resource is available and the mechanism by which the resource is retrieved. An example of a URL is the address of a web page on the World Wide Web, such as http://www.example.com/.

The detection mechanism begins with resource node 110 transmitting 20 registration messages to resource directory 212 of NMS server 102. The node obtains the resource directory's IP address in a variety of ways, including preconfiguration, bypass addresses, or detecting resource multicast resources. The registration mechanism may be implemented as a web proxy interface, whereby the node sends its registration using the POST or PUT method. The registration information is modeled as a network link list, where each link i c \] describes a network resource (resource descriptions). The node hosts this list of links a. As its own resource, for example in the URL "/ links". These resource images-

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Expectations could be presented in many different link formats, e.g. Atom or HTML oo § as links or in the form of an HTTP link header. In addition to the link URL, each reo 30 surge description contains possible metadata from the resource, e.g.

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mantra name, interface description, ID, and content type. According to one embodiment, the resource mapping uses a management-specific designation, which is made by the SNMP proxy mechanism. Registration can also be used with other management and M2M application resources.

An example of a resource description of a node 110 with SNMP management resources in the form of an HTTP link header might look like the following: </mib/l.3.6.1.2.1.1.3>; name = "IPv6-MIB" / type = "MIB", </mib/1.3.6.1.2.1.4.2>; name = "UDP-MIB" / type = "MIB"; To register these resource descriptions on the NMS server 102, the node 110 takes the resource by POST or PUT to the 10 familiar URLs on the NMS server. Resources can be stored in a directory called "" / links ". According to one embodiment, the query request registration chain includes metadata from a node. The virtual web service could look like this:

Request: POST rd.nms. example. org / links? name = no-15 del. example.org & id = a21 f Content-Type: application / link-format Payload: </mib/l.3.6.1.2.1.1.3>; name = "IPv6 MIB"; type = "MIB", </mib/1.3.6.1.2.1.4.2>; name = "UDP-MIB"; type = "MIB"; 20 Responses: 2 00 OK Location: / links / nodel. example. org

The payload above is a resource description in the form of an HTTP link header. In the payload, the resource URL is specified between the brackets co "<>". The Name field is the name of the resource in the case of the MIB management database °. The Type field indicates that this is an SNMP MIB.

When the resource directory receives this, it either updates the existing c \ j mass entry corresponding to the node name, identifier, or IP address | or create a new note. The entry contains the node metadata, a mapping of each reso, and the entry control metadata. The input control method section 00 includes the node status, which can be either active, ACTIVE, or old, δ 30 STALE. The resource directory does not use the entry STALE for searching or accessing the resource. In STALE mode, a node is considered temporarily unavailable.

10

The resource directory creates the node space internally. The first time a node registers, it is marked as ACTIVE. If no activity (active alarms) or new registrations are received from the node within a certain timeout (STALE_TIMEOUT), the node will be put into STALE mode.

5 In addition, the interface may include, for example, a router that tells the resource directory if the status of a node becomes unavailable or can be reached again.

Restricted M2M nodes can often disappear from M2M networks due to low battery, broken or network problems. For this reason, resource directory entries need to be refreshed from time to time. According to one embodiment, the 10 refresh can be done in any of the following three ways: the node can update the entry by its POST method to its entry URL, the NMS server can update the entry with the GET function to the node URL as defined in the directory '' / links. or excitations can be used, which eliminates the need for communication with the node.

According to one embodiment, the alarms are used to pass markings in the ACTIVE state or to mark markings in the STALE state if the node is no longer active. This solution has a significant advantage over the prior art in that it does not burden the limited network and does not deplete the lifetime of the node battery. The resource directory maintains two timers, an expiration timer, and a garbage collection timer for each character. If no active excitations or new registrations are received from the node (s) in ACTIVE state for the first time (STALE_TIME), the node will be marked as STALE. If no active excitations or new registrations are received from the ° node / node in STALE mode within the second time (GARBAGE_ § 25 COLLECT_TIMER), the node entry will be deleted.

Fig. 5 is a signaling diagram illustrating an embodiment oo of the invention. The diagram illustrates the node registration process,

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S including excitation mechanism. The process begins at step 502. When the M2M-30 node 110 first connects to the NMS server 102, it sends 504 a resource posting message by POSTing its resource description to, for example, the URL "/ links".

11 The NMS server is configured to respond either by reporting a failure (e.g., authentication failed) or by a 200 OK message 508 containing the location of the node entry below the address "" / links.

The NMS server resource directory is configured to create 506 5 entries for the node in the ACTIVE state if registration is successful. The SNMP proxy server and the network interface components of the server 102 continuously query the resource directory for information about nodes and resources (using an internal bus or interface). Entries in ACTIVE mode are available for inquiries.

10 The NMS server uses data traffic to refresh the node resource directory entry expiration timer. The NMS is configured to request 510 resources. Receiving a positive response 512 causes a REFRESH excitation 514 in the resource directory that resets the expiration timer.

In some cases, part of the network could fail 516 or the node could lose from the network subnet. If proxy 108 is located at a location where network status information is available, it is configured to send a STALE wake-up signal 518 from said node (s) and mark them in STALE state 520. An acknowledgment 522 may be sent to the proxy.

Entries will be kept in STALE mode for GARBAGE_ COLLECT_TIMER -20 for a period specified by the timer. The resource directory can be configured to periodically perform garbage collection by deleting old outdated entries. When the node is again in connection state 524, the resource directory can restore the mer-co tag either by receiving an ACTIVE excitation from the proxy server as the node transmits data or when the node re-registers to the resource directory 526, §25528,530.

c \ j Figure 3 illustrates an example of a web service cache | from server 108. This optional proxy 108 may be configured to act as a network cache between NMS server 102 and M2M resource nodes 00101. The proxy may be located, for example, on a router on the edge 30a of cell 112 of the nodes. However, the proxy may also be further away from the nodes. Proxy 108 comprises two or more IP network interfaces 114, 116.

12

One interface 116 is directed to the NMS server 102. One or more interfaces 114 are directed to resource nodes 110.

According to one embodiment, proxy 108 comprises a control logic 302 configured to handle network service traffic monitoring 5 with its IP network interfaces 114, 116. The control logic is configured to provide assistance in the resource registration process of resource nodes. For this purpose, the proxy may comprise a resource directory cache 304. The cache stores resource registration information for nodes 110 under the proxy 108. As a result, the proxy may be configured to maintain registrations on the NMS server on behalf of the nodes. Proxy 108 may also use cache 304 for intermediate storage of management resources on behalf of nodes to reduce network load on restricted networks. According to one embodiment, the proxy server can provide important security features, such as reducing the risk of denial of service, providing access control, or providing additional security on the NMS 15 Internet. In this context, denial of service means that the resource node is overloaded with too many simultaneous requests. A proxy can slow down the amount of traffic, which in effect becomes a limited node.

Figure 4 illustrates an example of a network node 110 managed by an NMS server 102. Node 110 in system 20 managed by NMS server is typically a restricted M2M device comprising an IP communication interface 114. The node may be a 6LoWPAN sensor node or a GSM-based M2M modem. . According to one embodiment, the whole node is implemented in the SIM card of the GSM device. The node comprises an NMS client ^ 402 configured to implement the binary network service protocol! P-S 25 over the stack. The NMS client 402 may still be configured to serve as a binary web service client and server. The node may comprise a management database and 404 configured to store the URLs for each of the associated administrative objects. These MIBs 404 are arranged in a manner compatible with the SNMP MIBs. Unlike prior art SNMPs, however, they are not identified by an Object ID (OID) but by URLs. The NMS client 402 may further be configured to be responsible for registering its resource marking points (top-level MIB resource URLs) on the NMS server 102 either directly or via proxy 108.

In addition to being used for management resource needs, the NMS client 402 is also typically used to register and serve conventional M2M application resources 5. For simplicity, components of the resource node corresponding to application resources, such as sensors, are not shown in Figure 4.

On the NMS server 102, the SNMP proxy server 206 is a component that acts as an SNMP agent and translates incoming SNMP messages into managed re-10 resources for network resource requests. It is configured to communicate with the nodes via binary network service protocols via the binary network service interface 210. According to one embodiment, the SNMP proxy 206 is configured to use the data cache 214 to prevent unnecessary network load and to allow for response, which is the sleeping cells. Figure 6 is a signaling diagram illustrating an embodiment of the invention. The diagram illustrates an example of the operation of a cache component. The process begins at step 600.

In step 602, the SNMP proxy 206 receives an SNMP command requesting a resource. The request comprises a resource SNMP-20 identifier, an MIB Object ID (OID) identifier.

To communicate with the node, the SNMP proxy creates in step 604 a URI of the MIB Object IDs (OIDs). For example, OID co 1.3.6.1.2.11.3 is converted to a URI: /mib/1.3.6.1.2.1.1.3 ° In step 606, the SNMP server is configured to check if the data cache 214 of the NMS server 102 comprises the requested resource c. \ j dataa. The proxy server tries to retrieve data from the data cache using the one created | URI by sending a request to the binary web service interface 210.

oo If cache 214 contains 608 requested data, the binary network service 00 subscriber sends the requested value to the proxy. The proxy is capable of transmitting the SNMP response in step 616.

c \ j 14

Otherwise, the proxy is configured to communicate 610 over binary network service interface 210 by sending a node binary message comprising a data request to the node.

In step 612, the proxy receives via the binary network service interface 210 210 a binary network message comprising a response to the request.

In step 614, the proxy is configured to update the cache 214 with the received data.

Finally, the proxy sends the SNMP response in step 616.

FIG. 7 illustrates an example of a messaging sequence 10 between an NMS server 102, an SNMP proxy agent 206, and a restricted node 110.

The NMS server 102 receives the SNMP request and forwards it 700 to the SNMP proxy 206.

The proxy sends to the binary network interface 210 a request 702 for the 15 requested data. The interface first attempts to retrieve the requested data from the data cache. If data is found, it is sent back to the proxy in response 710. Otherwise, the binary network service interface 210 sends a request 706 to the node 110.

The node is configured to send a binary network service message 20 708 comprising a response to the request. The interface sends 712 responses to the proxy server, after which the proxy is configured to send a response 704.

According to one embodiment, the SNMP proxy 206 first attempts to retrieve data from the cache. If the cache is empty, the proxy server requests data from 25 nodes. These messages can be sent via the binary network service interface 210 i c \].

| The payload type in the binary network service messages for management is transported either in XML or ASN.1 BER (Abstract Syntax Notation 00 is One Basic Encoding Rules) in a manner similar to the SNMP payload.

o 30 In the case of XML resources, the SNMP proxy translates to the appropriate ASN.1 BER format when responding to SNMP requests. Other types of payload could be transported but must be translated in a suitable manner (eg text / plain).

The SNMP proxy is configured to model the entire M2M system as a configuration of virtual SNMP agents using the SNMP 5 Community Name function (Conext Name in SNMPv3 terminology). Under the '' public '' Community Name ', the SNMP agent provides an Entity MIB with a logical group of parties, each representing a node. Each entry describes the metadata of a node, its MIB resources, and contains its community name, which may be its name, its identifier, or its IP address, collected at registration 10. The SNMP management tool 106 then generates a new SNMP request where it sets the community name of the node to be managed. According to one embodiment, the SNMP proxy is configured to support reactive and proactive management. In reactive management, every time a proxy server has a SNMP request, it generates a resource request (which could be available from cache memory). Proactive management uses binary web service orders. The proxy server is configured to pre-order network services. In this way, the data-daemon 214 is updated each time the resource is changed. This way, whenever a SNMP request is made from a proactively managed resource, the value is always cached.

20 In a small M2M system, all management data could be in the same credit and administrative domain. However, large M2M enterprise systems may have multiple information network areas that need to be kept separate. However, multiple co domains can be connected with even a single M2M node.

In one embodiment, a mechanism for domain management is disclosed. Mechanism 25 uses the URI authorization components to isolate network service requests, and it redirects them to the virtual servers on the NMS server 102 or the node. Web | the area management has no effect on the traffic interface 116 which operates as described above; it is an IP interface that manages binary network services.

00 According to one embodiment, when domain management is in use, 30 each web service request contains a URI authorization component in addition to the URI path.

The syntax of a URI can be constructed as a schema: // authority / path? Query # fragment. For example, one domain could be called A and another domain B. M2M-16 nodes may belong to different network domains, or one node may contain data belonging to different domains. When a node associated with domain A registers with the NMS server, it would send the following request: POST a .nms. example.org/links 5 The 'a' in the request specifies domain A. The address nms.example.org/link defines the address and directory of the node entry. The entry "a.nms.example.org" corresponds to the authorization field and the entry / links corresponds to the path field and the entry to "name = node1.example.org" corresponds to the query field. The fragment field is not used.

Figure 8 illustrates an embodiment of an NMS architecture that handles multiple domains. Here, it is assumed that there are two domains, Area A and Area B. The NMS architecture may comprise a load balancer 802 associated with both credentials (both domain names change to the load balancer IP address). When the load equalizer 802 receives the request, it checks the request domain authority and then forwards the request to the NMS server 102 that handles that domain. According to one embodiment, non-domain requests have a default domain.

Similarly, a node can support multiple domains, whereby it maintains 20 domain status requests marked in domain A separate from those in domain B. These domains are usually associated with another secure identity to ensure that the requests are for the correct domain.

According to one embodiment, the device implementing aspects of the invention can be implemented on a server, computer, or software in a computer group connected to the Internet and as a binary network service area directly or via a proxy or server.

| One embodiment provides a computer program provided by a distribution medium comprising program instructions which, when loaded on an electronic device, performs a computer process comprising: communicating with resource nodes o 30 using a binary network service; storing the resource node register in its resource directory; storing data relating to the resource nodes in a data cache; requests for resource-related data according to a simple network management protocol 17 through the receive interface; retrieving the requested data from the cache or nodes and responding to the request by sending the requested data.

The computer program may be in source code form, object code form, or in some intermediate form, and may be stored on some kind of medium, which may be an entity or device capable of carrying the program. Such carriers include e.g. media, computer memory, read-only memory, and software distribution package. Depending on the processing power required, the computer program may be implemented on a single electronic digital controller or distributed between multiple computers.

It will be clear to one skilled in the art that as technology advances, the inventive concept can be implemented in various ways. The invention and its embodiments are not limited to the examples described above, but may vary within the scope of the claims.

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Claims (19)

A device comprising a binary network service connection (210) for communicating with resource nodes functionally connected to the device using; A resource register (212) for storing a register from the resource nodes; a data cache memory (214) for storing data adjacent to the resource nodes; and a connection (206) for administering the resource nodes, which connection is configured to receive requests according to a simple network management protocol (Simple Network Management Protocol) relating to the resource nodes, for communicating with the binary network service connection (210) and responding to the request on the basis of communication with the binary network service connection; and a controller (204) for coordinating the operation of the device. The device of claim 1, further comprising a network service connection (202) configured to receive requests according to a Hypertext Transfer Protocol protocol relating to the resource nodes, for communicating with a binary network service connection (210) and responding to the request basis of communication with the binary network service connection. The device of claim 1 or 2, wherein the device is configured to define the node's resources as a Uniform Resource Identifier network resource structure. Device according to any one of claims 1-3, which device is configured to receive a POST or PUT network message from a functionally connected node to the device g, which message contains data about the node's resources; storing received data as records in the resource register (212); and CL record the state of the record as active. CO 5. Device according to claim 4, which device is further configured to CVJ record the state of the recording as outdated, if no activity related to the recording has been detected during a first given time monitoring period. Device according to claim 4, which device is further configured to remove the record from the resource register, if no activity related to the record has been detected during a given time monitoring period. Device according to claim 3, wherein the resources of the nodes functionally connected to the device belong to more than one network area, the device being configured to separate different network area resources by using a different authorization component for each network area on a Uniform Resource Identifier path. . Device according to any of the preceding claims 1-7, wherein the connection (206) is configured to receive a request according to the simple network administration protocol relating to the resource node, to the request for data in connection with the resource node from the data cache memory (214). via the binary network service connection (210); receiving the requested data from the binary network connection, if the data is in the cache, and responding to the request; requesting data associated with the resource node from the node via the binary network service connection (210), if data is not in the cache memory; to receive requested data from the node via the binary network connection o and respond to the request. g 25 9. A method for administering resource nodes, comprising in g> communicating with the resource nodes using a near-local network service; CL storing a register from the resource nodes in a resource register (212); 00 cache storage of data adjacent to the resource nodes in a data cache (214); C \ J receiving requests according to a simple network management protocol relating to data in connection with the resource nodes with the connection (206); obtaining requested data from the cache or nodes and responding to the request by transmitting the requested data. The method of claim 9, further comprising: requests are received according to a Hypertext Transfer Protocol protocol 5 which relates to the resource nodes, the requested data is obtained from the cache memory or nodes and is responded to the request by sending the requested data. The method of claim 9 or 10, wherein the resources of the nodes are further determined as a Uniform Resource Identifier network resource structure. 10 A method according to any of the preceding claims 9-11, wherein a Post or PUT network message is also received from the node, which message contains data about the node's resources; stored received data as records in the resource register (212); and the state of the record is recorded as active. A method according to any of the preceding claims 9-12, wherein the state of the recording is also recorded as parent, if no activity related to the recording has been detected during a first given time monitoring period. The method according to claim 12, wherein the record is also removed from the resource register if no activity related to the record has been detected during a second given time monitoring period. g 25 The method of claim 11, wherein the resources of the nodes belong to> more than one network area, wherein the resources of the network areas are distinguished by using a different access component for each network area on a Uniform RECl source Identifier path. OO g 16. A method according to any of the preceding claims 9-15, a request is received according to the simple network administration protocol, which request relates to the resource node, further comprising CVJ (214); data is requested in connection with the resource node from the data cache memory, requested data is received, if data is in the cache memory, and is responded to the request; 5, data in connection to the resource node from the node is requested, if data is not in the cache memory; the requested data is received from the node and responds to the request. A computer program product which encodes an instructional computer program, by which a computer process is performed which performs a method according to any of claims 9-16. 18. Computer program distribution means which can be read with a computer and which encode an instructional computer program, by means of which a computer process is performed which performs a method according to any of claims 9-16. The computer program distribution means of claim 18, which comprises at least one of the following means: a computer-readable device, a program storage device, a recording means, a computer-readable memory, a computer-readable software distribution package, and a computer-readable software package. CO δ C \ J o O) C \ l X cc CL CO CO o m δ CM