PATENT ABSTRACT
For secure configuration of network nodes from a backend with low connectivity requirements and workload at the backend and reduced communication overhead, a system, a control unit for a segment controller and a method for secure protocol execution in a network are provided, wherein protocol information is provided to a segment controller ( 60 ) for controlling a node ( 10 ) and a protocol is performed based on the protocol information to control the node ( 10 ), at least one response message of the node ( 10 ) being required at the segment controller ( 60 ) for performing one or more steps of the protocol.

PATENT DESCRIPTION
CROSS-REFERENCE TO PRIOR APPLICATIONS 
     This application is the U.S. National Phase application under 35 U.S.C. §371 of International Application No. PCT/IB2012/052763 filed on Jun. 1, 2012, which claims the benefit of European Patent Application No 11169391.7, filed on Jun. 10, 2011. These applications are hereby incorporated by reference herein. 
     FIELD OF THE INVENTION 
     The invention relates to a system, a control unit for a segment controller and a method for secure protocol execution in a network. 
     BACKGROUND OF THE INVENTION 
     Recently, wireless mesh networks attract more and more attention, e.g. for remote control of illumination systems, building automation, monitoring applications, sensor systems and medical applications. In particular, a remote management of outdoor luminaires, so-called telemanagement, becomes increasingly important. On the one hand, this is driven by environmental concerns, since telemanagement systems enable the use of different dimming patterns, for instance as a function of time, weather conditions or season, allowing a more energy-efficient use of the outdoor lighting system. On the other hand, this is also driven by economical reasons, since the increased energy efficiency also reduces operational costs. Moreover, the system can remotely monitor power usage and detect lamp failures, which allows for determining the best time for repairing luminaires or replacing lamps. 
     Current radio-frequency (RF) based wireless solutions preferably use a mesh network topology, e.g. as shown in  FIG. 1 . The wireless network comprises a central controller or segment controller  60  and a plurality of nodes  10  (N) being connected among each other by wireless communication paths  40  in a mesh topology. Thus, the nodes  10  and the central controller  60  may comprise a transceiver for transmitting or receiving data packets via wireless communication paths  40 , e.g. via RF transmission. In the backend, a service center  80  is situated and serves for system management. This entity normally communicates with one or more central controllers  60  of a corresponding network as a commissioning tool in charge of controlling or configuring this network over a third party communication channel  70 , such as the Internet or mobile communication networks or other wired or wireless data transmission systems. In case of a lighting system or any other large wireless network, a network can also be divided into segments, so that a node  10  belongs to exactly one segment having one segment controller  60 . Therefore, the terms “segment controller” and “central controller” should be seen as exchangeable throughout this description. 
     In general, any node  10  of the mesh network can communicate with the service center  80  via the segment controller  60 . However, in some situations, high security standards have to be fulfilled in order to provide basic security services. An example is protection against a man-in-the-middle attack, i.e. preventing sensitive information being provided to non-authorized nodes  10  or preventing manipulation of the information provided to the nodes  10 . For instance, outdoor lighting control involves the remote management of lighting nodes requiring a communication link between the service center  80  and the nodes  10  themselves through a controlling device such as a segment controller  60 . In contrast to the service center  80  and the nodes  10 , the segment controller  60 , which is in the middle, is often not fully trusted since it may be managed and manipulated by third parties such as installers or customers. Thus, a segment controller  60  may act as a man-in-the-middle and manipulate some messages. This makes the execution of security protocols challenging. For instance, keying material cannot be provided to the segment controller  60 , since it may be misused. Therefore, it is required to find means that allow to upgrade and/or activate software functionalities of the network nodes  10  or the like without being afraid of an intruder being able to put malware on the nodes  10 . For this, it is important to ensure that a protocol for performing such actions is correctly performed by the segment controller  60 . 
     Traditional end-to-end security protocols that allow for an end-to-end authentication between two trusted entities require the interactive exchange of messages between the service center  80  and the nodes  10 , e.g., based on a challenge-response authentication handshake. Although such a procedure provides high security, it poses severe requirements regarding the usage of the GPRS link  70  as shown in  FIG. 1  and regarding the service center  80  in the backend, since it involves continuous connections, more bandwidth and more operations at the service center  80 . Thus, an end-to-end security handshake from the service center  80  to the nodes  10  ensuring, e.g., mutual authentication, is expensive and involves a lot of data traffic, continuous connection with the backend, more bandwidth and more operations at the backend. 
     Hence, it is desired to find means for communicating with network nodes  10  from the backend via an intermediate controlling device, providing a reasonable trade-off between security and operational needs suitable for the respective application. 
     SUMMARY OF THE INVENTION 
     In view of above disadvantages and problems in the prior art, it is an object of the present invention to provide a system, a control unit for a segment controller and a method for secure protocol execution in a wireless network, allowing for the secure configuration of network nodes from a backend, while minimizing connectivity requirements and workload at the backend and reducing the communication overhead. 
     The invention is based on the idea to force a controlling device, which serves as an intermediate entity between network nodes and a service center, to carry out a particular protocol with at least one of the nodes by providing the controlling device with corresponding protocol information, wherein the controlling device requires a predetermined response message from the respective node(s) in order to carry out a next step of the protocol. It is to be understood that the service center as well as the controlling device or segment controller may also be represented by a certain network node, respectively. The predetermined response message may relate to a correct response(s) from the respective node(s), which can only be given by the node in case that the protocol is performed correctly. Thus, the protocol may be performed by the intermediate controlling device without causing extensive data traffic as it would be involved, e.g., in a common security handshake, thereby reducing the communication overhead. Moreover, by making the protocol execution dependent on a valid answer of the node to be controlled, manipulation of information provided to the node or misuse of the information by the controlling device may be prevented. Therefore, features of an end-to-end handshake between the nodes and the backend can be realized with respect to security. In one example, the protocol may relate to at least one of configuring the network nodes, updating node software, activating node features and commissioning of the nodes. Then, e.g., software update information may be provided to the nodes via the controlling device, while preventing manipulation of this information and preventing the information being provided to other nodes than the target nodes. Since the controlling device may only be able to proceed with the protocol having valid response messages from the right target node(s), correct protocol-based operation of the controlling device can be enforced. 
     According to one aspect of the present invention, a system for ensuring correct protocol execution in a network, such as a wireless mesh network, having one or more nodes is provided. The system comprises a service center and a segment controller, wherein the service center provides protocol information to the segment controller for carrying out a protocol with at least one particular node of the network nodes. In order to be able to use the protocol information, the segment controller may need information provided by this node in a response message. The response message may be sent by the node, after having received a message from the segment controller, e.g. announcing a particular information or execution of a particular protocol. Preferably, the node provides a valid response message to the segment controller only after successful verification of a previous message or information received from the segment controller. Therefore, the segment controller may be forced to provide the right protocol information to the right node in order to receive a valid response message for performing a further, following or subsequent step of the protocol. By these means, correct operation of the segment controller may be supervised by the node to be controlled, i.e. the target node, thus preventing misuse of the protocol information. Likewise, this prevents malware to be successfully installed on the node. Hence, it may be guaranteed without control by the service center that only information authorized by the service center is distributed to network nodes and that only parties authorized by the service center have access to the distributed information. Since no continuous communication with the service center may be required in this process, the service center may be partially offline. 
     In one embodiment, the response message of the node includes information about an identity of the node and/or about an identifier of the message received from the segment controller, to which the node is responding with the response message. The identifier of the message may be a string or value derived from the received message, e.g. a fingerprint of the message from the segment controller. Here, a fingerprint refers to uniquely identifying data by extracting from it a small key. Thus, the identifier of the message may relate to a function of a content of the message sent from the segment controller. The node identity may relate to an individual key of the node. In this case, it may also be ensured that the segment controller performs the protocol with the correct target node. However, the node identity may also relate to a symmetric key common to all nodes of the network, e.g. a commissioning key. This key or the node identity is preferably not known to the segment controller. Thus, the node may generate a check value or string depending on the content of the received message and/or based on its identity. By these means, the response message indicates the identity of the receiving node as well as the content of the received message, so that a correct protocol execution can be easily verified. 
     Preferably, the response message from the node (or parts thereof) is required in order to decrypt at least a part of the protocol information provided by the service center to the segment controller. Thus, the segment controller may generate a key for decryption based on the response message from the node. For instance, the segment controller may be provided by the service center with an at least partially encrypted configuration message for configuring at least one of the network nodes. In order to proceed with the configuration of the node, the segment controller may require the response message for decryption. The response message may include a security key of the node, e.g. node identity or commissioning key, a message fingerprint or the like in an inseparable or coded way, so that the segment controller or eavesdropping entities cannot derive the original security keys. Therefore, the segment controller can be enforced to carry out a specific protocol with specific nodes by providing the segment controller with correspondingly encrypted protocol information. Thus, the segment controller can neither misuse the nodes nor transmit the protocol information to non-authorized nodes, since the segment controller can only decrypt and use the protocol information, when following the protocol. If it does not follow the protocol correctly, it cannot decrypt the information and thus cannot misuse the information. After the segment controller has decrypted at least a part of the protocol information using the response message, the segment controller may forward some or all of the decrypted protocol information to the node or nodes in the network. 
     Preferably, the protocol information is encoded based on different keys. In this embodiment, the node(s) in a network may return (a) response messages corresponding to the last received message from the segment controller. These/this response messages (or party of them/it) may be used in turn by the segment controller to generate the next key for decrypting the next part of protocol information. For instance, information for a subsequent protocol step may be encoded with an expected valid response message of the node to a message from the segment controller relating to a previous protocol step. Thus, the protocol information may be iteratively decrypted. By these means, the correct operation of the segment controller is observed and ensured step by step. 
     In a preferred embodiment, the segment controller is provided with the protocol information for all steps of the protocol. In this case, the protocol information may be encoded based on different keys. This allows executing the protocol by involving mainly interactions between the segment controller and the nodes, since the security is already guaranteed by the requirement of the correct response message. Hence, the connectivity with the backend required for performing the protocol as well as the number of operations at the backend can be decreased. 
     Additionally, the segment controller may send a request for protocol information related to a subsequent protocol step to the service center, wherein the request message is based on the response message received from the at least one node. Thus, the service center may verify using the information about the response message of the node included in the request message that the segment controller has performed the previous protocol step with the correct node and/or in a correct way. Then, the service center may provide the segment controller with further protocol information required for performing a next protocol step. In case that more than one node is controlled with the protocol, the segment controller may aggregate information about all response messages (or a subset of them) from the respective nodes in the request message to the service center. Here, the service center may in addition check, whether all of the nodes to be controlled have been successfully addressed in the previous protocol step. 
     Preferably, the service center and a node of the network share at least one of a common security key, a commissioning key, a cryptographic function such as hash function, an iteration number of a hash function and a current hash value. The service center may know a security key individual for each network node or a security key common to all network nodes or for one or more groups of network nodes. Alternatively or additionally, the service center may keep a hash chain or hash function for each network or network segment and a start value a 0  thereof. Then, a node may be initialized with the anchor of the respective hash chain or function. The hash function may be replaced by another one-way function or chain, wherein an iterative application of the function gives chain links or elements derived from a starting string or starting value, e.g. a i =HASH(a i−1 ). Preferably, the protocol and/or the response message is at least partially based on a hash function such as a hash algorithm SHA-2. By these means, a node, which is initialized with the anchor of the hash chain and which keeps track of the current hash chain element can verify a received message by checking, whether the hash element a i−1  included in the received message satisfies the condition: a i =HASH(a i−1 ). Hence, using hash chains or other one-way function allows authentication without public-key cryptography. 
     In some embodiments, the protocol may include providing information to one ore more nodes of the network. Then, the information is preferably protected based on a secret key derived from a master secret and an information identity number. The information may be transmitted from the service center via the segment controller to the node. Thus, in order to secure the information, the secret key may be based on a master secret, i.e. a string or value only known to the node and the service center, but not to the segment controller. For instance, a master secret may relate to a security key of the node or a commissioning key of the node. Moreover, the secret key may additionally include an information identity number, e.g. a random number, a nonce or a salt set by the service center. Thus, in the example that the information relates to a software update, the information identity number may correspond to a software update number or software number. By these means, sensitive information can be protected and features of an end-to-end security handshake between the service center and the node can be mimicked. 
     In one embodiment, the service center may provide a random number, a salt or a nonce specific for the protocol to the node. This may be required at the node as an input in a one-way function such as a hash function. Preferably, the salt or nonce is at least 16 bytes long. The random number, salt or nonce may relate to the information identity number described above. 
     At least one of these protocol steps may include providing configuration information to a node or reconfiguration a node or rebooting a node or any combination thereof. Preferably, a reboot step may be additionally protected by means of an authentication token, e.g., a new hash chain link. Thus, a current or valid hash chain link has to be provided to the node in order to admit permit rebooting. The service center may therefore provide the segment controller with the current hash chain link, which may be the same for several nodes, so that rebooting in a synchronized manner is possible. This may enable a more secure and stable network operation, in particular, when providing a software update to a plurality of nodes. 
     When completing the protocol, the segment controller may send a confirmation message to the service center. The confirmation message may be based on at least one response message received at the segment controller from the respective nodes. Thus, the confirmation message may include information about the identity of the respective node(s) and/or about the content of the last message from the segment controller received at the respective node(s). In the example of a software update, the last message, which the node receives from the segment controller, may include a software image, possibly encoded by a secret key. Therefore, the corresponding response message from the node to the segment controller may comprise information about the node identity and/or a fingerprint of the software image, so that the service center may verify that the right node is updated and/or that the node is updated with the right software. Therefore, the service center may be only involved in the protocol, when providing the protocol information to the segment controller and when receiving the confirmation message from the segment controller. Thus, communication with the service center is reduced, while still enabling secure controlling of the network nodes via an intermediate entity, i.e. the segment controller. 
     In a preferred embodiment of the present invention, the system is applied for telemanagement of a lighting system. For instance, the node of the wireless network may correspond to a luminaire of the lighting system, such as a street lighting system or any other lighting system. In such systems, communication between the segment controller and the service center may rely on third party structures, while communication between the segment controller and the nodes are based on the wireless transmission within the network. Therefore, reducing communication with the service center results in lower maintenance costs. 
     According to another aspect of the present invention, a control unit for a segment controller is provided allowing for secure protocol execution in a wireless network one or more nodes. By means of the control unit according to the present invention, the segment controller is adapted to perform a protocol based on protocol information provided by a service center in order to control at least one of the network nodes, wherein the execution of the protocol depends on at least one response message of the controlled node. Thus, the control unit for the segment controller according to the present invention can be applied to a segment controller of any above-described embodiment for a system according to the present invention. The control unit may be incorporated, integrated, mounted to or operatively coupled to the segment controller. 
     According to a further aspect of the present invention, a method for secure protocol execution in a wireless network having one or more nodes is provided. According to the method, protocol information is provided to a segment controller of the network for control of at least one of the network nodes. The segment controller performs the protocol based on the received protocol information. For this, the segment controller needs at least one response message of the at least one node in order to carry out the protocol. Hence, the method according to the present invention is adapted to be performed by the system or the control unit of a segment controller according to any of the above-described embodiments of the present invention. 
     These and other aspects of the invention will be apparent from and elucidated with reference to the embodiments described hereinafter. The invention will be described in more detail with respect to exemplary embodiments that are illustrated by the accompanying figures. However, the invention is not limited to these exemplary embodiments. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       In the figures: 
         FIG. 1  illustrates an example of a wireless mesh network; 
         FIG. 2  shows a flow diagram illustrating an embodiment of the present invention; 
         FIG. 3  shows a schematic view of the process of  FIG. 2 ; 
         FIG. 4  shows a diagram for a process according an embodiment of the present invention; 
         FIG. 5  illustrate the principle of a HASH chain; 
         FIG. 6  shows a flow diagram illustrating another embodiment of the present invention; 
         FIG. 7  shows a schematic view of the process of  FIG. 6 ; and 
         FIG. 8  shows a flow diagram illustrating an embodiment of the present invention. 
     
    
    
     DETAILED DESCRIPTION 
     Preferred applications of the present invention are actuator networks, sensor networks or lighting systems, such as outdoor lighting systems (e.g. for streets, parking and public areas) and indoor lighting systems for general area lighting (e.g. for malls, arenas, parking, stations, tunnels etc.). In the following, the present invention will be explained further using the example of an outdoor lighting system for street illumination, however, without being limited to this application. In the field of lighting control, the telemanagement of outdoor luminaires via radio-frequency network technologies is receiving increasing interest, in particular solutions with applicability for large-scale installations with segments of above 200 luminaire nodes. Since radio frequency (RF) transmissions do not require high transmission power and are easy to implement and deploy, costs for setting up and operating a network can be reduced. However, the data packet transmission may alternatively use infrared communication, free-space-visible-light communication or power line communication. 
     In a telemanagement system for lighting control, the number of luminaire nodes  10  is extremely high. Hence, the size of the network is very large, especially when compared to common wireless mesh networks, which typically contain less than 200 nodes. In addition, the nodes  10  typically have limited processing capabilities due to cost considerations, so that processing and memory resources in the luminaire nodes  10  will be limited. Thus, security measures and communication protocols for transmitting data packets between single nodes  10  should consider the limited resources for efficient and secure data packet transmission. Finally, compared to other so-called ad-hoc mesh networks, the telemanagement system for an outdoor lighting control network is stationary, i.e. the luminaire nodes  10  do not move. Since the luminaire nodes  10  (e.g. the lamp poles) are stationary, node positions will not change over time. Thus, the physical positions of the nodes  10 , for instance GPS-coordinates or other position data, may be known in the system, enabling geographic or position-based routing using pre-programmed or predefined positions. 
     In the following, embodiments of the present invention will be described using the example of a protocol for software updates. However, the present invention is not limited thereto and the protocol to be performed by the segment controller  60  may also relate to activation of node features and the like. 
     In  FIG. 2 , a first embodiment for ensuring secure protocol execution by the segment controller  60  is shown. In  FIG. 3 , the data traffic of the example shown in  FIG. 2  between the service center  80 , the segment controller  60  and the network node  10  is schematically illustrated. The arrows in  FIG. 3  indicate the direction of communication, while time can be considered to run in the downward direction. 
     In a first step S 200 , the service center  80  provides information for executing a protocol to the segment controller  60 . Receiving this information, the segment controller  60  starts to perform the corresponding protocol. Thus, the segment controller  60  transmits a first message to one or more nodes  10  (S 210 ), e.g. for announcing the start of the protocol. Each node  10  acknowledges the message received from the segment controller  60  with a response message including an index or identifier of the content of the received message and an identifier or key indicating the node identity (S 220 ). In step S 230 , the segment controller  60  collects the response messages from the nodes  10  and forwards them in a compressed form, e.g. aggregated in a batch message, to the service center  80 . By these means, the service center  80  can verify that the segment controller  60  has performed the first steps of the protocol correctly and successfully. This may include verifying that the first message included the correct content, that the first message was successfully received by the nodes  10  or that the segment controller  60  has transmitted the first message to the correct nodes  10 , i.e. to the target nodes of the protocol. After having determined that at least one verification was successful, the service center  80  transmits information for further steps of the protocol to the segment controller  60  (S 240 ). Thus, in step S 250 , the segment controller  60  can perform the next step of the protocol, e.g. transmitting a second message to the nodes  10 . Preferably the second message comprises the software image of the software update, which is stored by the nodes  10  in step  260 . In addition, some identifying means may be included in the first message and the second message, so that the nodes  10  can verify the content of the received second message before storing it (S 260 ). Then, in step S 270 , the nodes  10  transmit to the segment controller  60  second response messages, which dependent on the received content and the respective node identity like the first response messages. In step S 280 , the segment controller  60  aggregates the second response messages into a batch of messages and forwards it to the service center  80 . After successful verification by the service center  80 , the service center  80  provides a reboot key to the segment controller  60  for activating the new software (S 290 ). When receiving and successfully verifying the reboot key, the nodes  10  are rebooted in step  2100 . Optionally, the segment controller  60  may receive confirmation messages from the nodes  10  after rebooting and forward them in a further message batch to the service center  80 . For increasing security, also certain time intervals may be set for receiving expected messages. For instance, a maximum time interval may be set at the service center  80  for the initiation of the protocol in step S 200  and the provision of the reboot key in step S 290 . It is also to be understood that more than two steps of the protocol are controlled in this way, i.e. that there are further iterations like the steps S 200  to S 230  or S 240  to  280 . 
     Therefore, according to the embodiment shown in  FIGS. 2 and 3 , the nodes  10  report to the service center  80  via the segment controller  60 , which of the nodes  10  has received the message from the segment controller  60  and what they have received. Only after the service center  80  has verified correct protocol execution, it provides the segment controller  60  with information for further steps of the protocol. Since the segment controller  60  bundles the response messages of the single nodes  10  and forwards them in a batch message, the data traffic between the segment controller  60  and the service center  80  can be reduced. Thus, due to the dependence of the response messages of the nodes  10  on the node identity and on the content of the message received from the segment controller  60 , the segment controller  60  will only receive valid response messages, when performing the protocol correctly. Therefore, although the protocol is performed by a not fully trusted entity, i.e. the segment controller  60 , correct protocol execution can be stepwise enforced without requiring high data load on the connection to the service center  80 . 
     In  FIG. 4 , a more detailed example for the first embodiment of the present invention is shown. In this example, the service center  80  knows a commissioning key K com  common to all nodes of the network, node identities or node specific keys K node  of the network nodes  10 , a HASH-function such as SHA256 is used by the nodes in the network, a start value of the HASH-function a 0 , and at least one of an iteration number  1  of the HASH-function and a last used HASH-chain element a L . The network nodes  10 , in contrast, know the commissioning key K com , the HASH-function SHA256 of the network, a last element or anchor a N  of the HASH-chain and the last HASH-chain element a L  that has been disclosed. 
     In  FIG. 5 , the principle of a HASH-chain is illustrated. The HASH-chain includes N elements a i  that are generated using a one-way HASH-function with a L =HASH(a L−1 ). Thus, each element a i  of the HASH-chain can only be generated based on the preceding HASH-chain element a i−1 . Since only the service center  80  knows the initial HASH-chain element a 0 , only the service center  80  can generate the next HASH-chain element a i+1 . For authentication of an information, the service center  80  uses the HASH-chain elements a i  in the opposite direction, as shown in  FIG. 5 . For instance, the service center  80  includes the current HASH-chain element a L−1  in a message to the node  10 . Then, the node  10 , which only knows the last used HASH-chain element a L , can verify the message by checking whether a L =HASH(a L−1 ). By these means, information can be authenticated without need for public-key cryptography. 
     As shown in  FIG. 4 , the service center  80  initiates the execution of a software updating protocol performed by the segment controller  60  by transmitting a first message M 1  to the segment controller  60 . The first message M 1  includes a preack, the preack being the value of a function such as a message authentication-code function depending on a current HASH-chain element a L−1  and a fingerprint of the software update. Here, the fingerprint can also refer to a value of a function or a string. For instance, the preack may be obtained using the following expression:
 
 M 1:preack= HMAC ( SHA 256( E   k ( SW ))∥salt, a   L−1 ),
 
wherein the two upright lines indicate concatenation, HMAC relates to a keyed HASH-message authentication-code, SHA256 is a HASH-function SHA-2 with a 256-bit fingerprint, E K  relates to an encryption function based on an encryption key K, SW denotes the software update, salt is an at least 16 byte nonce specific for the software update and a L−1  is the current HASH-chain element. The encryption key K may be derived from the commissioning key K com  and the salt, e.g. as K=HMAC(salt, K com ). The segment controller  60  forwards the message M 1  to the node  10 , which stores the preack. The preack is used for enabling verification of the software update and the origin of the message content in a subsequent step. Since the preack has only very small information amount, memory at the nodes can be saved. Then, the node  10  creates a response message M 2  based on the message content of the received message M 1  and the node specific key K node . For instance, the response message M 2  of the node  10  may include the result of following expression:
 
 M 2: SHA 256( M 1∥ K   node )
 
In general, a message authentication code is derived from M 1  and K node . If the segment controller  60  does not receive a response message M 2  from an addressed node  10 , the segment controller  60  may request this node  10  to sent the response message M 2 . Possibly, a certain time interval is set at the segment controller  60  for defining a maximum time interval for receiving the response messages. After the segment controller  60  has received the response messages M 2   node   _   1 , . . . , M 2   node   _   N  from the respective nodes  10 , it transmits a message M 3  to the service center  80  based on the received response messages M 2   node   _   1 , . . . , M 2   node   _   N . For instance, the segment controller  60  aggregates the response messages M 2   node   _   1 , . . . , M 2   node   _   N , e.g. using the HASH-function:
 
 M 3: SHA 256( M 2 node   _   1   ∥ . . . ∥M 2 node   _   N )
 
If the service center  80  has not received the message M 3  within a predetermined time, the service center  80  may request the message M 3  from the segment controller  60 . When receiving the message M 3 , the service center  80  can verify using the message M 3  that the correct target nodes  10  have been addressed and that all target nodes  10  have successfully received the first message M 1 . Then, the service center  80  transmits a message M 4  to the segment controller  60  including the encrypted software update E K (SW), the salt and the current HASH-chain-element a L−1 . The segment controller  60  calculates a fingerprint of the encrypted software update, e.g. SHA256(E K (SW)), and transmits a message M 5  to the node  10  including the fingerprint of the encrypted software update, the salt and the current HASH-chain element a L−1 . Then, the node  10  determines whether the value of the preack received in the message M 1  is identical to the result of a predefined function, when inputting parameters received with the message M 5 . Hence, in the example shown in  FIG. 4 , the node  10  checks whether:
 
preack== HMAC ( SHA 256( E   K ( SW ))∥salt, a   L−1 ))
 
In addition, the node  10  determines whether the last used HASH-chain element a L  can be derived by applying the HASH-function to the HASH-chain element a L−1  included in the message M 5 , e.g. whether SHA256(a L−1 )=a L . If both of these verification processes are successful, the node  10  accepts the fingerprint of the encrypted software update and the salt, which were received with the message M 5 , and switches to a software update mode. Moreover, the node  10  can now calculate the encryption key K based on the salt and the commissioning key K com . Meanwhile or afterwards, the segment controller  60  transmits a further message M 6  to the node  10  including the encrypted software update. If the node  10  can verify that the previously accepted fingerprint is identical to the calculated fingerprint of the encrypted software update received with the message M 6 , it will accept the software update and store the same. Instead of transmitting the messages M 5  and M 6 , however, the segment controller  60  may also just forward the message M 4  to the node  10 . Anyway, the node  10  will return a second response message M 7  to the segment controller  60  including a fingerprint of the received encrypted software update, the salt, the current HASH-chain element a L−1  and the node specific key K node . For instance, the message M 7  may include:
 
 M 7: SHA 256( SHA 256( E   K ( SW ))∥salt∥ a   L−1   ∥K   node )
 
The segment controller  60  collects the response messages M 7   node   _   1 , . . . , M 7   node   _   N  from all nodes  10  and aggregates them into a batch message M 8 , which is transmitted to the service center  80 . After having received and verified that the message M 8  is correct, i.e. that the segment controller  60  has executed the protocol steps correctly, the service center  80  provides the segment controller  60  with message M 9  including the next HASH-chain element a L−2 . This is used by the segment controller  60  as a reboot key for rebooting the target nodes  10  and activating the new software. Thus, in the last step, the segment controller  60  forwards the message M 9  including the reboot key or HASH-chain element a L−2  to the network nodes  10 . When verifying that the HASH-chain element key a L−2  is valid, the network nodes  10  can be rebooted in a synchronized manner and the new software on the network nodes  10  is activated. Possibly, a confirmation of the successful update and rebooting is sent from the nodes via the segment controller  60  to the service center. It should be noted that instead of the HASH-function SHA256, any other cryptographic function can be used to generated a message authentication code.
 
     Thus, a fingerprint of a software update can be distributed to predetermined target nodes  10  or to all nodes  10  of the network and the nodes  10  can be rebooted in a synchronized manner. This approach uses two links of the HASH-chain to sign the software fingerprint and the rebooting message, respectively. Moreover, the software update itself is protected with a secret encryption key K specific for the software update, so that the segment controller  60  has no access to the software update. Therefore, according to the first embodiment of the present invention, a secure and economic protocol for software updates can be provided without the need of public key cryptography. 
     However, this embodiment has a few limitations. For instance, it requires that the service center  80  is online, since a software update can only be finished after providing the reboot key in the message M 8 . Moreover, the protocol can be manipulated in order to store another software on the network nodes  10 , yet without being able to activate this software. This fake software upload attack may occur as follows: After reception of message M 4 , the manipulated segment controller  60  can send a number of fake messages M 1 , so that the nodes  10  have to drop the actual message M 1  provided by the service center  80 . Then, the segment controller  60  can generate a fake message M 5  based on a fake software update. If the segment controller has even access to the commissioning key K com , the segment controller  60  may be able to generate a valid software encryption key K using the salt received with the message M 5  from the service center  80  and put another software on a node  10 . Generally, however, the segment controller  60  will have no access to the commissioning key K com  and can hence create no valid encryption key K. In this case, the segment controller  60  can only fill the memory of the node  10  with useless information. Yet, in any of these cases, the segment controller  60  cannot activate the fake software, because it lacks the HASH-chain element a L−2  as reboot key. 
     In  FIG. 6 , a second embodiment of the present invention is illustrated, which can overcome at least some of these drawbacks of the first embodiment.  FIG. 7  is a schematic view of the embodiment described with respect to  FIG. 6  indicating the direction of communication between the different entities. The main difference of this embodiment to the first embodiment is that the segment controller  60  is provided with all information for protocol execution with a first message from the service center  80 , wherein the information for different protocol steps is encrypted based on different keys. By these means, the data traffic between the service center  80  and the segment controller  60  can be minimized, so that the service center  80  only has to trigger the software update protocol and optionally receive an acknowledgement, once the protocol is finished. Thus, this allows for offline operation of the service center  80 , since the service center  80  only has to provide the first message M 0  and can then be offline for the rest of the time. 
     In a first step S 500  of  FIG. 6 , the service center  80  provides the segment controller  60  with all information required to execute a software update protocol. Yet, only a first part of this information is not encoded and can thus be used by the segment controller  60 . The segment controller  60  forwards this part of information to the respective target nodes  10  (S 510 ). Each node  10  returns a response message based on the received message content and its node identity (S 520 ). Using the response messages from the nodes  10 , the segment controller  60  is now able to generate a first encryption key (S 530 ) in order to decode a further part of protocol information. Since the response messages depend on the node identity and on the message content transmitted to the node and since the segment controller  60  is only able to decode the next part of protocol information with valid response messages, the segment controller  60  is forced to provide the correct content to the correct nodes  10  in order to be able to proceed with the protocol. Using the generated encryption key, the segment controller  60  can decode the second part of the protocol information and forward it to the network nodes  10  in step S 540 . Possibly, the network nodes  10  verify the second part of the protocol information before storing it (S 550 ). In step S 560 , the nodes  10  transmit second response messages to the segment controller  60 . Based on the second response messages, the segment controller  60  can generate the second encryption key (S 570 ) and decode a further part of the protocol information. These steps may be repeated, until the segment controller  60  can decode a reboot key included in the protocol information received from the service center  80  and forward the reboot key to the nodes (S 580 ). If the reboot key is determined to be valid, the nodes  10  are rebooted and the new software is activated (S 590 ). Preferably, the protocol is completed by transmitting a conformation message to the service center  80  in step S 5100 . This confirmation message may relate to acknowledgements of the nodes  10  aggregated by the segment controller  60 , which may respectively include the node identity or a node specific key and a fingerprint of the activated software. By means of this confirmation message, the service center  80  can verify whether all nodes  10  have been successfully updated and whether the correct software has been used. Hence, also in this embodiment, correct protocol execution by the segment controller  60  is enforced step by step and activation of new node software is only possible after successful verification of the single protocol steps. 
     In  FIG. 8 , an example for the second embodiment according to the present invention is illustrated in more detail. Similar to the example illustrated in  FIG. 4 , the service center  80  knows the commissioning key K com  of the network, the node specific keys K node  or node identities, the HASH-function of the network, e.g. SHA256, the initial HASH-chain element a 0  and the last used HASH-chain element a L  or an iteration number of the HASH-function  1 . The node  10  knows about its node specific key K node  or its node identity, the commissioning key K com , the HASH-function SHA256, the last element or anchor of the HASH-chain a N  and the last used HASH-chain element a L . For starting the protocol, the service center  80  transmits a first message M 0  including the preack and at least two further information blocks, which are encrypted based on different encryption keys K i . In the example shown, only two further information parts are shown, encrypted with encryption key K 1  and K 2 , respectively. Thus, the message M 0  may comprise:
 
 M 0:preack; E   K1 ( SHA 256( E   k ( SW )),salt, a   L−1   ,E   k ( SW )); E   K2 ( a   L−2 )
 
With the message M 0 , the segment controller  60  should be able to execute the protocol, e.g. for updating software on the nodes  10 , without further interference from the backend. However, since only the preack is not encoded, the segment controller  60  can only use the preack in the beginning. Thus, the segment controller  60  transmits a message M 1  including the preack to the node  10 . The preack value has been generated by the service center  80  based on the salt or random number specific for the software update, the current HASH-chain element a L−1  and the fingerprint of the encrypted software update. For instance, the preack value may be derived as described above for the first embodiment. After receiving the preack with the message M 1 , the nodes  10  store the preack and return a first response message M 2  that might be dependent of a fingerprint of the content of the message M 1  and the respective node specific key K node . For instance, the message M 2  may include the value of the function SHA256(M 1 ∥K node ). As described above, predefined time intervals may be set also in this embodiment for defining a maximum time interval between two messages or protocol steps. For instance, if the segment controller  60  does not receive the response messages M 2   node   _   1 , . . . , M 2   node   _   N  from all the nodes  10  within a predefined time interval, the segment controller  60  may request the response message M 2  from the corresponding node  10 . When having received all response messages M 2   node   _   1 , . . . , M 2   node   _   N , the segment controller  60  can determine a first encryption key K 1 , e.g. using a key derivation function as the next one:
 
 K 1= SHA 256( M 2 node   _   1   ∥ . . . ∥M 2 node   _   N ),
 
Using this encryption key K 1 , the segment controller  60  can decrypt the second part of the protocol information, in the above example relating to the fingerprint of the encrypted software update SHA256(E k (SW)), the salt, the current HASH-chain element a L−1  and the software update E k (SW) encrypted with the encryption key K. The encryption key K can be based on the commissioning key K com  and the salt, as described above. Then, the segment controller  60  forwards the decrypted fingerprint of the encrypted software update SHA256(E k (SW)), the salt and the current HASH-chain element a L−1  in a message M 3  to the node  10 . After having received the message M 3  from the segment controller  60 , the node  10  determines whether the preack value received with the message M 1  is identical to a predetermined function of the fingerprint of the encrypted software update, the salt and the current HASH-chain element a L−1  and whether the HASH-chain element included in the message M 3  is valid. If this is the case, the node  10  accepts the salt and the fingerprint of the encrypted software update included in the message M 3  as software fingerprint and switches to the software update mode. Based on the salt and the commissioning key K com , the node  10  can calculate the encryption key K. Then, the segment controller  60  transmits a further message M 4  including the software update encrypted with the encryption key K to the node  10 . If the result of a given fingerprint function of the received encrypted software update is identical to the previously defined fingerprint, e.g. if fingerprint=? SHA256(E K (SW) received )), the node  10  accepts the software update. Instead of transmitting two messages M 3  and M 4  to the node  10 , the segment controller  60  can also transmit only one message including the fingerprint of the encrypted software update, the salt, the current HASH-chain element a L−1  and the encrypted software update. In any case, the node  10  transmits a response message M 5  to the segment controller  60  including a value calculated based on the fingerprint of the encrypted software update, the salt, the current HASH-chain element a L−1  and the node specific key K node . For instance, the value may be calculated based on the following expression:
 
 SHA 256( E   K ( SW ))∥salt∥ a   L−1   ∥K   node )
 
     In case the segment controller  60  does not receive the response message M 5  from the respective mode  10  within a predefined time interval, the segment controller  60  may request this response message M 5 . Using the received response messages M 5   node   _   1 , . . . , M 5   node   _   N , the segment controller  60  can compute the second encryption key K 2  and decrypt the third part of protocol information that was included in the message M 0  from the service center  80 . For instance, the encryption key K 2  can be calculated based on the following expression:
 
 K 2= SHA 256( M 5 node   _   1   ∥ . . . ∥M 5 node   _   N )
 
     Optionally, the second encryption key K 2  may also be used by the segment controller  60  as a conformation message to be transmitted to the service center  80 . In a final step, the segment controller  60  transmits a message M 7  to the node  10  including a next HASH-chain element a L−2 , which is used as a reboot key and was included in the third part of protocol information. The node  10  verifies the reboot key by determining whether the HASH-chain element is correct, e.g. by determining whether:
 
 SHA 256( a   L−2 )== a   L−1  
 
If this is the case, the node  10  is rebooted and the new software is activated.
 
     The gist of this embodiment relies on the fact that the information that the segment controller  60  has to distribute to the network nodes  10  in messages M 3 , M 4  and M 7  is encrypted with different keys K 1  and K 2 . These encryption keys depend on the acknowledgements from the respective network nodes  10 . Thus, the segment controller  60  can only decrypt and therefore use the next protocol information, if all network nodes  10  send the expected acknowledgements or response messages. In this way, correct operation is enforced and ensures the right behavior of the segment controller  60 : If the segment controller  60  does not follow the protocol, it cannot use the protocol information for the next protocol steps because the information is encrypted. If the segment controller  60  behaves in the right way, it can decrypt the information and follow the expected protocol operation. Moreover, communication with the service center  80  can be reduced, since the communication takes mainly place between the partially trusted segment controller  60  and the nodes  10  without reducing system security. This allows off-line operation of the service center  80 . 
     Therefore, according to the present invention, services from the backend can be provided by enforcing correct operation of an intermediate entity that is not fully trusted. Moreover, data traffic to the backend and operations at the backend can be minimized, thus simplifying the network management. Since the communication link between the segment controller  60  of the network and the service center  80  at the backend often relies on third party infrastructures such as GPRS, this also reduces maintenance costs of a network. The embodiments of the present invention are in particular suitable for large wireless networks such as outdoor lighting systems for enabling services from the service centre  80 , e.g. for updating dimming patterns of luminaire nodes  10  in a street lighting system or for transmitting other configuration or commissioning information. Here, it is important to ensure that only nodes  10  of the network receive the information. However, the embodiments of the present invention are also applicable to any other protocol, application, system or network exhibiting a communication and trust pattern as described above, e.g. a lightweight ZigBee-IP.