Patent Document

CROSS-REFERENCE TO RELATED APPLICATION 
     This application is a Continuation of U.S. application Ser. No. 10/717,601 filed Nov. 21, 2003, now U.S. Pat. No. 7,593,638 which is herein incorporated by reference in its entirety. 
    
    
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The invention relates to communication networks and optical transmission technology. Particularly, the invention relates to Ethernet passive optical networks and improving security therein using optical disturbing reflectors. 
     2. Description of the Related Art 
     In the last few years the requirements for consumer bandwidth have grown rapidly. To meet the demand for increased bandwidth new access network technologies have been developed. One such technology is based on the Institute of Electrical and Electronics Engineers (IEEE) 802.3ah standard. 802.3ah is a trademark of the IEEE inc. The standard is also known as Ethernet in the First Mile (EFM). The aim of IEEE 802.3ah is to bring Ethernet to ordinary consumers, thereby becoming an alternative for modem dial up lines and DSL connections as the primary access between a consumer and her internet service provider. The IEEE 802.3ah standard also introduces the Ethernet Passive Optical Networks (EPON) concept. The EPON is a Point-to-Multipoint (P2MP) network topology. The topology is implemented with passive optical splitters and Media Access Control (MAC) and MAC Control sublayers and physical layers that support this topology. 
     Reference is now made to  FIG. 1 , which illustrates the architecture of a prior art EPON. The EPON comprises a HUB  100 , to which an optical fiber  120  is connected. HUB  100  may be a passive physical layer signal repeater or a higher protocol layer equipment such as a bridge or a router. In some contexts a HUB is also referred to as an OLT (Optical Line Terminal). For the purpose of this invention a HUB such as HUB  100  is generally any kind of piece of network equipment that engages in communication with at least one optical network-unit in the EPON or other equivalent medium. The optical fiber must be connected to Optical Network Units (ONU)  110 ,  112 ,  114  and  116 . Typically, the ONUs are located in customer premises. HUB  100  connects the EPON to an Internet Service Provider (ISP) access router or similar equipment via an upstream connection  128 . In order to accomplish the connecting of HUB  100  to each of the ONUs  110 - 116 , an optical fiber  120  connects to an optical splitter  102 , which connects to fibers  121  and  122 . Fiber  121  connects to fibers  123  and  124  via an optical splitter  104 . Finally, fiber  123  is connected to ONU  110 , fiber  124  to ONU  112 , a fiber  125  to ONU  114  and a fiber  126  to ONU  116 . The direction from the ONUs  110 - 116  towards HUB  100  is referred to as upstream, whereas the opposite direction from HUB  100  towards the ONUs  110 - 116  is referred to as downstream. A signal  130 ,  131  transmitted from ONU  110  traverses towards HUB  100  via optical splitters  104  and  102 . However, a part of signal  130  may be reflected, for instance, from splitter  104  making the signal perceivable at ONU  112 . Upstream and downstream signal traverses in the same fiber using different wavelengths. Other option is to have separate fiber for up and downstream but this does not remove the security problem. 
     The drawback of the prior art IEEE 802.3ah is that the upstream traffic from any given ONU may be detectable from other ONU access points due to various unwanted signal reflections. The unwanted signal reflections may not be removed or even noticed from the network beforehand. The problem is further illustrated in  FIG. 2 . An ONU  202  transmits a signal  220  that is to be received exclusively by a HUB  230 . Along the transmission path from ONU  202  to HUB  230 , there is at least a first fiber  212 , an optical splitter  200  and a second fiber  210 . Fiber  210  connects to at least two fibers  212  and  214  by means of optical splitter  200 . Associated with fiber  210  is also a reflecting element  206 ; which reflects part of signal  220  as a reflection  222 , which is an unwanted reflection. Reflection  222  is in turn split at optical splitter  200  and becomes perceivable at an ONU  204 . Reflecting element  206  can be, for instance, a fiber connector, a fiber breaking point, an open fiber end or a second splitter along the fiber path between ONU  202  and HUB  230 . Reflecting elements where discrete back reflections may occur cause privacy and confidentiality problems in EPONs. The most critical places in EPONs are on the upstream side of the splitter that is closest to the transmitting user. 
     In order to overcome these problems various solutions have been proposed in prior art. One such solution is to use encryption for the upstream data traffic, for instance, so that an encrypted point-to-point data link layer connection is formed between HUB  230  and transmitting ONU  202 . The encryption may be based on a symmetric encryption method or an asymmetric encryption method. However, due to the point-to-multipoint nature of EPONs, the downstream traffic from HUB  230  to a given ONU may be encrypted in order to prevent eavesdropping by other ONUs connected to the same EPON. The key exchange mechanisms to be used in, the case where the upstream connection cannot be regarded as secure, are vastly more complicated compared to the case where the upstream connection can be regarded as, reliable. By a secure connection in this case is meant a connection supporting privacy and confidentiality. More complicated mechanisms always leads to the consumption of processing capacity, for example, in ONUs  202 ,  204 , and delays in transmission. Encryption is not a mandatory feature as such in EPON. In some implementations the system could be used without encryption. 
     An example of a key exchange mechanism to be used when the upstream connection is not reliable is the Diffie-Hellman protocol, which is disclosed, for example, in IETF RFC  2631 . If the upstream connection is secure, the establishing of a secure downstream connection from, for example, HUB  230  to ONU  202 , is rather easy. For example, it is sufficient to transmit a shared secret or encryption key from ONU  202  to HUB  230  prior to downstream signal transmission. 
     If separate fiber is used for up and downstream optical isolators can be used to overcome the security problems. This is a rather expensive solution. 
     SUMMARY OF THE INVENTION 
     The purpose of certain embodiments of the invention is to solve the problems discussed before. Particularly, the purpose of certain embodiments of the invention is to ensure secure and confidential upstream data transmission in Ethernet passive optical networks. 
     One embodiment of the invention discloses a, method for ensuring confidentiality of signal transmission in a point-to-multipoint data transmission network that includes at least one hub, at least one transmission medium and at least one station connected to the hub via the at least one transmission medium. In the method an upstream signal is transmitted from a first station. The upstream signal is reflected by at least one disturbing reflector for producing a disturbing reflection and the disturbing reflection is combined with a second reflection of the upstream signal to render the second reflection undecodable by a second station. 
     Another embodiment of the invention discloses also a system for ensuring confidentiality of signal transmission in a point-to-multipoint data transmission network including at least one hub, at least one transmission medium and at least one station connected to the hub via the at least one transmission medium. The disclosed system further includes at least one disturbing reflector placed upstream of a station and a possible point of eavesdropping, for producing a disturbing reflection of a signal transmitted by the station. The disturbing reflection combines with a second reflection of the signal. 
     Yet another embodiments of the invention also discloses a network, including at least one hub, transmission medium and at least one station connected to the hub via the transmission medium. The data transmission network further includes at least one disturbing reflector placed upstream of a station and a possible point of eavesdropping in the transmission network for producing a disturbing reflection of a signal transmitted by the station. The disturbing reflection combines with a second reflection of the signal. 
     Still another embodiment of the invention also discloses a transmission apparatus including at least one optical splitter and at least one connector for an optical network unit. The transmission apparatus further includes at least one disturbing reflector placed upstream of a station and a possible point of eavesdropping in the transmission network for producing a disturbing reflection of a signal transmitted by the station. The disturbing reflection combines with a second reflection of the signal. 
     According to certain embodiments, the disturbing reflector is beneficially located on the upstream side of a splitter, which connects the transmitting station and the station that is eavesdropping. The disturbing reflector can be also on the upstream side of the unwanted reflection. The disturbing reflector produces a disturbing signal, which makes the detection of the unwanted reflection impossible. 
     In one embodiment of the invention the second reflection is an unwanted reflection. In one embodiment of the invention the reflection and combining means include a disturbing reflector, which produces a reflection of a signal transmitted via one of the connectors, and a splitter, which combines the signal transmitted and the reflection produced. In one embodiment of the invention the transmission medium is an optical fiber. It should be noted that by an optical fiber in this case is meant either a single physical fiber or several interconnected fibers that are connected using splitters. The transmission medium may also be any other medium, for example a coaxial cable. The transmission medium may also include two separate physical circuits or channels, one for upstream traffic and the other for downstream traffic. In the case where the transmission medium is an optical fiber, the data transmission network may be an Ethernet passive optical network and the stations may be optical, network units. A disturbing reflector can be a long continuous reflector or combined from a number of discrete reflectors. Examples of reflectors are the Bragg reflectors. The disturbing reflectors may be located in a redundant branch of an optical splitter. 
     The benefits of certain embodiments of the invention are related to the confidentiality and security of signal transmission in EPONs. The method and system according to some of these embodiments is simplified since there is no need for expensive mutual key exchange algorithms. It is sufficient to provide confidentiality in the downstream transmission. Processing performance in the ONUs is saved. Similarly, the delay in the transmission of data is avoided, because the key exchange before data transmission can be simplified or omitted. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The accompanying drawings, which are included to provide a further understanding of the invention and constitute a part of this specification, illustrate embodiments of the invention and together with the description help to explain the principles of certain embodiments of the invention. In the drawings: 
         FIG. 1  is a block diagram illustrating a prior art solution that shows the structure and topology of an EPON; 
         FIG. 2  is a block diagram illustrating a prior art solution that shows a confidentiality and privacy problem associated with prior art EPONs; 
         FIG. 3  is a block diagram depicting a system, a network and a transmission apparatus utilizing the use of optical disturbing reflectors, in accordance with certain embodiments of the invention; 
         FIG. 4  is a block diagram illustrating the use of a disturbing reflector combined from discrete reflectors, in accordance with certain embodiments of the invention; 
         FIG. 5  is a block diagram illustrating the use of a single long continuous reflector, in accordance with certain embodiments of the invention; and 
         FIG. 6  is a block diagram depicting one embodiment of the invention utilizing a 2*N or N*N optical splitter. 
     
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Reference will now be made in detail to the embodiments of the present invention, examples of which are illustrated in the accompanying drawings. 
       FIG. 3  illustrates a block diagram depicting an EPON that utilizes one embodiment of the invention. The exemplary EPON includes two ONUs  202 ,  204 . ONUs  202  and  204  are connected to an optical splitter  200  that connects fiber  210  to a fiber  212  and a fiber  214 . ONU  202  acts as the transmitting terminal that is transmitting a signal  220  to fiber  210 . ONU  204  is causing a potential confidentiality problem for the transmission, since signal  220  is reflected back from a reflecting element  206  so that the intensity of the reflection permits reception at ONU  204  end of fiber  214 . Reflecting element  206  is assumed to be a part of the EPON infrastructure, which cannot be eliminated or is too difficult and/or expensive to eliminate. Besides, its precise location or reflecting quality may be unknown. In accordance with certain embodiments of the invention, fiber  210  is equipped with three disturbing reflectors  300 ,  302  and  304 . The numbers of disturbing reflectors, ONUs and HUBS mentioned herein should be seen just as examples for the purposes of the description of certain embodiments of the invention. The number of disturbing reflectors, ONUs and HUBs is thus not limited to their number in this example or any other example explained herein, but instead may vary in any embodiments or implementations of the invention. Particularly, the number of disturbing reflectors may be chosen by a network designer. 
     Signal  220  transmitted from ONU  202  is reflected at each of the disturbing reflectors  300 ,  302  and  304 , thereby generating the disturbing reflections  224 ,  226  and  228  respectively. Transmitted signal  220  may be recoverable from a reflection  222  directly, since no other signals of sufficient intensity are combined with it. From the point of view of this embodiment, reflection  222  can be denoted as an unwanted reflection. However, at reflector  300 , reflection  222  combines with a second reflection of the signal  220 , which is caused by reflector  300 . Due to propagation delay, the second reflection has a time displacement from the reflection  222 . Due to the time displacement, reflection signal  224  that includes reflection  222  and the second reflection is scrambled. The bits of reflection  222  and the second reflection are not aligned in time. Reflection signal  224  is further combined with a reflection of transmitted signal  220  at disturbing reflector  302  thereby generating a reflection signal  226  where signal  224  is further scrambled. Finally, reflection signal  226  is further combined with a reflection of the transmitted signal  220  at the disturbing reflector  304  resulting in a reflection signal  228 . When reflection signal  228  is received at ONU  204 , original signal  220  is no longer recoverable since reflection signal  228  is a combination of several reflections of original signal  220 , each reflection having a different time displacement from the start of signal  220 . 
       FIG. 4  illustrates a block diagram depicting one embodiment of the invention where disturbing reflectors are implemented as discrete reflectors, for example as Bragg reflectors. An original signal  410  sent on an optical fiber  400  is reflected at three different disturbing reflectors  402 ,  404  and  406  inserted to an optical fiber  400 . A reflected signal  412  represents a combination of each of the reflections caused by reflectors  402 ,  404  and  406 . A pulse of original signal  410  is depicted on X-axis  421  and Y-axis  420 , where Y-axis  420  represents signal intensity and X-axis  421  time. A resulting signal pulse  412  is as well depicted on X-axis  421  and-Y-axis  420 . The reflected signal  412  represents a sum of lower intensity reflections of original signal pulse  410 . Each reflection has different time displacement from the start of original signal  410  thereby producing reflected signal  412  in which signal pulse is scrambled. 
       FIG. 5  is illustrates a block diagram depicting one embodiment of the invention where disturbing reflectors are implemented as a single long continuous reflector. An optical fiber  400  along which a signal  410  is transmitted has a long continuous reflector  500 . The long continuous reflector  500  reflects signal energy of signal  410  along the whole length of long continuous reflector  500 . The reflection characteristics may vary along the length of the long continuous reflector  500 , thereby producing a reflection  502  of uneven intensity. When combined with an unwanted reflection of transmitted signal  410 , reflection  502  will scramble the unwanted reflection thereby rendering it unrecognizable. The long continuous reflector must produce a reflection of sufficient intensity taking into consideration the intensity of the reflection to be scrambled. The intensity of reflection  502  must be sufficient at all its duration in order to prevent detection of pulses from the unwanted reflection. 
       FIG. 6  is illustrates a block diagram depicting one embodiment of the invention where disturbing reflectors are used in the context of a 2*N or N*N optical splitter. A splitter  600  has two optical fibers  630  and  632  that lead towards two or more ONUs either directly or via one of several other splitters. Splitter  600  has an optical fiber  636  that is used for conveying upstream signals towards an eventual recipient. Optical fiber  636  is connected to some equipment or element that generates an unwanted reflection  624  of an upstream signal  610 . In order to provide confidentiality in accordance with the invention, an extra optical fiber  634  from splitter  600  is equipped with three discrete disturbing reflectors  602 ,  604  and  606 . The numbers of disturbing reflectors, ONUs, splitters and optical&#39; fibers mentioned herein should be seen just as examples for the purposes of the description of certain embodiments of the invention. The number of disturbing reflectors, ONUs and optical fibers is thus not limited to their number in this example, but instead may vary in any embodiments or implementations of the invention. Disturbing reflector  606  generates reflection  612 . Disturbing reflector  604  generates a reflection, which combines with the reflection  612  thereby producing a reflection  614 . Disturbing reflector  606  generates a reflection, which combines with reflection  614  thereby producing a reflection  616 . When reflection  616  combines with an unwanted reflection  624  at the splitter  600 , a reflection  622  is thus generated in which transmitted signal  610  has been rendered indistinguishable and undecodable. An ONU or an eavesdropper will not be able to decode transmitted signal  610  from reflection  622 . In addition to additive combination of reflected signals, there will also be interference of optical carriers, causing beat noise due to the optical phase differences. 
     It is obvious to a person skilled in the art that with the advancement of technology, the basic idea of the invention may be implemented in various ways. The invention and its embodiments are thus not limited to the examples described above; instead they may vary within the scope of the claims.

Technology Category: 5