Abstract:
Methods and systems for carrying different signals required for MIMO communication using a single coaxial cable between two endpoints of a distributed antenna system (DAS) network. Original MIMO signals having the same frequency are frequency-separated at a first endpoint of the network. The frequency-separated signals are propagated together over the single coaxial cable and then reconstructed to their original frequency at a second endpoint of the network.

Description:
CROSS REFERENCE TO RELATED APPLICATIONS 
     This application claims the benefit of U.S. Provisional Patent Application No. 60/889,306 filed Feb. 12, 2007, which is incorporated herein by reference in its entirety. 
    
    
     FIELD AND BACKGROUND OF THE INVENTION 
     The invention relates generally to wireless communication systems and services and more particularly to Multiple Input Multiple Output (MIMO) technology applied to Distributed Antenna Systems (DAS). 
     An internal wireless communication system is often deployed to overcome coverage problems inside buildings. The most commonly used internal coverage system is a Distributed Antenna System in which multiple antennas are distributed in the building to provide the required coverage. The antennas are connected, directly or indirectly, to a radio source through coaxial (“coax”) cables. The DAS can provide a multiplicity of wireless services in a variety of frequency bands. Since each wireless service is operated in a distinct frequency band, the services do not interfere with each other when they are propagated through the coaxial cables. Using such an architecture, it is possible to provide a multiplicity of services to each antenna of a DAS via a single coaxial cable, while the feeding point is located remotely in a service closet or in a communication room. 
     An exemplary known DAS is shown in  FIG. 1 . Three services (Service A, Service B and Service C) are connected to a service combiner  102 . The signals of the services are combined in a way that each coaxial cable  104  carries the three services. Since the services are in different frequency bands, they can be distributed on the same cable without disturbing each other. The cables connect the service combiner to antennas located in locations  1  to  4  chosen to provide optimal coverage to the covered area. 
     The emergence of the MIMO technology has changed the situation. MIMO technology is based on reception and transmission of signals that share the same spectrum, through two or more co-located antennas. That is, MIMO is a technology in which each antenna location includes multiple antennas that process different data streams at the same frequency. 
     One problem with trying to implement DAS architectures with MIMO technology is the requirement to route each of the MIMO signals in a separate coaxial cable to avoid mutual interference between the signals. This may result in significant increase in the amount of coaxial cables required and may significantly increase the cost and complexity of the installation. 
     Therefore, there is a need for and it would be advantageous to have systems and methods that supporting implementation of MIMO technology with a “conventional” DAS architecture, i.e. the use of a single coaxial cable. 
     SUMMARY OF THE INVENTION 
     The invention discloses methods and systems for carrying different signals required for MIMO communication using a single coaxial cable between two endpoints of a DAS, e.g. between a distribution point and each of the antenna locations. The single coaxial extends at least some of the path between the distribution point and each antenna. In cases it does not extend the entire path, the rest of the path may be covered by another type of cable such as a fiber optic cable. 
     The invention provides a mechanism for separating (in frequency) MIMO signals which were originally at the same frequency, in a way that the signals do not interfere with each other. This mechanism includes:
         a) Frequency shifting stages that support both Forward and Reverse paths of signals selected from the group consisting of Frequency Domain Duplexing (FDD) signals, Time Domain Duplexing (TDD) signals and a combination of FDD and TDD signals.   b) Elements that transfer a clock between a first endpoint and a second endpoint on the same single coaxial cable, to ensure accurate “shift-back” of the frequency-shifted signal.   c) In some embodiments and optionally, an element (receiver) which identifies the active channel of a given service and tunes the frequency shifting stages accordingly.
 
One original signal remains un-shifted. In this description, the following terminology is used interchangeably for frequency shifting operations: “Frequency shifting”, “frequency separation”, “frequency down-shift” or “frequency down-conversion” are used to describe the conversion of original frequencies into shifted frequencies. “Frequency reconstruction”, “frequency up-shift”, “frequency up-conversion” or “frequency shift-back” are used to describe the conversion of shifted frequencies back into original frequencies. After separation, all signals are propagated through the single coaxial cable and reconstructed (to their original frequency) at the second endpoint.
       

     The frequency down-shift and up-shift are performed at one (originating) endpoint by mixing each original signal f r  with a mixing signal f m  to create an intermediate frequency signal f i . At a second endpoint, the opposite function is performed, i.e. the mixing signal f m  is mixed with f i  to shift-back the signal to its original frequency f r . To clarify, each endpoint includes both frequency down-shift and frequency up-shift mechanisms. Since the mixing operation may include multiple unwanted products, it is necessary to pass the signals through a band pass filter (BPF). In order to bring the intermediate signal to the center of the BPF, it is necessary to know the frequency of the original signal f r  and to calculate the mixing signal accordingly, for example by using f m =f r −f i . Note that while the mixing may theoretically create four different intermediate frequencies f i =+f r +f m , f i =+f r −f m , f i =−f r +f m  and f i =−f r −f m , the last one has no physical meaning. 
     In applications in which the frequency of the original signal f r  is not known, the mixing signal f m  can not be generated. The only prior information is the frequency band in which the signal may be. In some embodiments, this problem is solved by monitoring the original (un-shifted signal) using a receiver which scans the entire band where the signal may be. Upon reception of a signal, the receiver provides the channel number of the received signal to a frequency synthesizer, which in turn generates the mixing signal based upon the information received from the receiver. In some embodiments the receiver may provide the channel number or frequency of the active channel to a central processing unit (“CPU”, not shown). The central processing then commands the synthesizer to create the required frequencies accordingly. 
     To enable accurate reconstruction of the MIMO signals, a reference frequency signal is transferred from the first endpoint to the second endpoint, using the same cable used for transferring the MIMO signals. 
     In some embodiments, there is provided a method for propagating MIMO signals in a DAS network including the steps of: (a) providing a plurality n of original MIMO signals; (b) at a first endpoint of the DAS network, frequency shifting n−1 of the MIMO signals into signals with n−1 separate frequencies, with one MIMO signal left un-shifted in frequency; (c) propagating the n−1 frequency shifted signals and the un-shifted frequency signal together over a single coaxial cable extending for at least part of a path from the first endpoint to a second endpoint of the DAS network; and, (cd) at the second endpoint, reconstructing the original MIMO signals. 
     In some embodiments, there is provided a method for propagating MIMO signals in a DAS network, including the steps of: (a) providing a plurality of MIMO signals; and (b) propagating the plurality of MIMO signals over a single coaxial cable from one endpoint to another endpoint of the DAS network. 
     In some embodiments, there is provided a system for propagating a plurality of MIMO signals in a DAS network, comprising (a) a master unit and at least one remote unit, each unit having a frequency separation mechanism for separating same-frequency original MIMO signals into frequency-separated MIMO signals and a frequency reconstruction mechanism for reconstructing the same-frequency original MIMO signals from frequency-separated MIMO signals; and (b) a single coaxial cable extending at least partially between the master unit and the at least one remote unit and used to propagate all the frequency-separated MIMO signals between the master unit and the at least one remote unit. 
     A more complete understanding of the invention, as well as further features and advantages of the invention will be apparent from the following detailed description and the accompanying drawings. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       The invention is herein described, by way of example only, with reference to the accompanying drawings, wherein: 
         FIG. 1  shows a prior art coaxial distributed antenna system (DAS). 
         FIG. 2  shows an embodiment of system of the invention; 
         FIG. 3  shows a block diagram of a Master unit; 
         FIG. 4  shows a block diagram of a Remote unit; 
         FIG. 5  shows an exemplary implementation of a Master unit; 
         FIG. 6  shows an exemplary implementation of a Remote unit; 
         FIG. 7  shows the elements of an exemplary active channel identification and system tuning; 
         FIG. 8  shows schematically the frequency shifting and shift-back procedures; 
         FIG. 9  shows a spectrum of the MIMO signals of three services received in three MIMO antennas and the spectrum of these signals after frequency shifting of signals of antennas  2  and  3 . 
     
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     The invention is based on the operation of two main units: Master and Remote. A Master unit is the unit to which the signals of the services are interfaced. A Remote unit is the unit to which the antennas are connected. A basic system includes at least one set of MIMO antennas, one Master unit and one Remote unit. The Master units are usually co-located at a central distribution point and interfaced, directly of through other distribution means, to the antenna port of the radio equipment which provides the services. The Remote units are located where coverage is required. The MIMO antennas may be positioned proximate to or attached directly to the Remote unit. When proximate, they are connected thereto by appropriate connectors. In the terminology used herein, the Master unit is associated with one endpoint while the Remote unit is associated with another endpoint of the DAS network. 
     The Master unit is used to down-convert the signals in the Forward path and up-convert the signals in the Reverse path. The Master unit is connected (directly or indirectly) to the radio equipment which generates the original signals and demodulates the received signals. Each Remote unit is used to down-convert the signals in the Reverse path and up-convert the signals in the Forward path. A single coaxial cable connected to each Remote unit is used to transfer the MIMO signal to and from the Remote unit. The coaxial cable is always connected to each Remote unit. However, in some embodiments, the coaxial cable does not necessarily extend all the way to the Master unit, but may go first to a distribution point which is connected through a coaxial or fiber cable to the Master unit. 
       FIG. 2  shows an exemplary system  200  in which three services (Service A, Service B and Service C), are distributed from a service combiner  210  to antenna arrays  208  in N locations. Each location is served by an array of three antennas connected to a Remote unit  206 . The array of the three antennas is used for reception and transmission of signals based on MIMO algorithms. Each antenna provides all three services. All signals of the three antennas, of all services, in both directions (Forward and Reverse) between a Master unit  202  and Remote unit  206 , are transferred (“propagated”) via a single coaxial cable  204 . The number of services and MIMO antennas provided in this figure are given by way of example, and it must be clear other combinations may be supported the same way (e.g. five different services and four signals corresponding to four MIMO antennas). Service combiner  210  includes N Master units  202 . Each Master unit may be connected to one or more Remote units. When connected to a plurality of Remote units, the connection may be made through such well known components as power splitters and combiners. The system is bidirectional and supports transmission of forward signals from the Master unit to the antennas and reverse signals from the antennas to the Master unit. 
     The three signals of each service received by the three antennas at each location occupy the same frequency band. In order to avoid mutual interference between the signals of a service while these are propagated through coaxial cable  204 , the signals need to be separated by means of frequency shifting. Frequency separation and frequency shift-back to the original frequencies are performed by both the Master unit and the Remote unit. 
       FIG. 3  shows a block diagram of an exemplary Master unit embodiment with details of its internal structure. The Master unit includes the following elements: a frequency shifting section  302 , a first service combiner  304 , a second service combiner  306 , a duplexer  308 , a reference oscillator  310  and a receiver  312 , interconnected as shown. According to this embodiment, the Master unit can handle three services (Service A, Service B and Service C), where each service has three different signals corresponding to the three MIMO antennas  1 ,  2  and  3 . The services themselves are in different frequency bands but the three signals of each service are in the same frequency band (see also  FIG. 9 ). Frequency shifting section  302  is used to shift the frequency band of the MIMO signals of each of the services. In some embodiments, all MIMO signals are frequency-shifted. In other embodiments, all but one of the MIMO signals are frequency shifted (see  FIG. 9 ). This is done by frequency shifting circuits included in section  302 . Such circuits are well known in the art. The un-shifted signal frequency is used in the selection of a specific active channel for referencing purposes, see e.g. the description of  FIG. 7 . To remove any doubt, the invention may be performed both without referencing (all original MIMO signals are frequency-shifted) and with referencing (all but one original MIMO signals are frequency shifted). 
     In use, in the Forward direction, signals that need to be frequency-shifted are fed to frequency shifting section  302 . Section  302  frequency shifts each of the incoming signals to a different frequency band. The shifted signals are fed to second service combiner  306  which handles the “low frequency” signals. The combined signals (now separated in frequency) are fed to duplexer  308 . Signals which are not shifted in frequency are combined by first service combiner  304  and fed to duplexer  308 . Duplexer  308  is connected through port  314 , directly or indirectly, to the Remote unit(s). 
     In the Reverse direction, signals arriving from the Remote unit are fed to frequency duplexer  308  and split to two frequency bands: “low frequency” signals which include signals that were shifted from their original frequency by the Remote unit, and “high frequency” signals which include un-shifted frequencies. The “low frequency” signals are fed to second service combiner  306  which acts in this direction as a signal splitter and splits the combined signals to the different frequency conversion paths of frequency conversion section  302 . The frequency conversion paths of frequency conversion section  302  shifts back the signals to their original frequency. 
     Reference oscillator  310  is used to synchronize the synthesizer which generates the mixing signals in the frequency shifting section. The signal of the reference oscillator is fed to second service combiner  306  where it is combined with the other signals and sent to the Remote unit. Receiver  312  in the Master unit is used for monitoring the “un-shifted” signals. The purpose of this monitoring is to enable automatic selection of a specific active channel. The following example will demonstrate the need and the implementation. The bandwidth dedicated for each service is limited (practically may range between 10 to 25 MHz). On the other hand, the operation band of some services is significantly higher then this bandwidth. For example, the operation band of the 802.11a service is 700 MHz ranges between 5.15 to 5.85 GHz. It is obvious that the whole operation band of 700 MHz can not be processed simultaneously. The 802.11a service uses only one channel at a time limited to 20 MHz bandwidth. To enable the multiplexing of the services in frequency, there is a need to identify which specific channel is in use and tune the system accordingly. 
       FIG. 4  shows a block diagram of an exemplary Remote unit embodiment with details of its internal structure. The Remote unit includes the following elements: a frequency duplexer  402 , a service combiner  404 , a frequency shifting section  408 , two service combiners  410  and  412 , a receiver  420  and a reference frequency reconstruction unit  406 . According to this example the Remote unit can handle three services (Service A, Service B and Service C), where each service has three different signals corresponding to the three MIMO antennas  414 ,  416  and  418 . The services themselves are in different frequency bands but the three signals of each service are in the frequency band of the signals of each of the services, except for one signal for each service which remains un-shifted (see  FIG. 9 ). 
     In use, in the Forward direction, the combined signal arrives at the Remote unit through frequency duplexer  402 , which separates the incoming signal into two frequency bands: a “low frequency” band  403   a  which includes the shifted signals and the reference frequency signal and a “high frequency” band  403   b  which includes the un-shifted signals. The un-shifted signals are transferred directly to Antenna  3   418 . The signals of the “low frequency” band are fed to service combiner  404  which acts in this direction as a power splitter that splits the combined signals to separate paths fed to the frequency conversion section  408 . Frequency shifting section  408  shifts back the signals to their original frequency. The signals, now in their original frequencies, are routed from frequency shifting section  408  to service combiners  410  and  412  and fed to Antennas  1  ( 414 ) and  2  ( 416 ) respectively. 
     In the Reverse direction, signals received in Antenna  3  are fed directly to frequency duplexer  402 . Signals received in Antennas  1  and  2  are fed to service combiners  410  and  412  respectively. From service combiners  410  and  412 , the signals are fed to frequency shifting section  408  where they are shifted in frequency to avoid collision between signals of the same frequency band. The shifted signals are then combined by service combiner  404  and fed to “low frequency” port  403   a  of duplexer  402 , in which they are combined with the “high frequency” signals received at port  403   b.  The combined signals are then fed through the single coaxial cable, directly or indirectly, to the Master unit. By “directly” it is meant that the signals are propagated the entire path from the Remote to the Master unit via the coaxial cable. By “indirectly” it is meant that the signals are propagated only part of the path from the Remote to the Master unit via the coaxial cable, with the other part of the path being another type of cable, for example a fiber optic cable. For example, the signals may be sent from the Remote unit, via the coaxial cable, to a “RF to optics” converter (not shown). In the “RF to optics” converter, the signals are converted from RE signals to modulated light and further propagated through a fiber optic cable for the rest of the path to the Master unit. Reference frequency unit  406  is an oscillator which is synchronized with the reference signal generated by reference oscillator  310  of the Master Unit. The reference signal is transferred to reference frequency unit  406  through service combiner  404  and duplexer  402 . 
       FIG. 5  shows the details of an exemplary implementation of a Master unit  500 . Master unit  500  is shown processing four different services in four different frequency bands. All services and frequencies mentioned herein are exemplary, and their use in examples should by no means considered as limiting the spirit and scope of the invention. In  FIG. 5 , three types of services are shown operating in MIMO mode: AWS (Wireless services at 1710-1755 MHz band uplink and 2110-2155 MHz downlink), WiFi—802.11b/g services operating in the 2.4-2.5 GHz band and WiFi—802.11a services operating in the 5.15 to 5.85 GHz band (and marked in the figures as a #). Each of these three services includes three signals (corresponding to the three MIMO antennas). An additional band, called in this example “Non-MIMO services”, handles services which do not use the MIMO algorithm and therefore use only one of the MIMO antennas. It should be noted that the structure of Master unit  500  is given as an example. Based on the same principle, different types of Master units can be created to handle other types and combinations of services. The target frequencies of the Reverse and Forward conversions in the Master and Remote units are also given as an example and other sets of frequencies can be used. 
     In operation, ports  504   a,    504   b  and  504   c  are used for signal # 1  of the three multiple signal (MIMO) services. Port  504   d  is used for “Non-MIMO services” shown in this example as ranging between 600 to 1450 MHz. In the Forward direction, the signals arriving at ports  504   a,    504   b,    504   c  (signals # 1 ) and  504   d  (low band services signal) are combined by a service combiner  512  and directed to a frequency duplexer  518 . The output of the frequency duplexer is provided directly or indirectly to the coaxial cable connected to a Remote unit, where the antenna elements are located (not shown). Ports  501 ( a  and  b ),  502 ( a  and  b ) and  503 ( a  and  b ) are used for signals AWS # 2  and AWS # 3  of the MIMO services. The b/g # 2 , b/g # 3 , a# 2  and a # 3  signals belong to WiFi services which are multiplexed in time (TDD) and therefore the same path is used for both Reverse and Forward links. Signals AWS # 2  and AWS # 3  of the AWS service are bidirectional FDD signals and therefore separated by duplexers  508   a  and  508   b  into Forward and Reverse paths. The AWS # 2  and AWS # 3  signals enter bidirectional amplification stages  505   a  and  505   b  respectively. After amplification in these stages, the Forward link signals AWS # 2  and AWS # 3  are down-converted by respective down-conversion stages  510   a  and  510   c  and filtered by respective band pass filters (BPF)  562   a  and  562   e.  Specific band pass filters are shown by way of example only, with the understanding that other types of filters in other frequency ranges may also be used and are within the scope of the invention. For example  562   a  (marked as 300 MHz BPF) is a BPF with a center frequency of 300 MHz. The bandwidth of these filters in this specific and exemplary implementation is 20 MHz. The filtered signals are combined by MUX  540 , which acts in the Forward path as a signal combiner and acts in the Reverse path as a signal splitter. The MUX in this specific implementation can handle signals ranging from DC to 510 MHz. Other types of power combiners and splitters capable of handling signals in other frequency ranges can be used and are within the scope of the invention. The output of MUX  540  is fed to the low band port of the frequency duplexer  518 , which combines the down-converted signals # 2  and # 3  of the MIMO services with signal # 1  of the MIMO services and with the “Non-MIMO services” signals. Signals b/g # 2 , b/g # 3 , a # 2  and a # 3 , fed to ports  502   a,    502   b,    503   a,    503   b  are also down-converted using similar architecture. The only difference is that each of these signals is TDD (Forward and Reverse paths use the same frequencies in different time slots) and therefore do not need to be separated to different Reverse and Forward paths with different frequency bands. 
     In the Reverse path, a bundle of frequency channels is fed to the Master unit via port  516  of frequency duplexer  518 . Frequency duplexer  518  separates these channels to “low frequencies” (below 510 MHz) and to “high frequencies (above 550 MHz). The signals above 550 MHz are either signals # 1  of the MIMO services or “Non-MIMO services” signals. These signals are directed to frequency multiplexer  512  and then separated by frequency band to their related ports. Signals below 510 MHz are routed to the “low band MUX”  540 , which acts in this direction as a signal splitter and splits the combined signals to the different frequency conversion paths. The Reverse link AWS # 2  and AWS # 3  MIMO signals are brought to the Master unit at frequency bands centered around 360 MHz and 480 MHz respectively. After passing frequency duplexer  518  and MUX  540 , these signals are filtered by band pass filters  562   b  and  562   d  respectively, followed by up-conversion in up-conversion stages  510   b  and  510   d,  respectively. These two signals are then amplified by amplifiers  505   a  and  505   d,  respectively, fed to duplexers  508   a  and  508   b  respectively and fed to ports  501   a  and  501   b  respectively. 
     The b/g # 2 , b/g # 3 , a # 2  and a # 3  WiFi signals are also up-converted using similar architecture. The only difference is that each of these signals is TDD (Forward and Reverse paths use the same frequencies in different time slots) and therefore do not need to be separated to different Reverse and Forward paths with different frequency bands. 
     Reference oscillator  522  is used as a reference to a synthesizer  720  (see  FIG. 7 ) that generates the frequencies of the frequency shifting stages. The 20 MHz reference signal shown in  FIG. 5  is exemplary. The synthesizer generates multiple frequencies shown in  FIG. 5  as “OSC”. OSC  530  which feeds mixer  526  is an example of these mixing frequencies. The signal of the reference oscillator is also fed to low band MUX  540 , which acts as a service combiner. The reference oscillator signal is combined there with all other “low frequency” signals, fed to duplexer  518  and transferred to the Remote unit. 
       FIG. 6  shows the details of an exemplary implementation of a Remote unit. The Remote unit is connected to the rest of the system via the coaxial cable and feeds an array of three antennas through ports  610 ,  612  and  614 . Port  610  is used for signals # 1  of the AWS, 802.11b/g and 802.11a services and for “Non-MIMO services”. Port  612  is used for signals # 2  of the AWS, 802.11b/g and 802.11a services. Port  614  is used for signals # 3  of the AWS, 802.11b/g and 802.11a services. 
     The b/g # 2 , b/g # 3 , a # 2  and a # 3  signals belong to WiFi services that are multiplexed in time (TDD) and therefore the same path is used for both Reverse and Forward links. Signals AWS # 2  and AWS # 3  of the AWS service are bidirectional FDD signals and therefore have separate Forward and Reverse paths. 
     In the Forward path, the signals enter the Remote unit through a port  680  and are separated by a duplexer  618  to frequencies below 510 MHz and frequencies above 550 MHz. The frequencies above 550 MHz include signal # 1  of the AWS, 802.11b/g and 802.11a services as well as of the “Non-MIMO services”. Signal # 1  of the AWS, 802.11b/g and 802.11a services as well as of the “Non-MIMO services” go directly to antenna port  610 . Forward AWS # 2  and AWS # 3  MIMO signals are brought to the Remote unit at frequency bands centered around 300 MHz and 420 MHz respectively. After passing through MUX  620  and filtered by band pass filters  662   f  and  662   b  respectively, the AWS # 2  and AWS # 3  Forward signals are up-converted by up-conversion stages  610   f  and  610   b,  respectively. Then these two signals are respectively amplified by amplifiers  605   i  and  605   g  respectively, fed to duplexers  608   b  and  608   a  respectively and fed to triplexers  644   b  and  644   a  respectively, which are used as service combiners. The b/g # 2 , b/g # 3 , a # 2  and a # 3  WiFi signals are also up-converted using similar architecture. The only difference is that each of these signals is TDD (Forward and Reverse paths use the same frequencies in different time slots) and therefore do not need to be separated to different Reverse and Forward paths with different frequency bands. 
     In the Reverse path, the signals received at MIMO antenna # 1  are fed through a port  610  and fed directly to frequency duplexer  618 . The signals received in MIMO antenna # 2  and MIMO antenna # 3  through ports  612  and  614  respectively are fed to triplexers  644   b  and  644   a,  respectively. Each triplexer separates the incoming signals to three frequency bands: 1.710-2.155 GHz for the AWS service, 2.4-2.5 GHz for the 802.11b/g service and 5.15 to 5.85 GHz band for the 802.11a service. The AWS # 2  and AWS # 3  signals enter duplexers  608   b  and  608   a  respectively and routed to amplifiers  605   h  and  605   a  respectively. After the amplification, the Reverse path signals AWS # 2  and AWS # 3  are down-converted by mixers  610   e  and  610   a  and filtered by band pass filters  662   e  and  662   a  respectively. The filtered signals are combined by low band MUX  620  which acts as a service combiner and fed to the low band port of frequency duplexer  618 , which combines the down-converted signals # 2  and # 3  of the MIMO services with signal # 1  of the MIMO services and with the “low band services” signal. Signals b/g # 2 , b/g # 3 , a # 2  and a # 3 , are also down-converted using similar architecture. The only difference is that each of these signals is TDD (Forward and Reverse paths use the same frequencies in different time slots) and therefore do not need to be separated to different Reverse and Forward paths with different frequency bands. 
     20 MHz REF  642   a  is an oscillator which is synchronized with the reference signal generated by reference oscillator 20 MHz REF  522  of the Master Unit ( FIG. 5 ). The reference signal originates in the Master signal and transfers to the 20 MHz REF  642   a  through duplexer  680  and low band MUX  620 . 
     Specific channel identification may be exemplarily based on the use of a simple receiver which monitors the transmitted data.  FIG. 7  shows the elements of an exemplary active channel identification and system tuning. Receiver  312  monitors the transmitted signals on the “legacy line”  718  which carries the un-shifted signals. This transmission contains the information on which specific channel the service is operating. When identifying which channel is in use, the receiver  312  provides this information to the synthesizer  720 . According to the information received from the receiver, the synthesizer generates the required frequencies for mixer  710  of the forward path (DL) conversion and for mixer  706  the reverse path (UL) conversion. In some embodiments, the receiver may provide the channel number or frequency of the active channel to a CPU (not shown). The CPU then commands the synthesizer to create the required frequencies accordingly. 
     The frequency shifting and shift-back are shown schematically in  FIG. 8 . They are performed by mixing the incoming signal with a signal obtained by a local oscillator. The incoming signal at frequency f r  is mixed by mixer  804  with a local oscillator  806  signal having a frequency f m . The product of the mixer may be at a frequency described by f i =±f r ±f m . A filter  808  at the output of the mixer  806  determines which of the possible combinations of f i  will be selected. 
     As an example to be used in the following explanation, the required combination may be f i =f m −f r . The signal with this frequency is fed to cable  810  and arrives through it (or through a propagation section  810 ′ that continues cable  810 , as explained above) to the Remote unit which includes, among other elements, a mixer  812 , a local oscillator  814  and a band pass filter  816 . The incoming signal at frequency f i  is mixed at mixer  812  with the signal produced by the local oscillator  814  with frequency f r . Filter  816  selects, according to this example, the frequency combination f 0 =f m′ −f i . In order for f o  to be exactly the same frequency as f r , f m′  needs to be exactly the same frequency as f m . In other words, the frequency of both local oscillators needs to be the identical.  FIG. 9  shows the spectrum of the MIMO signals of three services received in each of the three MIMO antennas ( 1 ,  2  and  3 ) and the spectrum of these signals after frequency shifting, as they are propagated along the single coaxial cable. 
     While the invention has been described with respect to a limited number of embodiments, it will be appreciated that many variations, modifications and other applications of the invention may be made. What has been described above is merely illustrative of the application of the principles of the present invention. Those skilled in the art can implement other arrangements and methods without departing from the spirit and scope of the present invention.