Distributed antenna system for MIMO signals

Information

  • Patent Grant
  • 10491273
  • Patent Number
    10,491,273
  • Date Filed
    Monday, May 21, 2018
    6 years ago
  • Date Issued
    Tuesday, November 26, 2019
    4 years ago
Abstract
A method includes: receiving MIMO channel signals at original MIMO frequency from signal source(s) at master unit of DAS, set(s) of the MIMO channel signals including first MIMO channel signal and second MIMO channel signal; generating local oscillator signal at master unit; frequency converting first MIMO channel signal(s) and second MIMO channel signal(s) from original MIMO frequency to different frequency different from first legacy service frequency band using local oscillator signal at master unit; combining first MIMO channel signal, second MIMO channel signal, and local oscillator signal into combined signal at master unit; transmitting combined signal across optical link to remote unit; processing first MIMO channel signal and/or second MIMO channel signal at remote unit; and frequency converting converted MIMO channel signal(s) from different frequency different from first legacy service frequency band back to original MIMO frequency for transmission over antenna(s).
Description
FIELD OF THE INVENTION

Embodiments of the invention are directed to wireless communication systems, and specifically directed to distributed antenna systems for wireless MIMO communications.


BACKGROUND OF THE INVENTION

A contemporary wireless communication system for repeating wireless signals, such as distributed antenna system 10, is shown in FIG. 1, and includes a number of remote units 12 distributed to provide coverage within a service area of the system 10. In particular, each remote antenna unit 12 typically includes an antenna 14 and suitable electronics. Each remote unit is coupled to a master unit 16 with a suitable media, such as a coaxial cable or optical fiber. Each master unit 16 is, in turn, coupled to an RF combination network 18 that combines the signals from one or more (1-N) base transceiver stations (“BTS,” or more simply, “base station”) 20 (hereinafter, “BTS” 20). As illustrated in FIG. 1, the system 10 may include a plurality of master units 16 and may couple to a plurality of BTSs 20, each master unit 16 configured to provide a combination of the signals from the BTSs 20 to the various remote units 12. The link 21 between the BTSs 20 and the RF combination network 18 and various master units 16 may be a wired or wireless link.


In FIG. 1, each remote unit 12 broadcasts a wireless signal 24 that, in turn, is transceived with a wireless device 26 that may be a mobile device, such as a telephone device or a computing device. In particular, and as discussed above, the wireless signal 24 from each remote unit 12 may be a combination of signals from the BTSs 20. Thus, the wireless device 26 may communicate with the system 10 through any of the wireless signals 24 from the remote units 12. Specific embodiments of the system 10 illustrated in FIG. 1 may include ION-B systems and ION-M systems, both of which are distributed by Andrew LLC, a division of CommScope, Inc., of Hickory, N.C.


To improve wireless communications, such as communications from a base station to mobile devices, Multiple-Input/Multiple-Output (“MIMO”) technology might be utilized to provide advanced solutions for performance enhancement and broadband wireless communication systems. Substantial improvements may be realized utilizing MIMO techniques with respect to the traditional SISO systems. MIMO systems have capabilities that allow them to fully exploit the multi-path richness of a wireless channel. This is in contrast with traditional techniques that try to counteract multi-path effects rather than embrace them. MIMO systems generally rely upon multi-element antennas at both of the ends of the communication links, such as in the base station and also in the wireless device. In addition to desirable beam-forming and diversity characteristics, MIMO systems also may provide spatial multiplexing gain, which allows multi data streams to be transmitted over spatially-independent parallel sub-channels. This may lead to a significant increase in the system capacity without extending the bandwidth requirements. Generally, a SISO system, such as that illustrated in FIG. 1, cannot increase spectral efficiency by taking advantage of spatial MIMO technology.


For example, the wireless device 26 of FIG. 1 receives one signal communication signal only, though it may be in the range of a plurality of remote units 12. The wireless signals 24 from each remote unit are typically at the same frequency and carry the same data, and communication between a plurality of remote units 12 and the wireless device 26 simultaneously may result in signal degradation and collisions. In a best case scenario, the multipath nature of the communication channel can be turned into an advantage by sophisticated equalizer algorithms. However, data bandwidth from the wireless device 26 is constricted to the speed of reception and processing of data from one remote unit 12.


It is therefore, desirable to take advantage of spatial MIMO signals within a distributed antenna system.


SUMMARY OF THE INVENTION

Embodiments of the invention provide a distributed antenna system (“DAS”) that is configured to operate in a multiple-input and multiple-output (“MIMO”) mode of operation. Alternative embodiments of the invention provide a DAS that normally operates in a single-input and single-output (“SISO”) mode of operation but that has been converted to operate in a MIMO mode of operation with the addition of specified components.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 is a block diagram of a contemporary distributed antenna system.



FIG. 2A is a block diagram of a MIMO distributed antenna system (“DAS”) that includes a master unit communicating at least three signals to a remote unit consistent with embodiments of the invention.



FIG. 2B is a block diagram of the remote unit of the MIMO DAS of FIG. 2A.



FIG. 3A is a block diagram of a MIMO DAS that includes a master unit communicating at least two signals to a remote unit consistent with embodiments of the invention.



FIG. 3B is a block diagram of the remote unit of the MIMO DAS of FIG. 3A.



FIG. 4A is a block diagram of a MIMO DAS that includes a master unit communicating signals to a remote unit connected to an extension unit consistent with embodiments of the invention.



FIG. 4B is a block diagram of the remote unit of the MIMO DAS of FIG. 4A.



FIG. 4C is a block diagram of the extension unit of the MIMO DAS of FIG. 4A.



FIG. 5A is a diagrammatic illustration of a downlink portion of a conversion module in the master unit of the MIMO DAS of FIG. 2A, 3A, or 4A, while FIG. 5B is a diagrammatic illustration of an uplink portion of the conversion module in the master unit of the MIMO DAS of FIG. 2A, 3A, or 4A.



FIG. 5C is a diagrammatic illustration of a downlink portion of a conversion module in the remote unit and/or extension unit of the MIMO DAS of FIG. 2A, 3A, or 4A, while FIG. 5D is a diagrammatic illustration of an uplink portion of the conversion module in the remote unit and/or extension unit of the MIMO DAS of FIG. 2A, 3A, or 4A.



FIG. 6A is a block diagram of a legacy DAS converted to a MIMO DAS using a MIMO point of interface component as well as at least one extension unit consistent with embodiments of the invention.



FIG. 6B is a block diagram of the converted MIMO DAS system in FIG. 6A with the addition of 2-way splitters and combiners configured so that the legacy signals share antennas with at least some of the MIMO signals consistent with embodiments of the invention.



FIG. 7A is a block diagram of a legacy DAS converted to a MIMO DAS by introducing additional signals consistent with embodiments of the invention.



FIG. 7B is a block diagram of an alternative embodiment of a DAS system capable of handling MIMO signals.



FIG. 8 is a block diagram of the MIMO point of interface component of FIGS. 6A-6B.



FIG. 9 is a block diagram of frequency conversion circuitry that may be used in the MIMO point of interface component of FIG. 8.



FIG. 10 is a block diagram of an optical transceiver that may be used in the MIMO DAS of FIG. 6A, 6B, 7A, or 7B.



FIG. 11 is a block diagram of a remote unit that may be used in the MIMO DAS of FIG. 6A, 6B, 7A, or 7B.



FIG. 12 is a block diagram of an extension unit that may be used in the MIMO DAS of FIG. 6A, 6B, 7A, or 7B.



FIG. 13 is a block diagram of frequency conversion circuitry that may be used in the extension unit of FIG. 12.



FIG. 14 is a block diagram of a DAS system and master unit in accordance with an alternative embodiment of the invention;



FIG. 15 is a block diagram of the DAS system of FIG. 14 illustrating the DL path of a remote unit and extension units for such a system.





It should be understood that the appended drawings are not necessarily to scale, presenting a somewhat simplified representation of various preferred features illustrative of the basic principles of embodiments of the invention. The specific design features of the system and/or sequence of operations as disclosed herein, including, for example, specific dimensions, orientations, locations, and shapes of various illustrated components, will be determined in part by the particular intended application and use environment. Certain features of the illustrated embodiments may have been enlarged, distorted or otherwise rendered differently relative to others to facilitate visualization and clear understanding.


DETAILED DESCRIPTION OF THE INVENTION


FIG. 2A is a diagrammatic illustration of a MIMO DAS 40 consistent with embodiments of the invention that further shows downlink (“DL”) and uplink (“UL”) gain of that MIMO DAS 40. The MIMO DAS 40 includes a plurality of remote units 42 distributed to provide coverage within a service area of the MIMO DAS 40, such as inside a building or some other enclosed area. Each remote unit 42, in turn, includes at least two antennas 44a-b and suitable electronics. In various of the disclosed embodiments, a 2×2 MIMO arrangement is illustrated or discussed. It should be understood that other MIMO scenarios, such as 4×4 or 8×8, etc., would also benefit from the invention. Each remote unit 42 is coupled to a master unit 46 through at least one optical link 48, which may include one or more optical fibers (not shown), optical splitters (not shown), or other optical transmission components (not shown). As illustrated in FIG. 2A, one remote unit 42 may be connected directly to the master unit 46 through a direct optical link, such as at link 48a. Alternatively, a plurality of remote units 42 may be connected to the master unit 46 in a series connection optical link, such as at link 48b. Or a plurality of remote units 42 may be connected to the master unit 46 in a tree connection optical link, such as at link 48c. The master unit 46 is configured with a respective electrical-to-optical conversion circuit 50 for each optical link 48 to convert electrical signals at the master unit 46 to optical signals for transmission over the respective optical links 48.


In the downlink direction (e.g., from the master unit 46 to the remote unit 42), the master unit 46 receives at least one signal from at least one MIMO BTS (not shown in FIG. 2A). The master unit 46 may receive signals from other BTSs as well. Specifically, the master unit 46 may receive the signals for the remote units 42 over an input optical link (not shown), or some other suitable fashion, then separate and/or combine the signals within a particular optical link for transmission over the optical link 48 to the remote units 42. The signals from the BTSs may be electrical RF signals, or in some other form for processing. As illustrated in FIG. 2A, the master unit 46 receives two signals from at least one MIMO BTS (illustrated as “BTS SIG1” and “BTS SIG2”) as well as a signal in the 850 MHz frequency band (illustrated as “850 SIG”) at a first input optical link.


The master unit 46 may frequency convert and/or combine the signals received at an input optical link for the remote unit 42 in a conversion module 52, in accordance with aspects of the invention. Conversion modules 52a-c are illustrated in FIG. 2A for handling the various BTS signals. The master unit 46 then converts the electrical signals to optical signals with appropriate electrical-to-optical circuits 50 (50a, 50b, and 50c) and transmits or sends the optical signals to the remote units 42. Similar frequency conversion, combining, and electrical-to-optical conversion takes place for the various optical links 48a-c. In the uplink direction (from the remote unit 42 to the master unit 46), the master unit 46 receives optical signals from the remote units 42 and converts the signals from optical signals to electrical signals, then may split and/or frequency convert the signals prior to sending them to the MIMO BTS as discussed further herein.


In the downlink direction (e.g., from the master unit 46 to the remote unit 42), the master unit 46 of the embodiment of FIG. 2A is configured to receive various communication signals in suitable frequency bands as used by service providers, such as a signal in the 850 MHz communication range labeled “850 SIG”. Some such signals might be typical signals for conventional SISO systems. The master unit 46 is also configured to receive and process a plurality of MIMO signals for MIMO services. In accordance with one aspect of the invention, the MIMO signals are frequency converted so that the multiple MIMO signals may be handled over a single fiber-optic cable in the uplink and/or downlink directions without loss of the benefits of those multiple signals, such as diversity and spatial multiplexing gain benefits. For example, in accordance with one exemplary embodiment of the invention, the MIMO signals may be in a 700 MHz range, including a first MIMO signal, such as that labeled “BTS SIG1”. BTS SIG1 is frequency converted or translated to a signal that falls into a first frequency band FB1. A second MIMO signal in the 700 MHz communication range, such as that labeled “BTS SIG2”, is frequency converted to a signal that falls into a second frequency band FB2 (See FIG. 5A). The first frequency band FB1 is different from the second frequency band FB2 so that the signals may be combined on a single fiber-optic cable while maintaining their unique MIMO information. Referring to FIG. 2A, the master unit 46 then combines the signals in the 850 MHz frequency band, the frequency converted MIMO signals and an LO reference having an LO frequency LO1. The master unit 46 directs the combined signals to a remote unit 42 through the optical link 48. As seen in FIG. 2A, the various downlink signals are appropriately converted from electrical to optical signals, and are then transmitted over fiber link 48 to one or more remote units.


In the uplink direction (e.g., to the master unit 46 from the remote unit 42), the master unit 42 is configured to receive the first signal in the 850 MHz communication range. The master unit 46 also receives uplink MIMO signals in a third frequency band FB3 or a fourth frequency band FB4 and converts the signals into uplink MIMO signals with a frequency at their original MIMO frequency. The master unit also receives additional MIMO signals from an additional antenna at the remote unit in a fifth frequency band FB5 or a sixth frequency band FB6 and converts the signals into uplink MIMO signals with a frequency at the frequency of the original MIMO signals, such as in the 700 MHz band (See FIG. 5B). In the uplink direction, the uplink MIMO signals might be received in various uplink MIMO sub-bands. Therefore, for frequency conversion, those MIMO uplink sub-bands may be converted to appropriate sub-bands F3/F4 and F/5/F6 associated with each of the multiple MIMO antennas. The master unit 46 then sends the frequency converted plurality of MIMO signals back to the MIMO BTS. Similar operations may occur for each of the signals for the other optical paths 48b-c depending on whether they are frequency converted MIMO signals or non-MIMO signals. While only one particular portion of the master unit 46 and specific remote unit 42 are discussed with respect to the MIMO aspect of the invention in FIG. 2A, it will be understood that the other portions and various associated remote units 42 might also handle MIMO signals.


In some embodiments of the invention, the DAS system and the master unit 46 may be an ION-M series system and master units as distributed by Andrew LLC, a division of CommScope, Inc. of Hickory, N.C. The master unit 46 thus includes a controller 56 that operates similar to previous controllers 56 for ION-M master units 46. As such, the controller 56 controls the operation of the master unit 46 and can be configured across the Internet (the Web) as well as using simple network management protocol (“SNMP”) communications or short messaging service (“SMS”) communications. The controller 56, in turn, manages the operation of the master unit 46, such as the operation of the electrical-to-optical circuits 50a-c through RS485 communications, as well as a modem 57. The controller 56 is also configured to receive data, such as through the modem 57, from a service computer through RS232, summary alarm messages, and data about alarm messages. In turn, the controller 56 outputs data about alarm messages. With respect to the conversion modules 52a-c, the controller 56 is further configured to provide alarms related thereto, such as a ConvMod X communication failure (indicating that communication with a conversion module X is lost), a ConvMod X Current alarm (indicating that a current monitored in a conversionmodule X is too high or too low, and a ConvMod X DL LO level too low (indicating that a local oscillator for a conversion module X has received too low a level). The master unit 46 also includes a power supply unit 58 to provide power thereto.


Turning to the remote unit 42, this may be an ION-M7P/7P/85P series repeater as also distributed by Andrew LLC. In the disclosed embodiment of FIG. 2B, the uplink and downlink paths between the remote unit 42 and master unit 46 are handled by a single fiber 48. FIG. 2B illustrates that the remote unit 42 may include a wave division multiplexer 68 to split the optical signals for the single fiber-optical link 48 into downlink and uplink signals. In the downlink direction (e.g., from the master unit 46 to the antennas 44a-b), the remote unit 42 converts the downlink signals from optical signals to electrical signals using an appropriate optical-to-electrical circuit 72a. Circuit 72a outputs the signal in the 850 MHz frequency band, the converted plurality of MIMO signals, and the LO signal LO1. The converted MIMO signals are processed by a conversion module 74, which frequency converts the converted MIMO signals back to a specific MIMO band, such as the 700 MHz MIMO band. Such a conversion module is discussed herein below.


In particular, the conversion module 74 converts the downlink MIMO signals in the first and second frequency bands FB1, FB2 into MIMO signals in the original 700 MHz range (See FIG. 5C). The signals are then amplified and transmitted over an air interface by the remote unit. The remote unit 42 amplifies the downlink signals in the 850 MHz communication range and the plurality of MIMO signals with respective power amplifiers 76 (76a, 76b, and 76c). The signals are then directed to appropriate antennas. The signal in the 850 MHz communication range is combined with one of the MIMO signals in a first duplexer 78a for communication through the first antenna 44a. Another of the MIMO signals is processed through a second duplexer 78b for transmission by the second antenna 44b. As such, the remote unit 42 is configured to send and/or receive signals, such as from a wireless device 26, which may also be MIMO enabled and include multiple antennas. As discussed herein, the embodiments discuss essentially two MIMO signals and a remote unit 42 with two antennas 44a-b. However, as noted above, it will be readily understood that the invention is also applicable with systems using a greater number of MIMO signals than two.


In the uplink direction (e.g., from the remote unit 42 to the master unit 46), the remote unit 42 separates the signal in the 850 MHz communication range from one of the MIMO signals, which has a frequency in one of the 700 MHz sub-bands used for uplink MIMO signals, via the duplexer 78a. The other MIMO signal also has a frequency in one of the 700 MHz MIMO sub-bands. The duplexer, in the uplink, is configured to handle the different frequency bands or sub-bands associated with the MIMO uplink signals.


The remote unit 42 then amplifies the 850 MHz and MIMO uplink signals via respective amplifiers 80a-c, such as LNAs, and then frequency converts the MIMO signals in the conversion module 74. In particular, the remote unit 42 converts one of the MIMO signals to a frequency in the third or fourth frequency band or sub-band FB3, FB4, and converts the other MIMO signal to a frequency in the fifth or sixth frequency band or sub-band FB5, FB6. The conversion module 74 then combines the multiple MIMO signals, and the remote unit 42 provides the 850 MHz signal and the combined MIMO signals for conversion to optical signals to the electrical-to-optical circuit 72b. The remote unit 42 then wave division multiplexes the uplink optical signal onto an optical link 48 using the wave division multiplexer 70. A controller 82 controls the operation of the remote unit 42. As illustrated in FIG. 2B, the controller 82 is illustrated controlling the electrical-to-optical circuits 72a-b as well as monitoring power provided by a power supply unit 84 and through various buffers 86a-d, though one having ordinary skill in the art will appreciate that the controller 82 controls additional operations thereof, such as status, alarm management, and alarm reporting, as noted above.


As illustrated in FIGS. 2A and 2B, the MIMO DAS 40 may have a downlink gain in the 700 MHz frequency band (whether a normal communication band or a MIMO specific communication band) of about 36 dB, whether that gain is measured using ICP3 optimized methods or NF optimized methods. Moreover, the MIMO DAS 40 has a downlink gain in the 850 MHz frequency band) of about 36 dB, also whether that gain is measured using ICP3 optimized methods or NF optimized methods. Similar gains are illustrated in the 700 MHz frequency band, 700 MHz MIMO specific communication band, and 850 MHz frequency band for ICP3 optimized measurements of uplink gain. However, the MIMO DAS 40 includes, for uplink gain measured using NF optimized methods, about 43 dB of gain for the 700 MHz frequency band, 700 MHz MIMO specific communication band, and 850 MHz frequency band.


In some embodiments, a DAS system might utilize dedicated MIMO remote units, rather than combining the MIMO service with other service frequency bands. As such, the master unit 46 may transceive the two signals from at least one MIMO BTS on an optical link 48a with one or more MIMO remote units 42. In particular, two or more MIMO signals in the 700 MHz frequency band (e.g., signals labeled “BTS SIG1” and “BTS SIG2”) are utilized. FIG. 3A is a diagrammatic illustration of a MIMO DAS 100 that includes such a dedicated remote MIMO unit 102. The remote units 102 are configured to transmit two MIMO signals, such as BTS SIG1 and BTS SIG2 in a 700 MHz frequency band. As such, the remote units 102 of FIG. 3B include many similar components to the remote units 42 illustrated in FIG. 2B. It utilizes power amplifiers 76a-b, duplexers 78a-b, amplifiers 80a-b, such as LNAs, and buffers 86a-c. The frequency conversion module 74 converts the two signals similarly to the manner as disclosed above for the plurality of MIMO signals discussed in connection with FIG. 2B. The remote unit 102 transmits one MIMO signal via the first antenna unit 44a and transmits the other MIMO signal via the second antenna unit 44b. Thus, the remote unit 102 may be an ION-M7P/7P series repeater unit, as also distributed by Andrew LLC.


As illustrated in FIGS. 3A and 3B, the MIMO DAS 100 may have a downlink gain in the 700 MHz frequency band (whether a normal communication band or a MIMO specific communication band) of about 36 dB, whether that gain is measured using ICP3 optimized methods or NF optimized methods. Similar gains are illustrated in the 700 MHz frequency band and the 700 MHz MIMO specific communication band for ICP3 optimized measurements of uplink gain. However, the MIMO DAS 100 includes, for uplink gain measured using NF optimized methods, about 43 dB of gain for the 700 MHz frequency band and the 700 MHz MIMO specific communication band.


In various scenarios, legacy DAS systems may be set up as SISO systems without MIMO operable remote units. In alternative embodiments of the invention, an extension unit may be utilized in combination with the remote units to extend the range of a MIMO DAS. FIG. 4A is a diagrammatic illustration of a MIMO DAS 110 that includes a remote unit 112 configured to communicate with an extension unit 114 through an extension port. As illustrated in FIG. 4A, the master unit 46 may be configured to receive appropriate service signals from the BTS, including a signal in the 850 MHz frequency band labeled “850 SIG”, as well as a signal in the 1900 MHz frequency band labeled “1900 SIG”, and the master unit 46 also receives a plurality of MIMO signals in the 700 MHz frequency band. As such, the master unit 46 frequency converts MIMO signals in the 700 MHz frequency band to frequencies in the first or second frequency band FB1, FB2 and combines the frequency shifted MIMO signals with the signals in the 1900 MHz frequency band to send over the optical link. The master unit 46 then combines and sends the 850 SIG, the combined 1900 SIG and converted MIMO 700 SIG, and an LO reference signal across the optical link 48a to the remote unit 112.


In the downlink direction and as illustrated in FIG. 4B, the remote unit 112 receives the combined signals and converts them from optical signals to a plurality of electrical signals. As such, the remote unit 112 includes wave division multiplexer 70 and the optical-to-electrical circuits 72a-b, as discussed above. In particular, the remote unit 112 provides the signal in the 850 MHz frequency service band along a different path than the signal that contains the combined 1900 MHz frequency band service signal and the converted 700 MHz frequency MIMO band signal. As shown in FIG. 4B, the 850 MHz signals are provided directly to an antenna port 126a through duplexer 124a. The combined 1900 MHz signals are provided to a duplexer 118a that splits the 1900 MHz frequency service band signals from the frequency converted 700 MHz frequency MIMO band signals. The 850 MHz frequency band signal and the 1900 MHz frequency band signal are then amplified by respective amplifiers 122 (122a, 122b, and 122c). In turn, the 850 MHz frequency band signals are duplexed by duplexer 124a and transmitted via a first antenna 44a that may be coupled to antenna port 126a. The 1900 MHz frequency band signals are duplexed by duplexer 124b and transmitted via a second antenna 44b that may be coupled to antenna port 126b. Therefore, the remote unit handles transceiving the 850 MHz and 1900 MHz signals. In the uplink direction, the 850 MHz frequency band signals and the 1900 MHz frequency band signals are amplified by respective amplifiers 125 (125a and 125b), such as LNA's. The amplified 850 MHz frequency band signals are then provided back to the electrical-to-optical circuit 72b while the amplified 1900 MHz frequency band signals are provided to the duplexer 118b for combination with any uplink frequency shifted 700 MHz frequency MIMO band signals.


With respect to the frequency converted 700 MHz frequency MIMO band signals, they are provided, along with the LO reference, in the downlink direction, to an extension port 126 through duplexer 118a. The exterior port is connected to extension unit 114. FIG. 4C is an illustration of one embodiment of such an extension unit 114.


The extension unit 114 receives the converted 700 MHz frequency MIMO band signals, which are in the first or second frequency band FB1, FB2, and converts the signals back to the MIMO band for the air interface through the extension unit. Specifically, the extension unit converts the MIMO signals in a conversion module 128 to signals in the range of the original MIMO frequency and splits that signal. The split signals are amplified by respective power amplifiers 130 (130a and 130b) then output through respective duplexers 131 (131a and 131b) to respective antenna ports and antennas 132a and 132b. Thus, the MIMO DAS 110 transmits the signals in the 850 MHz band and the 1900 MHz band on respective antennas 44 of the remote unit 112, while transmitting the MIMO signals in the 700 MHz band on both antennas 132 of the extension unit 114.


In the uplink direction, the extension unit 114 provides MIMO signals that are received via antennas 132a and 132b in the original MIMO frequency through the respective duplexers 131a and 131b to be amplified by respective low noise amplifiers 134a and 134b. The MIMO signals are then converted into a seventh frequency band or sub-band FB7, or an eighth frequency band or sub-band FB8 in the extension unit 114 using frequency conversion module 128. This converted 700 MHz frequency band signal is, in turn, provided over the extension port 126 back to remote unit 112 to be forwarded to the master unit. In the illustrated embodiment, the MIMO signals are duplexed with the uplink 1900 MHz band frequency signal received by the remote unit and provided at duplexer 118b. The output of duplexer 118b is then processed by the electrical-to-optical circuit 72b for transmission over the optical link 48.


As illustrated in FIG. 4C, the extension unit 114 also includes a connecting board 140 that receives the RS485 signal from controller 82 of the remote unit 112 through the extension port 126. The extension unit 114 further includes a control unit 142 that controls the operation of the extension unit 114 and a power supply unit 144 that powers the extension unit 114. As illustrated in FIG. 4C, the extension unit 114 may include one or more buffers 146a-c.


As illustrated in FIGS. 4A-4C, the MIMO DAS 110 may have a downlink gain in the 700 MHz frequency band (whether a normal communication band or a MIMO specific communication band) of about 36 dB, whether that gain is measured using ICP3 optimized methods or NF optimized methods. Similar gains are illustrated in the 700 MHz frequency band and the 700 MHz MIMO specific communication band for ICP3 optimized measurements of uplink gain. However, the MIMO DAS 110 includes, for uplink gain measured using NF optimized methods, about 43 dB of gain for the 700 MHz frequency band and the 700 MHz MIMO specific communication band.


Thus, FIGS. 2A-2B, 3A-3B, and 4A-4C illustration various MIMO DAS's consistent with embodiments of the invention.


In disclosed embodiments, each frequency conversion module 52, 74, and/or 128 for the master, remote, and extension units, generally includes a downlink portion and an uplink portion for handling the signal traffic. FIG. 5A is one embodiment of a downlink portion 160 of a frequency conversion module 52/74/128 for a master unit 46 that may be used to frequency convert signals in the 700 MHz frequency band as well as to combine those converted signals with another service signal, such as a signal in the 1900 MHz frequency band. In particular, the downlink portion 160 receives the various service signals, as well as the MIMO signals, from an appropriate source, such as the BTS. The conversion module section 160 may attenuate any of the 850 MHz frequency band signals, the 1900 MHz frequency band signals, or the 700 MHz frequency MIMO band signals with respective attenuators 162 (162a, 162b, 162c, and 162d). Those signals might then be forwarded for further processing, such as amplification and/or frequency conversion, in accordance with the present invention. The downlink portion 160 provides frequency conversion by mixing with mixer 164a, the MIMO BTS SIG1 with an LO having a first frequency LO1 signal generated by a suitable LO circuitry 176 to produce a first converted MIMO signal in the first frequency band FB1. The downlink portion 160 also mixes, with mixer 164b, the MIMO BTS SIG2 with an LO signal at the second LO frequency LO2 (which is an integral multiple of the first LO signal frequency LO1) to produce another converted MIMO signal in the second frequency band FB2. These converted signals are then filtered further by respective filters 166 (166a and 166b), amplified by respective amplifiers 168 (168a and 168b), filtered further by respective filters 170 (170a and 170b), and amplified by respective amplifiers 172 (172a and 172b).


As illustrated in FIG. 5A, a frequency conversion module might also provide some combination of other service signals with the MIMO signals that have been frequency converted. Other service signals might pass directly from the master unit to the remote unit, without being significantly affected. For example, as shown in FIG. 5A, a service signal, such as a non-MIMO 800 MHz signal, might be forwarded directly through to a remote unit. Alternatively, a non-MIMO 1900 MHz signal might be combined or duplexed with the converted MIMO signals. As would be readily understood, the combination of such signals may depend upon the frequency conversion that takes places with respect to the MIMO signals and their frequency as presented onto the fiber link. In FIG. 5A, the 1900 MHz frequency band signal or other service is combined with the two converted MIMO signals by duplexer 174 to provide a combined MIMO signal to an optical-to-electrical circuit 50.



FIG. 5B is an illustration of an uplink portion 161 of a frequency conversion module 52 for a master unit 46 that may be used to split frequency converted MIMO signals in the 700 MHz frequency band from a non-converted service signal in the 1900 MHz frequency band, and to further convert the converted MIMO signals. Thus, the uplink portion 161 generally acts in the opposite manner of the downlink portion 160. For example, referring to FIG. 4B, the uplink signal from a remote unit may include frequency converted MIMO signals that are combined with a 1900 MHz signal. As such, the uplink portion 161 includes a duplexer 178 that splits the 1900 MHz frequency band signals from converted 700 MHz frequency MIMO band signals (e.g., one or more signals in the third, fourth, fifth, or sixth frequency bands/sub-bands FB3, FB4, FB5, FB6). The duplexer circuitry further splits a signal in the fifth or sixth frequency band/sub-band FB5, FB6 and the signal in the third or fourth frequency band/sub-band FB3, FB4 into two separate, frequency converted channels. The signals in the frequency converted channels are thus filtered by respective filters 180 (180a and 180b) and mixed by respective mixers 182 (182a and 182b). In particular, the signals in the fifth or sixth frequency band FB5, FB6 are mixed, by mixer 182a, with an LO signal at the first LO frequency LO1 to produce MIMO signals in desired MIMO uplink frequency bands. The signals in the third or fourth frequency band/sub-band FB3, FB4 are mixed, by mixer 182b, with the LO signal at the second LO frequency LO2 to also produce MIMO signals also in the desired MIMO uplink frequency bands. The MIMO signals in the 700 MHz frequency band in the two channels are then filtered by respective filters 184 (184a and 184b) and amplified by respective amplifiers 186 (186a and 186b), and/or then attenuated by respective attenuators 188 (188c and 188d) to output as MIMO signals BTS SIG1 and BTS SIG2 to transmit back to a BTS or other location. The 850 MHz frequency band signals and 1900 MHz frequency band signals are likewise attenuated by respective attenuators 188 (188a and 188b) as necessary.



FIG. 5C is an illustration of a downlink circuit portion 189a of a frequency conversion module 74, 128 that may be included in a remote unit 42, 102, and/or 112, or an extension unit 114. The downlink circuit portion 189a receives an LO reference signal (which is the LO signal at the first LO frequency LO1) from the master unit. The circuit also receives frequency converted MIMO signals, such as an converted 700 MHz frequency MIMO band signal, and duplexes the converted MIMO signals into two channels with a duplexer 190. The signals in each channel are then filtered with respective filters 191 (191a and 191b). In turn, the signal in one channel, which is in the first frequency band FB1, is mixed by mixer 192a with the LO signal at the first LO frequency LO1 to produce a first signal in the 700 MHz MIMO downlink frequency band. The signal in the other channel, which is in the second frequency band FB2, is mixed by mixer 192b with an LO signal at the second LO frequency LO2 (which is an integral multiple of the first LO frequency LO1) to produce a second signal in the 700 MHz MIMO downlink frequency band. The MIMO signals are then filtered via respective filters 193 (193a and 193b) and amplified by respective amplifiers 194 (194a and 194b) before being output from the conversion circuitry for eventual transmission.


Similarly, FIG. 5D is an illustration of an uplink circuitry portion 189b of a frequency conversion module 74, 128 that may be included in a remote unit 42, 102, and/or 112, or an extension unit 114. Thus, the uplink portion 189b generally acts in an opposite manner to the downlink portion 189a. The uplink portion 189b includes two channels that each receives signals in the 700 MHz MIMO uplink frequency bands or sub-bands from suitable antennas and antenna ports. The signals in the channels are filtered by respective filters 195 (195a and 195b). In turn, the signal in one MIMO channel is mixed by mixer 196a with the LO signal at the first LO frequency LO1 to produce a first frequency converted uplink signal having a frequency in the fifth frequency band FB5 and the sixth frequency band FB6. The signal in the other MIMO channel is mixed by mixer 196b with a an LO signal at the second LO frequency LO2 (which is an integral multiple of the first LO signal at frequency LO1) to produce another converted uplink signal having a frequency in the third frequency band FB3 and the fourth frequency band FB4. The first and second converted signals are then filtered by respective filters 197 (197a and 197b), amplified by respective amplifiers 198 (198a and 198b), and combined by a suitable duplexer 199. The combined converted MIMO signal is then presented for transmission, in the uplink direction, over fiber link 48, back to the master unit.


In accordance with one aspect of the invention, as illustrated in FIGS. 2A-4C, the converted MIMO signals and other service signals are transmitted between the master unit and the various remote units and extension units implementing a single fiber that handles both the uplink signals and the downlink signals. Because of the frequency conversion provided for the various MIMO signals, the integrity of the MIMO process is maintained when the multiple MIMO signals originally having the same frequency are transmitted over a single cable, such as a single fiber-optic cable or link. In such a scenario, each of the individual MIMO signals is maintained at different frequencies in both the uplink direction and the downlink direction. That is, all the uplink MIMO signals have different frequencies, and all the downlink MIMO signals have different frequencies. Furthermore, to maintain the segregation between uplink and downlink signals over a single fiber-optic cable, all of the MIMO signals being transmitted in the downlink direction are at different frequencies from those that are being transmitted in the uplink direction.


In accordance with a further embodiment of the invention, the DAS system may incorporate separate cables, such as separate fiber-optic cables, between the master unit and any remote units or extension units. In such a case, the downlink signals are handled on a separate fiber-optic cable from the uplink signals.



FIG. 6A is a diagrammatic illustration of another embodiment of a MIMO DAS 200 that may be configured using a legacy DAS system, and in particular a legacy SISO DAS. Specifically, the MIMO DAS 200 includes a master unit 202. For example, the master unit might be an ION-B master unit, as distributed by Andrew LLC. The master unit is configured to provide signals to a plurality of remote units 204, such as ION-B remote units, which are also distributed by Andrew LLC. The present invention, therefore, might be used to provide a legacy system with MIMO capabilities. In a normal mode of operation, the master unit 202 is configured to send and receive signals from one or more plurality of BTSs, such as through a BTS point of interface component 206. Such BTS Bands 1-n might be conventional, non-MIMO service bands, for example. To implement a MIMO operation, the master unit 202 is additionally configured to send and receive signals through a MIMO point of interface component 208. For purposes of illustration, the MIMO signals are illustrated as a MIMO signal in the 700 MHz frequency band (illustrated as “700 LTE CH1”) and another, different MIMO signal in the 700 MHz frequency band (illustrated as “700 LTE CH2”).


In the downlink direction, the BTS point of interface component 206 is configured to provide each of the BTS signals to a splitting/combining network 210 of the master unit 202 through a respective downlink connection, such as a coaxial cable. The MIMO point of interface component 208 is similarly configured to provide the plurality of MIMO signals in the 700 MHz frequency MIMO band to the splitting/combining network 210 through a corresponding downlink connection, such as a coaxial cable. In turn, the splitting/combining network 210 is configured to split and/or otherwise combine signals from the BTS point of interface component 206 and/or MIMO point of interface component 208 for transceiving with respective remote units 204. In operation, the splitting/combining network 210 is configured to provide the Band 1-n service signals from at least one BTS, as well as the multiple MIMO signals in the 700 MHz frequency band, to optical transceiver circuitry 212 through a suitable downlink connection, such as a coaxial cable. The various optical transceiver circuits 212, in turn, provide downlink signals to respective remote units 204 through a downlink optical link, which may be an optical fiber. As is illustrated in FIG. 6A, the uplink (UL) and downlink (DL) paths are handled over separate fiber links.


Each remote unit 204 of the MIMO DAS 200 is configured to receive the optical signals from the master unit 202, convert those signals into appropriate electrical signals, transmit various of the signals for that remote unit 204 through one or more antennas 216a-b, and couple the plurality of MIMO signals in the 700 MHz MIMO frequency band to an extension unit 214 through downlink auxiliary channels for transmission on respective antennas 218a-b thereby.


In the uplink direction, the extension unit 214 receives uplink MIMO signals in the 700 MHz frequency band or other MIMO frequency band on respective antennas 218a-b and provides those signals to the remote unit 204 over the auxiliary channels or ports. The remote unit 204, in turn, receives other service signals via the antennas 216a-b and combines those signals with the MIMO signals from the extension unit 214. The remote unit provides them via an uplink optical link, which may be an optical fiber, to the optical transceiver 212 of the master unit 202 after appropriate conversion from electrical signals, such as using suitable optical transceiver circuitry, as noted below. The optical transceiver 212, in turn, provides the combined signals to the splitting/combining network 210 through an uplink connection, which may be a coaxial cable. The splitting combining network 210 splits the combined signals back to the MIMO point of interface 208 through an uplink connection, which may be a coaxial cable, as well as the signals for the respective BTS bands 1-n for transmission back to that BTS through the BTS point of interface component 206.


Thus, the MIMO DAS 200 operates to simultaneously transmit the signal from at least one BTS through the remote unit 204 as well as a plurality of MIMO signals in the 700 MHz frequency band or other MIMO band through the extension unit 214 using a legacy DAS communication system and additional components.


In accordance with the aspects of the invention, the DAS 200 as illustrated in FIGS. 6A-6B also provides frequency translation or frequency conversion of a plurality of MIMO signals for maintaining the integrity of the MIMO system. All of the MIMO signals, including any additional service signals, are sent over dual fiber-optic cables. One fiber link is for the uplink signals and another fiber link is for the downlink signals. As illustrated in the FIGS. 6A, 6B, and 7A, although the downlink and uplink paths are handled over separate fiber-optic cables, all the MIMO signals in the downlink direction, as well as all of the MIMO signals in the uplink direction, are present on the same fiber-optic cable. As such, the present invention addresses the integrity of the MIMO process by providing suitable frequency conversion and frequency translation of the MIMO signals discussed herein.



FIG. 6B is a diagrammatic illustration of another embodiment of the MIMO DAS 200 somewhat similar to the DAS system of FIG. 6A, except in which the signals from the remote unit 204 and the extension unit 214 are combined prior to being transmitted via the appropriate antennas 216a-b and/or 218a-b. The extension unit 214 processes the various MIMO signals, however, antennas from the remote units 204 are used for transceiving the MIMO signals, in addition to antennas coupled to the extension unit 214. As such, a combiner 217a and 217b is placed between the remote unit 204 and the respective antennas 216a and 216b of the remote unit. The combiners 217a and 217b, in turn, receive signals from a splitter 219a that is coupled with the extension unit 214. The other splitter 219b is placed between the extension unit 214 and respective antennas 218a and 218b. A first output of splitter 219a is provided to a first antenna 216a of the remote unit 204, while a second output of the splitter 219a is provided to the second antenna 216b of the remote unit 204. As for splitter 219b, a first output is provided to the first antenna 218a of the extension unit 214, while a second output is provided to the second antenna 218b of the extension unit 214. In this manner, the MIMO DAS 200 operates to simultaneously transmit the signals from at least one BTS service band, and one of the signals in the 700 MHz MIMO frequency band through a first antenna 216a of the remote unit 204, simultaneously transmit the signals from at least one BTS service band and one of the signals in the 700 MHz frequency band through a second antenna 216b of the remote unit 204, and simultaneously transmit another signal in the 700 MHz MIMO frequency band through the antennas 218a and 218b of the extension unit 214. As such, the MIMO transmission is shared between the remote unit and extension unit



FIG. 7A is a diagrammatic illustration of another alternative embodiment of a MIMO DAS 220 that may be configured from a pre-existing SISO DAS, and in particular a DAS that does not use an extension unit for handling the MIMO signals. As such, the MIMO DAS 220 includes at least one master unit 202a-b for each of the multiple MIMO signals in the 700 MHz frequency band. Specifically, the MIMO DAS 220 includes a point of interface component 222a-b for each master unit 202a-b that combines multiple MIMO signals in the 700 MHz frequency band (e.g., illustrated as “MIMO BTS1 CH1,” “MIMO BTS2 CH1,” “MIMO BTS1 CH2,” and “MIMO BTS2 CH2”) with one or more other service signals from a plurality of BTSs.


In the downlink direction, for example, the point of interface component 222a combines a signal from a first MIMO BTS in a MIMO band, such as the 700 MHz frequency band, (e.g., MIMO BTS1 CH1) with a signal from a second MIMO BTS in a MIMO band, such as the 700 MHz frequency band (e.g., MIMO BTS2 CH1) and at least one service signal from at least one additional BTS. This combined signal is provided to the master unit 202a via a downlink connection, such as a coaxial cable. The master unit 202a, in turn, provides the combined signals, through the optical transceiver circuitry 212a, to remote units 204a over a set of uplink and downlink fiber cables for transmission by antennas 216a-b. Therefore, the remote units 204a handle one MIMO signal for the various MIMO bands MIMO BTS1 and MIMO BTS 2.


Similarly, the point of interface component 222b combines a signal from the first MIMO BTS in a MIMO band, such as the 700 MHz frequency band, (e.g., MIMO BTS1 CH2) with a signal from the second MIMO BTS in a MIMO band, such as the 700 MHz frequency band, (e.g., MIMO BTS2 CH2) and at least one service signal from at least one additional BTS. This combined signal is provided to the master unit 202b via a downlink connection, such as a coaxial cable, which in turn provides the combined signals to another set of remote units 204b over a separate set of uplink and downlink fiber cables for transmission by its antennas 216c-d. Therefore, the remote units 204b handle an additional MIMO signal for the various MIMO bands MIMO BTS1 and MIMO BTS2.


In that way, the segregation between various MIMO signals is maintained by implementing various master units and associated remote units, each handling a specific MIMO signal. In that way, the plurality of MIMO signals might be transmitted throughout a space, such as the inside of a building or other confined area where the DAS system might be utilized in accordance with the principles of the invention. Master unit 202a incorporates a set of downlink and uplink fiber-optic cables 215a for handling one of the MIMO signals for each of the various different MIMO services. Alternatively, the master unit 202b handles another of the MIMO signals of the various different MIMO services. As such, in accordance with one aspect of the invention, the segregation of the different MIMO signals, CH1 and CH2, for example, are maintained without requiring frequency conversion or frequency translation, as is utilized in various of the other embodiments of the invention disclosed herein.



FIG. 7B is a diagrammatic illustration of another alternative embodiment of a MIMO DAS 220a that may be configured from a pre-existing SISO DAS. The MIMO DAS 220a includes one or more extension units for handling additional MIMO signals, thereby allowing a single remote unit to accommodate more than two MIMO BTSs. In contrast to the system illustrated in FIG. 7A, which provides an optical link between a master unit and remote unit with separate uplink and downlink cables, the system in FIG. 7B is configured so that the uplink and downlink optical signals between a master unit and remote unit share a single fiber. Advantageously, this configuration may allow a legacy SISO system that uses separate fibers for uplink and downlink signals (such as those illustrated in FIGS. 6A and 6B) to handle additional MIMO signal bands, as compared to the system illustrated in FIG. 7A. The additional MIMO signals may be coupled to extension units through extension ports on a single remote unit 204c for transmission to existing antennas. The MIMO DAS 220a may thereby provide MIMO signals to the service area without the need for frequency conversion or additional optical fibers with respect to an existing legacy system having separate uplink and downlink fiber cables.


To this end, the MIMO DAS 220a includes separate master units 202c-d for each of the multiple MIMO signals in the 700 MHz frequency band. Specifically, the MIMO DAS 220a includes point of interface components 222c-d for each of the separate master units 202c-d. The point of interface components 222c-d are coupled to appropriate sources of communication signals, such as one or more BTSs, and combine multiple MIMO signals in the 700 MHz frequency band (e.g., illustrated as “MIMO BTS1 CH1,” “MIMO BTS2 CH1,” “MIMO BTS3 CH1,” “MIMO BTS4 CH1,” “MIMO BTS1 CH2,” “MIMO BTS2 CH2,” “MIMO BTS3 CH2,” and “MIMO BTS4 CH2”) with one or more other service signals (BTS Band 1-n) from one or more BTSs.


In the downlink direction, for example, the point of interface component 222c combines signals from four MIMO BTSs in chosen MIMO bands, such as the 700 MHz frequency band and other bands (e.g., MIMO BTS1 CH1, MIMO BTS2 CH1, MIMO BTS3 CH1, and MIMO BTS4 CH1), with at least one service signal from at least one additional BTS (BTS Band). This combined signal is provided to the master unit 202c via a downlink connection, such as a coaxial cable. The master unit 202c, in turn, provides the combined signals, through the optical transceiver circuitry 212c, to a remote unit 204c over a single fiber cable 215c for transmission by antennas 216e-f. To reduce the total number of fiber cables required, the downlink signal shares the fiber cable 215c with its associated uplink signal. To this end, the uplink and downlink signals are multiplexed in optical units at either end of the fiber using appropriate combining or multiplexing circuitry, such as illustrated in FIGS. 2B, 3B, and 4B.


Similarly, the point of interface component 222d combines signals from the four MIMO BTSs in a MIMO band, such as the 700 MHz frequency band, (e.g., MIMO BTS1 CH2, MIMO BTS2 CH2, MIMO BTS3 CH2, and MIMO BTS4 CH2) with at least one service signal from at least one additional BTS. This combined signal is provided to the master unit 202d via a downlink connection, such as a coaxial cable, which in turn provides the combined signals to remote unit 204c over a separate fiber cable 215d for transmission by antennas 216c-d. Therefore, the MIMO DAS 202a handles the additional MIMO signals or Channel 2 signals for the various MIMO bands MIMO BTS1, MIMO BTS2, MIMO BTS3, and MIMO BTS 4 by utilizing a second fiber (which may have served as an uplink fiber in the legacy SISO system) to deliver MIMO CH2 signals from the plurality of BTSs. The remote unit 204c receives the various different MIMO signals and processes and directs those signals appropriately for the interface. Because the Channel 1 and Channel 2 MIMO signals are handled over separate fiber links, the MIMO information on those channels remains intact without frequency translation and segregation. The remote unit 204c communicates MIMO BTS1 CH1 and CH2; and MIMO BTS2 CH1 and CH2, and other appropriate signal bands over antennas 216e and 216f.


The additional MIMO signals in the downlink direction originating from the third and fourth MIMO BTSs in the MIMO band (e.g., MIMO BTS3 CH1, MIMO BTS4 CH1, MIMO BTS3 CH2, MIMO BTS4 CH2) are received by the remote unit 204c and communicated through extension or auxiliary ports to extension units 213a-b for transmission by antennas 216e, 216f. To accommodate these additional MIMO signals, the remote unit 204c may include one or more extension ports each configured to accept connections from an extension unit 213a-b. When the extension units 213a-b are coupled to the remote unit 204c via the extension ports, additional separate uplink and downlink paths are provided through the remote unit 204c to the various extension units. The multiple extension units might be configured to handle separate MIMO channels, as shown for the MIMO 3 and MIMO 4 bands. For example, extension unit 213a handles Channel 1 signals for the additional bands, and extension unit 213b handles Channel 2 signals.


Segregation between various MIMO signals is thereby maintained by implementing various master units and associated extension units coupled by a single remote unit. The remote unit handles transmission of the MIMO signals from the first and second MIMO BTSs, and the extension units each handle specific MIMO channel signals from the third and fourth MIMO BTS's. Each of the MIMO antennas 216e, f are coupled with the remote unit and extension units to handle the Channel 1 and Channel 2 signals respectively for multiple MIMO services. In that way, the plurality of MIMO signals may be transmitted throughout a space, such as the inside of a building or other confined area where the DAS system may be utilized in accordance with the principles of the invention. Master unit 202c utilizes one fiber-optic cable 215c for handling the uplink and downlink signals for one of the MIMO channel signals for each of the various different MIMO services; and master unit 202d utilizes a second fiber-optic cable 215d for handling the other of the MIMO channel signals. Additional master units may be added as required to handle additional MIMO BTSs, with corresponding extension units 213a-b coupling the additional MIMO signals to the antennas 216e-f through signal combiners 211a-b. As such, in accordance with one aspect of the invention, the segregation of the different MIMO signals, CH1, CH2 for example, is maintained without requiring frequency conversion or frequency translation, as is utilized in various of the other embodiments of the invention disclosed herein.



FIG. 8 is a diagrammatic illustration of at least a portion of the MIMO point of interface component 208 that may be used within the MIMO DAS 200 of FIGS. 6A, 6B. Returning to FIG. 8, the MIMO point of interface component 208 processes the various MIMO signals in the MIMO band, such as a 700 MHz frequency band, in much the same way, apart from the frequencies to which they are converted/translated and combined in the end.


More specifically, the MIMO point of interface is coupled with the master unit in DAS 200 such that the interface circuit 208 handles the frequency conversion or translation rather than the master unit, and thus delivers the frequency converted MIMO signals to the master unit to then be forwarded to the various remote units. For the purposes of discussion, the different MIMO signals will be referred to as Channel 1 or CH1 and Channel 2 or CH2. As discussed above, while a 2×2 MIMO arrangement is disclosed and discussed herein, additional MIMO arrangements might be utilized, and therefore, there may be additional MIMO signals such as CH3, CH4, etc. In accordance with the invention, those signals would have to be handled in a similar fashion to provide the desirable frequency conversion and/or separate handling of the various MIMO channel signals to maintain the integrity of the MIMO process.


As such, the MIMO point of interface component 208 is configured to accept both duplexed or un-duplexed signals. In the case of duplexed signals, the signals are processed through a respective duplexer circuitry, such as triplexers 230 (230a and 230b) that separate the downlink MIMO signals from uplink MIMO signal sub-bands. When the signals are not duplexed, the downlink (DL) signal is processed through a respective triplexer 230 with the uplink (UL) signal sub-bands connected to a respective separate connector 232 (232a and 232b).


With respect to the downlink path, the MIMO channel signals are attenuated by a fixed amount with an attenuator 234 (234a, 234b) then processed through two digital attenuators 236 (236a, 236b) and 238 (238a, 238b), one of which 236 is responsible for automatic level control (“ALC”) and the other of which 238 is used to adjust the gain (e.g., in the 30 dB range, in 1 dB steps). A filter 240 (240a and 240b) filters the respective channel signals. The signals are then mixed with an appropriate LO reference in a respective mixer 242 (242a and 242b) to produce respective frequency converted signals. As illustrated in FIG. 8, the signal of the first MIMO channel CH1 is mixed by mixer 242a with an LO reference at a third LO frequency LO3. The signal of the second MIMO channel CH2 is mixed by mixer 242b with an LO reference at a fourth LO frequency LO4. As such, in the embodiment of FIG. 8, the MIMO signals CH1, CH2 are converted into a ninth frequency band FB9 (CH1) and a tenth frequency band FB10 (CH2). The frequency converted signals are filtered again with a respective filter 244 (244a and 244b), and amplified by respective amplification circuits 246 (246a and 246b). After amplification, the two downlink signals CH1 and CH2 are combined in a duplexer 248a. The combined signal is then further amplified by amplifier circuit 250 before being combined with another attenuated and filtered frequency reference as at 252 by duplexer 254. The MIMO point of interface component 208 then provides the combined signals to the master unit 202 as described above.


In the uplink (UL) direction, the MIMO uplink signals from the master unit 202 are split appropriately into two signals by a duplexer 256. For example, the MIMO signals from the various remote units might be in an eleventh frequency band FB11 and a twelfth frequency band FB12. As noted above, the MIMO uplink signals may be in various sub-bands of FB11, FB12. Each signal is then filtered by a respective filter 258 (258a and 258b), attenuated by a respective attenuator 260 (260a and 260b), filtered again by respective filter 262 (262a and 262b), and again attenuated by respective attenuator 264 (264a and 264b). Each signal is then frequency converted by a respective mixer 266 (266a and 266b). In particular, the signal on the first channel is mixed by mixer 266a with an LO reference at a fifth LO frequency LO5, while the signal on the second channel is mixed by a mixer 266b with an LO reference at a sixth LO frequency LO6. This yields MIMO uplink signals in the original MIMO uplink band. In any event, the frequency converted signals are filtered by a respective filter 268 (268a and 268b), and amplified by a respective amplifier 270 (270a and 270b) prior to being provided back to a MIMO BTS as described above.


In particular, the signals in the uplink direction are split by respective splitter 272 (272a and 272b) and duplexed into respective MIMO uplink sub-bands by respective duplexer 274 (274a and 274b). Each sub-band is attenuated by respective attenuator 276 (276a-276b) then combined with the downlink signals by the respective duplexer circuits 230. Alternatively, the signals in the uplink direction are provided directly back to the respective MIMO BTSs via the respective connectors 232.



FIG. 9 is a diagrammatic illustration of frequency conversion circuitry 280 that may be used inside the MIMO point of interface component 208 for providing desirable LO's or other frequency references for frequency conversion. A voltage controlled crystal oscillator 282 provides a reference frequency signal, such as a signal at a first reference frequency R1. A frequency divider 284 produces stabilized reference signals that are subsequently filtered. The frequency divider 284 further divides the reference frequency signal into additional paths to generate the reference signals for the synthesizers of the LO references for the MIMO point of interface component 208. The reference signals are level adjusted, amplified, and/or filtered, as necessary. In specific embodiments, the frequency conversion circuitry 280 produces a frequency reference at frequency R1 and LO references at frequencies LO3, LO4, LO5, and LO6.



FIG. 10 is a diagrammatic illustration of at least a portion of optical transceiver circuitry 212 that may be used with the MIMO DAS 200 of FIGS. 6A, 6B, or the MIMO DAS 220 of FIG. 7A, or 7B. Returning to FIG. 10, the optical transceiver circuitry 212 includes main channel and auxiliary downlink inputs, as well as main channel and auxiliary uplink inputs. In the downlink direction, the signal received on the main channel downlink input is combined with any signal received on the auxiliary downlink input in a directional coupler 290, processed through a matching network 292, amplified in amplifier 294, and converted to an optical signal by an electrical-to-optical circuit 296. The optical signal may then be split by a series of optical splitters 302a-c to output various outputs, such as to one of four optical outputs. The outputs include the signals combined from the main channel and auxiliary downlink inputs. The downlink signals are provided by appropriate downlink optical links, such as fiber-optic cables, to remote units 204. As illustrated in FIG. 10, the optical transceiver 212 may include a microprocessor 300 to control its operation.


In the uplink direction, signals received from the remote units 204 on suitable optical links, such as fiber-optic cables, provide various (e.g., one of four) inputs that are converted from an optical signal to an electrical signal by a respective electrical-to-optical circuit 304 (304a-d). The signals are amplified by a respective amplifier 306 (306a-d), and attenuated by a respective attenuator 308 (308a-d). The signals are then amplified by another respective amplifier 310 (310a-d). Each of the uplink signals received is then combined by a series of RF couplers 312a-c, processed through a matching network 314, and split between the corresponding main channel and auxiliary uplink inputs for transmission to the splitting/combining network 210 of the master unit.



FIG. 11 is a diagrammatic illustration of at least a portion of a remote unit 204 that may be used with the MIMO DAS 200 of FIGS. 6A-6B, or the MIMO DAS 220 of FIGS. 7A-7B. The remote unit 204 couples with a master unit over multiple fiber-optic cables, one dedicated for the uplink traffic, and another for the downlink traffic. In the downlink direction, the remote unit 204 receives an optical signal across a downlink optical connection and converts that signal to an electrical signal using an electrical-to-optical circuit 320a under control of a suitable microprocessor 322. The electrical signal is then amplified by an amplifier 324 and attenuated by an adjustable automatic gain control attenuator 326 also under control of the microprocessor 322. The attenuated signal is again amplified by an amplifier 328. In accordance with one aspect of the invention, the signal is split into separate signals for the remote unit 204 and for an extension unit 214 using a directional coupler 330.


The directional coupler 330 separates the main signal for the remote unit 204 to include an auxiliary signal for provision to an auxiliary signal port 351 in the remote unit. An extension unit 214 is coupled to the auxiliary port 351. Thus, the auxiliary signal is amplified by an amplifier 332 then provided to extension unit 214. The main signal, in turn, is attenuated by an adjustable attenuator 333, which may compensate for temperature variances, and duplexed by a duplexer 334 into its high frequency and low frequency band components, such as a signal in the 1900 MHz frequency band (e.g., a “high” band) and a signal in the 850 MHz frequency band (e.g., a “low” band). The high and low band signals are amplified by respective amplifiers 336 (336a and 336b), filtered by respective filters 338 (338a and 338b), and again amplified by respective high or low band amplifiers 340 (high band amplifier 340a and low band amplifier 340b). The high and low band signals are then filtered via a respective filter 344 (344a and 344b), and coupled to each antenna 216a-b via a respective coupler 346 (346a and 346b). The high and low band signals combined by respective duplexers 348 (348a and 348b) for transmission on a plurality of antennas 216a-b of that remote unit 204. Thus, the remote unit 204 simultaneously provides the high and low band signals for each antenna 216a-b.


In the uplink direction, the signals from the antennas 216a-b are separated by the duplexers 348a-b and couplers 346a-b into their respective high and low band signals. Each of the high and low band uplink signals is then filtered by a respective filter 350 (350a and 350b), amplified by a respective amplifier 352 (high band amplifier 352a and low band amplifier 352b), and attenuated by a respective adjustable attenuator 354 (354a and 354b), which may adjust the gain of the respective band. The high band signal is then amplified by an amplifier 356 while the low band signal is filtered by a filter 358. The high and low band signals are then combined into a common uplink signal via a duplexer 360. The uplink signal is attenuated by a programmable and adjustable attenuator 362 that is controlled by the microprocessor 322. The signals handled by the remote unit are then combined with any auxiliary signals from the extension unit 214 by a combiner 364. The combined uplink and auxiliary signal is then amplified by an amplifier 366 before being converted into an optical signal by an electrical-to-optical circuit 320b for being directed to a master unit over the fiber link.


As discussed above with respect to FIGS. 6A and 6B, for implementing a MIMO service within an existing DAS system, an extension unit might utilized and coupled with the remote unit for handing one or more of the plurality of MIMO signals. Such an extension unit is coupled with the remote unit, such as through an auxiliary port that has individual uplink and downlink connections, as illustrated. Such a connection might be made using a suitable link, such as a coaxial cable link.



FIG. 12 is a diagrammatic illustration of an extension unit 214 that may be used with the MIMO DAS 200 of FIGS. 6A-6B, or the MIMO DAS 220 of FIGS. 7A-7B. In FIG. 12, the downlink signal coming into the extension unit 214 is attenuated by attenuator 400 and duplexed by duplexer 402 to separate the main signal from any frequency reference that might be utilized for the frequency conversion of the MIMO signals. The frequency reference is then filtered by filters 404a-b, amplified by amplifier 406, and level controlled through an automatic level control circuit 408 prior to use for signal frequency conversion.


The downlink signal, however, is amplified by amplifier 410 then duplexed by duplexer 412 into the multiple MIMO signals, such as the two MIMO signals corresponding to those provided to the MIMO point of interface component 208 and/or point of interface component 222. Each signal is level adjusted via another respective automatic level control component 414 (414a and 414b), amplified by a respective amplification circuit 416 (416a and 416b), filtered by a respective filter 418 (418a and 418b), and frequency converted with a respective active mixer 420 (420a and 420b). In particular, the signal on the first channel (e.g., the signal in the ninth frequency band FB9) is mixed by active mixer 420a with an LO reference at the third LO frequency LO3 and frequency converted to a range of the MIMO downlink band. The signal on the second channel (e.g., the signal the tenth frequency band FB10) is mixed by active mixer 420b with an LO reference at the fourth LO frequency LO4, and frequency converted to the MIMO downlink band. Each frequency converted signal is then filtered by a respective filters 422 (422a and 422b), amplified by a respective amplifier 424 (424a and 424b), filtered by another respective filter 426 (426a and 426b), attenuated by a respective attenuator 428 (428a and 428b), and amplified by a respective amplification circuit 430 (430a and 430b) before being isolated via a respective isolator 432 (432a and 432b) and duplexed with uplink signals via a respective duplexer 434 (434a and 434b). The isolators 432a-b provide adequate matching between the output of each amplification circuit 430a-b and the antennas 218a-b.


The MIMO signals might then be directed to appropriate antennas for providing an air interface for the signals. As illustrated in the embodiment of FIG. 6A, the extension unit 214 might handle the MIMO signals exclusively with the antennas coupled to the extension unit. Alternatively, as illustrated in FIG. 6B, MIMO signals might be directed from the extension unit to other antennas, such an antennas coupled to the remote unit 204. In accordance with MIMO principles, it is desirable to transmit the MIMO downlink signals over separate antennas to provide the advantages of a MIMO scheme.


In the uplink direction, each signal received from the antennas 218a-b is separated into uplink bands or sub-bands by the respective duplexers 434a-b. Each sub-band is amplified by a respective amplifier 436 (436a-d) and attenuated by a respective attenuator 438 (438a-d). The uplink sub-bands from the first antenna 218a are combined by duplexer 440a, while the uplink sub-bands from the second antenna are combined by duplexer 440b. The respective combined uplink signals then have their levels adjusted via a respective level control component 442 (442a and 442b) and are amplified by a respective amplifier 444 (444a and 444b), filtered by a respective filter circuit 446 (446a and 446b), and attenuated by a respective attenuator 448 (448a and 448b). The combined signals are then frequency converted by a respective mixer 450 (450a and 450b). In particular, the signal on the first channel is mixed by active mixer 450a with an LO reference at the fifth LO frequency LO5 and frequency converted to the eleventh frequency band FB11, while the signal on the second channel is mixed by active mixer 450b with an LO reference of at the sixth LO frequency LO6, and thereby frequency converted into the twelfth frequency band FB12. The frequency converted signals are then duplexed together by duplexer 452. The duplexed signal is then filtered by filter 454, attenuated by attenuator 456, amplified by amplifier 458, attenuated by attenuator 460, and provided to a respective remote unit 204 over an auxiliary uplink (UL) path in an auxiliary port.



FIG. 13 is a diagrammatic illustration of frequency conversion circuitry 470 that may be used with the extension unit 214. In particular, a frequency reference filtered from the downlink path (e.g., a frequency reference having a frequency of R1) is provided to a frequency divider 472 which divides the frequency reference by four to generate the references for the synthesizers of the LO references for the extension unit 214, each of which is level adjusted, amplified, and/or filtered, as necessary. In specific embodiments, the frequency conversion circuitry 470 produces reference signals of LO3, LO4, LO5, and LO6.



FIGS. 14-15 together present an exemplary embodiment of the distributed antenna system (DAS) 500 that provides broadband coverage to an extended service area. The DAS 500 is configured to accommodate multiple bands having both MIMO and SISO signals so that the extended service area is provided with coverage from a plurality of service providers and/or broadband services operating in different bands over one single transport media, such as an optical fiber 602. Such signals are provided by one or more BTS's. For the purposes of clarity, the description of FIGS. 14-15 is limited to the downlink signal paths. However, persons having ordinary skill in the art will understand that each downlink path has an associated uplink path which is provided in essentially the same manner using similar frequency conversions and sharing the same signal links.


Referring now to FIG. 14, the DAS 500 includes one or more master units 502 that interface with a plurality of service signals 490-494 such as from one or more base station transceivers (BTSs), an optical module 504 that couples the outputs of the master unit 502 to one or more remote units 506 over fiber-optic links, and a filter unit 508 that couples the outputs of the remote units 506 to a plurality of extension units, such as, for example three extension units 510, 512, 514. The master units 502 include uplink and downlink BTS connection modules 516, 518, frequency conversion modules 520, 522, and band combining modules 524, 526. Each of the uplink and downlink BTS connection modules 516, 518 includes a plurality of radio frequency (RF) signal attenuators 530-537 and 540-547, which couple uplink signals from the DAS 500 back to the signal sources or BTSs 490-494 and downlink signals from the signal sources or BTSs 490-494 to the DAS 500, respectively.


The plurality of BTSs 490-494 may include BTSs operating in different frequency bands and supporting different air interfaces. A low-band BTS 490 transmits and receives low-band MIMO (L-MIMO or L1/L2) signals over the evolved NodeB (eNB) air interface and operates in the 800 MHz band. To support MIMO, the low-band BTS 490 has two outputs or channels, with the first output providing a L-MIMO-1 or L1 signal and the second output providing an L-MIMO-2 or L2 signal. As noted, although a 2×2 MIMO scheme is shown in the examples illustrated, the invention is not so limited to such a MIMO scheme.


A low-band legacy BTS 491 transmits and receives GSM signals in the 900 MHz band. The LL-BTS 491 of the exemplary embodiment does not support MIMO, and thus has a single output.


A mid-band BTS 492 transmits and receives mid-band MIMO (M-MIMO) signals over the eNB air interface and operates in the 1800 MHz band. As with the low-band BTS 490, the mid-band BTS 492 has two outputs or channels, with the first output providing an M-MIMO-1 or M1 signal and the second output providing an M-MIMO-2 or M2 signal.


A mid-band legacy BTS 493 transmits and receives mid-band Universal Mobile Telecommunications System (MM-UMTS) signals in the 2100 MHz band. As with the low-band legacy BTS 491, the mid-band legacy BTS 493 of the exemplary embodiment does not support MIMO, and thus has a single output.


An upper-band BTS 494 transmits and receives upper-band MIMO (U-MIMO) signals over the eNB air interface and operates in the 2600 MHz band. As with the low-band and mid-band BTSs 490, 492, the upper-band BTS 490 has two outputs or channels, with the first output providing a U1 or U1 signal and the second output providing a U-MIMO-2 or U2 signal.


The low band L1 and L2 signals from the low-band BTS 490 are coupled to the master unit 502 by duplexers 550, 552, which separate the L-MIMO signals into a uplink signals 554a, 554b and downlink signals 556a, 556b. The L1 and L2 downlink signals pass through signal attenuators 540 and 542, respectively, which couple a portion of the downlink signals to the downlink frequency conversion module 522. While embodiments of the invention herein provide frequency translation for all the MIMO signals, the embodiment in FIGS. 14 and 15 provide a translation of only one of the signals. The downlink frequency conversion module 522 provides the L1 downlink signal 556a to the band combining module 526 relatively unaltered or at its original frequency. However, to preserve the information contained in the L2 downlink signal 556b, the L2 downlink signal 556b is frequency shifted by a first appropriate shift frequency amount SF1, so that the shifted L2 downlink signal 556b* is frequency shifted from an original frequency to a different frequency such as into a thirteenth frequency band FB13. For consistency with respect to the other described embodiments, the different bands used for frequency shifting are numbered consecutively, but that does not mean that as between different embodiments the bands must be unique. Rather, an appropriate frequency band is chosen so as to provide the desired signal segregation in accordance with the invention. The L1 and shifted (as designated with an *) L2 downlink signals 556a, 556b* are provided to the downlink band combining module 526 where they are combined with other downlink signals as described in more detail below.


In a similar fashion as described with respect to the low-band BTS signals 554, 556, the LL-GSM signal from the low-band legacy BTS 491 is a non-MIMO signal, such as a SISO signal, and is coupled to the master unit 502 by duplexer 558, which separate the LL-GSM signal into a downlink signal 560 and an uplink signal 562. The LL-GSM downlink signal 560 passes through signal attenuator 541, which couples a portion of the downlink signal 560 to the downlink frequency conversion module 522. The downlink frequency conversion module 522 provides the LL-GSM downlink signal 560 to the band combining module 526 relatively unaltered or unshifted or at the original frequency, where it is combined with other downlink signals.


The M-MIMO-1 (M1) and M-MIMO-2 (M2) signals from the mid-band BTS 492 are coupled to the master unit 502 by duplexers 564, 566, which separate the M-MIMO signals into uplink signals 568a, 568b and downlink signals 570a, 570b. The M1 and M2 downlink signals 570a, 570b pass through signal attenuators 543 and 545, respectively, which couple portions of the downlink signals 570a, 570b to the downlink frequency conversion module 522. Similarly to the low-band MIMO signals, the downlink frequency conversion module 522 provides the M1 downlink signal 570a to the band combining module 526 relatively unaltered or unshifted or at an original frequency. However, to preserve the information contained in the M2 downlink signal 570b, the M2 downlink signal 570b is frequency shifted by a shift frequency amount SF2, so that the M2 downlink signal 570b* is shifted from an original frequency to a different frequency such as into a fourteenth frequency band FB14. The M1 and shifted M2 downlink signals 570a, 570b* are provided to the downlink band combining module 526 where they are combined with other downlink signals.


The MM-UMTS signal from the mid-band legacy BTS 493 is a non-MIMO signal, such as a SISO signal, and is coupled to the master unit 502 by duplexer 572, which separate the MM-UMTS signal into an uplink signal 574 and a downlink signal 576. The MM-UMTS downlink signal 576 passes through signal attenuator 544, which couples a portion of the downlink signal 576 to the downlink frequency conversion module 522. The downlink frequency conversion module 522 provides the MM-UMTS downlink signal 576 to the band combining module 526 relatively unaltered or unshifted or at the original frequency, where it is combined with other downlink signals.


The U-MIMO-1 (U1) and U-MIMO-2 (U2) signals from the upper-band BTS 494 are coupled to the master unit 502 by duplexers 578, 580, which separate the U-MIMO signals into uplink signals 582a, 582b and downlink signals 584a, 584b. The U1 and U2 downlink signals 584a, 584b pass through signal attenuators 546 and 547, respectively, which couple portions of the downlink signals 584a, 584b to the downlink frequency conversion module 522. Similarly to the low and mid-band MIMO signals, the downlink frequency conversion module 522 provides the U1 downlink signal 584a to the band combining module 526 relatively unaltered of unshifted or at an original frequency. However, to preserve the information contained in the U2 downlink signal 584b, the U2 downlink signal 584b is frequency shifted a shift frequency amount SF3, so that the shifted U2 downlink signal 584b* is shifted from an original frequency to a different frequency such as into a fifteenth frequency band FB15. The U1 and shifted U2 downlink signals 584a, 584b* are provided to the downlink band combining module 526 where they are combined with other downlink signals for transmission to the remote unit 506.


In order to keep the MIMO channel signals for each MIMO band or MIMO set the master unit from interfering with each other, the master unit is operable to convert the various MIMO channel signals to different frequencies wherein the different frequency of one set of MIMO channel signals is different from the different frequency of another set of MIMO channel signals. For example, as discussed above, each of the FB13, FB14, and FB15 frequencies or frequency bands are different so that they may be transceived over the same fiber optic cable without interfering with each other.


The downlink band combining module 526 includes a low-band duplexer 586, and a high band duplexer 588. The low band duplexer 586 is coupled to L1 signal 556a, LL-GSM signal 560, frequency converted M2 signal 570b*, and frequency converted U2 signal 584b*. The aforementioned signals are thereby combined into a composite low band downlink signal 590 that includes signals in the fourteenth and fifteenth frequency bands FB14, FB15 as well as frequencies in about the 800 MHz and 900 MHz ranges. Similarly, the high band duplexer 588 is coupled to the frequency converted L2 signal 556b*, the MM-UMTS signal 576, and the U1 signal 584a. The aforementioned signals are thereby combined into a composite high band downlink signal 592 that includes signals in the thirteenth frequency band FB13 as well as frequencies in about the 2100 and 2600 MHz ranges. The remaining M1 signal 570a is passed through the band combining module relatively unaltered. The bands used for frequency shifting may be chosen so as to be close to existing service bands that are already being handled. That is one or more of the MIMO channel signals are converted to a different frequency that is close to the original frequency of the unshifted or original frequency of the MIMO or non-MIMO signals. In that way, the signals may be efficiently combined and separated at the remote and master units using appropriate band combining and band separating circuit components such as combiners and duplexers. For example, the frequency converted M2 and U2 signals are converted so as to be close to the L-band (800 MHz) and LL-Band (900 MHz). Alternatively, the shifted L2 signal is shifted so as to be close to the MM-band (2100 MHz) and U-band (2600 MHz). As such efficient use of components is provided.


The M1 downlink signal 570a, composite low-band downlink signal 590, and composite high-band downlink signal 592 are coupled to the optical module 504. The optical module 504 includes an appropriate electrical-to-optical circuit 594, an optical-to-electrical circuit 596, and a wavelength-division multiplexer 598. The wavelength-division multiplexer 598 couples the composite optical downlink signal having a first wavelength, or color onto the optical fiber 602 and extracts the composite uplink signal having a second wavelength, or color from the same optical fiber 602. The M1 and composite downlink signals 570a, 590, 592 are coupled to the input of electrical-to-optic circuit 594, which converts the signals into a composite downlink optical signal 600. The composite downlink optical signal 600 is coupled to the optical fiber 602, for transporting the composite downlink optical signal 600 to the remote unit 506.


Referring now to FIG. 15, the remote unit 506 is configured to receive and transmit optical signals over the optic fiber 602, convert between optical signals and electrical signals, and receive and transmit RF electrical signals via one or more extension units 510, 512, 514 and via one or more antennas 618. The remote unit 506 thereby provides wireless coverage to the extended service area. To this end, the remote unit 506 includes an optical module 604, a low-band downlink duplexer 606, a high-band downlink duplexer 608, power amplifiers 610-612, a post-amplification duplexer 614, an antenna feed duplexer 616, an antenna 618, and one or more extension ports 628.


The optical module 604 includes a wavelength-division multiplexer 620 that is coupled to an optical-to-electrical downlink receiver circuit 622 and an electrical-to-optical uplink transmitter circuit 624. The composite downlink optical signal 600 is coupled from the optic fiber 602 to the optical-to-electrical circuit 622 by the wavelength-division multiplexer 620. In turn, the optical-to-electrical circuit 622 converts the composite downlink optical signal 600 into a composite downlink electrical signal, thereby recovering the M1 signal 570a, low-band composite downlink signal 590, and high-band composite downlink signal 592.


The low-band and high-band composite downlink signals 590, 592 are coupled to the low-band and high-band downlink duplexers, 606, 608 respectively. In turn, the low-band downlink duplexer 606 separates the low-band composite downlink signal 590 into L1 signal 556a, LL-GSM signal 560, and a U/M-MIMO-2 composite signal 626 comprising the frequency shifted M2 and U2 signals 570b*, 584b*. Similarly, the high-band downlink duplexer 608 separates the high-band composite signal 592 into the frequency shifted L2 signal 556b*, MM-UMTS signal 576, and U1 signal 584a.


The LL-GSM signal 560, M1 signal 570a, and MM-UMTS signal 576 are coupled to power amplifiers 610, 611, and 612 respectively, which amplify the signals to a level suitable for providing wireless coverage. In turn, the resulting amplified signals are coupled to antenna 618 by the post-amplification and antenna duplexers 614, 616. The remote unit 506 thereby provides wireless coverage to the extended service area by extending the coverage of the low-band and mid-band legacy BTSs 491, 493. The remote unit 506 also extends the service area for the M1 signal 570a.


In the specific embodiment illustrated in FIG. 15, the remaining L1 signal 556a, frequency shifted L2 signal 556b*, U1 signal 584a, and U/M-MIMO-2 composite signal 626 are coupled to an appropriate filter unit 508 through the extension port 628, which is coupled to an input port 630 of the filter unit 508 via suitable transmission lines. However, it should be understood that in alternative embodiments, a suitably configured extension unit may be coupled directly to the extension port 628, in which case the filter unit 508 would be omitted. In the embodiment illustrated in FIG. 15, the filter unit 508 includes, in addition to the input port 630, three output ports 632-634 and a duplexer 636 that separates the frequency shifted M2 and U2 signals 570b*, 584b*. The filter unit 508 is thereby configured so that:

    • (1) the L1 and frequency shifted L2 signals 556a, 556b* are coupled to the first filter unit output port 632, which in turn is coupled to the first extension unit 510;
    • (2) the frequency shifted M2 signal 570b* is coupled to the second filter unit output port 633, which in turn is coupled to the second extension unit 512; and
    • (3) the U1 and frequency shifted U2 signals 584a, 584b* are coupled to the third filter unit output port 634, which in turn is coupled to the third extension unit 514.


The first extension unit 510 includes a frequency conversion circuit 638, transmit/receive duplexers 640, 642, power amplifiers 644, 646 and antennas 648, 650. The frequency shifted L2 signal 556b* is coupled to the input of the frequency conversion circuit 638, which shifts the signal by the first shift frequency amount SF1 so that the frequency range of the L2 signal 556b is restored to the same frequency range as the original L1 signal 556a for the air interface. The L1 and restored L2 signals 556a, 556b are coupled to the inputs of appropriate power amplifiers 644, 646, which in turn amplify the signals to a power level sufficient to cover the extended service area. The outputs of the power amplifiers 644, 646 are coupled to antennas 648, 650 by the transmit/receive duplexers 640, 642. The first extension unit 510 thereby extends the coverage of the low-band BTS 490 into the service area.


The second extension unit 512 includes a frequency conversion circuit 652, a transmit/receive duplexer 654, a power amplifier 656, and an antenna 658. The frequency shifted M2 signal 570b* is coupled to the input of the frequency conversion circuit 652, which shifts the signal by the second shift frequency amount SF2 so that the frequency range of the M2 signal 570b is restored to the same frequency range as the original M1 signal 570a. The restored M2 signal 570b is coupled to the input of power amplifier 656, which in turn amplifies the signal to a power level sufficient to cover the extended service area. The output of the power amplifier 656 is coupled antenna 658 by the transmit/receive duplexer 654. The second extension unit 512, working in cooperation with the remote unit 506 (which transmits the M1 signal 570a) thereby extends the coverage of the mid-band BTS 492 into the service area.


The third extension unit 514 includes a frequency conversion circuit 660, transmit/receive duplexers 662, 664, power amplifiers 666, 668 and antennas 670, 672. The frequency shifted U2 signal 584b* is coupled to the input of the frequency conversion circuit 660, which shifts the signal by the third shift frequency amount SF3 so that the frequency range of the U2 signal 584b is restored to the same frequency range (2620-2690 MHz) as the U1 signal 584a. The U1 and restored U2 signals 584a, 584b are coupled to the inputs of power amplifiers 666 and 668, which in turn amplify the signals to a power level sufficient to cover the extended service area. The outputs of the power amplifiers 666, 668 are coupled to antennas 670, 672 by the transmit/receive duplexers 662, 664. The third extension unit 512 thereby extends the coverage of the upper-band BTS 494 into the service area.


The frequency conversion circuits 638, 652, 660 in the extension units 510, 512, 514 may include local oscillators, mixers, and filters as is known in the art. To synchronize the local oscillators in the extension units 510, 512, 514 with the local oscillators in the frequency conversion modules 520, 522 in the master unit 502, the frequency conversion circuits 638, 652, 660 may receive a common reference signal transmitted via the same downlink path as the BTS signals. This common reference signal transmitted from the master unit to the remote unit and to the filter unit and all extension units may be used to synchronize the offset frequencies of the frequency conversion circuits 638, 652, 660 with their associated frequency conversion circuits in the frequency conversion module 522 and to frequency lock all of the frequency synthesizers used for frequency conversion. The common reference signal or signals may thereby allow the frequency converted signals to be recovered to their original frequency with minimal error. In an alternative embodiment, high stability reference sources may be used in the conversion modules 520, 522 and extension units 510, 512, 514 to provide frequency matching between the conversion stages.


The invention in its broader aspects is not limited to the specific details representative apparatus and method, and illustrative examples shown and described. Accordingly, departures may be made from such details without departure from the spirit or scope of the applicants' general inventive concept. For example, embodiments of the invention may shift or convert frequencies by either downconverting or upconverting the frequency. Thus, in a downlink direction, at least one MIMO signal received by a master unit may be upconverted before such signal is passed over an optical link to a remote unit and/or extension unit. This upconverted signal may then be downconverted to the appropriate MIMO band by the remote unit and/or extension unit before it is transmitted. Alternative embodiments of the invention may, instead, downconvert at least one signal received by the master unit before such signal is passed over an optical link to the remote unit and/or extension unit, then upconvert that signal to the MIMO band at the remote unit and/or extension unit. Therefore, the direction of the frequency conversion is not limiting, as described herein, for the exemplary embodiments. Correspondingly, in an uplink direction, at least one signal received by the remote unit and/or extension unit may be upconverted before such signal is passed over an optical ink to the master unit. This upconverted signal may then downconverted to the MIMO band by the master unit before it is transmitted back to a BTS. Alternative embodiments of the invention may, instead, downconvert at least one signal received by the remote unit and/or extension unit before such signal is passed over an optical link to the master unit, then upconvert that signal at the master unit to the appropriate MIMO band.


Moreover, the DAS systems of FIGS. 2A-2B, 3A-3B, 4A-4C, 6A-6B, and 7A-7B, and the components or circuits or FIGS. 5 and 8-15 may include more or fewer components consistent with embodiments of the invention. In particular, each master unit 46 of a MIMO DAS system may communicate with more than three sets of remote units and receive more signals than those shown or described. Such a master unit 46 can support up to 124 remote units in point to point architecture and or up to 31 optical links in cascaded architecture with up to 4 remote units per optical link in one embodiment of the invention. As such, the systems of FIGS. 2A-2B, 3A-3B, 4A-4C, 6A-6B, and 7A-7B may be configured with more or fewer master units, remote units, extension units, or other components consistent with embodiments of the invention.


Other modifications will be apparent to one of ordinary skill in the art. Therefore, the invention lies in the claims hereinafter appended.

Claims
  • 1. A method comprising: receiving at least one set of multiple input multiple output (MIMO) channel signals at an original MIMO frequency from at least one signal source at a master unit of a distributed antenna system, at least one set of the MIMO channel signals including at least a first MIMO channel signal and a second MIMO channel signal;generating a local oscillator signal at the master unit;frequency converting the at least one of the first MIMO channel signal and the second MIMO channel signal from an original MIMO frequency to a different frequency different from a first legacy service frequency band using the local oscillator signal at the master unit;receiving at least one non-MIMO signal that has a frequency in the first legacy service band at the master unit;processing the at least one converted MIMO channel signal and the at least one non-MIMO signal at the master unit;combining the at least one non-MIMO signal in the first legacy frequency band along with the first MIMO channel signal, the second MIMO channel signal, and the local oscillator signal into a combined signal at the master unit;transmitting the combined signal across an optical link to a remote unit;processing together the at least one non-MIMO signal in the first legacy service frequency band and the at least one of the first MIMO channel signal and the second MIMO channel signal at the remote unit; andfrequency converting the at least one converted MIMO channel signal from the different frequency different from the first legacy service frequency band back to the original MIMO frequency for transmission over at least one antenna.
  • 2. The method of claim 1, comprising: receiving the local oscillator signal from the remote unit at conversion circuitry; andusing the local oscillator signal to frequency convert the at least one of the first MIMO channel signal and the second MIMO channel signal from the different frequency different from the first legacy service frequency band back to the original MIMO frequency.
  • 3. The method of claim 1, comprising: using the local oscillator signal to generate other frequency signals for use in converting at least a second one of the first MIMO channel signal and the second MIMO channel signal to another different frequency different from the first legacy service frequency band from the original MIMO frequency.
  • 4. The method of claim 1, comprising: frequency converting both the first MIMO channel signal and the second MIMO channel signal to different frequencies at the master unit; andfrequency converting the first MIMO channel signal to a frequency that is different from a frequency of the second MIMO channel signal at the master unit.
  • 5. The method of claim 4, comprising: frequency converting all of the MIMO channel signals back to the original MIMO frequency for transmission over the at least one antenna.
  • 6. The method of claim 1, comprising: transceiving both uplink signals and downlink signals between the remote unit and the master unit across at least one fiber-optic cable.
  • 7. The method of claim 1, wherein frequency converting the at least one converted MIMO channel signal from the different frequency different from the first legacy service frequency band back to the original MIMO frequency occurs at the at least one remote unit.
  • 8. The method of claim 1, wherein frequency converting the at least one converted MIMO channel signal from the different frequency different from the first legacy service frequency band back to the original MIMO frequency occurs at least one extension unit in communication with the at least one remote unit.
  • 9. The method of claim 1, further comprising: wherein the first legacy service frequency band is lower in frequency than the original MIMO frequency of the at least one set of MIMO channel signals; andfrequency converting the at least one of the first MIMO channel signal and the second MIMO channel signal from the original MIMO frequency to a lower different frequency that is different from the first legacy service frequency band at the master unit.
  • 10. The method of claim 1, further comprising: wherein the first legacy service frequency band is higher in frequency than the original MIMO frequency of the at least one set of MIMO channel signals; andfrequency converting the at least one of the first MIMO channel signal and the second MIMO channel signal from the original MIMO frequency to a higher different frequency that is different from the first legacy service frequency band at the master unit.
  • 11. The method of claim 1, further comprising: receiving at least one additional set of MIMO channel signals at another original MIMO frequency different from the original MIMO frequency of the at least one set of MIMO signals at the master unit;frequency converting at least one of the first and second MIMO channel signals of the additional set of MIMO channel signals to another different frequency different from the first legacy service frequency band from the another original MIMO frequency at the master unit; andcombining the at least one additional set of MIMO channel signals for transmission at the master unit.
  • 12. The method of claim 1, further comprising: frequency converting the at least one of the first and the second converted MIMO channel signals of the at least one additional set from the frequency different from the first legacy service frequency band back to the another original MIMO frequency for transmission over the at least one antenna at a plurality of extension units coupled to at least one remote unit.
  • 13. The method of claim 1, further comprising: frequency converting the at least one of the first MIMO channel signal and the second MIMO channel signal of the additional set of MIMO channel signals to another different frequency that is different from the original MIMO frequency of the at least one set of MIMO channel signals at the master unit; andcombining the at least one set of MIMO channel signals for transmission at the master unit.
  • 14. The method of claim 1, further comprising: wherein at least one of the first MIMO channel signal and the second MIMO channel signal is maintained at the original MIMO frequency; andtransmitting at least one of the first MIMO channel signal and the second MIMO channel signal at the original MIMO frequency over the at least one antenna at the remote unit.
  • 15. A method comprising: receiving a plurality of sets of multiple input multiple output (MIMO) channel signals at respective original first and second MIMO frequencies at a master unit of a distributed antenna system, each set of the MIMO channel signals including at least a first MIMO channel signal and a second MIMO channel signal;generating a local oscillator signal at the master unit;frequency converting the at least one of the first MIMO channel signals from the original first MIMO frequency to a first different frequency different from a first legacy service frequency band using the local oscillator signal at the master unit;frequency converting the at least one of the second MIMO channel signals from the original second MIMO frequency to a second different frequency different from a second legacy service frequency band based on the local oscillator signal at the master unit;receiving a plurality of non-MIMO signals that have original frequencies in at least the first legacy service frequency band and the second legacy service frequency band at the master unit;processing the plurality of non-MIMO signals using the band processing circuit component at the master unit;combining the plurality of non-MIMO signals in the at least the first legacy service frequency band and the second legacy service frequency band along with the at least one of the first MIMO channel signals, the at least one of the second MIMO channel signals, and the local oscillator signal at the master unit into a combined signal at the master unit;transmitting the combined signal across an optical link to a remote unit;processing together the plurality of non-MIMO signals in the at least the first legacy frequency band and the at least one converted first MIMO channel signal at the remote unit;processing together the plurality of non-MIMO signals in the at least the second legacy service frequency band and the at least one converted second MIMO channel signal at the remote unit;frequency converting the at least one converted first MIMO channel signal from the first different frequency different from the first legacy service frequency band and back to the first MIMO frequency for transmission over the at least one antenna; andfrequency converting the at least one converted second MIMO channel signal from the second different frequency different from the second legacy service frequency band and back to the second MIMO frequency for transmission over at least one antenna.
  • 16. The method of claim 15, further comprising: receiving the local oscillator signal from the remote unit; andusing the local oscillator signal to frequency convert the at least one converted first MIMO channel signal from the first different frequency different from the first legacy service frequency band and back to the first MIMO frequency for transmission over the at least one antenna.
  • 17. The method of claim 15, further comprising: using the local oscillator signal to generate a second local oscillator signal for use in converting the original second MIMO frequency to the second different frequency different from the second legacy service frequency band at the master unit.
  • 18. The method of claim 17, further comprising: receiving the at least one local oscillator signal from the remote unit;using the local oscillator signal to frequency convert the at least one converted first MIMO channel signal from the first different frequency different from the first legacy service frequency band and back to the first MIMO frequency for transmission over the at least one antenna;using the second local oscillator signal to frequency convert the at least one converted second MIMO channel signal from the second different frequency different from the second legacy service frequency band and back to the second MIMO frequency for transmission over the at least one antenna.
CROSS-REFERENCE TO RELATED APPLICATIONS

This Application is a Continuation Application of U.S. application Ser. No. 15/464,014, filed Mar. 20, 2017, entitled “DISTRIBUTED ANTENNA SYSTEM FOR MIMO SIGNALS”, which Application is a Continuation Application of U.S. application Ser. No. 14/987,025, filed Jan. 4, 2016, entitled “DISTRIBUTED ANTENNA SYSTEM FOR MIMO SIGNALS”, which Application is a Continuation Application of U.S. application Ser. No. 13/796,978, filed Mar. 12, 2013, entitled “DISTRIBUTED ANTENNA SYSTEM FOR MIMO SIGNALS”, which Application is a Continuation Application of International PCT Application No. PCT/US2011/054281, filed Sep. 30, 2011, entitled “DISTRIBUTED ANTENNA SYSTEM FOR MIMO SIGNALS”, which claims priority to and the filing benefit of U.S. Provisional Patent Application Ser. No. 61/388,973 filed on Oct. 1, 2010, entitled “DISTRIBUTED ANTENNA SYSTEM FOR MIMO SIGNALS”, which applications are all incorporated by reference herein in their entireties.

US Referenced Citations (305)
Number Name Date Kind
3665316 Jeffers May 1972 A
3740756 Sosin Jun 1973 A
3778716 Stokes Dec 1973 A
3898566 Switzer et al. Aug 1975 A
4092596 Dickinson et al. May 1978 A
4213132 Davidson Jul 1980 A
4238779 Dickinson et al. Dec 1980 A
4615040 Mojoli et al. Sep 1986 A
4709418 Fox et al. Nov 1987 A
4763317 Lehman et al. Aug 1988 A
4827270 Udagawa et al. May 1989 A
4849811 Kleinerman Jul 1989 A
4949340 Smith et al. Aug 1990 A
5025485 Csongor et al. Jun 1991 A
5153763 Pidgeon Oct 1992 A
5239667 Kanai Aug 1993 A
5263175 Dejmek Nov 1993 A
5428817 Yahagi Jun 1995 A
5444697 Leung et al. Aug 1995 A
5519735 Rice et al. May 1996 A
5627879 Russell et al. May 1997 A
5657374 Russell et al. Aug 1997 A
5715275 Emi Feb 1998 A
5719867 Borazjani Feb 1998 A
5745858 Sato et al. Apr 1998 A
5774789 Van Der Kaay et al. Jun 1998 A
5854986 Dorren et al. Dec 1998 A
5867292 Crimmins et al. Feb 1999 A
5881095 Cadd Mar 1999 A
5930231 Miller et al. Jul 1999 A
5930293 Light et al. Jul 1999 A
5969837 Farber et al. Oct 1999 A
6064665 Leuck et al. May 2000 A
6125109 Fuerter Sep 2000 A
6215777 Chen et al. Apr 2001 B1
6222503 Gietema et al. Apr 2001 B1
6366789 Hildebrand Apr 2002 B1
6405341 Maru Jun 2002 B1
6418558 Roberts et al. Jul 2002 B1
6486907 Farber et al. Nov 2002 B1
6590871 Adachi Jul 2003 B1
6594496 Schwartz Jul 2003 B2
6704545 Wala Mar 2004 B1
6715349 Atkinson Apr 2004 B2
6801767 Schwartz et al. Oct 2004 B1
6831901 Millar Dec 2004 B2
6870515 Kitchener et al. Mar 2005 B2
6906681 Hoppenstein Jun 2005 B2
6925578 Lam et al. Aug 2005 B2
6961388 Ling et al. Nov 2005 B2
6963552 Sabat, Jr. et al. Nov 2005 B2
7024231 Cohen Apr 2006 B2
7043270 Judd et al. May 2006 B2
7215651 Millar May 2007 B2
7233771 Proctor, Jr. et al. Jun 2007 B2
7260153 Nissani (Nissensohn) Aug 2007 B2
7328033 Rappaport et al. Feb 2008 B2
7339897 Larsson et al. Mar 2008 B2
7346040 Weinstein Mar 2008 B2
7391815 Lakkis Jun 2008 B2
7395040 Behzad Jul 2008 B2
7403576 Lakkis Jul 2008 B2
7430397 Suda et al. Sep 2008 B2
7440436 Cheng et al. Oct 2008 B2
7443708 Madan et al. Oct 2008 B2
RE40564 Fischer et al. Nov 2008 E
7446630 Chan et al. Nov 2008 B2
7450637 Lakkis Nov 2008 B2
7469015 Le Nir et al. Dec 2008 B2
7483483 Lakkis Jan 2009 B2
7483504 Shapira et al. Jan 2009 B2
7555261 O'Neill Jun 2009 B2
7587001 Hazani et al. Sep 2009 B2
7603141 Dravida Oct 2009 B2
7613423 Ngo et al. Nov 2009 B2
7630356 Zhang et al. Dec 2009 B2
7650261 Takiishi et al. Jan 2010 B2
7653083 Liu et al. Jan 2010 B2
7653146 Kisovec et al. Jan 2010 B2
7653148 Kisovec et al. Jan 2010 B2
7656842 Thomas et al. Feb 2010 B2
7672739 Ganesan et al. Mar 2010 B2
7710327 Saban et al. May 2010 B2
7720036 Sadri et al. May 2010 B2
7751775 Baier et al. Jul 2010 B2
7760699 Malik Jul 2010 B1
7761050 Fitton et al. Jul 2010 B2
7787823 George et al. Aug 2010 B2
7809073 Liu Oct 2010 B2
7813451 Binder et al. Oct 2010 B2
7817603 Liu Oct 2010 B2
7822148 Shapira et al. Oct 2010 B2
7840190 Saban et al. Nov 2010 B2
7929596 Lakkis Apr 2011 B2
7965990 Luz et al. Jun 2011 B2
8010116 Scheinert Aug 2011 B2
8023826 Fasshauer et al. Sep 2011 B2
8055300 Andersson et al. Nov 2011 B2
8111959 Shapiro Feb 2012 B2
8121535 Proctor, Jr. et al. Feb 2012 B2
8121646 Oren et al. Feb 2012 B2
8126396 Bennett Feb 2012 B2
8131218 Kleider et al. Mar 2012 B2
8135273 Sabat, Jr. et al. Mar 2012 B2
8156535 Sage Apr 2012 B2
8159954 Larsson et al. Apr 2012 B2
8160121 Forenza et al. Apr 2012 B2
8170081 Forenza et al. May 2012 B2
8175459 Thelen et al. May 2012 B2
8175649 Saban et al. May 2012 B2
8184681 Binder et al. May 2012 B2
8195224 Saban et al. Jun 2012 B2
8208414 Singh et al. Jun 2012 B2
8208963 Codreanu et al. Jun 2012 B2
8245092 Kotecha et al. Aug 2012 B2
8248993 Cai Aug 2012 B2
8289910 Gabriel et al. Oct 2012 B2
8310963 Singh Nov 2012 B2
8320957 Saban et al. Nov 2012 B2
8325693 Hazani et al. Dec 2012 B2
8325759 Hazani et al. Dec 2012 B2
8331425 Nicolas et al. Dec 2012 B2
8346091 Kummetz et al. Jan 2013 B2
8351531 Yu et al. Jan 2013 B2
8396368 Tarlazzi et al. Mar 2013 B2
8412260 Rave Apr 2013 B2
8472367 Larsson et al. Jun 2013 B2
8503544 Chockalingam et al. Aug 2013 B2
8509342 Dufresne et al. Aug 2013 B2
8509708 Zhang et al. Aug 2013 B2
8514915 Binder et al. Aug 2013 B2
8514963 Matsumoto et al. Aug 2013 B2
8515862 Zhang et al. Aug 2013 B2
8548330 Berlin et al. Oct 2013 B2
8571086 Forenza et al. Oct 2013 B2
8594133 Shapira et al. Nov 2013 B2
8594223 Ranson et al. Nov 2013 B2
8626238 Stratford et al. Jan 2014 B2
8644844 Shapira et al. Feb 2014 B2
8654815 Forenza et al. Feb 2014 B1
8655396 Malladi et al. Feb 2014 B2
8681916 Braz et al. Mar 2014 B2
8681917 McAllister et al. Mar 2014 B2
8711760 Kasher Apr 2014 B2
8711778 Murata Apr 2014 B2
8730848 Schmid et al. May 2014 B2
8744504 Faccin et al. Jun 2014 B2
8774079 Proctor, Jr. et al. Jul 2014 B2
8798209 Lee et al. Aug 2014 B2
8824588 Emmanuel et al. Sep 2014 B2
8855036 Sabat et al. Oct 2014 B2
8873585 Oren et al. Oct 2014 B2
8897215 Shapira et al. Nov 2014 B2
8913963 Lundstrom et al. Dec 2014 B2
8958789 Bauman et al. Feb 2015 B2
8976887 Reingold Mar 2015 B2
9008205 Al-Dhahir Apr 2015 B1
9014237 Li et al. Apr 2015 B2
9014256 Ranson et al. Apr 2015 B2
9019929 Berlin et al. Apr 2015 B2
9026036 Saban et al. May 2015 B2
9036684 Hui et al. May 2015 B2
9054767 Razaviyayn et al. Jun 2015 B2
9059751 Nosratinia et al. Jun 2015 B2
9100048 Carlach et al. Aug 2015 B2
9100075 Lorca Hernando Aug 2015 B2
9106315 Hanson et al. Aug 2015 B2
9155055 Phillips Oct 2015 B2
9160437 Ajima et al. Oct 2015 B2
9160643 Gao et al. Oct 2015 B2
9184962 Tarlazzi et al. Nov 2015 B2
9203496 Fakhrai et al. Dec 2015 B2
9231670 Schmid Jan 2016 B2
9602176 Schmid et al. Mar 2017 B2
9979443 Schmid et al. May 2018 B2
10027369 Hanson Jul 2018 B2
20030002604 Fifield et al. Jan 2003 A1
20040100930 Shapira et al. May 2004 A1
20040106435 Bauman et al. Jun 2004 A1
20050143091 Shapira et al. Jun 2005 A1
20050249245 Hazani et al. Nov 2005 A1
20050266902 Khatri et al. Dec 2005 A1
20050276320 Tsubosaka Dec 2005 A1
20060063494 Zhang et al. Mar 2006 A1
20060202890 Otto Sep 2006 A1
20060233200 Fifield et al. Oct 2006 A1
20070104165 Hanaoka et al. May 2007 A1
20070177494 Tomizawa Aug 2007 A1
20070259643 Wu Nov 2007 A1
20070274253 Zhang et al. Nov 2007 A1
20070274279 Wood et al. Nov 2007 A1
20080056332 Lakkis Mar 2008 A1
20080095259 Dyer et al. Apr 2008 A1
20080107202 Lee et al. May 2008 A1
20080114580 Chin et al. May 2008 A1
20080129009 Czysz Jun 2008 A1
20080175175 Oren et al. Jul 2008 A1
20080180190 Chan et al. Jul 2008 A1
20080191941 Saban et al. Aug 2008 A1
20080192855 Shapira Aug 2008 A1
20080198955 Oren et al. Aug 2008 A1
20080200177 Wang et al. Aug 2008 A1
20080232305 Oren Sep 2008 A1
20080284647 Oren et al. Nov 2008 A1
20090080547 Naka et al. Mar 2009 A1
20090092201 Luo et al. Apr 2009 A1
20090124214 Zhang et al. May 2009 A1
20090135944 Dyer et al. May 2009 A1
20090141691 Jain Jun 2009 A1
20090180426 Sabat et al. Jul 2009 A1
20090219976 Oren et al. Sep 2009 A1
20090227203 Guerreri et al. Sep 2009 A1
20090316608 Singh Dec 2009 A1
20090316609 Singh Dec 2009 A1
20100029320 Malladi et al. Feb 2010 A1
20100062707 Gou et al. Mar 2010 A1
20100115358 Kotecha et al. May 2010 A1
20100246516 Pelletier et al. Sep 2010 A1
20100272202 Matsumoto et al. Oct 2010 A1
20100278530 Kummetz Nov 2010 A1
20110002410 Forenza et al. Jan 2011 A1
20110002411 Forenza et al. Jan 2011 A1
20110003608 Forenza et al. Jan 2011 A1
20110077044 Sampath et al. Mar 2011 A1
20110135308 Tarlazzi Jun 2011 A1
20110182217 Schmid et al. Jul 2011 A1
20110201368 Faccin et al. Aug 2011 A1
20110235622 Kasher Sep 2011 A1
20110241425 Hunter, Jr. Oct 2011 A1
20110263215 Asplund et al. Oct 2011 A1
20110268203 Chockalingam et al. Nov 2011 A1
20110292863 Braz et al. Dec 2011 A1
20110317679 Jain Dec 2011 A1
20120027145 Uyehara et al. Feb 2012 A1
20120120998 Fakhrai et al. May 2012 A1
20120213254 Yokouchi et al. Aug 2012 A1
20120230380 Keusgen et al. Sep 2012 A1
20120257659 Braz Oct 2012 A1
20120267659 Chou et al. Oct 2012 A1
20120281622 Saban et al. Nov 2012 A1
20120321314 Oren et al. Dec 2012 A1
20120329523 Stewart et al. Dec 2012 A1
20130028304 Murata Jan 2013 A1
20130051404 Binder et al. Feb 2013 A1
20130058281 Berlin et al. Mar 2013 A1
20130077658 Hui et al. Mar 2013 A1
20130078927 Razaviyayn et al. Mar 2013 A1
20130114650 Li et al. May 2013 A1
20130129009 Ranson et al. May 2013 A1
20130136202 Kummetz May 2013 A1
20130159817 Carlach et al. Jun 2013 A1
20130188753 Tarlazzi Jul 2013 A1
20130195467 Schmid Aug 2013 A1
20130201916 Kummetz Aug 2013 A1
20130219009 Bheemarajaiah Aug 2013 A1
20130279417 Binder et al. Oct 2013 A1
20130295980 Reuven et al. Nov 2013 A1
20130329825 Oren et al. Dec 2013 A1
20130343474 Nosratinia et al. Dec 2013 A1
20140016583 Smith Jan 2014 A1
20140056389 Lee et al. Feb 2014 A1
20140064399 Oren et al. Mar 2014 A1
20140072071 Berlin et al. Mar 2014 A1
20140079077 Saban et al. Mar 2014 A1
20140079112 Ranson Mar 2014 A1
20140083673 Thuillard Mar 2014 A1
20140087742 Brower et al. Mar 2014 A1
20140119735 Cune et al. May 2014 A1
20140135038 Shapira et al. May 2014 A1
20140153918 Hazani Jun 2014 A1
20140153919 Casterline et al. Jun 2014 A1
20140161164 Emmanuel et al. Jun 2014 A1
20140180581 Berlin et al. Jun 2014 A1
20140211875 Berlin et al. Jul 2014 A1
20140247791 Seo et al. Sep 2014 A1
20140269358 Gao et al. Sep 2014 A1
20140269859 Hanson Sep 2014 A1
20140269966 Faccin et al. Sep 2014 A1
20140286463 Reingold Sep 2014 A1
20140301496 Ko et al. Oct 2014 A1
20140348260 Lorca Hernando Nov 2014 A1
20150023444 Tarlazzi et al. Jan 2015 A1
20150023453 Ajima et al. Jan 2015 A1
20150031316 Berlin et al. Jan 2015 A1
20150035705 Anolik et al. Feb 2015 A1
20150038185 Saban et al. Feb 2015 A1
20150093106 Hazani Apr 2015 A1
20150110013 Zhang et al. Apr 2015 A1
20150131632 Hazani et al. May 2015 A1
20150139346 Ko et al. May 2015 A1
20150188582 Kahrizi et al. Jul 2015 A1
20150195055 Ben-Shlomo Jul 2015 A1
20150207558 Braz et al. Jul 2015 A1
20150215921 Zhang et al. Jul 2015 A1
20150249965 Dussmann Sep 2015 A1
20150282069 Hobbs et al. Oct 2015 A1
20150319699 Bar-David Nov 2015 A1
20150349868 Sawai Dec 2015 A1
20160065256 Yun et al. Mar 2016 A1
20160164648 Moon et al. Jun 2016 A1
20160164800 Eitan et al. Jun 2016 A1
20160173308 Yoon et al. Jun 2016 A1
20170012649 Kummetz Jan 2017 A1
20170163452 Breiling Jun 2017 A1
20170195015 Schmid et al. Jul 2017 A1
Foreign Referenced Citations (38)
Number Date Country
1523371 Aug 2004 CN
1797971 Jul 2006 CN
1964216 May 2007 CN
20060049193 May 2006 KR
9722186 Jun 1997 WO
9827748 Jun 1998 WO
9831133 Jul 1998 WO
9955012 Oct 1999 WO
0110156 Feb 2001 WO
0225506 Mar 2002 WO
2005048401 May 2005 WO
2007054945 May 2007 WO
2007133630 Nov 2007 WO
2008004955 Jan 2008 WO
2008027531 Mar 2008 WO
2008076432 Jun 2008 WO
2008088859 Jul 2008 WO
2008088862 Jul 2008 WO
2008097651 Aug 2008 WO
2008099383 Aug 2008 WO
2008099390 Aug 2008 WO
2008103374 Aug 2008 WO
2008103375 Aug 2008 WO
2009002938 Dec 2008 WO
2009053910 Apr 2009 WO
2009081376 Jul 2009 WO
2009138876 Nov 2009 WO
2009155602 Dec 2009 WO
2010013142 Feb 2010 WO
2010059103 May 2010 WO
2010060490 Jun 2010 WO
2010075865 Jul 2010 WO
2010089719 Aug 2010 WO
2011057750 May 2011 WO
2011071870 Jun 2011 WO
2011100219 Aug 2011 WO
2012044969 Apr 2012 WO
2012075137 Jun 2012 WO
Non-Patent Literature Citations (20)
Entry
Korean Intellectual Property Office, “Notice of Last Non-Final Rejection from KR Application No. 10-2013-7011250 dated Nov. 21, 2018”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, filed Nov. 21, 2018, pp. 1-9, Published: KR.
Cho, “Practical Scheme to Enable MIMO Communications in Distributed Antenna Systems for Efficient Indoor Coverage”, Department of Wireless Communications Engineering, Sep. 2009, pp. 25-28, IEEE.
European Patent Office, “Communication pursuant to Article 94(3) from EP Application No. 11768255.9 dated May 26, 2017”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, filed May 26, 2017, pp. 1-5, Published: EP.
European Patent Office, “Communication under Rule 71(3) from EP Application No. 11768255.9 dated Apr. 12, 2018”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, filed Apr. 12, 2018, pp. 1-88, Published: EP.
International Searching Authority, “International Search Report and Written Opinion from PCT Application No. PCT/US2011/054281 dated Feb. 24, 2012”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, filed Feb. 24, 2012, pp. 1-13, Published: EP.
Korean Intellectual Property Office, “Notice of Non-Final Rejection from KR Application No. 10-2013-7011250 dated Jan. 10, 2018”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, filed Jan. 10, 2018, pp. 1-32, Published: KR.
State Intellectual Property Office, P.R. China, “First Office Action from CN Application No. 201180047543.3 dated Mar. 18, 2015”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, filed Mar. 18, 2015, pp. 1-29, Published: CN.
State Intellectual Property Office, P.R. China, “Second Office Action from CN Application No. 201180047543.3 dated Oct. 19, 2015”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, filed Oct. 19, 2015, pp. 1-5, Published: CN.
U.S. Patent and Trademark Office, “Notice of Allowance”, U.S. Appl. No. 13/796,978, dated Aug. 19, 2015, pp. 1-15, Published: US.
U.S. Patent and Trademark Office, “Notice of Allowability”, U.S. Appl. No. 15/464,014, dated Apr. 26, 2018, pp. 1-6, Published: US.
U.S. Patent and Trademark Office, “Notice of Allowance”, U.S. Appl. No. 14/987,025, dated Nov. 22, 2016, pp. 1-21, Published: US.
U.S. Patent and Trademark Office, “Notice of Allowance”, U.S. Appl. No. 14/987,025, dated Jun. 29, 2016, pp. 1-14, Published: US.
U.S. Patent and Trademark Office, “Notice of Allowance”, U.S. Appl. No. 15/464,014, dated Oct. 2, 2017, pp. 1-64, Published: US.
Tarlazzi et al., “Characterization of an Interleaved F-DAS MIMO Indoor Propagation Channel”, “Nov. 8-9, 2010, Loughborough UK”, pp. 505-508.
U.S. Patent and Trademark Office, “Office Action”, U.S. Appl. No. 13/796,978, dated Jan. 15, 2015, pp. 1-53, Published: US.
U.S. Patent and Trademark Office, “Office Action”, U.S. Appl. No. 14/987,025, dated Feb. 23, 2016, pp. 1-67, Published: US.
U.S. Patent and Trademark Office, “Office Action”, U.S. Appl. No. 15/464,014, dated May 31, 2017, pp. 1-57, Published: US.
European Patent Office, “Invitation pursuant to Rule 63(1) from EP Application No. 18204606.0 dated Feb. 5, 2019”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, filed Feb. 5, 2019, pp. 1-3, Published: EP.
European Patent Office, “Extended European Search Report from EP Application No. 18204606.0 dated Jun. 3, 2019”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, pp. 1-12, Published: EP.
Korean Intellectual Property Office, “Notice of Final Rejection from KR Application No. 10-2013-7011250 dated Aug. 27, 2019”, from Foreign Counterpart to U.S. Appl. No. 13/796,978, pp. 1-5, Published: KR.
Related Publications (1)
Number Date Country
20180269933 A1 Sep 2018 US
Provisional Applications (1)
Number Date Country
61388973 Oct 2010 US
Continuations (4)
Number Date Country
Parent 15464014 Mar 2017 US
Child 15985454 US
Parent 14987025 Jan 2016 US
Child 15464014 US
Parent 13796978 Mar 2013 US
Child 14987025 US
Parent PCT/US2011/054281 Sep 2011 US
Child 13796978 US