In recent years, the telecommunications industry has experienced rapid growth by offering a variety of new and improved services to customers. This growth has been particularly notable in the area of wireless communications, e.g., cellular, personal communication services (PCS) and other mobile radio systems. One of the factors that has led to the rapid growth in the wireless arena is the objective of allowing a user to be reached any time, and anywhere. Unfortunately, the industry has not been able to reach this goal even though large and small companies and various consortiums are frantically building vast networks in an effort to capture a share of this booming market.
Despite their efforts to provide seamless and blanket coverage for wireless telecommunications, areas of limited wireless coverage still exist in heavily populated regions. One particular difficulty is communication within a substantially closed environment, such as a building or other structure which can interfere with radio frequency transmissions. In these situations, the structure itself acts as a barrier and significantly attenuates or reduces the signal strength of the radio waves to the point that transmission is virtually impossible at the frequency and power levels used in these systems.
The industry has developed a number of options to extend coverage into buildings and other substantially closed environments. For example, one solution to this problem has been to distribute antennas within the building. Typically, these antennas are connected to an RF signal source by dedicated coaxial cable, optical fiber, and, more recently, unshielded twisted pair wires. In such systems, various methods of signal conditioning and processing are used, ranging from straight bi-directional on-frequency amplification and band pass filtering to select which service or service provider to transport, to frequency conversion methods to move the signals to a more desirable segment of the frequency spectrum for transport. Some systems also use passive antenna methods and “leaky” coaxial cable to radiate signals within the desired area without any signal conditioning. Unfortunately, with the explosive growth in the wireless market, these solutions often are too limited in capacity to carry signals for the various services and service providers into the closed environment. Thus, the limited benefits of such systems, at times, can be outweighed by the costs associated with the installation and maintenance of the systems.
For the reasons stated above, and for other reasons stated below which will become apparent to those skilled in the art upon reading and understanding the present specification, there is a need in the art for an economically viable system and method for distributing wireless signals in a substantially closed environment.
Embodiments of the present invention provide solutions to the problems identified above. In particular, embodiments of the present invention enable economical distribution of wireless signals in a substantially closed environment.
In one embodiment, a communication system is provided. The communication system includes a master host unit that is adapted to communicate analog wireless signals with a plurality of service provider interfaces and that is adapted to send and receive digitized spectrum over a plurality of communication links. The master host unit includes circuitry for converting between analog wireless signals and digitized spectrum. The communication system further comprises at least one remote server unit that is communicatively coupled to the master host unit over a digital communication medium. The at least one remote server unit is adapted to convert between analog wireless signals and digitized spectrum and is adapted to amplify the analog wireless signals. The communication system further includes a plurality of remote units that are each communicatively coupled to one of the at least one remote server units over an analog communication medium. Each of the plurality of remote units is adapted to transmit and receive wireless signals over a plurality of air interfaces for the associated service provider interfaces.
In the following detailed description, reference is made to the accompanying drawings which form a part hereof, and in which is shown by way of illustration specific illustrative embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention, and it is to be understood that other embodiments may be utilized and that logical, mechanical and electrical changes may be made without departing from the scope of the present invention. The following detailed description is, therefore, not to be taken in a limiting sense.
Embodiments of the present invention provide improved wireless coverage into substantially closed environments, e.g., in buildings or other structures. Section II below provides an overview of one embodiment of a network topology shown in
The remainder of the detailed description describes an example implementation of the network topology to extend the coverage of the full 1.9 GHz PCS band and the 800 MHz cellular band into a plurality of buildings as shown in
The example implementation shown in
System 100 uses two main transport protocols to extend the coverage of the wireless services into the substantially enclosed environment. First, system 100 uses digital transport over an appropriate communication medium 105, e.g., optical fiber. Communication medium 105 is represented as optical fiber in
System 100 uses the digital transport technology for communication between master host unit 104 and remote server units 106, and 108-1 to 108-N. In one embodiment, master host unit 104 includes a plurality of ports to subtend remote server units. By way of example and not by way of limitation, master host unit 104, in one embodiment, includes up to six ports for subtending remote server units. In a practical application, the number of ports that can be implemented in a master host unit 104 is primarily limited by the noise in the system. As shown in the example of
Master host unit 104 and remote server units 106, and 108-1 to 108-N convert between analog wireless signals, e.g., analog RF signals, and digitized spectrum. In one embodiment, master host unit 104 includes a bank of individual circuits, such as a bank of Digivance™ Digital Host Units (DHUs) or FLX host unit commercially available from ADC Telecommunications, Inc. of Eden Prairie, Minn., that are each configured to operate on a selected portion of the wireless spectrum. In one embodiment, the DHUs convert between 25 MHz bands of wireless spectrum and digitized samples of the spectrum in the form of 20 bit words. Similarly, remote server units 106 and 108-1 to 108-N, in one embodiment, use a bank of Digivance™ Digital Remote Units (DRUs) or FLX remote units, also available from ADC Telecommunications, Inc. to operate on the selected spectrum. In one embodiment, course wave division multiplexing (CWDM) or dense wave division multiplexing (DWDM) are used to aggregate the signals for the various services onto a single fiber between the master host unit 104 and each of the remote server units 106, and 108-1 to 108-N. In one embodiment, master expansion unit 110 also includes banks of individual expansion circuits such as a bank of Digivance™ Digital Expansion Units (DEUs) commercially available from ADC Telecommunications, Inc.
The analog portion of system 100 provides communication between the remote server units 106 and 108-1 to 108-N and their respective remote units 112-1 to 112-M, 113-1 to 113-S and 114-1 to 114-Q. The analog portion of system 100 uses one or more of various communication media, e.g., coaxial cable, fiber optic cable or the like, to carry the wireless signals in their native analog frequency spectrum, e.g., their assigned RF spectrum. In other embodiments, the wireless signals are moved to other frequency spectrum for improved transport, e.g., up or down converted. In one embodiment, remote server unit 106 is coupled to remote units 112-1 to 112-M over coaxial cable. In another example, signals from remote server unit 108-N are provided to remote units 114-1 to 114-Q over optical fiber in analog format.
Each remote unit includes one or more antennas 116. In one embodiment, each remote unit supports up to four antennas. In other embodiments, other appropriate numbers of antennas are used.
In one embodiment, remote server units provide power to their respective remote units. For example, remote server unit 106 is coupled to remote units 112-1 to 112-M over coaxial cable. In this embodiment, remote server unit 106 injects power onto the coaxial cable for the circuitry of remote units 112-1 to 112-M. Further, remote units 112-1 to 112-M are equipped with circuitry to extract power from the coaxial cable for the operation of remote units 112-1 to 112-M.
In one embodiment, remote server units provide a telemetry signal to their respective remote units. The telemetry signal is used to adjust the gain applied to signals at the various remote units for the various services supported in system 100. In one embodiment, the telemetry signal is communicated at a frequency between the spectrum for the various services, e.g., at a frequency of 1.4 to 1.6 GHz for a system running 800 MHz cellular and 1.9 GHz PCS services.
In one embodiment, master host unit 104 and the remote server units all include modems for communicating and transporting signals for operations, administration and maintenance (O,A&M) functions such as alarms and the like.
The physical location of the various elements of system 100 varies based on the needs of a given implementation. For example, in some embodiments, the master host unit 104 is co-located with a base station or a base station hotel. In a system 100 that provides coverage into a number of buildings, one or more remote server terminals is provided, e.g., at a point of entry into each building. In other embodiments, a remote server terminal is located on each floor of the building. In yet other embodiments, a master expansion unit is provided at the point of entry into each building and a remote server unit is provided on each floor of the building. The exact location of each of the elements of system 100 is determined based on the specific layout and location of the area or areas to be covered by system 100. The examples provided here are not meant to be exhaustive and thus are not intended to be read in a limiting sense.
In operation, system 100 extends the coverage of at least two wireless services into a substantially enclosed environment. System 100 receives wireless signals for the services at service provider interface 102. Master host unit 104 receives the wireless signals and converts the wireless signals to digitized form. Master host unit 104 also aggregates the various services and passes these aggregated, digitized signals to a plurality of remote server units 106, and 108-1 to 108-N over a digital transport link. At each remote server unit, the signals for the two services are amplified and combined and transmitted over the analog link to a plurality of remote units. In one embodiment, telemetry and power are injected into the combined signal and transmitted to the remote units. At the remote units, the gain of the signals for the services are again adjusted, e.g., based on the telemetry signal, and transmitted over a plurality of antennas in various broadcast areas in the substantially enclosed environment.
Signals from wireless terminals, e.g., cell phones, are returned over system 100 in a similar fashion to the service provider interface 102.
Master host unit 200 communicates with a plurality of service providers at service provider interfaces 204-1 to 204-M, e.g., interfaces to base transceiver stations, repeaters, bi-directional amplifiers, or the like. These communications are in the form of analog wireless signals (also referred to herein as radio frequency (RF) signals). For purposes of this specification, the term “analog wireless signals” comprises signals in the frequency spectrum used to transport a wireless service, e.g., RF signals in the 800 MHz spectrum for cellular, RF signals in the 1.9 GHz spectrum for Personal Communication Services (PCS), and the like. These signals are referred to as analog signals even if the data for the service is in digital form, e.g., CDMA and TDMA signals, because the digital signals ride on an analog waveform. Advantageously, master host unit 200 enables the aggregation and transmission of a plurality of services to a plurality of buildings or other structures so as to extend the wireless coverage of multiple services into the structures on a single platform.
The interconnection of service provider interfaces 204-1 to 204-M and DHUs 202-1 to 202-N is configured based on the needs of a particular system. In some embodiments, multiple service provider interfaces 204-1 to 204-M are coupled to the same DHU 202-1 to 202-N by use of splitter/combiner circuits. In other embodiments, the same service provider interface 204-1 to 204-M is coupled to multiple DHUs 202-1 to 202-N. In one example, master host unit 200 enables the extension of both the 800 MHz cellular band and the 1.9 GHz PCS band into a plurality of buildings over a single platform. In this embodiment, master host unit 200 includes four DHUs 202-1 to 202-4. DHUs 202-1 to 202-3 are dedicated to handling the three segments of the PCS band and DHU 202-4 is dedicated to the 800 MHz band. Further, service provider interface 204-1 is a base transceiver station and is coupled to DHU 202-1 to provide the first segment of the 1.9 GHz band. Further, service provider interface 204-2 is also a base transceiver station and is coupled through splitter/combiner 206 to provide two PCS segments to DHUs 202-2 and 202-3. Finally, service provider interface 204-3 is a repeater and is coupled to provide 800 MHz service to DHU 202-4. The configuration shown in
Each DHU 202-1 to 202-N is coupled to each of a plurality of multiplexer (MUX) circuits 206-1 to 206-P. The DHUs 202-1 to 202-N communicate digitized spectrum for their assigned band with MUX circuits 206-1 to 206-P. The number of MUX circuits 206-1 to 206-P, in one embodiment, is related to the number of ports available on the DHUs 202-1 to 202-N. In one embodiment, the DHUs provide six ports, and thus a maximum of six MUX circuits 206-1 to 206-P are provided. Each MUX circuit 206-1 to 206-P provides a port for communicating aggregated, digitized signals with a remote building or other substantially closed structure. In one embodiment, MUX circuits 206-1 to 206-P comprise optical multiplexer circuits built on course wave division multiplexing (CWDM) or dense wave division multiplexing (DWDM) technology. For example, in one embodiment, MUX circuits 206-1 to 206-P comprise OptEnet optical multiplexers commercially available from ADC Telecommunications, Inc. of Eden Prairie, Minn. In one embodiment, MUX circuits 206-1 to 206-P comprise passive multiplexer modules. In yet other embodiments, MUX circuits 206-1 to 206-P comprise electrical multiplexer circuits.
Master host unit 200 also includes circuitry for providing an Operations, Administration and Maintenance (O, A & M) channel that provides, among other things, a mechanism for passing alarm information in system 100 of
Master host unit 200 also includes a computer 212 that is coupled to alarm concentrator 210. In one embodiment, computer 212 runs a network management system for system 100 of
Alarm concentrator 210 communicates and concentrates alarm messages and control messages for system 100. In one embodiment, alarm concentrator 210 receives and concentrates alarm messages from remote units 112-1 to 112-M, 113-1 to 113-S, and 114-1 to 114-Q in system 100. These alarm messages, in one embodiment, include an identification number for the remote unit and a status or alarm message. In other embodiments, other appropriate alarm messages are provided such as messages reporting changes in the attenuation levels applied at a remote unit.
Power for master host unit 200 is provided through power supply 214, e.g., an uninterrupted power supply (UPS).
In operation, master host unit 200 communicates signals between a service provider interface and a number of remote buildings or structures. In the downstream direction, the master host unit 200 receives analog wireless signals from service provider interfaces 204-1 to 204-M. These analog signals are digitized in DHUs 202-1 to 202-N. Each DHU 202-1 to 202-N provides its output to each of MUX circuits 206-1 to 206-P. The MUX circuits 206-1 to 206-P multiplex the signals on, for example, a plurality of optical carriers. Each MUX circuit 206-1 to 206-P provides its output to, for example, a digital optical cable to transport the aggregated, digitized signals to a plurality of buildings or other enclosed structures. In the upstream direction, the MUX circuits 206-1 to 206-P direct the appropriate digitized spectrum to the associated DHUs 202-1 to 202-N for conversion to analog wireless signals for the associated service provider interface 204-1 to 204-M. Modems 208-1 to 208-P process alarm messages for their assigned MUX circuit 206-1 to 206-P.
Master expansion unit 300 communicates with a master host unit, e.g., master host unit 200 of
Each DEU 302-1 to 302-N is coupled to each of a plurality of multiplexer (MUX) circuits 306-1 to 306-T. The DEUs 302-1 to 302-N communicate digitized spectrum for their assigned band with MUX circuits 306-1 to 306-T. The number of MUX circuits 306-1 to 306-T, in one embodiment, is related to the number of ports available on the DEUs 302-1 to 302-N. In one embodiment, the DEUs provide six ports, and thus a maximum of six MUX circuits 306-1 to 306-T are provided. Each MUX circuit 306-1 to 306-T provides a port for communicating aggregated, digitized signals for all of the supported services with a remote building or other substantially closed structure. In one embodiment, MUX circuits 306-1 to 306-T comprise optical multiplexer circuits built on course wave division multiplexing (CWDM) or dense wave division multiplexing (DWDM) technology. For example, in one embodiment, MUX circuits 306-1 to 306-T comprise OptEnet optical multiplexers commercially available from ADC Telecommunications, Inc. of Eden Prairie, Minn. In one embodiment, MUX circuits 306-1 to 306-T comprise passive multiplexer modules. In yet other embodiments, MUX circuits 306-1 to 306-T comprise electrical multiplexer circuits.
Master expansion unit 300 also includes circuitry for providing an Operations, Administration and Maintenance (O, A & M) channel that provides, among other things, a mechanism for passing alarm information in system 100 of
Power for master expansion unit 300 is provided through power supply 314, e.g, uninterrupted power supply (UPS).
In operation, master expansion unit 300 communicates signals between a master host unit and a remote server unit in a communication system that extends wireless coverage into a plurality of buildings. In the downstream direction, the master expansion unit 300 receives digitized wireless signals on a plurality of carriers at MUX 305 from a master host unit or another master expansion unit. The MUX circuit 305 separates the signals according to the various services and passes the signals to associated DEUs 302-1 to 302-N. These digitized signals are digitally split in DEUs 302-1 to 302-N. Each DEU 302-1 to 302-N provides its output to each of MUX circuits 306-1 to 306-T. The MUX circuits 306-1 to 306-P multiplex the signals from the DEUs 302-1 to 302-N on, for example, a plurality of optical carriers to provide an aggregated signal representing all of the digital wireless services. Each MUX circuit 306-1 to 306-T provides an output to, for example, a digital optical cable to transport the aggregated, digitized signals to a plurality of buildings or other enclosed structures.
In the upstream direction, the MUX circuits 306-1 to 306-T direct the appropriate digitized spectrum to the associated DEUs 302-1 to 302-N for digital summation. The DEUs 302-1 to 302-N provide the summed outputs for the digitized spectrum for the associated services to MUX circuit 305 for transmission to a master host or another master expansion unit.
Alarm control unit 310 and modems 309 and 308-1 to 308-P process alarm messages for the master expansion unit 300. Alarm control unit 310 receives messages from the remote units via the associated modems 308-1 to 308-T. Further, alarm control unit 310 passes alarms and other messages to selected remote units through their associated modem 308-1 to 308-T.
Remote server unit 400 communicates with a master host unit, such as master host unit 200 of
As with the master host unit 200 of
Remote server unit 400 also includes modem 416 and alarm concentrator 418 as part of an alarm mechanism for the communication system. In one embodiment, modem 416 is an optical modem. In other embodiments, modem 416 is a wireless or wired modem. Alarm concentrator 418 receives alarm and other messages from the remote units over interface 416. Alarm concentrator 418 passes these messages upstream through modem 416. In the downstream direction, messages for the remote units are received at modem 416 and provided to the appropriate remote unit through alarm concentrator 418.
Remote server unit 400 also includes a telemetry transceiver 422 coupled to splitter combiner 414. Telemetry transceiver 422 injects a signal into transmissions from the remote server unit 400 to the remote units. This signal is used by the remote units to adjust their attenuation levels based on the distance between the remote server unit 400 and the remote unit due to the affect of the length of a coaxial cable on the signal strength. In one embodiment, the telemetry signal is transmitted at frequency between the frequency ranges of the services transported over the system. For example, a telemetry signal with a frequency from 1.4 to 1.6 GHz is used when carrying both 800 MHz cellular service and 1.9 GHz PCS.
Power is also injected onto the signal at interface 416. Power is supplied via power supply 420. The power is injected onto each communication line extending from interface 416.
Remote unit 600 provides one or more air interfaces to wireless terminals for various service providers. Remote unit 600 communicates with a remote server unit, such as remote server unit 400 of
When the remote terminal is remotely powered from the remote server unit, port 602 is coupled to power supply 604. Power is extracted from the signal at port 602 and provided to power supply 604. Power supply 604 provides power to the rest of the circuitry in remote terminal 600.
Port 602 is also coupled to control carrier modem 606 to process the telemetry signal from the remote server unit. Modem 606 receives the telemetry signal from the remote server unit and passes the signal to alarm processor 608. Alarm processor 608 uses the information in the telemetry signal to determine the appropriate levels of attenuation for the various services supported by the remote terminal. The telemetry signal is used to compensate for differences in attenuation caused by different lengths of coaxial cable between the various remote units associated with a common remote server unit. In one embodiment, the remote terminal supports 800 MHz cellular service as well as the full 1.9 GHz PCS band. The telemetry signal is received at a frequency of, for example, 1.4 to 1.6 GHz. Based on the level of the telemetry signal, alarm processor 608 sets the appropriate attenuation level for processing the 800 MHz analog wireless signals and a separate attenuation level for processing 1.9 GHz analog wireless signals.
Port 602 also communicates analog wireless signals to and from the remote server unit. In one embodiment, the analog wireless signal includes both 800 MHz cellular service as well as the full 1.9 GHz PCS band. Remote terminal 600 includes separate paths for processing the various services supported. Port 602 is coupled to diplexer 610. Diplexer 610 splits and combines the signals for the various services supported by the remote terminal between a first path 612, e.g., for 800 MHz cellular, and a second path 614, e.g., for 1.9 GHz PCS.
First path 612 processes the 800 MHz signals both in the upstream and downstream directions. Duplexers 616 and 618 are located at either end of the first path 612 and separate the path into processing for the upstream signals and processing for the downstream signals. The downstream signals are processed by amplifier 620, filter 622, attenuator (Attn) 624 and amplifier 626 coupled in series between the duplexers 616 and 618. Filter 622 selects the appropriate downstream frequency band. Attenuator 624 attenuates the signal according to the level established by alarm processor 608. In the upstream direction, first path 612 includes amplifier 628, filter 630, attenuator (Attn) 632, and amplifier 634 coupled in series between duplexer 618 and duplexer 616. Filter 630 selects the upstream frequency band for the supported service and attenuator 632 provides the appropriate attenuation as set by alarm processor 608. Second path 614 operates in a similar manner and thus is not described further here.
The first and second paths 612 and 614 are coupled to diplexer 636. Diplexer 636 is also coupled to a plurality of antennas 638 over communication media, e.g., coaxial cable. In other embodiments, separate antennas are provided for each of paths 612 and 614.
In operation, remote unit 600 transmits and receives analog wireless signals for at least two services. In the downstream direction, a signal is received at port 602. This signal includes, in one embodiment, analog wireless signals in the 800 MHz band and in the 1.9 GHz band as well as power and telemetry signals. The power is extracted by power supply 604 which powers the operation of the circuitry of the remote unit 600. The telemetry signal is also received and processed by modem 606 and alarm processor 608. Alarm processor 608 generates signals to control attenuation in paths 612 and 614.
Remote unit 600 also processes the combined analog wireless signals. In the downstream direction, signals for the two services are separated in diplexer 610. The 800 MHz band is processed in path 612 and the 1.9 GHz band is processed in the 614 path. The signals are recombined in diplexer 636 and transmitted over the air interface at antennas 638. In the upstream direction, signals for the two services are received at the antennas 638 and separated at diplexer 636. Again, the 800 MHz band is processed in path 612 and the 1.9 GHz band is processed in the 614 path. The downstream signals are recombined at diplexer 610 for analog transport to the host remote server unit at port 602.
This application is a continuation of U.S. application Ser. No. 11/150,820, filed on Jun. 10, 2005, and entitled “PROVIDING WIRELESS COVERAGE INTO SUBSTANTIALLY CLOSED ENVIRONMENTS”, which is incorporated herein by reference in its entirety. This application is related to the following United States patent application, which is hereby incorporated herein by reference: U.S. application Ser. No. 12/775,897, filed on May 7, 2010, and entitled “PROVIDING WIRELESS COVERAGE INTO SUBSTANTIALLY CLOSED ENVIRONMENTS”.
Number | Date | Country | |
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Parent | 11150820 | Jun 2005 | US |
Child | 15448315 | US |