DUPLEXER WITH SIGNAL CANCELLATION

Abstract

There is provided a duplexer having first, second and third ports and adapted for connection between an antenna and uplink and downlink, respectively, in a full duplex communication system. The duplexer has first and second quarter wave transformers connected between the first and third and between the first and second ports, respectively. The duplexer has a balancing resistor connected between the third port and the output of the second transformer. The duplexer has a filter circuit connected between the output of the second transformer and the second port.

Claims

1. A duplexer having first, second and third ports and adapted for connection between an antenna and uplink and downlink, respectively, in a full duplex communication system, said duplexer comprising: first and second quarter wave transformers connected between said first and third ports and between said first and second ports, respectively; a balancing resistor connected between said third port and the output of said second transformer; and a filter circuit connected between said output of said second transformer and said second port.

2. The duplexer as in claim 1 wherein said filter circuit comprises a bandpass filter.

3. The duplexer as in claim 1 wherein said filter circuit comprises a heterodyne receiver.

4-11. (canceled)

12. A method of making a duplexer with cancellation and separation, said method comprising: modifying a Wilkinson combiner having a first port with first and second quarter wave transformers connected between a second port and said first port and between a third port and said first port respectively and a balancing resistor connected between said second and third ports, the Wilkinson combiner being modified by connecting a bandpass filter circuit to said second quarter wave transformer and said balancing resistor at one end and the third port at the other end.

13-19. (canceled)

20. A full duplex wireless communication system in which transmit and receive signals are transmitted between a base station and a plurality of subscriber equipment at first and second frequencies which are vanishingly close, each of said base station and subscriber equipment comprising a cancellation/separation duplexer having a transmit port and a receive port and being operative to shift the phase of any transmit signal at one of said transmit ports 180 degrees at the corresponding receive port.

21. The system as in claim 20 comprising cancellation/separation duplexers with first and second quarter wave transformers operative to shift the phase of any transmit signal 180 degrees.

22. The system as in claim 20 in which said subscriber equipment comprises customer premises equipment.

23. The system as in claim 20 in which said subscriber equipment comprises mobile devices.

24-33. (canceled)

34. In a full duplex wireless communication system, the duplex wireless communication system transmitting and receiving signals at the same frequency encoded in first and second encoding techniques, respectively.

35. In the full duplex wireless communication system as in claim 34, wherein the full duplex wireless communication system comprises cancellation/separation duplexers.

36. In the full duplex wireless communication system as in claim 34 wherein said first and second encoding techniques comprised frequency and amplitude modulation.

37. In the full duplex wireless communication system as in claim 34, wherein the transmit and receive signals are encoded in CDMA.

38-42. (canceled)

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0052] These and other features will become more apparent from the following description in which reference is made to the appended drawings, the drawings are for the purpose of illustration only and are not intended to be in any way limiting, wherein:

[0053] FIG. 1 is a generic block diagram of prior art two way communication system;

[0054] FIG. 2 is a block diagram of a prior art two way communication system for customer premises equipment (CPE);

[0055] FIGS. 3a and 3b are block diagrams of a generic wireless two way communication system including a cancellation/separation circuit combination and a single stage Wilkinson adapted to that use respectively;

[0056] FIG. 4 is a block diagram of the customer premises equipment of FIG. 2 adapted to include a cancellation/separation circuit; and

[0057] FIGS. 5a, 5b, and 5c are block diagrams of the Wilkinson in various modes of operation.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

[0058] FIG. 1 is a block diagram of a generic, prior art, two-way communication system. The system comprises a down link 10 and an uplink 11 connected to an antenna 13 via duplexer 14. The uplink and down link are connected to modem 16 via a second duplexer 17, the signals travelling as indicated by down pointing arrow 18 and up pointing arrow 19 in the down link and up link respectively.

[0059] FIG. 2 is a block diagram of prior art customer premises equipment for an illustrative, prior art, two-way communication system for wireless rural broadband service. The equipment comprises an antenna 110. Transceiver 140 is connected between the antenna and a modem 150. Connection to modem 150 is via duplexer 151.

[0060] The transceiver comprises an uplink 160 and a down link 170. Down link 170 and uplink 160 are connected to antenna 110 via duplexer 180. Uplink 160 comprises amplifier 190, up converter (UPC) 200, amplifier 210, and low pass filter 220. Down link 170 comprises amplifier 230. Customer premises equipment herein operates at 743 MHz downstream and 713 MHz up stream and requires a sharp duplexer.

[0061] FIG. 3a is a block diagram of the generic two-way communication system of FIG. 1 utilizing a cancellation/separation duplexer instead of a conventional duplexer. The system comprises a down link 300 and an uplink 301 connected between an antenna 302 and a modem 303 (through duplexer 309) as is the case in the prior art system of FIG. 1. But down link 300 and uplink 301 are connected to antenna 302 via a cancellation/separation duplexer 305.

[0062] FIG. 3b is a diagram of a Wilkinson combiner adapted by the addition of a filter circuit to form the cancellation/separation duplexer herein. The Wilkinson combiner is used to combine two signals into a single output. The Wilkinson combiner has three ports designated P1, P2 and P3. As shown in the FIG. 3b, quarter wave transformers T1 and T2 are connected between ports P1 and P2 and between ports P1 and P3 respectively. A balancing resistor R is connected between port P2 and port P3.

[0063] The Wilkinson combiner with a filter circuit constitutes a cancellation/separation duplexer.

[0064] The cancellation/separation duplexer is connected into any two-way communication system by connecting port P2, in FIG. 3a, to the input to down link 300 and connecting port P3 to uplink 301. As shown in FIG. 3a, downlink 300 and uplink 301 are connected to modem 303, as shown via block 309 in FIG. 3a. Block 309 represents a conventional duplexer. A cancellation/separation duplexer cannot be used for block 309.

[0065] FIG. 4 is a block diagram of customer premises equipment (CPE) for an illustrative rural broadband system using the cancellation/separation duplexer 305 of FIG. 3a. The CPE is operative to receive (downstream) signals at 743 MHz and (upstream) transmit signals at 713 MHz. The down link 401 comprises amplifier 402 high pass filter 403 and filter 417 of the duplexer. The uplink comprises low pass filter 410, amplifier 411, up converter 413, sharp filter 414, up converter (UPC) 415 and amplifier 416.

[0066] The uplink includes signal detector 421 connected to amplifier 416 operative to turn amplifier 416 on when a transmit signal is present.

[0067] Sharp filter 414 in the CPE illustratively operates at Intermediate Frequency of about 170 MHz suitable for UHF band (470-860 MHz). The filter can be used for each CPE in communication with a base station. The cost of a different duplexer for each CPE is thus eliminated and the use of identical fixed filters instead permits low cost manufacturing to bring the cost down dramatically.

[0068] As shown in FIG. 4, filter 414 is sandwiched between first and second up converters 413 and 415. These up converters are programmable, are voltage controlled and inexpensive. They are operative to change the frequency supplied by the modem (5-60 MHz) first to some Intermediate Frequency (170 MHz) and then to the 713 MHz transmit frequency as is explained more fully hereinafter.

[0069] Up converter 413 is connected to modem 420 via amplifier 411 and low pass filter 410. Up converter 415 is connected to the antenna via amplifier 416. Signal detector 421 is connected between amplifier 411 and low pass filter 410, and is connected to amplifier 416 via on/off switch (not shown).

[0070] The system of FIG. 4 operates to process transmit and receive signals as follows: The receive signal is received at the antenna 113. The signal goes through quarter wave transformer T1 into filter 417. Filter 417 passes the desired receive signal and attenuates all the other signals. The output of filter 417 is then fed into amp 402 that amplifies the signal. The output is fed into high pass filter 403. The output of the high pass filter 403 is connected to modem 420. Modem 420 receives the receive signal and processes the signal internally. The transmit signal is generated by modem 420 and fed into the input of the low pass filter 410. This filter blocks all the receive signal from entering the signal detector 421. The output of the Signal detector is fed into amp 411. The programmable upconverter 413 takes the input signal from amp 411 and translates it to an Intermediate Frequency (170 MHz). The Intermediate Frequency signal is fed into a fixed sharp filter 414. This filter is the same filter used in all the Transceivers regardless of location. The signal is cleaned up by the sharp filter and the output is fed into the programmable upconverter 415 that takes the signal to 713 MHz. This upconverter can be programmed to convert the 170 MHz to any one of the 470-860 MHz UHF band frequencies. The output of the programmable upconverter 415 is fed into amplifier 416. The output of amplifier 416 is only turned on when the signal detector 421 senses an input signal. The output of the amp 416 is fed into port P3 of the Wilkinson combiner 305. The transmit signal fed into port P3 sees 3 dB less at the antenna input. The same transmit signal is seen as being at least 40 dB less at port P2 on the cancellation/separation duplexer. The benefit of this is that even though the transmit signal is large it is seen to be over 40 dB less at port P3 on the Wilkinson combiner that is input port for the receive signal. Effectively using the cancellation/separation duplexer, to connect the antenna cost 3 dB in signal loss for transmit purposes. The Transceiver would have to produce 3 dB additional power to compensate for the loss in the duplexer. The 3 dB loss is easily compensated by outputting additional power on the amp 416 and thereby having the same power input to the antenna. The real benefit is that transmit power seen at input Filter 417 is over 40 dB lower.

[0071] The Intermediate Frequency described herein is conveniently chosen to be intermediate the system transmit frequency (470-860 MHz) and 5-60 MHz supplied by the modem at the customer premises. The Intermediate Frequency, on the other hand, may be any convenient frequency, even above the system transmit frequency. In this case, instead of two up-converters, an up converter converts the modem transmit frequency to the Intermediate Frequency and a down converter converts the frequency to the CPE transmit frequency.

[0072] FIGS. 5a, 5b, and 5c show, schematically, the Wilkinson organized as a splitter, a combiner, and as a cancellation/separation device respectively. The arrows in each case represent the direction of data flow. The signals are designated #1, #2, and #3 corresponding to the port designations. It is to be noticed that only FIG. 5c includes a filter which adapts the Wilkinson for use as a duplexer.

[0073] Using the cancellation/separation duplexer as disclosed herein, enables mobile devices to become full duplex systems thereby allowing a doubling of data rates due to fact that they can transmit and receive at the same time.

[0074] The heterodyne receiver is also well know (i.e. a radio tuner) and is used with the duplexer, disclosed herein, to provide a frequency agile transceiver which is programmable and thus obviates the need for different duplexers in CPE systems as noted above.

[0075] The single and multistage Wilkinson combiner also are well known, the latter permitting the frequency band to be made much wider thereby allow the duplexer to operate over a much wider frequency band than is possible with existing duplexers.

[0076] The cancellation/separation duplexer allows the use of the same carrier frequency for both transmit and receive.

[0077] Normally a receive signal is considerably less in power than the transmit signal. Preferably, the power of the transmit signal at the receive port is 50 dB less due to the 180 degree phase shift (signal cancellation) provided by the cancellation/separator duplexer. Consequently, the power of the transmit and receive signals at the receive port is relatively the same.

[0078] To separate the two signals at the receive port, two different modulation techniques are used. Amplitude modulation carrier and frequency modulation carrier were implemented experimentally and provided an additional 20 dB of signal separation, a total effective separation of 70 dB between the signals. It is clear that the same carrier frequency can be used for both transmit and receive by using a Wilkinson combiner/splitter plus a filter to produce the cancellation/separation duplexer. By interfacing to the transmit/receive antenna and by using two different modulation techniques over 70 dB of separation is obtained.

[0079] The 70 dB of separation has also been achieved by tuning the impedance of the transmit and receive ports to exactly match that of the antenna. With exact matched impedance plus the use of two different modulation techniques an extremely robust wireless system using the same carrier frequency is provided.

[0080] CDMA is an example of multiple access where several transmitters can send information simultaneously over a single communication channel. This allows several users to share a band of frequencies. To permit the band sharing without undue interference between the users, CDMA employs spread spectrum technology and a special coding scheme where each transmitter is assigned a code. Using CDMA with different coding for the transmit and receive channels the receive code can be separated from the transmit code using a Wilkinson combiner/splitter plus a filter to produce the cancellation/separation duplexer. With exact impedance matching CDMA can be used to provide an extremely robust wireless system using the same carrier frequency for both transmit and receive channels.

[0081] What has been described is considered merely illustrative of the principles of this invention. Thus, it should be understood that those skilled in the art are capable of producing modifications thereof within the scope of the claims. For example, a tower of a base station communicating with a plurality of CPEs may include a single antenna with a cancellation/separation duplexer, as disclosed herein, instead of the two-antenna system disclosed in the above mentioned co-pending patent application. Furthermore, multiple balancing resistors may be employed herein to provide for a relatively wide frequency response as is well understood with Multistage Wilkinson devices.

[0082] Although the invention herein is described in terms of providing cancellation/separation of in excess of 120 dB, it is be understood that the duplexer can be configured with different choices of filters to be operative with lower/higher levels of separation.